Enhanced Lipid Biosynthesis via Engineered Plastid Lipases

This application claims benefit of priority to the filing date of U.S. Provisional Application Ser. No. 62/479,599, filed March 31, 2017, the contents of which are specifically incorporated herein by reference in their entity.

Federal Funding

This invention was made with government support under DE-FG02-98ER20305, DE-FG02-91ER20021, and DE-FC02-07ER64494, awarded by the U.S. Department of Energy. The government has certain rights in the invention.

Background of the Invention

Plant oils such as triacylglycerols (TAGs) are useful for food, industrial feedstock and biofuel production. TAG is generally harvested from the seeds of oil crop species, such as canola.

Most fuels are currently produced from petroleum products, but such production involves considerable cost, both financially and environmentally. Sources of petroleum must be discovered, but petroleum exploration is an expensive and risky venture. The cost of exploring deep water wells can exceed $100 million. In addition to the economic cost, petroleum exploration carries a high environmental cost. For example, offshore exploration frequently disturbs the surrounding marine environments.

After a productive well is discovered, the petroleum must be extracted from the Earth, but such extraction is expensive and, even under the best circumstances, only 50% of the petroleum in a well can be extracted. Petroleum extraction also carries an environmental cost. For example, petroleum extraction can result in large seepages of petroleum rising to the surface. Offshore drilling involves dredging the seabed which disrupts or destroys the surrounding marine environment.

After extraction, petroleum must be transported over great distances from petroleum producing regions to petroleum consuming regions. In addition to the shipping costs, there is also the environmental risk of oil spills.

In its natural form, crude petroleum extracted from the Earth has few commercial uses. It is a mixture of hydrocarbons (e.g., paraffins (or alkanes), olefins (or alkenes), alkynes, napthenes (or cycloalkanes), aliphatic compounds, aromatic compounds, etc.) of varying length and complexity. In addition, crude petroleum contains other organic compounds (e.g., organic compounds containing nitrogen, oxygen, sulfur, etc.) and impurities (e.g., sulfur, salt, acid, metals, etc.). Hence, crude petroleum must be refined and purified before it can be used commercially.

Production of petroleum-based fuels typically involves extensive exploration, significant extraction, transportation over long distances, substantial refining, and/or significant distribution costs. There is a need for a renewable oil source that can be produced economically without environmental damage.

Summary

Described herein are transgenic plants with increased oil content. Also described are methods for producing oils from plants that exhibit enhanced expression of plastid- specific lipases. The plants can also express enzymes that increase the substrates for such lipases to facilitate increasing oil accumulation in oil seed crops. The lipase can be a plastid lipase (PLIP). For example, the lipase can be a PLASTID LIPASE 1 (PLIP1), for example a PLIP1 of Arabidopsis. The lipase can also be a PLIP2 or PLIP3 lipase. In some cases, the lipase is not a PLIP2 or PLIP3 lipase. The substrate can be a mixture of lipids, including for example a 16:l^ ^tmns -containing phosphatidylglycerol or a

monogalactosyldiacylglycerol (MGDG). In some cases, the manufacture of such substrates can be enhanced by expression of FAD4.

Described herein are also, plants, seeds, and plant cells that have at least about 1.2- fold, or at least about 15-fold more oil in its plant tissues, seeds or plant cells, as measured by percent oil per dry weight, than a plant or seed or plant cell, respectively, of the same species that has not been modified to contain nucleic acid, expression cassette, or expression vector that expresses a lipase described herein. For example, the lipases described herein are particularly useful for increasing oil content of plant seeds. The plant, plant seed, or plant cell can be, for example, an alfalfa, algae, avocado, barley, broccoli, Brussels sprout, cabbage, camelina, canola, cassava, cauliflower, coconut, cole vegetable, collard, crucifer, flax, grain, legume, forage grass, jatropa, kale, kohlrabi, maize, miscanthus, mustard, nut sedge, oat, oil firewood tree, oilseeds, olive, palm, peanut, potato, radish, rice, rutabaga, safflower, sorghum, soybean, sugar beet, sugarcane, sunflower, switchgrass, tobacco, tomato, turnip, or wheat seed plant, plant seed, or seed. In some cases, the plant, plant seed, or plant cell is not an Arabidopsis thaliana plant, plant seed, or plant cell.

Description of the Figures

FIG. 1A-1F illustrates subcellular localization of PLIP1 in Arabidopsis. FIG. 1A illustrates subcellular localization of PLIP1-YFP in leaf mesophyll cells of 3 -week-old Arabidopsis Col-0 transformed with PLIP1-YFP driven by 35S promoter or empty vector (EV) control using confocal laser scanning microscopy. Chlorophyll autofluorescence is shown in red, and YFP fluorescence is shown in green. Overlay of chlorophyll and YFP are shown as well (Merge). Representative images from one experiment are presented. Scale bars: 30 μπι. FIG. IB illustrates PLIP1 enrichment in chloroplast fractions analyzed by immunoblotting. Intact and subfractionated chloroplasts were prepared using 4-week- old Arabidopsis (Col-0) plants grown on MS medium. Equal amounts of protein of leaf tissues from the whole plant (wp), intact chloroplasts (chl), thylakoid (thy) and stroma (str) were separated by SDS-PAGE or further subjected to immunoblotting analysis using an antibody against PLIP1 ^S422A , a non-functional mutant of PLIP1. Immunoblotting was used to detect marker proteins BiP2 (endoplasmic reticulum) and LHCbl (thylakoid). For protein loading, 12 μg per fraction were loaded for PLIP1 ; 2 μg per fraction for BiP2 and LHCbl. FIG. 1C illustrates SDS-PAGE Coomassie Brilliant Blue staining to detect rubisco large subunit (stroma) and light-harvesting chlorophyll a/b-binding protein (LHCP) (thylakoid), which were used as makers. Numbers indicate protein molecular mass in kDa. For protein loading, 12 μg per fraction were loaded. FIG. ID illustrates chloroplast import experiments with labeled PLIP1 and control protein FtsH8.

Chloroplasts were treated with (+) or without (-) trypsin. Total chloroplast membranes (P) or soluble (S) fractions were analyzed by SDS-PAGE followed by fluorography. TP, translation products; p, precursor; i, intermediate; m, mature form; MW, molecular weight markers. FIG. IE shows a thin layer chromatography plates illustrating separation of polar (left) and neutral (right) lipids in E. coli containing a 6xHis-PLIPl expression cassette or an empty vector control (EV) at 6 hours following induction of PLIP1 expression. FFA, free fatty acid; O, origin of sample loading; PE, phosphatidylethanolamine; PG, phosphatidylglycerol. TLC plates were stained by iodine vapor. FIG. IF illustrates expression of PLIP1 active site mutants compared to wild type PLIP1. Lipid extracts of E. coli cultures 6 h after induction expressing 6xHis-PLIPl (PLIP1 ) or two-point mutation alleles, 6xHis-PLIPl -S422A or6xHis-PLIPl -D483A, or E. coli cultures containing an empty vector control (EV) were analyzed by thin layer chromatography to detect free fatty acid (FFA) products (top panel). Protein extracts were analyzed for protein production using an antibody against the 6xHis tag present on the expressed mutant and wild type PLIP1 proteins.

FIG. 2A-2H illustrates in vitro PLIP1 activity. FIG. 2A illustrates SDS-PAGE separation and analysis of purified PLIP1 and PLIP1 ^S422A proteins. Loading was 5 μg per lane for both samples. SDS-PAGE separated proteins were stained by Coomassie Brilliant Blue (left) or detected by irnmunoblotting with an antibody raised against PLIPl . Numbers indicate protein molecular mass in kDa. 6xHis-PLIPl and 6xHis-PLIPl ^S422A are indicated by the arrow. FIG. 2B shows a thin-layer chromatogram of products of a representative in vitro lipase reaction using phosphatidylcholine (PC) with wild- type (PLIPl + PC) and the mutant enzyme (PLIPl ^S422A + PC). Substrate without enzyme (Buffer + PC), or enzyme without substrate (PLIPl) were included as controls. PC, phosphatidylcholine. O, origin of sample loading. FIG. 2C shows illustrative gas-liquid chromatograms of methyl esters derived from commercial PC substrates or lyso-PC fractions from PLIPl lipase reactions with different PC substrates. 15:0 was used as an internal standard. FIG. 2D illustrates PLIPl lipase activity on commercial PC substrates (carbon number : double bond number; sn-l/sn-2) with different degree of saturation of the sn-1 acyl groups. PC containing 18 :0/18:1 and 18: 1/18:1 and PC containing 18:0/18:2 and 18:2/18:2 were compared, respectively. n=4, ± SD. Student's i-test was applied (**indicates p<0.01). FIG. 2E illustrates the activity of purified recombinant PLIPl on PC with different sn-2 acyl groups. PC containing 16:0/18:0, 16:0/18:1 , and 16:0/18 :2 were used as substrates. n=4, ± SD. Student's i-test was applied (** indicates p<0.01). FIG. 2F graphically illustrates PLIPl enzyme activity preferences for molecular species of phosphatidylglycerol isolated from tobacco leaves. Acyl groups of lyso- phosphatidylglycerol are shown as molar percentages of total acyl groups at any given time point. Experiments were repeated three times with similar results and data from one representative experiment are shown. FIG. 2G illustrates the activity of purified recombinant PLIPl on PC. Fatty acid methyl esters of acyl groups of both PC and Lyso-PC at each time point were analyzed by liquid gas chromatography. The fraction of PC degradation was calculated as 2 (molarity of lyso-PC acyl groups) / (2 (molarity of lyso-PC acyl groups) + (molarity of PC acyl groups)) *100. FIG. 2H illustrates PLIPl enzyme activity on different molecular species of phosphatidylglycerol. Acyl groups of lyso- phosphatidylglycerol are shown as molar percentages of total acyl groups at any given time point. Experiments were repeated three times with similar results and data from one representative experiment are shown. For each PLIPl lipase reaction, 60 μg lipids and 0.5 μg protein were used. The reactions were incubated at ambient temperature (-22 °C) for 1.5 h still during the linear portion of the reaction time course for PC in FIG. 2G. Reactions were stopped by lipid extraction, followed by lipid analysis with TLC and gas chromatography. PLIPls422A was included as a negative control and is shown in the top panel. All lipids contained two oleic acids (18: 1), except MGDG, DGDG, and SQDG, which were isolated from plants, and PI, which was isolated from bovine liver. n=3-4 for each substrate, + SD. DGDG, digalactosyldiacylglycerol; MGDG, monogalactosyldiacylglycerol; PA, phosphatidic acid; PC, phosphatidylcholine; PE, phosphatidyl ethanolamine; PG, phosphatidylglycerol; PI, phosphatidylinositol; PS, phosphatidylserine; SQDG, sulfoquinovosyldiacylglycerol; TAG, triacylglycerol.

FIG. 3A-3J illustrates in vivo PLIP1 activity. FIG. 3 A illustrates growth of 4-week- old soil-grown Arabidopsis plants. Arabidopsis wild-type plant (WT), one empty vector control line, two PLIP1 ^S422A -0X and three PLIPl-OX overexpression lines are shown. Scale bar: 5 cm. FIG. 3B graphically illustrates the relative acyl composition of phosphatidylglycerol (PG) in PLIPl-OX and empty vector (EV) control Unes. FIG. 3C graphically illustrates relative acyl composition of phosphatidylcholine (PC) in PLIPl-OX and empty vector (EV) control lines. FIG. 3D and 3E illustrate the radioactivity in polar lipids after in vivo pulse-chase acetate labeling of lipids in wild-type and PLIP -0X1 plants. FIG. 3D illustrates the radioactivity in polar lipids after a [ ¹⁴ C]-acetate labeling pulse of 60 min. FIG. 3E illustrates the radioactivity in polar lipids after a [ ¹⁴ C]-acetate labeling pulse of 60 min followed by replacement of the medium with non-labeled free acetate to initiate the chase with a duration of three days. The fractions of label in all polar lipids are given as percentages of total incorporation of label in polar lipids. Experiments were repeated three times with similar results and one representative result is shown. MGDG, monogalactosyldiacylglycerol; PC, phosphatidylcholine; PE, phosphatidylethanolamine; PG, phosphatidylglycerol. FIG. 3F illustrates the relative acyl composition of PC in wild- type (WT), fad3-2 and fad3-2, PLIPl-OXl plants. n=4, ± SD. FIG. 3G illustrates triacylglycerol (TAG) content in leaves of 4-week-old wild type (WT), plipl-1, plipl-2 and three PLIPl-OX lines. n=4-5, ± SD. FIG. 3H illustrates the radioactivity in polar lipids after a [ ¹⁴ C]-acetate labeling analysis of vegetative TAG in plants with the empty vector (EV) control and the PLIPl-OXl transgene. Excised leaves were floated on medium with [ ¹⁴ C]- acetate for 60 min, followed by changing to non-labeled acetate to initiate the chase continued for two days. Experiments were repeated three times and one representative result is shown. Where appropriate, Student's i-test was applied (* indicates p<0.05; ** indicates p<0.01). FIG. 31 graphically illustrates the relative acyl group composition of TAG found in PLIPl-OX lines as described for FIG. 3G. Acyl groups with a molar percentage less than 0.5% were omitted. n=4-5, ± SD. Student's t-test was applied (* indicates p<0.05; ** p<0.01). FIG. 3J graphically illustrates the ratio of 18:3 / 18:2 lipids in PLIPl-OX lines. FIG. 4A-4E illustrates the effects of PLIPl on seed oil biosynthesis and germination. FIG. 4 A PLIPl transcript levels in different tissues or developmental stages determined by quantitative PCR. Expression levels were normalized to those lowest in 4-week-old leaf tissues and shown as relative fold changes. n=3 for each tissue, ± SD. FIG. 4B illustrates the total acyl group content in dry seeds of wild type (WT), plipl-1, plipl-2, PLIPl-OXl and PLIP1-OX2. 30 seeds were analyzed in bulk for each repeat; n=5, ± SD. FIG. 4C illustrates the weight of the seeds used for the analysis and results shown in FIG. 4B. 200 seeds were used for each repeat; n=4-7, ± SD. FIG. 4D illustrates percent germination of WT, plipl-1, and plipl-2 seeds. The fraction of seeds showing radical emergence was determined 40 h after stratified seeds were sowed on the MS medium. 100 seeds were used for each repeat, n=3, ± SD. FIG. 4E illustrates the relative acyl group composition of dry seeds used in FIG. 4B. Acyl groups with a molar percentage less than 0.5% were omitted. Where appropriate, Student's i-test was applied (* indicates p<0.05; ** indicates p<0.01).

FIG. 5A-5C illustrate the phenotype of PLIPl-OXl embryos. FIG. 5 A illustrates the morphology of wild-type (WT) and PLIPl-OXl siliques nine days after flowering. Scale bar: 0.5 cm. The numbers indicate the length of siliques. n=9-12, ± SD. Student's i-test was applied (** indicates p<0.01). FIG. 5B shows differential interference contrast images of embryos isolated from siliques of WT and PLIPl-OXl plants. Scale bars: 50 μπι. Representative images are shown. FIG. 5C graphically illustrates radioactivity incorporated in pulse-chase labeled developing embryos isolated from siliques of wild-type (WT) and a PLIPl-OXl plants. The first two-time points represent the labeling pulse. Embryos were transferred to unlabeled medium after one hour. Values represent the fraction of label in select individual lipids compared to label in total lipids. The top panels show four lipids as indicated. The lower panels show PG and MGDG again, but on an expanded scale. MGDG, monogalactosyldiacylglycerol; PC, phosphatidylcholine; PG, phosphatidylglycerol; TAG, triacylglycerol.

FIG. 6 shows a model of PLIPl function in triacylglycerol biosynthesis. The left panel depicts the wild type (WT), the middle panel the PLIPl -overexpression lines, and the right panel the plipl mutant. The thickness of the arrows indicates the relative fluxes in the three different lines. Reactions or sets of reactions are numbered as follows: 1. In WT (left panel) acyl exchange on phosphatidylcholine (PC) involving desaturation of acyl groups by FAD2/3 provides one mechanism to introduce polyunsaturated fatty acids (FAs) into diacylglycerol (DAG). 2. A second, parallel mechanism to introduce PUFAs into DAG involves PLIPl. In the chloroplast, PLIPl hydrolyzes 18 :3/16 : l^'-phosphatidylglycerol (PG) at the sn-1 glyceryl position and releases 18 :3 (carbon : double bonds). 18:3 is exported to the Endoplasmic Reticulum and incorporated into the acyl-CoA pool and PC before entering DAG. 3. A head group exchange mechanism leads to DAG formation from PC containing polyunsaturated FAs. 4. Triacylglycerol (TAG), which accumulates in lipid droplets (LDs), is formed by the action of DAG-acyltransferases, which can introduce an additional 18:3 into TAG from the acyl-CoA pool. 5. DAG can also be formed by de novo assembly through the Kennedy pathway, which, however, is thought to play a minor role in the synthesis of TAGs in seeds. In the chloroplast, biosynthesis of PG and monogalactosyldiacylglycerol (MGDG) share the precursor phosphatidic acid (PA), with more PA being shuttled to MGDG biosynthesis in the wild type. In PLIPl -OX lines (middle panel), both PG biosynthesis and degradation are accelerated, resulting in increased export of 18:3 and its direct incorporation into PC (reactions 2). Direct incorporation of 18:3 competes with polyunsaturated FA formation by the acyl-editing pathway of PC involving FAD2/3 (reactions 1), but leads to increased flux of 18:3 into the end product TAG. Due to increased PG turnover in chloroplasts of PLIPl -OX lines, PA is preferably shuttled into PG biosynthesis, which subsequently reduces its availability for MGDG assembly in the plastid visible in changes in the MGDG acyl composition. In the plipl mutant (right panel), the PLIPl -dependent pathway is deficient, resulting in decreased TAG biosynthesis. Without the competing effect of PLIPl on the acyl exchange reactions and FAD2/3, morel8: l is converted to 18:3 explaining the altered acyl composition of TAG and other extraplastidic lipids.

FIG. 7A-7D illustrates examples of expression vectors. FIG. 7A shows an example of an expression vector for expressing PLIPl, where the PLIPl gene is under control of seed specific promoter, and a red fiuorescence marker DsRED was used for selection of transformants. FIG. 7B shows an example of an expression vector for expressing FAD4 from the seed specific, Oleosin, promoter. FIG. 7C shows an example of an expression vector for expressing PLIPl and FAD4. FIG. 7D shows another example of an expression vector for expressing PLIPl and FAD4.

FIG. 8 illustrates phylogenetic relationships of PLIPl -similar protein sequences and other characterized lipase sequences in Arabidopsis. The illustrated phylogenetic tree was built using the Maximum Likelihood method with PLIPl and the top 17 Arabidopsis similar protein sequences identified from the BLASTp search, as well as five other known Arabidopsis lipases. Previously studied lipases were presented with their gene names; others with their gene accession numbers. Bootstrap values (based on 500 repetitions) are indicated at the tree nodes. The scale measures evolutionary distances in substitution per amino acid. Any of the proteins identified in this figure can be used in the transgenic expression vectors, seeds and plants described herein.

Detailed Description

Described herein are transgenic plants, plant cells, and seeds that have one or more expression cassettes, each with a nucleic acid segment encoding a lipase operably linked to a heterologous promoter that can express the encoded lipase enzyme. The lipase can be a plastid lipase (PLIP). In some cases, the transgenic plants, plant cells, and seeds can have one or more additional expression cassettes that encode an enzyme capable of generating a substrate for a lipase. For example, the transgenic plants, plant cells, and seeds can express FAD4 in addition to one or more types of lipases. The lipases can be plastid- specific lipases, for example, PLIP1, PLIP2, PLIP3, or a combination thereof.

Such transgenic plants, plant cells, and seeds can accumulate enhanced amounts of lipids in their tissues, for example, in their seeds and/or in their vegetative tissues. The seeds and/or vegetative tissues of transgenic plants can, for example, have at least about 1.2-fold, at least about 1.5-fold, least about 2-fold, at least about 3-fold, at least about 4- fold, at least about 5-fold, at least about 7-fold, at least about 10-fold, at least about 12- fold, at least about 15-fold more lipid than a seed or vegetative tissue of the same species that has not been modified to contain a nucleic acid, expression cassette, or expression vector encoding the lipase and/or FAD4.

Overview of Lipid Biosynthesis

In plants, the lipid composition of thylakoid membranes inside chloroplasts is conserved from leaves to developing embryos. A finely tuned lipid assembly machinery builds these membranes during embryo and leaf development. Unlike thylakoid lipid biosynthetic enzymes, the function of most chloroplast lipid-degrading enzymes remains to be elucidated.

Lipid turnover requires lipases, which are enzymes that hydrolyze ester bonds of glycerolipids (Troncoso-Ponce et al., 2013; Kelly and Feussner, 2016). They are involved in a large number of cell biological processes from maintaining lipid homeostasis to lipid signaling (Wang, 2004; Scherer et al., 2010; Richmond and Smith, 2011). Phospholipases can be classified into four major types based on their lipid substrate cleavage sites: phospholipase D (PLD), phospholipase C (PLC), phospholipase Ai (PLA-), and phospholipase A ₂ (PLA?.). PLD releases the polar head group and produces phosphatidic acid while PLC cleaves the phosphodiester bond at the glyceryl sn-3 position and produces the phosphorylated head group and diacylglycerol. PLA-. and PLA?. release acyl groups from the glyceryl moiety at the sn-1 and sn-2 positions, respectively (Wang et al., 2012).

The Arabidopsis genome encodes approximately 300 proteins that are annotated as lipases, but most of them have not been biochemically verified or have unknown physiological functions (Li-Beisson et al., 2013; Troncoso-Ponce et al., 2013; Kelly and Feussner, 2016).

Some chloroplast-located lipases have intriguing physiological functions. For example, DEFECTIVE IN ANTHER DEHISCENT 1 (DAD1) (Ishiguro et al, 2001) is a chloroplast located PLAi that catalyzes the initial step of jasmonic acid production, which is involved in proper pollen development and biotic resistance. Despite the potential important functions in membrane maintenance and signaling, the bulk of chloroplast- localized lipases remains uncharacterized.

In land plants, fatty acid (FA) biosynthesis begins in plastids. In Arabidopsis, two pathways are responsible for glycerolipid biosynthesis (Benning, 2009; Hurlock et al., 2014). De novo synthesized fatty acids either directly enter the prokaryotic pathway in plastids or they are exported to the endoplasmic reticulum (ER) to be assembled into glycerolipids by the eukaryotic pathway. In developing embryos, the bulk of synthesized fatty acids, especially polyunsaturated fatty acids, is incorporated into triacylglycerol (TAG), which serves as the primary energy repository to fuel seed germination. Oleic acid (18:1 ; carbon : double bonds) is the fatty acid predominantly exported from chlorop lasts.

Exported fatty acids are activated to acyl-CoAs and initially incorporated into phosphatidylcholine (PC), which is present in the outer envelope membrane of chloroplasts and in the endoplasmic reticulum, before reentering the cytosolic acyl-CoA pool by a process referred to as acyl-editing (Bates et al., 2007). Acyl-editing allows 18 :1 to be further desaturated into polyunsaturated acyl groups attached to phosphatidylcholine (PC) before reentering the acyl-CoA pool for incorporation of FAs into other lipids, including triacylglycerols. In fact, acyl-editing is one of the two mechanisms reported for directing polyunsaturated fatty acids into triacylglycerols during embryogenesis, in parallel to direct head group exchange between PC and diacylglycerol (DAG) (Bates et al., 2012). Whether lipids other than phosphatidylcholine are subject to acyl exchange remains to be determined, as well as the nature of most of the enzymes involved in the process.

Lipases

Lipases are enzymes that can catalyze the hydrolysis of fats (lipids). Most lipases are a subclass of the esterases. For example, an Arabidopsis thylakoid membrane- associated lipase, PLASTID LIPASE 1 (PLIPl) is a phospholipase Al type enzyme that specifically hydro lyzes 18:3 (carbon : double bonds) acyl groups from a unique chloroplast- specific phosphatidylglycerol that contains ΙβΆ^ ³ * ¹³¹ _as its second acyl group. Thus far, a specific function of this 16:l ^A3trans -containing phosphatidylglycerol in chloroplasts has remained elusive. The PLIPl gene is highly expressed during seed development, and plipl mutant seeds contain less oil and exhibit delayed germination. Acyl groups released by PLIPl are exported from the chloroplast and reincorporated into phosphatidylcholine, and, ultimately, enter seed triacylglycerol. Thus, 16 :l ^A3trans uniquely labels a plastid phosphatidylglycerol pool that in developing embryos serves to channel polyunsaturated fatty acids into seed oil mediated by the action of PLIPl . Acyl exchange on thylakoid lipids can have a role in acyl export and seed oil biosynthesis.

One example of PLIPl amino acid sequence from Arabidopsis thaliana is the At3g61680 sequence, which is shown below as SEQ ID NO:l.

1MAFNTAMAST SPAAANDVLR EHIGLRRSLS GQDLVLKGGG IRRSSSDNHL 51CCRSGNNNNR ILAVSVRPGM KTSRSVGVFS FQISSSIIPS PIKTLLFETD 101TSQDEQESDE IE IETEPNLD GAKKANWVER LLEIRRQWKR EQKTESGNSD 151VAEESVDVTC GCEEEEGCIA NYGSVNGDWG RESFSRLLVK VSWSEAKKLS 201QLAYLCNLAY TIPEIKGEDL RRNYGLKFVT SSLEKKAKAA ILREKLEQDP 251THVPVITSPD LESEKQSQRS ASSSASAYKI AASAASYIHS CKEYDLSEP I 301YKSAAAAQAA ASTMTAVVAA GEEEKLEAAR ELQSLQSSPC EWFVCDDPNT 351YTRCFVIQGS DSLASWKANL FFEPTKFEDT DVLVHRGIYE AAKGIYEQFL 401PEI TEHLSRH GDRAKFQFTG HSLGGSLSLI VNLMLISRGL VSSEAMKSVV

451TFGSPFVFCG GEKILAELGL DESHVHCVMM HRDIVPRAFS CNYPDHVALV

501LKRLNGSFRT HPCLNKNKLL YSPMGKVYIL QPSESVSPTH PWLPPGNALY 551ILENSNEGYS PTALRAFLNR PHPLETLSQR AAYGSEGSVL RDHDSKNYVK

601AVNGVLRQHT KLIVRKARIQ RRSVWPVLTS AGRGLNESLT TAEEIMTRV

A nucleotide sequence encoding the SEQ ID NO:l Arabidopsis thaliana PLIPl amino acid sequence is shown below as SEQ ID NO:2.

1 CGTATATATT AATCTGGCTC CATCTACATC TGTGAAAGAG AGAGAGAGAT

51 TCATGAATCT TTTTACAGAA ACACGAACAA GTTTCAGAAT CTGGTCTGAC

101 TCTTTGTAAC CTTCTCGTTT AAGATTCATT GTACGTATTC AAATCTACAT

151 TTCTTTGCCA TTGTTGGAAT CTCCGCCTCG ATCGTTTCTT ATCAAAGGAT

201 CTGGTATTCG ATTTTTGCTA TCGTTTCAAA GCATGGTCTA ATGATGATCC

251 TGATCTCCGA CTGATCCAAT AACGGTTAAG CAACGCTGTT TTTGATCCTC

301 CATTGTTGTT TGCCATCGAT CAACACTCAG AAATAAGTTG GAGTTTTGTT

351 CATAAAGAAT GGCGTTTAAT ACGGCTATGG CGTCTACATC TCCAGCGGCG

401 GCAAATGACG TTTTAAGAGA ACATATTGGC CTCCGTAGAT CGTTGTCCGG

451 TCAAGATCTC GTCTTAAAAG GCGGTGGTAT ACGGAGATCG AGTTCCGACA

501 ATCACTTGTG TTGTCGCTCC GGTAATAATA ATAATCGCAT TCTTGCTGTG

551 TCTGTTCGTC CGGGGATGAA AACGAGTCGA TCTGTGGGAG TGTTCTCGTT

601 TCAGATATCG AGTTCTATAA TCCCAAGTCC GATAAAAACG TTGCTATTTG

651 AAACGGACAC GTCTCAAGAC GAGCAAGAGA GCGATGAGAT TGAGATTGAG 701 ACAGAGCCAA ATCTAGATGG AGCCAAGAAG GCAAATTGGG TCGAGAGGCT

751 GCTTGAGATA AGGAGACAGT GGAAGAGAGA GCAAAAAACA GAGAGTGGAA

801 ACAGTGACGT TGCAGAGGAA AGTGTTGACG TTACGTGTGG TTGTGAAGAA

851 GAAGAAGGTT GCATTGCGAA TTACGGATCT GTAAATGGTG ATTGGGGACG

901 AGAATCGTTC TCTAGATTGC TTGTGAAGGT TTCTTGGTCT GAGGCTAAAA

951 AGCTTTCTCA GTTAGCTTAT TTGTGTAACT TGGCTTACAC GATACCTGAG

1001 ATCAAGGGTG AGGATTTGAG AAGAAACTAT GGGTTAAAGT TTGTGACATC

1051 TTCATTGGAA AAGAAAGCTA AAGCAGCGAT ACTTAGAGAG AAACTAGAGC

1101 AAGATCCAAC ACATGTCCCT GTTATTACAT CCCCGGATTT AGAATCCGAG

1151 AAGCAGTCTC AACGATCAGC TTCATCTTCT GCTTCTGCTT ACAAGATTGC

1201 TGCTTCAGCT GCGTCTTACA TTCACTCTTG CAAAGAGTAT GATCTTTCAG

1251 AACCAATTTA TAAATCAGCT GCTGCTGCTC AGGCTGCAGC GTCTACCATG

1301 ACCGCGGTGG TTGCTGCGGG TGAGGAGGAG AAGCTAGAAG CGGCAAGGGA

1351 GTTACAGTCG CTACAATCAT CTCCTTGTGA GTGGTTTGTT TGTGATGATC

1401 CAAACACATA CACTAGGTGC TTTGTGATTC AGGGATCTGA TTCTTTAGCT

1451 TCTTGGAAAG CAAACCTTTT CTTCGAGCCA ACTAAGTTTG AGGACACAGA

1501 TGTATTAGTC CACAGAGGAA TCTACGAGGC AGCAAAAGGA ATATACGAAC

1551 AGTTCTTACC AGAAATAACA GAGCATTTGT CTAGACATGG AGATAGAGCT

1601 AAGTTTCAGT TCACGGGTCA TTCTCTTGGA GGCAGTCTCT CATTAATAGT

1651 GAATTTGATG CTTATCTCTA GAGGACTCGT TAGCTCTGAA GCTATGAAAT

1701 CCGTTGTCAC GTTCGGTTCA CCGTTTGTGT TTTGTGGTGG TGAGAAGATT

1751 CTAGCGGAGC TTGGTCTTGA CGAGAGTCAT GTTCACTGTG TGATGATGCA

1801 TAGAGATATC GTCCCACGAG CCTTTTCGTG TAATTATCCT GACCATGTTG

1851 CTCTCGTTCT CAAGCGTTTG AATGGCTCCT TCCGTACACA TCCTTGTCTC

1901 AACAAAAATA AACTGTTGTA TTCACCGATG GGGAAAGTAT ATATTCTACA

1951 GCCGAGTGAG AGCGTCTCGC CGACGCACCC ATGGCTTCCA CCGGGAAACG

2001 CTCTGTACAT TTTAGAAAAT AGCAACGAAG GTTACTCTCC TACGGCGTTA

2051 CGAGCATTTT TAAACCGCCC TCACCCGCTC GAAACGCTGA GTCAACGCGC

2101 AGCTTATGGC TCGGAAGGTT CAGTCTTGAG GGACCACGAC TCCAAGAACT

2151 ACGTTAAGGC CGTGAACGGA GTTCTCAGGC AGCACACGAA GCTCATAGTT

2201 AGGAAAGCCA GGATACAAAG GAGGAGTGTT TGGCCCGTGC TGACATCAGC

2251 AGGACGTGGA TTAAACGAGA GCCTGACGAC GGCCGAGGAG ATCATGACAC

2301 GTGTCTAATG AAGGAAAATG TACGGTTGTA TATAAGTGGA ATCACTTCTG

2351 ATTATGCGTT TATTTACATT TCTT

Sequence comparisons with related proteins illuminate which of the amino acids are conserved amino acids, for example, showing which amino acids may be important for activity and function of the protein. Such related protein can also be employed in the expression cassettes, plants, seeds, and plant cells, as well as the methods described herein.

For example, a PLIP1 -related lipase protein from Arabidopsis thaliana with SEQ ID NO:3 shares about 98.6% sequence identity with the SEQ ID NO:l sequence as illustrated below, where the asterisks identify amino acids that are identical in the two sequences.

Seql 1 MAFNTAMASTSPAAANDVLREHIGLRRSLSGQDLVLKGGGIRRSSSDNHLCCRSGNNNNR

Seq3 1 MAFNTAMASTSPAAANDVLREHIGLRRSLSGQDLVLKGGGIRRSSSDNHLCCRSGNNNNR

★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★

Seql 61 ILAVSVRPGMKTSRSVGVFSFQISSSIIPSPIKTLLFETDTSQDEQESDEIEIETEPNLD Seq3 61 ILAVSVRPGMKTSRSVGVFSFQISSSIIPSPIKTLLFETDTSQDEQESDEIEIETEPNLD

Seql 121 GAKKANWVERLLEIRRQWKREQKTESGNSDVAEESVDVTCGCEEEEGCIANYGSVNGDWG

Seq3 121 GAKKANWVERLLEIRRQWKREQKTESGNSDVAEESVDVTCGCEEEEGCIANYGSVNGDWG

Seql 181 RESFSRLLVKVSWSEAKKLSQLAYLCNLAYTIPEIKGEDLRRNYGLKFVTSSLEKKAKAA

Seq3 181 RESFSRLLVKVSWSEAKKLSQLAYLCNLAYTIPEIKGEDLRRNYGLKFVTSSLEKKAKAA

Seql 241 ILREKLEQDPTHVPVITSPDLESEKQSQRSASS SASAYKIAASAASYIHSCKEYDLSEP I Seq3 241 ILREKLEQDPTHVPVITSPDLESEKQSQRSASS SASAYKIAASAASYIHSCKEYDLSEP I

Seql 301 YKSAAAAQAAASTMTAWAAGEEEKLEAARELQSLQSSPCEWFVCDDPNTYTRCFVIQGS

Seq3 301 YKSAAAAQAAASTMTAWAAGEEEKLEAARELQSLQSSPCEWFVCDDPNTYTRCFVIQGS

Seql 361 DSLASWKANLFFEPTKFE DTDVLVHRGIYEAAKGIYEQFLPEITEHLSRHG

Seq3 361 DSLASWKANLFFEPTKFEVKILILARDDTDVLVHRGIYEAAKGIYEQFLPEITEHLSRHG

Seql 412 DRAKFQFTGHSLGGSLSLI LMLISRGLVSSEA KSWTFGSPFVFCGGEKILAELGLD Seq3 421 DRAKFQFTGHSLGGSLSLI LMLISRGLVSSEA KSWTFGSPFVFCGGEKILAELGLD

Seql 472 ESHVHCV MHRDIVPRAFSCNYPDHVALVLKRLNGSFRTHPCLNKNKLLYSPMGKVYILQ Seq3 481 ESHVHCV MHRDIVPRAFSCNYPDHVALVLKRLNGSFRTHPCLNKNKLLYSPMGKVYILQ

Seql 532 PSESVSPTHPWLPPGNALYILENSNEGYSPTALRAFLNRPHPLETLSQRAAYGSEGSVLR Seq3 541 PSESVSPTHPWLPPGNALYILENSNEGYSPTALRAFLNRPHPLETLSQRAAYGSEGSVLR

Seql 592 DHDSKNYVKAVNGVLRQHTKLIVRKARIQRRSVWPVLTSAGRGLNESLTTAEEIMTRV Seq3 601 DHDSKNYVKAVNGVLRQHTKLIVRKARIQRRSVWPVLTSAGRGLNESLTTAEEIMTRV

This related protein from Arabidopsis thaliana with SEQ ID NO:3 has accession number CAB71098 and the following sequence.

1 MAFNTAMAST SPAAANDVLR EHIGLRRSLS GQDLVLKGGG 41 IRRSSSDNHL CCRSGNNNNR ILAVSVRPGM KTSRSVGVFS 81 FQISSSIIPS PIKTLLFETD TSQDEQESDE IEIETEPNLD 121 GAKKANWVER LLEIRRQWKR EQKTESGNSD VAEESVDVTC 161 GCEEEEGCIA NYGSVNGDWG RESFSRLLVK VSWSEAKKLS 201 QLAYLCNLAY TIPEIKGEDL RRNYGLKFVT SSLEKKAKAA 241 I LREKLEQDP THVPVITSPD LESEKQSQRS ASSSASAYKI 281 AASAASYIHS CKEYDLSEPI YKSAAAAQAA ASTMTAVVAA 321 GEEEKLEAAR ELQSLQSSPC EWFVCDDPNT YTRCFVIQGS 361 DSLASWKANL FFEPTKFEVK ILILARDDTD VLVHRGIYEA 401 AKGIYEQFLP EITEHLSRHG DRAKFQFTGH SLGGSLSLIV 441 NLMLISRGLV SSEAMKSWT FGSPFVFCGG EKILAELGLD 481 ESHVHCVMMH RDIVPRAFSC NYPDHVALVL KRLNGSFRTH 521 PCLNKNKLLY SPMGKVYILQ PSESVSPTHP WLPPGNALYI 561 LENSNEGYSP TALRAFLNRP HPLETLSQRA AYGSEGSVLR 601 DHDSKNYVKA VNGVLRQHTK LIVRKARIQR RSVWPVLTSA 641 GRGLNESLTT AEEIMTRV

Another PLIPl-related lipase protein from Zea mays with SEQ ID NO:5 shares about 49% sequence identity as illustrated below.

Seql 70 MKTSRSVGVFSFQIS SSIIPSPIKTLLFETDTSQDEQESDEIEIETEPNLDGAKK—ANW Seq5 55 LTTSRSIGVFPFQFGAAPLRPPPLPDGGGDGSRLLTVADDADPPEPCPEMPPARRPEAHW

Seql 128 VERLLEIRRQWKR EQKTESGNSDVAEESVDVTCGCEEEEGCIANYGSVNGD WG

Seq5 115 LDRLLEVRSRFHDPTWRDVLDHDDDDDDEDLYRLDADHHHDGGCGVSYEDDGEEEDARWD

Seql 181 RESFSRLLVKVSWSEAKKLSQLAYLCNLAYTIPEIKGEDLRRNYGLKFVTSSLEKKAKAA Seq5 175 RDSFAKLLARAPLGEARLFAQLAFLCNMAYVIPEIKVEELKRHYGLRFVTSSLEKKAEAG

Seql 241 ILREKLEQDPTHVPVITSPDLESEKQSQRSASS SASAYKIAASAASYIHSCKEYDLS

Seq5 235 IISAKLDADSTRPRTAPAYEVASGPQPRRPIRS SHLAYEVAASAASYVHARARGLLSFGA

Seql 298 EPIYKSAAAAQAAASTMTAWAAGEEEKLEAARELQSLQSSPCEWFVCD

Seq5 295 PTRQQQQAAGQGRLYNSGVAAYMAASTVTAWAAEDEARQEAARDLRSPLSSPCEWFVCD

Seql 347 DPNTYTRCFVIQGSDSLASWKANLFFEPTKFEDTDVLVHRGIYEAAKGIYEQFLPEITEH Seq5 355 EADARTRCLVIQGSDSLASWQANLLFEPTEFEGTGVLVHRGIYEAAKGIYEQVMPEIEAH

Seql 407 LSRHGDRA—KFQFTGHSLGGSLSLIVNLMLISRGLVSSEAMKSWTFGSPFVFCGGEKI Seq5 415 LRAHAGRAPPRLRLTGHSLGGSLAVLVSLMLLARGWTPDALHPWTFGAPSVFCGGNRV

Seql 465 LAELGLDESHVHCVMMHRDIVPRAFSCNYPDHVALVLKRLNGSFRTHPCLNKNKLLYSPM Seq5 475 LEALGVGEAHVRSVAMHRDIVPRAFSCRYPGHAIALLKRLNGVLRTHPCLNTHKALYTPM

Seql 525 GKVYILQPSESVSPTHPWLPPGNALYILENSNEGYS PTALRAFLNRPHP

Seq5 535 GSTYILQPDSSVSPRHPFLPEGAALFRLDSDDAGLRGGAERPPRALVASALRAFLNSPHP

Seql 574 LETLSQRAAYGSEGSVLRDHDSKNYVKAVNGVLR

Seq5 595 LETLSDLSAYGAGGAILRDHESSNYFRALSALAR

This related protein from Zea mays with SEQ ID NO:5 has accession number

NP_001183891 and the SEQ ID NO:5 sequence shown below.

1 MVATVAAAGA AAAAASGRRR GARREPATMH AGIRRSRSEP

41 HLRCPRRGGA AGAALTTSRS IGVFPFQFGA APLRPPPLPD

81 GGGDGSRLLT VADDADPPEP CPEMPPARRP EAHWLDRLLE

121 VRSRFHDPTW RDVLDHDDDD DDEDLYRLDA DHHHDGGCGV

161 SYEDDGEEED ARWDRDSFAK LLARAPLGEA RLFAQLAFLC

201 NMAYVIPEIK VEELKRHYGL RFVTSSLEKK AEAGIISAKL 241 DADSTRPRTA PAYEVASGPQ PRRPIRSSHL AYEVAASAAS 281 YVHARARGLL SFGAPTRQQQ QAAGQGRLYN SGVAAYMAAS 321 TVTAWAAED EARQEAARDL RSPLSSPCEW FVCDEADART 361 RCLVIQGSDS LASWQANLLF EPTEFEGTGV LVHRGIYEAA 401 KGIYEQVMPE IEAHLRAHAG RAPPRLRLTG HSLGGSLAVL 441 VSLMLLARGV VTPDALHPW TFGAPSVFCG GNRVLEALGV 481 GEAHVRSVAM HRDIVPRAFS CRYPGHAIAL LKRLNGVLRT 521 HPCLNTHKAL YTPMGSTYIL QPDSSVSPRH PFLPEGAALF 561 RLDSDDAGLR GGAERPPRAL VASALRAFLN SPHPLETLSD 601 LSAYGAGGAI LRDHESSNYF RALSALARAP PRRRKQPEW

641 WQLPGVERLQ QYWWPGIAST VIPAPLAVSK KELVSEA

Another PLIPl-related lipase protein from Zea mays with SEQ ID NO:6 shares about 46% sequence identity with the SEQ ID NO: l protein as illustrated below.

Seql 161 GCEEEEGCIANYGSVNGDWGRESFSRLLVKVSWSEAKKLSQLAYLCNLAYTIPEIKGEDL Seq6 140 GPDSEEGCSVADGE ELDRAAFSRLLRKVSLAEAKLFSEMSGLCNLAYMVPRIKPRYL

Seql 221 RRNYGLKFVTSSLEKKAKAAILREKLEQDPT HVPVITSPDLESEKQSQRSASSS

Seq6 197 HK-YNMTFVTSSVEERAKLPNPCNQEDQNLNGRKNANISTS SRHSDEQESTYGATSEHER

Seql 275 ASAYKIAASAASYIHSCKEYDL SEPIY

Seq6 256 MQENQSGQGINPLAAYRIAASAASYMQSRAMEVLPFGSQNEARRDRTIQAIVNAQTEGLT

Seql 302 KSAAAAQAAASTMTAVVAAGEEEKLEAARELQSLQSSPCEWFVCDDPNTYTRCFVIQGSD Seq6 316 MDEASFVATTNSMTSMVAAKEETKQAVADDLNS SRSCPCEWFICDGNRNSTRYFVIQGSE

Seql 362 SLASWKANLFFEPTKFEDTDVLVHRGIYEAAKGIYEQFLPEITEHLSRHGDRAKFQFTGH Seq6 376 TIASWQANLLFEPIKFEGLDVLVHRGIYEAAKGIYQQMLPYVKSHFIVHGESARLRFTGH

Seql 422 SLGGSLSLIVNLMLI SRGLVS SEAMKSWTFGSPFVFCGGEKILAELGLDESHVHCV MH Seq6 436 SLGGSLALL LMFLIRGVAPAASLLPVITFGSPSVMCGGDYLLQKLGLPKSHVQSVTLH

Seql 482 RDIVPRAFSCNYPDHVALVLKRLNGSFRTHPCLNKNKLLYSPMGKVYILQPSESVSPTHP Seq6 496 RDIVPRAFSCHYPDHIASILKLVNGNFRSHPCLTNQKLLYAPMGEVFILQPDEKLSPHHH

Seql 542 WLPPGNALYIL—ENSNEGYSPTALR AFLNRPHPLETLSQRAAYGSEGSVLRDHDS

Seq6 556 LLPAGSGLYLIGGQTVDSGTS STALRSALSAFFNSPHPLEILRDAGAYGPKGTVYRDHDV

Seql 596 KNYVKAVNGVLRQHTKLIVRKARIQR

Seq6 616 HSYLRSIRAWRKEMRAEKERRRLLR

This protein from Zea mays with SEQ ID NO:6 has NP_001148192 and the SEQ ID NO:6 amino acid sequence is shown below.

1 MDVLRFVPGV RPPLPTFATP VSPATAPSPH AAAAAAAPGP 41 GFHSGMLGLW PRRAGENALG AAAEAAGVEE ARERRRRRAV

81 EAEDGRGGNW VLQILRVQSS PPPSPSRDDG RCGVDDGGSV

121 PGSGEGDGSS QRCVERGGVG PDSEEGCSVA DGEELDRAAF

161 SRLLRKVSLA EAKLFSEMSG LCNLAYMVPR IKPRYLHKYN

201 MTFVTS SVEE RAKLPNPCNQ EDQNLNGRKN ANISTSSRHS

241 DEQESTYGAT SEHERMQENQ SGQGINPLAA YRIAASAASY

281 MQSRAMEVLP FGSQNEARRD RTIQAIVNAQ TEGLTMDEAS

321 FVATTNSMTS MVAAKEETKQ AVADDLNSSR SCPCEWFICD

361 GNRNSTRYFV IQGSETIASW QANLLFEP IK FEGLDVLVHR

401 GIYEAAKGIY QQMLPYVKSH FIVHGESARL RFTGHSLGGS

441 LALLVNLMFL IRGVAPAASL LPVITFGSPS VMCGGDYLLQ

481 KLGLPKSHVQ SVTLHRDIVP RAFSCHYPDH IAS ILKLVNG

521 NFRSHPCLTN QKLLYAPMGE VFILQPDEKL SPHHHLLPAG

561 SGLYLIGGQT VDSGTSSTAL RSALSAFFNS PHPLEILRDA

601 GAYGPKGTVY RDHDVHSYLR SIRAWRKEM RAEKERRRLL

641 RWPIEVYGAL ATIDRRQVLR QLRRHAHLLV VFLLPAKLLF

681 LGVLSLIRPT

Another PLIPl-related lipase protein from Glycine max with SEQ ID NO:7 shares about 55-56% sequence identity with the SEQ ID NO:l protein as illustrated below.

Seql 1 MAFNTAMASTSPAAAN DVLREHIGLRRSLSGQDLVLKGGGIRRS SSDNHLCCRSGNN

Seq7 11 MAYTAVAMPTSPAATSATMDIAKEHNGLRRSQS SKELCTRS I-MRRSYSDNHLCC S

Seql 58 NNRILAVSVRPGMKTSRSVGVFSFQIS SSIIPSPIKTLLFETDTSQDEQESDEIEIETEP Seq7 66 INRIQATSVPPKLKSNRSMGI SPFQFSGSMLPNSLRSFLFDPETSKDVSVEEKWSIEEN

Seql 118 NLDGAK KANWVERLLEIRRQWKREQKTESGNSD-VAEESVDVTCGCE EEEGC

Seq7 126 MVESSKEEIANRANWVERLMEIKKHWRNRLPKESMDPDAICNENTYDECECDGDGDDNVC

Seql 169 IANYGSVNGD—WGRESFSRLLVKVSWSEAKKLSQLAYLCNLAYTIPEIKGEDLRRNYG L Seq7 186 WGEDEDEQEVTYDCDSFSNFLVQVPWSDTKLYSQLAFLCN AYVIPQIKAKDLRRYYSL

Seql 227 KFVTSSLEKKAKAAILREKLEQDPTHVPVITSPDLESEKQSQRSASS SASAYKIAASAAS Seq7 246 QFITSSLEKKVEVAKLKVKLDQDSTRVPIDDSDVSEKGKDS IKKPQIKL-AYDIAASAAS

Seql 287 YIH SCKEYDLSEPIYKSAAAAQAAASTMTA

Seq7 305 YVQLRAKDLLHRAAKSRDTQQTENEDSNGRGDSPREELESTSRGYKSEVAAYVAASTMTA

Seql 317 WAAGEEEKLEAARELQSLQS SPCEWFVCDDPNTYTRCFVIQGSDSLASWKANLFFEPTK Seq7 365 WAAGEKEKQEAANDLQSLHS SPCEWFVCDDPGNYTRCFVIQGSDSLASWQANLFFEPTK

Seql 377 FEDTDVLVHRGIYEAAKGIYEQFLPEITEHLSRHGDRAKFQFTGHSLGGSLSLIVNLMLI Seq7 425 FEDTDVLVHRGIYEAAKGIYKQFMPEIMEHLKRHGDRAKLQFTGHSLGGSLSLLVHLMLL

Seql 437 SRGLVSSEAMKSWTFGSPFVFCGGEKILAELGLDESHVHCVMMHRDIVPRAFSCNYPDH Seq7 485 TNKVVSPSTLRPVVTFGSPFVFCGGQQIINELGLDESQIHCVMMHRDIVPRAFSCNYPNH

Seql 497 VALVLKRLNGSFRTHPCLNKNKLLYSPMGKVYILQPSESVSPTHPWLPPGNALYILENSN Seq7 545 VAVVLKRLNSSFRSHPCLLKNKLLYSPLGKIFILQPDEKTSPPHPLLPRGSAFYALDNTK

Seql 557 EGYSPTALRAFLNRPHPLETLSQRAAYGSEGSVLRDHDSKNYVKAV GVLRQHTKLIVRK Seq7 605 GGYSPSVLRTFLNQPHPIDTLSDPTAYGSEGTILRDHDS SNYLKAINGVLRKHSKITVGR

** * * * * ** ****** ****** ** ** * ** *

Seql 617 ARIQR-RSVWPVLTS

Seq7 665 MRKQRINQLWPLLTS

This protein from Glycine max with SEQ ID NO:7 has XP_014627545 and the SEQ ID NO:7 amino acid sequence is shown below.

1 MQQVSNTGIS MAYTAVAMPT SPAATSATMD IAKEHNGLRR 41 SQSSKELCTR SIMRRSYSDN HLCCSINRIQ ATSVPPKLKS

81 NRSMGI SPFQ FSGSMLPNSL RSFLFDPETS KDVSVEEKW

121 SIEENMVESS KEEIANRANW VERLMEIKKH WRNRLPKESM

161 DPDAICNENT YDECECDGDG DDNVCWGED EDEQEVTYDC

201 DSFSNFLVQV PWSDTKLYSQ LAFLCNMAYV IPQIKAKDLR

241 RYYSLQFITS SLEKKVEVAK LKVKLDQDST RVPIDDSDVS

281 EKGKDS IKKP QIKLAYDIAA SAASYVQLRA KDLLHRAAKS

321 RDTQQTENED SNGRGDSPRE ELESTSRGYK SEVAAYVAAS

361 TMTAWAAGE KEKQEAANDL QSLHSSPCEW FVCDDPGNYT

401 RCFVIQGSDS LASWQANLFF EPTKFEDTDV LVHRGIYEAA

441 KGIYKQFMPE IMEHLKRHGD RAKLQFTGHS LGGSLSLLVH

481 LMLLTNKWS PSTLRPWTF GSPFVFCGGQ QIINELGLDE

521 SQIHCVMMHR DIVPRAFSCN YPNHVAWLK RLNSSFRSHP

561 CLLKNKLLYS PLGKIFILQP DEKTSPPHPL LPRGSAFYAL

601 DNTKGGYSPS VLRTFLNQPH PIDTLSDPTA YGSEGTILRD

641 HDSSNYLKAI NGVLRKHSKI TVGRMRKQRI NQLWPLLTSP

681 SPHSWSHEQN LERCSLRTKE IVTGV

Another PLIPl-related lipase protein from Glycine max with SEQ ID NO:8 shares about 55-56% sequence identity with the SEQ ID NO:l protein as illustrated below. Seql 13 AAANDVLREHIGLRRSLSGQDLVLKGGGIRRSS SDNHLCCRSGNNNNRILAVSVRPGMKT Seq8 9 SATMDIAKEHNGLRRSQSSKELCTRSI-MRRSYSDNHLCC SINRIQATSVPPKLKS

Seql 73 SRSVGVFSFQISSSIIPSPIKTLLFETDTSQDEQESDEIEIETEPNLDGAK KANW Seq8 64 NRSMGISPFQFSGSMLPNSLRSFLFDPETSKDVSVEEKVVS IEENMVESSKEEIANRANW

Seql 128 VERLLEIRRQWKREQKTESGNSD-VAEESVDVTCGCE EEEGCIANYGSVNGD—WGR

Seq8 124 VERLMEIKKHWRNRLPKESMDPDAICNENTYDECECDGDGDDNVCWGEDEDEQEVTYDC

Seql 182 ESFSRLLVKVSWSEAKKLSQLAYLCNLAYTIPEIKGEDLRRNYGLKFVTSSLEKKAKAAI Seq8 184 DSFSNFLVQVPWSDTKLYSQLAFLCNMAYVIPQIKAKDLRRYYSLQFITSSLEKKVEVAK Seql 242 LREKLEQDPTHVPVITSPDLESEKQSQRSASSSASAYKIAASAASYIH

Seq8 244 LKVKLDQDSTRVPIDDSDVSEKGKDSIKKPQIKL-AYDIAASAASYVQLRAKDLLHRAAK

Seql 290 SCKEYDLSEPIYKSAAAAQAAASTMTAWAAGEEEKLEAARE

Seq8 303 SRDTQQTENEDSNGRGDSPREELESTSRGYKSEVAAYVAASTMTAVVAAGEKEKQEAAND

Seql 332 LQSLQSSPCEWFVCDDPNTYTRCFVIQGSDSLASWKANLFFEPTKFEDTDVLVHRGIYEA Seq8 363 LQSLHSSPCEWFVCDDPGNYTRCFVIQGSDSLASWQANLFFEPTKFEDTDVLVHRGIYEA Seql 392 AKGIYEQFLPEITEHLSRHGDRAKFQFTGHSLGGSLSLI LMLISRGLVSSEA KSWT Seq8 423 AKGIYKQFMPEIMEHLKRHGDRAKLQFTGHSLGGSLSLLVHLMLLTNKWSPSTLRPWT

Seql 452 FGSPFVFCGGEKILAELGLDESHVHCV MHRDIVPRAFSCNYPDHVALVLKRLNGSFRTH Seq8 483 FGSPFVFCGGQQIINELGLDESQIHCV MHRDIVPRAFSCNYPNHVAWLKRLNSSFRSH

Seql 512 PCLNKNKLLYSPMGKVYILQP SESVSPTHPWLPPGNALYILENSNEGYSPTALRAFLNRP Seq8 543 PCLLKNKLLYSPLGKIFILQPDEKTSPPHPLLPRGSAFYALDNTKGGYSPSVLRTFLNQP

Seql 572 HPLETLSQRAAYGSEGSVLRDHDSKNYVKAVNGVLRQHTKLIVRKARIQR-RS PVLTS Seq8 603 HPIDTLSDPTAYGSEGTILRDHDSSNYLKAINGVLRKHSKITVGRMRKQRINQLWPLLTS

This protein from Glycine max with SEQ ID NO:8 has XP_014627549.1 and the

SEQ ID NO:8 amino acid sequence is shown below.

1 MPTSPAATSA TMDIAKEHNG LRRSQSSKEL CTRSIMRRSY

41 SDNHLCCSIN RIQATSVPPK LKSNRSMGIS PFQFSGSMLP

81 NSLRSFLFDP ETSKDVSVEE KWSIEENMV ESSKEEIANR

121 ANWVERLMEI KKHWRNRLPK ESMDPDAICN ENTYDECECD

161 GDGDDNVCW GEDEDEQEVT YDCDSFSNFL VQVPWSDTKL

201 YSQLAFLCNM AYVIPQIKAK DLRRYYSLQF ITSSLEKKVE

241 VAKLKVKLDQ DSTRVPIDDS DVSEKGKDS I KKPQIKLAYD

281 IAASAASYVQ LRAKDLLHRA AKSRDTQQTE NEDSNGRGDS

321 PREELESTSR GYKSEVAAYV AASTMTAVVA AGEKEKQEAA

361 NDLQSLHSSP CEWFVCDDPG NYTRCFVIQG SDSLASWQAN

401 LFFEPTKFED TDVLVHRGIY EAAKGIYKQF MPEIMEHLKR

441 HGDRAKLQFT GHSLGGSLSL LVHLMLLTNK WSPSTLRPV

481 VTFGSPFVFC GGQQI INELG LDESQIHCVM MHRDIVPRAF

521 SCNYPNHVAV VLKRLNSSFR SHPCLLKNKL LYSPLGKIFI

561 LQPDEKTSPP HPLLPRGSAF YALDNTKGGY SPSVLRTFLN

601 QPHPIDTLSD PTAYGSEGTI LRDHDSSNYL KAINGVLRKH

641 SKITVGRMRK QRINQLWPLL TSPSPHSWSH EQNLERCSLR

681 TKEIVTGV

Another PLIPl-related lipase protein from Glycine max with SEQ ID NO:9 shares about 54% sequence identity with the SEQ ID NO: l protein as illustrated below. Seql 1 MAFNTAMASTSPAAAN DVLREHIGLRRSLSGQDLVLKGGGIRRSS SDNHLCCRSGNN

Seq9 1 MAYTAVAMPTSPAATSATVDIAKEHNGLRRSQSSKELHTRAV-MRRSYSDNHLCC S

Seql 58 NNRILAVSVRPGMKTSRSVGVFSFQISS SIIPSP IKTLLFETDTSQDEQESDEIEIETEP Seq9 56 INRVQATSVPPKLKSNQPMGISPFQFSGSILPNSLRSFLFDPETSNDLWEEKVVSIEEN

Seql 118 NLDGAK KANWVERLLEIRRQWKREQKTESGNSD-VAEESVDVTCGCE EEEGC

Seq9 116 MVES SKEEIVNRANWVERLMEIKKHWRNRLPKESMNTDAICNDNTYDECECDGDGDDNVC

Seql 169 IANYGSVNGD—WGRESFSRLLVKVSWSEAKKLSQLAYLCNLAYTIPEIKGEDLRRNYG L Seq9 176 WGEDEDEQEVTYDRDSFSSFLVQVPWSDTKLYSQLAFLCNMAYVIPQIKAKDLRRYYSL

Seql 227 KFVTSSLEKKAKAAILREKLEQDPTHVPV ITSPDLESEKQSQRSASSSASAYKIAAS

Seq9 236 QFITSSLEKKAEVAKLKVQLNQDSTCVPVDDSVASQDVSKKDKDNTKKPQIKLAYDIAAS

Seql 284 AASYIH SCKEYDLSEPI YKSAAAAQAAAS

Seq9 296 AASYVQLRAKDLLHRAAKSQDTQQTENEDSNEREDLPGREELEGTSRGYKSEVAAYVAAS

Seql 313 TMTAVVAAGEEEKLEAARELQSLQSSPCEWFVCDDPNTYTRCFVIQGSDSLASWKANLFF Seq9 356 TMTAVVAAGEKEKQETANDLQSLHSSPCEWFVCDDPGNYTRCFVIQGSDSLASWQANLFF

Seql 373 EPTKFEDTDVLVHRGIYEAAKGIYEQFLPEITEHLSRHGDRAKFQFTGHSLGGSLSLIVN Seq9 416 EPTKFEGTDVLVHRGIYEAAKGIYKQFMPEIMEHLKRHGDRAKLQFTGHSLGGSLSLLVH

Seql 433 LMLI SRGLVS SEAMKSWTFGSPFVFCGGEKILAELGLDESHVHCV MHRDIVPRAFSCN Seq9 476 LMLLTNKWSPSTLGP IVTFGSPFVFCGGQQIIDELGLDESQIHCV MHRDIVPRAFSCN

Seql 493 YPDHVALVLKRLNGSFRTHPCLNKNKLLYSPMGKVYILQP SESVSPTHPWLPPGNALYIL Seq9 536 YPNHVALVLKRLHTSFRSHPCLLKNKLLYSPLGKIFILQPDEKTSPPHPLLPRGSAFYAL

Seql 553 ENSNEGYSPTALRAFLNRPHPLETLSQRAAYGSEGSVLRDHDSKNYVKAVNGVLRQHTKL Seq9 596 DNTK CPSVLRTFLNQPHPIDTLSDPTAYGSEGTILRDHDSSNYLKAINGVLRKHSKI

Seql 613 IVRKARIQR-RSVWPVLTS

Seq9 653 IVGRVRKQRINQLWPLLTS

This protein from Glycine max with SEQ ID NO:9 has K7KH33 and the SEQ ID

NO:9 amino acid sequence is shown below.

10 20 30 40 50

MAYTAVAMPT SPAATSATVD IAKEHNGLRR SQSSKELHTR AVMRRSYSDN

60 70 80 90 100

HLCCSINRVQ ATSVPPKLKS NQPMGISPFQ FSGSILPNSL RSFLFDPETS

110 120 130 140 150

NDLWEEKW SIEENMVESS KEEIVNRANW VERLMEIKKH WRNRLPKESM

160 170 180 190 200

NTDAICNDNT YDECECDGDG DDNVCWGED EDEQEVTYDR DSFSSFLVQV 210 220 230 2 40 250

PWSDTKLYSQ LAFLCNMAYV IPQIKAKDLR RYYSLQFITS SLEKKAEVAK

2 60 270 2 8 0 2 90 300

LKVQLNQDST CVPVDDSVAS QDVSKKDKDN TKKPQIKLAY DIAASAASYV

310 320 330 340 350

QLRAKDLLHR AAKSQDTQQT ENEDSNERED LPGREELEGT SRGYKSEVAA

360 370 38 0 3 90 400

YVAASTMTAV VAAGEKEKQE TANDLQSLHS SPCEWFVCDD PGNYTRCFVI

410 420 430 4 40 450

QGSDSLASWQ ANLFFEPTKF EGTDVLVHRG IYEAAKGIYK QFMPEIMEHL

4 60 470 4 8 0 4 90 500

KRHGDRAKLQ FTGHSLGGSL SLLVHLMLLT NKVVSPSTLG PIVTFGSPFV

510 520 530 540 550

FCGGQQIIDE LGLDESQIHC VMMHRDIVPR AFSCNYPNHV ALVLKRLHTS

560 570 58 0 5 90 600

FRSHPCLLKN KLLYSPLGKI FILQPDEKTS PPHPLLPRGS AFYALDNTKC

610 620 630 640 650

PSVLRTFLNQ PHPIDTLSDP TAYGSEGTIL RDHDSSNYLK AINGVLRKHS

660 670 68 0 6 90

KIIVGRVRKQ RINQLWPLLT SPSPHSRSHE QNSERCSLRT KEIVTGV

Another PLIPl-related lipase protein from Brassica napus with SEQ ID NO:10 shares about 84% sequence identity with the SEQ ID NO:l protein as illustrated below.

Seql 1 MAFNTAMASTSPAAA-NDVLREHIGLRRSLSGQDLVLKGGGIRRSSSDNHLCCRSGNNNN SeqlO 1 MAFNAAMASPPPAAAANDVFKEHFGLRRSLSGQDLWKAGGIRRSSSDNHLCC NN

Seql 60 RILAVSVRPG—MKTSRSVGVFSFQIS SSIIPSPIKTLLFETDTSQDEQESDEIEIETEP SeqlO 56 RIRAVSVRPGQGMKS SRSVGVFSFQIS SSIIPSPIKTLLFETE DDKDSDD-EPEVQP

Seql 118 NLDGAKKAN ERLLEIRRQWKREQKTESGNSDVAEESVDVTCGCEEEEGCIANYGSVNG SeqlO 112 NLDGVKKANWVQRLLEIRRQWKKETKTENVNGDWSEHENVTCGCEDGEGCVADY—ENG

Seql 178 DWGRESFSRLLVKVSWSEAKKLSQLAYLCNLAYTIPEIKGEDLRRNYGLKFVTSSLEKKA SeqlO 170 DWERESFSKLLVRVSWSDAKQLSQLAYLCNVAYTIPEIKGEDLRRNYGLKFVTSSLEKKA

Seql 238 KAAILREKLEQDPTHVPVITSPDLESEKQSQRSASSSASAYKIAASAASYIHSCKEYDLS SeqlO 230 KAALLREKLEQDSTRVPVVTSPESESEKPQQRS SSSSA—YNIAASAASYIHSCKEVDS S Seql 298 EPI—YKSAAAAQAAASTMTAWAAGEEEKLEAARELQSLQSSPCEWFVCDDPNTYTRCF SeqlO 288 DLSNPYKSAAAAQAAASTMTAWAAGEDEKLEAARELQSLQSSPCEWFVCDDLSSYTRCF

Seql 356 VIQGSDSLASWKANLFFEPTKFEDTDVLVHRGIYEAAKGIYEQFLPEITEHLSRHGDRAK SeqlO 348 VIQGSDSLASWKANLFFEPTKFEDTDVLVHRGIYEAAKGIYEQFLPEITEHLSLHGDRAR

Seql 416 FQFTGHSLGGSLSLIVNLMLI SRGLVS SEAMKSWTFGSPFVFCGGEKILAELGLDESHV SeqlO 408 FQFTGHSLGGSLSLIWLMLLSRGLVS SEAMKPWTFGSPFVFCGGEKILEELGLDESHV Seql 476 HCV MHRDIVPRAFSCNYPDHVALVLKRLNGSFRTHPCLNKNKLLYSPMGKVYILQPSES SeqlO 468 HCV MHRDIVPRAFSCNYPDHVALVLKRLNGTFRTHPCLNKNKLLYSPMGKVFILQPSES

Seql 536 VSPTHPWLPPGNALYILENSNEGYSPTALRAFLNRPHPLETLSQRAAYGSEGSVLRDHDS SeqlO 528 VSPTHPWLPPGNALYVLDKNNEDYSPTALRGFLNRPHPLETLSQRAAYGSEGSVLRDHDS Seql 596 KNYVKAVNGVLRQHTKLIVRKARIQRRSVWPVLTSA—GRGLNE-SLTTAEEIMTR SeqlO 588 KNYVKAVNGVIRQHTKLIVRKVRRQRSTIWPVLTSAEPNSS DWSLTATEEIMTR

This lipase protein from Brassica napus with SEQ ID NO:10 has CDY43945.1 and the SEQ ID NO: 10 amino acid sequence is shown below.

1 MAFNAAMASP PPAAAANDVF KEHFGLRRSL SGQDLWKAG 41 GIRRSS SDNH LCCNNRIRAV SVRPGQGMKS SRSVGVFSFQ

81 ISSSIIPSPI KTLLFETEDD KDSDDEPEVQ PNLDGVKKAN

121 WVQRLLEIRR QWKKETKTEN VNGDWSEHE NVTCGCEDGE

161 GCVADYENGD WERESFSKLL VRVSWSDAKQ LSQLAYLCNV

201 AYTIPE IKGE DLRRNYGLKF VTSSLEKKAK AALLREKLEQ

241 DSTRVPWTS PESESEKPQQ RSSSSSAYNI AASAASYIHS

281 CKEVDSSDLS NPYKSAAAAQ AAASTMTAVV AAGEDEKLEA

301 ARELQSLQSS PCEWFVCDDL SSYTRCFVIQ GSDSLASWKA

361 NLFFEPTKFE DTDVLVHRGI YEAAKGIYEQ FLPEITEHLS

401 LHGDRARFQF TGHSLGGSLS LIVNLMLLSR GLVSSEAMKP

441 VVTFGSPFVF CGGEKILEEL GLDESHVHCV MMHRDIVPRA

481 FSCNYPDHVA LVLKRLNGTF RTHPCLNKNK LLYSPMGKVF

521 ILQPSESVSP THPWLPPGNA LYVLDKNNED YSPTALRGFL

561 NRPHPLETLS QRAAYGSEGS VLRDHDSKNY VKAVNGVIRQ

601 HTKLIVRKVR RQRSTIWPVL TSAEPNSSVN DWSLTATEEI

641 MTRA Another PLIPl-related lipase protein from Brassica napus with SEQ ID NO:l 1 shares about 83-84% sequence identity with the SEQ ID NO:l protein as illustrated below.

Seql 1 MAFNTAMASTSPAAANDVLREHIGLRRSLSGQDLVLKGGGIRRSSSDNHLCCRSGNNNNR Seqll 1 MSFNAAMASPSPPAANDVFKEHFGLRRSLSGQDLWKAGGIRRSSSDNHLCCK NR

Seql 61 ILAVSVRPG—MKTSRSVGVFSFQISS SIIPSP IKTLLFETDTSQDEQESDEIEIETEPN Seqll 56 IRAVSVRPGQGMKSSRSVGVFSFQISSSIIPSPIKTLLFETE DDTDSDD-EPEVEPN

Seql 119 LDGAKKANWVERLLEIRRQWKREQKTESGNSDVAEESVDVTCGCEEEEGCIANYGSVNGD Seqll 112 LDGAKKANWVQRLLEIRRQWKKETRTENSNGDVVSEHENVTCGCEDGEGCVADY—ENG D Seql 179 WGRESFSRLLVKVSWSEAKKLSQLAYLCNLAYTIPEIKGEDLRRNYGLKFVTS SLEKKAK Seqll 170 WERESFSKLLVRVSWSDAKQLSQLAYLCNVAYTIPEIKGEDLRRNYGLKFVTS SLEKKAK Seql 239 AAILREKLEQDPTHVPVITSPDLESEKQSQRSASSSASAYKIAASAASYIHSCKEYDLSE Seqll 230 AALLREKLEQDSTRVPWTSPESESDKFQQRS-SSSSSAYKIAASAASYIHSCKEYESSD

Seql 299 —P IYKSAAAAQAAASTMTAVVAAGEEEKLEAARELQSLQS SPCEWFVCDDPNTYTRCFV Seqll 289 LNNPYKSAAAAQAAASTMTAVVAAGEDEKLEAARELQSLQS SPCEWFVCDEPNSYTRCFV Seql 357 IQGSDSLASWKANLFFEPTKFEDTDVLVHRGIYEAAKGIYEQFLPEITEHLSRHGDRAKF Seqll 349 IQGSDSLASWKANLFFEPTRFEDTDVLVHRGIYEAAKGIYEQFLPEITEHLSLHGDRAKF

Seql 417 QFTGHSLGGSLSLIVNLMLISRGLVSSEAMKSVVTFGSPFVFCGGEKILAELGLDESHVH Seqll 409 QFTGHSLGGSLSLIVNLMLLSRGLVSSEAMKPVVTFGSPFVFCGGEKILEELGLEESHVH

Seql 477 CVMMHRDIVPRAFSCNYPDHVALVLKRLNGSFRTHPCLNKNKLLYSPMGKVYILQPSESV Seqll 469 CVMMHRDIVPRAFSCNYPDHVALVLKRLNGTFRTHPCLNKNKLLYSPMGKVFILQPSESV

Seql 537 SPTHPWLPPGNALYILENSNEGYSPTALRAFLNRPHPLETLSQRAAYGSEGSVLRDHDSK Seqll 529 SPTHPWLPPGNALYVLDKNNEGYSPTALRGFLNRPHPLETLSQRAAYGSEGSVLRDHDSK

Seql 597 NYVKAVNGVLRQHTKLIVRKARIQRRS-VWPVLTSA—GRGLNE-SLTTAEEIMTR Seqll 589 NYVKAVNGVIRQHTKLIVRKVRRQRRSTVWPVLTPAEPNSSVNDWSLTATEEIMTR

This lipase protein from Brassica napus with SEQ ID NO:l 1 has accession number XP_013741914.1 and the SEQ ID NO:l l amino acid sequence is shown below.

1 MSFNAAMASP SPPAANDVFK EHFGLRRSLS GQDLWKAGG 41 IRRSSSDNHL CCKNRIRAVS VRPGQGMKSS RSVGVFSFQI

81 SSSIIPSPIK TLLFETEDDT DSDDEPEVEP NLDGAKKANW

121 VQRLLEIRRQ WKKETRTENS NGDVVSEHEN VTCGCEDGEG

161 CVADYENGDW ERESFSKLLV RVSWSDAKQL SQLAYLCNVA

181 YTIPEIKGED LRRNYGLKFV TSSLEKKAKA ALLREKLEQD

241 STRVPVVTSP ESESDKFQQR SSSSSSAYKI AASAASYIHS

281 CKEYES SDLN NPYKSAAAAQ AAASTMTAVV AAGEDEKLEA

321 ARELQSLQSS PCEWFVCDEP NSYTRCFVIQ GSDSLASWKA

361 NLFFEPTRFE DTDVLVHRGI YEAAKGIYEQ FLPEITEHLS

401 LHGDRAKFQF TGHSLGGSLS LIVNLMLLSR GLVSSEAMKP

421 VVTFGSPFVF CGGEKILEEL GLEESHVHCV MMHRDIVPRA

481 FSCNYPDHVA LVLKRLNGTF RTHPCLNKNK LLYSPMGKVF

521 ILQPSESVSP THPWLPPGNA LYVLDKNNEG YSPTALRGFL

561 NRPHPLETLS QRAAYGSEGS VLRDHDSKNY VKAVNGVIRQ

601 HTKLIVRKVR RQRRSTVWPV LTPAEPNSSV NDWSLTATEE

641 IMTRA Another PLIPl-related lipase protein from Gossypium hirsutum (cotton) with SEQ

ID NO:64 shares about 53-56% sequence identity with the SEQ ID NO:l protein as illustrated below. Seql 10 TSPAAANDVLREHIGLRRSLSGQDLVLKGGGIRRSSSDNHLCCRSGNNNNRILAVSVRPG Seq64 14 TAVAKKDGCKEEIGGLRRSNSGVNLH-KRVGIQRSYSDNHLCYYT NRIVAASTKST

Seql 70 MKTSRSVGVFS FQISSSIIPSPIKTLLFETDTSQD EQESDEIEIETEPNLDGA

Seq64 69 LKTSRSFGILPPLPFRISGSMIPNSVRSFLFDPETSKDLSGVGKD VIDGNSRGNDDEE

Seql 123 K KANWVERLLEIRRQWKREQKTES—GNSDVAEESVDVTCGCEEEEGCIANYGSVNG

Seq64 129 KEIKRANWLNRLLEIQSSFKHKQVEEGVEGAGIYDENENGDDGGCEVNYDSEDEGGEVKY

Seql 178 DWGRESFSRLLVKVSWSEAKKLSQLAYLCNLAYTIPEIKGEDLRRNYGLKFVTSSLEKKA Seq64 189 D—RDSFSKLLVQVPWSDTKVISQLAFLCNMAYVIPSIKEKDLRKYYGLRFVTSSLEKK A

Seql 238 KAAILREKLEQDPTHVPVITSPDLESEKQSQRSASSS ASAYKIAASAASYI

Seq64 247 KAAKIKAKLDQDSTRVPIAETSESESKKVESKEWKHPIRISWYEIAASAACYVQSQAKG

Seql 289 HSCK EYDLSEP-IYKSAAAAQAAASTMTAWAAGEEEK

Seq64 307 LLSPGSKSQEEEDDMNSCRISEQPEMEGENSPPRVYNSEVAALMAAEA TAWRAGEKEK

Seql 326 LEAARELQSLQSSPCEWFVCDDPNTYTRCFVIQGSDSLASWKANLFFEPTKFEDTDVLVH Seq64 367 QETAKDLQSLHSSPCEWFVCDDLNTYTRCFVIQGSDSLASWQANLLFEPTEFEGTGVLVH

Seql 386 RGIYEAAKGIYEQFLPEITEHLSRHGDRAKFQFTGHSLGGSLSLI LMLISRGLVSSEA Seq64 427 RGIYEAAKGIYEQFIPEIMDHLKRHGHRAKLQFTGHSLGGSLSLL LMLLARKWKPSA

Seql 446 MKSWTFGSPFVFCGGEKILAELGLDESHVHCV MHRDIVPRAFSCNYPDHVALVLKRLN Seq64 487 LRPWTFGSPFVFCGGQRILDELGLDDNHVHCV MHRDIVPRAFSCKYPNHVAWLKRLP

Seql 506 GSFRTHPCLNKNKLLYSPMGKVYILQP SESVSPTHPWLPPGNALYILENSNEGYSPTALR Seq64 547 GSLRSHPCLLKNKLLYTPLGKQFILQP SEKSSPPHPLIPPGNALYALDKTHSEYSMQALM

Seql 566 AFLNRPHPLETLSQRAAYGSEGSVLRDHDSKNYVKAVNGVLRQHTKLIVRKARIQRRSVW Seq64 607 AFLNCPHPLDTLGDLTAYGLDGTILRDHDSSNYLKAVNGVLRLQ-KMANRCSRMDTSLLW

Seql 626 PVLTS

Seq64 666 PLLNS

This lipase protein from Gossypium hirsutum (cotton) with SEQ ID NO:64 has accession number XP_016692941.1 and the SEQ ID NO:64 amino acid sequence is shown below.

1 MACTSMWPT SHVTAVAKKD GCKEEIGGLR RSNSGVNLHK 41 RVGIQRSYSD NHLCYYTNRI VAASTKSTLK TSRSFGILPP

81 LPFRISGSMI PNSVRSFLFD PETSKDLSGV GKDVNVIDGN

121 SRGNDDEEKE IKRANWLNRL LEIQSSFKHK QVEEGVEGAG

161 IYDENENGDD GGCEVNYDSE DEGGEVKYDR DSFSKLLVQV 201 PWSDTKVISQ LAFLCNMAYV IPS IKEKDLR KYYGLRFVTS

241 SLEKKAKAAK IKAKLDQDST RVPIAETSES ESKKVESKEW

281 KHPIRISWY EIAASAACYV QSQAKGLLSP GSKSQEEEDD

321 MNSCRISEQP EMEGENSPPR VYNSEVAALM AAEAMTAVVR

361 AGEKEKQETA KDLQSLHSSP CEWFVCDDLN TYTRCFVIQG

401 SDSLASWQAN LLFEPTEFEG TGVLVHRGIY EAAKGIYEQF

441 IPEIMDHLKR HGHRAKLQFT GHSLGGSLSL LVNLMLLARK

481 VVKPSALRPV VTFGSPFVFC GGQRILDELG LDDNHVHCVM

521 MHRDIVPRAF SCKYPNHVAV VLKRLPGSLR SHPCLLKNKL

561 LYTPLGKQFI LQPSEKSSPP HPLIPPGNAL YALDKTHSEY

601 SMQALMAFLN CPHPLDTLGD LTAYGLDGTI LRDHDSSNYL

641 KAVNGVLRLQ KMANRCSRMD TSLLWPLLNS PSPHSWSHDR

681 SLENILLSNK EIMSGV

Another PLIPl-related lipase protein from Gossypium hirsutum (cotton) with SEQ

ID NO:65 shares about 53-54% sequence identity with the SEQ ID NO:l protein as illustrated below.

Seql 33 DLVLKGGGIRRSSSDNHLCCRSGNNNNRILAVSVRPGMKTSRSVGVFSFQISSSIIPSPI Seq65 24 DSSMNKAGIRRSYSDNHLCC SINRIRAAASTKPTMTKSSSVGILPSLLPVQISSSTI

Seql 93 KTLLFETDTSQDEQESDEIEIETEPNLDGAKKANWVERLLEIRRQWKREQKTES-GNSDV Seq65 81 PNSVRSFWFDDNDDEEEEI KRANWVNRLLEVHSRWKHRQIEDGVEGGEI

Seql 152 AEESVDVTCGCEEEEGCIANYGS-VNGD WGRESFSRLLVKVSWSEAKKLSQLAYLCN

Seq65 130 YDENENDGNEDEHEGGCEVNYNSDEEGDEWYDRESFSKLLVRVPLSDTKLFSELAFLCN

Seql 208 LAYTIPEIKGEDLRRNYGLKFVTSSLEKKAKAAILREKLEQDPTHVPVITSPDLESEK� � Seq65 190 IAYVIPKIEGMELRKYYGLKFVTSSIEKKAEVATIKAKMDQDSIRVPVATPKSTELEKVE

Seql 266 -QSQRSASS SASAYKIAASAASYIHSCK EYDLS

Seq65 250 GTETKRLISLSAVYEIAASAAYYVQSRAKGLLSPGFKSPVEDERDSRRSGDEHEMEGENS

Seql 298 EPIYKSAAAAQAAASTMTAWAAGEEEKLEAARELQSLQSSPCEWFVCDDPNTYTRCFVI Seq65 310 PRVYNSEVAAYMAASA TAWRSGEKAKQATAKDLQSLQSSPSEWSVCDELSTYTRCFVI

Seql 358 QGSDSLASWKANLFFEPTKFEDTDVLVHRGIYEAAKGIYEQFLPEITEHLSRHGDRAKFQ Seq65 370 QGSDSLASWQANLLFEPTTFEYTDVLVHRGIYEAAKGIYEQFLPEIMDHLNRHGDRAKLQ

Seql 418 FTGHSLGGSLSLI LMLISRGLVSSEA KSWTFGSPFVFCGGEKILAELGLDESHVHC Seq65 430 FTGHSLGGSLSLLVSLMLLAKKWKPSALRPVITFGSPFVFCGGQKILEEFGLDDNHVHC

Seql 478 V MHRDIVPRAFSCNYPDHVALVLKRLNGSFRTHPCLNKNKLLYSPMGKVYILQPSESVS Seq65 490 V MHRDIVPRAFSCKYPNHVAIVLKRLPGSLRSHRCLLKNKLLYTPLGKLFIVQPSEKSS

Seql 538 PTHPWLPPGNALYILENSNEGYSPTALRAFLNRPHPLETLSQRAAYGSEGSVLRDHDSKN Seq65 550 PPHPLLPLGTA PLDTLSDLTAYGSEGTILRDHDSSN ★★★★★★

Seql 598 YVKAVNGVLRQHTKLI

Seq65 586 YLKAINGVLRQHKKTV

This lipase protein from Gossypium hirsutum (cotton) with SEQ ID NO:65 has accession number XP_016738139.1 and the SEQ ID NO:65 amino acid sequence is shown below.

1 MAVPTSRVAS KAKEEEINGL RRLDSSMNKA GIRRSYSDNH 41 LCCSINRIRA AASTKPTMTK SSSVGILPSL LPVQISSSTI

81 PNSVRSFWFD DNDDEEEEIK RANWVNRLLE VHSRWKHRQI

121 EDGVEGGEIY DENENDGNED EHEGGCEVNY NSDEEGDEW

161 YDRESFSKLL VRVPLSDTKL FSELAFLCNI AYVIPKIEGM

201 ELRKYYGLKF VTSSIEKKAE VATIKAKMDQ DSIRVPVATP

241 KSTELEKVEG TETKRLISLS AVYE IAASAA YYVQSRAKGL

281 LSPGFKSPVE DERDSRRSGD EHEMEGENSP RVYNSEVAAY

321 MAASAMTAW RSGEKAKQAT AKDLQSLQSS PSEWSVCDEL

361 STYTRCFVIQ GSDSLASWQA NLLFEPTTFE YTDVLVHRGI

401 YEAAKGIYEQ FLPEIMDHLN RHGDRAKLQF TGHSLGGSLS

441 LLVSLMLLAK KWKP SALRP VITFGSPFVF CGGQKILEEF

481 GLDDNHVHCV MMHRD IVPRA FSCKYPNHVA IVLKRLPGSL

521 RSHRCLLKNK LLYTPLGKLF IVQPSEKSSP PHPLLPLGTA

561 PLDTLSDLTA YGSEGTILRD HDSSNYLKAI NGVLRQHKKT

601 VPSLTTRTVS DTSLLWPLLV SPSPRTWNHH RQMMFSNKEI

641 MTGV

Another PLIPl-related lipase protein from Arachis hypogaea (peanut) with SEQ

ID NO:66 shares about 53-54% sequence identity with the SEQ ID NO:l protein as illustrated below.

Seql 1 MAFNTAMASTSPAAANDV LREHIGLRRSLSGQDLVLKGGGIRRS SSDNHLCCRSGNN

Seq66 1 MAFSAVGMATSPASSATMDIRTTKHNGLRRSSSGIELSTRS I-MQRSYSDTHLCCAV

Seql 58 NNRILAVSVRPGMKTSRSVGVFSFQIS SSIIPSPIKTLLFETDTSQD EQESDEI

Seq66 57 -NP IQATSLQPKQKSNKSMGI SPFQFSGSILPNSLRSFLFDPETSKEMNMGEKDHSSHFE

Seql 112 EIETEPNLDGA-KKANWVERLLEIRRQWKREQKTESGNSDVAEESVDVTCGCEEEEGCIA Seq66 116 ESAVECNEDEKINRTNWIERLMEIKKNWRNRIPKEEMDPDMICDN-NSNDECDCDEGCVV

Seql 171 NY—GSVNGDWGRESFSRLLVKVSWSEAKKLSQLAYLCNLAYTIPEIKGEDLRRNYGLK F Seq66 175 DYVEDGQEGTYDHDSFTKFLSQVSWSDTKLYSKLAFLCNMAYVIPEIKAKDLRRYYSLQF

Seql 229 VTS SLEKKAKAAILREKLEQDPTHVPV ITSPDLESEKQSQRSAS SSASAYKIAASAA

Seq66 235 ITS SLEKKAEVEKLKERLDKDSTRIPINGSVASQDGSEKGKDNKERHQIRLAYDIATSAA

Seql 286 SYIH SCKEYDLSEPIYKS AAAAQAAASTMTAV Seq66 295 SYVQLRAKDLLSLTAKRQQPQSDILDSNGRENSEGFEAEALPGLIHQSCSLCCSINNDAV

Seql 318 VAAGEEEKLEAARELQSLQSSPCEWFVCDDPNTYTRCFVIQGSDSLASWKANLFFEPTKF Seq66 355 VAACEKEKQEAAKDLQSLHSSLCEWFICDDSNTYTRYFVIQGSDSLASWQANLFFEPTKF

Seql 378 EDTDVLVHRGIYEAAKGIYEQFLPEITEHLSRHGDRAKFQFTGHSLGGSLSLI LMLI S Seq66 415 EDTDVLVHRGIYEAAKGIYEQFLPEIKAHLKRHGDRAKLQFTGHSLGGSLSLLVHLMLLS

Seql 438 RGLVSSEA KSWTFGSPFVFCGGEKILAELGLDESHVHCV MHRDIVPRAFSCNYPDHV Seq66 475 RKVVSPSTLRPWTFGSPFVFCGGHKLLDHLGLDESHIHCV MHRDIVPRAFSCNYPNHV

Seql 498 ALVLKRLNGSFRTHPCLNKNKLLYSPMGKVYILQPSESVSPTHPWLPPGNALYILENSNE Seq66 535 ALVLKRLNSTFRSHPCLIKNKLLYSPLGKIFILQPDERTSPPHPLLP SGSAFYALDSARC Seql 558 GYSPTALRAFLNRPHPLETLSQRAAYGSEGSVLRDHDSKNYVKAVNGVLRQHTKLIVRKA Seq66 595 GYTPSVLRTFLNQPHPIETLSDPTAYGSEGTILRDHDSSNYLKWNGVLRQHSKNIVRQM

Seql 618 RIQR-RSVWPVLTS

Seq66 655 RKQRINELWPLLTT

This lipase protein from Arachis hypogaea (peanut) with SEQ ID NO:66 has accession number ADY38373.1 and the SEQ ID NO:66 amino acid sequence is shown below.

1 MAFSAVGMAT SPASSATMDI RTTKHNGLRR SSSGIELSTR

41 SIMQRSYSDT HLCCAVNPIQ ATSLQPKQKS NKSMGISPFQ

81 FSGSILPNSL RSFLFDPETS KEMNMGEKDH SSHFEESAVE

121 CNEDEKINRT NWIERLMEIK KNWRNRIPKE EMDPDMICDN

161 NSNDECDCDE GCWDYVEDG QEGTYDHDSF TKFLSQVSWS

201 DTKLYSKLAF LCNMAYVIPE IKAKDLRRYY SLQFITSSLE

241 KKAEVEKLKE RLDKDSTRIP INGSVASQDG SEKGKDNKER

281 HQIRLAYDIA TSAASYVQLR AKDLLSLTAK RQQPQSDILD

321 SNGRENSEGF EAEALPGLIH QSCSLCCSIN NDAWAACEK

361 EKQEAAKDLQ SLHSSLCEWF ICDDSNTYTR YFVIQGSDSL

401 ASWQANLFFE PTKFEDTDVL VHRGIYEAAK GIYEQFLPEI

441 KAHLKRHGDR AKLQFTGHSL GGSLSLLVHL MLLSRKVVSP

481 STLRPVVTFG SPFVFCGGHK LLDHLGLDES HIHCVMMHRD

521 IVPRAFSCNY PNHVALVLKR LNSTFRSHPC LIKNKLLYSP

561 LGKIFI LQPD ERTSPPHPLL PSGSAFYALD SARCGYTPSV

601 LRTFLNQPHP IETLSDPTAY GSEGTILRDH DSSNYLKVVN

641 GVLRQHSKNI VRQMRKQRIN ELWPLLTTPS PHSWNHEQNL

681 ERCNLMTKEI VTGV

Another PLIPl-related lipase protein from Helianthus annuus (sunflower) with SEQ ID NO:67 shares about 55-56% sequence identity with the SEQ ID NO:l protein as illustrated below. Seql 25 LRRSLSGQDLVLKGGGIRRSS SDNHLCCRSGNNNNRILAVSVRPGMKTSRSVGVFSFQI S Seq67 19 LNRSISSQNL-RQHARIRRAHSDNNLCYSA NHVQASMNQPKLKNSRSVGIFNLNLS

Seql 85 SSIIPSPIKTLLFETDTSQ DEQESDEIE—IETEPNLDGAKKANWVERLLEIRR

Seq67 74 SSFIPNSLKTLLFDPDTSTGMDTDTDTERGDEVADVSDVEMTKEEKNRANWIERLVEIRS

Seql 137 QWKREQKTESGNSDVAEESVDVTCGCEEEEGCIANYGSVNGDW—GRESFSRLLVKVSW S Seq67 134 RWVQKQNNELDGENGEEKGCDED GNGEGCEVDYSDDEDNVIVNQETFSGMLKQVSWS

Seql 195 EAKKLSQLAYLCNLAYTIPEIKGEDLRRNYGLKFVTSSLEKKAKAAILREKLEQDPTHVP Seq67 191 DTKQFSQLAFLCNMAYVIPEIEEDDLRRYYDLTFVTSSLEKKVSAQEIPRELNSVPVTAS

Seql 255 VITS-PDLESEKQSQRSASSSASAYKIAASAASYIH SCKEYDLSEP IYKSA

Seq67 251 TNNQRPEKHTTRTSAYEIAASAATY-VQSQAGGLINLESDPLAEEDDDITDPS SRVYNSE

Seql 305 AAAQAAASTMTAWAAGEEEKLEAARELQSLQS SPCEWFVCDDPNTYTRCFVIQGSDSLA Seq67 310 MAAYMAASTMTAWAAPEKEKQEAARDLQSLHSSPCEWFICDDSSIYTRCFVIQGSDSVA

Seql 365 SWKANLFFEPTKFEDTDVLVHRGIYEAAKGIYEQFLPEITEHLSRHGDRAKFQFTGHSLG Seq67 370 SWQANLFFEPTKFEETGVPVHRGIYEAAKGIYEQFMPHIQEHLNRYGERAKLQFTGHSLG

Seql 425 GSLSLIVNLMLISRGLVSSEAMKSWTFGSPFVFCGGEKILAELGLDESHVHCVMMHRDI Seq67 430 GSLSLLVNLMLLTRKWKPSALRPWTFGSPFVFCNGQKILDQLGLDENHVHCA/MMHRDI

Seql 485 VPRAFSCNYPDHVALVLKRLNGSFRTHPCLNKNKLLYSPMGKVYILQPSESVSPTHPWLP Seq67 490 VPRAFSCNYPKHVAQLLKRLCGTFRSHPCLNRNSILYTPLGKMFILQPDEKSSPHHPLLP

Seql 545 PGNALYILENSNEGYSPTALRAFLNRPHPLETLSQRAAYGSEGSVLRDHDSKNYVKAVNG Seq67 550 AGSALYVMENTNRGLTKTAIRAFLNSPHPIETLQHPTAYGSDGTILRDHDSSNYLKAVNG

Seql 605 VLRQHTKLIVRKARIQRRSVWPVLTS

Seq67 610 IIRQHTKTFIRKPKQQRNLLWPLLTS

This lipase protein from Helianthus annuus (sunflower) with SEQ ID NO:67 has accession number XP_022035660.1 and the SEQ ID NO:67 amino acid sequence is shown below.

1 MMVCSSISVS SQPTTPNILN RSISSQNLRQ HARIRRAHSD 41 NNLCYSANHV QASMNQPKLK NSRSVGIFNL NLSSSFIPNS

81 LKTLLFDPDT STGMDTDTDT ERGDEVADVS DVEMTKEEKN

121 RANWIERLVE IRSRWVQKQN NELDGENGEE KGCDEDGNGE

161 GCEVDYSDDE DNVIVNQETF SGMLKQVSWS DTKQFSQLAF

201 LCNMAYVIPE IEEDDLRRYY DLTFVTSSLE KKVSAQEIPR

241 ELNSVPVTAS TNNQRPEKHT TRTSAYEIAA SAATYVQSQA

281 GGLINLESDP LAEEDDDITD PSSRVYNSEM AAYMAASTMT

321 AWAAPEKEK QEAARDLQSL HSSPCEWFIC DDSSIYTRCF 361 VIQGSDSVAS WQANLFFEPT KFEETGVPVH RGIYEAAKGI

401 YEQFMPHIQE HLNRYGERAK LQFTGHSLGG SLSLLVNLML

441 LTRKWKPSA LRPWTFGSP FVFCNGQKIL DQLGLDENHV

481 HCVMMHRDIV PRAFSCNYPK HVAQLLKRLC GTFRSHPCLN

521 RNSILYTPLG KMFILQPDEK SSPHHPLLPA GSALYVMENT

561 NRGLTKTAIR AFLNSPHPIE TLQHPTAYGS DGTILRDHDS

601 SNYLKAVNGI IRQHTKTFIR KPKQQRNLLW PLLTSQSPHY

641 WSQETKVKEK QLTVSDQRRL VTTEVA

Another PLIPl-related lipase protein from Helianthus annuus (sunflower) with

SEQ ID NO:68 shares about 55-56% sequence identity with the SEQ ID NO: l protein as illustrated below.

Seql 25 LRRSLSGQDLVLKGGGIRRSS SDNHLCCRSGNNNNRILAVSVRPGMKTSRSVGVFSFQI S Seq68 53 LNRSISSQNL-RQHARIRRAHSDNNLCYSA NHVQASMNQPKLKNSRSVGIFNLNLS

Seql 85 SSIIPSPIKTLLFETDTSQ DEQESDEIE—IETEPNLDGAKKANWVERLLEIRR

Seq68 108 SSFIPNSLKTLLFDPDTSTGMDTDTDTERGDEVADVSDVEMTKEEKNRANWIERLVEIRS

Seql 137 QWKREQKTESGNSDVAEESVDVTCGCEEEEGCIANYGSVNGDW—GRESFSRLLVKVSW S Seq68 168 RWVQKQNNELDGENGEEKGCDED GNGEGCEVDYSDDEDNVIVNQETFSGMLKQVSWS

Seql 195 EAKKLSQLAYLCNLAYTIPEIKGEDLRRNYGLKFVTSSLEKKAKAAILREKLEQDPTHVP Seq68 225 DTKQFSQLAFLCNMAYVIPEIEEDDLRRYYDLTFVTSSLEKKVSAQEIPRELNSVPVTAS

Seql 255 VITS-PDLESEKQSQRSASSSASAYKIAASAASYIH SCKEYDLSEP IYKSA Seq68 285 TNNQRPEKHTTRTSAYEIAASAATY-VQSQAGGLINLESDPLAEEDDDITDPS SRVYNSE

Seql 305 AAAQAAASTMTAWAAGEEEKLEAARELQSLQS SPCEWFVCDDPNTYTRCFVIQGSDSLA Seq68 344 MAAYMAASTMTAWAAPEKEKQEAARDLQSLHSSPCEWFICDDSSIYTRCFVIQGSDSVA

Seql 365 SWKANLFFEPTKFEDTDVLVHRGIYEAAKGIYEQFLPEITEHLSRHGDRAKFQFTGHSLG Seq68 404 SWQANLFFEPTKFEETGVPVHRGIYEAAKGIYEQFMPHIQEHLNRYGERAKLQFTGHSLG

Seql 425 GSLSLIVNLMLISRGLVSSEAMKSWTFGSPFVFCGGEKILAELGLDESHVHCVMMHRDI Seq68 464 GSLSLLVNLMLLTRKWKPSALRPWTFGSPFVFCNGQKILDQLGLDENHVHCA/MMHRDI

Seql 485 VPRAFSCNYPDHVALVLKRLNGSFRTHPCLNKNKLLYSPMGKVYILQPSESVSPTHPWLP Seq68 524 VPRAFSCNYPKHVAQLLKRLCGTFRSHPCLNRNSILYTPLGKMFILQPDEKSSPHHPLLP

Seql 545 PGNALYILENSNEGYSPTALRAFLNRPHPLETLSQRAAYGSEGSVLRDHDSKNYVKAVNG Seq68 584 AGSALYVMENTNRGLTKTAIRAFLNSPHPIETLQHPTAYGSDGTILRDHDSSNYLKAVNG

Seql 605 VLRQHTKLIVRKARIQRRSVWPVLTS

Seq68 644 IIRQHTKTFIRKPKQQRNLLWPLLTS This lipase protein from Helianthus annuus (sunflower) with SEQ ID NO:68 has accession number OTG29254.1 and the SEQ ID NO:68 amino acid sequence is shown below.

1 MYIICSMRSP ISYGTETAGV DSRSVFFSAL LLLVMMVCSS 41 ISVSSQPTTP NILNRSISSQ NLRQHARIRR AHSDNNLCYS

81 ANHVQASMNQ PKLKNSRSVG IFNLNLSSSF IPNSLKTLLF

121 DPDTSTGMDT DTDTERGDEV ADVSDVEMTK EEKNRANWIE

161 RLVEIRSRWV QKQNNELDGE NGEEKGCDED GNGEGCEVDY

201 SDDEDNVIVN QETFSGMLKQ VSWSDTKQFS QLAFLCNMAY

241 VIPEIEEDDL RRYYDLTFVT SSLEKKVSAQ EIPRELNSVP

281 VTASTNNQRP EKHTTRTSAY EIAASAATYV QSQAGGLINL

321 ESDPLAEEDD DITDPSSRVY NSEMAAYMAA STMTAWAAP

361 EKEKQEAARD LQSLHSSPCE WFICDDSSIY TRCFVIQGSD

401 SVASWQANLF FEPTKFEETG VPVHRGIYEA AKGIYEQFMP

441 HIQEHLNRYG ERAKLQFTGH SLGGSLSLLV NLMLLTRKW

481 KPSALRPWT FGSPFVFCNG QKILDQLGLD ENHVHCVMMH

521 RDIVPRAFSC NYPKHVAQLL KRLCGTFRSH PCLNRNSILY

561 TPLGKMFILQ PDEKSSPHHP LLPAGSALYV MENTNRGLTK

601 TAIRAFLNSP HPIETLQHPT AYGSDGTILR DHDSSNYLKA

641 VNGI IRQHTK TFIRKPKQQR NLLWPLLTSQ SPHYWSQETK

681 VKEKQLTVSD QRRLVTTEVA

Another PLIP1 -related lipase protein from Olea europaea (olive) with SEQ ID

NO:69 shares about 57-58% sequence identity with the SEQ ID NO:l protein as illustrated below.

Seql 25 LRRSLSGQDLVLKGGGIRRSS SDNHLCCRSGNNNNRILAVSVRPGMKTSRS-VGVFSFQI Seq69 26 LRKSWSSKNLTRRAG-IRRAFSDNNLFCRV SRIQASTVEPKLKSSSSSAGFFNIQL

Seql 84 SSS IIPSPIKTLLFETDTSQDEQESDE-IEIETEPNLDGAK KANWVERLLEIRRQWK

Seq69 81 SSTMIPDTLKPFLFDLELSKEITIEDKLVESEREDEIDVEKVKKRANWIERLMEIRDSWK

Seql 140 REQKTESGNSDVAE—ESVDVTCGCEEEEGCIANYGS GDWGRESFSRLLVKVSWSEAK Seq69 141 EKQQREDVN-DVGENNEACDEDGGCEVDYDDDAEGKEMNIDG—KIFSSLLGKVSWSDT K

Seql 198 KLSQLAYLCNLAYTIPEIKGEDLRRNYGLKFVTSSLEKKAKAAILREKLEQDPTHVPVIT Seq69 198 YFSKLAFLCNMAYVIPDIKTRDLSRYYGLELVTSSLEKKAEAEVTKDKPEQDSTTVHVAT

Seql 258 SPDLESEK QSQRSASS SASAYKIAASAASYIHSCKEYDLSEP IYKSA

Seq69 258 SASVDSISTKTMDREQKCRLRPSDAYEIAASAAVYVQSRTKDDLQEEEKKSSSHRVSKSE

Seql 305 AAAQAAASTMTAVVAAGEEEKLEAARELQSLQS SPCEWFVCDDPNTYTRCFVIQGSDSLA Seq69 318 MAASVAASTVTAVIAADEKEKQEAAKDLQSLHS SPCEWFVCDDSSIYTRCFVIQGSDSVE

Seql 365 SWKANLFFEPTKFEDTDVLVHRGIYEAAKGIYEQFLPEITEHLSRHGDRAKFQFTGHSLG Seq69 378 SWQANLFFEPTEFEGTDVLVHRGIYEAAKGIYEQFMPEIMQHLNRFGDRAKLQFTGHSLG Seql 425 GSLSLIVNLMLISRGLVSSEAMKSWTFGSPFVFCGGEKILAELGLDESHVHCVMMHRDI Seq69 438 GSLALLVNMMLLTRKVIKPSALLPWTFGSPFVFCGGHRILNELGLDENHVHCA/MMHRDI

Seql 485 VPRAFSCNYPDHVALVLKRLNGSFRTHPCLNKNKLLYSPMGKVYILQPSESVSPTHPWLP Seq69 498 VPRAFSCNYPNYVAQVLKRLSRTFRSHPCLNKSKLLYSPMGKIFILQPDEKSSPPHPLLP Seql 545 PGNALYILENSNEGYSPTALRAFLNRPHPLETLSQRAAYGSEGSVLRDHDSKNYVKAVNG Seq69 558 SGSALYALDSTNFSLTKTAFRAFLNSPHPLETLSYPTAYGSEGTIIRDHDSSNYLKAMNE

Seql 605 VLRQHTKLIVRKARIQRRSVWPVLTS

Seq69 618 VIRQHTRQVNKKVSKQTKQLWPLLTS

This lipase protein from Olea europaea (olive) with SEQ ID NO:69 has accession number XP_022857295.1 and the SEQ ID NO:69 amino acid sequence is shown below.

1 MACSLPSITS SSSFTIENSQ KNEGRLRKSW SSKNLTRRAG 41 IRRAFSDNNL FCRVSRIQAS TVEPKLKSSS SSAGFFNIQL

81 SSTMIPDTLK PFLFDLELSK EITIEDKLVE SEREDEIDVE

121 KVKKRANWIE RLMEIRDSWK EKQQREDVND VGENNEACDE

161 DGGCEVDYDD DAEGKEMNID GKIFSSLLGK VSWSDTKYFS

201 KLAFLCNMAY VIPDIKTRDL SRYYGLELVT SSLEKKAEAE

241 VTKDKPEQDS TTVHVATSAS VDS I STKTMD REQKCRLRPS

281 DAYEIAASAA VYVQSRTKDD LQEEEKKSSS HRVSKSEMAA

321 SVAASTVTAV IAADEKEKQE AAKDLQSLHS SPCEWFVCDD

361 SSIYTRCFVI QGSDSVESWQ ANLFFEPTEF EGTDVLVHRG

401 IYEAAKGIYE QFMPEIMQHL NRFGDRAKLQ FTGHSLGGSL

441 ALLVNMMLLT RKVIKPSALL PWTFGSPFV FCGGHRILNE

481 LGLDENHVHC VMMHRDIVPR AFSCNYPNYV AQVLKRLSRT

521 FRSHPCLNKS KLLYSPMGKI FILQPDEKSS PPHPLLPSGS

561 ALYALDSTNF SLTKTAFRAF LNSPHPLETL SYPTAYGSEG

601 T I IRDHDSSN YLKAMNEVIR QHTRQVNKKV SKQTKQLWPL

641 LTSQSPHMWS NKR I GDTMV TKEILTGV

Another PLIP1 -related lipase protein from Olea europaea (olive) with SEQ ID NO:70 shares about 53-54% sequence identity with the SEQ ID NO:l protein as illustrated below.

Seql 7 MASTSPAAANDVLREHIGLRRSLSGQDLVLKGGGIRRSS SDNHLCCRSGNNNNRILAVSV Seq70 1 MAS SLPSITSSPVTTEEGRLRKSWSSKGLTERARLRRTYSDNNLSCRV SRIQASKV Seql 67 RPGMKTSRS-VGVFSFQISSS IIPSPIKTLLFETDTSQD EQESDEIEIETEPNLDGA

Seq70 57 EPKLKSSSSSASFFNIQLPSTMFPDSLKSFFSDLESSKEINIEEILVESEQEDEIDVEKV

Seql 123 KK-ANWVERLLEIRRQWKREQKTESGN-SDVAEESVDVTCGCEEEEGCIANYGSVNGDWG Seq70 117 KKRANWIERLMEIRNNWKEKQRKED VAGENDEHCDEDGGCEVDYDDDDDAKGKEMNID Seql 181 RESFSRLLVKVSWSEAKKLSQLAYLCNLAYTIPEIKGEDLRRNYGLKFVTSSLEKKAKAA Seq70 177 SKRFTPFLGQVSWSDTKHFSKLAFLCNMAYIIPNIKTRDLRRYYGLELVTSSLQKKVEAK

5 Seql 241 ILREKLEQDPTHVPVITSPDLES EKQSQRSASSSASAYKIAASAASYIHSC

Seq70 237 VMKVKPEQNSTSVYVATPAVLDSISAKTEDFEQKCLLRS SAAYEIAASAAFYVQSQTKDV

Seql 292 KEYDLSEP-1YKSAAAAQAAASTMTAWAAGEEEKLEAARELQSLQSSPCEWF0 Seq70 297 KDDHQEEEEEESSSPRVYKSEMAASVAASTMTAVIAADENQKQEAARDLQSIHSSPCEWF

Seql 344 VCDDPNTYTRCFVIQGSDSLASWKANLFFEPTKFEDTDVLVHRGIYEAAKGIYEQFLPEI Seq70 357 VCDDSSIYTRCFVIQGSDSVESWQANLFFEPTKFEGTDVLVHRGIYEAAKGIYEQFMPEI ^

Seql 404 TEHLSRHGDRAKFQFTGHSLGGSLSLIVNLMLI SRGLVS SEAMKSWTFGSPFVFCGGEK Seq70 417 MQHLNRFGNRAKLQFTGHSLGGSLALL LMLLTRKWKPSALLPWTFGSPFVFCGGHK0

Seql 464 ILAELGLDESHVHCV MHRDIVPRAFSCNYPDHVALVLKRLNGSFRTHPCLNKNKLLYSP Seq70 477 ILDELGLDENHVHCV MHRDIVPRAFSCNYPNYVAQVLKRLSRTFRAHPCLNKNKLLYSP 5 Seql 524 MGKVYILQP SESVSPTHPWLPPGNALYILENSNEGYSPTALRAFLNRPHPLETLSQRAAY Seq70 537 MGRIFILQPDEKLSPPHPLLP SGSALYSLDSIKCSLAKSAFRAFLNSPHPLETLSNPTAY

Seql 584 GSEGSVLRDHDSKNYVKAVNGVLRQHTKLIVRKARIQRRSVWPVLTS

0 Seq70 597 GSEGTIIRDHDSSNYLKVMNEVIRQHTWQVDRKAGKQTNQLWPLLTS

This lipase protein from Olea europaea (olive) with SEQ ID NO:70 has accession number XP_022897656.1 and the SEQ ID NO:70 amino acid sequence is shown below.

5 1 MASSLPSITS SPVTTEEGRL RKSWSSKGLT ERARLRRTYS

41 DNNLSCRVSR IQASKVEPKL KSSSSSASFF NIQLPSTMFP

81 DSLKSFFSDL ESSKE INIEE ILVESEQEDE IDVEKVKKRA

121 NWIERLMEIR NNWKEKQRKE DVNVAGENDE HCDEDGGCEV

161 DYDDDDDAKG KEMNIDSKRF TPFLGQVSWS DTKHFSKLAF

0 201 LCNMAYIIPN IKTRDLRRYY GLELVTSSLQ KKVEAKVMKV

241 KPEQNSTSVY VATPAVLDSI SAKTEDFEQK CLLRSSAAYE

281 IAASAAFYVQ SQTKDVKDDH QEEEEEESSS PRVYKSEMAA

321 SVAASTMTAV IAADENQKQE AARDLQSIHS SPCEWFVCDD

361 SSIYTRCFVI QGSDSVESWQ ANLFFEPTKF EGTDVLVHRG

5 401 IYEAAKGIYE QFMPEIMQHL NRFGNRAKLQ FTGHSLGGSL

441 ALLVNLMLLT RKWKPSALL PWTFGSPFV FCGGHKILDE

481 LGLDENHVHC VMMHRDIVPR AFSCNYPNYV AQVLKRLSRT

521 FRAHPCLNKN KLLYSPMGRI FILQPDEKLS PPHPLLPSGS

561 ALYSLDSIKC SLAKSAFRAF LNSPHPLETL SNPTAYGSEG

0 601 T I IRDHDSSN YLKVMNEVIR QHTWQVDRKA GKQTNQLWPL

641 LTSQSPHMWS AKSNI GGMTA TEEILTGV Another PLIP1 -related lipase protein from Elaeis guineensis (oil palm) with SEQ

ID NO:71 shares about 52-54% sequence identity with the SEQ ID NO:l protein as illustrated below.

Seql 8 ASTSPAAANDVLREHIGLRRSLSGQDLVLKGGGIRRSSSDNHLCCRSGNNNNRILAVSVR Seq71 14 SAASAVAKDHLHGRQDGIRRSLSGTDLV GVRRSRSEPLLRC-SLSIPRPATAASAP

Seql 68 PGMKTSRSVGVFSFQISSSIIPSPIKTLLFETDTSQDEQE—SDEIEIETEPNLDGAKK A Seq71 69 AKLKTSRSVGLFSF IPNSIRSFLFNSEEAHGGMRFVDPEES SEEEVGSETEKRS

Seql 126 NWVERLLEIRRQWK—REQKTESGNSDVAEESVDVTCGCEEEEGCIANYGSVNGDWGRE S Seq71 123 NWVERIWELRSRWRDRKPKADEEDASDGGGEESDEFCRVSYDSGEEAEREEERSEWDRES

Seql 184 FSRLLVKVSWSEAKKLSQLAYLCNLAYTIPEIKGEDLRRNYGLKFVTSSLEKKAKAAILR Seq71 183 FERLLAPVSWTDAKLFSQLAFLCNMAYVIPEIKAEDLRKYYDLRYVTSSLEKKSEAAI-K

Seql 244 EKLEQDPTHVPV-ITSPDLESEKQSQRSASSSAS-AYKIAASAASYIHSCKEYDLS E

Seq71 242 ARLESDSTRPPPGPTGPCPRSDSETQRRPLIRP SVAYEIAASAASYIHSRARGLLSLGGE

Seql 299 P IYKSAAAAQAAASTM

Seq71 302 PGSTNGMERLGERPEEAVSPQETLGQETTGEGLEEAQSLKGSPGRMYKSNVAAFVARSTM

Seql 315 TAVVAAGEEEKLEAARELQSLQSSPCEWFVCDDPNTYTRCFVIQGSDSLASWKANLFFEP Seq71 362 TAVVAAEDEARQEAAKDLRSLHSSPCEWFVCDDPSTGTRCFVIQGSDSLASWQANLFFEP

Seql 375 TKFEDTDVLVHRGIYEAAKGIYEQFLPEITEHLSRHGDRAKFQFTGHSLGGSLSLIVNLM Seq71 422 TKFEETEVLVHRGIYEAAKGIYEQFMPEIEVHLQRWGDMAKLRFTGHSLGGSLSLLVHLM

Seql 435 LISRGLVSSEAMKSVVTFGSPFVFCGGEKILAELGLDESHVHCVMMHRDIVPRAFSCNYP Seq71 482 LLSRGAVKP STLLPVVTFGSP SVFCRGKRVLEGLGLDEGQVHSVMMHRDIVPRAFSCGYP

Seql 495 DHVALVLKRLNGSFRTHPCLNKNKLLYSPMGKVYILQPSESVSPTHPWLPPGNALYILEN Seq71 542 NHVAQVLKRLNKAFRSHPCLNNEKVLYSPLGQTYILQPDDKSSPPHPLLPPGAALYILDG

Seql 555 SNEGYSPTALRAFLNRPHPLETLSQRAAYGSEGSVLRDHDSKNYVKAVNGVL

Seq71 602 KKAAERGETKKATVAGALRAFLNSPHPLETLSDPAAYGSDGTILRDHDSSNYLKAMNGLV

Seql 607 RQHTKLIVRKARIQR-RSVWPVLTS

Seq71 662 REHTKSWRRTRRQRFYQLWPLLAT

This lipase protein from Elaeis guineensis (oil palm) with SEQ ID NO:71 has accession number XP_010913778.1 and the SEQ ID NO:71 amino acid sequence is shown below.

1 MPCAAAAIIH GGSSAASAVA KDHLHGRQDG IRRSLSGTDL 41 VGVRRSRSEP LLRCSLSIPR PATAASAPAK LKTSRSVGLF 81 SFIPNSIRSF LFNSEEAHGG MRFVDPEESS EEEVGSETEK 121 RSNWVERIWE LRSRWRDRKP KADEEDASDG GGEESDEFCR

161 VSYDSGEEAE REEERSEWDR ESFERLLAPV SWTDAKLFSQ

201 LAFLCNMAYV IPEIKAEDLR KYYDLRYVTS SLEKKSEAAI

241 KARLESDSTR PPPGPTGPCP RSDSETQRRP LIRPSVAYEI

281 AASAASYIHS RARGLLSLGG EPGSTNGMER LGERPEEAVS

321 PQETLGQETT GEGLEEAQSL KGSPGRMYKS NVAAFVARST

361 MTAWAAEDE ARQEAAKDLR SLHSSPCEWF VCDDPSTGTR

401 CFVIQGSDSL ASWQANLFFE PTKFEETEVL VHRGIYEAAK

441 GIYEQFMPEI EVHLQRWGDM AKLRFTGHSL GGSLSLLVHL

481 MLLSRGAVKP STLLPWTFG SPSVFCRGKR VLEGLGLDEG

521 QVHSVMMHRD IVPRAFSCGY PNHVAQVLKR LNKAFRSHPC

561 LNNEKVLYSP LGQTYILQPD DKSSPPHPLL PPGAALYILD

601 GKKAAERGET KKATVAGALR AFLNSPHPLE TLSDPAAYGS

641 DGTILRDHDS SNYLKAMNGL VREHTKSVVR RTRRQRFYQL

681 WPLLATPTNR LTGGHHSRME KSEPVNQEVL TTSV

As illustrated in FIG. 8, the PLIPl enzyme is evolutionarily related to PLIP2 and PLIP3 lipases. In some cases, the lipase used in the expression cassettes and methods described herein can be a PLIP2 or PLIP3 lipase. However, some preliminary evidence indicates that the activities of the PLIP2 and PLIP3 lipases are different from the PLIPl lipase. Hence, in some cases the lipase used in the expression cassettes and methods described herein is not a PLIP2 or PLIP3 lipase. However, in some cases, expression of a combination of PLIPl , PLIP2, and/or PLIP3 lipases may be useful and can be employed when making the expression cassettes and using the methods described herein.

A PLIP2 lipase can in some cases be encoded in expression cassettes and utilized in the methods described herein. However, in some cases the lipase is not a PLIP2 lipase. One example of an Arabidopsis thaliana PLIP2 protein sequence is shown below as SEQ

ID NO: 12.

1 MDSLCLNSGL HGVIPAITAV GNGGCGGWE VRATASAPSQ

41 KRGPFGFSFK YPLTPFWSRG GGGGIASRRR SGLCLDDAVL

81 VDSGDSRKPI AEETAVEMDT ERRNGSWVLK ILDVQSTWKH

121 EEEEDDDEVE DEDGDEDEEV ELDDAWSED DGGCDVCSVL

161 EDDGNEANKF QLDRESFSKL LRRVTLPESK LYAQLSYLGN

201 LAYSISKIKP ANLSKYYGLR FVTSSAEKTE SALKAENGEV

241 SGETKPIVEA EEEVEEEEKN KSRKI SASAA YEIVASAASY

281 LHSRTNNILP FNSSSKAENS DKHDVNLTNA ESSSDVAYSV

321 TSWAAEEDV KQAVADDLKS TISSPCDWFI CDDDQSHTRF

361 WIQGSESLA SWQANLLFEP IEFEGLGAIV HRGIYEAAKG

401 MYEQMLPEVK AHIKTHGTSA KFRFTGHSLG GSLSLLLNLM

441 LLVRGEVPAS SLLPVITYGA PFVLCGGDRL LKKLGLPKSH

481 VQAIVMHRDI VPRAFSCNYP YHVAELLKAV NGNFRSHPCL

521 NKQSMLYSPM GELLILQPDE TFSPGHELLP SGNGLYLLTS

561 DFESPDIEDS DEERLRAAQT VFLNTPHPLD ILSDRSAYGS

601 SGTIQRDHDM NSYLKAVRSV IRKEVNQIRR AKREHRRSLW 641 WPILVARESG SSGIAVSNGQ INGQDFSGMM QTGRKSLQRF

681 SRLVASQHMP LIWMLFPVK LLFLGAFNVF SFR

A nucleic acid encoding the SEQ ID NO: 12 Arabidopsis thaliana PLIP2 protein sequence is shown below as SEQ ID NO: 13.

1 ATGGACAGTT TGTGTTTGAA TAGCGGTTTA CACGGTGTAA

41 TTCCAGCGAT CACTGCGGTT GGAAACGGCG GTTGCGGTGG

81 AGTTGTTGAA GTCCGAGCAA CTGCGTCGGC ACCATCGCAA

121 AAAAGAGGAC CTTTCGGGTT CTCATTTAAG TACCCACTGA

161 CGCCGTTTTG GTCTCGCGGC GGTGGAGGAG GAATTGCGTC

201 GAGGAGACGA AGTGGATTGT GTTTAGACGA CGCCGTTTTG

241 GTTGATTCCG GCGATTCGAG AAAGCCGATC GCGGAGGAGA

281 CGGCGGTGGA AATGGATACG GAGAGGCGAA ATGGGAGCTG

321 GGTTTTGAAG ATCTTGGATG TACAATCTAC GTGGAAACAC

361 GAAGAAGAAG AAGATGATGA TGAAGTAGAA GATGAAGACG

401 GAGACGAAGA CGAGGAGGTT GAATTAGACG ACGCCGTAGT

441 ATCTGAAGAT GATGGTGGAT GCGATGTATG TTCAGTTTTG

481 GAAGATGATG GCAACGAAGC AAACAAATTT CAACTCGATA

521 GAGAATCGTT CTCCAAATTG CTAAGGAGGG TTACGTTACC

561 CGAATCAAAA CTCTATGCCC AACTATCGTA TTTGGGAAAC

601 TTGGCTTATT CAATTTCAAA AATCAAGCCT GCGAATCTGT

641 CGAAATATTA CGGCCTGAGA TTTGTAACTT CATCAGCTGA

681 GAAAACAGAA TCGGCGTTAA AAGCTGAGAA TGGTGAAGTT

721 TCAGGTGAGA CTAAGCCAAT TGTGGAAGCA GAAGAAGAAG

761 TTGAAGAAGA AGAGAAGAAC AAAAGTCGCA AGATTAGTGC

801 TTCTGCTGCA TATGAGATTG TTGCATCAGC TGCTTCTTAC

841 CTTCACTCTC GTACCAACAA CATACTTCCT TTCAACTCTT

881 CATCGAAAGC CGAGAATTCG GACAAACATG ATGTAAATTT

921 GACTAATGCG GAGTCATCAT CAGATGTTGC TTATTCTGTT

961 ACTTCTGTTG TTGCTGCTGA GGAAGATGTG AAGCAAGCAG

1001 TTGCAGACGA TTTGAAATCC ACGATTTCGT CTCCCTGCGA

1041 TTGGTTTATA TGTGATGATG ATCAGAGTCA CACTAGATTC

1081 GTTGTGATTC AGGGATCTGA ATCTCTAGCT TCTTGGCAAG

1121 CAAATTTACT CTTTGAGCCT ATTGAATTTG AGGGCCTTGG

1161 TGCGATCGTA CACAGAGGAA TATACGAAGC TGCAAAAGGA

1201 ATGTATGAAC AAATGCTACC TGAAGTTAAA GCCCATATTA

1241 AAACCCATGG GACCAGCGCT AAATTCCGTT TCACCGGTCA

1281 TTCATTAGGT GGAAGCTTAT CGCTATTACT AAACCTCATG

1321 TTACTCGTTC GAGGCGAAGT ACCTGCGTCT TCTTTACTTC

1361 CGGTTATAAC ATATGGTGCA CCATTTGTGC TATGTGGAGG

1401 TGACCGTCTT CTTAAGAAAC TCGGATTGCC TAAAAGCCAT

1441 GTTCAAGCTA TTGTTATGCA CCGTGACATT GTTCCGAGAG

1481 CTTTTTCTTG TAACTATCCG TACCATGTTG CTGAGCTTCT

1521 CAAAGCTGTT AATGGAAACT TCCGTAGCCA TCCTTGTCTT

1561 AACAAACAGA GTATGTTGTA TTCTCCGATG GGCGAGCTTC

1601 TGATTCTTCA ACCAGATGAG ACATTCTCCC CCGGGCATGA

1641 ACTTCTTCCT TCCGGAAACG GTTTATACCT TCTAACTAGT

1681 GATTTTGAAT CGCCGGATAT TGAAGATTCG GATGAGGAGC

1721 GGTTAAGAGC CGCGCAGACG GTTTTCTTGA ACACCCCGCA 1761 TCCTCTCGAC ATTCTCAGCG ACAGATCGGC TTATGGGTCC

1801 AGCGGAACAA TCCAAAGAGA CCATGATATG AACTCGTATC

1841 TGAAAGCGGT TAGGAGTGTA ATAAGAAAGG AAGTGAATCA

1881 GATAAGGAGA GCAAAAAGGG AGCATCGCCG GAGTCTTTGG

1921 TGGCCAATTC TGGTGGCTAG AGAAAGTGGA AGCTCAGGGA

1961 TTGCGGTCAG TAACGGCCAA ATCAACGGTC AGGATTTCTC

2001 CGGGATGATG CAGACAGGAA GAAAGTCGTT GCAGAGGTTT

2041 AGCCGCCTTG TGGCGTCTCA ACATATGCCG TTGATCGTTG

2081 TTATGTTGTT TCCGGTTAAG TTGTTGTTCC TTGGAGCTTT

2121 CAACGTCTTT AGTTTCCGTT GA

Arabidopsis thaliana has proteins related to the SEQ ID NO:12 PLIP2 protein, for example, the Arabidopsis thaliana PLIP2 -related protein with SEQ ID NO: 14 has 99% sequence identity to SEQ ID NO: 12 as illustrated below.

Seql2 1 MDSLCLNSGLHGVIPAITAVGNGGCGGWEVRATASAPSQKRGPFGFSFKYPLTPFWSRG

Seql4 1 MDSLCLNSGLHGVIPAITAVGNGGCGGWEVRATASAPSQKRGPFGFSFKYPLTPFWSRG ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★

Seql2 61 GGGGIASRRRSGLCLDDAVLVDSGDSRKPIAEETAVEMDTERRNGSWVLKILDVQSTWKH Seql4 61 GGGGIASRRRSGLCLDDAVLVDSGDSRKPIAEETAVEMDTERRNGSWVLKILDVQSTWKH ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★

Seql2 121 EEEEDDDEVEDEDGDEDEEVELDDAWSEDDGGCDVCSVLEDDGNEANKFQLDRESFSKL

Seql4 121 EEEEDDDEVEDEDGDEDEEVELDDAWSEDDGGCDVCSVLEDDGNEANKFQLDRESFSKL ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★

Seql2 181 LRRVTLPESKLYAQLSYLGNLAYSISKIKPANLSKYYGLRFVTSSAEKTESALKAENGEV Seql4 181 LRRVTLPESKLYAQLSYLGNLAYSISKIKPANLSKYYGLRFVTSSAEKTESALKAENGEV ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★

Seql2 241 SGETKPIVEAEEEVEEEEKNKSRKISASAAYEIVASAASYLHSRTNNILPFNS SSKAENS

Seql4 241 SGETKPIVEAEEEVEEEEKNKSRKISASAAYEIVASAASYLHSRTNNILPFNS SSKAENS ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★

Seql2 301 DKHDVNLTNAESSSDVAYSVTSWAAEEDVKQAVADDLKSTISSPCDWFICDDDQSHTRF

Seql4 301 DKHDVNLTNAESSSDVAYSVTSWAAEEDVKQAVADDLKSTISSPCDWFICDDDQSHTRF ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★

Seql2 361 WIQGSESLASWQANLLFEPIEFEGLGAIVHRGIYEAAKGMYEQMLPEVKAHIKTHGTSA Seql4 361 WIQGSESLASWQANLLFEPIEFEGLGAIVHRGIYEAAKGMYEQMLPEVKAHIKTHGTSA ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★

Seql2 421 KFRFTGHSLGGSLSLLLNLMLLVRGEVPASSLLPVITYGAPFVLCGGDRLLKKLGLPKSH

Seql4 421 KFRFTGHSLGGSLSLLLNLMLLVRGEVPASSLLPVITYGAPFVLCGGDRLLKKLGLPKSH ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★

Seql2 481 VQAIVMHRDIVPRAFSCNYPYHVAELLKAVNGNFRSHPCLNKQSMLYSPMGELLILQPDE

Seql4 481 VQAIVMHRDIVPRAFSCNYPYHVAELLKAVNGNFRSHPCLNKQSMLYSPMGELLILQPDE ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★

Seql2 541 TFSPGHELLPSGNGLYLLTSDFESPDIEDSDEERLRAAQTVFLNTPHPLDILSDRSAYGS

Seql4 541 TFSPGHELLPSGNGLYLLTSDFESPDIEDSDEERLRAAQTVFLNTPHPLDILSDRSAYGS ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★

Seql2 601 SGTIQRDHDMNSYLKAVRSVIRKEVNQIRRAKREHRRSLWWPILVARESGSSGIAVSNGQ Seql4 601 SGTIQRDHDMNSYLKAVRSVIRKEVNQIRRAKREHRRSLWWPILVARESGSSVIAVSNGQ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★ ★★★★★★★

Seql2 661 INGQDFSGMMQTGRKSLQRFSRLVASQHMPLIVVMLFPVKLLFLGAFNVFSFR

Seql4 661 INGQDFSGMMQTGRKSLQRFSRLVASQHMPLIVVMLFPVKLLFLGAFNVFSFR

★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★

This PLIP2-related lipase protein from Arabidopsis thaliana with SEQ ID NO: 14 has accession number AAM98103.1 and the SEQ ID NO: 14 amino acid sequence is shown below.

1 MDSLCLNSGL HGVIPAITAV GNGGCGGVVE VRATASAPSQ 41 KRGPFGFSFK YPLTPFWSRG GGGGIASRRR SGLCLDDAVL 81 VDSGDSRKPI AEETAVEMDT ERRNGSWVLK ILDVQSTWKH 121 EEEEDDDEVE DEDGDEDEEV ELDDAWSED DGGCDVCSVL 161 EDDGNEANKF QLDRESFSKL LRRVTLPESK LYAQLSYLGN 201 LAYSISKIKP ANLSKYYGLR FVTSSAEKTE SALKAENGEV 241 SGETKP IVEA EEEVEEEEKN KSRKISASAA YEIVASAASY 281 LHSRTNNILP FNSSSKAENS DKHDVNLTNA ESSSDVAYSV 321 TSWAAEEDV KQAVADDLKS TISSPCDWFI CDDDQSHTRF 361 VVIQGSESLA SWQANLLFEP IEFEGLGAIV HRGIYEAAKG 401 MYEQMLPEVK AHIKTHGTSA KFRFTGHSLG GSLSLLLNLM 441 LLVRGEVPAS SLLPVITYGA PFVLCGGDRL LKKLGLPKSH 481 VQAIVMHRDI VPRAFSCNYP YHVAELLKAV NGNFRSHPCL 521 NKQSMLYSPM GELLI LQPDE TFSPGHELLP SGNGLYLLTS 561 DFESPD IEDS DEERLRAAQT VFLNTPHPLD ILSDRSAYGS 601 SGTIQRDHDM NSYLKAVRSV IRKEVNQIRR AKREHRRSLW 641 WPILVARESG SSVIAVSNGQ INGQDFSGMM QTGRKSLQRF 681 SRLVASQHMP LIWMLFPVK LLFLGAFNVF SFR

Another PLIP2-related lipase protein from Arabidopsis thaliana with SEQ ID NO: 15 shares about 97% sequence identity with the SEQ ID NO: 12 PLIP2 protein as illustrated below.

Seql2 1 MDSLCLNSGLHGVIPAITAVGNGGCGGWEVRATASAPSQKRGPFGFSFKYPLTPFWSRG

Seql5 1 MDSLCLNSGLHGVIPAITAVGNGGCGGWEVRATASAPSQKRGPFGFSFKYPLTPFWSRG ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★

Seql2 61 GGGGIASRRRSGLCLDDAVLVDSGDSRKPIAEETAVEMDTERRNGSWVLKILDVQSTWKH

Seql5 61 GGGGIASRRRSGLCLDDAVLVDSGDSRKPIAEETAVEMDTERRNGSWVLKILDVQSTWKH ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★

Seql2 121 EEEEDDDEVEDEDGDEDEEVELDDAWSEDDGGCDVCSVLEDDGNEANKFQLDRESFSKL Seql5 121 EEEEDDDEVEDEDGDEDEEVELDDAWSEDDGGCDVCSVLEDDGNEANKFQLDRESFSKL ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ Seql2 181 LRRVTLPESKLYAQLSYLGNLAYSISKIKPANLSKYYGLRFVTSSAEKTESALKAENGEV Seql5 181 LRRVTLPESKLYAQLSYLGNLAYSISKIKPANLSKYYGLRFVTSSAEKTESALKAENGEV ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★

Seql2 241 SGETKPIVEAEEEVEEEEKNKSRKISASAAYEIVASAASYLHSRTNNILPFNS SSKAENS Seql5 241 SGETKPIVEAEEEVEEEEKNKSRKISASAAYEIVASAASYLHSRTNNILPFNS SSKAENS ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ ★★★★★★★★★★★★★★★★★★★★ Seql2 301 DKHDVNLTNAESSSDVAYSVTSWAAEEDVKQAVADDLKSTISSPCDWFICDDDQSHTRF Seql5 301 DKHDVNLTNAESSSDVAYSVTSWAAEEDVKQAVADDLKSTISSPCDWFICDDDQSHTRF

Seql2 361 WIQGSESLASWQANLLFEPIEFEGLGAIVHRGIYEAAKGMYEQMLPEVKAHIKTHGTSA Seql5 361 WIQG LGAIVHRGIYEAAKGMYEQMLPEVKAHIKTHGTSA

Seql2 421 KFRFTGHSLGGSLSLLLNLMLLVRGEVPASSLLPVITYGAPFVLCGGDRLLKKLGLPKSH Seql5 401 KFRFTGHSLGGSLSLLLNLMLLVRGEVPASSLLPVITYGAPFVLCGGDRLLKKLGLPKSH

Seql2 481 VQAIVMHRDIVPRAFSCNYPYHVAELLKAVNGNFRSHPCLNKQSMLYSPMGELLILQPDE Seql5 461 VQAIVMHRDIVPRAFSCNYPYHVAELLKAVNGNFRSHPCLNKQSMLYSPMGELLILQPDE

Seql2 541 TFSPGHELLPSGNGLYLLTSDFESPDIEDSDEERLRAAQTVFLNTPHPLDILSDRSAYGS Seql5 521 TFSPGHELLPSGNGLYLLTSDFESPDIEDSDEERLRAAQTVFLNTPHPLDILSDRSAYGS

Seql2 601 SGTIQRDHDMNSYLKAVRSVIRKEVNQIRRAKREHRRSLWWPILVARESGSSGIAVSNGQ Seql5 581 SGTIQRDHDMNSYLKAVRSVIRKEVNQIRRAKREHRRSLWWPILVARESGSSGIAVSNGQ

Seql2 661 INGQDFSGMMQTGRKSLQRFSRLVASQHMPLIVVMLFPVKLLFLGAFNVFSFR

Seql5 641 INGQDFSGMMQTGRKSLQRFSRLVASQHMPLIVVMLFPVKLLFLGAFNVFSFR

This PLIP2-related lipase protein from Arabidopsis thaliana with SEQ ID NO: 15 has accession number AAG10634.1 and the SEQ ID NO: 15 amino acid sequence is shown below.

1 MDSLCLNSGL HGVIPAITAV GNGGCGGVVE VRATASAPSQ 41 KRGPFGFSFK YPLTPFWSRG GGGGIASRRR SGLCLDDAVL

81 VDSGDSRKPI AEETAVEMDT ERRNGSWVLK ILDVQSTWKH

121 EEEEDDDEVE DEDGDEDEEV ELDDAWSED DGGCDVCSVL

161 EDDGNEANKF QLDRESFSKL LRRVTLPESK LYAQLSYLGN

201 LAYSISKIKP ANLSKYYGLR FVTS SAEKTE SALKAENGEV

241 SGETKP IVEA EEEVEEEEKN KSRKISASAA YEIVASAASY

281 LHSRTNNILP FNSSSKAENS DKHDVNLTNA ESSSDVAYSV

321 TSWAAEEDV KQAVADDLKS TISSPCDWFI CDDDQSHTRF

361 VVIQGLGAIV HRGIYEAAKG MYEQMLPEVK AHIKTHGTSA

401 KFRFTGHSLG GSLSLLLNLM LLVRGEVPAS SLLPVITYGA

441 PFVLCGGDRL LKKLGLPKSH VQAIVMHRDI VPRAFSCNYP

481 YHVAELLKAV NGNFRSHPCL NKQSMLYSPM GELLILQPDE

521 TFSPGHELLP SGNGLYLLTS DFESPDIEDS DEERLRAAQT

561 VFLNTPHPLD ILSDRSAYGS SGTIQRDHDM NSYLKAVRSV

601 IRKEVNQIRR AKREHRRSLW WPILVARESG SSGIAVSNGQ

641 I GQDFSGMM QTGRKSLQRF SRLVASQHMP LIVVMLFPVK

681 LLFLGAFNVF SFR Another PLIP2-related lipase protein from Zeq mays with SEQ ID NO: 16 shares about 48-50% sequence identity with the SEQ ID NO:12 PLIP2 protein as illustrated below.

Seql2 103 RNGSWVLKILDVQSTWKHEEEEDDDEVEDEDGDEDEEVELDDAWSEDDGGCDVCSVLED Seql6 86 RGGNWVLQILRVQSSPPPSPSRDDGRCGVDDGGSVPGSGEGDGSSQRCVERGGVGPDSEE

Seql2 163 DGNEANKFQLDRESFSKLLRRVTLPESKLYAQLSYLGNLAYSISKIKPANLSKYYGLRFV Seql6 146 GCSVADGEELDRAAFSRLLRKVSLAEAKLFSEMSGLCNLAYMVPRIKPRYLHKY-NMTFV

Seql2 223 TSSAE KTESALKAENGEVSG ETKP IVEAEEEVEEEEKNKSRK-

Seql6 205 TSSVEERAKLPNPCNQEDQNLNGRKNANISTSSRHSDEQESTYGATSEHERMQENQSGQG

Seql2 265 ISASAAYEIVASAASYLHSRTNNILPFNSSSKAENS DKHD LTNAESSS-DV

Seql6 265 INPLAAYRIAASAASYMQSRAMEVLPFGSQNEARRDRTIQAIVNAQTEGLTMDEASFVAT

Seql2 317 AYSVTSWAAEEDVKQAVADDLKSTISSPCDWFICDDDQSHTRFWIQGSESLASWQANL Seql6 325 TNSMTSMVAAKEETKQAVADDLNSSRSCPCEWFICDGNRNSTRYFVIQGSETIASWQANL

Seql2 377 LFEPIEFEGLGAIVHRGIYEAAKGMYEQMLPEVKAHIKTHGTSAKFRFTGHSLGGSLSLL Seql6 385 LFEPIKFEGLDVLVHRGIYEAAKGIYQQMLPYVKSHFIVHGESARLRFTGHSLGGSLALL

Seql2 437 LNLMLLVRGEVPASSLLPVITYGAPFVLCGGDRLLKKLGLPKSHVQAIVMHRDIVPRAFS Seql6 445 VNLMFLIRGVAPAASLLPVITFGSPSVMCGGDYLLQKLGLPKSHVQSVTLHRDIVPRAFS

Seql2 497 CNYPYHVAELLKA GNFRSHPCLNKQSMLYSPMGELLILQPDETFSPGHELLPSGNGLY Seql6 505 CHYPDHIAS ILKL GNFRSHPCLTNQKLLYAPMGEVFILQPDEKLSPHHHLLPAGSGLY

Seql2 557 LLTSDFESPDIEDSDEERLRAAQTVFLNTPHPLDILSDRSAYGSSGTIQRDHDMNSYLKA Seql6 565 LIGGQTVD SGTS STALRSALSAFFNSPHPLEILRDAGAYGPKGTVYRDHDVHSYLRS Seql2 617 VRSVIRKEVNQIRRAKREHRRSLWWPILV

Seql6 622 IRAWRKEM RAEKERRRLLRWPIEV

This PLIP2-related lipase protein from Zea mays with SEQ ID NO: 16 has accession number NP_001148192.1 and the SEQ ID NO: 16 amino acid sequence is shown below.

1 MDVLRFVPGV RPPLPTFATP VSPATAPSPH AAAAAAAPGP 41 GFHSGMLGLW PRRAGENALG AAAEAAGVEE ARERRRRRAV

81 EAEDGRGGNW VLQILRVQSS PPPSPSRDDG RCGVDDGGSV

121 PGSGEGDGSS QRCVERGGVG PDSEEGCSVA DGEELDRAAF

161 SRLLRKVSLA EAKLFSEMSG LCNLAYMVPR IKPRYLHKYN

201 MTFVTS SVEE RAKLPNPCNQ EDQNLNGRKN ANISTSSRHS

241 DEQESTYGAT SEHERMQENQ SGQGINPLAA YRIAASAASY

281 MQSRAMEVLP FGSQNEARRD RTIQAIVNAQ TEGLTMDEAS 321 FVATTNSMTS MVAAKEETKQ AVADDLNSSR SCPCEWFICD 361 GNRNSTRYFV IQGSETIASW QANLLFEP IK FEGLDVLVHR 401 GIYEAAKGIY QQMLPYVKSH FIVHGESARL RFTGHSLGGS 441 LALLVNLMFL IRGVAPAASL LPVITFGSPS VMCGGDYLLQ 481 KLGLPKSHVQ SVTLHRDIVP RAFSCHYPDH IAS ILKLVNG 521 NFRSHPCLTN QKLLYAPMGE VFILQPDEKL SPHHHLLPAG 561 SGLYLIGGQT VDSGTSSTAL RSALSAFFNS PHPLEILRDA 601 GAYGPKGTVY RDHDVHSYLR SIRAWRKEM RAEKERRRLL 641 RWPIEVYGAL ATIDRRQVLR QLRRHAHLLV VFLLPAKLLF 681 LGVLSLIRPT

Another PLIP2-related lipase protein from Zeq mays with SEQ ID NO: 17 shares about 47-49% sequence identity with the SEQ ID NO: 12 PLIP2 protein as illustrated below.

Seql2 85 DSRKPIAEETAVEMDTERRNGSWVLKILDVQSTWKHEEEEDDDEVEDEDGDEDEEVELDD Seql7 56 EPRSPPDEERKAE-GAQRGQGNWVLQMLRVQPRWV DAADAEATGGGQEPDEETAAAA

Seql2 145 AWSEDDGGCDVCSVLEDDGNEANKFQ LDRESFSKLLRRVTLPESKLYAQLSYL

Seql7 112 AAGAGGVEECASCGCGEDDEGCAVGYGDGDGEVFDRASFSRLLRKASLGEAKEYSMMSYL

Seql2 199 GNLAYSISKIKPANLSKYYGLRFVTSSAEKTESALKAENGEVSGETKPIV—EAEEEVE E Seql7 172 CNIAYMIPRIQPKCLRRY-NLRFVTSSVQDKAGVSNPDQKQERSTKKDESGDQASEAVDD

Seql2 257 EEKNKSR-KISASAAYEIVASAASYLHSRTNNILPFNSS SKAENSDKHDVNLTNAESSSD Seql7 231 AVPRRGLGTIKPFGAYHWSSAASYLHSRAMGVMPFGPGNGVKDDHPAAVTSLVSGASGD

Seql2 316 VAYSVTSWAAEEDVKQAVADDLKSTIS SPCDWFICDDDQSHTRFWIQ

Seql7 291 GLSVDEASFVATTSSVTSMVAAKEETRQAVADDLNSSRSCPCEWFVCEDDQNSTIYFWQ

Seql2 365 GSESLASWQANLLFEPIEFEGLGAIVHRGIYEAAKGMYEQMLPEVKAHIKTHGTSAKFRF Seql7 351 GSESIASWQANLLFEPVKFEEVDVLVHRGIYEAAKGMYHQMLPYVKAHLKSWGKSARLRF

Seql2 425 TGHSLGGSLSLLLNLMLLVRGEVPASSLLPVITYGAPFVLCGGDRLLKKLGLPKSHVQAI Seql7 411 TGHSLGGSLALLVNLMLLVRGEAPASSLLPVITFGAPCIMCGGDHLLRRLGLPRSHVQSV

Seql2 485 VMHRDIVPRAFSCNYPYHVAELLKA GNFRSHPCLNKQSMLYSPMGELLILQPDETFSP Seql7 471 TMHRDIVPRVFSCHYPDHVANILKLANGNFRSHPCLANQKLLYAPMGEVLILQPDERLSP

Seql2 545 GHELLPSGNGLYLLTSDF ESPDIEDSDEERLRAAQTVFLNTPHPLDILSDRSAY

Seql7 531 HHHLLPPDSGIYHLGGGGGGGGAGTAANAGEGSLPQLRSALSAFFNSPHPLEILKDGAAY

Seql2 599 GSSGTIQRDHDMNSYLKAVRSVIRKEVNQIRRAKREH-RRSLWWPILVARESGSS Seql7 591 GPRGSVYRDHDVNSYLRSVRAWRKEARRAREAERERWRLLLWWPFGVHGVSSAS This PLIP2-related lipase protein from Zea mays with SEQ ID NO: 17 has accession number NP_001169446.1 and the SEQ ID NO:17 amino acid sequence is shown below.

1 MDVLRFVRAA AAPQPAVAPP ASAATVPAQR QRLRMWPRGG 41 GDQPPPVGAA STRGAEPRSP PDEERKAEGA QRGQGNWVLQ

81 MLRVQPRWVD AADAEATGGG QEPDEETAAA AAAGAGGVEE

121 CASCGCGEDD EGCAVGYGDG DGEVFDRASF SRLLRKASLG

161 EAKEYSMMSY LCNIAYMIPR IQPKCLRRYN LRFVTSSVQD

201 KAGVSNPDQK QERSTKKDES GDQASEAVDD AVPRRGLGTI

241 KPFGAYHWS SAASYLHSRA MGVMPFGPGN GVKDDHPAAV

281 TSLVSGASGD GLSVDEASFV ATTSSVTSMV AAKEETRQAV

321 ADDLNS SRSC PCEWFVCEDD QNSTIYFVVQ GSESIASWQA

361 NLLFEPVKFE EVDVLVHRGI YEAAKGMYHQ MLPYVKAHLK

401 SWGKSARLRF TGHSLGGSLA LLVNLMLLVR GEAPASSLLP

441 VITFGAPCIM CGGDHLLRRL GLPRSHVQSV TMHRDIVPRV

481 FSCHYPDHVA NILKLANGNF RSHPCLANQK LLYAPMGEVL

521 I LQPDERLSP HHHLLPPDSG IYHLGGGGGG GGAGTAANAG

561 EGSLPQLRSA LSAFFNSPHP LEILKDGAAY GPRGSVYRDH

601 DVNSYLRSVR AWRKEARRA REAERERWRL LLWWPFGVHG

641 VSSASAGRRG GLVDAVSEAA RRAHLLLVVL LPAELLALGA

681 LLAVIRFR

Another PLIP2-related lipase protein from Glycine max with SEQ ID NO: 18 shares at least 57% sequence identity with the SEQ ID NO: 12 PLIP2 protein as illustrated below.

Seql2 1 MDSLCLNSGLHGVIPAITAV-GNGGCGGWEVRATASAP SQKRGPFG-FSFKYPLTPFWS Seql8 1 METMCLKSGIVPTIS ISGSLDARANPSQVSTVGRSASDKPPQRSVFSRFSFWYPLESLWP

Seql2 59 RGGGGGIASRRRSGLCLDDAVLVDSGDSRKPIAEETAVEMDTERRNGSWVLKILDVQSTW Seql8 61 RGN NSRYKGLALDDAVLSDNNAEAKAVGDD GTERQTGNWVLKILHVKSLW

Seql2 119 KHEEEEDDDEVEDEDGDEDEEVELDDAWSEDDGGCDVCSVLEDDGNEANKFQLDRESFS Seql8 111 EGKQRDEEEGSVRDQTQTNYEEEEEVCE CDAC DEVEEAQFDRGSFS

Seql2 179 KLLRRVTLPESKLYAQLSYLGNLAYSI SKIKPANLSKYYGLRFVTSSAEKTESALKAENG Seql8 157 RMLRRVSLAESRLYAQMSHLGNLAYDIPRIKPGKLLKHYGLRFVTSS IEKKELAVAATAE

Seql2 239 EVSGETKPIVEAEEEVEEEE-KNKSRKISASAAYEIVASAASYLHSRTNNILPFNSS

Seql8 217 KDPQKVQTDEKVDEKEERKDPKNGEYKISATAAYNIAASAATYLHSQTRSIFPLKSSNAV

Seql2 295 SKAENSDKHD-VNLTNAESSSDVAY—SVTSWAAEEDVKQAVADDLKSTISSPCD

Seql8 277 AGEGSLAGNNESLDS MLNTEVASLMATTDSVTAVVAAKEEVKQAVADDLNS SHSTPCE

Seql2 348 WFICDDDQSHTRFWIQGSESLASWQANLLFEP IEFEGLGAIVHRGIYEAAKGMYEQMLP Seql8 337 WFVCDNDQSGTRFFVIQGSETLASWQANLLFEP IKFEGLDVLVHRGIYEAAKGIYQQMLP Seql2 408 EVKAHIKTHGTSAKFRFTGHSLGGSLSLLLNLMLLVRGEVPASSLLPVITYGAPFVLCGG Seql8 397 EVHAHLKSRGSRATFRFTGHSLGGSLALLVNLMLLIRHEVP ISSLLPVITFGSPSIMCGG

Seql2 468 DRLLKKLGLPKSHVQAIVMHRDIVPRAFSCNYPYHVAELLKAVNGNFRSHPCLNKQSMLY Seql8 457 DSLLEKLGLPKSHVQAITMHRDIVPRAFSCNYPNHVAELLKAVNGNFRSHPCLNKQKLLY

Seql2 528 SPMGELLILQPDETFSPGHELLPSGNGLYLLTSDFESPDIEDSDEERLRAAQTVFLNTPH Seql8 517 APMGNLLILQPDEKFSPSHHLLPSGSGLYLLCCPLSE SNDTEKQLRAAQMVFLNSPH

Seql2 588 PLDILSDRSAYGSSGTIQRDHDMNSYLKAVRSVIRKE QIRRAKREHRRSLWWPILVAR Seql8 574 PLEILSDRSAYGSGGSVQRDHDMNSYLKSVRTVIRQELNQIRKAKREQRRK WPLLLPR

Seql2 648 E SGSSGIAVSNGQINGQDFSG MQTGRKSLQRFSRLVASQHMPLIWMLFPVKL

Seql8 634 GVDTSIVAGRSMISINVGQ-RQSPFSGV-QTGRESLKRFSRWTSQHMHLFVLLLFPARL

Seql2 702 LFLGAFNVFSFR

Seql8 692 LLLGTYSVINLK

This PLIP2-related lipase protein from Glycine max with SEQ ID NO: 18 has accession number XP_014619726.1 and the SEQ ID NO:18 amino acid sequence is shown below.

1 METMCLKSGI VPTISISGSL DARANPSQVS TVGRSASDKP

41 PQRSVFSRFS FWYPLESLWP RGNNSRYKGL ALDDAVLSDN

81 NAEAKAVGDD GTERQTGNWV LKILHVKSLW EGKQRDEEEG

121 SVRDQTQTNY EEEEEVCECD ACDEVEEAQF DRGSFSRMLR

161 RVSLAESRLY AQMSHLGNLA YDIPRIKPGK LLKHYGLRFV

201 TSSIEKKELA VAATAEKDPQ KVQTDEKVDE KEERKDPKNG

241 EYKISATAAY NIAASAATYL HSQTRSIFPL KSSNAVAGEG

281 SLAGNNESLD SVNMLNTEVA SLMATTDSVT AVVAAKEEVK

321 QAVADDLNSS HSTPCEWFVC DNDQSGTRFF VIQGSETLAS

361 WQANLLFEPI KFEGLDVLVH RGIYEAAKGI YQQMLPEVHA

401 HLKSRGSRAT FRFTGHSLGG SLALLVNLML LIRHEVPISS

441 LLPVITFGSP SIMCGGDSLL EKLGLPKSHV QAITMHRDIV

481 PRAFSCNYPN HVAELLKAVN GNFRSHPCLN KQKLLYAPMG

521 NLLILQPDEK FSPSHHLLPS GSGLYLLCCP LSESNDTEKQ

561 LRAAQMVFLN SPHPLEILSD RSAYGSGGSV QRDHDMNSYL

601 KSVRTVIRQE LNQIRKAKRE QRRKVWWPLL LPRGVDTSIV

641 AGRSMISINV GQRQSPFSGV QTGRESLKR FSRVVTSQHM

681 HLFVLLLFPA RLLLLGTYSV INLK

Another PLIP2-related lipase protein from Glycine max with SEQ ID NO: 19 shares at least 54-55% sequence identity with the SEQ ID NO: 12 PLIP2 protein as illustrated below.

Seql2 1 MDSLCLNSGLHGVIPAITAVGNGGCGGWEV—RATASAPSQKRGPFGFSFKYPLTPFWS Seql9 1 METVCLKSGMVPTIS ISGSLDARANPSQVSTVGRAAGDKPPQRSVFSRFSFWYPLESLWP

Seql2 59 RGGGGGIASRRRSGLCLDDAVLVDSGDSRKPIAEETAVEMDTERRNGSWVLKILDVQSTW Seql9 61 RGN NSRYKGLALDDAVLADNNAEAKAVRDDGQGD-GTERQTGNWVLKILHVKSVW

Seql2 119 KHEEEEDDDEVEDEDGDEDEEVELDDAWSEDDGGCDVCSVLEDDGN-EANKFQLDRESF Seql9 115 EGKQRNE EDGTVHDQTQTNFDEEEVCE CDACGVDEDDGYCEEEEAEFDRGSF

Seql2 178 SKLLRRVTLPESKLYAQLSYLGNLAYS ISKIKPANLSKYYGLRFVTS SAEKTESAL

Seql9 167 SR LRRVSLGEARLYAQMSHLGNLAYDIPRIKPGKLLKHHGLRFVIS SIEKKELAVAATA

Seql2 234 KAENGEVSGETKPIVEAEEEVEEEE

Seql9 227 EKDPQKVGS SIEKKEFAAIAEKDPQKVGSSTEKKEFAAIAEKDPQKVETDEKVEEKEETK

Seql2 259 —KNKSRKI SASAAYEIVASAASYLHSRTNNILPFNSSS KAENSDKHDVNLT

Seql9 287 DPKNAGYKI SATAAYNIAASAATYLHSQTSSIFPFKSSNAVTGEGSLEGSNESLDTVNML

Seql2 309 NAESSSDVAY—SVTSWAAEEDVKQAVADDLKSTISSPCDWFICDDDQSHTRFWIQGS Seql9 347 NTEVASL ATTDSVTAWAAKEEVKQAVADDLNSAHSTPCEWFVCDDDQSATRFFVIQGS

Seql2 367 ESLASWQANLLFEPIEFEGLGAIVHRGIYEAAKGMYEQMLPEVKAHIKTHGTSAKFRFTG Seql9 407 ETLASWQANLLFEPIKFEGLDVLVHRGIYEAAKGIYQQMLPEVRAHLKSRGSRATFRFTG

Seql2 427 HSLGGSLSLLLNLMLLVRGEVPASSLLPVITYGAPFVLCGGDRLLKKLGLPKSHVQAIVM Seql9 467 HSLGGSLALLVNLMLLIRNEVPVSSLLPVITFGSPSIMCGGDSLLKKLGLPRSHVQAITM

Seql2 487 HRDIVPRAFSCNYPYHVAELLKAVNGNFRSHPCLNKQSMLYSPMGELLILQPDETFSPGH Seql9 527 HRDIVPRAFSCNYPNHVAELLKAVNGNFRSHPCLNKQKLLYAPMGNLLILQPDEKFSPSH

Seql2 547 ELLPSGNGLYLLTSDFESPDIEDSDEERLRAAQTVFLNTPHPLDILSDRSAYGSSGTIQR Seql9 587 HLLPSGSGLYLLCCPLSE SDDTEKRLRAAQMVFLNSPHPLEILSDRSAYGSGGSIQR

Seql2 607 DHDMNSYLKAVRSVIRKEVNQIRRAKREHRRSLWWPILVARES GSSGIAVSNGQ

Seql9 644 DHDMNSYLKSLRTVIRKELNQIRKAKREQRRKVWWPLLLSRGADTSIVAGRSMISINVGQ

Seql2 661 INGQDFSGMMQTGRKSLQRFSRLVASQHMPLIVVMLFPVKLLFLGAFNVFSFR

Seql9 704 -RQSPFSSVIQTGRESLKRFSRIVTSQHMHLFVLLLFPARLLLLGTYSVINLK

This PLIP2-related lipase protein from Glycine max with SEQ ID NO: 19 has accession number XP_003535965.1 and the SEQ ID NO:19 amino acid sequence is shown below.

1 METVCLKSGM VPTISISGSL DARANPSQVS TVGRAAGDKP 41 PQRSVFSRFS FWYPLESLWP RGNNSRYKGL ALDDAVLADN

81 NAEAKAVRDD GQGDGTERQT GNWVLKILHV KSVWEGKQRN 121 EEDGTVHDQT QTNFDEEEVC ECDACGVDED DGYCEEEEAE

161 FDRGSFSRML RRVSLGEARL YAQMSHLGNL AYDIPRIKPG

201 KLLKHHGLRF VISSIEKKEL AVAATAEKDP QKVGSSIEKK

241 EFAAIAEKDP QKVGS STEKK EFAAIAEKDP QKVETDEKVE

281 EKEETKDPKN AGYKI SATAA YNIAASAATY LHSQTSSIFP

321 FKSSNAVTGE GSLEGSNESL DTVNMLNTEV ASLMATTDSV

361 TAWAAKEEV KQAVADDLNS AHSTPCEWFV CDDDQSATRF

401 FVIQGSETLA SWQANLLFEP IKFEGLDVLV HRGIYEAAKG

441 IYQQMLPEVR AHLKSRGSRA TFRFTGHSLG GSLALLVNLM

481 LLIRNEVPVS SLLPVITFGS PSIMCGGDSL LKKLGLPRSH

521 VQAITMHRDI VPRAFSCNYP NHVAELLKAV NGNFRSHPCL

561 NKQKLLYAPM GNLLI LQPDE KFSPSHHLLP SGSGLYLLCC

601 PLSESDDTEK RLRAAQMVFL NSPHPLEILS DRSAYGSGGS

641 IQRDHDMNSY LKSLRTVIRK ELNQIRKAKR EQRRKVWWPL

681 LLSRGADTSI VAGRSMISIN VGQRQSPFSS VIQTGRESLK

721 RFSRIVTSQH MHLFVLLLFP ARLLLLGTYS VINLK

Another PLIP2-related lipase protein from Brassica napus with SEQ ID NO:20 shares at least 80% sequence identity with the SEQ ID NO: 12 PLIP2 protein as illustrated below.

Seql2 1 MDSLCLNSGLHGVIPAITAVGNGGCGGWEVRATASAPSQKRGPFGFSFKYPLTPFWSRG Seq20 1 MDSLCLNP GVIPAIKAVGSG-CGGWEVRANA SQKRRPSGS SFKHPLTPFWSRG

Seql2 61 GGGGIASRRRSGLCLDDAVLVDSGDSRKPIAEE—TAVEMDTERRNGSWVLKILDVQST W Seq20 54 G—GIASRRRSGLGLDDAVLVDSGDSRKPIAEEEPSAVEMETERRNGSWILKILDVHSM W Seql2 119 KHEEEEDDDEVEDEDGDEDEEVELDDAWSEDDGGCDVCSVLEDDGNEANKFQLDRESFS Seq20 112 R DEEIEEEEEEELNDAVLPEDDG VCSVLED-GDEENKFQMHRESFS

Seql2 179 KLLRRVTLPESKLYAQLSYLGNLAYSI SKIKPANLSKYYGLRFVTSSAEKTESALKAENG Seq20 157 KLLKRVSLSESKLYAQMSYLGNLAYSI SKIKPANLSKYYGLRFVTSSAEKTELALKA

Seql2 239 EVSGETKPIVEAEEEVEEEEKNKSRKI SASAAYEIVASAASYLHSRTNNILPFNSSSKAE Seq20 214 QVSAETKP-KEEDEEVEDEENK GASAAYEWASAASYLQSRTTNILPFPSSSKND

Seql2 299 NSDKHDVNLTNAESS SDVAYSVTSWAAEEDVKQAVADDLKSTISSPCDWFICDDDQSHT Seq20 268 DEEE SSSSSSSLTSSVTCWAAEEDVKQAVADDLKFTISSPCDWFICDDDQTLT

Seql2 359 RFVVIQGSESLASWQANLLFEPIEFEGL—GAIVHRGIYEAAKGMYEQMLPEVKAHIKT H Seq20 322 RFFVIQGSESLASWQANLLFEPIEFEELDDGAIVHRGIYEAAKGMYEQMLPEVKAHIKAH Seql2 417 GTSAKFRFTGHSLGGSLSLLLNLMLLVRGEVPASSLLPVITYGAPFVLCGGDRLLKKLGL Seq20 382 GNRAKFRFTGHSLGGSLSLLLNLMLLVRGEVPASSLLPVITFGAPFVLCGGDSLLKMLGL

Seql2 477 PKSHVQAIVMHRDIVPRAFSCNYPYHVAELLKAVNGNFRSHPCLNKQSMLYSPMGELLIL Seq20 442 PKSHVQAIIMHRDIVPRAFSCNYPYHVAELLKAVNGHFRSHPCLNKQSMLYSPMGELLIL Seql2 537 QPDETFSPGHELLPSGNGLYLLTSD-FESPDIEDSDEERLRAAQTVFLNTPHPLDILSDR Seq20 502 QPDESFSPGHDLLPIGNGLYLLTGGGFES—LDDEEEQRLRAAQTVFLNTPHPLDILSD R

Seql2 596 SAYGSSGTIQRDHDMNSYLKAVRSVIRKEVNQIRRAKREHRRSLWWP ILVARESG-SSGI Seq20 560 SAYGSSGTIQRDHDMNSYLKAVRSVIRKEVSQIRRLKREHRRSLWWP ILVARESGRSSGT

Seql2 655 AVSNGQINGQDFSGMMQTGRKSLQRFSRLVASQHMPLIVVMLFPVKLLFLGAFNVFSFR Seq20 620 AIGN NGQDFSGMMKTGRKSLQRFSRLVASQHMPLIVVLLFPVKLLFLEAFNVLSFR

This PLIP2-related lipase protein from Brassica napus with SEQ ID NO:20 has accession number CDY51303.1 and the SEQ ID NO:20 amino acid sequence is shown below.

1 MDSLCLNPGV IPAIKAVGSG CGGVVEVRAN ASQKRRPSGS 41 SFKHPLTPFW SRGGGIASRR RSGLGLDDAV LVDSGDSRKP 81 IAEEEP SAVE METERRNGSW ILKI LDVHSM WRDEEIEEEE 121 EEELNDAVLP EDDGVCSVLE DGDEENKFQM HRESFSKLLK 161 RVSLSESKLY AQMSYLGNLA YSISKIKPAN LSKYYGLRFV

201 TSSAEKTELA LKAQVSAETK PKEEDEEVED EENKGASAAY 241 EWASAASYL QSRTTNILPF PSSSKNDDEE ESSSSSSSLT 281 SSVTCVVAAE EDVKQAVADD LKFTISSPCD WFICDDDQTL 321 TRFFVIQGSE SLASWQANLL FEPIEFEELD DGAIVHRGIY 361 EAAKGMYEQM LPEVKAHIKA HGNRAKFRFT GHSLGGSLSL 401 LLNLMLLVRG EVPASSLLPV ITFGAPFVLC GGDSLLKMLG 441 LPKSHVQAII MHRDIVPRAF SCNYPYHVAE LLKAVNGHFR 481 SHPCLNKQSM LYSPMGELLI LQPDESFSPG HDLLPIGNGL 521 YLLTGGGFES LDDEEEQRLR AAQTVFLNTP HPLDILSDRS 561 AYGSSGTIQR DHDMNSYLKA VRSVIRKEVS QIRRLKREHR 601 RSLWWPILVA RESGRSSGTA IGNNGQDFSG MMKTGRKSLQ 641 RFSRLVASQH MPLIVVLLFP VKLLFLEAFN VLSFR

In some cases, the lipase used in the expression cassettes and methods described herein can be a PLIP3 lipase. However, some preliminary evidence indicates that the activities of the PLIP3 lipases are different from the PLIP1 lipase. Hence, in some cases the lipase used in the expression cassettes and methods described herein is not a PLIP3 lipase. However, in some cases, expression of a combination of PLIP1 , PLIP2, and/or

PLIP3 lipases may be useful and can be employed when making the expression cassettes and using the methods described herein. One example of an Arabidopsis thaliana PLIP3 protein sequence is shown below as SEQ ID NO:21.

1 MEGVFLKMSV VGVSPMIPVG PSSFICAIGG SVEEKSTAAS

41 LPRWVSLRRL RPLEFLRIGG KREEKGTVRD DDAVLLERRD

81 RNRNENDNGN WVLKILEVGS IWKGKRQRSG GGGGGEEDEE 121 EEVAEPKKKE DLCEECDFCR IDDDDEDEEK EKTVFEFSEM 161 LSKIPVEDAQ MFAKLSFLGN LAYSIPKIKP ENLLKYQKLR 201 FVTSSIEKRM SLKVEENNNG EEDEEKKKLI NPAVAYRIAA 241 SAASRLFSHS KSVLPFGSSK RQDNEEASLL ATADSVTAVV

281 AAKEEVKQAV ADDLKSNRSP PCEWFVCDDD KSGTRFFFIQ 321 GSDSLASWQA NLLFEPVPFE DLDVLVHRGI YEAAKGIYEQ

361 MLPEVHAHLN SRGKNRAFLR FSGHSLGGSL SLLVNLMLLI

401 RGQVPASSLL PVITFGSPCI MCGGDRLLQK LGLPKSHLLG 441 ISMHRDIVPR AFSCNYPNRA AKLLKALNGN FRNHPCLNNQ

481 NVLYSPMGKL LILQPSERFS PPHPLLPPGS GLYLLASKNT 521 DETEKSLRAA KILFFNSPHP LEILSDRRSY GSEGKIKRNH

561 DMSSYLKALR HVIRKELKQM KAERDQWLRK FFIINILFSG 601 RDSLKLITRF VASRSSQLVI IFFLP IRLLI MSVYSWFHH 641 SQAHFSFFK

A nucleic acid sequence encoding the Arabidopsis thaliana PLIP3 lipase with SEQ ID NO:21 is shown below as SEQ ID NO:22.

1 ATGGAGGGTG TTTTCTTAAA AATGTCGGTG GTTGGAGTAT 41 CTCCGATGAT ACCGGTGGGA CCTTCTTCTT TCATATGCGC 81 CATCGGAGGC TCTGTTGAGG AGAAATCAAC GGCTGCTTCT 121 CTGCCGCGTT GGGTTTCCCT TCGTCGTCTT CGTCCGCTTG 161 AGTTTCTTCG GATCGGTGGT AAGAGAGAGG AAAAGGGAAC 201 GGTAAGAGAC GACGACGCCG TTTTGTTGGA GAGAAGGGAC 241 CGGAACCGCA ACGAAAACGA TAACGGAAAC TGGGTTTTGA 281 AAATTTTGGA GGTTGGATCA ATCTGGAAAG GGAAGAGACA 321 ACGATCAGGT GGCGGTGGCG GTGGAGAAGA GGACGAGGAA 361 GAGGAAGTTG CTGAGCCTAA GAAGAAGGAA GATTTATGTG 401 AGGAATGCGA TTTCTGCAGG ATCGATGATG ATGATGAAGA 441 CGAAGAAAAG GAGAAGACAG TGTTTGAGTT CTCGGAGATG 481 TTAAGCAAAA TTCCTGTTGA AGATGCTCAG ATGTTTGCCA 521 AATTGTCGTT TCTGGGGAAT TTGGCTTATT CAATCCCTAA 561 AATCAAGCCT GAGAATCTGT TGAAATATCA GAAACTGAGA 601 TTCGTTACAT CCTCAATTGA GAAGAGGATG AGTCTTAAGG 641 TTGAAGAGAA CAACAATGGC GAGGAAGATG AGGAGAAGAA 681 GAAGCTAATC AACCCTGCTG TTGCTTACAG AATCGCTGCT 721 TCTGCAGCCT CTCGTCTCTT TTCCCATTCT AAGTCTGTGC 761 TTCCTTTTGG ATCATCTAAA CGTCAAGACA ACGAAGAAGC 801 TTCTCTACTG GCTACTGCTG ATTCGGTTAC TGCAGTCGTG 841 GCAGCCAAAG AGGAAGTTAA GCAGGCCGTC GCAGATGATC 881 TCAAATCAAA CCGTTCACCG CCTTGTGAGT GGTTTGTATG 921 TGATGATGAT AAAAGCGGCA CCAGGTTCTT CTTTATTCAG 961 GGATCAGATT CACTGGCCTC ATGGCAAGCT AACCTTCTGT 1001 TCGAGCCTGT TCCATTTGAG GACCTTGATG TGCTTGTTCA 1041 CAGAGGCATA TACGAAGCTG CAAAAGGAAT ATACGAACAG 1081 ATGTTACCAG AAGTTCATGC CCACCTCAAT TCCCGTGGCA 1121 AGAACCGTGC TTTTCTCAGG TTTAGTGGAC ATTCTCTAGG 1161 CGGAAGCTTG TCATTGTTAG TGAACCTCAT GCTTCTGATA 1201 AGAGGTCAAG TCCCTGCTTC TTCTCTGCTT CCAGTGATCA 1241 CTTTTGGTTC GCCTTGCATC ATGTGCGGAG GCGATAGGCT 1281 TCTTCAGAAA CTTGGTTTGC CTAAGAGTCA TCTTCTCGGA

1321 ATCTCAATGC ATAGAGATAT TGTTCCTCGA GCATTCTCCT

1361 GCAATTACCC TAACCGAGCC GCAAAGCTTC TCAAGGCATT

1401 GAATGGAAAC TTCCGGAACC ATCCTTGTCT GAATAACCAG

1441 AATGTATTGT ATTCTCCAAT GGGGAAGCTT CTAATTCTGC

1481 AACCATCCGA GAGATTCTCT CCCCCACACC CCCTGCTTCC

1521 TCCCGGAAGT GGTCTCTATC TCTTAGCATC TAAGAATACC

1561 GATGAAACAG AGAAAAGTCT AAGGGCTGCA AAGATTCTCT

1601 TCTTTAACTC ACCACACCCC CTAGAGATTC TCAGTGATCG

1641 TCGTTCTTAC GGGTCGGAAG GAAAAATCAA AAGAAACCAT

1681 GACATGAGCT CTTACCTGAA GGCCTTGAGG CATGTGATCC

1721 GGAAGGAGCT GAAGCAGATG AAAGCTGAGC GGGATCAATG

1761 GCTGCGCAAG TTCTTTATTA TAAACATTTT ATTTAGTGGG

1801 AGAGATTCTT TGAAACTCAT AACAAGATTC GTGGCATCAA

1841 GGAGTAGTCA ACTAGTGATC ATCTTCTTTC TCCCAATTAG

1881 ATTGTTAATA ATGAGTGTCT ACAGTGTGGT CTTTCACCAT

1921 TCACAAGCAC ATTTTAGTTT CTTCAAGTGA

Another PLIP3-related lipase protein from Arabidopsis lyrata with SEQ ID NO:23 shares at least 92% sequence identity with the SEQ ID NO:21 PLIP3 protein as illustrated below.

Seq21 8 MSVVGV-SPMIPVGP SSFICAIGGSVEEKSTAASLPRWVSLRRLRPLEFLRIGGKREEKG Seq23 1 MSVQGWSPMIPVGP SSFIRAIGGSVEEKSTAGSLPRWVSRRRPRPLEFLRIGGKRDEKG

Seq21 67 TVRDDDAVLLERRDRNRNENDNGNWVLKILEVGSIWKGKRQRSGGGGGGEEDEEEEVAEP Seq23 61 PVRDDAAVLLEREERVGN—DNGNWVLKILEVGSIWKGKRQRSGGG—GEEDDEEQVT ES

Seq21 127 KK-KEDLCEECDFCRIDDDDEDEEKEKTVF EFSEMLSKIPVEDAQMFAKLSFLGNLA

Seq23 117 KNDKEDLCEECDFCRVDDDDDEEEKEETVFGREEFSEMLSKVPVEDAQIFAKLSFLGNLA

Seq21 183 YSIPKIKPENLLKYQKLRFVTSSIEKRMSLKVEENNNGEEDEEKKKLINPAVAYRIAASA Seq23 177 YSIPKIKPDNLLKYQKLRFVTSSIEKRTSLKVEENNNGEEEEEKKKLINPAVAYRIAASA

Seq21 243 ASRLFSHSKSVLPFGSSKRQDNEEASLLATADSVTAWAAKEEVKQAVADDLKSNRSPPC Seq23 237 ASRLFSHSKSVLPFGSSKRQDNEEASLLATADSVTAWAAKEEVKQAVADDLKSNRSPPC

Seq21 303 EWFVCDDDKSGTRFFFIQGSDSLASWQANLLFEPVPFEDLDVLVHRGIYEAAKGIYEQML Seq23 297 EWFVCDDDKSGTRFFFIQGSDSLASWQANLLFEPVPFEDLDVLVHRGIYEAAKGLYEQML

Seq21 363 PEVHAHLNSRGKNRAFLRFSGHSLGGSLSLL LMLLIRGQVPASSLLPVITFGSPCIMC Seq23 357 PEVHAHLNSRGRHRAFLRFSGHSLGGSLSLL LMLLIRGQVPASSLLPVITFGSPCIMC

Seq21 423 GGDRLLQKLGLPKSHLLGISMHRDIVPRAFSCNYPNRAAKLLKALNGNFRNHPCLNNQNV Seq23 417 GGDRLLQKLGLPKSHLLGISMHRDIVPRAFSCNYPNRAANILKALNGNFRNHPCLNNQNV Seq21 483 LYSPMGKLLILQPSERFSPPHPLLPPGSGLYLLASKNTDETEKSLRAAKILFFNSPHPLE Seq23 477 LYSPMGKLLILQPSERFSPPHPLLPPGSGIYLLTSKNTDETEKSLRAAKSVFFNSPHPLE

Seq21 543 ILSDRRSYGSEGKIKRNHDMS SYLKALRHVIRKELKQMKAERDQWLRKFFIINILFSGRD Seq23 537 ILSDRRSYGSEGKIKRNHDMS SYLKALRHVIRKELKQIKAERDQWRRKFFIINILFTGRD

Seq21 603 SLKLITRFVASRSSQLVIIFFLPIRLLIMSVYSWFHHSQAHFSFFK

Seq23 597 SLKLITRFVASRSSQLVIIFFLPIRLLIMNVYGWFHHSQAHFSFFK

This PLIP3-related lipase protein from Arabidopsis lyrata with SEQ ID NO:23 has accession number XP_002878465.1 and the SEQ ID NO:23 amino acid sequence is shown below.

1 MSVQGVVSPM IPVGPSSFIR AIGGSVEEKS TAGSLPRWVS 41 RRRPRPLEFL RIGGKRDEKG PVRDDAAVLL EREERVGNDN

81 GNWVLKILEV GSIWKGKRQR SGGGGEEDDE EQVTESKNDK

121 EDLCEECDFC RVDDDDDEEE KEETVFGREE FSEMLSKVPV

161 EDAQIFAKLS FLGNLAYSIP KIKPDNLLKY QKLRFVTSSI

201 EKRTSLKVEE NNNGEEEEEK KKLI PAVAY RIAASAASRL

241 FSHSKSVLPF GSSKRQDNEE ASLLATADSV TAVVAAKEEV

281 KQAVADDLKS NRSPPCEWFV CDDDKSGTRF FFIQGSDSLA

321 SWQANLLFEP VPFEDLDVLV HRGIYEAAKG LYEQMLPEVH

361 AHLNSRGRHR AFLRFSGHSL GGSLSLLVNL MLLIRGQVPA

401 SSLLPVITFG SPCIMCGGDR LLQKLGLPKS HLLGISMHRD

441 IVPRAFSCNY PNRAANILKA LNGNFRNHPC LNNQNVLYSP

481 MGKLLI LQPS ERFSPPHPLL PPGSGIYLLT SKNTDETEKS

521 LRAAKSVFFN SPHPLEILSD RRSYGSEGKI KRNHDMSSYL

561 KALRHVIRKE LKQIKAERDQ WRRKFFI INI LFTGRDSLKL

601 ITRFVASRSS QLVIIFFLPI RLLIMNVYGV VFHHSQAHFS

641 FFK

Another PLIP3-related lipase protein from Brassica napus with SEQ ID NO:24 shares at least 82% sequence identity with the SEQ ID NO:21 PLIP3 protein as illustrated below.

Seq21 3 GVFLKMSWGVSPMIPVGPSSFICAIGGSVEEKSTAASLPRWVSLRRLRPLEFLRIGGKR Seq24 4 GVFLKMSVQCVSPKIPVGPS-MIRAIGGSVEERRTSGSLPRRVSRR PLEFLRIGGKG

Seq21 63 EEKGTVRDDDAVLLERRDRNRNENDNGNWVLKILEVGSIWKGKRQRSGGGGGGEEDEEEE Seq24 60 RKESARDDNDAVLLEREERN GNWVLKILEVGSIWKGKRQRSGGGDG—EDEEEG

Seq21 123 VAEPKKKEDLCEECDFCRIDDDDEDEEKEKTVFEFSEMLSKIPVEDAQMFAKLSFLGNLA Seq24 112 SKKD ESCDFCRIDDE-EEEEMVFDRENFSKMLMKIPLDDAQMFAKLSYLGNLA Seq21 183 YSIPKIKPENLLKYQKLRFVTSSIEKRMSL-KVEENNNGEEDEEKKKLINPAVAYRIAAS Seq24 164 YSIPNIKPENLLKYQKLRFVTSSIEKRSSLDQQDEISNEEEEEEEKKLINPAAAYRIAAS Seq21 242 AASRLFSHSKSVLPFGSSKRQDNEEASLLATADSVTAWAAKEEVKQAVADDLKSNRSPP Seq24 224 AASRLFSHSKSVLPFG RRENE-ASLMATADSVTAWAAEEEVKQAVADDLKSNHSPP

Seq21 302 CEWFVCDDDKSGTRFFFIQGSDSLASWQANLLFEPVPFEDLDVLVHRGIYEAAKGIYEQM Seq24 280 CEWFVCDDDKTSTRFFFIQGSDSLASWQANLLFEPVPFEDFDVPVHRGIYEAAKGIYEQM Seq21 362 LPEVHAHLNSRGKNRAFLRFSGHSLGGSLSLLVNLMLLIRGQVPASSLLPVITFGSPCIM Seq24 340 LPEVHAHLNSRGKNRAFLRFSGHSLGGSLSLLVNLMLLIRGQVPASSLLPVITFGSPCIM

Seq21 422 CGGDRLLQKLGLPKSHLLGISMHRDIVPRAFSCNYPNRAAKLLKALNGNFRNHPCLNNQN Seq24 400 CGGDRLLEKLGLPKSHLLGISMHRDIVPRAFSCSYPNRAAKLLKALNRNFRNHPCLNNQN

Seq21 482 VLYSPMGKLLILQPSERFSPPHPLLPPGSGLYLLASKNTDETEKSLRAAKILFFNSPHPL Seq24 460 LLYSPMGKLLILQPSERFSPPHPLLPPGSGLYVLTSKNTDETEKGLRAAKTVFFNSPHPL

Seq21 542 EILSDRRSYGSEGKIKRNHDMSSYLKALRHVIRKELKQMKAERDQWLRKFFIINILFSGR Seq24 520 EILSDRRSYGSEGKIKRNHDMSSYLKALRHVIRKELKQIKAERDQWRAKFLIVNIICTGR

Seq21 602 DSLKLITRFVASRSSQLVIIFFLPIRLLIMSVYSWFHHSQAHF-SFFK

Seq24 580 DSLKLIARFVASRSSQLVIIFFLPIRLLTTSVYGVLLHHSHEHFFSFFK

This PLIP3-related lipase protein from Brassica napus with SEQ ID NO:24 has accession number CDY11429.1 and the SEQ ID NO:24 amino acid sequence is shown below.

1 MDSGVFLKMS VQCVSPKIPV GPSMIRAIGG SVEERRTSGS 41 LPRRVSRRPL EFLRI GGKGR KESARDDNDA VLLEREERNG

81 NWVLKILEVG SIWKGKRQRS GGGDGEDEEE GSKKDESCDF

121 CRIDDEEEEE MVFDRENFSK MLMKIPLDDA QMFAKLSYLG

161 NLAYSIPNIK PENLLKYQKL RFVTSSIEKR SSLDQQDEIS

201 NEEEEEEEKK LINPAAAYRI AASAASRLFS HSKSVLPFGR

241 RENEASLMAT ADSVTAWAA EEEVKQAVAD DLKSNHSPPC

281 EWFVCDDDKT STRFFFIQGS DSLASWQANL LFEPVPFEDF

321 DVPVHRGIYE AAKGIYEQML PEVHAHLNSR GKNRAFLRFS

361 GHSLGGSLSL LVNLMLLIRG QVPASSLLPV ITFGSPCIMC

401 GGDRLLEKLG LPKSHLLGIS MHRD IVPRAF SCSYPNRAAK

441 LLKALNRNFR NHPCLNNQNL LYSPMGKLLI LQPSERFSPP

481 HPLLPPGSGL YVLTSKNTDE TEKGLRAAKT VFFNSPHPLE

521 I LSDRRSYGS EGKIKRNHDM SSYLKALRHV IRKELKQIKA

561 ERDQWRAKFL IVNIICTGRD SLKLIARFVA SRSSQLVIIF

601 FLPIRLLTTS VYGVLLHHSH EHFFSFFK

Another PLIP3-related lipase protein from Zea mays with SEQ ID NO:25 shares at least 48% sequence identity with the SEQ ID NO:21 PLIP3 protein as illustrated below. Seq21 222 EDEEKKKLINPAVAYRIAASAASRLFSHSKSVLPFGSSK—RQD

Seq25 257 QENQSGQGINPLAAYRIAASAASYMQSRAMEVLPFGSQNEARRDVRTIQAIVNAQTEGLT Seq21 264 NEEASLLATADSVTAWAAKEEVKQAVADDLKSNRSPPCEWFVCDDDKSGTRFFFIQGSD Seq25 317 MDEASFVATTNSMTSMVAAKEETKQAVADDLNS SRSCPCEWFICDGNRNSTRYFVIQGSE

Seq21 324 SLASWQANLLFEPVPFEDLDVLVHRGIYEAAKGIYEQMLPEVHAHLNSRGKNRAFLRFSG Seq25 377 TIASWQANLLFEPIKFEGLDVLVHRGIYEAAKGIYQQMLPYVKSHFIVHGES-ARLRFTG

Seq21 384 HSLGGSLSLLVNLMLLIRGQVPASSLLPVITFGSPCIMCGGDRLLQKLGLPKSHLLGISM Seq25 436 HSLGGSLALLVNLMFLIRGVAPAASLLPVITFGSPSVMCGGDYLLQKLGLPKSHVQSVTL

Seq21 444 HRDIVPRAFSCNYPNRAAKLLKALNGNFRNHPCLNNQNVLYSPMGKLLILQPSERFSPPH Seq25 496 HRDIVPRAFSCHYPDHIASILKLVNGNFRSHPCLTNQKLLYAPMGEVFILQPDEKLSPHH

Seq21 504 PLLPPGSGLYLLASKNTDETEKS—LRAAKILFFNSPHPLEILSDRRSYGSEGKIKRNH D Seq25 556 HLLPAGSGLYLIGGQTVDSGTSSTALRSALSAFFNSPHPLEILRDAGAYGPKGTVYRDHD Seq21 562 MSSYLKALRHVIRKELKQMKAERDQWLRKFFIINILFSGRDSLKLITRFVASRSSQLVI I Seq25 616 VHSYLRSIRAWRKEMRAEK-ERRRLLRWPIEVYGALATIDRRQVLRQL—RRHAHLLVV

Seq21 622 FFLPIRLLIMSVYSVV

Seq25 673 FLLPAKLLFLGVLSLI

This PLIP3-related lipase protein from Zea mays with SEQ ID NO:25 has accession number NP_001148192.1 and the SEQ ID NO:25 amino acid sequence is shown below.

1 MDVLRFVPGV RPPLPTFATP VSPATAPSPH AAAAAAAPGP

41 GFHSGMLGLW PRRAGENALG AAAEAAGVEE ARERRRRRAV

81 EAEDGRGGNW VLQILRVQSS PPPSPSRDDG RCGVDDGGSV

121 PGSGEGDGSS QRCVERGGVG PDSEEGCSVA DGEELDRAAF

161 SRLLRKVSLA EAKLFSEMSG LCNLAYMVPR IKPRYLHKYN

201 MTFVTS SVEE RAKLPNPCNQ EDQNLNGRKN ANISTSSRHS

241 DEQESTYGAT SEHERMQENQ SGQGINPLAA YRIAASAASY

281 MQSRAMEVLP FGSQNEARRDVRTIQAIVNAQ TEGLTMDEAS

321 FVATTNSMTS MVAAKEETKQ AVADDLNSSR SCPCEWFICD

361 GNRNSTRYFV IQGSETIASW QANLLFEP IK FEGLDVLVHR

401 GIYEAAKGIY QQMLPYVKSH FIVHGESARL RFTGHSLGGS

441 LALLVNLMFL IRGVAPAASL LPVITFGSPS VMCGGDYLLQ

481 KLGLPKSHVQ SVTLHRDIVP RAFSCHYPDH IAS ILKLVNG

521 NFRSHPCLTN QKLLYAPMGE VFILQPDEKL SPHHHLLPAG

561 SGLYLIGGQT VDSGTSSTAL RSALSAFFNS PHPLEILRDA

601 GAYGPKGTVY RDHDVHSYLR SIRAWRKEM RAEKERRRLL

641 RWPIEVYGAL ATIDRRQVLR QLRRHAHLLV VFLLPAKLLF

681 LGVLSLIRPT Another PLIP3-related lipase protein from Zea mays with SEQ ID NO:26 shares at least 49% sequence identity with the SEQ ID NO:21 PLIP3 protein as illustrated below.

Seq21 77 ERRDRNRNENDNGNWVLKILEVGSIWKGKRQRSGGGGGGEEDEEEEVAEPKKKEDLCEEC Seq26 63 EERKAEGAQRGQGNWVLQMLRVQPRWVDAADAEATGGGQEPDEETAAAAAAGAGGV-EEC

Seq21 137 DFCRIDDDDED EEKEKTVFE FSEMLSKIPVEDAQMFAKLSFLGNLAYSIPKI

Seq26 122 ASCGCGEDDEGCAVGYGDGDGEVFDRASFSRLLRKASLGEAKEYS MSYLCNIAYMIPRI

Seq21 189 KPENLLKYQKLRFVTSSIEKRMSL KVEENNNGEEDEEKKK LI

Seq26 182 QPKCLRRYN-LRFVTSSVQDKAGVSNPDQKQERSTKKDESGDQASEAVDDAVPRRGLGTI

Seq21 231 NPAVAYRIAASAASRLFSHSKSVLPFGSSK—RQDN EEASLL

Seq26 241 KPFGAYHWSSAASYLHSRA GVMPFGPGNGVKDDHPAAVTSLVSGASGDGLSVDEASFV

Seq21 271 ATADSVTAVVAAKEEVKQAVADDLKSNRSPPCEWFVCDDDKSGTRFFFIQGSDSLASWQA Seq26 301 ATTSSVTSMVAAKEETRQAVADDLNSSRSCPCEWFVCEDDQNSTIYFWQGSESIASWQA

Seq21 331 NLLFEPVPFEDLDVLVHRGIYEAAKGIYEQMLPEVHAHLNSRGKNRAFLRFSGHSLGGSL Seq26 361 NLLFEPVKFEEVDVLVHRGIYEAAKGMYHQMLPYVKAHLKSWGKS-ARLRFTGHSLGGSL

Seq21 391 SLL LMLLIRGQVPASSLLPVITFGSPCIMCGGDRLLQKLGLPKSHLLGISMHRDIVPR Seq26 420 ALL LMLLVRGEAPASSLLPVITFGAPCIMCGGDHLLRRLGLPRSHVQSVTMHRDIVPR

Seq21 451 AFSCNYPNRAAKLLKALNGNFRNHPCLNNQNVLYSPMGKLLILQPSERFSPPHPLLPPGS Seq26 480 VFSCHYPDHVANILKLANGNFRSHPCLANQKLLYAPMGEVLILQPDERLSPHHHLLPPDS

Seq21 511 GLYLL ASKNTDETEKSLRAAKILFFNSPHPLEILSDRRSYGSEGKIKRN

Seq26 540 GIYHLGGGGGGGGAGTAANAGEGSLPQLRSALSAFFNSPHPLEILKDGAAYGPRGSVYRD Seq21 560 HDMSSYLKALRHVIRKELKQMK-AERDQW

Seq26 600 HDVNSYLRSVRAWRKEARRAREAERERW This PLIP3-related lipase protein from Zea mays with SEQ ID NO:26 has accession number NP_001169446.1 and the SEQ ID NO:26 amino acid sequence is shown below.

1 MDVLRFVRAA AAPQPAVAPP ASAATVPAQR QRLRMWPRGG 41 GDQPPPVGAA STRGAEPRSP PDEERKAEGA QRGQGNWVLQ

81 MLRVQPRWVD AADAEATGGG QEPDEETAAA AAAGAGGVEE

121 CASCGCGEDD EGCAVGYGDG DGEVFDRASF SRLLRKASLG

161 EAKEYSMMSY LCNIAYMIPRIQPKCLRRYN LRFVTSSVQD

201 KAGVSNPDQK QERSTKKDES GDQASEAVDD AVPRRGLGTI

241 KPFGAYHWS SAASYLHSRA MGVMPFGPGN GVKDDHPAAV

281 TSLVSGASGD GLSVDEASFV ATTSSVTSMV AAKEETRQAV 301 ADDLNS SRSC PCEWFVCEDD QNSTIYFVVQ GSESIASWQA 361 NLLFEPVKFE EVDVLVHRGI YEAAKGMYHQ MLPYVKAHLK 401 SWGKSARLRF TGHSLGGSLA LLVNLMLLVR GEAPASSLLP 441 VITFGAPCIM CGGDHLLRRL GLPRSHVQSV TMHRDIVPRV 481 FSCHYPDHVA NILKLANGNF RSHPCLANQK LLYAPMGEVL 521 I LQPDERLSP HHHLLPPDSG IYHLGGGGGG GGAGTAANAG 561 EGSLPQLRSA LSAFFNSPHP LEILKDGAAY GPRGSVYRDH 601 DVNSYLRSVR AWRKEARRA REAERERWRL LLWWPFGVHG 641 VSSASAGRRG GLVDAVSEAA RRAHLLLVVL LPAELLALGA 681 LLAVIRFR

Another PLIP3-related lipase protein from Glycine max with SEQ ID NO:27 shares at least 51-58% sequence identity with the SEQ ID NO:21 PLIP3 protein as illustrated below.

Seq21 85 ENDNGNWVLKILEVGSIWKGKRQRSGGGGGGEEDEEEEVAEPKKKEDLCEECDFCRIDDD Seq27 93 ERQTGNWVLKILHVKSLWEGK QRDEEEGSVRDQTQTNYEEEEEVCECDAC

Seq21 145 DEDEEKEKTVFEFSEMLSKIPVEDAQMFAKLSFLGNLAYSIPKIKPENLLKYQKLRFVTS Seq27 143 DEVEEAQFDRGSFSRMLRRVSLAESRLYAQMSHLGNLAYDIPRIKPGKLLKHYGLRFVTS

Seq21 205 SIEKRMSL KVEENNNGEEDEEKKK LINPAVAYRIAASAASRLFS

Seq27 203 SIEKKELAVAATAEKDPQKVQTDEKVDEKEERKDPKNGEYKISATAAYNIAASAATYLHS

Seq21 249 HSKSVLPFGSSKRQ DNEEASLLATADSVTAWAAKEEVKQA

Seq27 263 QTRSIFPLKSSNAVAGEGSLAGNNESLDSVNMLNTEVASLMATTDSVTAWAAKEEVKQA

Seq21 290 VADDLKSNRSPPCEWFVCDDDKSGTRFFFIQGSDSLASWQANLLFEPVPFEDLDVLVHRG Seq27 323 VADDLNSSHSTPCEWFVCDNDQSGTRFFVIQGSETLASWQANLLFEP IKFEGLDVLVHRG

Seq21 350 IYEAAKGIYEQMLPEVHAHLNSRGKNRAFLRFSGHSLGGSLSLLVNLMLLIRGQVPASSL Seq27 383 IYEAAKGIYQQMLPEVHAHLKSRG-SRATFRFTGHSLGGSLALLVNLMLLIRHEVPISSL Seq21 410 LPVITFGSPCIMCGGDRLLQKLGLPKSHLLGISMHRDIVPRAFSCNYPNRAAKLLKALNG Seq27 442 LPVITFGSP SIMCGGDSLLEKLGLPKSHVQAITMHRDIVPRAFSCNYPNHVAELLKAVNG

Seq21 470 NFRNHPCLNNQNVLYSPMGKLLILQPSERFSPPHPLLPPGSGLYLLAS—KNTDETEKS L Seq27 502 NFRSHPCLNKQKLLYAPMGNLLILQPDEKFSPSHHLLPSGSGLYLLCCPLSESNDTEKQL

Seq21 528 RAAKILFFNSPHPLEILSDRRSYGSEGKIKRNHDMSSYLKALRHVIRKELKQMKAERDQW Seq27 562 RAAQMVFLNSPHPLEILSDRSAYGSGGSVQRDHDMNSYLKSVRTVIRQELNQIRKAKREQ

Seq21 588 LRKFFIINILFSGRDS

Seq27 622 RRKVWWPLLLPRGVDT This PLIP3-related lipase protein from Glycine max with SEQ ID NO:27 has accession number XP_014619726.1 and the SEQ ID NO:27 amino acid sequence is shown below.

1 METMCLKSGI VPTISISGSL DARANPSQVS TVGRSASDKP 41 PQRSVFSRFS FWYPLESLWP RGNNSRYKGL ALDDAVLSDN

81 NAEAKAVGDD GTERQTGNWV LKILHVKSLW EGKQRDEEEG

121 SVRDQTQTNY EEEEEVCECD ACDEVEEAQF DRGSFSRMLR

161 RVSLAESRLY AQMSHLGNLA YDIPRIKPGK LLKHYGLRFV

201 TSSIEKKELA VAATAEKDPQ KVQTDEKVDE KEERKDPKNG

241 EYKISATAAY NIAASAATYL HSQTRSIFPL KSSNAVAGEG

281 SLAGNNESLD SVNMLNTEVA SLMATTDSVT AVVAAKEEVK

321 QAVADDLNSS HSTPCEWFVC DNDQSGTRFF VIQGSETLAS

361 WQANLLFEPI KFEGLDVLVH RGIYEAAKGI YQQMLPEVHA

401 HLKSRGSRAT FRFTGHSLGG SLALLVNLML LIRHEVPISS

441 LLPVITFGSP SIMCGGDSLL EKLGLPKSHV QAITMHRDIV

481 PRAFSCNYPN HVAELLKAVN GNFRSHPCLN KQKLLYAPMG

521 NLLILQPDEK FSPSHHLLPS GSGLYLLCCP LSESNDTEKQ

561 LRAAQMVFLN SPHPLEILSD RSAYGSGGSV QRDHDMNSYL

601 KSVRTVIRQE LNQIRKAKRE QRRKVWWPLL LPRGVDTSIV

641 AGRSMISINV GQRQSPFSGV IQTGRESLKR FSRWTSQHM

681 HLFVLLLFPA RLLLLGTYSV INLK

FAD4

Fatty acid desaturases are involved in the production of chloroplast-specific phosphatidylglycerol molecular species containing 16:1 (number of carbons : number of bond). These enzymes can catalyze the formation of a trans double bond introduced close to the carboxyl group of palmitic acid, which is specifically esterified to the sn-2 glyceryl carbon of phosphatidylglycerol. Expression of the FATTY ACID DESATURASE4 (FAD4) can facilitate lipid accumulation in plants.

Transgenic plants, plant cells, and/or seeds can include expression cassettes having a nucleic acid segment encoding a FAD4 protein in addition to one or more lipase expression cassettes. For example, an Arabidopsis thaliana FAD4 amino acid sequence with accession number At4g27030 is shown below as SEQ ID NO:28.

1 MAVSLPTKYP LRPITNIPKS HRPSLLRVRV TCSVTTTKPQ PNREKLLVEQ

51 RTVNLPLSND QSLQSTKPRP NREKLWEQR LASPPLSNDP TLKSTWTHRL

101 WVAAGCTTLF VSLAKSVIGG FDSHLCLEPA LAGYAGYILA DLGSGVYHWA

151 IDNYGDESTP VVGTQIEAFQ GHHKWPWTIT RRQFANNLHA LAQVITFTVL

201 PLDLAFNDPV FHGFVCTFAF CILFSQQFHA WAHGTKSKLP PLVVALQDMG 251 LLVSRRQHAE HHRAPYNNNY CIVSGAWNNV LDESKVFEAL EMVFYFQLGV

301 RPRSWSEPNS DWIEETEISN NQA A nucleotide sequence encoding the SEQ ID NO:28 FAD4 protein is available as accession number NM_118837.2 and shown below as SEQ ID NO:29.

1 TTTGACAACT TTCACCTGCA ATCACTCTCA ATGGCTGTAT

41 CACTTCCAAC CAAGTACCCT CTACGACCTA TCACCAACAT 81 CCCAAAAAGC CACCGTCCCT CGCTTCTCCG TGTACGTGTC

121 ACCTGCTCTG TTACTACCAC CAAGCCTCAG CCTAATCGTG

161 AGAAGCTTCT GGTAGAGCAA CGCACTGTGA ATCTTCCTCT

201 GTCCAACGAC CAATCTCTGC AATCGACCAA GCCTCGCCCT

241 AACCGTGAGA AGCTTGTGGT TGAGCAACGC CTTGCCAGCC 281 CTCCTCTGTC CAATGACCCA ACTTTGAAAT CGACATGGAC

321 TCACCGGTTA TGGGTTGCAG CGGGCTGCAC CACTTTGTTT

361 GTCTCTTTAG CTAAATCTGT CATTGGAGGG TTTGATTCTC

401 ATCTCTGCCT CGAACCAGCT TTAGCCGGTT ATGCAGGGTA

441 CATCTTAGCT GATCTAGGTT CCGGTGTCTA CCACTGGGCC 481 ATTGATAACT ACGGTGATGA GTCAACACCT GTAGTAGGAA

521 CCCAAATCGA AGCATTTCAG GGTCACCACA AGTGGCCTTG

561 GACAATCACC AGACGGCAAT TTGCCAACAA TCTACACGCT

601 CTGGCTCAAG TCATAACCTT CACAGTTCTT CCACTAGACC

641 TTGCATTTAA CGACCCTGTG TTTCACGGCT TTGTGTGCAC 681 ATTTGCATTT TGCATATTGT TTAGCCAGCA ATTCCATGCT

721 TGGGCACATG GAACCAAGAG CAAGCTTCCA CCTCTCGTGG

761 TCGCGTTGCA GGACATGGGG TTACTTGTTT CACGGAGACA

801 GCATGCGGAA CATCATCGAG CACCGTATAA CAACAATTAC

841 TGCATCGTGA GTGGAGCATG GAACAATGTT CTGGATGAGA 881 GTAAGGTCTT TGAGGCATTG GAGATGGTGT TTTATTTCCA

921 GCTTGGGGTG AGACCTAGGT CATGGAGTGA GCCAAACTCT

961 GACTGGATAG AAGAAACCGA AATCTCCAAC AACCAAGCAT

1001 AAATATTTTT TTTACAGAGT GATACATGTA CAAGAAAATT

1041 TCAGTAATAT ACTGAAAAGA TTTCTTCGTA ATTTATATGT 1081 AACGAGTGTG ACTGTATTTA ATACTGTATA AAACAAGCAA

1121 AACAACTGAG CATGTACCAT TTAAGTATCA

A related FAD4 protein from Brassica napus with SEQ ID NO:30 shares at least about 79% sequence identity with the SEQ ID NO:28 protein as illustrated below.

Seq28 1 MAVSLPTKYPLRPITN-IPKSHRPSLLRVRVTCSVTTTKPQPNREKLLVEQRT LPLSN Seq30 1 MAVSLQTKYPLRPITNNIPSTHRYSLLHVRVTCSATTTTNKP

Seq28 60 DQSLQSTKPRPNREKLVVEQRLASPPLSNDPTLKSTWTHRLWVAAGCTTLFVSLAKSVIG Seq30 43 QAKLWENRFMSPPLSNDPSLQSTWTHRLWVAAGCTTLFASLSKSIIG

Seq28 120 GFDSHLCLEPALAGYAGYILADLGSGVYHWAIDNYGDESTPWGTQIEAFQGHHKWPWTI Seq30 91 GVGSHLWLEPALAGYAGYILADLGSGVYHWAIDNYGDESTP IVGTQIEAFQGHHKWPWTI

Seq28 180 TRRQFANNLHALAQVITFTVLPLDLAFNDPVFHGFVCTFAFCILFSQQFHAWAHGTKSKL Seq30 151 TRRQFANNLHALARVITFTVLPLDLAFNDPWHGFVSTFAFCIMFSQQFHAWAHGTKSKL

Seq28 240 PPLWALQDMGLLVSRRQHAEHHRAPYNNNYCIVSGAWNNVLDESKVFEALEMVFYFQLG Seq30 211 PPLWALQDMGVLVSRREHAEHHRAPYNNNYCIVSGAWNKVLDESKVFEALEMVLYFKLG

Seq28 300 VRPRSWSEPNSDWIEETEISNN

Seq30 271 VRPRSWSEPNSEWTEEKDISNN

This FAD4 protein from Brassica napus with SEQ ID NO:30 has

XP_013709030. land the SEQ ID NO:30 amino acid sequence is shown below.

1 MAVSLQTKYP LRPITNNIPS THRYSLLHVR VTCSATTTTN

41 KPQAKLWEN RFMSPPLSND PSLQSTWTHR LWVAAGCTTL

81 FASLSKSIIG GVGSHLWLEP ALAGYAGYIL ADLGSGVYHW

121 AIDNYGDEST PIVGTQIEAF QGHHKWPWTI TRRQFANNLH

161 ALARVI TFTV LPLDLAFNDP WHGFVSTFA FCIMFSQQFH

201 AWAHGTKSKL PPLWALQDM GVLVSRREHA EHHRAPYNNN

241 YCIVSGAWNK VLDESKVFEA LEMVLYFKLG VRPRSWSEPN

281 SEWTEEKDIS NNHKV Another related FAD4 protein from Zea mays with SEQ ID NO:31 shares at least about 54% sequence identity with the SEQ ID NO:28 protein as illustrated below.

Seq28 92 LKSTWTHRLWVAAGCTTLFVSLAKSV-IGGFDSHLCLEPALAGYAGYILADLGSGVYHWA Seq31 48 LRSTWPQRAWTLAGTAAILSSLSTSASLAASGSGSPAEP IAAALAAYSLADLATGVYHWF

Seq28 151 IDNYGDESTPWGTQIEAFQGHHKWPWTITRRQFANNLHALAQVITFTVLPLDLAFN

Seq31 108 VDNYGDAATPVFGSQIAAFQGHHRYPSTITLRETCNNLHALARGAALALAPVDAALSATG Seq28 208 -DPVFHGFVCTFAFCILFSQQFHAWAHGTKSKLPPLWALQDMGLLVSRRQHAEHHRAPY Seq31 168 APAAAHAFVGAFTACWLSQQFHAWAHEKRRRLPPGVEALQDAGVLVSRAQHAAHHRQPY

Seq28 267 NNNYCIVSGAWNNVLDESKVFEALEMVFYFQLGVRPRSWSEPNSDWIEET

Seq31 228 NTNYCIVSGMWNGLLDRYKVFEALEMVVYFRTGIRPRSWGETDASWKEDT

This FAD4 protein from Zea mays with SEQ ID NO:31 has XP_008662704.1 and the SEQ ID NO:31 amino acid sequence is shown below.

1 MYTLIPRCHL QPVHRSPPPC QAATTTSSAP PSPSPSLSIR

41 FRPDQDELRS TWPQRAWTLA GTAAILSSLS TSASLAASGS

81 GSPAEP IAAA LAAYSLADLA TGVYHWFVDN YGDAATPVFG

121 SQIAAFQGHH RYPST ITLRE TCNNLHALAR GAALALAPVD

161 AALSATGAPA AAHAFVGAFT ACWLSQQFH AWAHEKRRRL

201 PPGVEALQDA GVLVSRAQHA AHHRQPYNTN YCIVSGMWNG

241 LLDRYKVFEA LEMWYFRTG IRPRSWGETD ASWKEDTGAE

281 AAAAAAS AG LLQTAGISSD SD Another related FAD4 protein from Zea mays with SEQ ID NO:32 shares about 47% sequence identity with the SEQ ID NO:28 protein as illustrated below.

Seq28 92 LKSTWTHRLWVAAGCTTLFVSLAKS—VIGGFDSHLC—LEPALAGYAGYILADLGSG VY Seq32 15 VRSTWLQRAWTLAGTAAILMSFFTTARLVAASSTWTDSLAVALAVWAAYSVADLTTGVY

Seq28 148 HWAIDNYGDESTPWGTQIEAFQGHHKWPWTITRRQFANNLHALAQVITFTVLPLDLAF- Seq32 75 HWFIDNYGDAGTPVFGAQIVAFHDHHVHPTAITRLEPCNSLHVIAGTVAVALPAVDAALL

Seq28 207 NDPVFHGFVCTFAFCILFSQQFHAWAHGTKSKLPPLWALQDMGLLVSRRQHAE

Seq32 135 YFAGGSSPAAAHAFACTFAVCVMLSVQFHAWAHERPSRLPPGVEALQAAGVLVSRSQHAG

Seq28 261 HHRAPYNNNYCIVSGAWNNVLDESKVFEALEMVFYFQLGVRPRSW

Seq32 195 HHRPPYNSNYCTVSGMWNWALDGYKVFLAVEKVIYLATGAPPRSW

This FAD4 protein from Zea mays with SEQ ID NO:32 has XP_008663953.1 and the SEQ ID NO:32 amino acid sequence is shown below. 1 MSATPSGDVP DELRVRSTWL QRAWTLAGTA AILMSFFTTA

41 RLVAASSTW TDSLAVALAV WAAYSVADLT TGVYHWFIDN

81 YGDAGTPVFG AQIVAFHDHH VHPTAITRLE PCNSLHVIAG

121 TVAVALPAVD AALLYFAGGS SPAAAHAFAC TFAVCVMLSV

161 QFHAWAHERP SRLPPGVEAL QAAGVLVSRS QHAGHHRPPY

201 NSNYCTVSGM WNWALDGYKV FLAVEKVIYL ATGAPPRSWR

241 MKMTEHGV

Another related FAD4 protein from Glycine max with SEQ ID NO:33 shares at least about 62-72% sequence identity with the SEQ ID NO:28 protein as illustrated below.

Seq28 85 PLSNDPTLKSTWTHRLWVAAGCTTLFVSLAKSVIGGFDSHLCLEPALAGYAGYILADLGS Seq33 69 PMNNDPSLQSTWSHRAWVAAGCTTLLI SLGESIKGAMDLNMWAEPILAGWVGYILADLGS Seq28 145 GVYHWAIDNYGDESTPWGTQIEAFQGHHKWPWTITRRQFANNLHALAQVITFTVLPLDL Seq33 129 GVYHWAIDNYGDASIPIVGTQIEAFQGHHKWPWTITKRQFANNLHALARAVTFTVLPIVL

Seq28 205 AFNDPVFHGFVCTFAFCILFSQQFHAWAHGTKSKLPPLVVALQDMGLLVSRRQHAEHHRA Seq33 189 LCHDPIVEGFVGMCSGCIMFSQQFHAWSHGTKSRLPPLVVALQEAGVLVSRSQHAAHHRP

Seq28 265 PYNNNYCIVSGAWNNVLDESKVFEALEMVFYFQLGVRPRSWSEPNSDWIEETE

Seq33 249 PYNNNYCIVSGVWNEFLDKHKVFEALEMVLYFKTGVRPRSWSETASEWIEEIE

** ** ********* ** ********* * **** * This FAD4 protein from Glycine max with SEQ ID NO:33 has XP_003551889.1 and the SEQ ID NO:33 amino acid sequence is shown below.

1 MYSLAQHKYI PRFHLQACKN HPPHHPSSPV FCSTTTTTSR

41 DKPNPKPLVI EPWLVPVPPT WTADNPRPM NNDPSLQSTW

81 SHRAWVAAGC TTLLI SLGES IKGAMDLNMW AEPILAGWVG

121 YILADLGSGV YHWAIDNYGD ASIPIVGTQI EAFQGHHKWP

161 WTITKRQFAN NLHALARAVT FTVLPIVLLC HDP IVEGFVG

201 MCSGCIMFSQ QFHAWSHGTK SRLPPLWAL QEAGVLVSRS

241 QHAAHHRPPY NNNYCIVSGV WNEFLDKHKV FEALEMVLYF

281 KTGVRPRSWS ETASEWIEEI ETPSQIQAQ

Another related FAD4 protein from Glycine max with SEQ ID NO:34 shares about 65 71 % sequence identity with the SEQ ID NO:28 protein as illustrated below.

Seq28 85 PLSNDPTLKSTWTHRLWVAAGCTTLFVSLAKSVIGGFDSHLCLEPALAGYAGYILADLGS Seq34 73 PMNNDPSLQSTWSHRAWVAAGCSTLVI SLGESIKGAIDLNMWVEPIVAGWVGYILADLGS

Seq28 145 GVYHWAIDNYGDESTPWGTQIEAFQGHHKWPWTITRRQFANNLHALAQVITFTVLPLDL Seq34 133 GVYHWAIDNYGDGSTPIVGAQIEAFQGHHKWPWTITRRQFANNLHALARAVTLAVLPWL

Seq28 205 AFNDPVFHGFVCTFAFCILFSQQFHAWAHGTKSKLPPLVVALQDMGLLVSRRQHAEHHRA Seq34 193 LCHDPIVEGFVWCSGCIMFSQQFHAWSHGTKSRLPPLVVALQEAGVLVSRWQHAAHHRA

Seq28 265 PYNNNYCIVSGAWNNVLDESKVFEALEMVFYFQLGVRPRSWSEPNSDWIEETE

Seq34 253 PYNNNYCIVSGVWNEFLDKHKVFEAMEMVLYFKTGVRPRSWSEPAPEWVEEIE

This FAD4 protein from Glycine max with SEQ ID NO:34 has XP_003530742.1 and the SEQ ID NO:34 amino acid sequence is shown below.

1 MYSLAQHKYT PNFHHQVCKN HPPRHPSRVH CSTTTTTTTT

41 SRSKSNAKSL VIETRLVPVP PMPTWTTEI HRPMNNDPSL

81 QSTWSHRAWV AAGCSTLVIS LGES IKGAID LNMWVEPIVA

121 GWVGYILADL GSGVYHWAID NYGDGSTP IV GAQIEAFQGH

161 HKWPWTITRR QFANNLHALA RAVTLAVLPV VLLCHDPIVE

201 GFVWCSGCI MFSQQFHAWS HGTKSRLPPL WALQEAGVL

241 VSRWQHAAHH RAPYNNNYCI VSGVWNEFLD KHKVFEAMEM

281 VLYFKTGVRP RSWSEPAPEW VEEIETPSQI QIQTQ

Variants

Additional related lipase and/or FAD4 sequences can also be employed in expression cassettes and in the methods, seeds, plant cells, and plants described herein, including those with about at least 40% sequence identity, or at least 50% sequence identity, or at least 60% sequence identity, or at least 70% sequence identity, or 60-99% sequence identity, or 70-99% sequence identity, or 80-99% sequence identity, or 90-95% sequence identity, or 90-99% sequence identity, or 95-97% sequence identity, or 97-99% sequence identity, or 100% sequence identity (or complementarity) with any of SEQ ID NOs:l-34, 61-71.

In some cases, the lipase and/or FAD4 nucleic acid and amino acid sequences are not identical to a wild type sequence. Instead the lipase and/or FAD4 nucleic acid and amino acid sequences have at least one, or at least two, or at least three, or at least four nucleotide or amino acid substitutions, deletions, or insertions compared to the corresponding wild type lipase and/or FAD4 nucleic acid or amino acid sequence.

Related lipase and/or FAD4 sequences can be isolated from a variety of plant types such as alfalfa (e.g., forage legume alfalfa), algae, avocado, barley, broccoli, Brussels sprouts, cabbage, camelina, canola, cassava, cauliflower, coconut, cole vegetables, collards, crucifers, flax, grain legumes, grasses (e.g., forage grasses), jatropa, kale, kohlrabi, maize, miscanthus, mustards, nut sedge, oats, oil firewood trees, oilseeds, olive, palm, peanut, potato, rapeseed, radish, rice, rutabaga, safflower, sorghum, soybean, sugar beets, sugarcane, sunflower, switchgrass, tobacco, tomato, turnips, and wheat. In some embodiments, the plant is a corn, soybean, or rapeseed species. In some cases the plant is a Brassicaceae or other species. In some embodiments, the plant is not a species of Arabidopsis, for example, in some embodiments, the plant is not Arabidopsis thaliana.

As described herein, nucleic acids encoding a lipase and/or FAD4 is useful for expressing such proteins in plants. Such lipase and/or FAD4 proteins and nucleic acids can include any with at least at least 50% sequence identity, or at least 60% sequence identity, or at least 70% sequence identity, or 60-99% sequence identity, or 70-99% sequence identity, or 80-99% sequence identity, or 90-95% sequence identity, or 90-99% sequence identity, or 95-97% sequence identity, or 97-99% sequence identity, or 100% sequence identity to any of SEQ ID NO: 1-34, 61 -70 and/or 71.

If desired, the proteins with any of SEQ ID NOs:l , 3-12, 14-21 , 23-28, 30-34, 61- 70 and/or 71 can have one or more amino acid substitution, deletion, or insertion compared to its corresponding wild type amino acid sequence.

Nucleic acids with at least 50% sequence identity to those described herein (e.g., with SEQ ID NO:2, 13, 22, and/or 29) can readily be identified, isolated and used to facilitate production of increased oil content in plants. Such nucleic acids can encode or hybridize to lipase and/or FAD4 nucleic acids, or fragments thereof. These related nucleic acids can be used to increase the expression of lipase and/or FAD4 in plants. For example, related nucleic acids can be isolated and identified by mutation of the cDNA sequences encoding any of SEQ ID NOs: 1, 3-12, 14-21, 23-28, 30-34, 61-70 and/or 71 and/or by hybridization to DNA and/or RNA isolated from other plant species using nucleic acid encoding any of the SEQ ID NO: 1 , 3-12, 14-21, 23-28, 30-34, 61-70 and/or 71 as probes. Sequences of the lipase (e.g., SEQ ID NO: 1-27, 61-71) and sequences of FAD4 (e.g., SEQ ID NOs: 28-34) can also be examined and used a basis for designing alternative lipase and/or FAD4 proteins and nucleic acids.

In some embodiments, the lipase and/or FAD4 nucleic acids described herein include any nucleic acid that can selectively hybridize to a nucleic acid encoding any of the SEQ ID NO: 1-34, 61-71 protein or cDNA sequences.

Alternatively, the lipase and/or FAD4 nucleic acids (e.g., SEQ ID NO:2, 13, 22, 29) can be examined and used a basis for designing additional nucleic acids (e.g., having optimized codons or selected mutant lipase and/or selected mutant FAD4 proteins) that function in selected plant species. As illustrated herein, two point mutation alleles, where the lipase has an alanine residue at position 422 (instead of a serine PLIP1 -S422A) or at position 483 (instead of an aspartic acid PLIP1-D483A), express mutant lipase enzymes with reduced lipase activity. However, these mutant lipase proteins are useful as antigens for generating antibodies because these mutant proteins are expressed in greater amounts in some host cells than is the wild type lipase protein.

The term "selectively hybridize" includes hybridization, under stringent hybridization conditions, of a nucleic acid sequence to a specified nucleic acid target sequence (e.g., SEQ ID NO:2, 13, 22, and/or 29) to a detectably greater degree (e.g., at least 2-fold over background) than its hybridization to non-target nucleic acid sequences. Such selective hybridization substantially excludes non-target nucleic acids.

Related lipase and/or FAD4 nucleic acids sequences typically have about at least

40% sequence identity, or at least 50% sequence identity, or at least 60% sequence identity, or at least 70% sequence identity, or at least 80% sequence identity, or at least 85% sequence identity, or at least 90% sequence identity, or at least 95% sequence identity, or at least 97% sequence identity, or 60-99% sequence identity, or 70-99% sequence identity, or 80-99% sequence identity, or 90-95% sequence identity, or 90-99% sequence identity, or 95-97% sequence identity, or 97-99% sequence identity, or 100% sequence identity (or complementarity) with any of SEQ ID NO:2, 13, 22, and/or 29. In some embodiments, a selectively hybridizing sequence has about at least about 80% sequence identity or complementarity with any of SEQ ID NO: 2, 13, 22, and/or 29. The lipase and/or FAD4 nucleic acids employed in the expression vectors, transgenes, plants, plant cells, plant seeds and methods described herein can also have less than 100%, or less than 99.5%, or less than 99% sequence identity (or complementarity) with any of SEQ ID NO: 2, 13, 22, and/or 29. In other words, the lipase and/or FAD4 nucleic acids employed in the expression vectors, transgenes, plants, plant cells, plant seeds and methods described herein can also not include a wild type sequence. However, use of wild type lipase and/or FAD4 nucleic acids in the expression vectors, transgenes, plants, plant cells, plant seeds and methods described herein can also be useful.

In some embodiments, the nucleic acids used in the methods and plants provided herein can include fragments of lipase and/or FAD4 nucleic acids. For example, the nucleic acids of the invention include those with about 500 of the same nucleotides as any of the SEQ ID NO: 2, 13, 22, and/or 29 sequences, or about 700 of the same nucleotides as any of the SEQ ID NO: 2, 13, 22, and/or 29 sequences, or about 900 of the same nucleotides as any of the SEQ ID NO: 2, 13, 22, and/or 29 sequences, or about 1000 of the same nucleotides as any of the SEQ ID NO: 2, 13, 22, and/or 29 sequences, or about 1200 of the same nucleotides as any of the SEQ ID NO: 2, 13, 22, and/or 29 sequences, or about 1250 of the same nucleotides as any of the SEQ ID NO: 2, 13, 22, and/or 29 sequences, or about 1300 of the same nucleotides as any of the SEQ ID NO:2, 13, 22, and/or 29 sequences. The identical nucleotides can be distributed throughout the nucleic acid, and need not be contiguous but are present in homologous positions.

For example, the nucleic acid sequence of a lipase and/or FAD4 nucleic acids can be optimized for expression in a particular plant species by altering selected codons to encode the same amino acid but use nucleotide codons that are more easily 'read' by the transcription/translation machinery of a selected plant species.

Note that if a value of a variable that is necessarily an integer (e.g., the number of nucleotides or amino acids in a nucleic acid or protein), is described as a range, such as 80-99% sequence identity, what is meant is that the value can be any integer between 80 and 99 inclusive, i.e., 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98 or 99, or any range between 80 and 99 inclusive, e.g., 81 -99%, 81 -98%, 82-99%, etc. Moreover, if a specifically recited percent sequence identity indicates that a partial nucleotide or amino acid is present (in a nucleic acid or polypeptide) the percent sequence identity is rounded up or down so that a complete nucleotide or amino acid is present.

In some embodiments, a related nucleic acid hybridizes to at least one of the nucleic acids described herein under "stringent conditions" or "stringent hybridization conditions." The terms "stringent conditions" or "stringent hybridization conditions" include conditions under which a probe will hybridize to its target sequence to a detectably greater degree than other sequences (e.g., at least 2- fold over background). Stringent conditions are somewhat sequence-dependent and can vary in different circumstances. By controlling the stringency of the hybridization and/or washing conditions, target sequences can be hybridized that have up to 100% complementarity to the probe (homologous probing). Alternatively, stringency conditions can be adjusted to allow some mismatching in sequences so that lower degrees of sequence similarity are detected (heterologous probing).

A probe for identifying and/or isolating a related nucleic acid can be approximately

15-500 nucleotides in length, but can vary greatly in length from about 17 nucleotides to equal to the entire length of the target sequence. In some embodiments, the probe is about 10-50 nucleotides in length, or about 15-50 nucleotides in length, or about 16-45 nucleotides in length, or about 18-25 nucleotides in length.

Typically, stringent conditions will be those where the salt concentration is less than about 1.5 M Na ion (or other salts), typically about 0.01 to 1.0 M Na ion

concentration (or other salts), at pH 7.0 to 8.3 and the temperature is at least about 30 °C. for shorter probes (e.g., 10 to 50 nucleotides) and at least about 60 °C for longer probes (e.g., greater than 50 nucleotides). Stringent conditions may also be achieved with the addition of destabilizing agents such as formamide or Denhardt's solution. Exemplary low stringency conditions include hybridization with a buffer solution of 30 to 35% formamide, 1M NaCl, 1 % SDS (sodium dodecyl sulfate) at 37 °C, and a wash in 1 x SSC to 2 x SSC (where 20 x SSC is 3.0 M NaCl, 0.3 M trisodium citrate) at 50 to 55 °C.

Exemplary moderate stringency conditions include hybridization in 40 to 45 % formamide, 1M NaCl, 1% SDS at 37 °C, and a wash in 0.5 x SSC to 1 x SSC at 55 to 60 °C.

Exemplary high stringency conditions include hybridization in 50% formamide, 1M NaCl, 1 % SDS at 37° C, and a wash in 0.1 x SSC at 60 to 65 °C. Specificity is typically a function of post-hybridization washes, where the factors controlling hybridization include the ionic strength and temperature of the final wash solution. Hence, high stringency conditions include can be achieved simply by employing a wash in 0.1 x SSC at 60 to 65 °C.

For DNA-DNA hybrids, the T _m can be approximated from the equation of Meinkoth and Wahl (Anal. Biochem. 138:267-84 (1984)):

T _m = 81.5 °C + 16.6 (log M) + 0.41 (% GC) - 0.61 (% formamide) - 500/L where M is the molarity of monovalent cations; % GC is the percentage of guanosine and cytosine nucleotides in the DNA, % formamide is the percentage of formamide in the hybridization solution, and L is the length of the hybrid in base pairs. The T _m is the temperature (under defined ionic strength and pH) at which 50% of a complementary target sequence hybridizes to a perfectly matched probe. The T _m is reduced by about 1 °C for each 1% of mismatching. Thus, the T _m , hybridization and/or wash conditions can be adjusted to hybridize to sequences of the desired sequence identity. For example, if sequences with greater than or equal to 90% sequence identity are sought, the T _m can be decreased 10 °C. Generally, stringent conditions are selected to be about 5 °C lower than the thermal melting point (T _m ) for the specific sequence and its complement at a defined ionic strength and pH. However, severely stringent conditions can include hybridization and/or a wash at 1 , 2, 3 or 4° C lower than the thermal melting point (T _m ). Moderately stringent conditions can include hybridization and/or a wash at 6, 7, 8, 9 or 10 °C lower than the thermal melting point (T _m ). Low stringency conditions can include hybridization and/or a wash at 11, 12, 13, 14, 15 or 20 °C lower than the thermal melting point (T _m ). Using the equation, hybridization and wash compositions, and a desired Tm, those of ordinary skill can identify and isolate nucleic acids with sequences related to any of the SEQ ID NO: 2, 13, 22, and/or 29 sequences.

Those of skill in the art also understand how to vary the hybridization and/or wash solutions to isolate desirable nucleic acids. For example, if the desired degree of mismatching results in a T _m of less than 45 °C (aqueous solution) or 32 °C (formamide solution) it is preferred to increase the SSC concentration so that a higher temperature can be used.

An extensive guide to the hybridization of nucleic acids is found in Tijssen,

LABORATORY TECHNIQUES IN BIOCHEMISTRY AND MOLECULAR BIOLOGY -

HYBRIDIZATION WITH NUCLEIC ACID PROBES, part 1 , chapter 2, "Overview of principles of hybridization and the strategy of nucleic acid probe assays," Elsevier, N.Y. (1993); and in CURRENT PROTOCOLS IN MOLECULAR BIOLOGY, chapter 2, Ausubel, et al, eds, Greene Publishing and Wiley-Interscience, New York (1995).

Unless otherwise stated, in the present application, high stringency is defined as a wash in 0.1 x SSC, 0.1% SDS at 65 °C. High stringency hybridization can include hybridization in 4 x SSC, 5 x Denhardt's (5 g Ficoll, 5 g polyvinylpyrrolidone, 5 g bovine serum albumin in 500 ml of water), 0.1 mg/ml boiled salmon sperm DNA, and 25 mM Na phosphate at 65 °C, followed by a wash in 0.1 x SSC, 0.1 % SDS at 65 °C. The following terms are used to describe the sequence relationships between two or more nucleic acids or nucleic acids or polypeptides: (a) "reference sequence," (b) "comparison window," (c) "sequence identity," (d) "percentage of sequence identity" and (e) "substantial identity."

As used herein, "reference sequence" is a defined sequence used as a basis for sequence comparison. The reference sequence can be a nucleic acid sequence (e.g., any of the SEQ ID NO: 1-34 protein or cDNA sequences). A reference sequence may be a subset or the entirety of a specified sequence. For example, a reference sequence may be a segment of a full-length cDNA or of a genomic DNA sequence, or the complete cDNA or complete genomic DNA sequence, or a domain of a polypeptide sequence.

As used herein, "comparison window" refers to a contiguous and specified segment of a nucleic acid or an amino acid sequence, wherein the nucleic acid/amino acid sequence can be compared to a reference sequence and wherein the portion of the nucleic acid/amino acid sequence in the comparison window may comprise additions or deletions (i.e., gaps) compared to the reference sequence (which does not comprise additions or deletions) for optimal alignment of the two sequences. The comparison window can vary for nucleic acid and polypeptide sequences. Generally, for nucleic acids, the comparison window is at least 16 contiguous nucleotides in length, and optionally can be 18, 20, 30, 40, 50, 100 or more nucleotides. For amino acid sequences, the comparison window is at least about 15 amino acids, and can optionally be 20, 30, 40, 50, 100 or more amino acids. Those of skill in the art understand that to avoid a high similarity to a reference sequence due to inclusion of gaps in the nucleic acid or amino acid sequence, a gap penalty is typically introduced and is subtracted from the number of matches.

Methods of alignment of nucleotide and amino acid sequences for comparison are well known in the art. The local homology algorithm (BESTFIT) of Smith and Waterman, (1981) Adv. Appl. Math 2:482, may permit optimal alignment of compared sequences; by the homology alignment algorithm (GAP) of Needleman and Wunsch, (1970) J. Mol. Biol. 48:443-53; by the search for similarity method (Tfasta and Fasta) of Pearson and Lipman, (1988) Proc. Natl. Acad. Sci. USA 85:2444; by computerized implementations of these algorithms, including, but not limited to: CLUSTAL in the PC/Gene program by

Intelligenetics, Mountain View, Calif, GAP, BESTFIT, BLAST, FASTA and TFASTA in the Wisconsin Genetics Software Package, Version 8 (available from Genetics Computer Group (GCG™ programs (Accelrys, Inc., San Diego, Calif.)). The CLUSTAL program is well described by Higgins and Sharp (1988) Gene 73:237-44; Higgins and Sharp, (1989) CABIOS 5:151-3; Corpet, et al, (1988) Nucleic Acids Res. 16:10881-90; Huang, et al, (1992) Computer Applications in the Biosciences 8:155-65 and Pearson, et al., (1994) Meth. Mol. Biol. 24:307-31. An example of a good program to use for optimal global alignment of multiple sequences is PileUp (Feng and Doolittle, (1987) J. Mol. Evol., 25:351-60, which is similar to the method described by Higgins and Sharp, (1989) CABIOS 5:151-53 (and is hereby incorporated by reference). The BLAST family of programs that can be used for database similarity searches includes: BLASTN for nucleotide query sequences against nucleotide database sequences; BLASTX for nucleotide query sequences against protein database sequences; BLASTP for protein query sequences against protein database sequences; TBLASTN for protein query sequences against nucleotide database sequences; and TBLASTX for nucleotide query sequences against nucleotide database sequences. See, Current Protocols in Molecular Biology, Chapter 19, Ausubel, et al., eds., Greene Publishing and Wiley-Interscience, New York (1995).

GAP uses the algorithm of Needleman and Wunsch, (1970) J. Mol. Biol. 48:443-

53, to find the alignment of two complete sequences that maximizes the number of matches and minimizes the number of gaps. GAP considers all possible alignments and gap positions and creates the alignment with the largest number of matched bases and the fewest gaps. It allows for the provision of a gap creation penalty and a gap extension penalty in units of matched bases. GAP makes a profit of gap creation penalty number of matches for each gap it inserts. If a gap extension penalty greater than zero is chosen, GAP must, in addition, make a profit for each gap inserted of the length of the gap times the gap extension penalty. Default gap creation penalty values and gap extension penalty values in Version 10 of the Wisconsin Genetics Software Package are 8 and 2, respectively. The gap creation and gap extension penalties can be expressed as an integer selected from the group of integers consisting of from 0 to 100. Thus, for example, the gap creation and gap extension penalties can be 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 15, 20, 30, 40, 50 or more.

GAP presents one member of the family of best alignments. There may be many members of this family. GAP displays four figures of merit for alignments: Quality, Ratio, Identity and Similarity. The Quality is the metric was maximized to facilitate alignment of the sequences. Ratio is the quality divided by the number of bases in the shorter segment. Percent Identity is the percent of the symbols that actually match. Percent Similarity is the percent of the symbols that are similar. Symbols that are across from gaps are ignored. A similarity is scored when the scoring matrix value for a pair of symbols is greater than or equal to 0.50, the similarity threshold. The scoring matrix used in Version 10 of the Wisconsin Genetics Software Package is BLOSUM62 (see, Henikoff and Henikoff, (1989) Proc. Natl. Acad. Sci. USA 89:10915).

Unless otherwise stated, sequence identity/similarity values provided herein refer to the value obtained using the BLAST 2.0 suite of programs using default parameters (Altschul, et al., (1997) Nucleic Acids Res. 25 :3389-402).

As those of ordinary skill in the art will understand, BLAST searches assume that proteins can be modeled as random sequences. However, many real proteins comprise regions of nonrandom sequences, which may be homopolymeric tracts, short-period repeats, or regions enriched in one or more amino acids. Such low-complexity regions may be aligned between unrelated proteins even though other regions of the protein are entirely dissimilar. A number of low-complexity filter programs can be employed to reduce such low-complexity alignments. For example, the SEG (Wooten and Federhen, (1993) Comput. Chem. 17:149-63) and XNU (C.sub.l-ayerie and States, (1993) Comput. Chem. 17:191-201) low-complexity filters can be employed alone or in combination.

The terms "substantial identity" indicates that a related nucleic acid comprises a sequence with between 55-100% sequence identity to a reference sequence, with at least 55% sequence identity, or at least 60%, or at least 70%, or at least 80%, or at least 90% or at least 95% sequence identity or any percentage of range between 55-100% sequence identity relative to any of the reference sequence (e.g., any of SEQ ID NO: 1-34, 61 -71) over a specified comparison window. Optimal alignment may be ascertained or conducted using the homology alignment algorithm of Needleman and Wunsch, supra.

An indication that two polypeptide sequences are substantially identical is that both polypeptides have similar activities. For example, when the polypeptide is related to lipase and/or FAD4, that polypeptide can act as a transcription factor by binding to the same or similar upstream regions of genes normally under the regulatory control of lipase and/or FAD4. For example, proteins related to the lipase and/or FAD4 can be identified and/or characterized in assays that involve binding of a test protein (i.e., a potential lipase or potential FAD4 related to a lipase and/or FAD4 described herein) to a promoter or regulatory sequence that is bound by a lipase and/or FAD4 with any of the sequences recited herein.

The related lipase and/or FAD4 polypeptide can be identified, evaluated or characterized in assays for observing increased (or decreased) expression. The related lipases can also be evaluated for in lipase activity assays including, for example, activity against substrates such as PG and MGDG. Kits are available for evaluation of FAD4 activity.

In some embodiments, a lipase and/or FAD4 protein with a sequence related to any of the SEQ ID NO: 1-34, 61-71 sequences may not have exactly the same level of activity as the lipase and/or FAD4 protein with a SEQ ID NO: 1-34, 61 -71. Instead, the substantially identical polypeptide may exhibit greater or lesser levels of activity than the lipase and/or FAD4 protein with a SEQ ID NO: 1-34, 61-71 sequence, as measured by assays available in the art. For example, the substantially identical polypeptide may have at least about 40%, or at least about 50%, or at least about 60%, or at least about 70%, or at least about 80%, or at least about 90%, or at least about 95%, or at least about 97%, or at least about 98%, or at least about 100%, or at least about 105%, or at least about 110%, or at least about 120%, or at least about 130%, or at least about 140%, or at least about 150%, or at least about 200% of the activity of the lipase and/or FAD4 protein with a SEQ ID NO: 1-34, 61 -71 sequence, when measured by similar assay procedures.

Alternatively, substantial identity is present when second polypeptide is immunologically reactive with antibodies raised against the first polypeptide (e.g., a polypeptide with SEQ ID NO: 1 , 3-12, 14-21, 23-28, 30-34, 61-70 and/or 71 sequence). Thus, a polypeptide is substantially identical to a first polypeptide, for example, where the two polypeptides differ only by a conservative substitution. In addition, a polypeptide can be substantially identical to a first polypeptide when they differ by a non-conservative change if the epitope that the antibody recognizes is substantially identical. Polypeptides that are "substantially similar" share sequences as noted above except that some residue positions, which are not identical, may differ by conservative amino acid changes.

The lipase and/or FAD4 polypeptides can include at least the first 10, 12, 14, 15, 16, 17, 18, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107, 108, 109, 110, 111 , 112, 113, 114, 115, 116, 117, 118, 119, 120, 121, 112, 123, 124, 125, 126, 127, 128, 129, 130, 131, 132, 133, 134, 135, 136, 137, 138, 139, 140, 141 , 142, 143, 144, 145, 146, 147, 148, 149, 150, 151, 152, 153, 154, 155, 156, 157, 158, 159, 160, 161, 162, 163, 164, 165, 166, 167, 168, 169, 170, 171 , 172, 173, 174, 175, 176, 177, 178, 179, 180, 181, 182, 183, 184, 185, 186, 187, 188, 189, 190, 191, 192, 193, 194, 195, 196, 197, 198, or 199 N-terminal amino acid residues of a the SEQ ID NO: 1, 3-12, 14-21 , 23-28, 30-34, 61-70 and/or 71 sequence.

The lipase and/or FAD4 polypeptides can include additional amino acids, for example, at the N-terminal or C-terminal end. For example, the lipase and/or FAD4 polypeptides can include a histidine tag.

Transgenic Plants

To engineer plants with increased vegetative tissue or seed oil content, one of skill in the art can introduce nucleic acids encoding the lipase and/or FAD4 proteins described herein into the plants to promote the production of oils.

For example, one of skill in the art can generate genetically-modified plants that contain nucleic acids encoding lipase and/or FAD4 proteins within their somatic and/or germ cells. Such genetic modification can be accomplished by procedures available in the art. For example, one of skill in the art can prepare an expression cassette or expression vector that can express one or more encoded lipase and/or FAD4 proteins. Plant cells can be transformed by the expression cassette or expression vector, and whole plants (and their seeds) can be generated from the plant cells that were successfully transformed with the lipase and/or FAD4 nucleic acids. Some procedures for making such genetically modified plants and their seeds are described below.

Promoters: The lipase and/or FAD4 nucleic acids can be operably linked to a promoter, which provides for expression of an mRNA expressed from the lipase and/or FAD4 nucleic acids. The promoter can be a promoter functional in plants and/or seeds, and/or it can be a promoter functional during plant growth and development or in a mature plant. The promoter can be a heterologous promoter. As used herein, "heterologous" when used in reference to a gene or nucleic acid refers to a gene or nucleic acid that has been manipulated in some way. For example, a heterologous promoter is a promoter that contains sequences that are not naturally linked to an associated coding region.

A lipase and/or FAD4 nucleic acid is operably linked to the promoter when it is located downstream from the promoter, thereby forming a key portion of an expression cassette.

Promoter regions are typically found in the flanking DNA upstream from the coding sequence in both prokaryotic and eukaryotic cells. A promoter sequence provides for regulation of transcription of the downstream gene sequence and typically includes from about 50 to about 2,000 nucleotide base pairs. Promoter sequences also contain regulatory sequences such as enhancer sequences that can influence the level of gene expression. Some isolated promoter sequences can provide for gene expression of heterologous DNAs, that is a DNA different from the native or homologous DNA.

Promoter sequences are also known to be strong or weak, or inducible. A strong promoter provides for a high level of gene expression, whereas a weak promoter provides a very low level of gene expression. An isolated promoter sequence that is a strong promoter for heterologous DNAs can be advantageous because it provides for a sufficient level of gene expression for easy detection and selection of transformed cells and provides for a high level of gene expression when desired. However, as illustrated herein, expression of a lipase from a constitutive promoter can reduce seed production in transgenic plants. Hence, expression of lipase from an inducible or tissue-specific promoter can be used.

An inducible promoter is a promoter that can turn on and off gene expression of an operably linked coding region in response to an exogenously added agent, or to an environmental or developmental stimulus. For example, a bacterial promoter such as the P _t ac promoter can be induced to vary levels of gene expression depending on the level of isothiopropylgalactoside added to the transformed cells.

The promoters can also be tissue specific or developmentally regulated promoters. In some embodiments, the promoter is an inducible promoter and/or a tissue-specific promoter. For example, the promoter can be a seed-specific promoter, such as those for seed storage proteins (for example, a phaseolin promoter, a napin promoter, an oleosin promoter, and a promoter for soybean beta conglycin (Beachy et al. (1985) EMBO J. 4: 3047-3053, herein incorporated by reference in its entirety).

Examples of promoters that can be used can also include, but are not limited to, the CaMV 35S promoter (Odell et al, Nature. 313:810-812 (1985)), or others such as CaMV 19S (Lawton et al, Plant Molecular Biology . 9:315-324 (1987)), nos (Ebert et al, Proc. Natl. Acad. Sci. USA. 84:5745-5749 (1987)), Adhl (Walker et al, Proc. Natl. Acad. Sci. USA. 84:6624-6628 (1987)), sucrose synthase (Yang et al, Proc. Natl. Acad. Sci. USA. 87:4144-4148 (1990)), a-tubulin, ubiquitin, actin (Wang et al, Mol. Cell. Biol. 12:3399 (1992)), cab (SuUivan et al, Mol. Gen. Genet. 215:431 (1989)), PEPCase (Hudspeth et al, Plant Molecular Biology. 12:579-589 (1989)), the CCR (cinnamoyl CoA:NADP oxidoreductase, EC 1.2.1.44) promoter sequence isolated from Lollium perenne, (or a perennial ryegrass) and/or those associated with the R gene complex (Chandler et al., The Plant Cell. 1 :1175-1183 (1989)). Further suitable promoters include the poplar xylem- specific secondary cell wall specific cellulose synthase 8 promoter, cauliflower mosaic virus promoter, the Z10 promoter from a gene encoding a 10 kD zein protein, a Z27 promoter from a gene encoding a 27 kD zein protein, inducible promoters, such as the light inducible promoter derived from the pea rbcS gene (Coruzzi et al., EMBO J. 3:1671 (1971)) and the actin promoter from rice (McElroy et al., The Plant Cell. 2:163-171 (1990)). Seed specific promoters, such as the phaseolin promoter from beans, may also be used (Sengupta-Gopalan, Proc. Natl. Acad. Sci. USA. 83:3320-3324 (1985)). Other promoters useful in the practice of the invention are known to those of skill in the art.

Alternatively, novel tissue specific promoter sequences may be employed in the practice of the present invention. cDNA clones from particular tissues are isolated and those clones which are expressed specifically in that tissue are identified, for example, using Northern blotting. Preferably, the gene isolated is not present in a high copy number, but is relatively abundant in specific tissues. The promoter and control elements of corresponding genomic clones can then be localized using techniques well known to those of skill in the art.

For example, the promoter can be an inducible promoter. Such inducible promoters can be activated by agents such as chemicals, hormones, sugars, metabolites, or by the age or developmental stage of the plant. For example, the promoter can be an ethanol-inducible promoter, a sugar-inducible promoter, a senescence-induced promoter or any promoter activated in vegetative tissues of dicots and monocots.

A lipase and/or FAD4 nucleic acid can be combined with the promoter by standard methods to yield an expression cassette, for example, as described in Sambrook et al. (Molecular Cloning: A Laboratory Manual. Second Edition (Cold Spring Harbor, NY: Cold Spring Harbor Press (1989); Molecular Cloning: A Laboratory Manual. Third Edition (Cold Spring Harbor, NY: Cold Spring Harbor Press (2000)). Briefly, a plasmid containing a promoter such as the 35S CaMV promoter can be constructed as described in Jefferson (Plant Molecular Biology Reporter 5:387 405 (1987)) or obtained from Clontech Lab in Palo Alto, California (e.g., pBI121 or pBI221). Typically, these plasmids are constructed to have multiple cloning sites having specificity for different restriction enzymes downstream from the promoter. The lipase and/or FAD4 nucleic acids can be subcloned downstream from the promoter using restriction enzymes and positioned to ensure that the DNA is inserted in proper orientation with respect to the promoter so that the DNA can be expressed as sense RNA. Once the lipase and/or FAD4 nucleic acid is operably linked to a promoter, the expression cassette so formed can be subcloned into a plasmid or other vector (e.g., an expression vector). In some embodiments, a cDNA clone encoding a selected lipase and/or FAD4 protein is synthesized or isolated from vegetative tissue (e.g., stems, roots, and/or leaves). The cDNA clone encoding a selected lipase and/or FAD4 protein can be synthesized by available methods or isolated from mature plants. In other embodiments, cDNA clones from other species (that encode a lipase and/or FAD4 protein) are isolated from selected plant tissues, or a nucleic acid encoding a mutant or modified lipase and/or FAD4 protein is prepared by available methods or as described herein. For example, the nucleic acid encoding a mutant or modified lipase and/or FAD4 protein can be any nucleic acid with a coding region that hybridizes, for example, to SEQ ID NO:2, 13, 22, and/or 29, and that has lipase and/or FAD4 oil production activity.

Using restriction endonucleases, the coding sequence for the selected lipase and/or FAD4 is subcloned downstream of the promoter in a 5' to 3' sense orientation.

Targeting Sequences: Additionally, expression cassettes can be constructed and employed to target the lipase and/or FAD4 expression cassettes / vectors to an intracellular compartment within plant cells (e.g., the nucleus, chloroplast, or plastid) or to direct the lipase and/or FAD4 to the extracellular environment (e.g., for collection and/or purification). This can generally be achieved by joining a DNA sequence encoding a transit or signal peptide sequence to the coding sequence of the lipase and/or FAD4 nucleic acid. The resultant transit, or signal, peptide transports the protein to a particular intracellular, or extracellular destination, respectively, and can then be posttranslational removed. Transit peptides act by facilitating the transport of proteins through intracellular membranes, e.g., vacuole, vesicle, plastid, chloroplast, and mitochondrial membranes, whereas signal peptides direct proteins through the extracellular membrane. By facilitating transport of the protein into compartments inside or outside the cell, these sequences can increase the accumulation of a particular gene product in a particular location. For example, see U.S. Patent No. 5,258,300.

3 ' Sequences: When the expression cassette is to be introduced into a plant cell, the expression cassette can also optionally include 3' nontranslated plant regulatory DNA sequences that act as a signal to terminate transcription and allow for the polyadenylation of the resultant mRNA. The 3' nontranslated regulatory DNA sequence preferably includes from about 300 to 1 ,000 nucleotide base pairs and contains plant transcriptional and translational termination sequences. For example, 3' elements that can be used include those derived from the nopaline synthase gene of Agrobacterium tumefaciens (Bevan et al., Nucleic Acid Research. 11 :369 385 (1983)), or the terminator sequences for the T7 transcript from the octopine synthase gene of Agrobacterium tumefaciens, and/or the 3' end of the protease inhibitor I or II genes from potato or tomato. Other 3' elements known to those of skill in the art can also be employed. These 3' nontranslated regulatory sequences can be obtained as described in An (Methods in Enzymology. 153:292 (1987)). Many such 3' nontranslated regulatory sequences are already present in plasmids available from commercial sources such as Clontech, Palo Alto, California. The 3' nontranslated regulatory sequences can be operably linked to the 3' terminus of the lipase and/or FAD4 nucleic acids by standard methods.

Selectable and Screenable Marker Sequences: To improve identification of trans formants, a selectable or screenable marker gene can be employed with the lipase and/or FAD4 nucleic acids. "Marker genes" are genes that impart a distinct phenotype to cells expressing the marker gene and thus allow such transformed cells to be distinguished from cells that do not have the marker. Such genes may encode either a selectable or screenable marker, depending on whether the marker confers a trait which one can 'select' for by chemical means, i.e., through the use of a selective agent (e.g., a herbicide, antibiotic, or the like), or whether it is simply a trait that one can identify through observation or testing, i.e., by 'screening' (e.g., the R-locus trait). Of course, many examples of suitable marker genes are known to the art and can be employed in the practice of the invention.

Included within the terms selectable or screenable marker genes are also genes which encode a "secretable marker" whose secretion can be detected as a means of identifying or selecting for transformed cells. Examples include markers which encode a secretable antigen that can be identified by antibody interaction, or secretable enzymes that can be detected by their catalytic activity. Secretable proteins fall into a number of classes, including small, diffusible proteins detectable, e.g., by ELISA; and proteins that are inserted or trapped in the cell wall (e.g., proteins that include a leader sequence such as that found in the expression unit of extensin or tobacco PR-S).

With regard to selectable secretable markers, the use of a gene that encodes a polypeptide that becomes sequestered in the cell wall, where the polypeptide includes a unique epitope may be advantageous. Such a secreted antigen marker can employ an epitope sequence that would provide low background in plant tissue, a promoter leader sequence that imparts efficient expression and targeting across the plasma membrane, and can produce protein that is bound in the cell wall and yet is accessible to antibodies. A normally secreted wall protein modified to include a unique epitope would satisfy such requirements.

Examples of proteins suitable for modification in this manner include extensin or hydroxyproline rich glycoprotein (HPRG). For example, the maize HPRG (Stiefel et al., The Plant Cell. 2:785 793 (1990)) is well characterized in terms of molecular biology, expression, and protein structure and therefore can readily be employed. However, any one of a variety of extensins and/or glycine rich wall proteins (Keller et al., EMBO J. 8 :1309 1314 (1989)) could be modified by the addition of an antigenic site to create a screenable marker.

Possible selectable markers for use in connection with the present invention include, but are not limited to, a neo gene (Potrykus et al., Mol. Gen. Genet. 199:183 188 (1985)) which codes for kanamycin resistance and can be selected for using kanamycin, G418, and the like; a bar gene which codes for bialaphos resistance; a gene which encodes an altered EPSP synthase protein (Hinchee et al., Bio/Technology. 6:915 922 (1988)) thus conferring glyphosate resistance; a nitrilase gene such as bxn from Klebsiella ozaenae which confers resistance to bromoxynil (Stalker et al., Science. 242:419 423 (1988)); a mutant acetolactate synthase gene (ALS) which confers resistance to imidazolinone, sulfonylurea or other ALS-inhibiting chemicals (European Patent Application 154,204 (1985)); a methotrexate resistant DHFR gene (Thillet et al, J. Biol. Chem. 263:12500 12508 (1988)); a dalapon dehalogenase gene that confers resistance to the herbicide dalapon; or a mutated anthranilate synthase gene that confers resistance to 5-methyl tryptophan. Where a mutant EPSP synthase gene is employed, additional benefit may be realized through the incorporation of a suitable chloroplast transit peptide, CTP (European Patent Application 0 218 571 (1987)).

An illustrative embodiment of a selectable marker gene capable of being used in systems to select transformants is the gene that encode the enzyme phosphinothricin acetyltransferase, such as the bar gene from Streptomyces hygroscopicus or the pat gene from Streptomyces viridochromo genes (U.S. Patent No. 5,550,318). The enzyme phosphinothricin acetyl transferase (PAT) inactivates the active ingredient in the herbicide bialaphos, phosphinothricin (PPT). PPT inhibits glutamine synthetase, (Murakami et al., Mol. Gen. Genet. 205:42 50 (1986); Twell et al., Plant Physiol. 91 :1270 1274 (1989)) causing rapid accumulation of ammonia and cell death. The success in using this selective system in conjunction with monocots was surprising because of the major difficulties that have been reported in transformation of cereals (Potrykus, Trends Biotech. 7:269 273

(1989) ).

Screenable markers that may be employed include, but are not limited to, a β- glucuronidase or uidA gene (GUS) that encodes an enzyme for which various

chromogenic substrates are known; an R-locus gene, which encodes a product that regulates the production of anthocyanin pigments (red color) in plant tissues (Dellaporta et al., In: Chromosome Structure and Function: Impact of New Concepts, 18th Stadler Genetics Symposium, J.P. Gustafson and R. Appels, eds. (New York: Plenum Press) pp. 263 282 (1988)); a β-lactamase gene (Sutcliffe, Proc. Natl. Acad. Sci. USA. 75:3737 3741 (1978)), which encodes an enzyme for which various chromogenic substrates are known (e.g., PAD AC, a chromogenic cephalosporin); a xylE gene (Zukowsky et al., Proc. Natl. Acad. Sci. USA. 80:1101 (1983)) which encodes a catechol dioxygenase that can convert chromogenic catechols; an a-amylase gene (Ikuta et al., Bio/technology 8:241 242

(1990) ); a tyrosinase gene (Katz et al, J. Gen. Microbiol. 129:2703 2714 (1983)) which encodes an enzyme capable of oxidizing tyrosine to DOPA and dopaquinone which in turn condenses to form the easily detectable compound melanin; a β-galactosidase gene, which encodes an enzyme for which there are chromogenic substrates; a luciferase (lux) gene (Ow et al., Science. 234:856 859.1986), which allows for bioluminescence detection; or an aequorin gene (Prasher et al., Biochem. Biophys. Res. Comm. 126:1259 1268 (1985)), which may be employed in calcium sensitive bioluminescence detection, or a green or yellow fluorescent protein gene (Niedz et al., Plant Cell Reports. 14:403 (1995).

For example, genes from the maize R gene complex can be used as screenable markers. The R gene complex in maize encodes a protein that acts to regulate the production of anthocyanin pigments in most seed and plant tissue. Maize strains can have one, or as many as four, R alleles that combine to regulate pigmentation in a

developmental and tissue specific manner. A gene from the R gene complex does not harm the transformed cells. Thus, an R gene introduced into such cells will cause the expression of a red pigment and, if stably incorporated, can be visually scored as a red sector. If a maize line carries dominant alleles for genes encoding the enzymatic intermediates in the anthocyanin biosynthetic pathway (C2, Al , A2, Bzl and Bz2), but carries a recessive allele at the R locus, transformation of any cell from that line with R will result in red pigment formation. Exemplary lines include Wisconsin 22 that contains the rg-Stadler allele and TR112, a K55 derivative that is r-g, b, PI. Alternatively any genotype of maize can be utilized if the CI and R alleles are introduced together. The R gene regulatory regions may be employed in chimeric constructs to provide mechanisms for controlling the expression of chimeric genes. More diversity of phenotypic expression is known at the R locus than at any other locus (Coe et al., in Corn and Corn Improvement, eds. Sprague, G.F. & Dudley, J.W. (Am. Soc. Agron., Madison, WI), pp. 81 258 (1988)). It is contemplated that regulatory regions obtained from regions 5' to the structural R gene can be useful in directing the expression of genes, e.g., insect resistance, drought resistance, herbicide tolerance or other protein coding regions. In some embodiments, any of the various R gene family members may be successfully employed (e.g., P, S, Lc, etc.). However, one that can be used is Sn (particularly Sn:bol3). Sn is a dominant member of the R gene complex and is functionally similar to the R and B loci in that Sn controls the tissue specific deposition of anthocyanin pigments in certain seedling and plant cells, therefore, its phenotype is similar to R.

A further screenable marker contemplated for use in the present invention is firefly luciferase, encoded by the lux gene. The presence of the lux gene in transformed cells may be detected using, for example, X-ray film, scintillation counting, fluorescent

spectrophotometry, low light video cameras, photon counting cameras or multiwell luminometry. It is also envisioned that this system may be developed for population screening for bioluminescence, such as on tissue culture plates, or even for whole plant screening.

Some aspects of expression systems are exemplified using marker genes. However, numerous other possible selectable and/or screenable marker genes will be apparent to those of skill in the art in addition to the one set forth herein below. Therefore, it will be understood that the discussion provided herein is exemplary rather than exhaustive. In light of the techniques disclosed herein and the general recombinant techniques that are known in the art, the present invention readily allows the introduction of any gene, including marker genes, into a recipient cell to generate a transformed plant cell, e.g., a monocot cell or dicot cell.

Other Optional Sequences: An expression cassette of the invention can also further comprise plasmid DNA. Plasmid vectors include additional DNA sequences that provide for easy selection, amplification, and transformation of the expression cassette in prokaryotic and eukaryotic cells, e.g., pUC derived vectors such as pUC8, pUC9, pUC18, pUC19, pUC23, pUCl 19, and pUC120, pSK derived vectors, pGEM derived vectors, pSP derived vectors, or pBS derived vectors. The additional DNA sequences include origins of replication to provide for autonomous replication of the vector, additional selectable marker genes, such as antibiotic or herbicide resistance, unique multiple cloning sites providing for multiple sites to insert DNA sequences, and/or sequences that enhance transformation of prokaryotic and eukaryotic cells.

Another vector that is useful for expression in both plant and prokaryotic cells is the binary Ti plasmid (as disclosed in Schilperoort et al., U.S. Patent No. 4,940,838) as exemplified by vector pGA582. This binary Ti plasmid vector has been previously characterized by An (Methods in Enzymology. 153:292 (1987)). This binary Ti vector can be replicated in prokaryotic bacteria such as E. coli and Agrobacterium. The

Agrobacterium plasmid vectors can be used to transfer the expression cassette to dicot plant cells and under certain conditions to monocot cells, such as rice cells. The binary Ti vectors preferably include the nopaline T DNA right and left borders to provide for efficient plant cell transformation, a selectable marker gene, unique multiple cloning sites in the T border regions, the colEl replication of origin and a wide host range replicon. The binary Ti vectors carrying an expression cassette of the invention can be used to transform both prokaryotic and eukaryotic cells, but is preferably used to transform dicot plant cells.

In Vitro Screening of Expression Cassettes: Once the expression cassette is constructed and subcloned into a suitable plasmid, it can be screened for the ability to express the encoded lipase and/or FAD4 proteins by available methods. For example, the lipase protein can hydro lyze a lipid substrate such as a phospholipid, a 16:l ^A3trans - containing phosphatidylglycerol, or a monogalactosyldiacylglycerol (MGDG). The cleavage products of the lipase can be quantified by a variety of methods (e.g., thin layer chromatography, gas chromatography, or other methods available in the art). Expression of lipase or FAD4 can also be detected by observing mRNA expression, protein expression, and/or whether an expression cassette or vector encoding a lipase and/or FAD4 protein can facilitate synthesis of plant carbons into oils.

DNA Delivery of the DNA Molecules into Host Cells: The lipase and/or FAD4 nucleic acid can be introduced into a recipient cell to create a transformed cell by available methods. The frequency of occurrence of cells taking up exogenous (foreign) DNA can be low, and it is likely that not all recipient cells receiving DNA segments or sequences will result in a transformed cell wherein the DNA is stably integrated into the plant genome and/or expressed. Some may show only initial and transient gene expression. However, cells from virtually any dicot or monocot species can be stably transformed, and those cells can be regenerated into transgenic plants, for example, through the application of the techniques disclosed herein.

Another aspect of the invention is a plant species with increased vegetative tissue oil content, wherein the plant has an introduced lipase and/or FAD4 nucleic acid. The plant can be a monocotyledon or a dicotyledon. Another aspect of the invention includes plant cells (e.g., embryonic cells or other cell lines) that can regenerate fertile transgenic plants. Another aspect of the invention includes transgenic seeds from which transgenic plants can be grown. The plants, cells and seeds can be either monocotyledons or dicotyledons. The cell(s) may be in a suspension cell culture or may be in an intact plant part, such as an immature embryo, or in a specialized plant tissue, such as callus, such as Type I or Type II callus.

Examples of plants, seeds, and/or plant cells that can be modified as described herein to express the lipase and/or FAD4 proteins include alfalfa (e.g., forage legume alfalfa), algae, avocado, barley, broccoli, Brussels sprouts, cabbage, camelina, canola, cassava, cauliflower, coconut, cole vegetables, collards, corn, crucifers, flax, grain legumes, grasses (e.g., forage grasses), jatropa, kale, kohlrabi, maize, miscanthus, mustards, nut sedge, oats, oil firewood trees, oilseeds, olive, palm, peanut, potato, radish, rape, rapeseed, rice, rutabaga, safflower, sorghum, soybean, sugar beets, sugarcane, sunflower, switchgrass, tobacco, tomato, turnips, and wheat. In some embodiments, the plant is a Brassicaceae or other species. In some embodiments, the plant or cell can be a maize plant or cell. In some embodiments, the plant is not a species of Arabidopsis, for example, in some embodiments the plant is not Arabidopsis thaliana.

Transformation of the cells of the plant tissue source can be conducted by any one of a number of methods known to those of skill in the art. Examples are: Transformation by direct DNA transfer into plant cells by electroporation (U.S. Patent No. 5,384,253 and U.S. Patent No. 5,472,869, Dekeyser et al, The Plant Cell. 2:591 602 (1990)); direct DNA transfer to plant cells by PEG precipitation (Hayashimoto et al., Plant Physiol. 93:857 863 (1990)); direct DNA transfer to plant cells by microprojectile bombardment (McCabe et al, Bio/Technology. 6:923 926 (1988); Gordon Kamm et al., The Plant Cell. 2:603 618 (1990); U.S. Patent No. 5,489,520; U.S. Patent No. 5,538,877; and U.S. Patent No.

5,538,880) and DNA transfer to plant cells via infection with Agrobacterium. Methods such as microprojectile bombardment or electroporation can be carried out with "naked" DNA where the expression cassette may be simply carried on any E. coli derived plasmid cloning vector. In the case of viral vectors, it is desirable that the system retain replication functions, but lack functions for disease induction.

One method for dicot transformation, for example, involves infection of plant cells with Agrobacterium tumefaciens using the leaf disk protocol (Horsch et al., Science 227:1229 1231 (1985). Monocots such as Zea mays can be transformed via microprojectile bombardment of embryogenic callus tissue or immature embryos, or by electroporation following partial enzymatic degradation of the cell wall with a pectinase containing enzyme (U.S. Patent No. 5,384,253; and U.S. Patent No. 5,472,869). For example, embryogenic cell lines derived from immature Zea mays embryos can be transformed by accelerated particle treatment as described by Gordon Kamm et al. (The Plant Cell. 2:603 618 (1990)) or U.S. Patent No. 5,489,520; U.S. Patent No. 5,538,877 and U.S. Patent No. 5,538,880, cited above. Excised immature embryos can also be used as the target for transformation prior to tissue culture induction, selection and regeneration as described in U.S. application Serial No. 08/112,245 and PCT publication WO 95/06128. Furthermore, methods for transformation of monocotyledonous plants utilizing Agrobacterium tumefaciens have been described by Hiei et al. (European Patent 0 604 662, 1994) and Saito et al. (European Patent 0 672 752, 1995).

Methods such as microprojectile bombardment or electroporation are carried out with "naked" DNA where the expression cassette may be simply carried on any E. coli derived plasmid cloning vector. In the case of viral vectors, it is desirable that the system retain replication functions, but lack functions for disease induction.

The choice of plant tissue source for transformation will depend on the nature of the host plant and the transformation protocol. Useful tissue sources include callus, suspension culture cells, protoplasts, leaf segments, stem segments, tassels, pollen, embryos, hypocotyls, tuber segments, meristematic regions, and the like. The tissue source is selected and transformed so that it retains the ability to regenerate whole, fertile plants following transformation, i.e., contains totipotent cells. Type I or Type II embryonic maize callus and immature embryos are preferred Zea mays tissue sources. Selection of tissue sources for transformation of monocots is described in detail in U.S. Application Serial No. 08/112,245 and PCT publication WO 95/06128.

The transformation is carried out under conditions directed to the plant tissue of choice. The plant cells or tissue are exposed to the DNA or RNA encoding the lipase and/or FAD4 protein for an effective period of time. This may range from a less than one second pulse of electricity for electroporation to a 2-3 day co-cultivation in the presence of plasmid bearing Agrobacterium cells. Buffers and media used will also vary with the plant tissue source and transformation protocol. Many transformation protocols employ a feeder layer of suspended culture cells (e.g., tobacco or Black Mexican Sweet corn, for example) on the surface of solid media plates, separated by a sterile filter paper disk from the plant cells or tissues being transformed.

Electroporation: Where one wishes to introduce DNA by means of electroporation, it is contemplated that the method of Krzyzek et al. (U.S. Patent No. 5,384,253) may be advantageous. In this method, certain cell wall degrading enzymes, such as pectin degrading enzymes, are employed to render the target recipient cells more susceptible to transformation by electroporation than untreated cells. Alternatively, recipient cells can be made more susceptible to transformation, by mechanical wounding.

To effect transformation by electroporation, one may employ either friable tissues such as a suspension cell cultures, or embryogenic callus, or alternatively, one may transform immature embryos or other organized tissues directly. The cell walls of the preselected cells or organs can be partially degraded by exposing them to pectin degrading enzymes (pectinases or pectolyases) or mechanically wounding them in a controlled manner. Such cells would then be receptive to DNA uptake by electroporation, which may be carried out at this stage, and transformed cells then identified by a suitable selection or screening protocol dependent on the nature of the newly incorporated DNA.

Microprojectile Bombardment: A further advantageous method for delivering transforming DNA segments to plant cells is microprojectile bombardment. In this method, microparticles may be coated with DNA and delivered into cells by a propelling force. Exemplary particles include those comprised of tungsten, gold, platinum, and the like.

It is contemplated that in some instances DNA precipitation onto metal particles would not be necessary for DNA delivery to a recipient cell using microprojectile bombardment. In an illustrative embodiment, non-embryogenic Black Mexican Sweet (BMS) cells are bombarded with intact cells of the bacteria E. coli or Agrobacterium tumefaciens containing plasmids with the lipase and/or FAD4 nucleic acids engineered for expression in plants. Bacteria were inactivated by ethanol dehydration prior to

bombardment. A low level of transient expression of the lipase and/or FAD4 protein can be observed 24-48 hours following DNA delivery. In addition, stable transformants containing the lipase and/or FAD4 nucleic acids are recovered following bombardment with either E. coli or Agrobacterium tumefaciens cells. It is contemplated that particles may contain DNA rather than be coated with DNA. Hence particles may increase the level of DNA delivery but are not, in and of themselves, necessary to introduce DNA into plant cells.

An advantage of microprojectile bombardment, in addition to being an effective means of reproducibly stably transforming monocots, is that the isolation of protoplasts (Christou et al, PNAS. 84:3962 3966 (1987)), the formation of partially degraded cells, or the susceptibility to Agrobacterium infection is not required. An illustrative embodiment of a method for delivering DNA into maize cells by acceleration is a Biolistics Particle Delivery System, which can be used to propel particles coated with DNA or cells through a screen, such as a stainless steel or Nytex screen, onto a filter surface covered with maize cells cultured in suspension (Gordon Kamm et al., The Plant Cell. 2:603 618 (1990)). The screen disperses the particles so that they are not delivered to the recipient cells in large aggregates. It is believed that a screen intervening between the projectile apparatus and the cells to be bombarded reduces the size of projectile aggregate and may contribute to a higher frequency of transformation, by reducing damage inflicted on the recipient cells by an aggregated projectile.

For bombardment, cells in suspension can be concentrated on filters or solid culture medium. Alternatively, immature embryos or other target cells may be arranged on solid culture medium. The cells to be bombarded are positioned at an appropriate distance below the macroprojectile stopping plate. If desired, one or more screens are also positioned between the acceleration device and the cells to be bombarded. Using techniques set forth here in one may obtain up to 1000 or more foci of cells transiently expressing a desirable trait (e.g., as detected by expression of a marker gene). The number of cells in a focus which express the exogenous gene product 48 hours post bombardment often range, for example, from about 1 to 10 and average about 1 to 3.

In bombardment transformation, one may optimize the prebombardment culturing conditions and the bombardment parameters to yield the maximum numbers of stable transformants. Both the physical and biological parameters for bombardment can influence transformation frequency. Physical factors are those that involve manipulating the DNA/microprojectile precipitate or those that affect the path and velocity of either the macroprojectiles or microprojectiles. Biological factors include all steps involved in manipulation of cells before and immediately after bombardment, the osmotic adjustment of target cells to help alleviate the trauma associated with bombardment, and also the nature of the transforming DNA, such as linearized DNA or intact supercoiled plasmid DNA.

One may wish to adjust various bombardment parameters in small scale studies to fully optimize the conditions and/or to adjust physical parameters such as gap distance, flight distance, tissue distance, and helium pressure. One may also minimize the trauma reduction factors (TRFs) by modifying conditions which influence the physiological state of the recipient cells and which may therefore influence transformation and integration efficiencies. For example, the osmotic state, tissue hydration and the subculture stage or cell cycle of the recipient cells may be adjusted for optimum transformation. Execution of such routine adjustments will be known to those of skill in the art.

An Example of Production and Characterization of Stable Transgenic Maize: After effecting delivery of one or more lipase and/or FAD4 nucleic acid(s) to recipient cells by any of the methods discussed above (e.g., in an expression vector), the transformed cells can be identified for further culturing and plant regeneration. As mentioned above, to improve the ability to identify transformants, one may desire to employ a selectable or screenable marker gene as, or in addition to, the lipase and/or FAD4 nucleic acids. In this case, one would then generally assay the potentially transformed cell population by exposing the cells to a selective agent or agents, or one would screen the cells for the desired marker gene trait. Alternatively, the introduced (e.g., transgenic) nucleic acids can be detected and/or characterized by use of a nucleic acid probe to detect the presence of an expression cassette and/or expressed RNA. The introduced nucleic acids can also be detected and/or evaluated by sequencing.

Selection: An exemplary embodiment of methods for identifying transformed cells involves exposing the bombarded cultures to a selective agent, such as a metabolic inhibitor, an antibiotic, herbicide or the like. Cells which have been transformed and have stably integrated a marker gene conferring resistance to the selective agent used, will grow and divide in culture. Sensitive cells will not be amenable to further culturing.

For example, to use the bar-bialaphos or the EPSPS-glyphosate selective system, bombarded tissue is cultured for about 0-28 days on nonselective medium and

subsequently transferred to medium containing from about 1-3 mg/1 bialaphos or about 1-3 mM glyphosate, as appropriate. While ranges of about 1-3 mg/1 bialaphos or about 1-3 mM glyphosate can be employed, it is proposed that ranges of at least about 0.1-50 mg/1 bialaphos or at least about 0.1-50 mM glyphosate may be useful. Tissue can be placed on any porous, inert, solid or semi-solid support for bombardment, including but not limited to filters and solid culture medium. Bialaphos and glyphosate are provided as examples of agents suitable for selection of transformants, but the technique of this invention is not limited to them.

An example of a screenable marker trait is the red pigment produced under the control of the R-locus in maize. This pigment may be detected by culturing cells on a solid support containing nutrient media capable of supporting growth at this stage and selecting cells from colonies (visible aggregates of cells) that are pigmented. These cells may be cultured further, either in suspension or on solid media. The R-locus is useful for selection of transformants from bombarded immature embryos. In a similar fashion, the introduction of the CI and B genes will result in pigmented cells and/or tissues.

The enzyme luciferase is also useful as a screenable marker in the context of the present invention. In the presence of the substrate luciferin, cells expressing luciferase emit light which can be detected on photographic or X-ray film, in a luminometer (or liquid scintillation counter), by devices that enhance night vision, or by a highly light sensitive video camera, such as a photon counting camera. All of these assays are nondestructive and transformed cells may be cultured further following identification. The photon counting camera is especially valuable as it allows one to identify specific cells or groups of cells which are expressing luciferase and manipulate those in real time.

It is further contemplated that combinations of screenable and selectable markers may be useful for identification of transformed cells. For example, selection with a growth inhibiting compound, such as bialaphos or glyphosate at inhibiting concentrations that cause 100% inhibition followed by screening of growing tissue for expression of a screenable marker gene such as luciferase would allow one to recover transformants from cell or tissue types that are not amenable to selection alone. In one example, embryogenic Type II callus of Zea mays L. can be selected with sub lethal levels of bialaphos. Slowly growing tissue was subsequently screened for expression of the luciferase gene and transformants can be identified.

Regeneration and Seed Production: Cells that survive the exposure to the selective agent, or cells that have been scored positive in a screening assay, are cultured in media that supports regeneration of plants. One example of a growth regulator that can be used for such purposes is dicamba or 2,4-D. However, other growth regulators may be employed, including NAA, NAA + 2,4-D or perhaps even picloram. Media improvement in these and like ways can facilitate the growth of cells at specific developmental stages. Tissue can be maintained on a basic media with growth regulators until sufficient tissue is available to begin plant regeneration efforts, or following repeated rounds of manual selection, until the morphology of the tissue is suitable for regeneration, at least two weeks, then transferred to media conducive to maturation of embryoids. Cultures are typically transferred every two weeks on this medium. Shoot development signals the time to transfer to medium lacking growth regulators.

The transformed cells, identified by selection or screening and cultured in an appropriate medium that supports regeneration, can then be allowed to mature into plants. Developing plantlets are transferred to soilless plant growth mix, and hardened, e.g., in an environmentally controlled chamber at about 85% relative humidity, about 600 ppm C02, and at about 25-250 microeinsteins/sec-m of light. Plants can be matured either in a growth chamber or greenhouse. Plants are regenerated from about 6 weeks to 10 months after a transformant is identified, depending on the initial tissue. During regeneration, cells are grown on solid media in tissue culture vessels. Illustrative embodiments of such vessels are petri dishes and Plant Con™. Regenerating plants can be grown at about 19 °C to 28 °C. After the regenerating plants have reached the stage of shoot and root development, they may be transferred to a greenhouse for further growth and testing.

Mature plants are then obtained from cell lines that express the desired trait(s). In some embodiments, the regenerated plants are self-pollinated. In addition, pollen obtained from the regenerated plants can be crossed to seed grown plants of agronomically important inbred lines. In some cases, pollen from plants of these inbred lines is used to pollinate regenerated plants. The trait is genetically characterized by evaluating the segregation of the trait in first and later generation progeny. The heritability and expression in plants of traits selected in tissue culture are of particular importance if the traits are to be commercially useful.

Regenerated plants can be repeatedly crossed to inbred plants in order to introgress the lipase and/or FAD4 nucleic acids into the genome of the inbred plants. This process is referred to as backcross conversion. When a number of crosses to the recurrent inbred parent have been completed, a product of the backcross conversion process that is substantially isogenic with the recurrent inbred parent except for the presence of the introduced lipase and/or FAD4 nucleic acids is generated. Such a plant is self-pollinated at least once in order to produce a homozygous backcross converted inbred plant line containing the lipase and/or FAD4 nucleic acids. Progeny of these plants are true breeding. Alternatively, seed from transformed plants regenerated from transformed tissue cultures is grown in the field and self-pollinated to generate true breeding plants.

Seed from the fertile transgenic plants can be evaluated for the presence and/or expression of the lipase and/or FAD4 nucleic acids (or the lipase and/or FAD4 protein products). Transgenic plant and/or seed tissue can be analyzed for lipase and/or FAD4 expression using standard methods such as SDS polyacrylamide gel electrophoresis, liquid chromatography (e.g., HPLC) or other means of detecting a lipase and/or FAD4 protein.

Once a transgenic seed expressing the lipase and/or FAD4, and having an increase in oil in the plant tissue is identified, the seed can be used to develop true breeding plants. The true breeding plants are used to develop a line of plants with an increase in the percent of oil in the plant tissues while still maintaining other desirable functional agronomic traits. Adding the trait of increased oil / decreased carbohydrate production to the plant can be accomplished by back crossing with this trait and with plants that do not exhibit these traits and studying the pattern of inheritance in segregating generations.

Those plants expressing the target trait in a dominant fashion are preferably selected. Back crossing is carried out by crossing the original fertile transgenic plants with a plant from an inbred line exhibiting desirable functional agronomic characteristics while not necessarily expressing the trait of an increased percent of oil in the plant. The resulting progeny are then crossed back to the parent that expresses the increased oil / decreased carbohydrate trait. The progeny from this cross will also segregate so that some of the progeny carry the traits and some do not. This back crossing is repeated until an inbred line with the desirable functional agronomic traits, and with expression of the trait involving an increase in oil and/or a decrease in carbohydrate in the vegetative tissues of the plant. Such expression of the increased percentage of oil or decreased percentage of carbohydrate in plant tissues can be expressed in a dominant fashion.

Subsequent to back crossing, the new transgenic plants can be evaluated for an increase in the weight percent of oil (TAG) incorporated into vegetative tissues of the plant. This can be done, for example, by thin layer chromatography (TLC), gas chromatography, gas chromatography- flame ionization detector (GC-FID), electrospray ionization mass spectrometry (ESI-MS), mass spectroscopy, nuclear magnetic resonance (NMR), high pressure liquid chromatography (HPLC), and/or infrared spectral analysis of plant tissue or by other available methods of detecting and quantifying oils in harvested plant tissues. The new transgenic plants can also be evaluated for a battery of functional agronomic characteristics such as lodging, kernel hardness, yield, resistance to disease, resistance to insect pests, drought resistance, and/or herbicide resistance.

Plants that can be generated by these methods include but are not limited to oil and/or starch plants (canola, potatoes, cassava, lupins, oilseeds, olive, palm, peanut, rape, rapeseed, safflower, sorghum, soybean, sunflower and cottonseed), forage plants (alfalfa, clover and fescue), grains (maize, wheat, barley, oats, rice, sorghum, millet and rye), grasses (switchgrass, prairie grass, wheat grass, sudangrass, sorghum, straw-producing plants), fiber-producing plants (cotton, flax), softwood, hardwood and other woody plants (e.g., those used for paper production such as poplar species, pine species, and eucalyptus). Examples of plants and/or plant cells that can be modified as described herein include alfalfa (e.g., forage legume alfalfa), algae, avocado, barley, broccoli, Brussels sprouts, cabbage, camelina, canola, cassava, cauliflower, coconut, cole vegetables, collards, corn, crucifers, flax, grain legumes, grasses (e.g., forage grasses), jatropa, kale, kohlrabi, maize, miscanthus, mustards, nut sedge, oats, oil firewood trees, oilseeds, olive, palm, peanut, potato, radish, rape, rapeseed, rice, rutabaga, safflower, sorghum, soybean, sugar beets, sugarcane, sunflower, switchgrass, tobacco, tomato, turnips, and wheat. In some embodiments, the plant is a Brassicaceae or other Solanaceae species. In some embodiments, the plant or cell can be a maize plant or cell. In some embodiments, the plant is not a species of Arabidopsis, for example, in some embodiments, the plant is not Arabidopsis thaliana.

Determination of Stably Transformed Plant Tissues: To confirm the presence of the lipase and/or FAD4 nucleic acids in the regenerating plants, or seeds or progeny derived from the regenerated plant, a variety of assays may be performed. Such assays include, for example, molecular biological assays available to those of skill in the art, such as Southern and Northern blotting and PCR; biochemical assays, such as detecting the presence of a protein product, e.g., by immunological means (ELISAs and Western blots) or by enzymatic function; plant part assays, such as leaf, seed or root assays; and also, by analyzing the phenotype of the whole regenerated plant. In some embodiments, the amount of oil in plant tissues is quantified. Such a quantified oil content can be compared to a control plant, for example, a control plant of the same species that has not be modified to express the lipase and/or FAD4 protein.

Whereas DNA analysis techniques may be conducted using DNA isolated from any part of a plant, RNA may only be expressed in particular cells or tissue types and so RNA for analysis can be obtained from those tissues. PCR techniques may also be used for detection and quantification of RNA produced from the introduced lipase and/or FAD4 nucleic acids. RT-PCR also be used to reverse transcribe expressed RNA into DNA, using enzymes such as reverse transcriptase, and then this DNA can be amplified through the use of PCR techniques. Further information about the nature of the RNA product may be obtained by Northern blotting. This technique will demonstrate the presence of an RNA species and give information about the integrity of that RNA. The presence or absence of an RNA species can also be determined using dot or slot blot Northern hybridizations. These techniques are modifications of Northern blotting and also demonstrate the presence or absence of an RNA species.

Southern blotting, northern blotting and PCR may be used to detect the lipase and/or FAD4 nucleic acid in question. Expression may also be evaluated by specifically identifying the presence or absence of protein products of the introduced lipase and/or FAD4 nucleic acids, by assessing the level of lipase and/or FAD4 mRNA and/or protein expressed, or evaluating the phenotypic changes brought about by their expression.

Assays for the production and identification of specific proteins may make use of physical chemical, structural, functional, or other properties of the proteins. Unique physical chemical or structural properties allow the proteins to be separated and identified by electrophoretic procedures, such as native or denaturing gel electrophoresis or isoelectric focusing, or by chromatographic techniques such as ion exchange, liquid chromatography or gel exclusion chromatography. The unique structures of individual proteins offer opportunities for use of specific antibodies to detect their presence in formats such as an ELISA assay. Combinations of approaches may be employed with even greater specificity such as Western blotting in which antibodies are used to locate individual gene products that have been separated by electrophoretic techniques.

Additional techniques may be employed to confirm the identity of the lipase and/or FAD4 protein expressed such as evaluation by nucleic acid or amino acid sequencing following purification. The Examples of this application also provide assay procedures for detecting lipase and/or FAD4 activity. Other procedures may be additionally used.

The expression of a lipase and/or FAD4 gene product can also be determined by evaluating the phenotypic results of its expression. These assays also may take many forms including but not limited to analyzing changes in the chemical composition, morphology, or physiological properties of the plant. Chemical composition of plant tissues may be altered by expression of the lipase and/or FAD4 protein(s).

Kits A kit is provided that can include a transgenic seed containing lipase and/or FAD4 nucleic acids, as well as instructions for cultivating the seeds, as well the use of any other material or reagent not included in the kit. The kit can also include a medium for growth of the seeds, or for grow of seedlings, or for induction of expression of the lipase and/or FAD4 nucleic acids to generate lipase and/or FAD4 proteins. Such a medium can also include sugar or a source of sugar. The kit can also include fertilizer. Instructions can include text on when and how to induce expression of the lipase and/or FAD4. Variations that can be implemented can also be described in the instructions.

Any of the lipase and/or FAD4 nucleic acids, polypeptides and/or related nucleic acids and/or polypeptides described herein can be included in a kit. In some embodiments, the kits can include a container that includes a nucleic acid, or a mixture of nucleic acids. Such a nucleic acid or mixture of nucleic acids can be used, for example, to transform plant cells and/or generate transgenic plants. The nucleic acid(s) can encode a lipase and/or FAD4 protein.

The kits can also include more than one container. For example, the kits can include two or more containers, where one container includes a lipase and/or FAD4 nucleic acid, and another container includes other nucleic acids of interest, or other components for transformation of plant cells. For example, the kit can include a container with a lipase and/or FAD4 nucleic acid, where the lipase and/or FAD4 nucleic acid can be part of an expression cassette or an expression vector.

The kits may also include one or more containers of buffers, such as buffers to dilute or stabilize the lipase and/or FAD4 nucleic acids, or transcription buffers, or hybridization buffers, or buffers for measuring lipase and/or FAD4 activity or compounds for manipulating the nucleic acids, and/or components for isolating the resultant expression cassette that may be integrated into a plant genome.

The kits can also contain substrates for measuring lipase and/or FAD4 activities. For example, the kits can contain lipase substrates such as PG and/or MGDG.

The components of the kits may be packaged either in aqueous media or in lyophilized form. The containers can be vials, test tubes, flasks, bottles, syringes or other container means, into which a component may be placed, and suitably aliquoted.

Where there is more than one component in the kit, the kit also will generally contain a second, third or other additional container into which the additional components may be separately placed. However, various combinations of components may also be included in one container. The kits of the present invention also will typically include a means for containing the nucleic acids, and any other reagent containers in close confinement for commercial sale. Such containers may include injection or blow-molded plastic packages into which the desired vials are retained.

When the components of the kit are provided in one and/or more liquid solutions, the liquid solution is an aqueous solution, for example, a sterile aqueous solution. The nucleic acids can also be provided as an alcohol precipitate or as dried powder(s). When reagents and/or components are provided as a dry powder, the powder can be reconstituted by the addition of a suitable solvent. It is envisioned that the solvent may also be provided in another container.

In some embodiments, nucleic acids are provided in dried form or suspended in an appropriate buffer or solvent. It is contemplated that 0.1 , 1, 5, 10, 20, 30, 40, 50, 60, 70, 80, 90, 100, 120, 120, 130, 140, 150, 160, 170, 180, 190, 200, 300, 400, 500, 600, 700, 800, 900, 1000 μg or nucleic acid can be provided in kits of the invention.

The kits can also include a means for containing the vials in close confinement for commercial sale, such as, e.g., injection and/or blow-molded plastic containers into which the desired vials are retained.

Such kits may also include components that preserve or maintain the nucleic acids or that protect against their degradation. Such components may be DNAse-free or RNAse free. The kits may include containers of DNase or RNase inhibitors. Such kits generally will comprise, in suitable means, distinct containers for each individual reagent or solution.

A kit will also include instructions for employing the kit components as well the use of any other reagent not included in the kit. Instructions may include variations that can be implemented.

PLIPl prefers lSrS/ierl^'-PG as natural substrate

Recombinant lipases are notoriously difficult to produce and to study in vitro. PLIPl is no exception as its production in E. coli led to membrane degradation, which confirmed its general lipase activity, but made PLIPl challenging to purify (FIG. IE- IF). Furthermore, while recombinant PLIPl was specifically acting on the glyceryl sn-1 position, it could use a range of polar lipids found in plants and bacteria in vitro (FIG. 2G-2H). Notably, it did not act on TAG and had very little activity on the two glycolipids DGDG and sulfolipid found in the chloroplast, but high activity towards PG and MGDG. Because the full spectrum of all possible combinations of glycerolipid molecular species occurring in chloroplasts was impractical to test in vitro, the in vivo specificity of PLIPl was evaluated by overproducing the protein in chloroplasts, which the inventors had determined was the location of PLIP1 in plant cells using multiple independent approaches (FIG. 1). This allowed testing PLIP1 lipase activity in a quasi-native environment with the caveat that PLIP1 is normally not abundant in leave chloroplasts and more likely active in chloroplasts of developing embryos based on the gene's expression profile and the loss-of- function phenotype visible in seeds (FIG. 4). However, leaf chloroplasts are much more readily accessible for assays than embryo chloroplasts and we assumed that findings on PLIP1 activity would be transferable between the two tissues, which was ultimately confirmed. Based on the in vivo analysis of PLIP1 , 18:3/16:1^ ^Λ -ΡΟ emerged as the most likely in vivo substrate for PLIP1, which was corroborated in vitro using a native, leaf-isolated molecular species mixture of PG (FIG. 2D-2F). It should be noted that in the over expression lines, effects on MGDG and PC were observed in addition to PG (FIG. 3B and 3C). This could be directly due to the activity of PLIP1 on MGDG, or caused by secondary effects related to acyl exchange and acyl transfer in case of PC, which is not in the thylakoid membranes and should not be directly accessible to PLIPl .

PLIP1 location limits availability of likely substrates in vivo

To explain the observed PLIP1 substrate preference in vivo, one might invoke the presence of factors in its native environment that are simply not present in vitro. Another, more likely, explanation might be the limited accessibility of certain lipid molecular species to PLIP1 due to the specific membrane location of the PLIP1, assuming that specific membrane leaflets or lateral subdomains might have a specific lipid composition. The inventors now have some clarity on the location of PLIP1, its likely peripheral association with thylakoid membranes based on fractionation, chloroplast import, and protease protection experiments, and its dual processing (FIG. 1). Fractionation showed that PLIP1 is associated with thylakoid membranes, while import and protease protection assays were consistent with three possible suborganellar locations for PLIP1 : stroma, thylakoid or the stroma leaflet of the inner envelope membrane (FIG. 1). PLIP1 is not predicted to contain transmembrane domains, but must be a peripheral membrane protein to gain access to its substrate. Most likely, PLIP1 is a peripheral thylakoid protein, but PLIP1 also can transiently be free in the stroma or PLIP1 can even access to the inner envelope membrane. Double processing of PLIP1 as observed can be interpreted as first generating an intermediate during protein import into the stroma, while the second processing possibly releases the majority of the mature protein from the thylakoid fraction into the soluble stroma fraction. A conserved twin-arginine motif is generally required for importing proteins into thylakoids (Robinson and Bolhuis, 2001 ; Goosens and van Dijl, 2016), but PLIPl is missing a canonical motif, although it contains two sets of twin-arginine in its transit peptide usually part of such a motif. Therefore, PLIPl may peripherally attach to the thylakoid membrane but is likely prevented from being further imported into thylakoid lumen.

For the likely substrate of PLIPl, \%· Ι\6:\ ^Δ3 '-Ϋθ, we only know that it is exclusively present in chloroplasts, where the FAD4 desaturase required for its synthesis is located as well (Gao et al., 2009). However, the presence of 18:3/16:1^ ^Λ -ΡΟ in a specific suborganellar membrane, leaflet, or lateral membrane domain is not known. All we can conclude based on our localization of PLIPl is that 18:3/16:1 ^Z|J '-PG must be present in the stroma leaflet of the thylakoid or envelope membranes to be accessible to PLIPl .

PLIPl is involved in TAG biosynthesis in developing embryos

PG is required for proper embryo development. The development of embryos in a pgpl, pgp2 double mutant affected in PG biosynthesis in chloroplasts, mitochondria and the endoplasmic reticulum is delayed and maturing seeds shrink during desiccation, resulting subsequently in compromised germination (Tanoue et al., 2014). Originally, it was proposed that the chloroplast-specific molecular lipid species, 18:3/16 il^'-PG, is critical for the function of the photosynthetic membrane, but its complete replacement with 18:3/16:0-PG in the Arabidopsis/<¾f4 mutant had only mild effects on leaf photosynthesis (Browse et al., 1985; McCourt et al., 1985). Therefore, the fact that PLIPl preferentially releases 18:3 from 18:3/16: l^'-PG, might point towards previously unrecognized roles for this lipid, especially in seeds, where PLIPl is most highly expressed (FIG. 4A). In fact, with increased expression of PLIPl, seed TAG content increased, while decreased PLIPl expression in T-DNA insertional lines reduced seed TAG content (FIG. 4), corroborating a possible involvement of PLIPl in seed TAG biosynthesis. Furthermore, decreased TAG in plipl seeds lead to decreased germination (FIG. 4D).

During the labeling experiment on isolated embryos, saturating substrate levels were provided (FIG. 5C). Therefore, higher carbon incorporation into TAG in PLIPl -OX seeds reflects an increased capacity for TAG biosynthesis in individual embryos, despite the reduced plant growth and the decreased overall seed yield of the plants (FIG. 3A). Interestingly, this increased rate of incorporation into TAG was also observed for leaves of the PLIP1-OX lines (FIG. 3H). Furthermore, given the preference of PLIPl for 18:3/16:1^- PG, the recapitulation of the plipl low- TAG seed phenotype in the fad4 mutant lacking 18:3/16:1 -PG supports the role of PLIP1 in seed TAG biosynthesis and provides a possible function for this unusual lipid molecular species.

PLIP1 enables channeling of acyl groups from plastid 18:3/16:l ^JJi -PG to TAG at the Endoplasmic Reticulum

How can PLIP1, a lipase, be a component of a mechanisms directing FAs synthesized in the plastid into TAG lipid droplets in the cytosol during embryogenesis? A large body of evidence suggests that PC is a critical precursor for TAG biosynthesis in developing seeds. As shown in FIG. 6, at least two pathways, acyl editing of PC (FIG. 6, reaction 1) followed by transfer of 18:3 from the acyl-CoA pool to TAG (FIG. 6, Reaction 4) and head group exchange generating DAG with 18:3 acyl groups (FIG. 6, reaction 3), contribute to the incorporation of polyunsaturated FAs into TAG during seed development (Bates et al., 2012; Li-Beisson et al., 2013). However, even in the rodl,lpcatl,lpcat2 triple mutant carrying the strongest known alleles at each locus, which in combination should completely disrupt acyl editing and head group exchange, the capacity of seeds to produce 18:3-containing TAG is only cut by half (Bates et al., 2012). Therefore, other mechanisms likely exist for incorporating polyunsaturated FAs into ER lipids and TAGs. The inventors hypothesized that PLIP1 provides an additional acyl editing mechanism to resupply the cytosolic 18:3-CoA pool as depicted in FIG. 6, Reaction 2. Whenever PLIP1 is highly abundant in vegetative tissues or seeds, the turnover of plastid PG accelerates (FIG. 3 and FIG. 5). The PG pool size does not change, but the PG acyl composition does, which is indicative of acyl-editing of plastid PG. Importantly carbon flux and specifically 18:3 flux from PG to PC are increased in PLIP1 overexpression lines, which is evident from the pulse- chase labeling experiments (FIG. 5) and reflected in the compositional changes of bulk PC, respectively (FIG. 4). Restoration of the low 18:3-PC lipid phenotype of the fad3-2 mutant by overexpression of PLIP1 (FIG. 3F) corroborates this hypothesis. This result is consistent with a competition between PLIP1 providing 18:3 acyl groups incorporated into PC by acyl exchange from the acyl-CoA pool and desaturation of acyl groups directly on PC by ER desaturases followed by head group exchange and 18:3 DAG production.

PLIP1 takes part in acyl group export from chloroplasts

The hypothesis outlined above (FIG. 6) also implies that PLIP1 activity leads to acyl export from the plastid. Assuming that PLIP1 acts at the stroma surface of the thylakoids or the inner envelope membrane, additional chloroplast proteins are likely necessary to direct acyl groups from chloroplast Ιδ ^/Ιό^^'-Ρϋ into TAGs. Recently, chalcone isomerase-like chloroplast proteins were shown to be FATTY ACID BINDING PROTEINS (FAP), which may be associated with chloroplast fatty acid export (Ngaki et al., 2012). The expression pattern of FAPs resembles that of PLIPl, and all FAPs are located in the stroma of chloroplasts. One of the FAPs, FAP1 shows high proclivity for binding 18:3. Therefore, it seems possible that 18:3 released by PLIPl from 18:3/16: l^'-PG is bound by FAP, thereby sequestering it to avoid cytotoxicity of free FAs or to mediate FA transfer to the chloroplast envelope membrane. Another protein possibly involved is FATTY ACID EXPORT 1 (FAX1), a likely acyl group or FA transporter of the inner envelope membrane of plastids (Li et al., 2015). In the faxl mutant, of the four thylakoid lipids PG levels are increased the most, especially Ι δ^/Ιό^^'-Ρϋ, and levels of PC are decreased. Also, TAG biosynthesis, especially its poly unsaturated FA content correlates with the presence of FAX1 in reproductive tissues. Hence it seems possible that PLIPl, FAP and FAX1 work together to channel plastid synthesized acyl groups through Ι δ^/Ιό^^'-Ρϋ into PC outside the plastid and ultimately into TAG during seed development.

Movement of de novo synthesized lipid groups through the chloroplast membrane lipid pool has been previously observed in Chlamydomonas, in which PGD1 is a lipase specific for newly synthesized 18:1/18 :1 -MGDG, while 18:3/16:4 MGDG is resistant to its activity (Li et al., 2012). In this case PGD1 expression is induced following N-deprivation and participates in the channeling of acyl groups into TAG biosynthesis under those conditions. Although plants synthesize TAG in vegetative tissues under stress (Moellering et al., 2010), they generally produce bulk TAG in developing embryos. PLIPl is too distantly related to PGD1 to be an orthologue and Chlamydomonas does not contain PC, while Arabidopsis lacks 18:3/16:4-MGDG. However, both lipases point towards a common theme, the need for channeling of newly synthesized acyl groups through the chloroplast lipid pool prior to incorporation into extraplastidic TAGs. The specific substrate selectivity of these two lipases also partially explains the existence of unusual molecular species of chloroplast lipids, 18 :3/16:4 MGDG in Chlamydomonas and Ιδ^/Ιό^'-ΡΟ in Arabidopsis and most other plants and algae. It seems likely that unusual acyl groups tag specific molecular species for specific purposes. In case of 18:3/16:4 MGDG in Chlamydomonas it is tagged as structural thylakoid membrane lipid resistant to PGD1 , while in case of Ιδ^/Ιό^^'-Ρϋ in Arabidopsis it is the preferred substrate for PLIPl leading to 18:3 acyl export, rather than having a specific function related to photosynthetic light capture and conversion as previously assumed. Chlamydomonas also contains Ι δ^/Ιό^^'-Ρϋ and genomes of plants and algae encode many more potential plastid- targeted lipases. Therefore, it is likely that acyl hydrolysis catalyzed by specific plastid lipases and their respective native substrates is a common process in maintaining photosynthetic membrane homeostasis while enabling the exchange and export of acyl groups for the synthesis of extraplastidic lipids or as precursors for retrograde signaling molecules.

Definitions

As used herein, "isolated" means a nucleic acid or polypeptide has been removed from its natural or native cell. Thus, the nucleic acid or polypeptide can be physically isolated from the cell, or the nucleic acid or polypeptide can be present or maintained in another cell where it is not naturally present or synthesized. The isolated nucleic acid or the isolated polypeptide can also be a nucleic acid or protein that is modified but has been introduced into a cell where it is or was naturally present. Thus, a modified isolated nucleic acid or an isolated polypeptide expressed from a modified isolated nucleic acid can be present in a cell along with a wild copy of the (unmodified) natural nucleic acid and along with wild type copies of the (natural) polypeptide.

As used herein, a "native" nucleic acid or polypeptide means a DNA, RNA or amino acid sequence or segment that has not been manipulated in vitro, i.e., has not been isolated, purified, mutated, and/or amplified.

The term "transgenic" when used in reference to a plant or leaf or vegetative tissue or seed for example a "transgenic plant," transgenic leaf," "transgenic vegetative tissue," "transgenic seed," or a "transgenic host cell" refers to a plant or leaf or tissue or seed that contains at least one heterologous or foreign gene in one or more of its cells. The term "transgenic plant material" refers broadly to a plant, a plant structure, a plant tissue, a plant seed or a plant cell that contains at least one heterologous gene in one or more of its cells.

The term "transgene" refers to a foreign gene that is placed into an organism or host cell by the process of transfection. The term "foreign nucleic acid" or refers to any nucleic acid (e.g., encoding a promoter or coding region) that is introduced into the genome of an organism or tissue of an organism or a host cell by experimental manipulations, such as those described herein, and may include nucleic acid sequences found in that organism so long as the introduced gene does not reside in the same location, as does the naturally occurring gene.

The term "host cell" refers to any cell capable of replicating and/or transcribing and/or translating a heterologous nucleic acid. Thus, a "host cell" refers to any eukaryotic or prokaryotic cell (e.g., plant cells, algal cells, bacterial cells, yeast cells, E. coli, insect cells, etc.), whether located in vitro or in vivo. For example, a host cell may be located in a transgenic plant, or located in a plant part or part of a plant tissue or in cell culture.

As used herein, the term "wild-type" when made in reference to a gene refers to a functional gene common throughout an outbred population. As used herein, the term "wild-type" when made in reference to a gene product refers to a functional gene product common throughout an outbred population. A functional wild-type gene is that which is most frequently observed in a population and is thus arbitrarily designated the "normal" or "wild-type" form of the gene.

As used herein, the term "plant" is used in its broadest sense. It includes, but is not limited to, any species of grass (e.g. turf grass), ornamental or decorative, crop or cereal, fodder or forage, fruit or vegetable, fruit plant or vegetable plant, herb plant, woody plant, flower plant or tree. It is not meant to limit a plant to any particular structure. It also refers to a unicellular plant (e.g. microalga) and a plurality of plant cells that are largely differentiated into a colony (e.g. volvox) or a structure that is present at any stage of a plant's development. Such structures include, but are not limited to, a seed, a tiller, a sprig, a stolen, a plug, a rhizome, a shoot, a stem, a leaf, a flower petal, a fruit, et cetera.

The term "plant tissue" includes differentiated and undifferentiated tissues of plants including those present in roots, shoots, leaves, pollen, seeds and tumors, as well as cells in culture (e.g., single cells, protoplasts, embryos, callus, etc.). Plant tissue may be in planta, in organ culture, tissue culture, or cell culture.

As used herein, the term "plant part" as used herein refers to a plant structure or a plant tissue, for example, pollen, an ovule, a tissue, a pod, a seed, a leaf and a cell. Plant parts may comprise one or more of a tiller, plug, rhizome, sprig, stolen, meristem, crown, and the like. In some instances, the plant part can include vegetative tissues of the plant.

Vegetative tissues or vegetative plant parts do not include plant seeds, and instead include non-seed tissues or parts of a plant. The vegetative tissues can include

reproductive tissues of a plant, but not the mature seeds.

The term "seed" refers to a ripened ovule, consisting of the embryo and a casing.

The term "propagation" refers to the process of producing new plants, either by vegetative means involving the rooting or grafting of pieces of a plant, or by sowing seeds. The terms "vegetative propagation" and "asexual reproduction" refer to the ability of plants to reproduce without sexual reproduction, by producing new plants from existing vegetative structures that are clones, i.e., plants that are identical in all attributes to the mother plant and to one another. For example, the division of a clump, rooting of proliferations, or cutting of mature crowns can produce a new plant.

The term "heterologous" when used in reference to a nucleic acid refers to a nucleic acid that has been manipulated in some way. For example, a heterologous nucleic acid includes a nucleic acid from one species introduced into another species. A heterologous nucleic acid also includes a nucleic acid native to an organism that has been altered in some way (e.g., mutated, added in multiple copies, linked to a non-native promoter or enhancer sequence, etc.). Heterologous nucleic acids can include cDNA forms of a nucleic acid; the cDNA may be expressed in either a sense (to produce mRNA) or anti-sense orientation (to produce an anti-sense RNA transcript that is complementary to the mRNA transcript). For example, heterologous nucleic acids can be distinguished from endogenous plant nucleic acids in that the heterologous nucleic acids are typically joined to nucleic acids comprising regulatory elements such as promoters that are not found naturally associated with the natural gene for the protein encoded by the heterologous gene. Heterologous nucleic acids can also be distinguished from endogenous plant nucleic acids in that the heterologous nucleic acids are in an unnatural chromosomal location, or are associated with portions of the chromosome not found in nature (e.g., the heterologous nucleic acids are expressed in tissues where the gene is not normally expressed).

The term "expression" when used in reference to a nucleic acid sequence, such as a gene, refers to the process of converting genetic information encoded in a gene into RNA (e.g., mRNA, rRNA, tRNA, or snRNA) through "transcription" of the gene (i.e., via the enzymatic action of an RNA polymerase), and into protein where applicable (as when a gene encodes a protein), through "translation" of mRNA. Gene expression can be regulated at many stages in the process. "Up-regulation" or "activation" refers to regulation that increases the production of gene expression products (i.e., RNA or protein), while "down-regulation" or "repression" refers to regulation that decrease production. Molecules (e.g., transcription factors) that are involved in up-regulation or down- regulation are often called "activators" and "repressors," respectively.

The terms "in operable combination," "in operable order," and "operably linked" refer to the linkage of nucleic acid sequences in such a manner that a nucleic acid molecule capable of directing the transcription of a coding region (e.g., gene) and/or the synthesis of a desired protein molecule is produced. The term also refers to the linkage of amino acid sequences in such a manner so that a functional protein is produced. Transcriptional control signals in eukaryotes comprise "promoter" and "enhancer" elements. Promoters and enhancers consist of short arrays of DNA sequences that interact specifically with cellular proteins involved in transcription (see, for e.g., Maniatis, et al. (1987) Science 236:1237; herein incorporated by reference). Promoter and enhancer elements have been isolated from a variety of eukaryotic sources including genes in yeast, insect, mammalian and plant cells. Promoter and enhancer elements have also been isolated from viruses and analogous control elements, such as promoters, are also found in prokaryotes. The selection of a particular promoter and of a particular enhancer depends on the cell type used to express the protein of interest. Some eukaryotic promoters and enhancers have a broad host range while others are functional in a limited subset of cell types (for review, see Maniatis, et al. (1987), supra; herein incorporated by reference).

The terms "promoter element," "promoter," or "promoter sequence" refer to a DNA sequence that is located at the 5' end of the coding region of a DNA polymer. The location of most promoters known in nature is 5' to the transcribed region. The promoter functions as a switch, activating the expression of a gene. If the gene is activated, it is said to be transcribed, or is participating in transcription. Transcription involves the synthesis of mRNA from the gene. The promoter, therefore, serves as a transcriptional regulatory element and also provides a site for initiation of transcription of the gene into mRNA.

The term "regulatory region" refers to a gene's 5' transcribed but untranslated regions, located immediately downstream from the promoter and ending just prior to the translational start of the gene.

The term "promoter region" refers to the region immediately upstream of the coding region of a DNA polymer, and is typically between about 500 bp and 4 kb in length, and is preferably about 1 to 1.5 kb in length. Promoters may be tissue specific or cell specific.

The term "tissue specific" as it applies to a promoter refers to a promoter that can direct selective expression of a nucleic acid of interest to a specific type of tissue (e.g., vegetative tissues) in the relative absence of expression of the same nucleic acid of interest in a different type of tissue (e.g., seeds). Tissue specificity of a promoter may be evaluated by, for example, operably linking a reporter gene and/or a reporter gene expressing a reporter molecule, to the promoter sequence to generate a reporter construct, introducing the reporter construct into the genome of a plant such that the reporter construct is integrated into every tissue of the resulting transgenic plant, and detecting the expression of the reporter gene (e.g., detecting mRNA, protein, or the activity of a protein encoded by the reporter gene) in different tissues of the transgenic plant. The detection of a greater level of expression of the reporter gene in one or more tissues relative to the level of expression of the reporter gene in other tissues shows that the promoter is specific for the tissues in which greater levels of expression are detected.

The term "cell type specific" as applied to a promoter refers to a promoter that is capable of directing selective expression of a nucleic acid of interest in a specific type of cell in the relative absence of expression of the same nucleic acid of interest in a different type of cell within the same tissue. The term "cell type specific" when applied to a promoter also means a promoter capable of promoting selective expression of a nucleotide sequence of interest in a region within a single tissue. Cell type specificity of a promoter may be assessed using methods well known in the art, e.g., immunohistochemical staining. Briefly, tissue sections are embedded in paraffin, and paraffin sections are reacted with a primary antibody that is specific for the polypeptide product encoded by the nucleic acid of interest whose expression is controlled by the promoter. A labeled (e.g., peroxidase conjugated) secondary antibody that is specific for the primary antibody can bind to the sectioned tissue and specific binding detected (e.g., with avidin/biotin) by microscopy.

Promoters may be "constitutive" or "inducible." The term "constitutive" when made in reference to a promoter means that the promoter can direct transcription of an operably linked nucleic acid in the absence of a stimulus (e.g., heat shock, chemicals, light, etc.). Typically, constitutive promoters are capable of directing expression of a trans gene in substantially any cell and any tissue. Exemplary constitutive plant promoters include, but are not limited to Cauliflower Mosaic Virus (CaMV SD; see e.g., U.S. Pat. No. 5,352,605, incorporated herein by reference), mannopine synthase, octopine synthase (ocs), superpromoter (see e.g., WO 95/14098; herein incorporated by reference), and ubi3 promoters (see e.g., Garbarino and Belknap, Plant Mol. Biol. 24: 119-127 (1994); herein incorporated by reference). Such promoters have been used successfully to direct the expression of heterologous nucleic acid sequences in transformed plant tissue.

In contrast, an "inducible" promoter is one that can direct a level of transcription of an operably linked nucleic acid in the presence of a stimulus (e.g., heat shock, chemicals, light, etc.) that is different from the level of transcription of the operably linked nucleic acid in the absence of the stimulus.

The term "vector" refers to nucleic acid molecules that transfer DNA segment(s). Transfer can be into a cell, cell to cell, et cetera. The term "vehicle" is sometimes used interchangeably with "vector." The vector can, for example, be a plasmid. But the vector need not be plasmid.

The following non-limiting Examples illustrate how aspects of the invention have been developed and can be made and used.

Example 1: Materials and Methods

This Example describes some of the materials and methods employed in the development of the invention.

Plant Material and Growth Conditions

Experiments were performed with Arabidopsis thaliana ecotype Columbia (Col-0). Seeds of T-DNA insertion lines SALK_102149 ipUpl-1) and SALK_147687 (plipl-2) were obtained from the Arabidopsis Biological Resource Center, Ohio State University. Lines overexpressing PUP I (or PLIPl ⁵⁴²² ^ were generated by subcloning the coding sequence of PLIP1 or PLIP1 ^S422A (see below for their origin) into pEarleyGate 101 (YFP at the C- terminus) (Earley et al., 2006), followed by introducing constructs into Col-0 plants by Agrobacterium tumefaciens-mediated floral dip (Clough and Bent, 1998). Transformed seeds were initially screened for resistance to Basta, followed by confirmation by RT-PCR. Primers used for genotyping of T-DNA insertion lines or for RT-PCR analysis of overexpression lines are given in Table 1. Arabidopsis seeds were vernalized at 4 °C in the dark for two days before being sown on soil, and grown under 100 μΕ m ^~2 s ^_1 in a 16 h light (22 °C) and 8h dark (20 °C) cycle. Alternatively, sterilized and vernalized seeds were sown onto phytoagar plates containing 1 x Murashige and Skoog (MS) growth medium (Murashige and Skoog, 1962) and 1 % sucrose under 100 μΕ m ^~2 s ^_1 in the same light/dark cycle at 22 °C (Wang et al, 2016).

Quantitative Real-Time PCR

Total RNA was isolated from leaves of 4-week-old Arabidopsis plants grown on soil as previously described (Wang et al., 2016) using an RNeasy Plant Mini kit (Qiagen). Total RNA (600 ng) was used to synthesize complementary DNA using Superscript III Reverse Transcriptase (Invitrogen). qRT-PCR was performed using the SYBR Green PCR Core Reagents mix (Life Technologies) based on the manufacturer's instructions. The 2 ^{" Ct} calculation was used to determine the relative mRNA levels. Table 1 lists the primers used. Reference primers were as previously described (Robinson and Bolhuis, 2001).

Table 1: Primer sequences PEG_PLIP1 F CACCATGGCGTTTAATACGGCTATG 35

PEG101_PLIP1 R GACACGTGTCATGATCTCCTCGG 36

PEG104_PLIP1 R TTAGACACGTGTCATGATCTCCTCG 37

BamHI_PLIPl F TCGGATCCATGGCGTTTAATACGGCTATG 38

PLIPl_XhoI R GACTCGAGTTAGACACGTGTCATGATCTCC 39 pET41a_His del F ATGTATATCTCCTTCTAAAGTAAACAAA 40 pET41a_His del R ATGGCGTTTAATACGGCTATG 41

PLIP1_TP_Q5 F GCCGAGGAGATCATGACACGTGTC 42

PLIP1_TP_Q5 R ACGAACAGACACAGCAAGAATGCG 43

PLIP1_S422A F AGTCTCTCATTAATAGTGAATTTGATGCTTATC 44

PLIP1_S422A R GCCTCCAAGAGCATGACCCGTG 45

PLIP1_D483A F GAGCCTTTTCGTGTAATTATCCTGACCA 46

PLIP1_D483A R GTGGGACGATAGCTCTATGCATCA 47

PLIPl_qPCR F AGTTCTATAATCCCAAGTCCGA 48

PLIPl_qPCR R CTCCTTATCTCAAGCAGCCT 49

TIP-41_like qPCR F GTGAAAACTGTTGGAGAGAAGCAA 50

TIP-41_like qPCR R TCAACTGGATACCCTTTCGCA 51

PDF2 qPCR F TAACGTGGCCAAAATGATGC 52

PDF2 qPCR R GTTCTCCACAACCGCTTGGT 53

LBbl.3 ATTTTGCCGATTTCGGAAC 54 plipl-1 LP AGATTCTAGCGGAGCTTGGTC 55 plipl-1 RP GCCTCTTCAAACCAAATCTCC 56 plipl-2 LP TTATTACCGGAGCGACAACAC 57 plipl-2 RP TCCAATAACGGTTAAGCAACG 58 fad3-2 genotype F GTCACGATGAGAAGTTGCCTTGG 59 fad3-2 genotype R CAATGTCGTGATGAATGTTGTTAAAGAAT 60

Confocal Laser Scanning Microscopy

Imaging of YFP fusions was performed on leaves of 4-week-old Arabidopsis grown on soil using an Olympus FluoView 1000 confocal laser scanning microscope (Olympus) with excitation at 514 ran and emissions at 600 nm. Chlorophyll autofluorescence was visualized using excitation at 633 nm and emission at 700 nm. Images were merged and pseudocolored using Olympus FluoView 1000 confocal microscope software (Olympus). Protein Extraction and Immunoblot Analysis

Intact chloroplasts were isolated from 4-week-old Arabidopsis plants grown on MS medium essentially according to (Aronsson and Jarvis, 2002; Roston et al., 2011), followed by sub-fractionation into stroma and thylakoid according to (Keegstra and Yousif, 1986; Roston et al., 2012) with minor modifications. In brief, isolated intact chloroplasts were pelleted and ruptured by resuspension in hypertonic solution (0.6 M sucrose in TE buffer) and the suspension was homogenized with a Dounce tissue homogenizer. After incubation on ice for 10 min, bulk thylakoid fractions were harvested by three 1500 x g 5-min centrifugations at 4 °C. Supernatants were subjected to another 100,000 x g 2-h centrifugation at 4 °C to remove envelope membranes, and the final supernatants were harvested as the stroma fraction. Total protein from each fraction was extracted using a Plant Total Protein Extraction Kit (Sigma) according to the manufacturer's instructions, and protein was quantified using the Bio-Rad Bradford assay. Appropriate amounts of extracted organellar or total cellular protein were separated by SDS-PAGE (4-20% gradient, Bio- Rad), transferred to polyvinylidene fluoride membranes (Bio-Rad) and subjected to immunoblot analysis using primary antisera in 1 :1000 to 1 :5000 dilutions in TBST buffer (137 mM NaCl; 20mM Tris base pH 7.5; 0.5% Tween-20). Secondary anti-rabbit or anti- chicken IgG antibodies were diluted 1 :10,000. Positive immunoreactions were visualized using the Horseradish Peroxidase reaction with SuperSignal West Dura Extended Duration Substrate (Thermo Scientific), and the chemiluminescent signal was captured using the ChemiDoc™ MP imaging system (Bio-Rad) according to the manufacturer's instructions. Recombinant Protein and Antiserum Production

The PLIP1 sequence was amplified from Arabidopsis wild-type cDNA (see above under RT-PCR procedure) and inserted into pGEM-T-EASY plasmid (Promega). It was then subcloned into the pET41a plasmid through BamHI and Xhol restriction sites. The PLIP1 ^S422A point mutation construct was generated with a Q5 Site-Directed Mutagenesis Kit (New England Bio labs). Constructs were confirmed by sequencing. Final pET41a- PLIP1 and pET41 a-PLIPl ^S422A constructs were transformed into BL21 (DE3) E. coli strains for protein production. Cultures grown in LB medium (containing 0.1% glucose) were inoculated with fresh E. coli colonies and grown to log phase (OD ₂ 600.8) at 37 °C. Protein production was then induced by adding isopropyl- -D-thiogalactopyranoside (IPTG) to the final concentration of 0.2 mM, and the culture was transferred to 14 °C. Cells were harvested after 3 h of induction. Cultures were harvested and sonicated to lyse cells. Supernatant was collected after centrifugation at 10,000 x g for 30 min, and subjected to another 1-h centrifugation at 100,000 x g to remove the majority of membrane bound PLIPl . The finally harvested supernatant was used to extract and purify PLIPl recombinant proteins using a Ni-NTA column as described (Lu and Benning, 2009), except with a modified washing buffer (50 mM Tris HC1, pH 7.5 ; 600 mM NaCl; 40 mM imidazole). Purified protein was concentrated using an Amicon Ultra- 15 Centrifugal Filter (Millipore, UFC901024) and recovered with 1 x PBS buffer. The protein was quantified using the Bio-Rad Bradford assay, before the protein was aliquoted and stored at -20 °C with 30% glycerol.

Recombinant PLIP1 ^S422A was produced in E. coli and purified with a Ni-NTA column as described above. Purified protein was separated by SDS-PAGE and the corresponding band of PLIP1 ^S422A was isolated. Protein was recovered by immersing gel bands into 1 x PBS buffer at 4 °C overnight with gentle agitation. Recovered proteins were concentrated with an Amicon Ultra-15 Centrifugal Filter to a final purity above 98%. Antisera were raised in rabbits by Cocalico Biologicals, Inc. using their standard protocol. Chloroplast Import Assay

The N-terminal 6xHis tag and TEV cleavage site of pET4la-PLIPl were removed using a Q5 Site-Directed Mutagenesis Kit (New England Biolabs) and the construct was confirmed by sequencing prior to use for import assays. The FtsH8 gene was used as control. Isolation of pea chloroplasts, import assays and post-import trypsin treatment were done as previously described (Xu et al. , 2005).

PLIPl Lipase Assay

Commercial lipid substrates were purchased from Avanti Polar Lipids Inc. For each PLIPl lipase reaction, 60 μg lipids were used. The organic solvent was removed under an N2 stream, and the lipids were resuspended in 300 reaction buffer (0.1 M PBS, pH 7.4; 4.2 mM Anzergent 3-12 (Anatrace)) and dispersed by sonication for 3 x 10 s on ice (Misonix; Sonicator 3000 with microprobe; power setting 1.5). Then, 0.5 μg protein in 20 μΕ 1 x PBS with 30% glycerol was added to each reaction. The mixture was sonicated again for 10 s with the same parameters mentioned above and incubated at ambient temperature (-22 °C) for 1.5 h or as indicated for time courses. The reaction was stopped by lipid extraction, followed by lipid analysis with TLC and gas chromatography as described below.

To prepare tobacco phosphatidylglycerol (PG) substrates, total lipids were isolated from 4-week-old plant leaves and resolved by polar thin layer chromatography (TLC). The phosphatidylglycerol bands were isolated and lipids were recovered from silica powder by extraction with chloroform-methanol (1 : 1 by volume). Lipid Analysis

Lipid extraction, TLC of polar and neutral lipids, transesterification, and gas chromatography were done as described in (Wang and Benning, 2011). Polar lipids were analyzed on activated ammonium sulfate-impregnated silica gel TLC plates (TLC Silica gel 60; EMD Chemical, Germany) using a solvent system consisting of acetone, toluene and water (91 :30:7-7.5 by volume). The water amount adjusted according to ambient humidity (in general, 7 for summer; 7.5 for winter). This solvent system was also used for separation of lyso-lipids derived from monogalactosyldiacylglycerol, (MGDG) and phosphatidylglycerol during in vitro lipase assays. For triacylglycerol (TAG) quantification, lipids were resolved by TLC on DC-Fertigplatten SIL G-2 (MACHEREY-NAGEL, Germany) using a solvent system consisting of petroleum ether, ether and acetic acid (80:20:1 by volume). For total fatty acid analysis of dry seeds, 3 h transesterification was conducted directly on a number of seeds as specified. Lipids were visualized on TLC plates by brief exposure to iodine vapor. To separate lyso-lipids from phosphatidylcholine (PC), phosphatidylethanolamine (PE), or phosphatidylinositol (PI), a solvent system consisting of chloroform, methanol, glacial acetic acid and water (65:35:8:5 by volume) was used. To separate lyso-PS from PS, the running solvent consisted of chloroform, methanol and ammonium hydroxide (28-30% NH3 in water) (65:25:5 by volume). To separate lyso-lipids from digalactosyldiacylglycerol, (DGDG) and sulfoquinovosyldiacylglycerol (SQDG) the running solvent contained chloroform, methanol, glacial acetic acid and water (85:20:10:4 by volume).

Pulse- Chase Labeling

For leaf labeling experiments, detached leaves from 4-week-old soil-grown plants were incubated in non-radioactive medium (25mM MES-KOH, pH 5.7; 0.01 % Triton X- 100) under light (-40 μΕ m ^~2 s ^_1 ) at ambient temperature for 1 h. Radiolabeling was initiated by adding sodium [ ¹⁴ C]-acetate (specific activity 100 mCi/mmol in ethanol; American Radiolabeled Chemicals, Inc.) to the medium to provide 1 μ^πιΕ followed by a 1 -hour incubation with gentle agitation. The leaves were then washed twice in non-radioactive medium prior to incubation in non-radioactive medium for another 48 hours. At various time points after application of the label, samples were harvested and the metabolism was halted by immediate lipid extraction. Lipids were extracted and separated by TLC as described above, and radioactivity in each lipid fraction was analyzed using a scintillation counter (MicroBeta Trilux, Perkin Elmer) with 3 ml of scintillator solution (4a20, Research Products International Corporation) for 1 min per sample, or using phosphorimaging (FBCS 810, Fisher Biotech) with quantification by Quantity One (V 4.6.6).

Embryo labeling experiments were done as described (Bates et al., 2012). Briefly, the newly opened flowers of 4- week-old soil-grown plants were tagged, and nine days later, siliques were harvested for embryo isolation. For each time point, a 100 μL· volume of embryos was collected from approximately 50 siliques, and pre-incubated in nonradioactive buffer (5 mM MES, pH 5.8; 0.5% sucrose; 0.5 x MS) under light (-40 μΕ m ^~2 s ^_1 ) for 20 min with gentle agitation at room temperature. Labeling was initiated by removing the old medium and replacing it with the same medium containing 5 μθ sodium [ ¹⁴ C] acetate. Pulse labeling lasted for one hour, followed by washing and replacing with non-radioactive medium to start the chase. Samples were collected at indicated time points, and the reaction was quenched by immediate lipid extraction as described above.

Observation of Embryo Morphology

Siliques were harvested nine days after flowering and subsequently cleared with a clearing solution (chloral hydrate : glycerol : water = 8 :2 :1) according to (Herr Jr, 1993). Developing embryos were dissected from siliques after clearance and observed under a Nikon C2 microscope.

Accession Number

Sequences can be found in the Arabidopsis TAIR database (see website at www.arabidopsis.org/) under the following accession numbers: At3g61680 for PLIP1, At2g29980 for FAD3, At4g27030 for FAD4, At5g42020 for BIP2, Atlg06430 for FTSH8.

The At3g61680 sequence for the PLIP1 protein is shown below as SEQ ID NO: l.

1 MAFNTAMAST SPAAANDVLR EHIGLRRSLS GQDLVLKGGG IRRSSSDNHL 51 CCRSGNNNNR ILAVSVRPGM KTSRSVGVFS FQISSSIIPS PIKTLLFETD 101 TSQDEQESDE IEIETEPNLD GAKKANWVER LLEIRRQWKR EQKTESGNSD 151 VAEESVDVTC GCEEEEGCIA NYGSVNGDWG RESFSRLLVK VSWSEAKKLS

201 QLAYLCNLAY TIPEIKGEDL RRNYGLKFVT SSLEKKAKAA ILREKLEQDP 251 THVPVITSPD LESEKQSQRS ASSSASAYKI AASAASYIHS CKEYDLSEPI

301 YKSAAAAQAA ASTMTAWAA GEEEKLEAAR ELQSLQSSPC EWFVCDDPNT 351 YTRCFVIQGS DSLASWKANL FFEPTKFEDT DVLVHRGIYE AAKGIYEQFL 401 PEITEHLSRH GDRAKFQFTG HSLGGSLSLI VNLMLISRGL VSSEAMKSW

451 TFGSPFVFCG GEKILAELGL DESHVHCVMM HRDIVPRAFS CNYPDHVALV 501 LKRLNGSFRT HPCLNKNKLL YSPMGKVYIL QPSESVSPTH PWLPPGNALY 551 ILENSNEGYS PTALRAFLNR PHPLETLSQR AAYGSEGSVL RDHDSKNYVK 601 AVNGVLRQHT KLIVRKARIQ RRSVWPVLTS AGRGLNESLT TAEEIMTRV

The At2g29980 sequence for the FAD3 protein is shown below as SEQ ID NO:61.

1 MVVAMDQRTN VNGDPGAGDR KKEERFDPSA QPPFKIGDIR AAIPKHCWVK 51 SPLRSMSYW RDI IAVAALA IAAVYVDSWF LWPLYWAAQG TLFWAIFVLG 101 HDCGHGSFSD IPLLNSWGH ILHSFILVPY HGWRISHRTH HQNHGHVEND 151 ESWVPLPERV YKKLPHSTRM LRYTVPLPML AYPLYLCYRS PGKEGSHFNP 201 YSSLFAPSER KLIATSTTCW SIMFVSLIAL SFVFGPLAVL KVYGVPYIIF 251 VMWLDAVTYL HHHGHDEKLP WYRGKEWSYL RGGLTTIDRD YGIFNNIHHD 301 IGTHVIHHLF PQIPHYHLVD ATKAAKHVLG RYYREPKTSG AIPIHLVESL 351 VASIKKDHYV SDTGDIVFYE TDPDLYVYAS DKSKIN

The At4g27030 sequence for the FAD4 protein is shown below as SEQ ID NO:28.

1 MAVSLPTKYP LRPITNIPKS HRPSLLRVRV TCSVTTTKPQ PNREKLLVEQ

51 RTVNLPLSND QSLQSTKPRP NREKLWEQR LASPPLSNDP TLKSTWTHRL

101 WVAAGCTTLF VSLAKSVIGG FDSHLCLEPA LAGYAGYILA DLGSGVYHWA

151 IDNYGDESTP VVGTQIEAFQ GHHKWPWTIT RRQFANNLHA LAQVITFTVL

201 PLDLAFNDPV FHGFVCTFAF CILFSQQFHA WAHGTKSKLP PLVVALQDMG

251 LLVSRRQHAE HHRAPYNNNY CIVSGAWNNV LDESKVFEAL EMVFYFQLGV

301 RPRSWSEPNS DWIEETEISN NQA

The At5g42020 sequence for the BIP2 protein is shown below as SEQ ID NO:62.

1 MARSFGANST VVLAIIFFGC LFAFSTAKEE ATKLGSVIGI DLGTTYSCVG 51 VYKNGHVEI I ANDQGNRITP SWVGFTDSER LIGEAAKNQA AVNPERTVFD 101 VKRLIGRKFE DKEVQKDRKL VPYQIVNKDG KPYIQVKIKD GETKVFSPEE 151 ISAMILTKMK ETAEAYLGKK IKDAVVTVPA YFNDAQRQAT KDAGVIAGLN 201 VARI INEPTA AAIAYGLDKK GGEKNILVFD LGGGTFDVSV LTIDNGVFEV 251 LSTNGDTHLG GEDFDHRIME YFIKLIKKKH QKDISKDNKA LGKLRRECER 301 AKRALSSQHQ VRVEIESLFD GVDLSEPLTR ARFEELNNDL FRKTMGPVKK 351 AMDDAGLQKS QIDEIVLVGG STRIPKVQQL LKDFFEGKEP NKGVNPDEAV 401 AYGAAVQGGI LSGEGGDETK DILLLDVAPL TLGIETVGGV MTKLIPRNTV 451 IPTKKSQVFT TYQDQQTTVS IQVFEGERSL TKDCRLLGKF DLTGVPPAPR 501 GTPQIEVTFE VDANGI LNVK AEDKASGKSE KITITNEKGR LSQEEIDRMV 551 KEAEEFAEED KKVKEKIDAR NALETYVYNM KNQVSDKDKL ADKLEGDEKE 601 KIEAATKEAL EWLDENQNSE KEEYDEKLKE VEAVCNPIIT AVYQRSGGAP 651 GAGGESSTEE EDESHDEL

The Atlg06430 sequence for the FTSH8 protein is shown below as SEQ ID NO:63.

1 MAASSACLLG NGLSVYTTKQ RFQKLGLDRT SKVTVVKASL DEKKHEGRRG 51 FFKLLLGNAA AGVGLLASGN ANADEQGQGV SSSRMSYSRF LEYLDKGRVE 101 KVDLYENGTI AIVEAVSPEL GNRIQRVRVQ LPGLSQELLQ KLRAKNIDFA 151 AHNAQEDQGS PILNLIGNLA FPVILIGGLF LLSRRSSGGM GGPGGPGFPL 201 QIGQSKAKFQ MEPNTGVTFD DVAGVDEAKQ DFMEVVEFLK KPERFTAVGA 251 RIPKGVLLVG PPGTGKTLLA KAIAGEAGVP FFSISGSEFV EMFVGVGASR 301 VRDLFKKAKE NAPCIVFVDE IDAVGRQRGT GIGGGNDERE QTLNQLLTEM 351 DGFEGNTGVI WAATNRADI LDSALLRPGR FDRQVSVDVP DVKGRTDILK 401 VHSGNKKFES GVSLEVIAMR TPGFSGADLA NLLNEAAILA GRRGKTAISS 451 KEIDDSIDRI VAGMEGTVMT DGKSKSLVAY HEVGHAICGT LTPGHDAVQK 501 VTLIPRGQAR GLTWFIPSDD PTLISKQQLF ARIVGGLGGR AAEEVIFGES 551 EVTTGAVSDL QQITGLAKQM VTTFGMSEIG PWSLMDSSEQ SDVIMRMMAR 601 NSMSEKLAND IDTAVKTLSD KAYEIALSQI RNNREAMDKI VEILLEKETM 651 SGDEFRAILS EFTEIPPENR VASSTSTSTP TPASV Example 2: PLIP1 is a chloroplast thylakoid associated protein

The Arabidopsis genome encodes approximately 300 putative lipases (Li-Beisson et al. , 2013 ; Troncoso-Ponce et al., 2013 ; Kelly and Feussner, 2016), among which 46 were included in the Chloroplast 2010 Project, aimed at assigning functions to nearly all plastid localized proteins (Lu et al., 2008; Ajjawi et al., 2010). The inventors hypothesized that some of these putative chloroplast lipases may play roles in the maintenance of photosynthetic membranes and perhaps have specialized roles in tissues with high demands on lipid metabolism such as developing seeds that accumulate TAG.

One of the predicted chloroplast lipase genes, At3g61680, encodes a protein with a conserved Lipase 3 domain and a strongly predicted transit peptide, was subsequently named PLIP1. With its Lipase 3 domain, this Arabidopsis protein has similarities to a bona fide lipase of Chlamydomonas, PGD1 , involved in the turnover of chloroplast MGDG, leading to the export of acyl groups and their incorporation into TAG following nutrient deprivation (Li et al., 2012), although the two proteins do not share sequence similarity outside the Lipase 3 domain and are not orthologues.

To experimentally verify the subcellular location of PLIP1 , the PLIP1 coding sequence derived from an Arabidopsis wild-type (Col-0) cDNA was spliced at its 3 '-end (creating a C-terminal fusion) to the open reading frame of yellow fluorescent protein (YFP). When the PLIPl-YFP construct was stably expressed in wild type under the control of the cauliflower mosaic virus (CaMV) 35S promoter, the YFP and chlorophyll signals overlapped (FIG. 1A). Although transgenic lines used in this experiment had constitutive expression of PLIPl-YFP, only about 10 to 15% of mesophyll chloroplasts showed YFP signals.

To corroborate the suborganellar location of PLIP1 , intact chloroplasts were isolated from 4-week-old wild-type seedlings, and further fractionated into thylakoid membranes and stroma. Immunoblot analysis of PLIP1 showed increasing signal intensity from whole plant tissue to intact chloroplasts and thylakoids, consistent with an association of PLIP1 with the thylakoids (FIG. IB). Fractionation quality was controlled for by including marker proteins for each fraction. The thylakoid protein Light Harvesting Complex b l (LHCb l) showed a similar intensity pattern as PLIP1. To exclude contamination with endoplasmic reticulum (ER) associated proteins, the ER specific marker BiP2 was also included (FIG. I B). The fractionation of the stroma-specific rubisco large subunit and the thylakoid- specific light-harvesting chlorophyll a/b-binding protein (LHCP) are visible on a Coomassie Brilliant Blue-stained SDS-PAGE gel (FIG. 1C). The PLIPl gene is predicted to encode a 71,735-D protein for which a molecular or biochemical function had not been experimentally determined. Based on the ARAMEMNON database, PLIPl is not predicted to contain any transmembrane domains (Schwacke et al., 2003). These data indicate that PLIPl is a peripheral thylakoid membrane protein. To learn more about its suborganellar location and processing enroute, the PLIPl cDNA was translated in vitro in the presence of labeled methionine. During the import of the translation product into isolated pea chloroplasts, the PLIPl precursor was processed into a smaller intermediate protein which was present in both stroma and chloroplast membrane fractions. In addition, the trypsin resistance of PLIPl indicated that it is inside the chloroplast (FIG. ID). Interestingly, the intermediate PLIPl form was further processed into a smaller mature protein, which mainly was associated with the stroma fraction. As a control for proper fractionation and import, thylakoid lumen localized FtsH8 (Rodrigues et al., 2011) was processed and imported into the thylakoids with a pattern that is different from PLIPl, suggesting that PLIPl is probably not imported into the thylakoid lumen, but attaches to the outside leaflet of thylakoid membranes and can be released into the stroma with additional processing. Summing all the localization data up, PLIPl is likely a thylakoid membrane associated protein.

Example 3: PLIPl is a phospholipase Ai with a preference for unsaturated acyl groups

PLIPl is annotated as a TAG lipase in Arabidopsis (see TAIR website at arabidopsis.org). An in vitro lipase assay was developed to verify PLIP activity and determine its enzymatic properties. However, expression of the recombinant PLIPl purified from E. coli that expressed the recombinant 6xHis-PLIPl construct was very low as detected by immunoblotting against the His tag. Analysis of transgenic E. coZi ^' -derived lipid extracts by thin-layer chromatography (TLC) showed that, when PLIPl was expressed, PG and phosphatidylethanolamine (PE), the two major polar lipids of E. coli, were degraded leading to the accumulation of free FAs (FIG. IE). This observation indicated that PLIPl is a lipase that releases acyl groups from PG and PE.

Lipases belong to a group of serine esterases with a lipase signature motif, an Asp-

His-Ser triad, with some exceptions having only a Ser-Asp dyad. In all cases Ser serves as the active site residue participating in the reaction mechanism (Brady et al., 1990; Winkler et al, 1990; Richmond and Smith, 2011 ; Kelly and Feussner, 2016). Alignment of the PLIPl protein sequence with those of classic lipases using NCBI's conserved domain database (Marchler-Bauer et al., 2015) identified two potential catalytic residues, Asp ⁴⁸³ and Ser ⁴²² . Replacing these two residues with Ala, respectively, abolished PLIPl lipase activity, when the respective mutant proteins were abundantly produced in E. coli, as PG and PE were not degraded (FIG. IF). Taken together, these data indicate that PLIPl is a lipase with a catalytic dyad with Ser ⁴²² as the catalytic residue. Taking advantage of the enhanced production of nonfunctional PLIPl ^S422A in E. coli as compared to the wild-type enzyme, the mutant protein was purified and an antibody was raised in rabbits to specifically detect PLIPl .

To develop an in vitro lipase assay, recombinant PLIPl and PLIPl ^S422A were produced in E. coli, and then were affinity-purified from the soluble fraction (FIG. 2A). Anzergent 3-12 was chosen as the solubilizing detergent from a series of other reagents, because of its high compatibility with PLIPl enzyme activity and because it was not co- chromatographing with native plant membrane lipids during subsequent TLC analysis. In the final optimized system, in vitro lipase activity of PLIPl was observed on a wide range of substrates (FIG. 2G-2H). As an example, which is shown in FIG. 2B,

phosphatidylcholine (PC) was provided to PLIPl and PLIPl ^S422A . At the end of the reaction, lipids were extracted and separated by TLC. Lipase activity based on the production of lyso-PC was only observed when PLIPl was present, but not when the _{PLIP 1} S422A _{was present} ( _{FIG 2} B).

To survey PLIPl substrate preference in vitro, most plant glycerolipids were offered to PLIPl, including galactoglycerolipids, phospholipids, as well as TAG (FIG. 2H). High enzyme activity was detected for all tested phospholipids and MGDG. Given the plastid location of PLIPl, possible native substrates were limited to PG and MGDG. Low activities detected for SQDG, DGDG and TAG indicated that these are not likely substrates of PLIPl (FIG. 2H). Based on these results, despite its conserved Lipase 3 domain, PLIPl is apparently not a TAG lipase.

PLIPl in vitro activity with PC and other glycerolipids as substrates always resulted in lyso-lipid products, indicating that PLIPl can only hydrolyze one of the two acyl-glyceryl ester bonds in glycerolipids. To investigate which glyceryl position PLIPl prefers, two PCs with reversed acyl compositions were offered to PLIPl . At the end of the reaction, lipids were extracted, lyso-PC was isolated by TLC, and FA methyl esters derived from the lyso- lipid were analyzed by liquid-gas chromatography.

FIG. 2C shows that for PC with a composition of Ιδ^/ΙόιΟ (sn-l/sn-2), 18:1 ^A9 was selectively cleaved and 16:0 was retained in the lyso-product. The result was reversed with PC containing Ιόιθ ΐδιΐ^ ⁹ because the lyso-product contained IS:1 ^A9 . Therefore, PLIPl is a lipase that prefers the sn-1 glyceryl position of the respective glycerolipid. To determine a possible acyl group preference of PLIPl at the sn-1 glyceryl position, PLIPl was offered different combinations of pure PC molecules carrying the same acyl groups at the sn-2, but acyl groups with different degree of saturation levels at the sn-1 position (FIG. 2D). Comparing 18:0/18: 1 with 18:1/18:1, PLIPl enzyme activity was approximately twice as high for 18:1/18: 1-PC. When comparing 18:0/18:2 with 18:2/18:2, PLIPl activity was nearly four times elevated for 18:2/18:2-PC. Therefore, PLIPl is a phospholipase Ai with a preference for more unsaturated acyl groups.

Example 4: 18:3/16:l ^A3t -PG is the native substrate of PLIPl The in vitro assays in combination with its established chloroplast location narrowed down possible native PLIPl substrates to MGDG and PG (FIG. 2H). However, given the complexity of native plant acyl compositions, this limited survey based on an in vitro lipase assay alone could only provide a first approximation of the likely PLIPl - preferred substrate in vivo. To assess PLIPl activity in its native biological context, Arabidopsis transgenic lines were prepared and used for PLIPl localization as described in previous Examples.

In total, 30 independent PLIP1-YFP (PLIPl-OX) and 14 PLIP1 ^S422A -YFP

(PLIP1 ^S422A -0X) overexpression Arabidopsis transgenic lines were generated and three PLIPl-OX Arabidopsis transgenic lines were selected as representatives. As shown in FIG. 3A, the PLIPl-OX lines had smaller rosettes and fewer leaves, which were slightly pale yellow, whereas PLIPl ^S422A -OX plants were indistinguishable from wild-type and empty vector control plants.

On a fresh weight basis, the total leaf acyl group content of the smaller PLIPl-OX plants was not reduced (Table 2).

Table 2. Leaf acyl group content in different genotypes

Genotypes Acyl Groups ^g/mg FW)

Col-0 3.48 ± 0.067 plipl-1 3.51 + 0.076 plipl-2 3.51 + 0.063

EV control 3.55 + 0.055

PLIP1 ^S422A -0X\ 3.53 + 0.055

PLIP1 ^S422A -0X2 3.59 + 0.049

PLIP -OXl 3.56 + 0.062

PLIPl -OX2 3.54 + 0.063

PLIPl -OX3 3.56 + 0.067

Acyl group contents are determined by the measurement of total leaf fatty acid methyl esters. Plants were grown on soil for 4 weeks. Four independent samples were averaged and the SD is indicated. FW, fresh weight. A comparison of the relative abundance of polar lipids and the acyl group composition of individual polar lipids of empty vector control plants and two PLIPl -OX lines is shown in FIG. 3. In PLIPl -OX lines, lipids associated with chloroplasts (MGDG, PG and DGDG) decreased, while lipids mostly associated with the ER (PC, PE and PI) increased, indicating a decreased ratio of plastid-to-extraplastidic membranes in PLIPl -OX lines. Acyl group analysis of individual membrane lipids showed the greatest changes for PG (FIG. 3B). Specifically, the ratio of 16:0 to 16:1^ was increased in PLIPl-OX lines. For 18 -carbon acyl groups, which are primarily present at the sn-1 position of plastid PG, polyunsaturated 18:3 decreased with a concurrent increase in relative abundance of 18:1 and 18:2. Based on these changes in the molecular composition of PG, \% ·3Ι\6:\ ^Δ3 '-Ϋθ is a preferred substrate of PLIPl in its native environment.

MGDG, the most abundant lipid in chloroplasts, also showed a subtly decreased ratio of 16:3 to 18:3 in PLIPl-OX lines. For ER lipids, a decrease in 18:2 and an increase in 18:1 was observed for PC (FIG. 3C), as well as for PE and PI. PLIPl is located in the chloroplast and is spatially separated from ER lipids. Observation of the ER lipid alteration shown, for example in FIG. 3C, indicated that turnover of chloroplast lipids can affect the synthesis of ER lipids (assuming that lipid precursors are transported from the chloroplast to ER). The other two photosynthetic membrane lipids, DGDG and SQDG showed very minor changes in their molecular compositions in PLIPl-OX lines, which was consistent with the low activity of PLIPl on DGDG and SQDG in vitro (FIG. 2G-2H).

Example 5: Overexpression of PLIPl accelerates recycling of lS-.^lie-.l^-VG acyls groups and their transfer to PC The analysis of PLIPl -OX lines described above represents the lipid composition at steady-state. However, lipid metabolism is a dynamic process, and pulse-chase labeling is an effective way of probing the dynamics of lipid metabolism and movement of acyl groups through different lipid pools and between organelles (Xu et al., 2008; Li et al., 2012). Therefore, pulse-chase labeling was employed of membrane lipids using [ ¹⁴ C]-acetate, which can be readily converted to acyl groups in plastids by the FA synthase complex.

The pulse phase of the experiment is shown in FIG. 3D. These results show that MGDG, PG and PC contain the majority of the label in empty vector (EV) control leaves with PG accounting for approximately 15% of the label after 1 hour. However, in PLIPl - OXl plants, incorporation of label into PG accounted for nearly 70% of total label at the end of the pulse phase. This result indicates that incorporation of de novo synthesized acyl groups into PG is greatly accelerated in PLIPl -OX lines. During the chase phase (FIG. 3E), PG rapidly lost most of the label (within a day), and the label concomitantly increased in PC and to a smaller extent in PE in the PLIPl -0X1 line. The EV control line showed less drastic changes in labeling during the chase phase. The rapid increase and subsequent loss of PG label in PLIPl -0X1 during the pulse and chase phases, respectively, indicates that a rapid acyl exchange occurs preferably on PG in these lines. These results support a conclusion that PG is the preferred PLIPl substrate in its native environment.

The most notable acyl group change observed in PLIPl -OX lines was the increased \6 θ ο-\6 \ ^Δ3 ' ratio in PG (FIG. 3B). However, 16-carbon FAs only exist at the sn-2 position of plastid PG. This indicates that acyl groups at the glycerol sn-2 position affect PLIPl catalyzed hydrolysis at the glyceryl sn-1 position of PG. To test this possibility, purified recombinant PLIPl was provided with a set of commercial PCs with 16:0 at the glyceryl sn-1 position, but 18 -carbon acyl groups of different saturation levels at the glyceryl sn-2 position. The highest enzyme activity was observed for PC with 18:2 at the sn-2 position, followed by 18:1 with lowest activity for 18:0 (FIG. 2E), indicating that unsaturated sn-2 acyl groups enhance PLIPl activity. Therefore, it follows that l6:l ^A3t should be favored over 16:0 at the sn-2 position of PG.

To test the hypothesis that 16:1^^ is favored over 16:0 at the sn-2 position of PG, plant derived PG composed of species containing 16 :0 or 16 : \ ^A3t at the glyceryl sn-2 position was extracted from tobacco leaves and offered to PLIPl in vitro. Total PG was degraded while lyso-PG was produced over time. The fraction of l6:l ^A3t in lyso-PG increased over time, while 16:0 decreased (FIG. 2F), indicating that 16:1^ ^Λ -ΡΟ is preferred by PLIPl under these conditions when native PG substrate is offered. The opposite pattern between 16:0 and 16: 1 ^A3t was observed in retained PG. Therefore, Ιδ ^/Ιό^^'-Ρϋ is the native substrate of PLIPl based on data gathered from the above described combination of in vitro and in vivo experiments.

Another interesting observation was noted during the chase phase of the labeling experiment: the sequential labeling of PG and PC points towards a precursor-product relationship between these two lipids, which was consistent with the decreased plastid-to- extraplastidic lipid ratio observed during steady-state lipids analysis of PLIP1-OX lines. The data indicated that 18:3 released from 18 :3/16 i l^'-PG was exported from the plastid and incorporated into PC. PC is known for its intermediate role in acyl editing involving desaturation of PC-acyl groups (18 :1 to 18 :2 and 18:3) followed by acyl exchange (Bates et al., 2007).

The inventors reasoned that the decreased 18 :2 content of PC in PLIP1-OX lines might be due to the increased competition for incorporation of plastid derived 18:3 into PC with the activity of ER desaturases FAD2 and FAD3 generating 18:3 from 18:1 and 18:2 bound to PC. To test this hypothesis, a PLIP1 -0X1 plant was crossed to afad3-2 mutant plant, which is deficient in the desaturation of 18 :2 to 18:3 for ER lipids (PC, PI and PE). The inventors expected that PLIP1 overexpression might rescue thefad3-2 defect. The fad3- 2 mutant had a decreased 18:3 content in ER lipids, while the overexpression of PLIP1 in the fad3-2 mutant background partially reversed this phenotype by increasing 18 :3 in ER lipids PC, PI and PE (FIG. 3F). These 18:3 acyl groups must have been derived from the chloroplast where the FAD7/8 desaturases (Li-Beisson et al., 2013) catalyze the lipid-linked desaturation of acyl groups from 18:2 to 18:3. This increase in 18:3 in PC is paralleled by a decrease in \%· Ι\6: \ ^Δ3 '-Ϋθ. Taken together, these data indicate that in PLIP1 -OX lines 18:3 increasingly moves from plastid \%·3Ι\6:\ ^Δ3 '-Ϋθ to PC, which interferes with desaturation of acyl groups on PC and the PC-based acyl editing process.

Example 6: Overexpression of PLIP1 increases TAG content in leaf tissues Accelerated recycling of the PG pool and exporting of 18:3 to PC only resulted in a minor increase of the amount of PC in leaves (FIG. 3), indicating that PC is an intermediate, not an end product.

To explore the ultimate fate of exported acyl groups in PLIP1-OX lines, TAG was analyzed from lyophilized whole rosettes of 4-week-old Arabidopsis plants. PLIP 1 -OX lines contained five to six-fold more TAG than WT and plipl mutant lines (FIG. 3G). Labeling of PLIPl-OX lines with [ ¹⁴ C]-acetate (FIG. 3H) confirmed that TAG labeling in PLIPl-OXl leaves during the first day of the chase was much higher than for the EV control plants and then stabilized. Interestingly, acyl group analysis of TAG in leaves also showed a pattern of decreased 18:2 and increased 18:1 and 18 :3 (FIG. 3I-3J), similar to the leaf PC acyl group composition found in PLIPl-OX lines. The trends were clearer when the ratios between 18:3 and 18:2 were calculated (FIG. 3I-3J). Similar acyl group compositions of PC and TAG in leaves indicated a precursor- and-product relationship, respectively. Taken together, the polar lipid and TAG labeling data (FIG. 3), and the rapid turnover of PG followed by increased label incorporation into PC and TAG within the first day of the chase, supported the hypothesis that label moves from PG-to-PC-to-TAG in leaves of the PLIPl- OX lines. Example 7: PLIP1 is involved in TAG synthesis during embryogenesis

The analysis of PLIP1 , thus far, has focused on its biochemical function in vitro and in vivo using overexpression lines. Querying the native tissue-specific and developmental expression of PLIP1 , the highest gene expression was detected primarily in seeds and in the reproductive tissues, including flowers and siliques (FIG. 4A). Considering the fact that PLIP1 encodes a lipase that has high expression during embryogenesis, the inventors postulated that PLIP1 might play a role in seed lipid metabolism, which is dominated by the synthesis of TAG. In fact, towards the end of seed development, over 90% of total acyl groups are stored in TAG (Li et al., 2006; Li-Beisson et al., 2013).

To explore the physiological function of PLIP1 during embryogenesis, two independent T-DNA insertion Arabidopsis lines were obtained (Alonso et al., 2003). The T-DNA allele corresponding to SALK_102149 was designated as plipl-1, and the second corresponding to SALK_147687 as plipl-2. The T-DNA insertions were in the 3' and 5' UTRs, respectively. Quantitative RT-PCR analysis indicated that both lines carry leaky alleles. Under normal growth conditions, the two plipl mutant alleles were physiologically indistinguishable from the wild-type plants (WT). Lipid analysis also showed no changes in vegetative tissues. However, in dry seeds, where PLIP1 has high expression levels, insertion lines showed an approximate 10% reduction of total seed acyl group content indicative of a decrease in TAG, while overexpression lines had a 40-50% increased seed acyl group content (FIG. 4B). Altered seed TAG amounts were consistent with seed weight changes; plipl mutants had smaller seeds, while the seeds of overexpression lines were larger (FIG. 4C). Concomitant with the decreased seed oil content, germination of the plipl mutant seeds was also compromised (FIG. 4D). However, it must be noted that mature PLIP1-OX lines had shorter and bushier inflorescences and that seed yield was decreased by approximately 60% for the PLIP1-OX lines. Thus, overall oil yield was not increased in the PLIP1-OX plants. Nevertheless, the plipl mutant phenotype indicated that PLIP1 might play a role in TAG synthesis during embryogenesis.

To gain more information on how the plastid-located PLIP1 contributes to TAG synthesis during embryogenesis, TAG acyl groups were analyzed in dry seeds. In the insertional mutants, especially in the slightly stronger plipl-2 allele, 18:3 increased relative to 18:1 (FIG. 4E). For the two PLIP1-OX lines, 18:2 FA decreased, while 18:3 and 18: 1 increased, a pattern that resembled the leaf PC acyl group profile (FIG. 3C). This indicated that increased TAG may be derived from increased flux of acyl groups through PC in the overexpression lines. From the lipid analysis in vegetative tissues above (FIG. 3), the inventors hypothesized that PLIPl in developing embryos contributes to TAG synthesis by catalyzing the turnover of PG increasing the flux of acyl groups into PC and ultimately TAG.

As discussed above, ΙδιΒ/ΙδιΙ^-ΡΘ is likely the native substrate of PLIPl andl 6: l ^A3t only exists at the sn-2 position of plastid PG. FAD4 is the enzyme in Arabidopsis that specifically introduces iraws-double bonds into the 16:0 acyl chain of PG (Gao et al., 2009). If our hypothesis that PLIPl contributes to embryonic TAG biosynthesis is correct, removal of Ιδιΐ^-ΡΘ should result in a similar seed phenotype as observed for the plipl mutants. To test this hypothesis, two FAD4 knockout lines, fad4-2 and fad4-3 (Gao et al., 2009), were characterized. Observations indicated that l6: l ^A3t was not detected in PG in either fad4-2 or fad4-3 leaf tissues. Similar to the plipl mutants, fad4-2 and fad4-3 showed a close to 10% reduction in total seed acyl group content, reduced seed weight, but no altered seed yield. The fad4-2 and fad4-3 mutants also had altered seed acyl group profiles, specifically decreased 18 :2 and increased 18:3 content, similar to the changes in plipl -2 seed acyl group composition (FIG. 4E). Taken together, these observations indicate that acyl groups in plastid 18:3/16: l^'-PG contribute to TAG biosynthesis during embryogenesis and that this requires PLIPl activity.

Example 8: Overexpression of PLIPl

increases PG recycling and TAG synthesis during embryogenesis

To determine whether increased turnover of plastid PG is responsible for increased TAG biosynthesis during embryogenesis in PLIP1-OX lines, siliques were harvested nine days after flowering from WT and PLIPl -OX1 plants and embryos were isolated. Embryos at this developmental stage have robust lipid metabolism (Le et al., 2010; Bates et al., 2012). However, siliques of the same age collected from PLIPl -OX1 plants were shorter than those from WT (FIG. 5A), which raised the concern that embryos from PLIPl-OXl and WT might be at different developmental stages. However, upon closer examination, WT and PLIPl-OXl had nearly mature embryos with fully developed cotyledons and radicals (FIG. 5B), indicating they were at similar developmental stage and likely metabolically comparable. Therefore, [ ¹⁴ C]-acetate pulse-chase labeling was performed on isolated embryos. Pulse time pointes were collected after 20 and 60 minutes and are shown before time 0 of the chase start on the X axis, followed by three chase time points (FIG. 5C). Compared to PC and TAG, plastid lipids PG and MGDG were not highly labeled, during embryogenesis, likely due to their small pool size; therefore, an expanded view for PG is shown in the lower graph of FIG. 5C. PLIPl -OX1 had higher incorporation of label into PG and increased turnover during the chase phase as was observed for the equivalent experiment done on leaves (FIG. 5C). The altered labeling patterns between PG and MGDG resembled those observed in leaf labeling assays (FIG. 3D and 3E). The most strongly labeled lipids were TAG and PC reflecting their end-product status (TAG) or large pool size (PC) in developing seeds. However, the much smaller PG pool (mostly in the chloroplast as I6: l ^zljt -PG) seemed to be more metabolically active in PLIPl-OXl than in WT. Incorporation of label into PG during the pulse under the conditions tested was faster than could be captured by the earliest sampling time points. The rate and extent of incorporation into TAG was increased in the PLIPl-OXl line consistent with increased total acyl group content in these seeds, while the PC pool was similarly labeled in the WT and overexpression lines.

Example 9: Transgenic Camelina expressing PLIP1 and PLIP1/FAD4

This Example describes generation of transgenic camelina (false flax) that express increased levels of PLIP1 and/or PLIP1/FAD. Camelina was selected as a transgenic host because it is a crop that can produce much more oil than Arabidopsis, it is an oil seed plant that is transformable, and transformation of Camelina is typically easier than

transformation of an oil seed plant such as Canola. Another reason for using Camelina is that it has a relatively short life cycle of about 3 months.

An example, of a vector for recombinant expression of PLIP1 is shown in FIG. 7.

The PLIP1 gene is under control of seed specific promoter, and a red fluorescence marker DsRED was used for selection of transformants. Another expression vector that included PLIP1 and hygromycin resistance coding regions was created. A further expression vector was made that included a FAD4 coding region downstream of the seed specific Oleosin promoter. An expression vector with Glycin-PLIPl and Oleosin- FAD4 expression cassettes was also prepared. See FIG. 7A-7D.

At least twenty camelina plants from ten independent PLIP1 transgenic events and the control empty vector lines were grown. There was no apparent growth difference between the empty vector control and the PLIP1 transgenic lines. No life-cycle differences were observed in the PLIP1 transgenic lines, and no differences were observed in germination rates compared to wild type. However, all transgenic plants were maturing faster than usual. T2 seeds were harvested.

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Plant Cell 17, 3094-3110. All patents and publications referenced or mentioned herein are indicative of the levels of skill of those skilled in the art to which the invention pertains, and each such referenced patent or publication is hereby specifically incorporated by reference to the same extent as if it had been incorporated by reference in its entirety individually or set forth herein in its entirety. Applicants reserve the right to physically incorporate into this specification any and all materials and information from any such cited patents or publications. The following statements of the invention are intended to describe and summarize various embodiments of the invention according to the foregoing description in the specification.

Statements:

1. An expression system comprising at least one expression cassette comprising a promoter operably linked to a heterologous nucleic acid segment encoding a plastid- specific lipase.

2. The expression system of statement 1, wherein the lipase has at least 90%, or at least 91%, or at least 93%, or at least 95%, or at least 96%, or at least 97%, or at least 98%, or at least 99% sequence identity to SEQ ID NO: 1, 3-12, 14-21, 23-27, 64-70 or 71.

3. The expression system of statement 1 or 2, further comprising at least one expression cassette comprising a promoter operably linked to a nucleic acid segment encoding a FAD4.

4. The expression system of statement 1, 2, or 3, wherein the FAD4 has at least 90%, or at least 91%, or at least 93%, or at least 95%, or at least 96%, or at least 97%, or at least

98%, or at least 99% sequence identity to any of SEQ ID NOs: 28, 30-33, or 34.

5. The expression system of statement 1-3 or 4, wherein the nucleic acid encoding the lipase has at least 90%, or at least 91 %, or at least 93%, or at least 95%, or at least 96%, or at least 97%, or at least 98%, or at least 99% sequence identity to SEQ ID NO: 2, SEQ ID NO:13, or SEQ ID NO: 22.

6. The expression system of statement 1-4 or 5, wherein the nucleic acid encoding the FAD4 has at least 90%, or at least 91 %, or at least 93%, or at least 95%, or at least 96%, or at least 97%, or at least 98%, or at least 99% sequence identity to SEQ ID NO:29.

7. The expression system of statement 1-5 or 6, wherein the promoter operably linked to a heterologous nucleic acid segment encoding a lipase is an inducible promoter, a tissue-specific promoter, or a developmentally regulated promoter.

8. A plant cell comprising the expression system of statement 1-6 or 7.

9. The plant cell of statement 8, wherein the plant cell is not an Arabidopsis thaliana plant cell.

10. The plant cell of statement 8 or 9, wherein the plant cell is a food plant cell, vegetable oil plant cell, seed oil plant cell, forage plant cell, or fodder plant cell.

11. The plant cell of statement 8, 9, or 10, wherein the plant cell is a monocot or dicot.

12. The plant cell of statement 8-10 or 11, wherein the plant cell is an alfalfa, algae, avocado, barley, broccoli, Brussels sprout, cabbage, camelina, canola, cassava, cauliflower, coconut, cole vegetables, collard, corn, crucifers, flax, grain legumes, forage grasses, jatropa, kale, kohlrabi, maize, miscanthus, mustards, nut sedge, oats, oil firewood trees, oilseeds, olive, palm, peanut, potato, radish, rapeseed, rice, rutabaga, safflower, sorghum, soybean, sugar beets, sugarcane, sunflower, switchgrass, tobacco, tomato, turnips, or wheat plant cell.

13. A seed comprising the expression system of statement 1-6 or 7.

14. The seed of statement 13, wherein the seed is not an Arabidopsis thaliana seed.

15. The seed of statement 13 or 14, wherein the seed is a food plant seed, vegetable oil plant seed, seed oil plant seed, forage plant seed, or fodder plant seed.

16. The seed of statement 13, 14, or 15, wherein the seed is a monocot or dicot.

17. The seed of statement 13-15 or 16, wherein the seed is an alfalfa, algae, avocado, barley, broccoli, Brussels sprouts, cabbage, camelina, canola, cassava, cauliflower, coconut, cole vegetables, collards, crucifers, flax, grain legumes, forage grasses, jatropa, kale, kohlrabi, maize, miscanthus, mustards, nut sedge, oats, oil firewood trees, oilseeds, olive, palm, peanut, potato, radish, rice, rutabaga, safflower, sorghum, soybean, sugar beets, sugarcane, sunflower, switchgrass, tobacco, tomato, turnip, or wheat seed.

18. The seed of statement 13-16 or 17, wherein the seed has about 0.5% to about 60%, or about 0.5% to about 50%, or about 0.5% to about 40%, or about 0.5% to about 30%, or about 0.5% to about 25%, or about 1 % to about 20%, or about 2% to about 18%, or about 3% to about 15%, or about 5% to about 15% oil content.

19. The seed of statement 13-17 or 18, wherein the seed has at least about 1.2-fold, at least about 1.5-fold, least about 2-fold, at least about 3-fold, at least about 4-fold, at least about 5-fold, at least about 7-fold, at least about 10-fold, at least about 12-fold, at least about 15-fold more oil, as measured by percent oil per dry weight, than a seed of the same species that has not been modified to contain the expression system.

20. A plant comprising the expression system of statement 1-6 or 7.

21. The plant of statement 20, wherein the plant is not an Arabidopsis thaliana plant.

22. The plant of statement 20 or 21 , wherein the plant is a food plant, vegetable oil plant, seed oil plant, forage plant, or fodder plant.

23. The plant of statement 20, 21 or 22, wherein the plant is a monocot or dicot.

24. The plant of statement 20-22 or 23, wherein the plant is an alfalfa, algae, avocado, barley, broccoli, Brussels sprout, cabbage, camelina, canola, cassava, cauliflower, coconut, cole vegetables, collards, corn, crucifers, flax, grain legumes, forage grasses, jatropa, kale, kohlrabi, maize, miscanthus, mustards, nut sedge, oats, oil firewood trees, oilseeds, olive, palm, peanut, potato, radish, rapeseed, rice, rutabaga, safflower, sorghum, soybean, sugar beets, sugarcane, sunflower, switchgrass, tobacco, tomato, turnips, or wheat plant.

25. The plant of statement 20-23 or 24, wherein the plant tissues of the plant have about 0.5% to about 40%, or about 0.5% to about 35%, or about 0.5% to about 30%, or about 0.5% to about 25%, or about 0.5% to about 20%, or about 1% to about 18%, or about 2% to about 15%, or about 3% to about 15%, or about 5% to about 15% oil or lipid content.

26. The plant of statement 20-24 or 25, wherein the seed has at least about 1.2-fold, at least about 1.5-fold, least about 2-fold, at least about 3-fold, at least about 4-fold, at least about 5-fold, at least about 7-fold, at least about 10-fold, at least about 12-fold, or at least about 15-fold, more oil in its plant tissues, as measured by percent oil per dry weight, than a plant of the same species that has not been modified to contain the nucleic acid, expression cassette, or expression vector.

27. A method of generating oil comprising isolating tissues or seeds from the plant of any of statements 20-25 or 26 and extracting oil from the tissues or seeds.

28. The method of statement 27, further comprising cultivating the seed of statement 13-18 or 19 to generate the plant.

29. A method comprising cultivating the seed of statements 1-6 or 7.

30. The method of statement 29, further comprising generating at least one line of plants comprising a heterologous nucleic acid segment encoding a lipase with at least 90% amino acid sequence identity to any of SEQ ID NOs: 1, 3-12, 14-21 , 23-27, 64-70 or 71.

31. The method of statement 30, wherein the at least one line of plants is generated by transforming one or more plant cells with the expression system of any of statements 1-6, or 7 to generate one or more transgenic plant cells; generating one or more transgenic plants from the one or more transgenic plant cells; and clonally or vegetatively propagating at least one line of transgenic plants.

32. The method of statement 29, 30 or 31, wherein the plant is not an Arabidopsis thaliana plant.

33. The method of statement 29-31 or 32, wherein the plant is a food plant, vegetable oil plant, seed oil plant, forage plant, or fodder plant.

34. The method of statement 29-32 or 33, wherein the plant is a monocot or dicot.

35. The method of statements 28-33 or 34, wherein the plant is an alfalfa, algae, avocado, barley, broccoli, Brussels sprouts, cabbage, camelina, canola, cassava, cauliflower, coconut, cole vegetables, collards, crucifers, flax, grain legumes, forage grasses, jatropa, kale, kohlrabi, maize, miscanthus, mustards, nut sedge, oats, oil firewood trees, oilseeds, olive, palm, peanut, potato, radish, rice, rutabaga, safflower, sorghum, soybean, sugar beets, sugarcane, sunflower, switchgrass, tobacco, tomato, turnips, or wheat plant.

The specific compositions and methods described herein are representative, exemplary and not intended as limitations on the scope of the invention. Other objects, aspects, and embodiments will occur to those skilled in the art upon consideration of this specification, and are encompassed within the spirit of the invention as defined by the scope of the claims. It is apparent to one skilled in the art that varying substitutions and modifications may be made to the invention disclosed herein without departing from the scope and spirit of the invention. The terms and expressions that have been employed are used as terms of description and not of limitation, and there is no intent in the use of such terms and expressions to exclude any equivalent of the features shown and described or portions thereof, but it is recognized that various modifications are possible within the scope of the invention as claimed. Thus, it will be understood that although the present invention has been specifically disclosed by embodiments and optional features, modification and variation of the concepts herein disclosed may be resorted to by those skilled in the art, and that such modifications and variations are considered to be within the scope of this invention as defined by the appended claims and statements of the invention.

The invention illustratively described herein may be practiced in the absence of any element or elements, or limitation or limitations, which is not specifically disclosed herein as essential. The methods and processes illustratively described herein may be practiced in differing orders of steps, and the methods and processes are not necessarily restricted to the orders of steps indicated herein or in the claims.

As used herein and in the appended claims, the singular forms "a," "an," and "the" include plural reference unless the context clearly dictates otherwise. Thus, for example, a reference to "a compound" or "a catalyst" or "a ligand" includes a plurality of such compounds, catalysts or ligands, and so forth. In this document, the term "or" is used to refer to a nonexclusive or, such that "A or B" includes "A but not B," "B but not A," and "A and B," unless otherwise indicated.

Under no circumstances may the patent be interpreted to be limited to the specific examples or embodiments or methods specifically disclosed herein. Under no circumstances may the patent be interpreted to be limited by any statement made by any Examiner or any other official or employee of the Patent and Trademark Office unless such statement is specifically and without qualification or reservation expressly adopted in a responsive writing by Applicants.

The invention has been described broadly and generically herein. Each of the narrower species and subgeneric groupings falling within the generic disclosure also form part of the invention. This includes the generic description of the invention with a proviso or negative limitation removing any subject matter from the genus, regardless of whether or not the excised material is specifically recited herein. In addition, where features or aspects of the invention are described in terms of Markush groups, those skilled in the art will recognize that the invention is also thereby described in terms of any individual member or subgroup of members of the Markush group.

The Abstract is provided to comply with 37 C.F.R. §1.72(b) to allow the reader to quickly ascertain the nature and gist of the technical disclosure. The Abstract is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.