The present invention relates to a process for the preparation of ammeline and/or ammelide. The invention further relates a product obtainable by the process according to the invention, wherein the product comprises ammeline and/or ammelide.

Ammeline (4,6-diamino-2-hydroxy-1 ,3,5-triazine) and ammelide (6- amino-2,4-dihydroxy-1 ,3,5-triazine) are 1 ,3,5-triazine compounds of industrial interest, e.g. for use in flame retardant compositions as mentioned for example in US4341694, JP55094953, JP59029676. They are however not commercially available on large, industrial scale today.

Several chemical routes have been investigated and described for the preparation of ammeline and ammelide (E. M. Smolin and L. Rapoport. 2008.

Ammelide, Ammeline and Related Compounds. In: Chemistry of heterocyclic compounds: s-Triazines and Derivatives. Volume 13. Chapter 5. p. 269-308). Such synthetic routes are quite laborious and troublesome. Furthermore, these require relatively expensive starting materials (e.g. dicyandiamide and biuret), severe reaction conditions (temperatures above 200°C), halogen-containing compounds, toxic solvents (e.g. phenols, cresols or xylenol), and the addition of alcohols (e.g. methanol) for the precipitation and recovery of the ammeline and/or ammelide from the solvent.

Additionally, these routes often lead to formation of ammeline and ammelide in uncontrolled ratios and to limited yields in combination with formation of varying quantities of by-products, e.g. cyanuric acid, of which removal by washing is difficult and expensive due its very low solubility. Accordingly, there is a need for alternative routes to ammeline and/or ammelide, preferably a more cost-effective process from cheap starting materials, such as melamine (2, 4, 6-triamino-1 ,3,5-triazine; also called sym-triamino-triazine).

It is an object of the present invention to provide a process for the preparation of ammeline and/or ammelide that would overcome one or more of the drawbacks mentioned above, in particular resulting in a high yield and low amount of by-products, thereby providing a commercially attractive process.

It is also an object of the present invention to provide a novel process for the preparation of ammeline and/or ammelide, wherein the ammeline:ammelide ratio can be fine-tuned. It is further an object of the present invention to provide a product that comprises ammeline and/or ammelide in a controlled ratio.

These objects have been achieved with the process according to the invention comprising a process for the preparation of ammeline and/or ammelide, wherein melamine is converted into ammeline, and optionally ammelide, by a solid-to- solid reaction in an aqueous reaction mixture comprising a biocatalyst and wherein the biocatalyst comprises at least one enzyme belonging to the amidohydrolase

superfamily and having aminohydrolase activity towards 1 ,3,5-triazine compounds.

In the process according to the invention, melamine is converted into ammeline, and optionally ammelide, by a "solid-to-solid" reaction. This means that in said reaction, only a small proportion of the substrate and/or the product is in solution at any time, while the remainder part of the substrate and/or product is in a solid phase. The starting solid melamine substrate dissolves progressively, passing through solution as it is converted to ammeline and/or ammelide, which then precipitate(s).

The solid-to-solid reaction according to the invention is carried out in an "aqueous reaction mixture" comprising solid substrate and/or product and a biocatalyst in an aqueous phase. Said aqueous phase is a liquid phase in which the predominant solvent is water.

"Biocatalyst" as defined herein is a biological material or moiety derived from a biological source that catalyzes the reaction step(s) in the process according to the invention. The biocatalyst may be in principle any organism, e.g. a microorganism, or a biomolecule derived there from. It may in particular comprise one or more enzymes.

The "amidohydrolase superfamily" is a structure-based cluster of "metal-dependent hydrolase" enzymes which contain a triosephosphate isomerase (TIM)-like barrel fold in the catalytic domain. Members of this superfamily catalyze the cleavage of not only C-N but also C-C, C-O, C-CI, C-S and O-P bonds of organic compounds (L. Aimin, L. Tingfeng, F. Rong. 2007. Amidohydrolase superfamily. In: Encyclopedia of life sciences 2007).

An "enzyme having aminohydrolase activity towards 1 ,3,5-triazine compounds" is an enzyme having hydrolytic activity towards amino-substituted 1 ,3,5- triazine compounds with the ability to convert one or more amino substituents to hydroxy substituents by hydrolysis of the C-N bond between a carbon atom in the triazine ring and the N-atom of the amino substituent, meanwhile generating ammonia (reaction scheme [1 ]).

wherein R., and R ₂ are

preferably NH ₂ groups

[1 ]

The "enzyme having aminohydrolase activity towards 1 ,3,5-triazine compounds" is also referred hereafter as "the enzyme".

In comparison with the methods of the prior art, the process according to the invention requires mild conditions. The process is carried out at moderate temperatures in the presence of an aqueous phase for the biocatalyst to remain active. The process is furthermore environment friendly with no use of toxic solvents, halogen-containing compounds or alcohols. The ammeline and/or ammelide directly precipitate(s) in the aqueous reaction mixture and their (its) recovery requires only a few washing steps using water. Another advantage of the process is the production of the desired product without formation of by-products, e.g. cyanuric acid, resulting in a loss of yield. It is envisaged that a method according to the invention allows a better yield than the chemical routes described in the prior art. High maximum conversions of melamine to ammeline and/or ammelide (up to about 99%) are achieved. An additional advantage of the process according to the invention over the chemical routes is the ability to fine-tune the ammeline:ammelide ratio.

The conversion of melamine to ammeline and/or ammelide is said to reach its "maximum conversion" when no significant reaction occurs despite the presence of unreacted substrate and biocatalyst.

Some studies have investigated the contribution of soil bacteria to melamine toxicity in humans and animals and have led to the identification of a bacterial melamine metabolic pathway, in which melamine was shown to be hydrolyzed into ammeline and ammelide by sequential deamination. The genes and enzymes involved in these two deamination steps have been identified and in some cases, the enzymes have been purified and characterized. The latter have been found to belong to the amidohydrolase superfamily (reaction scheme [2]; J.L. Seffernick, A.G. Dodge, M.J. Sadowsky, J.A. Bumpus and L.P. Wackett. 2010. Bacterial ammeline metabolism via guanine deaminase. J. Bacteriology 192(4), 1 106-1 1 12; A.G. Dodge, L.P. Wackett, M.J. Sadowsky. 2012. Plasmid localization and organization of melamine degradation genes in Rhodococcus sp. strain Mel. Applied and environmental microbiology 78(5), 1397-1403). These studies do not relate to the technical field of the present invention, i.e. process for the preparation of ammeline and/or ammelide from melamine by a solid-to-solid reaction in an aqueous reaction mixture comprising a biocatalyst, and there has been no indication that the enzymes identified in the bacterial melamine metabolic pathway could be suitably used in the process according to the invention.

The first two steps from the hydrolytic degradation pathway of melamine are shown in reaction scheme [2]. The genes encoding microbial enzymes that catalyze each step are indicated. The fr/A, frzA, aizB genes are encoding a melamine deaminase, a s-triazine hydrolase and a hydroxyatrazine hydrolase, respectively. GDA is an abbreviation of guanine deaminase. All of the enzymes are members of the amidohydrolase superfamily.

( riazine)

Ammelide

(6-amino-2,4-dihydroxy-1 ,3,5-triazine) [2]

In accordance with the invention, melamine is converted into ammeline, and optionally ammelide, by a "solid-to-solid" reaction in an aqueous reaction mixture comprising a biocatalyst. Reaction parameters (e.g. biocatalyst, aqueous phase, mixing, pH, temperature or substrate loading) may be varied in order to optimize the reaction and to obtain the desired product.

The biocatalyst according to the invention may be used in any form. The biocatalyst may be used for example in the form of (partially) purified enzyme, lyophilised enzyme powder, immobilized enzyme, whole cells (e.g. permeabilised, freeze-dried), immobilized whole cells, cell lysate or cell free extract.

It will be clear to the skilled person that use can be made of a naturally occurring biocatalyst (wild type) or a mutant of a naturally occurring biocatalyst with suitable activity in the process according to the invention. Properties of a naturally occurring biocatalyst may be improved by biological techniques known to the skilled person, such as e.g. molecular evolution or rational design. Mutants of wild- type biocatalysts can for example be made by modifying the encoding DNA of an organism capable of acting as a biocatalyst or capable of producing a biocatalytic moiety (e.g. an enzyme) using mutagenesis techniques known to the skilled person (e.g. random mutagenesis, site-directed mutagenesis, directed evolution, gene recombination). In particular, the DNA may be modified such that it encodes an enzyme that differs by at least one amino acid from the wild type enzyme, so that it encodes an enzyme that comprises one or more amino acid substitutions, deletions and/or insertions compared to the wild type, or such that the mutants combine sequences of two or more parent enzymes or by effecting the expression of the thus modified DNA in a suitable (host) cell. The latter may be achieved by methods known to the skilled person such as codon pair optimization, e.g. based on a method as described in WO 2008/000632.

A mutant biocatalyst may have improved properties, for instance with respect to one or more of the following aspects: selectivity towards the substrate, activity, stability, solvent tolerance, pH profile, temperature profile, substrate profile, susceptibility to inhibition, cofactor utilisation and substrate-affinity. Mutants with improved properties can be identified by applying e.g. suitable high through-put screening or selection methods based on such methods known to the skilled person.

A cell, in particular a recombinant cell, comprising one or more enzymes for catalysing the reaction step(s) in a process according to the invention can be constructed using molecular biology techniques, which are known in the art per se. For instance, if one or more exogenous enzymes are to be produced in a recombinant cell, such techniques can be used to provide a vector (e.g. a recombinant vector) which comprises one or more exogenous genes encoding one or more of said exogenous enzymes. One or more vectors may be used, each comprising one or more of such exogenous genes. Such vector can comprise one or more regulatory elements, e.g. one or more promoters, which may be operably linked to the gene(s) encoding the enzyme(s).

The term "exogenous" as it is used herein is intended to mean that the biomolecule (e.g. DNA, RNA, protein) is introduced into the host cell. The biomolecule can be, for example, a homologous (or heterologous) nucleic acid that encodes a homologous (or heterologous) protein following introduction into the host cell. The term "heterologous" refers to a biomolecule isolated from a donor source other than the host cell whereas the term "homologous" refers to a biomolecule isolated from the host cell. Accordingly, exogenous expression of an encoding nucleic acid of the invention can utilize either or both heterologous or homologous encoding nucleic acid.

As the inventors have found, the enzyme belonging to the

amidohydrolase superfamily and having aminohydrolase activity towards 1 ,3,5-triazine compounds (as used in the process according to the present invention) can be any suitable enzyme (i.e. the enzyme is suitable if it can be confirmed to have

aminohydrolase activity towards 1 ,3,5-triazine compounds) selected from the group consisting of melamine deaminase (also called melamine amidohydrolase), s-triazine hydrolase (also called N-ethylammeline chlorohydrolase), hydroxyatrazine hydrolase (also called atrazine chlorohydrolase), guanine deaminase (also called guanine amidohydrolase) and simazine chlorohydrolase.

In one embodiment, a suitable melamine deaminase might be selected from the group consisting of melamine deaminases originating from

Acidovorax, Ketogulonicigenium, Pseudomonas, Gordonia, Rhodococcus,

Micrococcus, Klebsiella, Williamsia, Nocardia, Arthrobacter, Nesterenkonia, Kocuria, Dermacoccus, Kytococcus and Enterobacter. In particular, said melamine deaminase might originate from Acidovorax citrulii (formerly called Pseudomonas citrulii),

Acidovorax avenae subspecies citrulii (formerly called Pseudomonas

pseudoalcaligenes subsp. citrulii), Ketogulonicigenium vulgare, Gordonia

rubripertinctus (also called Gordona rubripertincta; synonym to Rhodococcus corallinus), Klebsiella terragena or Micrococcus sp. strain MF-1 . More particularly, said melamine deaminase might originate from Acidovorax citrulii NRRL B-12227 or Ketogulonicigenium vulgare Y25.

In another embodiment, a suitable s-triazine hydrolase may be selected from the group consisting of s-triazine hydrolases originating from Gordonia, Rhodococcus, Saccharopolyspora, Streptococcus, Streptomyces, Enterococcus, Abiotrophia, Lactococcus, Ruminococcus, Gemalla, Atopobium, Streptoverticillium, Actinoplanes, Kitasatospora, Chainia and Actinosporangium. A suitable s-triazine hydrolase may in particular be selected from Gordonia rubripertinctus (also called Gordona rubripertincta; synonym to Rhodococcus corallinus), more particularly from Rhodococcus corallinus NRRL B-15444R.

In a further embodiment, a suitable hydroxyatrazine hydrolase may originate from Arthrobacter, Beta proteobacterium, Pseudomonas, Aminobacter, Micrococcus, Aureobacterium, Corynebacterium, Rhodococcus, Brevibacterium, Nocardioides, Terrabacter, Comamonas, Burkholderia, Brevundimonas, Vogesella, deleya, Methylobacterium, Herbaspirillum, Hydrogenophaga or Pseudoalteromonas. In particular, a suitable hydroxyatrazine hydrolase may originate from Pseudomonas sp. ADP or Aminobacter aminovorans.

In yet a further embodiment, a suitable guanine deaminase may be selected from the group consisting of guanine deaminases originating from

Brady rhizobium, Escherichia, Rhizobium and Leclercia. In particular, said guanine deaminase may originate from Bradyrhizobium japonicum or Escherichia coli. More particularly, said guanine deaminase may originate from Bradyrhizobium japonicum USDA 1 10 or Escherichia coli ETEC H10407.

In yet a further embodiment, a suitable simazine chlorohydrolase may be selected from the group consisting of simazine chlorohydrolases originating from Herbaspirillum. In particular, said simazine chlorohydrolase may originate from

Herbaspirillum sp. B601 .

In a specific embodiment, the enzyme belonging to the

amidohydrolase superfamily and having aminohydrolase activity towards 1 ,3,5-triazine compounds comprises an amino acid sequence represented by SEQ ID NO 5

(AAG41202.1 ), SEQ ID NO 6 (YP_003963954.1 ), SEQ ID NO 7 (Q52725.2), SEQ ID NO 8 (NP_770520.1 ) and SEQ ID NO 9 (CBJ02579.1 ) or a homologue thereof.

A "homologue" is used herein in particular for a polypeptide having a sequence identity of at least 30 % with its reference protein (i.e. SEQ ID NO 5, 6, 7, 8 or 9), preferably at least 40 %, more preferably at least 50%, more preferably at least 60%, more preferably at least 65%, more preferably at least 70 %, more preferably at least 75%, more preferably at least 80%, in particular at least 85 %, more in particular at least 90 %, at least 91 %, at least 92 %, at least 93 %, at least 94 %, at least 95 %, at least 96 %, at least 97 %, at least 98 % or at least 99 %. A homologue is generally a polypeptide that has functional and, preferably, also structural similarity to its reference protein. One type of homologue is encoded by a gene from another species of the same genus or even from other genera. "Homologue" is also intended to include those proteins which have been altered by mutagenesis techniques that have been performed to improve the protein's desired properties.

Sequence identity is herein defined as a relationship between two or more polypeptide sequences or two or more nucleic acid sequences, as determined by comparing the sequences. Usually, sequence identities are compared over the whole length of the sequences, but may however also be compared only for a part of the sequences aligning with each other. In the art, "identity" also means the degree of sequence relatedness between polypeptide sequences or nucleic acid sequences, as the case may be, as determined by the match between such sequences. Preferred methods to determine identity are designed to give the largest match between the sequences tested. In the context of this invention a preferred computer program method to determine identity between two sequences includes BLASTP and BLASTN (Altschul, S. F. et al., J. Mol. Biol. 1990, 215, 403-410, publicly available from NCBI and other sources (BLAST Manual, Altschul, S., et al., NCBI NLM NIH Bethesda, MD 20894). Preferred parameters for polypeptide sequence comparison using BLASTP are gap open 10.0, gap extend 0.5, Blosum 62 matrix. Preferred parameters for nucleic acid sequence comparison using BLASTN are gap open 10.0, gap extend 0.5, DNA full matrix (DNA identity matrix).

The aqueous phase in the process of the invention is a liquid phase in which the predominant solvent is water. The aqueous phase might be water only, a buffer comprising a mixture of water and a buffering salt / buffering salts (e.g.

potassium phosphate buffer), a mixture of water with an organic solvent (e.g. ethylene glycol, DMSO, THF) or mixture of buffer with an organic solvent (e.g. ethylene glycol, DMSO, THF). A skilled person will be able to select and optimize the aqueous phase for efficient activity of the biocatalyst.

Due to the nature of the solid-to-solid reaction, effective mixing of the aqueous reaction mixture is important to provide good transport and contact of the reaction components and to avoid particle settling. A skilled person will be able to select the right mixer design and mixing conditions using commercially available techniques. Efficient mixing can for instance be done by a radial pumping stirrer, while particle settling can be avoided by an axial stirrer, pumping downward to the bottom of the reaction vessel. As axial pumping impellers narrow blade hydrofoils are used as state-of-the-art. Traditionally pitched bladed turbines as standard impellers are used. Propellers can be used in an off centered position as well. When using centered impellers, baffling can be applied to turn the flow swirling to the desired pattern of the impeller. Providing mixing by pumping the aqueous reaction mixture via an outer loop is also an option. It was surprisingly found that the enzymes used in the process according to the invention survive the hydrodynamic shear forces which arise due to the mixing and the presence of undissolved solids.

In principle, the pH of the reaction medium may be chosen within wide limits, as long as the biocatalyst is active under the pH conditions applied. The pH of the reaction mixture is suitably between 4 and 1 1 , preferably between 5 to 10. A pH selected between A and B, a pH ranging from A to B or a pH range of A to B comprises the end points A and B.

The inventors have surprisingly found that the pH has a profound effect on the ammeline:ammelide ratio. Example 2 and Table 3 illustrate this effect. Under the conditions applied and within a pH range of 7 to 10, a higher pH resulted in a higher ammeline:ammelide ratio. In particular, pH of 7, 8, 9, 9.5 and 10 resulted in ammeline:ammelide ratios of 3.5 (75.2 mol% ammeline, 21.2 mol% ammelide), 14.3 (90.0 mol% ammeline, 6.3 mol% ammelide), 56.8 (96.5 mol% ammeline, 1.7 mol% ammelide), 108.8 (97.9 mol% ammeline, 0.9 mol% ammelide) and 164 (98.4 mol% ammeline, 0.6 mol% ammelide), respectively. An inverse trend was observed at pH values below 7, wherein a higher pH resulted in a lower ammeline:ammelide ratio. In particular, the ammeline:ammelide ratios were of 18.3 (91.5 mol% ammeline, 5.0 mol% ammelide) and 8.8 (86.9 mol% ammeline, 9.9 mol% ammelide) at a pH of 5 and 6, respectively. In other words, under the conditions applied and within a pH ranging from 6.5 and 7.5, a product with high ammelide content was obtained, whereas at pH below 6.5, preferably below 6 or at pH above 7.5, preferably above 8, a product with high ammeline content was formed. The pH has therefore been identified as an important parameter for fine-tuning the ammeline:ammelide ratio.

In principle, the temperature of the reaction medium used may be chosen within wide limits, as long as the biocatalyst remains active under the temperature conditions applied. In the process according to the invention, the reaction temperature is normally between 0 and 100 °C, preferably between 10 and 60 °C.

In the process according to the invention, the melamine substrate is added to the aqueous reaction mixture at loadings above saturation to form a solid within the temperature and pH ranges to be selected in the invention. Melamine loadings at which melamine forms a solid at a selected reaction condition can be determined by routine experiments.

As meant herein, the term "loading" is the total mass of melamine initially added to the reaction mixture, relative to the total mass of the aqueous reaction mixture. The melamine loading is expressed as mass percentage (mass %).

"Saturation" is defined herein as a point of maximum loading at which a solution of melamine can no more dissolve any additional amounts of melamine and such additional amounts of melamine will appear as a solid.

In one embodiment of the invention, melamine is present in a loading of at least 1 .0 mass %, relative to the total mass of the aqueous reaction mixture, preferably at least 10 mass %, more preferably at least 15 mass %, still more preferably at least 20 mass %, even more preferably at least 30 mass %

The inventors have surprisingly found that the substrate loading has a profound effect on the composition of the final product, wherein a higher melamine loading results in a higher ammeline:ammelide ratio. Example 3 and Table 4 illustrate this effect. Under the conditions applied, initial melamine loadings of about 1 mass %, 9 mass % and 17.5 mass % resulted in ammeline:ammelide ratios of 108.8 (97.9 mol% ammeline, 0.9 mol% ammelide), 329.7 (98.9 mol% ammeline, 0.3 mol% ammelide), 494 (98.8 mol% ammeline, 0.2 mol% ammelide), respectively. Melamine loading has therefore been identified as another important parameter for fine-tuning the

ammeline:ammelide ratio.

After the solid-to-solid reaction has proceeded to an acceptable conversion level, the solid product can be isolated from the aqueous reaction mixture by conventional methods (e.g. by filtration, by centrifugation or by applying a decanter centrifuge). Subsequently, the isolated product can be washed with water for removal of residual melamine substrate. The ammeline:ammelide ratio is not affected by these washing steps.

The solid product obtainable by the process according to the invention has high ammeline and/or ammelide content and low level of residual melamine. Suitably the product comprises at least 95 mass % of ammeline and/or ammelide and at most 5 mass % of melamine. Preferably, the product comprises at least 98 mass % of ammeline and/or ammelide and at most 2 mass % of melamine. More preferably, the product comprises at least 99 mass % of ammeline and/or ammelide and at most 1 mass % of melamine.

In principle, the ammeline:ammelide ratio of the solid product can be fine-tuned within a wide range. Typically, ammeline is in excess of ammelide. Suitably, the solid product has an ammeline:ammelide ratio in the range of 1 - 1000, more suitably in the range of 2 - 500.

The invention further relates to all possible combinations of different embodiments and/or preferred features according to the process of the invention as described herein.

The invention is elucidated with reference to the following examples, without however being restricted by these. EXAMPLES

Materials and general methods

1. Melamine substrate; reference materials ammeline, ammelide and cyanuric acid

Melamine (from OCI-Nitrogen), with a chemical purity of > 99.9% was applied for the examples.

Ammeline (from Hicol) with a chemical purity of 97.5% was used as reference material in HPLC analyses.

Ammelide with a chemical purity of 99.7% was used as reference material in HPLC analyses.

Cyanuric acid with a chemical purity of > 99% was used as reference material in HPLC analyses.

2. Preparation of biocatalysts

2.a. Cloning and expression of recombinant enzymes

Five genes from different organisms encoding enzymes with aminohydrolase activity towards 1 ,3,5-triazine compounds were selected to exemplify the invention; namely SEQ ID NO 10 (gi_1 1890745), SEQ ID NO 1 1 (gi_310815990), SEQ ID NO 12 (gi_4033703), SEQ ID NO 13 (gi_27378991 ) and SEQ ID NO 14 (gi_309703244) encoding SEQ ID NO 5 (AAG41202.1 ), SEQ ID NO 6 (YP_003963954.1 ), SEQ ID NO 7 (Q52725.2), SEQ ID NO 8 (NP_770520.1 ) and SEQ ID NO 9 (CBJ02579.1 ), respectively (Table 1 ).

Table 1 : Overview of enzymes, donor organisms, accession numbers and recombinant vectors.

For expression in Escherichia coli Four out of the five target genes, i.e. SEQ ID NO 10, SEQ ID NO 1 1 , SEQ ID NO 12 and SEQ ID NO 13, were codon pair optimized for expression in Escherichia coli, resulting in SEQ ID NO 1 , SEQ ID NO 2, SEQ ID NO 3 and SEQ ID NO 4, respectively (sequence listing). Codon pair optimization was performed according to a procedure described in WO2008/000632.

For larger scale expression experiments, £ coli RV31 1 cells were made chemically competent using the Z-Competent™ £ coli Transformation Kit (Zymo Research, Irvine, CA, USA) and transformed with the pBAD recombinant vectors isolated as described above from the £ coli TOP10 strains. Transformants were selected on LB agar plates containing 100 μg/ml neomycin. From these plates 50 ml precultures in LB medium containing 50 μg/ml neomycin were inoculated and incubated on an orbital shaker at 180 rpm and 28°C. After overnight incubation the precultures were used to inoculate 1 I LB expression cultures (in 2 I baffled Erienmeyer flasks) to starting OD ₆ 2oS of 0.05. These expression cultures were incubated on an orbital shaker at 180 rpm and 28°C. In one third of the cultures, the melamine deaminase gene expression was induced after 8 h by addition of 0.02% (w/v) L- arabinose and incubation was continued overnight. Subsequently these cultures were harvested by centrifugation at 10,000 g for 10 min. The other two third of the cultures were also incubated overnight and induced as described above after approximately 24 h. After 4 and 8 h, respectively, also these cultures were harvested by centrifugation.

2.b. Fermentation of biocatalyst on 10 I scale

Fermentation of £. coli RV31 1 expressing the pBAD recombinant vectors was performed in a fed-batch fermentation on 10 I scale, using glucose as a carbon source.

2.C. Preparation of cell free extract on small scale (1 -10 ml)

The cell pellets were resuspended in twice the volume of their wet weight with ice-cold 100 mM potassium phosphate buffer pH 7.0. Cell-free extracts (CFEs) were obtained by sonification of the cell suspensions using a Sonics

(Meyrin/Satigny, Switzerland) Vibra-Cell VCX130 sonifier (output 100%, 10 sec. on/10 sec. off, for 10 min) with cooling in an ice/acetone bath and subsequent centrifugation in an Eppendorf 5415R centrifuge (Hamburg, Germany) at 13,000x g and 4°C for 30 min. The supernatants (= CFEs) were transferred to fresh tubes and stored on ice for immediate use or stored at -20°C. 2.d. Preparation of cell free extract on larger scale (10-250 ml scale)

To 76.3 g wet cells (frozen), 152.6 g potassium phosphate buffer (100 mM pH=7) was added. Cells were suspended and put on ice. Subsequently, 1 125 mg lysozym and 50 μΙ benzonase were added, mixed and put at -20°C overnight. The next morning the suspension was put at 37°C room on a shaker for 2.25 h. The suspension was cooled afterwards on ice and subsequently divided over 8 tubes of 50 ml (-28 ml each) and each suspension was sonicated for 2 min, using a Sonics (Meyrin/Satigny, Switzerland) Vibra-Cell VCX130 sonifier (output 100%, 10 sec. on/10 sec. off, for 10 min) with cooling in an ice/acetone bath. Subsequently, the suspensions were stored on ice at 4°C room for 4 h. Next, the suspensions were centrifuged at 15.000 rpm for 15 min. The obtained supernatants were collected and stored at -20°C.

3. Protein determination

The protein concentrations in the CFEs were determined using a modified protein-dye binding method as described by Bradford in Anal. Biochem. 72: 248-254 (1976). Of each sample 50 μΙ in an appropriate dilution was incubated with 950 μΙ reagent (100 mg Brilliant Blue G250 dissolved in 46 ml ethanol and 100 ml 85% ortho-phosphoric acid, filled up to 1 ,000 ml with Milli-Q water) for at least five minutes at room temperature. The absorption of each sample at a wavelength of 595 nm was measured in a PerkinElmer Lambda35 UV/VIS spectrophotometer. Using a calibration line determined with solutions containing known concentrations of bovine serum albumin (BSA, ranging from 0.0125 mg/ml to 0.20 mg/ml), the protein concentration in the samples was calculated.

4. SDS-PAGE analysis

The recombinant expression in E. coli was analyzed by SDS-PAGE of the E. coli TOP10 CFEs and of the £. coli RV 31 1 CFEs and compared to a CFE with an overexpressed control protein. 5. Conversion reactions and product isolation

5.a. Conversion reactions - general description

Conversion reactions were either performed in a glass reactor of 80 ml containing a propeller stirrer or in a glass reactor of 1600 ml, containing a turbine stirrer and pH-stat equipment (type 718 Stat Titrino from Metrohm). A stirrer speed of about 500 rpm was applied. ln general, a conversion was performed as follows: a certain amount of melamine was added to a buffer (100 mM K ₂ HP0 ₄ / 1 mM MgS0 ₄ .7H ₂ 0) at 37°C to reach a desired loading. The pH was adjusted to the desired value, using 1 M H ₃ P0 ₄ (for obtaining a pH of 7 or lower) or 1 M NaOH (for obtaining a pH of 8 or higher). Subsequently, the biocatalyst was added to start the conversion. Samples were taken in the course of the conversion for HPLC analysis as described in paragraph 6.

5. b. Product isolation

Product isolation was performed after a certain reaction time by pouring the reaction mixture over a P3 glass filter, using vacuum (about 750 mbar). The filter cake was washed three times with water. The obtained product was dried overnight.

6. HPLC analysis

6.a. Sample preparation for HPLC-analysis

Samples of the aqueous reaction mixtures or samples of the isolated products were diluted in first instance with formic acid to a total 1 ,3,5-triazine compounds concentration of about 0.5 mass % and subsequently diluted 50 times with water before subjecting to HPLC analysis.

6.P. HPLC analysis method

Two 250 mm Prevail C18 columns are used. The critical separation takes place at 0 % acetonitrile. The columns are to be equilibrated for at least 8 minutes after the gradient.

The specific analytical conditions on the HPLC used are:

Columns : Prevail C18 2x (250 mm x 4.6 mm ID x 5 Dm)

Eluent A : HCI0 ₄ pH = 2.0 (1.63 g 70% HCIO ₄ /I water)

Eluent B : Acetonitrile

Flow : 1.2 ml/min

Injection volume : 5 μΙ

Column temperature

Detection wavelength Time (min) %B

0 0

12 0

12.5 80

13.5 80

14 0

22 Stop

Example 1 : Preparation of ammeline and/or ammelide from melamine by a solid-to- solid reaction in an aqueous reaction mixture.

Reactions were performed in 80 ml reactors with a filling volume of about 55 ml, containing a stirrer and pH-stat equipment.

For the test reaction, 555 mg of melamine was added to 47 g buffer (100 mM K ₂ HP0 ₄ / 1 mM MgS0 ₄ .7H ₂ 0) at 37°C. The pH was adjusted to pH 9.5 with 1 .65 g 1 M NaOH. Subsequently, 0.25 ml of cell free extract of E. coli RV31 1 pBAD_Meldeam_Aci was added to start the reaction, thereby obtaining a final concentration of cell free extract of 0.5 vol %. The melamine loading was 1 .1 mass %. The pH was kept constant at 9.5 by titration with 1 M NaOH.

A chemical blank reaction was run in parallel, using the same procedure as described above, with the exception that no biocatalyst was added. A biological blank reaction was run in parallel, using the same procedure as described above, with the exception that cell free extract is obtained from E. coli RV31 1 harboring a pBAD recombinant vector having a gene insert that encodes an enzyme not able to convert melamine (in this case a P450 monooxygenase enzyme from Bacillus megaterium BM3).

After 18 h reaction time, samples were taken from the three reaction mixtures for HPLC analysis. Results are shown in Table 2.

Table 2: HPLC analyses of the reaction mixtures after 18 h reaction time

Reaction Melamine Ammeline Ammelide Cyanuric acid Conversion (%) mixture (mol%) (mol%) (mol%) (mol%)

Test reaction 1 .2 97.7 1 .1 0 98.8

Chemical blank 99.8 0.2 0.0 0 0.2

Biological blank 99.9 0.1 0.0 0 0.1 The results in Table 2 show that the conversion of melamine to ammeline and ammelide is due to the activity of the biocatalyst (i.e. cell free extract of E. coli RV31 1 pBAD_Meldeam_Aci). The melamine initially added to the reaction mixture is almost fully converted to ammeline and ammelide within 18 h. No cyanuric acid was formed. No significant conversion of melamine took place in the chemical blank reaction mixture, showing that the melamine is chemically stable during the reaction time, under the conditions applied. Furthermore, no significant conversion of melamine took place in the biological blank reaction mixture. Example 2: Effect of pH on the ammeline:ammelide ratio.

Conversion reactions were performed in 80 ml reactors with a filling volume of about 55 ml containing a stirrer and pH-stat equipment.

555 mg of melamine was added to 47 g buffer (100 mM K ₂ HP0 ₄ / 1 mM MgS0 ₄ .7H ₂ 0) at 37°C. The pH was adjusted to the desired value, using 1 M H ₃ P0 ₄ (for obtaining a pH of 7 or lower) or 1 M NaOH (for obtaining a pH of 8 or higher). Subsequently, 0.25 ml of cell free extract of E. coli RV31 1 pBAD_Meldeam_Aci was added to start the reaction, thereby obtaining a final concentration of cell free extract of 0.5 vol %. The melamine loading was 1 .1 mass %. The pH was kept constant by titration with 1 M H ₃ P0 ₄ or 1 M NaOH. Samples were taken over time for HPLC analysis. At maximum conversion, the solid products were isolated and analyzed as described in "materials and general methods". Results are shown in Table 3.

Table 3: Maximum conversion and analysis results of the isolated solid products pH Melamine Ammeline Ammelide Ammeline:ammelide Conversion

(mass %) (mass %) (mass %) ratio at maximum (%)

conversion

5 3.5 91 .5 5.0 18.3 96.1

6 3.2 86.9 9.9 8.8 96.8

7 3.6 75.2 21.2 3.5 96.4

8 3.7 90.0 6.3 14.3 96.3

9 1 .8 96.5 1 .7 56.8 98.2

9.5 1 .2 97.9 0.9 108.8 98.8

10 1 .0 98.4 0.6 164 99.0 The results in Table 3 show that the ammeline:ammelide ratio obtained in the reaction mixture can be fine-tuned by the pH. Within a pH range of 7 to 10, the higher the pH, the higher the ammeline:ammelide ratio. An inverse trend was observed at pH values below 7, wherein a higher pH resulted in a lower

ammeline:ammelide ratio. It is noteworthy to mention that cyanuric acid was never detected.

Example 3: Effect of melamine loading on the ammeline:ammelide ratio.

Conversion reactions were performed in 80 ml reactors with a filling volume of about 55 ml containing a stirrer and pH-stat equipment.

Melamine was added to 47 g buffer (100 mM K ₂ HP0 ₄ / 1 mM MgS0 ₄ .7H ₂ 0) at 37°C to a loading of 1.1 mass %, 9 mass % or 17.5 mass %. The pH was adjusted to 9.5 using 1 M NaOH. Subsequently, to start the reactions, cell free extract of E. coli RV31 1 pBAD_Meldeam_Aci was added to a concentration of 0.5 vol %, 5 vol % or 10 vol %, respectively. The pH was kept constant during the conversion by titration with 1 M NaOH. Samples were taken over time for HPLC analysis. At maximum conversion, the solid products were isolated and analyzed as described in "materials and general methods". Results are shown in Table 4. Table 4: Maximum conversion and analysis results of the isolated solid products

The results in Table 4 show that at the chosen reaction conditions, the ammeline:ammeline ratio can be fine-tuned by adjusting the melamine loading; the higher the melamine loading under the chosen reaction conditions, the higher the ammeline:ammelide ratio. It is noteworthy to mention that cyanuric acid was never detected. Example 4: Preparation of ammeline and/or ammelide by a solid-to-solid reaction in an aqueous mixture on 1 I scale.

A reaction mixture was prepared in a stirred 1.6 I glass reactor, by adding 125.2 g melamine to 1050ml buffer (100 mM K ₂ HP0 ₄ / 1 mM MgS0 ₄ .7H ₂ 0). The melamine solid substrate was stirred for 20 min at 37°C after which the pH was adjusted to pH 9.5 by adding 0.05 g 5M NaOH. To start the reaction 62.5 ml of cell free extract of E. coli RV31 1 pBAD_Meldeam_Aci was added (5 vol %), after which the pH was adjusted to pH 9.5 by adding another 0.1 g of 5 M NaOH. The melamine loading was 10.1 mass %. During the conversion, the pH was kept constant at pH 9.5 by titrating a solution of 1 M H ₃ P0 ₄ applying a pH-stat equipment. Samples were taken for HPLC analysis. After 5 h, the reaction was stopped and the solid product was isolated and analyzed as described in "materials and general methods". A total of 125 g of product was obtained, containing 98.6 mass % ammeline, 0.4 mass % ammelide and 1 mass % melamine, corresponding to a conversion of 99%. No cyanuric acid was formed.