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PLANKTON STRAIN ALGAE PARACHLORELLA NUREKIS 1904 KIEG AND HIS USE TO

EXTERMINATE CYANOBACTERIA, BACTERIA AND FUNGI

Technical Fields

The invention refers to the strain ; of a unicellular green algae Parachtorella nurekis 1904 KIEG which is designed for biomass; production and eradication of cyanobacteria (blue-green algae).

Background Arts

There is a well-known strain of unicellular green algae Chlorella vulgaris IFR C-l l l characterized by high productivity vvhich meets the requirements of industrial cultivation (patent RU 1751981).

The disadvantage of Chlorella vulgaris IFR C-l l l lies in the seasonality of its development (during the period frorn May to December), demand factors of the nutrient medium content, the permanent; eyciej of the development of cells and the narrow range of cultivation temperatures (26-36°C). .

There is a known strain of unicellular green algae Chlorella vulgaris BIN, with a wide range of temperatures acceptable ^" for cultivation (20-40°C), which is demanding on the substrate, possesses the ability of cleaning sewage waters (patent RU 2192459), and is applied in the biological rehabilitation of waiter reservoirs (Bogdanov, 2008).

The disadvantage of Clilore!lla vulgaris BIN strain is the absence of seasonal reproduction in natural reservoirs complicating its application in different climatic zones. Poor keeping of vitality in water; reservoirs at a temperature range from 0 to 16°C requires the repeated treatment of the reservoir by the algae. The deficient adaptability to natural conditions of the reservoir requires the additional adaptation of the strain. Another deficiency of Chlorella vulgaris BIN is the najprqw adaptation range - only to certain sewage waters.

The aim of the inventiQ^ tis to create a new strain of unicellular green algae Parachlorella nurekis 1904 KJEGj' kh will differ by a higher productivity, seasonal reproduction in natural watersheds and vitality at temperature intervals from 0 to 16°C, and will possess the ability to adapt to natural conditions in different climatic zones, and eradicate cyanobacteria, bacteria and fungi;

Disclosure of Invention

Unicellular green algae !are - able to eliminate .the aforesaid disadvantages of the previous strains. The strain Par chlorella nurekis 1904 KIEG was cultivated on the basis of Chlorella vulgaris BIN from the collection of the Penza Research Agricultural Institute, Russian Academy of Agriculture^ This strain was cultivated in natural reservoir water in different climatic zones. As the final, result, the transitional strain had been chosen, which is more adaptable and less demanding relative to the cultivation. Its application demonstrated a high flexibility as regards to water vresservoirs of different climatic zones, also the ability to eradicate cyanobacteria, other baqter|¾and fungi.

Medium: For cultivation ofpcarachlorella nurekis 1904 KIEG strain we take per 1 1 of tap water a nutrient medium containing the following four components. Nutrient medium

Component >.k nitric-phosphoric solution - 0.3 ml

Component 2:-sp _. dium-ferrous solution - 0.15 ml

Component -3: copper -cobalt solution - 0.2 ml

Component 4: carbon dioxide solution - 10 ml

Morphological characteristic^:' New cells have slightly ellipsoidal shape and size of 2-3 μηι. Adult vegetative cells have^7-8 μιη in diameter. Cells with a diameter of 8-10 μηι with already formed autonomic spores aire still in the maternal capsule. New cells have thin walls which gradually become thicker. When autonomic spores are released, the (side) is split into 2-3 parts, which remain connected. (Chloroplast wideband and open covers ¾ of cell surface and fits tightly the cell side). Pyrenoid is surrounded by starch paper, consisting of two or three hemispheres. Reproduction is provided by autonomic spores. Spores have the same size. The quantity of spores is four, rarely two and more. The quantity is strictly even. The dividing of cells, genesis and release of autbtiortiic spores runs during the whole day without strict lineup to the fixed hour. Both new and ,grown-up cells are dark green.

Cultural characteristics: The cells are not accumulated, but distributed equally in the suspension volume. (Vascular) walls ;are not overgrown. _; -The algae is cultivated and stored in the liquid nutrient medium. It grows Well with the application of ammonium nitrate. The algae require the feed of a carbon dioxide solution produced from cellulose.

During cultivation the cells practically do not sediment. In the state of rest the cells start sedimentation in 5-10 days. The process of sedimentation ends in a month period.

The strain's cultivation does riot require automatic mixing.

The conditions of cultivatioh; ;do not (contain) _. - seasonal reproduction. (In natural conditions the seasonality is otherwise very much expressed). In cultivation conditions the strain requires the certain nutrienf-fifredium and the maintenance of the biotechnological course of cultivation. In the open-air the alga adapts to the conditions of the watershed which it has been implemented in. \ ^ '

Parachlorella nurekis 1904 · KIEG eliminates bacteria, fungi, implicates decomposition of cells and colony of the cyanobac eria .up to their complete elimination.

The strain evolution cycle is unstable; the cells are developed in an asynchronous way.

Parachlorella nurekis 1904 ^' ΚΪΕΟ strain could be cultivated in 19 % salty water.

Algae cultivation does not! demand sterility. The strain possesses the ability of creating the monoculture conditions. <? »* ·

Physiological characteristics: The strain is autotrophic; it requires feed of nitrogen, mainly of ammonium nitrate. It grows in the sunlight, also in the conditions of artificial lightning in open reservoirs with larnps.Osram Plantastar 250W. The light penetrates through a layer of 20 cm. The strain has good plankton properties, i.e. ability of uplifting and of equal distribution in cultivation medium.

Living algal cells have negative; charges. Loss of charges implicates the coagulation of cells and their agglutination. The ability of sticking to the hydrogenous bubbles is used for extracting the biomass from the cultivation medium by electric flotation. The optimal temperature for cultivation is 28-30°C. At natural conditions the alga grows in temperature 16 - 32°C, at the sameitime it has long vitality in all watersheds at temperatures from 0 to 16°C.

The lighting mode corresponds to the continuation of straight illumination artificial light provided by OSRAM PLANTASTAR 250W lamps - lightning lasts for 10-12 hours. The sufficient minimum of lightning, lasti'S- 10, maximum 12-14 hours. The strain evolution does not depend on the season or sources! light.

The strain behaves antagonistically towards to other water algae, bacteria, fungi or yeast in the cultivation medium. No other · algae can be developed in the presence of this strain. Bacteria die and sediment.

The vitality of cells is mihnrr¾n%30 years, if the conditions of storage at scattered light and room temperature are kept for the culture.

In natural watersheds the strain kills three kinds of cyanic bacteria (cyanobacteria): Aphanizomenon, Anabaena a Microcystis. In laboratory conditions Parachlorella nurekis 1904 KIEG implicates decomposition of cells and colonies of the cyanobacteria up to their complete elimination.

The strain is characterized by _;i high productivity (see the Table) and ability to destroy algal bloom causing cyanobactertia, _i( ai|d, other bacteria and fungi.

Brief Description of Drawings

Cyanobacteria (Aphanizome^|¾flos-aquae) in twelve hours.

Made for Carrying Out the Invention

Example 1. We sample ;¾i blooming watershed with Aphanizomenon flos-aquae cyanobacteria. 100 ml of the sample is to be filtered, and weighed; biomass is to be extracted (300 mg), and put into the Petri Idiste where we then add 100 ml of Parachlorella suspension (biomass 60 mg/100 ml). We put ¾b'0 ml of the cyanobacteria sample into the second Petri dish. The first Petri dish is an exp¾nmental one; the second is the control one. Both dishes should be kept in scattered light aridfoom temperature.

At the beginning of the experiment the colonies of cyanobacteria are well visible in both dishes. In three hours cyanobact0r¾ija ^; tJie experimental dish darken more, than in the control one. The process of colony decomposition starts in the experimental dish in 6 hours. There are no changes observed in the controi 'dish. In 9 hours cyanobacteria in the experimental dish fully lose their structure. They look lata a whole formless unit, darker than cyanobacteria in the control dish. There are no changes observed in the control dish. In 12 hours the experimental dish does not contain visible traces df¾yanic bacteria. The control dish shows no changes. Thus, in 12 hours Parachlorella suspension has completely eliminated the colony of cyanobacteria with a biomass 5 times larger than the biomass of Parachlorella.

Example 2. We pour 100 ml of water sample from a blooming watershed - Aphanizomenon flos-aquae cyanobacteria - into two conical flasks. Biomass of cyanobacteria totals 200 mg/100 ml of water. Theii we add 15 ml of suspension of Parachlorella nurekis 1904 KIEG into the first flask. The biomass of Parachlorella makes 60 mg/100 ml. First flask is an experimental, second is the control one. Both flasks should be kept in scattered light and room temperature (22°C).

At the beginning of the,' experiment the colonies of cyanobacteria could be well observed in both flaska. In 6 hours it 'can be seen that cyanobacteria in the experimental flask darken more than in the control one; tCyanobacteria in the experimental flask completely lose their structure in 12 hours. They , l oj , ¹ like formless flocks and are darker than cyanobacteria in the control flask. There are ho changes observed in the control flask. The experimental flask contains no visible traces of cyanic bacteria in 20 hours.

Within 20 hours the Parachlorejla suspension implemented to the natural environment of cyanobacteria has completely eliminated the colony 6f cyanobacteria with a biomass 20 times larger than the biomass of Parachlorella itself.

Cyanobacteria were elimirtate Ijn,the Parachlorella medium, as well as after we treated the environment of cyanobacteria with Parachlorella suspension. At the same time biomass of cyanobacteria was several times large];, than Parachlorella' s biomass.

Therefore, the designed algak strain Parachlorella nurekis 1904 KIEG is more productive against other known .strains, and is able to completely eliminate the cyanobacteria causing the algal bloom. For instahc^ an the result of using this strain at the Tsimlyanskoye watershed (Russia) they managed to entirely destroy cyanobacteria within three years (2006- 2009).

Table

Comparative indic^¾>f Efficiency of Chlorella vulgaris strains

Industrial applicability

Parachlorella nurekis 1904 KIEG(is a strain highly adaptable and undemanding towards the conditions of cultivation. Its ;uti¾¾a¾on has proven ^' high flexibility towards watersheds of various climatic areas and ability! to ki l cyanobacteria, bacteria and fungi.