본 연구는 유기농업에서 생물자원으로서 담수 클로렐라의 활용 가능성을 연구하고자 유기농 생태계로부터 담수 녹조류를 분리, 동정하고, 생물학적인 특성을 조사하였다. 조사 지역의 수온은 $12.4{\sim}28.2^{\circ}C$, pH는 6.1~8.5이었다. 담수 녹조류를 분리할 때 고체배양법이 액체배양법보다 오염도가 낮고 분리 빈도가 높았다. 전국 9개 지역, 6개 담수 녹조류 서식처로 부터 총 115개의 균주를 분리하였다. 담수 녹조류의 분리 및 배양을 위해 질소원으로는 $NaNO_3$과 $KNO_3$, 탄소원으로 $Na_2CO_3$를 사용하였고, macro media의 구성 성분 중 $MgSO_4{\cdot}7H_2O$과 $CaCl_2{\cdot}2H_2O$를 분리하여 제조한 BGMM(BG11 Modified Medium)배지를 고안하였다. 담수녹조류는 배양 후 4일째부터 급격히 흡광도가 증가하였고 8일째부터 흡광도가 감소하였다. 공시한 7개의 균주 중 CHK008 균주가 배양 7일째에 가장 높은 흡광도를 보였다. 담수 녹조류 배양에 적합한 BGMM 배지의 pH는 6~7이었고 조사되는 빛이 강할수록 생육이 증가하였으며 5종류 당류 중에서 Glucose와 Galactose를 첨가하였을 때 클로랄라의 생육이 좋았다. 순수 분리한 16개 녹조류 균주의 균총색은 녹색, 진녹색, 연녹색을 나타내었고, 11개의 균주가 형광현미경하에서 강한 형광 빛을 나타내었다. 녹조류 16개 균주의 형태적인 특징을 조사한 결과 C. vulgalis, C. sorokiniana, C. pyrenoidosa, C. kessleri, C. emersonii, and Chlamydomonas sp.의 2개 속 6개종으로 동정되었다. 담수 녹조류의 세포 크기는 종마다 다양한 변이를 보였다. 대부분의 담수 녹조류의 세포형태는 구형이었다. Chlamydomonas sp.는 타원형이었고 Chlorella sorokiniana는 구형과 타원형이 섞여 있었다. 6개 녹조류 종류 중 Chlamydomonas sp.를 제외한 모든 균주는 편모가 없었다. Chlamydomonas sp. 1개 균주와 C. sorokiniana 5개 균주는 세포에서 점질물을 분비하였다.

This study aimed to isolate and identify freshwater algae from the organic agricultural ecosystems and investigate its biological characteristics to study the possibility of utilizing a biomass freshwater algae in organic farming. In the survey area, average water temperature was $12.4{\sim}28.2^{\circ}C$ and the pH ranges were from 6.1 to 8.5. The solid culture method is more suitable than liquid culture method for isolation of freshwater algae with lower contamination level and higher isolation frequency. A total of 115 strains were isolated from six freshwater algae habitats in nine regions in Korea. BGMM (BG11 Modified Medium) amended with NaNO3 and $KNO_3$ as a nitrogen, and $Na_2CO_3$ as carbon source was designed to isolate and culture freshwater algae. Absorbance of freshwater algae culture has increased dramatically to four days and decreased after eight days after inoculation. CHK008 of the seven isolates showed the highest absorbance in seven days after culturing in BGMM. The optimal pH of BGMM for culturing freshwater algae was pH 6-7. As light intensity increased, growth of freshwater algae increased. Among the five kinds of carbon sources, glucose and galactose promoted good growth of freshwater algae in BGMM. The colony color of purified 16 green algae isolates showed a separation of green, dark and light green, and of them, eleven algae strains showed a strong fluorescent light under fluorescence microscopy. Cell size of the green algae showed a wide range of variation depending on the species. General morphology of the green algae strains was spherical. Chlamydomonas sp. was elliptical, and Chlorella sorokiniana was ellipsoidal and cylindrical. All strains of the green algae except for Chlamydomonas sp. did not have flagella. One isolate of Chlamydomonas sp. and five isolates of C. sorokiniana secreted mucus. Sixteen isolates of 16 green algae were identified as two family and six species, Chlorella vulgalis, C. sorokiniana, C. pyrenoidosa, C. kessleri, C. emersonii, and Chlamydomonas sp. based on their morphological characteristics.

1 차재영, "클로렐라 균주의 분리 동정 및 열수 추출물의 이화학적 조성" 한국생명과학회 18 (18): 1723-1727, 2008

2 이태윤, "발광다이오드를 이용한 클로렐라 배양 연구" 대한환경공학회 33 (33): 591-597, 2011

3 전선미, "미세조류를 이용한 이산화탄소 고정화 기술 현황" 한국공업화학회 19 (19): 145-150, 2008

4 채희정, "기능성 생물 소재로서의 클로렐라" 한국생물공학회 19 (19): 1-11, 2004

5 Warburg, O., "Über die geschindigkeit der kohlensäurezersetzung in lebenden Zellen" 100 : 230-270, 1919

6 Gabriel, B., "Wastewater Microbiology" John Wiley & Son 68-75, 1996

7 Geoghegan, M. J., "Unicellular algae as a source of food" 168 : 426-427, 1951

8 Huang, B., "The physiological effects of different N-P ratios on algae in semicontinuous culture" 11 : 137-142, 1994

9 Kärin, N, "The construction of a scientific model: Otto Warburg and the building block strategy" 40 : 73-86, 2009

10 Fott, B., "The Freshwater Species, Studies in Phycology" Academia 10-74, 1969

11 Takeda, H., "Sugar composition of the cell wall and the taxonomy of Chlorella (Chlorophyceae)" 27 : 224-232, 1991

12 Allen, M. B., "Studies on the properties of some blue-green algae" University of California 1966

13 Lee, Y. N., "Studies on nucleic acid and protein biosynthesis of Chlorella cells during the course of the chloroplast development" 8 : 1-12, 1970

14 Zallen, D. T., "Redrawing the boundaries of molecular biology: The case of photosynthesis" 26 : 65-87, 1993

15 Stanier R. Y., "Purification and properties of multi-cellular blue-green algae (order Chlorococcales)" 35 : 171-205, 1971

16 Jin, H. J., "Optimization of media composition and culture conditions for the growth of Chlorella sp. CMS-1" Dong-A University 2008

17 Mahmoud, M. S., "Nutritional status and growth of maize plants as affected by green microalgae as soil additives" 1 : 475-479, 2001

18 Kanetsuna, Y., "New and interesting desmids (Zygnematales, Chlorophyeae) collected from asia" 50 : 101-103, 2002

19 US DOE, "National Algal Biofuels Technology Rodmap"

20 Oh-Hama T., "Microalgal Biotechnology" Cambridge University Press 3-26, 1998

21 Mata, T. M., "Microalgae for biodiseal production and other applications: A review" 14 : 217-232, 2010

22 Krauss, R. W., "Mass culture of algae for food and other organic compounds" 49 : 425-435, 1962

23 Sheehan, J., "Life cycle inventory of biodiesel and petroleum diesel for use in an urban bus" National Renewable Energy Laboratory 1998

24 Rhichmond, A., "Large scale microalgal culture and applications" 1-62, 1990

25 Aksu, Z., "Investigation of simultaneous biosorption of copper (II) and chromum (VI) on dried Chlorella vulgaris from binary metal mixtures: Application of multicomponent adsorption isotherms" 34 : 501-524, 1999

26 Cho, I. S., "Industrial applications and production of Chlorella" 30 : 42-49, 2004

27 Wu, H. L., "Identification of Chlorella spp. isolates using ribosomal DNA sequences" 42 : 115-121, 2001

28 Vonshak. A., "Handbook of Microalgal Mass Culture" CRC Press 117-, 1986

29 Hernandez, J. P., "Growth promotion of the freshwater microalga Chlorella vulgaris by the nitrogen-fixing plant growth-promoting bacterium Bacillus pumilus from arid zone soils" 45 : 88-93, 2009

30 Benson A. A., "Following the path of carbon in photosynthesis: A personal story" 73 : 29-49, 2002

31 Karakashian, S. J., "Evolution and symbiosis in the genus Chlorella and related algae" 19 : 368-377, 1965

32 Ördög, V., "Endogenous cytokinins in three genera of microalgae from Chlorophyta" 40 : 88-95, 2004

33 Hiroto, N., "Effects of the hot water extract and its residues of Chlorella cells on the growth of radish seedlings and changes in soil microflora" 67 : 17-23, 1996

34 Ichimi, K., "Effects of light intensity on the cyst germination of Chattonella sp. (Raphidophyeae)" 50 : 22-24, 2003

35 Jeanfils, J., "Effect of nitrate concentrations on growth and nitrate uptake by free-living and immobilized Chlorella vulgaris cells" 5 : 369-374, 1993

36 Faheed, F. A., "Effect of Chlorella vulgaris as bio-fertilizer on growth parameters and metabolic aspects of lettuce plant" 4 : 165-169, 2008

37 Stirk, W. A., "Cytokinin-and auxin-like activity in Cyanophyta and microalgae" 14 : 215-221, 2002

38 Thompson, A. S., "Culture and Collection of Algae and Protozoa" National environmental Research Council, Titus Wilson and Sons LTD 13-35, 1988

39 Tamiya, H., "Correlation between phytosynthesis and light-independent metabolism in the growth of Chlorella" 12 : 23-40, 1953

40 Raposo, M. F. D. J., "Chlorella vulgaris as soil amendment: influence of encapsulation and enrichment with rhizobacteria" 13 : 719-724, 2011

41 Shihira, I., "Chlorella Physiology and Taxonomy of Forty-one Isolates" University of Maryland 1-92, 1965

42 Metting, B., "Biologically active compounds from microalgae" 8 : 386-394, 1986

43 Lin C. S., "Biodiversity of soil algae in the farmlands of mid-Taiwan" 54 : 1-12, 2013

44 Huss, V. R., "Biochemical taxonomy and molecular phylogeny of the genus Chlorella Sensu Lato (Chlorophyta)" 35 : 587-598, 1999

45 Kazumasa, H., "Bioactivities of nostocine a produced by a freshwater cyanobacterium Nostoc spongiaeforme TISTR 8169" 95 : 512-517, 2003

46 Rippka, R., "Assignments strain history and properties of pure culture of Cyanobacteria" 111 : 1-61, 1979

47 Anderson, R. A, "Algal Culturing Techni" Elsevier Academic Press 578-, 2005

48 Guiry, M. D., "AlgaeBase" World-wide electronic publication, National University of Ireland

49 Green, B. R., "After the primary endosymbiosys: an update on the chromalveolate hypothesis and the origins of algae with chl c" 107 : 103-115, 2011

50 Höxteman, E., "A comment on Werburg’s early understanding of biocatalysis" 92 : 121-127, 2007