[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.4490/algae.2022.37.4.1

Statistical optimization of phytol and polyunsaturated fatty acid production in the Antarctic microalga Micractinium variabile KSF0031

Kim, Eun Jae (Division of Life Sciences, Korea Polar Research Institute)
Chae, Hyunsik (Division of Life Sciences, Korea Polar Research Institute)
Koo, Man Hyung (Research Unit of Cryogenic Novel Material, Korea Polar Research Institute)
Yu, Jihyeon (Division of Life Sciences, Korea Polar Research Institute)
Kim, Hyunjoong (Division of Life Sciences, Korea Polar Research Institute)
Cho, Sung Mi (Division of Life Sciences, Korea Polar Research Institute)
Hong, Kwang Won (R&D Department, Microalgae Ask Us Co., Ltd.)
Lee, Joo Young (Department of Polar Sciences, University of Science and Technology)
Youn, Ui Joung (Division of Life Sciences, Korea Polar Research Institute)
Kim, Sanghee (Division of Life Sciences, Korea Polar Research Institute)
Choi, Han-Gu (Division of Life Sciences, Korea Polar Research Institute)
Han, Se Jong (Division of Life Sciences, Korea Polar Research Institute)

Publication Information

ALGAE / v.37, no.2, 2022 , pp. 175-183 More about this Journal

Abstract

Polar microorganisms produce physiologically active substances to adapt to harsh environments, and these substances can be used as biomedical compounds. The green microalga Micractinium variabile KSF0031, which was isolated from Antarctica, produced phytol, a natural antimicrobial agent. Furthermore, several polyunsaturated fatty acids (PUFAs), including omega-3, exhibit antioxidant properties. Here statistical methods (Plackett-Burman design and Box-Behnken design) were used to optimize the culture medium of KSF0031 to improve biomass production, and K₂HPO₄, MgSO₄·7H ₂O, and ammonium ferric citrate green (AFCg) were selected as significant components of the culture medium. Changes in the concentration of K₂HPO₄ and MgSO₄·7H ₂O as positive factors and AFCg as a negative factor affected cell growth to a remarkable degree. The biomass production in a 100 L culture using the optimized medium for 24 d at 18℃ was improved by 37.5% compared to that obtained using the original BG-11 medium. The quantities of PUFAs and phytol obtained were 13 mg g^-1 dry cell weight (DCW) and 10.98 mg g^-1 DCW, which represent improved yields of 11.70% and 48.78%, respectively. The results of this study could contribute to an improved production of phytol and fatty acids from Antarctic microalgae in the biomedical industry.

Keywords

Antarctic algae; growth medium optimization; Micractinium variabile; phytol; polyunsaturated fatty acids;

Citations & Related Records

Times Cited By KSCI : 2 (Citation Analysis)

Reference
Cited By KSCI

1	Stanier, R. Y., Kunisawa, R., Mandel, M. & Cohen-Bazire, G. 1971. Purification and properties of unicellular bluegreen algae (order Chroococcales). Bacteriol. Rev. 35: 171-205. DOI
2	Suh, S. -S., Hong, J. -M., Kim, E. J., Jung, S. W., Kim, S. -M., Kim, J. E., Kim, I. -C. & Kim, S. 2018. Anti-inflammation and anti-cancer activity of ethanol extract of antarctic freshwater microalga, Micractinium sp. Int. J. Med. Sci. 15:929-936. DOI
3	Komiya, T., Kyohkon, M., Ohwaki, S., Eto, J., Katsuzaki, H., Imai, K., Kataoka, T., Yoshioka, K., Ishii, Y. & Hibasami, H. 1999. Phytol induces programmed cell death in human lymphoid leukemia Molt 4B cells. Int. J. Mol. Med. 4:377-380.
4	Murbach Teles Andrade, B. F., Nunes Barbosa, L., da Silva Probst, I. & Fernandes Junior, A. 2014. Antimicrobial activity of essential oils. J. Essent. Oil Res. 26:34-40. DOI
5	Plackett, R. L. & Burman, J. P. 1946. The design of optimum multifactorial experiments. Biometrika 33:305-325. DOI
6	Rodriguez-Garcia, I. & Guil-Guerrero, J. L. 2008. Evaluation of the antioxidant activity of three microalgal species for use as dietary supplements and in the preservation of foods. Food Chem. 108:1023-1026. DOI
7	Islam, M. T., de Alencar, M. V. O. B., da Conceicao Machado, K., da Conceicao Machado, K., de Carvalho Melo-Cavalcante, A. A., de Sousa, D. P. & de Freitas, R. M. 2015. Phytol in a pharma-medico-stance. Chem. Biol. Interact. 240:60-73. DOI
8	Jaafari, J. & Yaghmaeian, K. 2019. Optimization of heavy metal biosorption onto freshwater algae (Chlorella coloniales) using response surface methodology (RSM). Chemosphere 217:447-455. DOI
9	Khan, M. I., Shin, J. H. & Kim, J. D. 2018. The promising future of microalgae: current status, challenges, and optimization of a sustainable and renewable industry for biofuels, feed, and other products. Microb. Cell Fact. 17:36. DOI
10	Kim, E. J., Jung, W., Lim, S., Kim, S., Han, S. J. & Choi, H. -G. 2016. Growth and lipid content at low temperature of Arctic alga Chlamydomonas sp. KNM0029C. Bioprocess Biosyst. Eng. 39:151-157. DOI
11	Borchert, E., Jackson, S. A., O'Gara, F. & Dobson, A. D. W. 2017. Psychrophiles as a source of novel antimicrobials. In Margesin, R. (Ed.) Psychrophiles: from Biodiversity to Biotechnology. Springer, Cham, pp. 527-540.
12	Brouchkov, A., Melnikov, V., Kalenova, L., Fursova, O., Pogorelko, G., Potapov, V., Fursova, N., Ignatov, S., Brenner, E., Bezrukov, V. & Muradian, K. 2017. Permafrost bacteria in biotechnology: biomedical applications. In Margesin, R. (Ed.) Psychrophiles: from Biodiversity to Biotechnology. Springer, Cham, pp. 541-554.
13	Chae, H., Lim, S., Kim, H. S., Choi, H. -G. & Kim, J. H. 2019. Morphology and phylogenetic relationships of Micractinium (Chlorellaceae, Trebouxiophyceae) taxa, including three new species from Antarctica. Algae 34:267-275. DOI
14	Chowdhury, R. R., Fitch, R. W. & Ghosh, S. K. 2013. Efficacy of phytol-derived diterpenoid immunoadjuvants over alum in shaping the murine host's immune response to Staphylococcus aureus. Vaccine 31:1178-1186. DOI
15	Czyrski, A. & Sznura, J. 2019. The application of Box-Behnken-Design in the optimization of HPLC separation of fluoroquinolones. Sci. Rep. 9:19458. DOI
16	Elshobary, M. E., Abo-Shady, A. M., Khairy, H. M., Essa, D., Zabed, H. M., Qi, X. & Abomohra, A. E. -F. 2019. Influence of nutrient supplementation and starvation conditions on the biomass and lipid productivities of Micractinium reisseri grown in wastewater for biodiesel production. J. Environ. Manage. 250:109529. DOI
17	Park, H. J., Lee, C. W., Kim, D., Do, H., Han, S. J., Kim, J. E., Koo, B. -H., Lee, J. H. & Yim, J. H. 2018. Crystal structure of a cold-active protease (Pro21717) from the psychrophilic bacterium, Pseudoalteromonas arctica PAMC 21717, at 1.4 A resolution: structural adaptations to cold and functional analysis of a laundry detergent enzyme. PLoS ONE 13:e0191740. DOI
18	Prabuseenivasan, S., Jayakumar, M. & Ignacimuthu, S. 2006. In vitro antibacterial activity of some plant essential oils. BMC Complement. Alternat. Med. 6:39. DOI
19	Remize, M., Brunel, Y., Silva, J. L., Berthon, J. -Y. & Filaire, E. 2021. Microalgae n-3 PUFAs production and use in food and feed industries. Mar. Drugs 19:113. DOI
20	Siram, K., Rahman, S. M. H., Balakumar, K., Duganath, N., Chandrasekar, R. & Hariprasad, R. 2019. Pharmaceutical nanotechnology: brief perspective on lipid drug delivery and its current scenario. In Andrew, W. (Ed.) Biomedical Applications of Nanoparticles. William Andrew Publishing, New York, pp. 91-115.
21	Sorokina, K. N., Samoylova, Y. V., Gromov, N. V., Ogorodnikova, O. L. & Parmon, V. N. 2020. Production of biodiesel and succinic acid from the biomass of the microalga Micractinium sp. IC-44. Bioresour. Technol. 317:124026. DOI
22	Subramaniyam, V., Subashchandrabose, S. R., Thavamani, P., Chen, Z., Krishnamurti, G. S. R., Naidu, R. & Megharaj, M. 2016. Toxicity and bioaccumulation of iron in soil microalgae. J. Appl. Phycol. 28:2767-2776. DOI
23	Suh, S. -S., Hong, J. -M., Kim, E. J., Jung, S. W., Chae, H., Kim, J. E., Jim, J. H., Kim, I. -C. & Kim, S. 2019. Antarctic freshwater microalga, Chloromonas reticulata, suppresses inflammation and carcinogenesis. Int. J. Med. Sci. 16:189-197. DOI
24	Ghaneian, M. T., Ehrampoush, M. H., Jebali, A., Hekmatimoghaddam, S. & Mahmoudi, M. 2015. Antimicrobial activity, toxicity and stability of phytol as a novel surface disinfectant. Environ. Health Eng. Manag. J. 2:13-16.
25	Barker, P. F., Filippelli, G. M., Florindo, F., Martin, E. E. & Scher, H. D. 2007. Onset and role of the Antarctic Circumpolar Current. Deep Sea Res. Part II Top. Stud. Oceanogr. 54:2388-2398. DOI
26	Teoh, M. -L., Chu, W. -L., Marchant, H. & Phang, S. -M. 2004. Influence of culture temperature on the growth, biochemical composition and fatty acid profiles of six Antarctic microalgae. J. Appl. Phycol. 16:421-430. DOI
27	Abou-Shanab, R. A. I., El-Dalatony, M. M., El-Sheekh, M. M., Ji, M. -K., Salama, E. -S., Kabra, A. N. & Jeon, B. -H. 2014. Cultivation of a new microalga, Micractinium reisseri, in municipal wastewater for nutrient removal, biomass, lipid, and fatty acid production. Biotechnol. Bioprocess Eng. 19:510-518. DOI
28	Box, G. E. P. & Behnken, D. W. 1960. Some new three level designs for the study of quantitative variables. Technometrics 2:455-475. DOI
29	Cho, S. M., Kim, S., Cho, H., Lee, H., Lee, J. H., Lee, H., Park, H., Kang, S., Choi, H. -G. & Lee, J. 2019. Type II ice-binding proteins isolated from an arctic microalga are similar to adhesin-like proteins and increase freezing tolerance in transgenic plants. Plant Cell Physiol. 60:2744-2757. DOI
30	Ekpenyong, M. G., Antai, S. P., Asitok, A. D. & Ekpo, B. O. 2017. Plackett-Burman design and response surface optimization of medium trace nutrients for glycolipopeptide biosurfactant production. Iran. Biomed. J. 21:249-260. DOI
31	Gutierrez, S., Svahn, S. L. & Johansson, M. E. 2019. Effects of omega-3 fatty acids on immune cells. Int. J. Mol. Sci. 20:5028. DOI
32	Jo, S. -W., Kang, N. -S., Chae, H., Lee, J. A., Kim, K. M., Yoon, M., Hong, J. W. & Yoon, H. -S. 2020. First record of a marine microalgal species, Micractinium singularis (Trebouxiophyceae) isolated from Janghang Harbor, Korea. Korean J. Environ. Biol. 38:61-70. DOI
33	Kim, E. J., Lee, J. H., Lee, S. G. & Han, S. J. 2017. Improving thermal hysteresis activity of antifreeze protein from recombinant Pichia pastoris by removal of N-glycosylation. Prep. Biochem. Biotechnol. 47:299-304. DOI