通过工程化微藻-细菌群落来提高微藻生物质生产力。

Enhancing microalgal biomass productivity by engineering a microalgal-bacterial community.

机构信息

Sustainable Bioresource Research Center, Korea Research Institute of Bioscience and Biotechnology (KRIBB), Daejeon 305 806, Republic of Korea.

Sustainable Bioresource Research Center, Korea Research Institute of Bioscience and Biotechnology (KRIBB), Daejeon 305 806, Republic of Korea; Major of Green Chemistry and Environmental Biotechnology, University of Science & Technology (UST), Daejeon 305 350, Republic of Korea.

出版信息

Bioresour Technol. 2015 Jan;175:578-85. doi: 10.1016/j.biortech.2014.10.159. Epub 2014 Nov 6.

DOI:10.1016/j.biortech.2014.10.159

PMID:25459870

Abstract

This study demonstrates that ecologically engineered bacterial consortium could enhance microalgal biomass and lipid productivities through carbon exchange. Phycosphere bacterial diversity analysis in xenic Chlorella vulgaris (XCV) confirmed the presence of growth enhancing and inhibiting microorganisms. Co-cultivation of axenic C. vulgaris (ACV) with four different growth enhancing bacteria revealed a symbiotic relationship with each bacterium. An artificial microalgal-bacterial consortium (AMBC) constituting these four bacteria and ACV showed that the bacterial consortium exerted a statistically significant (P<0.05) growth enhancement on ACV. Moreover, AMBC had superior flocculation efficiency, lipid content and quality. Studies on carbon exchange revealed that bacteria in AMBC might utilize fixed organic carbon released by microalgae, and in return, supply inorganic and low molecular weight (LMW) organic carbon influencing algal growth and metabolism. Such exchanges, although species specific, have enormous significance in carbon cycle and can be exploitated by microalgal biotechnology industry.

摘要

本研究表明，通过碳交换，生态工程细菌联合体可以提高微藻生物量和油脂产量。异养小球藻（XCV）的菌根细菌多样性分析证实了存在促进生长和抑制微生物的存在。与四种不同的生长促进细菌共培养的无菌小球藻（ACV）显示出与每种细菌的共生关系。由这四种细菌和 ACV 组成的人工微藻-细菌联合体（AMBC）表明，细菌联合体对 ACV 表现出统计学上显著的（P<0.05）生长促进作用。此外，AMBC 具有更高的絮凝效率、脂质含量和质量。对碳交换的研究表明，AMBC 中的细菌可能利用微藻释放的固定有机碳，而作为回报，提供无机和低分子量（LMW）有机碳，影响藻类的生长和代谢。这种交换虽然具有物种特异性，但在碳循环中具有巨大的意义，可以被微藻生物技术产业利用。

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通过工程化微藻-细菌群落来提高微藻生物质生产力。

Enhancing microalgal biomass productivity by engineering a microalgal-bacterial community.

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