Characterization of Involved in Fatty Acid Transport for Oil Accumulation in the Green Alga

Overview

Journal Biotechnol Biofuels

Publisher Biomed Central

Specialty Biotechnology

Date 2019 Jan 18

PMID 30651755

Citations 19

Authors

Nannan Li

Yan Zhang

Hongjun Meng

Shengting Li

Shufeng Wang

Zhongchun Xiao

Peng Chang

Xiaohui Zhang

Qing Li

Liang Guo

Yasuo Igarashi

Feng Luo

Affiliations

Soon will be listed here.

Abstract

Background: In the past few decades, microalgae biofuel has become one of the most interesting sources of renewable energy. However, the higher cost of microalgae biofuel compared to that of petroleum prevented microalgae biofuel production. Therefore, the research on increasing lipid productivity from microalgae becomes more important. The lipid production source, triacylglycerol biosynthesis in microalgae requires short chain fatty acids as substrates, which are synthesized in chloroplasts. However, the transport mechanism of fatty acids from microalgae chloroplasts to cytosol remains unknown.

Results: cDNAs from two homologs of the Arabidopsis fatty acid exporter 1 (FAX1) were cloned from and were named and Both CrFAXs were involved in fatty acid transport, and their substrates were mainly C16 and C18 fatty acids. Overexpression of both CrFAXs increased the accumulation of the total lipid content in algae cells, and the fatty acid compositions were changed under normal TAP or nitrogen deprivation conditions. Overexpression of both CrFAXs also increased the chlorophyll content. The MGDG content was decreased but the TAG, DAG, DGDG and other lipid contents were increased in CrFAXs overexpression strains.

Conclusion: These results reveal that CrFAX1 and CrFAX2 were involved in mediating fatty acid export for lipids biosynthesis in . In addition, overexpression of both CrFAXs obviously increased the intracellular lipid content, especially the triacylglycerol content in microalgae, which provides a potential technology for the production of more biofuels using microalgae.

Citing Articles

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Towards Lipid from Microalgae: Products, Biosynthesis, and Genetic Engineering.

Xin Y, Wu S, Miao C, Xu T, Lu Y Life (Basel). 2024; 14(4).

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Fatty acid exporter 1 enhances seed oil content in .

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Co-Expression of Lipid Transporters Simultaneously Enhances Oil and Starch Accumulation in the Green Microalga under Nitrogen Starvation.

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Lipid turnover and SQUAMOSA promoter-binding proteins mediate variation in fatty acid desaturation under early nitrogen deprivation revealed by lipidomic and transcriptomic analyses in .

Wang R, Miao X Front Plant Sci. 2022; 13:987354.

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