不同碳源和氮源条件下异养产油微藻伯纳德四列藻的生物量、脂质积累动力学及转录组

Biomass, lipid accumulation kinetics, and the transcriptome of heterotrophic oleaginous microalga Tetradesmus bernardii under different carbon and nitrogen sources.

作者信息

Gao Baoyan, Wang Feifei, Huang Luodong, Liu Hui, Zhong Yuming, Zhang Chengwu

机构信息

Department of Ecology, Research Center for Hydrobiology, Jinan University, Guangzhou, 510632, People's Republic of China.

College of Resources and Environment, Zhongkai University of Agriculture and Engineering, Guangzhou, 510225, China.

出版信息

Biotechnol Biofuels. 2021 Jan 6;14(1):4. doi: 10.1186/s13068-020-01868-9.

DOI:10.1186/s13068-020-01868-9

PMID:33407769

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7789750/

Abstract

BACKGROUND

Heterotrophic cultivation of microalgae has been proposed as a viable alternative method for novel high-value biomolecules, enriched biomass, and biofuel production because of their allowance of high cell density levels, as well as simple production technology. Tetradesmus bernardii, a newly isolated high-yielding oleaginous microalga under photoautotrophic conditions, is able to grow heterotrophically, meaning that it can consume organic carbon sources in dark condition. We investigated the effect of different carbon/nitrogen (C/N) ratios on the growth and lipid accumulation of T. bernardii in heterotrophic batch culture under two nitrogen sources (NaNO and CO(NH)). In addition, we conducted time-resolved transcriptome analysis to reveal the metabolic mechanism of T. bernardii in heterotrophic culture.

RESULTS

T. bernardii can accumulate high biomass concentrations in heterotrophic batch culture where the highest biomass of 46.09 g/L was achieved at 100 g/L glucose concentration. The rate of glucose to biomass exceeded 55% when the glucose concentration was less than 80 g/L, and the C/N ratio was 44 at urea treatment. The culture was beneficial to lipid accumulation at a C/N ratio between 110 and 130. NaNO used as a nitrogen source enhanced the lipid content more than urea, and the highest lipid content was 45% of dry weight. We performed RNA-seq to analyze the time-resolved transcriptome of T. bernardii. As the nitrogen was consumed in the medium, nitrogen metabolism-related genes were significantly up-regulated to speed up the N metabolic cycle. As chloroplasts were destroyed in the dark, the metabolism of cells was transferred from chloroplasts to cytoplasm. However, storage of carbohydrate in chloroplast remained active, mainly the synthesis of starch, and the precursor of starch synthesis in heterotrophic culture may largely come from the absorption of organic carbon source (glucose). With regard to lipid metabolism, the related genes of fatty acid synthesis in low nitrogen concentration increased gradually with the extension of cultivation time.

CONCLUSION

T. bernardii exhibited rapid growth and high lipid accumulation in heterotrophic culture. It may be a potential candidate for biomass and biofuel production. Transcriptome analysis showed that multilevel regulation ensured the conversion from carbon to the synthesis of carbohydrate and lipid.

摘要

背景

微藻的异养培养因其能够实现高细胞密度水平以及生产技术简单，已被提议作为生产新型高价值生物分子、富集生物质和生物燃料的一种可行替代方法。伯纳德四列藻是一种新分离出的在光自养条件下高产的产油微藻，它能够进行异养生长，即在黑暗条件下消耗有机碳源。我们研究了在两种氮源（NaNO₃和CO(NH₂)₂）下，不同碳氮（C/N）比在异养分批培养中对伯纳德四列藻生长和脂质积累的影响。此外，我们进行了时间分辨转录组分析，以揭示伯纳德四列藻在异养培养中的代谢机制。

结果

伯纳德四列藻在异养分批培养中能够积累高生物量浓度，在100 g/L葡萄糖浓度下实现了最高生物量46.09 g/L。当葡萄糖浓度低于80 g/L且尿素处理时，葡萄糖转化为生物量的比率超过55%，C/N比为44。在C/N比为110至130之间时，培养有利于脂质积累。用作氮源的NaNO₃比尿素更能提高脂质含量，最高脂质含量为干重的45%。我们进行了RNA测序以分析伯纳德四列藻的时间分辨转录组。随着培养基中氮的消耗，与氮代谢相关的基因显著上调以加速氮代谢循环。由于叶绿体在黑暗中被破坏，细胞代谢从叶绿体转移到细胞质。然而，叶绿体中碳水化合物的储存仍然活跃，主要是淀粉的合成，异养培养中淀粉合成的前体可能很大程度上来自有机碳源（葡萄糖）的吸收。关于脂质代谢，低氮浓度下脂肪酸合成的相关基因随着培养时间的延长逐渐增加。

结论

伯纳德四列藻在异养培养中表现出快速生长和高脂质积累。它可能是生物质和生物燃料生产的潜在候选者。转录组分析表明，多级调控确保了从碳到碳水化合物和脂质合成的转化。

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不同碳源和氮源条件下异养产油微藻伯纳德四列藻的生物量、脂质积累动力学及转录组

Biomass, lipid accumulation kinetics, and the transcriptome of heterotrophic oleaginous microalga Tetradesmus bernardii under different carbon and nitrogen sources.

作者信息

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出版信息

BACKGROUND

RESULTS

CONCLUSION

背景

结果

结论

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