中等生长速度的布朗葡萄藻779（绿藻门）亚分离株对氮缺乏响应的转录组分析。

Transcriptomic analysis of a moderately growing subisolate Botryococcus braunii 779 (Chlorophyta) in response to nitrogen deprivation.

作者信息

Fang Lei, Sun Deying, Xu Zhenyu, He Jing, Qi Shuyuan, Chen Xin, Chew Wee, Liu Jianhua

机构信息

Collaborative Innovation Center of Deep Sea Biology, Ocean College, Zhejiang University, Hangzhou, 310058 Zhejiang China.

Dalian Ocean University, Dalian, 116023 Liaoning China.

出版信息

Biotechnol Biofuels. 2015 Aug 28;8:130. doi: 10.1186/s13068-015-0307-y. eCollection 2015.

DOI:10.1186/s13068-015-0307-y

PMID:26322124

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4552190/

Abstract

BACKGROUND

The colonial microalga Botryococcus braunii has been brought to people's attention for its conspicuous ability to accumulate a variety of lipids including hydrocarbons. B. braunii strains are classified into 3 races based on the types of hydrocarbons. A and B races are known to accumulate high level of lipids. However, their extreme slow growth rate has impeded its application for renewable biofuel production.

RESULTS

In this study, we report the transcriptomic response of a moderately growing subisolate from the culture of Botryococcus sp. CCALA-779 upon nitrogen deprivation (ND). We show that the subisolate has an average growth rate of 0.52 g l(-1) day(-1) under photoautotrophic growth conditions and lipid content is enhanced to 75 % of CDW upon ND. Both rDNA sequence and hydrocarbon composition analyses indicate that the subisolate belongs to A race B. braunii. Hence, it is designated as B. braunii 779. We show that B. braunii 779 transcriptome shares homology to majority of the A race but not B race B. braunii ESTs, suggesting that transcriptomes of A race differ from that of B race. We found that many homologous ESTs between A races 779 and Bot-88 are unknown sequences, implying that A race contains many unknown genes. Pathway-based transcriptomic analysis indicates that energy metabolisms are among the top expressed functions in log-phase cells, indicating that the slow growth rate is a result that energy flow is directed to lipid biosynthesis but not population growth. Upon ND, reconfiguration of metabolisms for reducing power is apparent, suggesting that B. braunii 779 is rapidly adapting under ND condition by transcriptomic reprogramming.

CONCLUSIONS

Taken together, our result shows that the subisolate B. braunii 779, similar to the Gottingen strain, is useful for biofuel production. Difference between transcriptomes of A and B races implies that different races of B. braunii strains belong to different sub-species. Furthermore, there are many novel genes that are unique to A race, suggesting that sequences of many enzymes involved in hydrocarbon biosynthesis are not currently known. We propose that B. braunii transcriptomes provide a rich source for discovery of novel genes involved in hydrocarbon biosynthesis.

摘要

背景

殖民微藻布朗葡萄藻因其积累包括碳氢化合物在内的多种脂质的显著能力而受到人们关注。布朗葡萄藻菌株根据碳氢化合物类型分为3个族。已知A族和B族积累高水平脂质。然而，它们极慢的生长速度阻碍了其在可再生生物燃料生产中的应用。

结果

在本研究中，我们报告了来自布朗葡萄藻CCALA - 779培养物的一个适度生长的亚分离株在氮剥夺（ND）条件下的转录组反应。我们表明该亚分离株在光自养生长条件下的平均生长速率为0.52 g l⁻¹ 天⁻¹，并且在氮剥夺后脂质含量提高到细胞干重的75%。rDNA序列和碳氢化合物组成分析均表明该亚分离株属于布朗葡萄藻A族。因此，将其命名为布朗葡萄藻779。我们表明布朗葡萄藻779转录组与大多数A族但不是B族布朗葡萄藻EST具有同源性，这表明A族转录组与B族不同。我们发现A族779和Bot - 88之间的许多同源EST是未知序列，这意味着A族包含许多未知基因。基于通路的转录组分析表明，能量代谢是对数期细胞中表达量最高的功能之一，这表明生长速度缓慢是能量流导向脂质生物合成而非群体生长的结果。在氮剥夺后，用于还原力的代谢重配置很明显，这表明布朗葡萄藻779通过转录组重编程在氮剥夺条件下迅速适应。

结论

综上所述，我们的结果表明，与哥廷根菌株类似，亚分离株布朗葡萄藻779可用于生物燃料生产。A族和B族转录组之间的差异意味着不同族的布朗葡萄藻菌株属于不同的亚种。此外，有许多A族特有的新基因，这表明目前尚不知道许多参与碳氢化合物生物合成的酶的序列。我们提出布朗葡萄藻转录组为发现参与碳氢化合物生物合成的新基因提供了丰富来源。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ab0e/4552190/cb22bdf7d23e/13068_2015_307_Fig1_HTML.jpg

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中等生长速度的布朗葡萄藻779（绿藻门）亚分离株对氮缺乏响应的转录组分析。

Transcriptomic analysis of a moderately growing subisolate Botryococcus braunii 779 (Chlorophyta) in response to nitrogen deprivation.

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