嗜酸绿藻基因组为适应酸性环境提供了线索。
Acidophilic green algal genome provides insights into adaptation to an acidic environment.
机构信息
Department of Cell Genetics, National Institute of Genetics, Shizuoka 411-8540, Japan;
Core Research for Evolutional Science and Technology, Japan Science and Technology Agency, Saitama 332-0012, Japan.
出版信息
Proc Natl Acad Sci U S A. 2017 Sep 26;114(39):E8304-E8313. doi: 10.1073/pnas.1707072114. Epub 2017 Sep 11.
Abstract
Some microalgae are adapted to extremely acidic environments in which toxic metals are present at high levels. However, little is known about how acidophilic algae evolved from their respective neutrophilic ancestors by adapting to particular acidic environments. To gain insights into this issue, we determined the draft genome sequence of the acidophilic green alga and performed comparative genome and transcriptome analyses between and its neutrophilic relative The results revealed the following features in that probably contributed to the adaptation to an acidic environment. Genes encoding heat-shock proteins and plasma membrane H-ATPase are highly expressed in This species has also lost fermentation pathways that acidify the cytosol and has acquired an energy shuttle and buffering system and arsenic detoxification genes through horizontal gene transfer. Moreover, the arsenic detoxification genes have been multiplied in the genome. These features have also been found in other acidophilic green and red algae, suggesting the existence of common mechanisms in the adaptation to acidic environments.
摘要
一些微藻适应于存在高浓度毒性金属的极端酸性环境中。然而,对于嗜酸藻类如何通过适应特定的酸性环境从各自的嗜中性祖先进化而来,人们知之甚少。为了深入了解这个问题,我们测定了嗜酸绿藻的基因组草图序列,并对其与嗜中性亲缘种 进行了比较基因组和转录组分析。结果揭示了 可能有助于适应酸性环境的以下特征。在 中,热休克蛋白和质膜 H+-ATPase 的编码基因高度表达。该物种还失去了使细胞质酸化的发酵途径,并通过水平基因转移获得了能量穿梭和缓冲系统以及砷解毒基因。此外,砷解毒基因在基因组中大量扩增。这些特征也存在于其他嗜酸绿藻和红藻中,表明在适应酸性环境方面存在共同的机制。
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