极海洋模式纤毛虫杜氏副纤毛虫的基因组和比较转录组揭示了对环境盐度的适应。

IF 4.4 1区 生物学 Q1 BIOLOGY
Yu Fu, Ping Ni, Ying Zhang, Fasheng Liang, Naomi A Stover, Lifang Li
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引用次数: 0

摘要

背景:作为环境和细胞生物学研究的潜在模式生物,杜氏副动物(Paramecium duboscqui)是副动物中一种特殊的极卤型物种,可在淡水、咸水或海水中发现,自然盐度范围在 0‰至 33‰之间。然而,它的基因组信息和分子机制仍是未知数。为了描述其基因组特征,我们结合PacBio和Illumina测序技术,首次组装出了高质量、近乎完整的P. duboscqui大核基因组。同时,不同盐度条件下的转录组比较图谱使我们得以深入了解其适应盐度环境的分子机制:结果:研究结果表明,P. duboscqui的MAC基因组由160个片段组成,其中113个片段具有端粒(单倍体基因组大小约为28.82 Mb)。通过与其他纤毛虫的基因组比较分析,我们发现杜氏栉水母中编码跨膜转运蛋白的基因家族得到了扩展,显示了其在盐度适应方面的巨大潜力。与其他纤毛虫一样,杜氏拟尾柱虫使用 TGA 作为其唯一的终止密码子,并重新分配了 TAA 和 TAG 来编码谷氨酰胺。杜氏拟尾柱虫在不同盐度下的生长速度不同,在 5‰盐度下生长速度最佳。对不同浓度下生长的 P. duboscqui 的转录组图谱进行比较后发现,参与蛋白质折叠、氧呼吸和谷胱甘肽依赖性解毒的基因在高盐度组中上调,而编码 DNA 结合蛋白和转录因子的基因在低盐度组中上调,这表明对低盐度和高盐度的反应机制不同。加权基因共表达网络分析(WGCNA)将在30‰盐度下表达的枢纽基因与半胱氨酸型肽酶活性、脂质转移、钠氢交换和细胞分裂联系起来,而在0‰盐度下表达的枢纽基因则参与跨膜转运和蛋白质定位:本研究揭示了一种新的极卤型鹦鹉螺的特征,为鹦鹉螺的进化提供了新的见解,并描述了杜氏鹦鹉螺适应不同渗透环境的分子机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The genome and comparative transcriptome of the euryhaline model ciliate Paramecium duboscqui reveal adaptations to environmental salinity.

Background: As a potential model organism for studies of environmental and cell biology, Paramecium duboscqui is a special euryhaline species of Paramecium that can be found in fresh, brackish, or marine water in natural salinity ranges between 0‰ and 33‰. However, the genome information as well as molecular mechanisms that account for its remarkable halotolerant traits remain extremely unknown. To characterize its genome feature, we combined PacBio and Illumina sequencing to assemble the first high-quality and near-complete macronuclear genome of P. duboscqui. Meanwhile, comparative transcriptomic profiles under different salinities gave underlying insight into the molecular mechanism of its adaptations to environmental salinity.

Results: The results showed that the MAC genome of P. duboscqui comprises 160 contigs, with 113 of them possessing telomere (~ 28.82 Mb haploid genome size). Through comparative genomic analyses with the other ciliate, we found that gene families encoding transmembrane transporter proteins have been expanded in P. duboscqui, showing enormous potential in salinity adaptation. Like other Paramecium, P. duboscqui utilizes TGA as its only termination codon and has reassigned TAA and TAG to encode glutamine. P. duboscqui showed different growth rates under different salinities, with an optimum growth rate in 5‰ salinity. A comparison of the transcriptomic profiles among P. duboscqui grown under different concentrations showed that genes involved in protein folding, oxygen respiration, and glutathione-dependent detoxification were upregulated in the high-salt group, whereas genes encoding DNA-binding proteins and transcription factors were upregulated in the low-salt group, suggesting distinct mechanisms for responding to low and high salinity. Weighted gene coexpression network analysis (WGCNA) linked the hub genes expressed at 30‰ salinity to cysteine-type peptidase activity, lipid transfer, sodium hydrogen exchange, and cell division, with the hub genes expressed at 0‰ salinity involved in transmembrane transport and protein localization.

Conclusions: This study characterizes a new euryhaline model Paramecium, provides novel insights into Paramecium evolution, and describes the molecular mechanisms that have allow P. duboscqui to adapt to different osmotic environments.

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来源期刊
BMC Biology
BMC Biology 生物-生物学
CiteScore
7.80
自引率
1.90%
发文量
260
审稿时长
3 months
期刊介绍: BMC Biology is a broad scope journal covering all areas of biology. Our content includes research articles, new methods and tools. BMC Biology also publishes reviews, Q&A, and commentaries.
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