对海洋硫酸盐还原丝状脱硫浮游动物(Desulfonema limicola)和脱硫浮游动物(Desulfonema magnum)生理学的蛋白质基因组学见解。

Pub Date : 2021-02-19 DOI:10.1159/000513383
Vanessa Schnaars, Lars Wöhlbrand, Sabine Scheve, Christina Hinrichs, Richard Reinhardt, Ralf Rabus
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引用次数: 0

摘要

Desulfonema属属于脱硫杆菌科(Desulfobacteraceae)脱硫杆菌属(deltaproteobacterial),由海洋硫酸盐还原细菌组成,它们能形成菌丝并通过滑行移动。本研究报告了 Dn. limicola 5ac10T(6.91 Mbp;6 207 CDS)和 Dn. magnum 4be13T(8.03 Mbp;9 970 CDS)的完整人工注释基因组,并整合了底物特异性蛋白质组图谱(8 对 11)。移动遗传元件的丰富程度与其他脱硫杆菌科成员相同,这证实了水平基因转移是形成该家族基因组的主要驱动力。Dn. limicola 和 Dn. magnum 的分解代谢网络具有以下一般特征:分配的基因数分别为 98 个和 145 个(基因组份额分别为 1.7% 和 2.2%),蛋白质组覆盖率分别为 92.5% 和 89.7%,底物降解和能量代谢基因群分散。Dn. magnum 的芳香化合物降解能力(如对甲酚、3-苯基丙酸酯)需要 48 个基因,这些基因组成了操作子样结构(蛋白质组覆盖率为 87.7%;Dn. limicola 中没有同源基因)。两个基因组中脂肪族化合物降解、中心途径和能量代谢的蛋白质互补高度相似,并在很大程度上(69-96%)得到了鉴定。差异蛋白图谱显示,外围反应序列(形成中心中间体)具有高度的底物特异性,这与预测的两种菌株的大量感觉/调节蛋白相吻合。相比之下,在测试的底物条件下,能量代谢的中心途径和模块是组成性形成的。由于其自然栖息地的理化参数会发生波动性变化,因此这两种 Desulfonema 菌株都能很好地应对各种压力条件。除了超氧化物歧化酶和过氧化氢酶之外,还形成了脱硫铁氧还蛋白和红宝石还蛋白氧化还原酶,以抵御分子氧的侵袭。还检测到多种蛋白酶和伴侣蛋白,它们在热或冷休克时起着维持细胞平衡的作用。此外,甘氨酸甜菜碱/脯氨酸甜菜碱运输系统可对高渗透压做出反应。滑行运动可能依赖于通过 IV 型纤毛器的抽动运动或冒险运动。总之,这项蛋白质基因组研究表明,Dn. limicola和Dn. magnum能通过灵活的分解代谢和广泛的应激反应能力来适应其动态栖息地。
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Proteogenomic Insights into the Physiology of Marine, Sulfate-Reducing, Filamentous Desulfonema limicola and Desulfonema magnum.

The genus Desulfonema belongs to the deltaproteobacterial family Desulfobacteraceae and comprises marine, sulfate-reducing bacteria that form filaments and move by gliding. This study reports on the complete, manually annotated genomes of Dn. limicola 5ac10T (6.91 Mbp; 6,207 CDS) and Dn. magnum 4be13T (8.03 Mbp; 9,970 CDS), integrated with substrate-specific proteome profiles (8 vs. 11). The richness in mobile genetic elements is shared with other Desulfobacteraceae members, corroborating horizontal gene transfer as major driver in shaping the genomes of this family. The catabolic networks of Dn. limicola and Dn. magnum have the following general characteristics: 98 versus 145 genes assigned (having genomic shares of 1.7 vs. 2.2%), 92.5 versus 89.7% proteomic coverage, and scattered gene clusters for substrate degradation and energy metabolism. The Dn. magnum typifying capacity for aromatic compound degradation (e.g., p-cresol, 3-phenylpropionate) requires 48 genes organized in operon-like structures (87.7% proteomic coverage; no homologs in Dn. limicola). The protein complements for aliphatic compound degradation, central pathways, and energy metabolism are highly similar between both genomes and were identified to a large extent (69-96%). The differential protein profiles revealed a high degree of substrate-specificity for peripheral reaction sequences (forming central intermediates), agreeing with the high number of sensory/regulatory proteins predicted for both strains. By contrast, central pathways and modules of the energy metabolism were constitutively formed under the tested substrate conditions. In accord with their natural habitats that are subject to fluctuating changes of physicochemical parameters, both Desulfonema strains are well equipped to cope with various stress conditions. Next to superoxide dismutase and catalase also desulfoferredoxin and rubredoxin oxidoreductase are formed to counter exposure to molecular oxygen. A variety of proteases and chaperones were detected that function in maintaining cellular homeostasis upon heat or cold shock. Furthermore, glycine betaine/proline betaine transport systems can respond to hyperosmotic stress. Gliding movement probably relies on twitching motility via type-IV pili or adventurous motility. Taken together, this proteogenomic study demonstrates the adaptability of Dn. limicola and Dn. magnum to its dynamic habitats by means of flexible catabolism and extensive stress response capacities.

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