Faculty of Biology, Technion, Israel Institute of Technology, Haifa, Israel.
ISME J. 2011 Jul;5(7):1178-90. doi: 10.1038/ismej.2011.2. Epub 2011 Feb 10.
Viral genomes often contain genes recently acquired from microbes. In some cases (for example, psbA) the proteins encoded by these genes have been shown to be important for viral replication. In this study, using a unique search strategy on the Global Ocean Survey (GOS) metagenomes in combination with marine virome and microbiome pyrosequencing-based datasets, we characterize previously undetected microbial metabolic capabilities concealed within the genomes of uncultured marine viral communities. A total of 34 microbial gene families were detected on 452 viral GOS scaffolds. The majority of auxiliary metabolic genes found on these scaffolds have never been reported in phages. Host genes detected in viruses were mainly divided between genes encoding for different energy metabolism pathways, such as electron transport and newly identified photosystem genes, or translation and post-translation mechanism related. Our findings suggest previously undetected ways, in which marine phages adapt to their hosts and improve their fitness, including translation and post-translation level control over the host rather than the already known transcription level control.
病毒基因组通常包含最近从微生物中获得的基因。在某些情况下(例如 psbA),这些基因编码的蛋白质已被证明对病毒复制很重要。在这项研究中,我们使用全球海洋调查 (GOS) 宏基因组上的独特搜索策略,结合海洋病毒组和基于微生物组焦磷酸测序的数据集,对未培养海洋病毒群落基因组中隐藏的以前未检测到的微生物代谢能力进行了描述。在 452 个病毒 GOS 支架上共检测到 34 个微生物基因家族。这些支架上发现的大多数辅助代谢基因从未在噬菌体中报道过。在病毒中检测到的宿主基因主要分为不同能量代谢途径的编码基因,如电子传递和新发现的光合作用基因,或翻译和翻译后机制相关的基因。我们的研究结果表明,海洋噬菌体以前未被发现的适应宿主和提高自身适应性的方式,包括对宿主的翻译和翻译后水平控制,而不是已经知道的转录水平控制。