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日本池塘中微囊藻噬藻体的昼夜感染模式及其影响。

Diurnal infection patterns and impact of Microcystis cyanophages in a Japanese pond.

机构信息

Graduate School of Agriculture, Kyoto University, Kitashirakawa-Oiwake, Sakyo-ku, Kyoto, Japan.

出版信息

Appl Environ Microbiol. 2012 Aug;78(16):5805-11. doi: 10.1128/AEM.00571-12. Epub 2012 Jun 8.

Abstract

Viruses play important roles in regulating the abundance, clonal diversity, and composition of their host populations. To assess their impact on the host populations, it is essential to understand the dynamics of virus infections in the natural environment. Cyanophages often carry host-like genes, including photosynthesis genes, which maintain host photosynthesis. This implies a diurnal pattern of cyanophage infection depending on photosynthesis. Here we investigated the infection pattern of Microcystis cyanophage by following the abundances of the Ma-LMM01-type phage tail sheath gene g91 and its transcript in a natural population. The relative g91 mRNA abundance within host cells showed a peak during the daylight hours and was lowest around midnight. The phage g91 DNA copy numbers in host cell fractions, which are predicted to indicate phage replication, increased in the afternoon, followed by an increase in the free-phage fractions. In all fractions, at least 1 of 71 g91 genotypes was observed (in tested host cell, free-phage, and RNA fractions), indicating that the replication cycle of the cyanophage (i.e., injection, transcription, replication, and release of progeny phages) was occurring. Thus, Microcystis cyanophage infection occurs in a diel cycle, which may depend on the light cycle. Additionally, our data show that the abundance of mature cyanophage produced within host cells was 1 to 2 orders of magnitude greater than that of released phages, suggesting that phage production may be higher than previously reported.

摘要

病毒在调节宿主种群的丰度、克隆多样性和组成方面发挥着重要作用。为了评估它们对宿主种群的影响,了解自然环境中病毒感染的动态至关重要。蓝藻噬菌体通常携带宿主样基因,包括光合作用基因,这些基因维持宿主的光合作用。这意味着蓝藻噬菌体的感染模式取决于光合作用呈昼夜节律变化。在这里,我们通过跟踪自然种群中 Ma-LMM01 型噬菌体尾鞘基因 g91 及其转录物的丰度来研究微囊藻噬菌体的感染模式。宿主细胞内相对 g91 mRNA 丰度在白天达到峰值,午夜左右最低。宿主细胞部分中噬菌体 g91 DNA 拷贝数(预计可指示噬菌体复制)在下午增加,随后游离噬菌体部分增加。在所有部分中,至少观察到 71 个 g91 基因型中的 1 个(在测试的宿主细胞、游离噬菌体和 RNA 部分),这表明蓝藻噬菌体的复制周期(即注射、转录、复制和释放子代噬菌体)正在发生。因此,微囊藻噬菌体感染呈昼夜节律变化,这可能取决于光周期。此外,我们的数据表明,在宿主细胞内产生的成熟噬菌体的丰度比释放的噬菌体高 1 到 2 个数量级,这表明噬菌体的产生可能比之前报道的要高。

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本文引用的文献

1
A novel cyanophage with a cyanobacterial nonbleaching protein A gene in the genome.
J Virol. 2012 Jan;86(1):236-45. doi: 10.1128/JVI.06282-11. Epub 2011 Oct 26.
2
Defense islands in bacterial and archaeal genomes and prediction of novel defense systems.
J Bacteriol. 2011 Nov;193(21):6039-56. doi: 10.1128/JB.05535-11. Epub 2011 Sep 9.
3
Phage auxiliary metabolic genes and the redirection of cyanobacterial host carbon metabolism.
Proc Natl Acad Sci U S A. 2011 Sep 27;108(39):E757-64. doi: 10.1073/pnas.1102164108. Epub 2011 Aug 15.
4
Molecular enumeration of an ecologically important cyanophage in a Laurentian Great Lake.
Appl Environ Microbiol. 2011 Oct;77(19):6772-9. doi: 10.1128/AEM.05879-11. Epub 2011 Aug 12.
7
Genomic analysis of oceanic cyanobacterial myoviruses compared with T4-like myoviruses from diverse hosts and environments.
Environ Microbiol. 2010 Nov;12(11):3035-56. doi: 10.1111/j.1462-2920.2010.02280.x.
9
Bacteriophage resistance mechanisms.
Nat Rev Microbiol. 2010 May;8(5):317-27. doi: 10.1038/nrmicro2315. Epub 2010 Mar 29.
10
Ratification vote on taxonomic proposals to the International Committee on Taxonomy of Viruses (2009).
Arch Virol. 2010;155(1):133-46. doi: 10.1007/s00705-009-0547-x. Epub 2009 Dec 4.

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