弧菌中的噬菌体

Kerrin Steensen, Joana Séneca, Nina Bartlau, Xiaoqian A Yu, Fatima A Hussain, Martin F Polz
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摘要

尽管人们认为有尾噬菌体(Caudoviricetes)类噬菌体构成了最丰富、与生态最相关的噬菌体群体,它们可以将基因组整合到宿主染色体中,但越来越清楚的是,其他噬菌体也广泛存在。在这里,我们发现基因组大小低于 16 kb 的丝状噬菌体和无尾噬菌体衍生出的噬菌体构成了弧菌属海洋细菌中噬菌体的主体。为了估算噬菌体的流行率而不受数据库偏差的影响,我们对 58 个不同的环养弧菌分离物进行了比较基因组学和化学诱导,得到了 107 个经过精心筛选的噬菌体。作为对计算预测噬菌体的补充,我们从 931 株自然共存的弧菌科菌株中获得了 1,158 个噬菌体。类似无尾噬菌体和丝状噬菌体的噬菌体占绝大多数,占环口噬菌体所有噬菌体的 80%,占整个弧菌科噬菌体的 60%。在我们的实验模型中,所有三种病毒领域的噬菌体在诱导后都会积极复制,这表明它们有能力转移到新的宿主身上。事实上,噬菌体的增殖和消失都很迅速,这一点从近缘的环养荚膜葡萄球菌之间不同的噬菌体含量可以看出。与丝状噬菌体和无尾噬菌体有关的噬菌体只整合到了三个基因组位置,并恢复了整合位点的功能。尽管噬菌体的体积很小,但它们含有高度多样化的附属基因,这些基因可能有助于宿主的健康,如噬菌体防御系统。我们认为,无尾噬菌体和丝状温带噬菌体就像研究得很透彻的有尾噬菌体一样,是海洋弧菌宿主生态学和进化的活跃和高度丰富的驱动因素,而这些因素在很大程度上被忽视了。
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Prophages in Vibrio
Although tailed bacteriophages (phages) of the class Caudoviricetes are thought to constitute the most abundant and ecologically relevant group of phages that can integrate their genome into the host chromosome, it is becoming increasingly clear that other prophages are widespread. Here, we show that prophages derived from filamentous and tailless phages with genome sizes below 16 kb make up the majority of prophages in marine bacteria of the genus Vibrio. To estimate prophage prevalence unaffected by database biases, we combined comparative genomics and chemical induction of 58 diverse Vibrio cyclitrophicus isolates, resulting in 107 well-curated prophages. Complemented with computationally predicted prophages, we obtained 1,158 prophages from 931 naturally co-existing strains of the family Vibrionaceae. Prophages resembling tailless and filamentous phages predominated, accounting for 80% of all prophages in V. cyclitrophicus and 60% across the Vibrionaceae. In our experimental model, prophages of all three viral realms actively replicated upon induction indicating their ability to transfer to new hosts. Indeed, prophages were rapidly gained and lost, as suggested by variable prophage content between closely related V. cyclitrophicus. Prophages related to filamentous and tailless phages were integrated into only three genomic locations and restored the function of their integration site. Despite their small size, they contained highly diverse accessory genes that may contribute to host fitness, such as phage defense systems. We propose that, like their well-studied tailed equivalent, tailless and filamentous temperate phages are active and highly abundant drivers of host ecology and evolution in marine Vibrio, which have been largely overlooked.
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