Bacteriophage self-counting in the presence of viral replication

Tianyou Yao, Seth T. Coleman, Thu Vu Phuc Nguyen, I. Golding, O. Igoshin
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引用次数: 7

Abstract

Significance Viral dormancy, in which the infected cell is not killed but rather becomes the long-term residence of the parasite, is a hallmark of viruses across kingdoms from bacteriophages to HIV. When and how viruses decide to opt for this lifestyle remains mysterious. Phage lambda, which serves as a paradigm for viral dormancy, is reported to count the number of coinfecting viruses and then uses this value to assess the abundance of potential hosts and decide whether to become dormant. Here, we use a single-cell measurement of viruses and messenger RNA together with mathematical modeling to illuminate how lambda performs this task. When host cells are in low abundance, temperate bacteriophages opt for dormant (lysogenic) infection. Phage lambda implements this strategy by increasing the frequency of lysogeny at higher multiplicity of infection (MOI). However, it remains unclear how the phage reliably counts infecting viral genomes even as their intracellular number increases because of replication. By combining theoretical modeling with single-cell measurements of viral copy number and gene expression, we find that instead of hindering lambda’s decision, replication facilitates it. In a nonreplicating mutant, viral gene expression simply scales with MOI rather than diverging into lytic (virulent) and lysogenic trajectories. A similar pattern is followed during early infection by wild-type phage. However, later in the infection, the modulation of viral replication by the decision genes amplifies the initially modest gene expression differences into divergent trajectories. Replication thus ensures the optimal decision—lysis upon single-phage infection and lysogeny at higher MOI.
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在病毒复制的情况下噬菌体自我计数
病毒休眠是病毒从噬菌体到HIV的一个特征,在这个过程中,受感染的细胞没有被杀死,而是成为寄生虫的长期居住地。病毒何时以及如何决定选择这种生活方式仍然是个谜。噬菌体lambda是病毒休眠的范例,据报道,它可以计算感染病毒的数量,然后使用这个值来评估潜在宿主的丰度,并决定是否进入休眠状态。在这里,我们使用病毒和信使RNA的单细胞测量以及数学建模来阐明lambda如何执行此任务。当宿主细胞丰度较低时,温带噬菌体选择休眠(溶原性)感染。噬菌体lambda通过提高感染多重度(MOI)时溶原性的频率来实现这一策略。然而,目前尚不清楚噬菌体如何可靠地计数感染病毒基因组,即使它们的细胞内数量因复制而增加。通过将理论建模与病毒拷贝数和基因表达的单细胞测量相结合,我们发现复制非但没有阻碍λ的决定,反而促进了它的决定。在非复制突变体中,病毒基因表达仅与MOI成比例,而不是分化成裂解(毒力)和溶原轨迹。在野生型噬菌体的早期感染期间也遵循类似的模式。然而,在感染后期,决定基因对病毒复制的调节将最初适度的基因表达差异放大为不同的轨迹。因此,复制确保了在单菌体感染时的最佳决策裂解和在较高MOI下的溶原。
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