Department of Biology, Indiana University, Bloomington, Indiana, USA.
Department of Soil and Crop Sciences, Colorado State University, Fort Collins, Colorado, USA.
mBio. 2023 Jun 27;14(3):e0018223. doi: 10.1128/mbio.00182-23. Epub 2023 Apr 12.
Spore-forming bacteria are prevalent in mammalian guts and have implications for host health and nutrition. The production of dormant spores is thought to play an important role in the colonization, persistence, and transmission of these bacteria. Spore formation also modifies interactions among microorganisms such as infection by phages. Recent studies suggest that phages may counter dormancy-mediated defense through the expression of phage-carried sporulation genes during infection, which can alter the transitions between active and inactive states. By mining genomes and gut-derived metagenomes, we identified sporulation genes that are preferentially carried by phages that infect spore-forming bacteria. These included genes involved in chromosome partitioning, DNA damage repair, and cell wall-associated functions. In addition, phages contained homologs of sporulation-specific transcription factors, notably , the master regulator of sporulation, which could allow phages to control the complex genetic network responsible for spore development. Our findings suggest that phages could influence the formation of bacterial spores with implications for the health of the human gut microbiome, as well as bacterial communities in other environments. Phages acquire bacterial genes and use them to alter host metabolism in ways that enhance phage fitness. To date, most auxiliary genes replace or modulate enzymes that are used by the host for nutrition or energy production. However, phage fitness is affected by all aspects of host physiology, including decisions that reduce the metabolic activity of the cell. Here, we focus on endosporulation, a complex and ancient form of dormancy found among the that involves hundreds of genes. By coupling homology searches with host classification, we identified 31 phage-carried homologs of sporulation genes that are mostly limited to phages infecting spore-forming bacteria. Nearly one-third of the homologs recovered were regulatory genes, suggesting that phages may manipulate host genetic networks by tapping into their control elements. Our findings also suggest a mechanism by which phages can overcome the defensive strategy of dormancy, which may be involved in coevolutionary dynamics of spore-forming bacteria.
形成孢子的细菌在哺乳动物肠道中很普遍,对宿主的健康和营养有影响。休眠孢子的产生被认为在这些细菌的定植、持续存在和传播中起着重要作用。孢子形成还改变了微生物之间的相互作用,例如噬菌体的感染。最近的研究表明,噬菌体可能通过在感染过程中表达噬菌体携带的孢子形成基因来对抗休眠介导的防御,这可以改变活跃和不活跃状态之间的转换。通过挖掘基因组和肠道衍生的宏基因组,我们鉴定了优先由感染形成孢子的细菌的噬菌体携带的孢子形成基因。这些基因包括参与染色体分配、DNA 损伤修复和细胞壁相关功能的基因。此外,噬菌体还包含与孢子形成特异性转录因子的同源物,特别是孢子形成的主要调节因子,这可以使噬菌体能够控制负责孢子发育的复杂遗传网络。我们的研究结果表明,噬菌体可能影响细菌孢子的形成,这对人类肠道微生物组的健康以及其他环境中的细菌群落都有影响。噬菌体获取细菌基因并利用它们改变宿主代谢,以增强噬菌体的适应性。迄今为止,大多数辅助基因替代或调节宿主用于营养或能量产生的酶。然而,噬菌体的适应性受到宿主生理学各个方面的影响,包括降低细胞代谢活性的决策。在这里,我们专注于内孢子形成,这是一种在 中发现的复杂而古老的休眠形式,涉及数百个基因。通过将同源搜索与宿主分类相结合,我们鉴定了 31 种噬菌体携带的孢子形成基因的同源物,这些同源物主要局限于感染形成孢子的细菌的噬菌体。回收的同源物中有近三分之一是调节基因,这表明噬菌体可能通过利用其调控元件来操纵宿主遗传网络。我们的研究结果还提出了一种噬菌体可以克服休眠防御策略的机制,这可能与形成孢子的细菌的共同进化动态有关。
