受体修饰和适应性之间的权衡推动宿主-噬菌体共同进化,导致噬菌体灭绝或共存

Lin Chen, Xue Zhao, Shelyn Wongso, Zhuohui Lin, Siyun Wang
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摘要

寄生虫-宿主共同进化会导致种群灭绝或共存,但驱动这些不同结果的因素仍然难以捉摸。在这项研究中,沙门氏菌菌株分别与溶菌噬菌体 SF1 共同进化 30 天,结果导致噬菌体灭绝或共存。我们对进化宿主细胞和噬菌体的表型和遗传动态进行了系统调查,以阐明进化机制。在整个共同进化过程中,宿主细胞表现出多种噬菌体抗性模式:对野生型噬菌体敏感、部分抗性和完全抗性。此外,噬菌体的抗性强度与噬菌体的吸附力呈稳健的线性关系,这表明表面修饰介导的噬菌体附着是进化细菌种群的主要抗性机制。此外,与导致共存的细菌相比,消除噬菌体的细菌分离物在产生抗性时表现出更高的突变率和更低的适应成本。噬菌体抗性基因分为两类:一类是关键突变,其特征是 rfaH 调控的 rfb 基因发生无义/帧移位突变,导致受体 O 抗原被移除;另一类是次要突变,涉及不那么关键的修饰,如流苏合成和 tRNA 修饰。次要突变的积累导致了部分和完全的抗性,这些抗性可以被进化的噬菌体克服,而关键突变则通过删除受体赋予了不可战胜的完全抗性。总之,较高的关键突变频率和较低的适合度成本保证了噬菌体的强抗性和最终的灭绝,而适合度成本、突变率和关键突变的不足则导致了共存。我们的发现揭示了共同进化过程中噬菌体抗性的不同种群动态和进化权衡,从而加深了我们对微生物相互作用的理解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Trade-offs between receptor modification and fitness drive host-bacteriophage co-evolution leading to phage extinction or co-existence
Parasite–host co-evolution results in population extinction or co-existence, yet the factors driving these distinct outcomes remain elusive. In this study, Salmonella strains were individually co-evolved with the lytic phage SF1 for 30 days, resulting in phage extinction or co-existence. We conducted a systematic investigation into the phenotypic and genetic dynamics of evolved host cells and phages to elucidate the evolutionary mechanisms. Throughout co-evolution, host cells displayed diverse phage resistance patterns: sensitivity, partial resistance, and complete resistance, to wild-type phage. Moreover, phage resistance strength showed a robust linear correlation with phage adsorption, suggesting that surface modification-mediated phage attachment predominates as the resistance mechanism in evolved bacterial populations. Additionally, bacterial isolates eliminating phages exhibited higher mutation rates and lower fitness costs in developing resistance compared to those leading to co-existence. Phage resistance genes were classified into two categories: key mutations, characterized by nonsense/frameshift mutations in rfaH-regulated rfb genes, leading to the removal of the receptor O-antigen; and secondary mutations, which involve less critical modifications, such as fimbrial synthesis and tRNA modification. The accumulation of secondary mutations resulted in partial and complete resistance, which could be overcome by evolved phages, whereas key mutations conferred undefeatable complete resistance by deleting receptors. In conclusion, higher key mutation frequencies with lower fitness costs promised strong resistance and eventual phage extinction, whereas deficiencies in fitness cost, mutation rate, and key mutation led to co-existence. Our findings reveal the distinct population dynamics and evolutionary trade-offs of phage resistance during co-evolution, thereby deepening our understanding of microbial interactions.
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