噬菌体-抗生素协同作用:细胞丝状是噬菌体捕食成功的关键驱动因素。

IF 6.7 1区 医学 Q1 Immunology and Microbiology
PLoS Pathogens Pub Date : 2023-09-13 eCollection Date: 2023-09-01 DOI:10.1371/journal.ppat.1011602
Julián Bulssico, Irina PapukashvilI, Leon Espinosa, Sylvain Gandon, Mireille Ansaldi
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引用次数: 1

摘要

噬菌体是对抗抗生素耐药性细菌的有前途的工具,就目前而言,噬菌体治疗基本上是与抗生素联合进行的。有趣的是,包括噬菌体和多种抗生素在内的联合治疗会导致细菌杀伤增加,这一现象被称为噬菌体-抗生素协同作用(PAS),表明抗生素诱导的细菌生理学变化改变了噬菌体繁殖的动力学。使用单噬菌体和单细胞技术,在用头孢他啶、头孢氨苄或环丙沙星这三种诱导成丝的抗生素处理的大肠杆菌培养物中研究了噬菌体HK620裂解周期的每一步。在存在亚致死剂量的抗生素的情况下,SOS反应激活后会触发多种应激耐受和DNA修复途径。最显著的作用之一是抑制细菌分裂。结果,相当一部分细胞形成停止分裂但突变率更高的细丝。荧光显微镜和流式细胞术技术表明,抗生素诱导的细丝由于其扩大的表面积而成为噬菌体的容易靶点。与常规大小的细菌相比,丝状细胞更容易发生吸附、感染和裂解。此外,细胞分裂受损导致的细菌数量减少可能是PAS过程中细菌清除速度加快的原因。我们开发了一个数学模型来捕捉亚致死剂量的抗生素和暴露于噬菌体之间的相互作用。该模型表明,亚致死剂量的抗生素诱导成丝可以放大噬菌体的复制,从而产生PAS。我们还使用这个模型来研究PAS对抗生素耐药性出现的影响。由于噬菌体对感染的易感性增加,相当大比例的超诱变丝状细菌被噬菌体有效杀死。结果,即使添加非常少量的噬菌体,也会大大降低整个细菌种群的诱变率。我们使用细菌DNA修复的报告子通过实验证实了这一预测。我们的工作强调了亚致死剂量的抗生素与噬菌体相结合的多种益处。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Phage-antibiotic synergy: Cell filamentation is a key driver of successful phage predation.

Phage-antibiotic synergy: Cell filamentation is a key driver of successful phage predation.

Phage-antibiotic synergy: Cell filamentation is a key driver of successful phage predation.

Phage-antibiotic synergy: Cell filamentation is a key driver of successful phage predation.

Phages are promising tools to fight antibiotic-resistant bacteria, and as for now, phage therapy is essentially performed in combination with antibiotics. Interestingly, combined treatments including phages and a wide range of antibiotics lead to an increased bacterial killing, a phenomenon called phage-antibiotic synergy (PAS), suggesting that antibiotic-induced changes in bacterial physiology alter the dynamics of phage propagation. Using single-phage and single-cell techniques, each step of the lytic cycle of phage HK620 was studied in E. coli cultures treated with either ceftazidime, cephalexin or ciprofloxacin, three filamentation-inducing antibiotics. In the presence of sublethal doses of antibiotics, multiple stress tolerance and DNA repair pathways are triggered following activation of the SOS response. One of the most notable effects is the inhibition of bacterial division. As a result, a significant fraction of cells forms filaments that stop dividing but have higher rates of mutagenesis. Antibiotic-induced filaments become easy targets for phages due to their enlarged surface areas, as demonstrated by fluorescence microscopy and flow cytometry techniques. Adsorption, infection and lysis occur more often in filamentous cells compared to regular-sized bacteria. In addition, the reduction in bacterial numbers caused by impaired cell division may account for the faster elimination of bacteria during PAS. We developed a mathematical model to capture the interaction between sublethal doses of antibiotics and exposition to phages. This model shows that the induction of filamentation by sublethal doses of antibiotics can amplify the replication of phages and therefore yield PAS. We also use this model to study the consequences of PAS on the emergence of antibiotic resistance. A significant percentage of hyper-mutagenic filamentous bacteria are effectively killed by phages due to their increased susceptibility to infection. As a result, the addition of even a very low number of bacteriophages produced a strong reduction of the mutagenesis rate of the entire bacterial population. We confirm this prediction experimentally using reporters for bacterial DNA repair. Our work highlights the multiple benefits associated with the combination of sublethal doses of antibiotics with bacteriophages.

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来源期刊
PLoS Pathogens
PLoS Pathogens 生物-病毒学
CiteScore
11.40
自引率
3.00%
发文量
598
审稿时长
2 months
期刊介绍: Bacteria, fungi, parasites, prions and viruses cause a plethora of diseases that have important medical, agricultural, and economic consequences. Moreover, the study of microbes continues to provide novel insights into such fundamental processes as the molecular basis of cellular and organismal function.
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