Antibiotic resistant bacteria survive treatment by doubling while shrinking.

IF 5.1 1区 生物学 Q1 MICROBIOLOGY mBio Pub Date : 2024-11-20 DOI:10.1128/mbio.02375-24
Adrian Campey, Urszula Łapińska, Remy Chait, Krasimira Tsaneva-Atanasova, Stefano Pagliara
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Abstract

Many antibiotics that are used in healthcare, farming, and aquaculture end up in environments with different spatial structures that might promote heterogeneity in the emergence of antibiotic resistance. However, the experimental evolution of microbes at sub-inhibitory concentrations of antibiotics has been mainly carried out at the population level which does not allow capturing single-cell responses to antibiotics. Here, we investigate and compare the emergence of resistance to ciprofloxacin in Escherichia coli in well-mixed and structured environments using experimental evolution, genomics, and microfluidics-based time-lapse microscopy. We discover that resistance to ciprofloxacin and cross-resistance to other antibiotics is stronger in the well-mixed environment due to the emergence of target mutations, whereas efflux regulator mutations emerge in the structured environment. The latter mutants also harbor sub-populations of persisters that survive high concentrations of ciprofloxacin that inhibit bacterial growth at the population level. In contrast, genetically resistant bacteria that display target mutations also survive high concentrations of ciprofloxacin that inhibit their growth via population-level antibiotic tolerance. These resistant and tolerant bacteria keep doubling while shrinking in size in the presence of ciprofloxacin and regain their original size after antibiotic removal, which constitutes a newly discovered phenotypic response. This new knowledge sheds light on the diversity of strategies employed by bacteria to survive antibiotics and poses a stepping stone for understanding the link between mutations at the population level and phenotypic single-cell responses.

Importance: The evolution of antimicrobial resistance poses a pressing challenge to global health with an estimated 5 million deaths associated with antimicrobial resistance every year globally. Here, we investigate the diversity of strategies employed by bacteria to survive antibiotics. We discovered that bacteria evolve genetic resistance to antibiotics while simultaneously displaying tolerance to very high doses of antibiotics by doubling while shrinking in size.

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抗生素耐药细菌在缩小的同时还能存活一倍。
许多用于医疗保健、种植业和水产养殖业的抗生素最终会进入具有不同空间结构的环境中,这可能会促进抗生素耐药性的异质性出现。然而,微生物在亚抑制浓度抗生素作用下的实验进化主要是在群体水平上进行的,无法捕捉单细胞对抗生素的反应。在这里,我们利用实验进化、基因组学和基于微流控技术的延时显微镜,研究并比较了大肠埃希菌在混合良好的环境和结构化环境中对环丙沙星产生耐药性的情况。我们发现,在混合良好的环境中,由于目标突变的出现,对环丙沙星的耐药性和对其他抗生素的交叉耐药性更强,而在结构化环境中,则出现了外排调节剂突变。后一种突变体还蕴藏着亚群持久体,它们能在高浓度环丙沙星的作用下存活下来,从而在群体水平上抑制细菌的生长。与此相反,出现目标突变的耐药细菌也能在高浓度环丙沙星的环境中存活下来,而高浓度环丙沙星会在群体水平上抑制细菌的生长。在环丙沙星存在的情况下,这些具有抗药性和耐受性的细菌在不断加倍的同时体积也在缩小,并在去除抗生素后恢复到原来的大小,这是一种新发现的表型反应。这一新知识揭示了细菌在抗生素环境中生存策略的多样性,并为理解群体水平的突变与单细胞表型反应之间的联系提供了一块基石:抗菌药耐药性的演变对全球健康构成了紧迫的挑战,据估计,全球每年有 500 万人死于抗菌药耐药性。在这里,我们研究了细菌为在抗生素中存活而采用的策略的多样性。我们发现,细菌在对抗生素产生遗传抗药性的同时,还能通过将体积缩小一倍来显示对高剂量抗生素的耐受性。
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来源期刊
mBio
mBio MICROBIOLOGY-
CiteScore
10.50
自引率
3.10%
发文量
762
审稿时长
1 months
期刊介绍: mBio® is ASM''s first broad-scope, online-only, open access journal. mBio offers streamlined review and publication of the best research in microbiology and allied fields.
期刊最新文献
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