SOS反应和DNA修复系统对诺氟沙星诱导的大肠杆菌突变的贡献

IF 5.8 2区 生物学 Q1 MARINE & FRESHWATER BIOLOGY Marine Life Science & Technology Pub Date : 2023-09-21 DOI:10.1007/s42995-023-00185-y
Tongtong Lin, Jiao Pan, Colin Gregory, Yaohai Wang, Clayton Tincher, Caitlyn Rivera, Michael Lynch, Hongan Long, Yu Zhang
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引用次数: 1

摘要

摘要耐药细菌严重威胁着人类健康。除了内源性因素引起的自发突变外,耐药性也可能源于某些抗生素(如氟喹诺酮类药物)引起的突变。这类抗生素通过引入来自SOS反应途径的复制错误或降低DNA修复系统的效率来增加全基因组突变率。然而,这些分子机制的相对贡献仍然不清楚,阻碍了对耐药病原体产生的理解。在这里,利用野生型和SOS不可诱导型大肠杆菌菌株的新积累突变,以及缺乏错配修复(MMR)和氧化损伤修复途径的菌株,我们发现SOS反应是突变升高的主要诱变因素,在亚致死水平的诺氟沙星(0 ~ 50 ng/mL)处理下,约30-50%的总碱基对取代(BPS)突变率升高负责。我们使用线性模型进一步估计了这些机制对大肠杆菌中其他突变特征(即,翻转,结构变异和突变谱)的影响的重要性。SOS反应在bps的三个突变特征(突变率、翻转、结构变异)中都起着积极的作用,并影响突变谱。无论是否存在抗生素,修复系统都显著降低了BPS突变率和翻转率,同时显著增加了大肠杆菌的结构变化率。我们的结果定量地解开了SOS反应和DNA修复系统在抗生素诱导诱变中的贡献。
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Contribution of the SOS response and the DNA repair systems to norfloxacin induced mutations in E. coli
Abstract Antibiotic-resistant bacteria severely threaten human health. Besides spontaneous mutations generated by endogenous factors, the resistance might also originate from mutations induced by certain antibiotics, such as the fluoroquinolones. Such antibiotics increase the genome-wide mutation rate by introducing replication errors from the SOS response pathway or decreasing the efficiency of the DNA repair systems. However, the relative contributions of these molecular mechanisms remain unclear, hindering understanding of the generation of resistant pathogens. Here, using newly-accumulated mutations of wild-type and SOS-uninducible Escherichia coli strains, as well as those of the strains deficient for the mismatch repair (MMR) and the oxidative damage repair pathways, we find that the SOS response is the major mutagenesis contributor in mutation elevation, responsible for ~ 30–50% of the total base-pair substitution (BPS) mutation-rate elevation upon treatment with sublethal levels of norfloxacin (0 ~ 50 ng/mL). We further estimate the significance of the effects on other mutational features of these mechanisms (i.e., transversions, structural variations, and mutation spectrum) in E. coli using linear models. The SOS response plays a positive role in all three mutational features (mutation rates of BPSs, transversions, structural variations) and affects the mutational spectrum. The repair systems significantly reduce the BPS mutation rate and the transversion rate, regardless of whether antibiotics are present, while significantly increasing the structural variation rate in E. coli . Our results quantitatively disentangle the contributions of the SOS response and DNA repair systems in antibiotic-induced mutagenesis.
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来源期刊
Marine Life Science & Technology
Marine Life Science & Technology MARINE & FRESHWATER BIOLOGY-
CiteScore
9.60
自引率
10.50%
发文量
58
期刊介绍: Marine Life Science & Technology (MLST), established in 2019, is dedicated to publishing original research papers that unveil new discoveries and theories spanning a wide spectrum of life sciences and technologies. This includes fundamental biology, fisheries science and technology, medicinal bioresources, food science, biotechnology, ecology, and environmental biology, with a particular focus on marine habitats. The journal is committed to nurturing synergistic interactions among these diverse disciplines, striving to advance multidisciplinary approaches within the scientific field. It caters to a readership comprising biological scientists, aquaculture researchers, marine technologists, biological oceanographers, and ecologists.
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