大肠埃希菌 AcrB 的缺失、失活或抑制不会增加其他支持发现 AcrB 抑制剂作为抗生素佐剂的外排泵基因的表达。

Absence, loss-of-function, or inhibition of Escherichia coli AcrB does not increase expression of other efflux pump genes supporting the discovery of AcrB inhibitors as antibiotic adjuvants.

机构信息

Institute of Microbiology and Infection, College of Medical and Dental Sciences, University of Birmingham, Birmingham, UK.

出版信息

J Antimicrob Chemother. 2022 Feb 23;77(3):633-640. doi: 10.1093/jac/dkab452.

DOI:10.1093/jac/dkab452

PMID:34897478

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8865010/

Abstract

OBJECTIVES

To determine whether expression of efflux pumps and antibiotic susceptibility are altered in Escherichia coli in response to efflux inhibition.

METHODS

The promoter regions of nine efflux pump genes (acrAB, acrD, acrEF, emrAB, macAB, cusCFBA, mdtK, mdtABC, mdfA) were fused to gfp in pMW82 and fluorescence from each reporter construct was used as a measure of the transcriptional response to conditions in which AcrB was inhibited, absent or made non-functional. Expression was also determined by RT-qPCR. Drug susceptibility of efflux pump mutants with missense mutations known or predicted to cause loss of function of the encoded efflux pump was investigated.

RESULTS

Data from the GFP reporter constructs revealed that no increased expression of the tested efflux pump genes was observed when AcrB was absent, made non-functional, or inhibited by an efflux pump inhibitor/competitive substrate, such as PAβN or chlorpromazine. This was confirmed by RT-qPCR for PAβN and chlorpromazine; however, a small but significant increase in macB gene expression was seen when acrB is deleted. Efflux inhibitors only synergized with antibiotics in the presence of a functional AcrB. When AcrB was absent or non-functional, there was no impact on MICs when other efflux pumps were also made non-functional.

CONCLUSIONS

Absence, loss-of-function, or inhibition of E. coli AcrB did not significantly increase expression of other efflux pump genes, which suggests there is no compensatory mechanism to overcome efflux inhibition and supports the discovery of inhibitors of AcrB as antibiotic adjuvants.

摘要

目的

确定大肠杆菌中流出泵的表达和抗生素敏感性是否因流出泵抑制而改变。

方法

将九个流出泵基因（acrAB、acrD、acrEF、emrAB、macAB、cusCFBA、mdtk、mdtABC、mdfA）的启动子区域融合到 pMW82 中的 gfp 中，并用每个报告基因构建体的荧光作为衡量 acrB 被抑制、不存在或失去功能时转录反应的指标。还通过 RT-qPCR 确定了表达。研究了具有已知或预测导致编码流出泵功能丧失的错义突变的流出泵突变体的药物敏感性。

结果

从 GFP 报告基因构建体获得的数据表明，当 AcrB 不存在、失去功能或被流出泵抑制剂/竞争性底物（如 PAβN 或氯丙嗪）抑制时，未观察到测试的流出泵基因表达增加。PAβN 和氯丙嗪的 RT-qPCR 结果证实了这一点；然而，当 acrB 缺失时，macB 基因的表达略有但显著增加。只有在 AcrB 功能正常的情况下，流出抑制剂才能与抗生素协同作用。当 AcrB 不存在或失去功能时，当其他流出泵也失去功能时，MIC 没有受到影响。

结论

大肠杆菌 AcrB 的缺失、功能丧失或抑制并未显著增加其他流出泵基因的表达，这表明不存在克服流出抑制的补偿机制，支持发现 AcrB 的抑制剂作为抗生素佐剂。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8c36/8865010/b71065c255d3/dkab452f1.jpg

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大肠埃希菌 AcrB 的缺失、失活或抑制不会增加其他支持发现 AcrB 抑制剂作为抗生素佐剂的外排泵基因的表达。

Absence, loss-of-function, or inhibition of Escherichia coli AcrB does not increase expression of other efflux pump genes supporting the discovery of AcrB inhibitors as antibiotic adjuvants.

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