肺炎克雷伯氏菌中 SHV β-内酰胺酶的多样性、功能分类和基因分型。

IF 4 2区 生物学 Q1 GENETICS & HEREDITY
Kara K Tsang, Margaret M C Lam, Ryan R Wick, Kelly L Wyres, Michael Bachman, Stephen Baker, Katherine Barry, Sylvain Brisse, Susana Campino, Alexandra Chiaverini, Daniela Maria Cirillo, Taane Clark, Jukka Corander, Marta Corbella, Alessandra Cornacchia, Aline Cuénod, Nicola D'Alterio, Federico Di Marco, Pilar Donado-Godoy, Adrian Egli, Refath Farzana, Edward J Feil, Aasmund Fostervold, Claire L Gorrie, Brekhna Hassan, Marit Andrea Klokkhammer Hetland, Le Nguyen Minh Hoa, Le Thi Hoi, Benjamin Howden, Odion O Ikhimiukor, Adam W J Jenney, Håkon Kaspersen, Fahad Khokhar, Thongpan Leangapichart, Małgorzata Ligowska-Marzęta, Iren Høyland Löhr, Scott W Long, Amy J Mathers, Andrew G McArthur, Geetha Nagaraj, Anderson O Oaikhena, Iruka N Okeke, João Perdigão, Hardik Parikh, My H Pham, Francesco Pomilio, Niclas Raffelsberger, Andriniaina Rakotondrasoa, K L Ravi Kumar, Leah W Roberts, Carla Rodrigues, Ørjan Samuelsen, Kirsty Sands, Davide Sassera, Helena Seth-Smith, Varun Shamanna, Norelle L Sherry, Sonia Sia, Anton Spadar, Nicole Stoesser, Marianne Sunde, Arnfinn Sundsfjord, Pham Ngoc Thach, Nicholas R Thomson, Harry A Thorpe, M Estée Torok, Van Dinh Trang, Nguyen Vu Trung, Jay Vornhagen, Timothy Walsh, Ben Warne, Hayley Wilson, Gerard D Wright, Kathryn E Holt, KlebNET-Gsp Amr Genotype-Phenotype Group
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引用次数: 0

摘要

解释肺炎克雷伯菌基因组中 bla SHV 等位基因的表型非常复杂。虽然所有菌株都会携带一个染色体拷贝,赋予其对氨苄西林的耐药性,但它们也可能携带染色体 bla SHV 等位基因的突变或质粒携带的额外 bla SHV 等位基因,这些等位基因具有扩谱β-内酰胺酶(ESBL)活性和/或β-内酰胺酶抑制剂(BLI)耐药活性。此外,单个突变/a 变化的作用尚未完全记录或了解。这导致文献和抗菌药耐药性(AMR)基因数据库(如美国国家生物技术信息中心(NCBI)参考基因目录和β-内酰胺酶数据库(BLDB))中对单个巯基可变(SHV)蛋白变体的具体功能混淆不清。因此,从肺炎克雷伯菌基因组数据中鉴定产 ESBL 菌株非常复杂。在此,我们回顾了与特定 aa 置换相关的 SHV 酶功能扩展的实验证据。然后,我们根据这些突变的存在将 SHV 等位基因系统地归入功能类别(WT、ESBL 和 BLI 耐药性)。与目前在 NCBI 的参考基因目录和/或 BLDB 中的分类相比,我们对 37 个 SHV 等位基因进行了重新分类(21 个等位基因归入 WT 类,12 个等位基因归入 ESBL 类,4 个等位基因归入 BLI 耐药类)。系统发育和比较基因组分析表明:(i) SHV-1(由 bla SHV-1 编码)是染色体上的祖先变体;(ii) 耐 ESBL 变种和耐 BLI 变种通过平行置换突变多次进化;(iii) ESBL 变种大多迁移到质粒上;(iv) 耐 BLI 变种大多来自染色体 bla SHV 的突变。我们利用 KlebNET-GSP AMR 基因型-表型组中匹配的基因组-表型数据,确定了 3999 个携带一个或多个 bla SHV 等位基因但没有其他获得性 β-内酰胺酶的肺炎克雷伯菌分离株,以评估 bla SHV 的基因型-表型关系。这些分离物包括 2001 年至 2021 年期间从 24 个国家采集的人类、动物和环境分离物。我们的分析结果表明,Ambler 位点 238 和 179 的突变具有 ESBL 活性,而大多数欧米伽环置换不具有 ESBL 活性。我们的数据还为 67 个蛋白质变体的 WT 分配提供了支持,其中包括 8 个在公共数据库中被注明为 ESBL 的变体。这 8 个变体被重新归类为 WT,因为它们缺乏 ESBL 相关突变,而我们的表型数据支持对第三代头孢菌素(SHV-27、SHV-38、SHV-40、SHV-41、SHV-42、SHV-65、SHV-164 和 SHV-187)的敏感性。本文概述的方法和结果已在 Kleborate v2.4.1(肺炎双球菌基因分型软件工具)中实施,根据致病突变对已知和新型 bla SHV 等位基因进行分类。Kleborate v2.4.1已经更新,纳入了来自KlebNET-GSP数据集的10个新型蛋白质变体以及截至2023年11月公共数据库中的所有等位基因。这项研究表明,共享 AMR 表型和基因组数据有助于更好地了解抗药性机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Diversity, functional classification and genotyping of SHV β-lactamases in Klebsiella pneumoniae.

Interpreting the phenotypes of bla SHV alleles in Klebsiella pneumoniae genomes is complex. Whilst all strains are expected to carry a chromosomal copy conferring resistance to ampicillin, they may also carry mutations in chromosomal bla SHV alleles or additional plasmid-borne bla SHV alleles that have extended-spectrum β-lactamase (ESBL) activity and/or β-lactamase inhibitor (BLI) resistance activity. In addition, the role of individual mutations/a changes is not completely documented or understood. This has led to confusion in the literature and in antimicrobial resistance (AMR) gene databases [e.g. the National Center for Biotechnology Information (NCBI) Reference Gene Catalog and the β-lactamase database (BLDB)] over the specific functionality of individual sulfhydryl variable (SHV) protein variants. Therefore, the identification of ESBL-producing strains from K. pneumoniae genome data is complicated. Here, we reviewed the experimental evidence for the expansion of SHV enzyme function associated with specific aa substitutions. We then systematically assigned SHV alleles to functional classes (WT, ESBL and BLI resistant) based on the presence of these mutations. This resulted in the re-classification of 37 SHV alleles compared with the current assignments in the NCBI's Reference Gene Catalog and/or BLDB (21 to WT, 12 to ESBL and 4 to BLI resistant). Phylogenetic and comparative genomic analyses support that (i) SHV-1 (encoded by bla SHV-1) is the ancestral chromosomal variant, (ii) ESBL- and BLI-resistant variants have evolved multiple times through parallel substitution mutations, (iii) ESBL variants are mostly mobilized to plasmids and (iv) BLI-resistant variants mostly result from mutations in chromosomal bla SHV. We used matched genome-phenotype data from the KlebNET-GSP AMR Genotype-Phenotype Group to identify 3999 K. pneumoniae isolates carrying one or more bla SHV alleles but no other acquired β-lactamases to assess genotype-phenotype relationships for bla SHV. This collection includes human, animal and environmental isolates collected between 2001 and 2021 from 24 countries. Our analysis supports that mutations at Ambler sites 238 and 179 confer ESBL activity, whilst most omega-loop substitutions do not. Our data also provide support for the WT assignment of 67 protein variants, including 8 that were noted in public databases as ESBL. These eight variants were reclassified as WT because they lack ESBL-associated mutations, and our phenotype data support susceptibility to third-generation cephalosporins (SHV-27, SHV-38, SHV-40, SHV-41, SHV-42, SHV-65, SHV-164 and SHV-187). The approach and results outlined here have been implemented in Kleborate v2.4.1 (a software tool for genotyping K. pneumoniae), whereby known and novel bla SHV alleles are classified based on causative mutations. Kleborate v2.4.1 was updated to include ten novel protein variants from the KlebNET-GSP dataset and all alleles in public databases as of November 2023. This study demonstrates the power of sharing AMR phenotypes alongside genome data to improve the understanding of resistance mechanisms.

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来源期刊
Microbial Genomics
Microbial Genomics Medicine-Epidemiology
CiteScore
6.60
自引率
2.60%
发文量
153
审稿时长
12 weeks
期刊介绍: Microbial Genomics (MGen) is a fully open access, mandatory open data and peer-reviewed journal publishing high-profile original research on archaea, bacteria, microbial eukaryotes and viruses.
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