Skaare Dagfinn, Anthonisen Inger Lill, Zecic Nermin, Jenkins Andrew, Caugant Dominique A, Ranheim Trond Egil, Sundsfjord Arnfinn, Hegstad Kristin
Antimicrobial Resistance Research Group, Department of Microbiology, Vestfold Hospital Trust, Tønsberg, Norway.
Department of Infection Prevention and Control, Vestfold Hospital Trust, Tønsberg, Norway.
Front Microbiol. 2025 Jul 29;16:1601390. doi: 10.3389/fmicb.2025.1601390. eCollection 2025.
Cefotaxime-resistant (CRHI) are a global concern, but little is known about their molecular epidemiology. The goal of this study was to perform genomic profiling of 191 CRHI from Norway ( = 183) or Sweden ( = 8) (2006-2018) and assess clonal spread using core genome multilocus sequence typing (cgMLST)-based Life Identification Number (LIN) codes based on whole genome sequencing (Ion Torrent). Cefotaxime resistance was confirmed with broth microdilution minimal inhibitory concentration (MIC), interpreted with the European Committee on Antimicrobial Susceptibility Testing (EUCAST) breakpoints. 35.7% of isolates with cefotaxime gradient MIC of 0.25 mg/L were falsely resistant. All but two isolates (blood) were non-invasive, and all but two (serotype f) were non-typeable. Characterization included calling of resistance determinants, typing (penicillin-binding protein 3, PBP3), and classification of PBP3-mediated beta-lactam resistance (rPBP3), with assignment to rPBP3 stage and group. All isolates had rPBP3-defining substitutions, and 78.5% were stage 3 (L389F positive). Beta-lactam MICs correlated well with rPBP3 genotypes. Significant proportions of stage 3 isolates were cross-resistant to ceftriaxone (86.0%) and meropenem (meningitis breakpoints, 26.0%). The CRHI prevalence in Norway doubled during the study period and approached 1%. A shift from stage 2 to stage 3 rPBP3 in 2011-2012 led to emergence of CRHI with higher beta-lactam MICs and co-resistance to multiple non-beta-lactams, including extensively drug-resistant (XDR) strains. The shift was driven by transformation with two distinct variants of the transpeptidase region and multiclonal expansion. 66.0% of the isolates belonged to 27 clusters. Ten clusters or singletons belonged to international CRHI clones represented in the PubMLST database. The study provides new insight into CRHI evolution, resistance profiles, and clonal dynamics in a period when this phenotype went from exceptional to unusual in Europe. International CRHI clones are described for the first time, including eight high-risk clones associated with invasive disease, calling for enhanced genomic surveillance. LIN coding, supplemented with typing and rPBP3 staging, is well-suited for definition of CRHI clones. LIN9, defined by ≤ 10 allelic differences, offered the highest resolution level fully supported by maximum likelihood core genome phylogeny and is proposed as a global standard for genomic surveillance of .
耐头孢噻肟(CRHI)是一个全球关注的问题,但对其分子流行病学了解甚少。本研究的目的是对来自挪威(n = 183)或瑞典(n = 8)(2006 - 2018年)的191株CRHI进行基因组分析,并使用基于核心基因组多位点序列分型(cgMLST)的生命识别号(LIN)编码,基于全基因组测序(Ion Torrent)评估克隆传播情况。通过肉汤微量稀释法测定最低抑菌浓度(MIC)来确认头孢噻肟耐药性,并根据欧洲抗菌药物敏感性试验委员会(EUCAST)的断点进行解释。头孢噻肟梯度MIC为0.25 mg/L的分离株中有35.7%被错误判定为耐药。除两株(血液)分离株外,所有分离株均为非侵袭性,除两株(血清型f)外,所有分离株均无法分型。特征分析包括耐药决定簇的鉴定、分型(青霉素结合蛋白3,PBP3)以及PBP3介导的β-内酰胺耐药性(rPBP3)的分类,并确定rPBP3阶段和组别。所有分离株均有rPBP3定义性替换,78.5%为3期(L389F阳性)。β-内酰胺MIC与rPBP3基因型相关性良好。相当比例的3期分离株对头孢曲松(86.0%)和美罗培南(脑膜炎断点,26.0%)交叉耐药。在研究期间,挪威的CRHI患病率翻了一番,接近1%。2011 - 2012年从2期rPBP3向3期rPBP3的转变导致了具有更高β-内酰胺MIC以及对多种非β-内酰胺类药物包括广泛耐药(XDR)菌株产生共耐药性的CRHI的出现。这种转变由转肽酶区域的两个不同变体的转化和多克隆扩增驱动。66.0%的分离株属于27个簇。10个簇或单株属于PubMLST数据库中代表的国际CRHI克隆。该研究为欧洲这一表型从罕见变为常见这一时期内CRHI的进化、耐药谱和克隆动态提供了新的见解。首次描述了国际CRHI克隆,包括8个与侵袭性疾病相关的高风险克隆,呼吁加强基因组监测。LIN编码,辅以分型和rPBP3分期,非常适合定义CRHI克隆。由≤10个等位基因差异定义的LIN9提供了最高分辨率水平,得到最大似然核心基因组系统发育的充分支持,并被提议作为CRHI基因组监测的全球标准。
