Area of Biochemistry and Molecular Biology, OneHealth-UR Research Group, University of La Rioja, Logroño, 26006, Spain.
Spanish Wildlife Research Institute IREC (CSIC-UCLM-JCCM), SaBio (Health and Biotechnology) Research Group, Ciudad Real, Spain.
Eur J Clin Microbiol Infect Dis. 2023 May;42(5):569-581. doi: 10.1007/s10096-023-04579-9. Epub 2023 Mar 9.
This study determined the carriage rates and antimicrobial resistance (AMR) genes of enterococci from nasotracheal samples of three healthy animal species and in-contact humans. Nasal samples were collected from 27 dog-owning households (34 dogs, 41 humans) and 4 pig-farms (40 pigs, 10 pig-farmers), and they were processed for enterococci recovery (MALDI-TOF-MS identification). Also, a collection of 144 enterococci previously recovered of tracheal/nasal samples from 87 white stork nestlings were characterized. The AMR phenotypes were determined in all enterococci and AMR genes were studied by PCR/sequencing. MultiLocus-Sequence-Typing was performed for selected isolates. About 72.5% and 60% of the pigs and pig-farmers, and 29.4% and 4.9%, of healthy dogs and owners were enterococci nasal carriers, respectively. In storks, 43.5% of tracheal and 69.2% of nasal samples had enterococci carriages. Enterococci carrying multidrug-resistance phenotype was identified in 72.5%/40.0%/50.0%/23.5%/1.1% of pigs/pig-farmers/dogs/dogs' owners/storks, respectively. Of special relevance was the detection of linezolid-resistant enterococci (LRE) in (a) 33.3% of pigs (E. faecalis-carrying optrA and/or cfrD of ST59, ST330 or ST474 lineages; E. casseliflavus-carrying optrA and cfrD); (b) 10% of pig farmers (E. faecalis-ST330-carrying optrA); (c) 2.9% of dogs (E. faecalis-ST585-carrying optrA); and (d) 1.7% of storks (E. faecium-ST1736-carrying poxtA). The fexA gene was found in all optrA-positive E. faecalis and E. casseliflavus isolates, while fexB was detected in the poxtA-positive E. faecium isolate. The enterococci diversity and AMR rates from the four hosts reflect differences in antimicrobial selection pressure. The detection of LRE carrying acquired and transferable genes in all the hosts emphasizes the need to monitor LRE using a One-Health approach.
本研究旨在确定三种健康动物物种和接触人群的鼻拭子中肠球菌的携带率和抗生素耐药性(AMR)基因。从 27 个养狗家庭(34 只狗,41 人)和 4 个养猪场(40 只猪,10 个养猪户)中采集了鼻腔样本,并对肠球菌进行了回收(MALDI-TOF-MS 鉴定)。此外,还对先前从 87 只白鹳雏鸟的气管/鼻腔样本中回收的 144 株肠球菌进行了特征描述。对所有肠球菌进行了 AMR 表型检测,并通过 PCR/测序研究了 AMR 基因。对选定的分离株进行了多位点序列分型。健康犬及其主人的鼻拭子中肠球菌的携带率分别为 29.4%和 4.9%,而猪和养猪户的携带率分别为 60%和 72.5%。在鹳鸟中,43.5%的气管样本和 69.2%的鼻腔样本携带肠球菌。分别在 72.5%/40.0%/50.0%/23.5%/1.1%的猪/养猪户/狗/狗的主人/鹳中鉴定出具有多药耐药表型的肠球菌。特别值得注意的是,在(a)33.3%的猪(携带 optrA 和/或 cfrD 的屎肠球菌,ST59、ST330 或 ST474 谱系;携带 optrA 和 cfrD 的屎肠球菌)中,(b)10%的养猪户(携带 optrA 的屎肠球菌 ST330),(c)2.9%的狗(携带 optrA 的屎肠球菌 ST585)和(d)1.7%的鹳鸟(携带 poxtA 的屎肠球菌)中检测到了利奈唑胺耐药肠球菌(LRE)。所有 optrA 阳性屎肠球菌和屎肠球菌分离株均携带 fexA 基因,而 poxtA 阳性屎肠球菌分离株则携带 fexB 基因。来自四个宿主的肠球菌多样性和 AMR 率反映了抗菌药物选择压力的差异。在所有宿主中均检测到携带获得性和可转移基因的 LRE,这强调了需要采用一种“同一健康”的方法来监测 LRE。
