Multi-approach Methods to Predict Cryptic Carbapenem Resistance Mechanisms in Detected in Central Italy

Overview

Journal Front Microbiol

Specialty Microbiology

Date 2023 Sep 13

PMID 37700864

Authors

Alessandra Cornacchia

Anna Janowicz

Gabriella Centorotola

Maria Antonietta Saletti

Sofia Chiatamone Ranieri

Massimo Ancora

Paola Ripa

Cesare Camma

Francesco Pomilio

Alexandra Chiaverini

Affiliations

Soon will be listed here.

Abstract

The rapid emergence of carbapenem-resistant () strains in diverse environmental niches, even outside of the clinical setting, poses a challenge for the detection and the real-time monitoring of novel antimicrobial resistance trends using molecular and whole genome sequencing-based methods. The aim of our study was to understand cryptic resistance determinants responsible for the phenotypic carbapenem resistance observed in strains circulating in Italy by using a combined approach involving whole genome sequencing (WGS) and genome-wide association study (GWAS). In this study, we collected 303 strains from inside and outside clinical settings between 2018-2022 in the Abruzzo region of Italy. The antimicrobial resistance profile of all isolates was assessed using both phenotypic and bioinformatic methods. We identified 11 strains resistant to carbapenems, which did not carry any known genetic determinants explaining their phenotype. The GWAS results showed that incongruent carbapenem-resistant phenotype was associated specifically with strains with two capsular types, KL13 and KL116 including genes involved in the capsule synthesis, encoding proteins involved in the assembly of the capsule biosynthesis apparatus, capsule-specific sugar synthesis, processing and export, polysaccharide pyruvyl transferase, and lipopolysaccharide biosynthesis protein. These preliminary results confirmed the potential of GWAS in identifying genetic variants present in KL13 and KL116 that could be associated with carbapenem resistance traits in . The implementation of advanced methods, such as GWAS with increased antimicrobial resistance surveillance will potentially improve infection treatment and patient outcomes.

Citing Articles

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