ABSTRACT
Serratia marcescens is an opportunistic bacterial pathogen. It is notorious for its increasing antimicrobial resistance and its potential to cause outbreaks of colonization and infections, predominantly in neonatal intensive care units (NICUs). There, its spread requires rapid infection control response. To understand its spread, detailed molecular typing is key. We present a whole-genome multilocus sequence typing (wgMLST) method for S. marcescens Using a set of 299 publicly available whole-genome sequences (WGS), we developed an initial wgMLST system consisting of 9,377 gene loci. This included 1,455 loci occurring in all reference genomes and 7,922 accessory loci. This closed system was validated using three geographically diverse collections of S. marcescens consisting of 111 clinical isolates implicated in nosocomial dissemination events in three hospitals. The validation procedure showed a full match between epidemiological data and the wgMLST analyses. We set the cutoff value for epidemiological (non)relatedness at 20 different alleles, though for the majority of outbreak-clustered isolates, this difference was limited to 4 alleles. This shows that the wgMLST system for S. marcescens provides prospects for successful future monitoring for the epidemiological containment of this opportunistic pathogen.
Subject(s)
Genome, Bacterial , Multilocus Sequence Typing/methods , Serratia Infections/epidemiology , Serratia marcescens/classification , Whole Genome Sequencing , Adolescent , Adult , Alleles , DNA, Bacterial/genetics , Disease Outbreaks , Female , Genetic Loci , Germany/epidemiology , Humans , Infant , Infant, Newborn , Intensive Care Units, Neonatal , Intensive Care Units, Pediatric , Male , Microbial Sensitivity Tests , Netherlands/epidemiology , Serratia Infections/microbiologyABSTRACT
Acinetobacter seifertii is a recently described species that belongs to the Acinetobacter calcoaceticus-Acinetobacter baumannii complex. It has been recovered from clinical samples and is sometimes associated with antimicrobial resistance determinants. We present here the case of three A. seifertii clinical isolates which were initially identified as Acinetobacter sp. by phenotypic methods but no identification at the species level was achieved using semi-automated identification methods. The isolates were further analysed by whole genome sequencing and identified as A. seifertii. Due to the fact that A. seifertii has been isolated from serious infections such as respiratory tract and bloodstream infections, we emphasize the importance of correctly identifying isolates of the genus Acinetobacter at the species level to gain a deeper knowledge of their prevalence and clinical impact.
Subject(s)
Acinetobacter Infections/microbiology , Acinetobacter/genetics , Acinetobacter/isolation & purification , Acinetobacter/classification , Acinetobacter/drug effects , Acinetobacter Infections/blood , Acinetobacter Infections/epidemiology , Acinetobacter baumannii/genetics , Anti-Bacterial Agents/pharmacology , Bolivia/epidemiology , Catheter-Related Infections/microbiology , DNA Gyrase/genetics , DNA, Bacterial/genetics , Genome, Bacterial , High-Throughput Nucleotide Sequencing , Humans , Polymerase Chain Reaction , RNA, Ribosomal, 16S/genetics , Spectrometry, Mass, Matrix-Assisted Laser Desorption-IonizationABSTRACT
Objectives: To investigate the mechanisms of tigecycline resistance in isogenic Acinetobacter baumannii isolate pairs as well as 65 unique clinical A. baumannii isolates obtained during the MagicBullet clinical trial from Greece, Italy and Spain. Methods: A. baumannii isolates were subjected to WGS and the regulatory genes of resistance-nodulation-cell division (RND)-type efflux pumps were analysed. MICs were determined by agar dilution and the expression of RND-type efflux pumps was measured by semi-quantitative RT-PCR. Results: In isolate pairs, disruption of adeS or adeN by ISs increased adeB or adeJ expression and conferred increased resistance to at least three antimicrobial classes, respectively. The insertion of ISAba1 in adeN was observed in more than 30% of tested isolates and was the most prevalent IS. Furthermore, the insertion of ISAba125 and ISAba27 into adeN was observed for the first time in A. baumannii isolates. Besides ISs, several different mutations were observed in adeN (e.g. deletions and premature stop codons), all of which led to increased tigecycline MICs. Moreover, several amino acid substitutions were detected in AdeRS, AdeN and AdeL. Of note, the substitutions D21V, G25S and D26N in AdeR were found in multiple sequences and suggest a mutational hotspot. Conclusions: This study provides an insight into the different mechanisms associated with tigecycline resistance using a genomic approach and points out the importance of considering adeRS and adeN as markers for tigecycline-resistant A. baumannii isolates.