Clinically Relevant Plasmid-Host Interactions Indicate that Transcriptional and Not Genomic Modifications Ameliorate Fitness Costs of Klebsiella pneumoniae Carbapenemase-Carrying Plasmids.

Michelle M C Buckner,Alan Mcnally,Howard T H Saw,Alasdair Ivens,Laura J V Piddock,Vito Ricci,Matthew E Wand,Mark A Webber,Rachael N Osagie,Neil Woodford

doi:10.1128/mbio.02303-17

Abstract

ABSTRACTThe rapid dissemination of antimicrobial resistance (AMR) around the globe is largely due to mobile genetic elements, such as plasmids. They confer resistance to critically important drugs, including extended-spectrum beta-lactams, carbapenems, and colistin. Large, complex resistance plasmids have evolved alongside their host bacteria. However, much of the research on plasmid-host evolution has focused on small, simple laboratory plasmids in laboratory-adapted bacterial hosts. These and other studies have documented mutations in both host and plasmid genes which occur after plasmid introduction to ameliorate fitness costs of plasmid carriage. We describe here the impact of two naturally occurring variants of a large AMR plasmid (pKpQIL) on a globally successful pathogen. In our study, after pKpQIL plasmid introduction, no changes in coding domain sequences were observed in their natural host, Klebsiella pneumoniae. However, significant changes in chromosomal and plasmid gene expression may have allowed the bacterium to adapt to the acquisition of the AMR plasmid. We hypothesize that this was sufficient to ameliorate the associated fitness costs of plasmid carriage, as pKpQIL plasmids were maintained without selection pressure. The dogma that removal of selection pressure (e.g., antimicrobial exposure) results in plasmid loss due to bacterial fitness costs is not true for all plasmid/host combinations. We also show that pKpQIL impacted the ability of K. pneumoniae to form a biofilm, an important aspect of virulence. This study used highly relevant models to study the interaction between AMR plasmids and pathogens and revealed striking differences from results of studies done on laboratory-adapted plasmids and strains.

Highlights

IMPORTANCE Antimicrobial resistance is a serious problem facing society
To determine the impact on the K. pneumoniae chromosome and plasmid, we investigated the impact of pKpQIL-UK and pKpQIL-D2 on pKpQIL-naïve K. pneumoniae strains using wholegenome sequencing (WGS) and RNA sequencing to determine the effect of plasmid carriage on global gene expression
The sequences obtained from sequence type 258 (ST258) and Ecl8 carrying pKpQIL-UK or pKpQIL-D2 were compared with their respective pKpQIL-free isoforms

Summary

Introduction

IMPORTANCE Antimicrobial resistance is a serious problem facing society. Many of the genes that confer resistance can be shared between bacteria through mobile genetic elements, such as plasmids. The plasmid most often associated with carbapenem resistance in ST258 isolates in Israel was named pKpQIL and was a conjugative 113,637-bp IncFII-like plasmid with blaTEM-1 and blaKPC-3 ␤-lactamase genes [10, 11]. A further variant, pKpQIL-D2, was isolated from K. pneumoniae, Escherichia coli, and Enterobacter species during a United Kingdom outbreak [33] Both pKpQIL-UK and pKpQIL-D2 have the blaKPC-2 gene located within the Tn4401a isoform [29, 33]. Despite the global success of plasmids like pKpQIL and the difficulties associated with eradicating KPC-producing organisms, in general terms, plasmid persistence and survival within a bacterial population are considered to represent a paradox [34,35,36]. Plasmids can impose a fitness defect with respect to the host bacterium but can

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