The plasmid-borne hipBA operon of Klebsiella michiganensis encodes a potent plasmid stabilization system
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Aims
Klebsiella michiganensis is a medically-important bacterium that has been subject to relatively little attention in the literature. Interrogation of sequence data from K. michiganensis strains in our collection has revealed the presence of multiple large plasmids encoding type II toxin-antitoxin (TA) systems. Such TA systems are responsible for mediating a range of phenotypes including plasmid stability (“addiction”) and antibiotic persistence. In this work, we characterize the hipBA TA locus found within the Klebsiella oxytoca species complex (KoSC).
Methods and Results
The HipBA TA system is encoded on a plasmid carried by K. michiganensis PS_Koxy4, isolated from an infection outbreak. Employing viability and plasmid stability assays, we demonstrate that PS_Koxy4 HipA is a potent antibacterial toxin and that HipBA is a functional TA module contributing substantially to plasmid maintenance. Further, we provide in silico data comparing HipBA modules across the entire KoSC.
Conclusions
We provide the first evidence of the role of a plasmid-encoded HipBA system in stability of mobile genetic elements and analyze the presence of HipBA across the KoSC. These results expand our knowledge of both a common enterobacterial TA system and a highly medically-relevant group of bacteria.
Impact Statement
The HipBA TA system is typically encoded on bacterial chromosomes where it contributes to antimicrobial tolerance by interfering with translation during cellular stress. Here, we show that plasmid-encoded HipBA from a disease isolate of Klebsiella michiganensis is responsible for highly effective plasmid addiction; the first such evidence of a HipBA module contributing to plasmid stability. This has important implications for enteric pathogen evolution and horizontal gene transfer in the era of multidrug resistance.
