Abstract
Carbapenemase-producing Klebsiella pneumoniae (KPC) has emerged and spread throughout the world. A retrospective analysis was performed on carbapenem-resistant K. pneumoniae isolated at our teaching hospital during the period 2009–2010, when the initial outbreak occurred. To determine the mechanism(s) that underlies the increased infectivity exhibited by KPC, Multilocus Sequence Typing (MLST) was conducted. A series of plasmids was also extracted, sequenced and analyzed. Concurrently, the complete sequences of blaKPC−2-harboring plasmids deposited in GenBank were summarized and aligned. The blaKPC−2 and KlcAHS genes in the carbapenem-resistant K. pneumoniae isolates were examined. E. coli strains, carrying different Type I Restriction and Modification (RM) systems, were selected to study the interaction between RM systems, anti-RM systems and horizontal gene transfer (HGT). The ST11 clone predominated among 102 carbapenem-resistant K. pneumoniae isolates, all harbored the blaKPC−2 gene; 98% contained the KlcAHS gene. KlcAHS was one of the core genes in the backbone region of most blaKPC−2 carrying plasmids. Type I RM systems in the host bacteria reduced the rate of pHS10842 plasmid transformation by 30- to 40-fold. Presence of the anti-restriction protein, KlcAHS, on the other hand, increased transformation efficiency by 3- to 6-fold. These results indicate that RM systems can significantly restrict HGT. In contrast, KlcAHS can disrupt the RM systems and promote HGT by transformation. These findings suggest that the anti-restriction protein, KlcAHS, represents a novel mechanism that facilitates the increased transfer of blaKPC-2 and KlcAHS-carrying plasmids among K. pneumoniae strains.
Highlights
Since carbapenemase-producing Klebsiella pneumoniae (KPC) was first reported in the USA in 2001, it has emerged worldwide as a multidrug-resistant hospital pathogen and a significant problem in treating infectious diseases (Yigit et al, 2001)
The first carbapenem-resistant K. pneumoniae isolate was identified at Huashan Hospital in 2006
Analyses of the Plasmid Sequences Derived from the Carbapenem-Resistant K. pneumoniae Isolates
Summary
Since carbapenemase-producing Klebsiella pneumoniae (KPC) was first reported in the USA in 2001, it has emerged worldwide as a multidrug-resistant hospital pathogen and a significant problem in treating infectious diseases (Yigit et al, 2001). Carbapenem antibiotics are ineffective in treating more than half the patients infected with K. pneumoniae due to drug resistance (Pitout et al, 2015). The exchange of genetic material by mobile elements, e.g., plasmids and phages, between closely and distantly related bacterial species is influenced by three horizontal gene transfer (HGT) mechanisms: conjugation, transformation, and transduction (Brown-Jaque et al, 2015). Due to these mechanisms, bacteria can achieve significant genetic diversity by acquiring DNA from distantly-related species. This plays a key role in evolution (e.g., acquiring antibiotic resistance), contributing to the fitness and diversity of prokaryotes (Wiedenbeck and Cohan, 2011; San Millan et al, 2015)
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