Development of a multiplex-PCR probe system for the proper identification of Klebsiella variicola.

BACKGROUND: Klebsiella variicola was very recently described as a new bacterial species and is very closely related to Klebsiella pneumoniae; in fact, K. variicola isolates were first identified as K. pneumoniae. Therefore, it might be the case that some isolates, which were initially classified as K. pneumoniae, are actually K. variicola. The aim of this study was to devise a multiplex-PCR probe that can differentiate isolates from these sister species. RESULT: This work describes the development of a multiplex-PCR method to identify K. variicola. This development was based on sequencing a K. variicola clinical isolate (801) and comparing it to other K. variicola and K. pneumoniae genomes. The phylogenetic analysis showed that K. variicola isolates form a monophyletic group that is well differentiated from K. pneumoniae. Notably, the isolate K. pneumoniae 342 and K. pneumoniae KP5-1 might have been misclassified because in our analysis, both clustered with K. variicola isolates rather than with K. pneumoniae. The multiplex-PCR (M-PCR-1 to 3) probe system could identify K. variicola with high accuracy using the shared unique genes of K. variicola and K. pneumoniae genomes, respectively. M-PCR-1 was used to assay a collection of multidrug-resistant (503) and antimicrobial-sensitive (557) K. pneumoniae clinical isolates. We found K. variicola with a prevalence of 2.1% (23/1,060), of them a 56.5% (13/23) of the isolates were multidrug resistant, and 43.5% (10/23) of the isolates were antimicrobial sensitive. The phylogenetic analysis of rpoB of K. variicola-positive isolates identified by multiplex-PCR support the correct identification and differentiation of K. variicola from K. pneumoniae clinical isolates. CONCLUSIONS: This multiplex-PCR provides the means to reliably identify and genotype K. variicola. This tool could be very helpful for clinical, epidemiological, and population genetics studies of this species. A low but significant prevalence of K. variicola isolates was found, implying that misclassification had occurred previously. We believe that our multiplex-PCR assay could be of paramount importance to understand the population dynamics of K. variicola in both clinical and environmental settings.

Transfer of quinolone resistance gene qnrA1 to Escherichia coli through a 50 kb conjugative plasmid resulting from the splitting of a 300 kb plasmid.

OBJECTIVES: To analyse the in vitro transfer of the qnrA1 gene by a 50 kb (pSZ50) self-transferable plasmid that derives from a 300 kb plasmid (pSZ300) and to determine the complete nucleotide sequence of plasmid pSZ50. METHODS: Extended-spectrum ß-lactamase (ESBL) and plasmid-mediated quinolone resistance (PMQR) genes of an Escherichia coli clinical isolate were analysed. Plasmid analysis included conjugation and selection on seven antibiotics examined by antimicrobial susceptibility testing, RFLP comparison, Southern hybridization, incompatibility group identification and shotgun sequencing. RESULTS: The E. coli 5509 isolate carries the genes encoding the ESBL CTX-M-15 and the quinolone resistance determinants qnrA1, qnrB2 and aac(6')-Ib-cr on a 300 kb plasmid. Seven transfer resistances were analysed by conjugation under two conditions (30 and 37°C), leading to two distinct transconjugant phenotypes with different resistances. Transconjugants of phenotype A harboured a 300 kb plasmid named pSZ300 that conferred resistance to eight antibiotics and harboured the qnrA1, aac(6')-Ib-cr and bla(CTX-M-15) genes. Transconjugants of phenotype B were resistant to three antibiotics and they harboured the qnrA1 gene on an ≈ 50 kb plasmid named pSZ50. Both plasmids were self-transferable at a frequency of 1 × 10(-3). Plasmid pSZ300 was typed to be both an IncF and IncN plasmid, whereas pSZ50 corresponded only to type IncN. Fingerprinting and Southern hybridization showed that plasmid pSZ50 derived from pSZ300. The complete nucleotide sequence of plasmid pSZ50 was determined (51556 bp) and 55 open reading frames were predicted. The qnrA1 gene was identified in a tandem duplicate inside a sul1-type integron structure. CONCLUSIONS: The plasmid pSZ300 represented a fusion of two replicons (IncF and IncN), and our observations suggest that the plasmid pSZ50 (IncN) may split and transfer antibiotic resistance determinants. This mechanism could be advantageous in the dissemination of antibiotic resistance genes.