Objectives To characterize carbapenemase-producing isolates of the Klebsiella pneumoniae hypervirulent (hvKp) clone ST23 in Poland. Methods Fifteen K. pneumoniae ST23 isolates were identified by the Polish surveillance of carbapenemase-producing Enterobacterales. These comprised a cluster with KPC-2 + NDM-1 (n = 7), KPC-2 (n = 1) or NDM-1 (n = 1) enzymes from one hospital from 2018, and sporadic isolates with KPC-2 (n = 1), NDM-1 (n = 1), VIM-1 (n = 1) or OXA-48 (n = 3), recovered from 2009 to 2019 in different towns. The isolates were sequenced by Illumina MiSeq, followed by MinION for six representatives. Clonality, phylogeny, serotypes, virulomes, resistomes and plasmids of the isolates were analysed and compared with international ST23 strains, using various bioinformatic tools. Results Only two diverse isolates with KPC-2 or VIM-1 were of typical hvKp ST23 serotypes K1 and O1v.2, and its predominant phylogenetic clade. These contained multiple chromosomal (ybt, clb) and pK2044/KpVP-1 plasmid (iuc, iro, rmpADC, rmpA2) virulence loci, whereas carbapenemase and other antimicrobial resistance (AMR) genes were on single additional plasmids. All remaining isolates were of K57 and O2v.2 serotypes, and a minor, distant clade of unclear phylogeny, including also ∼10 isolates from other European countries. These had fewer virulence loci (ybt, iuc, rmpADC, rmpA2) but abounded in plasmids, which with several chromosomal AMR mutations conferred more extensive MDR phenotypes than in K1 O1v.2. Lower clonal diversity than in K1, and numerous common characteristics of the isolates supported the hypothesis of the emerging character of the ST23 K57 clade. Conclusions A new MDR ST23 lineage has emerged in Europe, causing a potential threat to public health.
Objectives To assess the spread of New Delhi metallo-β-lactamase-1 (NDM-1)-producing Klebsiella pneumoniae ST147 organisms in Poland since an introduction from Tunisia in March 2015, including their phylogenetic position in the global population of the high-risk clone. Methods Out of 8925 unique NDM-positive K. pneumoniae isolates identified in Poland from April 2015 till December 2019, 126 isolates, including the Tunisian imports, were related by PFGE and blaNDM gene-carrying Tn125 transposon derivatives. Forty-seven representative isolates were sequenced by Illumina MiSeq. The phylogeny, resistome, virulome and plasmid replicons were analysed and compared with the international ST147 strains. Plasmids of six isolates were studied by the MinION sequencing. Results A high homogeneity of the 47 isolates was observed, with minor variations in their resistomes and plasmid replicon profiles. However, the detailed SNP comparison discerned a strict outbreak cluster of 40 isolates. All of the organisms were grouped within the ST147 phylogenetic international lineage, and four NDM-1 producers from Tunisia, Egypt and France were the closest relatives of the Polish isolates. Yersiniabactin genes (YbST280 type) were located within the ICEKpn12-like element in most of the outbreak isolates, characterized by O2v1 and KL64 antigen loci. The blaNDM-1 genes were located in double-replicon IncFIIK2+IncFIBK plasmids. Conclusions The continuous spread of K. pneumoniae ST147 NDM-1 in Poland since 2015, largely in the Warsaw area, is demonstrated by this genomic analysis. The isolates showed a high degree of homogeneity, and close relatedness to organisms spreading in the Mediterranean region.
Background Consecutive Polish regions have become endemic for NDM-1-producing Klebsiella pneumoniae ST11, followed by K. pneumoniae ST147. Since 2017 a significant increase in NDM-positive Enterobacter hormaechei cases has been observed. Objectives To investigate the origin and character of this increase in NDM-positive E. hormaechei. Methods The analysis included 160 NDM-producing Enterobacter cloacae complex isolates, recovered in 2015–20 in 37 centres of 9/16 regions. These were typed by PFGE and MLST, and screened by PCR-mapping for NDM-1-encoding Tn125-like elements. Forty-four isolates were sequenced by MiSeq. Species identification was based on whole-genome average nucleotide identity; clonality and phylogeny were inferred by SNP approaches. The structural plasmid analysis was done for 12 isolates sequenced by MinION. Results The isolates belonged to 11 STs, predominantly ST89 (65.6%), followed by ST146 (15.6%), ST198 (7.5%) and ST1303 (3.7%), representing different E. hormaechei subspecies. Most of the isolates contained the Tn125A variant of the K. pneumoniae ST11 lineage, and several had Tn125F of the ST147. Individual E. hormaechei genotypes represented various epidemiological situations, from sporadic cases to single-hospital, city and regional outbreaks, including one caused by ST89 organisms with 82 cases in 17 centres. Acquisitions of the Tn125A/Tn125F determinants by the E. hormaechei strains occurred around 10 times and were plasmid-mediated, with a significant plasmid rearrangement in case of Tn125F. Conclusions The increase in E. hormaechei NDM-1 cases in Poland is a consequence of the uncontrolled spread of NDM-1-producing K. pneumoniae genotypes. Several E. hormaechei lineages have acquired NDM-encoding plasmids in different locales which started ‘secondary’ progressive outbreaks.
Introduction: Pseudomonas putida group are described as low-incidence opportunistic pathogens, but also as a significant reservoir of antimicrobial resistance (AMR) genes, including those of metallo-b-lactamases (MBLs). Our objective was the molecular and genomic characterization of MBL-producing P. putida (MPPP) group isolates from Poland, focusing on population structures, successful genotypes and MBL-encoding integrons. Methods: During a country-wide MBL surveillance in Pseudomonas spp., 59 non-duplicate MPPP isolates were collected from 36 hospitals in 23 towns from 2003 to 2016. All of the isolates were subjected to whole-genome sequencing (WGS), followed by species identification, multi-locus sequence typing (MLST), single-nucleotide polymorphism (SNP)-based phylogenetic/clonality analysis, resistome determination, and susceptibility testing.Results: The study collection comprised 12 species, of which P. alloputida (n = 19), P. monteilii (n = 15), and P. asiatica (n = 11) prevailed, while the others were P. kurunegalensis, P. putida, P. soli, P. mosselii, P. juntendi, and four potentially new species. MLST classified the isolates into 23 sequence types (STs) of which 21 were new, with three main clones, namely P. alloputida ST69, P.monteilii ST95 and P. asiatica ST15. The isolates produced VIM-like MBLs only, largely VIM-2 (n = 40), encoded by 24 different class 1 integrons (ten new), a number of which occurred also in P. aeruginosa and/or Enterobacterales in Poland. The plasmid pool was dominated by IncP-9, IncP-2, and pMOS94-like types. Multiple isolates were extensively drugresistant. Conclusions: This study, being one of the most comprehensive analyses of MPPP so far, has shown high diversity of the isolates in general, with three apparently international lineages, each internally diversified by MBL-encoding structures.
We sequenced all nonduplicate 934 VIM/IMP carbapenemase-producing Enterobacterales (CPE) reported in Poland during 2006–2019 and found ≈40% of the isolates (n = 375) were Enterobacter spp. During the study period, incidence of those bacteria gradually grew in nearly the entire country. The major factor affecting the increase was clonal spread of several E. hormaechei lineages responsible for multiregional and interregional outbreaks (≈64% of all isolates), representing mainly the pandemic sequence type (ST) 90 or the internationally rare ST89 and ST121 clones. Three main VIM-encoding integron types efficiently disseminated across the clone variants (subclones) with various molecular platforms. Those variants were predominantly Pseudomonas aeruginosa –derived In238-like elements, present with IncHI2+HI2A, IncFII+FIA, IncFIB, or IncN3 plasmids, or chromosomal genomic islands in 30 Enterobacter STs. Another prevalent type, found in 34 STs, were In916-like elements, spreading in Europe recently with a lineage of IncA-like plasmids.
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