Identical plasmid AmpC beta-lactamase genes and plasmid types in E. coli isolates from patients and poultry meat in the Netherlands.

The increasing prevalence of third-generation cephalosporin-resistant Enterobacteriaceae is a worldwide problem. Recent studies showed that poultry meat and humans share identical Extended-Spectrum Beta-Lactamase genes, plasmid types, and Escherichia coli strain types, suggesting that transmission from poultry meat to humans may occur. The aim of this study was to compare plasmid-encoded Ambler class C beta-lactamase (pAmpC) genes, their plasmids, and bacterial strain types between E. coli isolates from retail chicken meat and clinical isolates in the Netherlands. In total, 98 Dutch retail chicken meat samples and 479 third-generation cephalosporin non-susceptible human clinical E. coli isolates from the same period were screened for pAmpC production. Plasmid typing was performed using PCR-based replicon typing (PBRT). E coli strains were compared using Multi-Locus-Sequence-Typing (MLST). In 12 of 98 chicken meat samples (12%), pAmpC producing E. coli were detected (all blaCMY-2). Of the 479 human E. coli, 25 (5.2%) harboured pAmpC genes (blaCMY-2 n = 22, blaACT n = 2, blaMIR n = 1). PBRT showed that 91% of poultry meat isolates harboured blaCMY-2 on an IncK plasmid, and 9% on an IncI1 plasmid. Of the human blaCMY-2 producing isolates, 42% also harboured blaCMY-2 on an IncK plasmid, and 47% on an IncI1 plasmid. Thus, 68% of human pAmpC producing E. coli have the same AmpC gene (blaCMY-2) and plasmid type (IncI1 or IncK) as found in poultry meat. MLST showed one cluster containing one human isolate and three meat isolates, with an IncK plasmid. These findings imply that a foodborne transmission route of blaCMY-2 harbouring plasmids cannot be excluded and that further evaluation is required.

Comparison of ESBL contamination in organic and conventional retail chicken meat.

Contamination of retail chicken meat by Extended Spectrum Beta-Lactamase (ESBL) producing bacteria likely contributes to the increasing incidence of infections with these bacteria in humans. This study aimed to compare the prevalence and load of ESBL positive isolates between organic and conventional retail chicken meat samples, and to compare the distribution of ESBL genes, strain genotypes and co-resistance. In 2010, 98 raw chicken breasts (n=60 conventional; n=38 organic) were collected from 12 local stores in the Netherlands. Prevalence of ESBL producing micro-organisms was 100% on conventional and 84% on organic samples (p<0.001). Median loads of ESBL producing micro-organisms were 80 (range <20-1360) in conventional, and <20 (range 0-260) CFU/25 g in organic samples (p=0.001). The distribution of ESBL genes in conventional samples and organic samples was 42% versus 56%, respectively (N.S.), for CTX-M-1, 20% versus 42% (N.S.) for TEM-52, and 23% versus 3% (p<0.001) for SHV-12. CTX-M-2 (7%), SHV-2 (5%) and TEM-20 (3%) were exclusively found in conventional samples. Co-resistance rates of ESBL positive isolates were not different between conventional and organic samples (co-trimoxazole 56%, ciprofloxacin 14%, and tobramycin 2%), except for tetracycline, 73% and 46%, respectively, p<0.001). Six of 14 conventional meat samples harbored 4 MLST types also reported in humans and 5 of 10 organic samples harbored 3 MLST types also reported in humans (2 ST10, 2 ST23, ST354). In conclusion, the majority of organic chicken meat samples were also contaminated with ESBL producing E. coli, and the ESBL genes and strain types were largely the same as in conventional meat samples.