An outbreak of gastro-enteritis caused by S typhimurium in the c

An outbreak of gastro-enteritis caused by S. typhimurium in the children’s ward of a Belgian hospital dropped as soon as the German cockroach infestation had been controlled [48]. Tarshis [49] recorded that control of cockroaches was accompanied by a decrease in the incidence of endemic infectious hepatitis. The German cockroach was also shown as a potential mechanical vector of the piglet pathogen Escherichia coli F18 [50]. To our knowledge, surveillance for resistance to antibiotics in enterococci from insects associated with swine production environments MGCD0103 datasheet has not been previously find more conducted. Recently, Graham et al. [51] reported that flies may be involved in the transmission

of drug resistant enterococci and staphylococci from confined poultry farms. In our study, enterococci were detected in the digestive tracts of house flies, cockroach fecal samples and pig fecal samples collected from two different swine farms with enterococci recovered from 93.7% of 364 samples analyzed. High concentrations of enterococci in the digestive tract of house flies and cockroaches suggest that enterococci are common commensals of these insects intestinal

microbiota. Among the four most frequently identified species, E. faecalis and E. faecium are the most important Batimastat enterococcal species from a clinical perspective [20, 22, 27]. However, infections caused by E. hirae and E. casseliflavus may also occur and warrant attention [52]. In addition, enterococci

are regarded as important reservoirs of antibiotic resistance and virulence genes that are often found on mobile genetic elements [22, 27, 30, 52]. The most frequently encountered enterococcal species in the intestines of farm animals are E. faecalis, E. faecium, E. hirae, and E. durans; however, culture methods may influence the recovery and selection of enterococcal species [36, 53]. The dominance of E. hirae in pig feces in our study is consistent with studies of the enterococcal community of swine [32, 33]. E. faecalis was observed more frequently from the digestive tract of insects and these results are also in agreement with previous studies [19, 54]. The favorable Astemizole conditions in the fly and cockroach digestive tract may serve to select and amplify environmentally acquired E. faecalis, including those carrying antibiotic resistance genes. High frequency of resistance to tetracycline, erythromycin, streptomycin, kanamycin, and ciprofloxacin in our study likely reflects use of tetracyclines, macrolides, aminoglycosides and fluoroquinolones for swine in the USA [55]. Unfortunately, we were unable to obtain any specific information on the use of antibiotics in the two commercial farms in this study. Similar results were reported on antimicrobial resistant phenotypes and resistance genes in enterococci from animals and insects [10, 19, 51]. The patterns of antibiotic resistance observed in Enterococcus spp.

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