Potential for colonization of O111:H25 atypical enteropathogenic E. coli

Using clonal phylogenetic methods, it has been demonstrated that O111:H25 atypical enteropathogenic E. coli (aEPEC) strains belong to distinct clones, suggesting the possibility that their ability to interact with different hosts and abiotic surfaces can vary from one clone to another. Accordingly, the ability of O111:H25 aEPEC strains derived from human, cat and dogs to adhere to epithelial cells has been investigated, along with their ability to interact with macrophages and to form biofilms on polystyrene, a polymer used to make biomedical devices. The results demonstrated that all the strains analyzed were able to adhere to, and to form pedestals on, epithelial cells, mechanisms used by E. coli to become strongly attached to the host. The strains also show a Localized-Adherence-Like (LAL) pattern of adhesion on HEp-2 cells, a behavior associated with acute infantile diarrhea. In addition, the O111:H25 aEPEC strains derived either from human or domestic animals were able to form long filaments, a phenomenon used by some bacteria to avoid phagocytosis. O111:H25 aEPEC strains were also encountered inside vacuoles, a characteristic described for several bacterial strains as a way of protecting themselves against the environment. They were also able to induce TNF-alpha release via two routes, one dependent on TLR-4 and the other dependent on binding of Type I fimbriae. These O111:H25 strains were also able to form biofilms on polystyrene. In summary the results suggest that, regardless of their source (i.e. linked to human origin or otherwise), O111:H25 aEPEC strains carry the potential to cause human disease

Shiga toxin-producing Escherichia coli (STEC): Zoonotic risks associated with psittacine pet birds in home environments

Psittacidae are frequentely bred as pets worldwide, but little is known about the zoonotic risks of these animals. The objective of this study was to investigate the presence of Shiga toxin-producing Escherichia colt (STEC) in the feces of psittacine birds housed as pets. A total of 171 fecal samples (67 cockatiels, 59 budgerigars, and 45 agapornis) were cultured. Forty-two (E. coli) strains were identified, and the presence of the eae,stx1, and stx2 genes was determined using PCR. The antimicrobial resistance profiles of the STEC strains were determined using the disk diffusion method and phylogenetic analysis according to the new Clermont phylotyping method. Using these methods, 19.4% (8/42) of the STEC strains were determined to be positive for the eae and stx2 genes. The results revealed a STEC frequency of 4.6% in the birds (8/171), with a percentage of 8.47% in budgerigars (5/59), 4.47% in cockatiels (3/67), and 0% in agapornis (0/45). None of the STEC isolates belonged to the 0157 serogroup. Most of the strains were classified as sensitive to the 18 antibiotics tested. None of the strains exhibited a multiresistance profile. In the phylogenetic analysis, two strains were classified as non-typeable, three were classified as B2, two were classified as F, and one was classified as Clade I. Seven of the eight STEC strains showed a clonal profile using AFLP. E. coli strains that are stx2(+) plus eae(+) are usually associated with severe human diseases such as hemorrhagic colitis and hemolytic-uremic syndrome. The STEC-positive results indicate the zoonotic risk of breeding psittacidae in home environments. (C) 2016 Elsevier B.V. All rights reserved.