Diversity of Plasmids and Antimicrobial Resistance Genes in Multidrug-Resistant Escherichia coli Isolated from Healthy Companion Animals.

The presence and transfer of antimicrobial resistance genes from commensal bacteria in companion animals to more pathogenic bacteria may contribute to dissemination of antimicrobial resistance. The purpose of this study was to determine antimicrobial resistance gene content and the presence of genetic elements in antimicrobial resistant Escherichia coli from healthy companion animals. In our previous study, from May to August, 2007, healthy companion animals (155 dogs and 121 cats) from three veterinary clinics in the Athens, GA, USA area were sampled and multidrug-resistant E. coli (n = 36; MDR, resistance to ≥ 2 antimicrobial classes) were obtained. Of the 25 different plasmid replicon types tested by PCR, at least one plasmid replicon type was detected in 94% (34/36) of the MDR E. coli; four isolates contained as many as five different plasmid replicons. Nine replicon types (FIA, FIB, FII, I2, A/C, U, P, I1 and HI2) were identified with FIB, FII, I2 as the most common pattern. The presence of class I integrons (intI) was detected in 61% (22/36) of the isolates with eight isolates containing aminoglycoside- and/or trimethoprim-resistance genes in the variable cassette region of intI. Microarray analysis of a subset of the MDR E. coli (n = 9) identified the presence of genes conferring resistance to aminoglycosides (aac, aad, aph and strA/B), ß-lactams (ampC, cmy, tem and vim), chloramphenicol (cat), sulfonamides (sulI and sulII), tetracycline [tet(A), tet(B), tet(C), tet(D) and regulator, tetR] and trimethoprim (dfrA). Antimicrobial resistance to eight antimicrobials (ampicillin, cefoxitin, ceftiofur, amoxicillin/clavulanic acid, streptomycin, gentamicin, sulfisoxazole and trimethoprim-sulfamethoxazole) and five plasmid replicons (FIA, FIB, FII, I1 and I2) were transferred via conjugation. The presence of antimicrobial resistance genes, intI and transferable plasmid replicons indicate that E. coli from companion animals may play an important role in the dissemination of antimicrobial resistance, particularly to human hosts during contact.

Characterization of a region of the IncHI2 plasmid R478 which protects Escherichia coli from toxic effects specified by components of the tellurite, phage, and colicin resistance cluster.

The IncHI2 plasmid R478 specifies resistance to potassium tellurite (Te(r)), to some bacteriophages (Phi), and to pore-forming colicins (PacB). The genes encoding the three phenotypes are linked, and an 8.4-kb fragment of R478 DNA encoding them cannot be subcloned unless cocloned with a second section of the plasmid. Subclone pKFW4A contains a 5.9-kb BamHI-EcoRI fragment which caused some toxicity when present in Escherichia coli cells. Bacterial cells containing freshly transformed pKFW4A, examined by light microscopy and electron microscopy, had a filamentous morphology consistent with a block in septation. Insertion of transposon Tn1000 into terZ, -A, -B, and -C genes of pKFW4A resulted in the loss of the filamentation phenotype. Deletion of several regions of the clone confirmed that these latter components are involved in the filamentation phenotype. The region specifying protection from toxicity caused by the larger 8.4-kb fragment (encompassing this cluster and the entire 5.9-kb section of pKFW4A) was sequenced and analyzed by T7 polymerase expression and Tn1000 mutagenesis. Three open reading frames, terW, terY, and terX, were identified in a 2.6-kb region. Two polypeptides with approximate molecular masses of 18 and 28 kDa were expressed in CSRDE3 cells and were consistent with TerW (17.1 kDa; 155 amino acids [aa]) and TerY (26.9 kDa; 248 aa), whereas a protein of 213 aa deduced from terX was not observed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The terX gene product shows strong identity with the previously identified TerE, TerD, and TerZ polypeptides, and there is a conserved motif of 13 residues, GDN(R/L)TG(E/A)GDGDDE, within this group of polypeptides. Complementation analysis indicated that terW, located approximately 6.0 kb upstream of terZ, brings about protection of cells from toxic effects of components of the Te(r), Phi, and PacB cluster.

A bacteriocin-like peptide induces bacteriocin synthesis in Lactobacillus plantarum C11.

In this study, we show that bacteriocin production in Lactobacillus plantarum C11 is an inducible process triggered by a secreted protein factor produced by the bacteriocin producer itself. The induction factor was identified to be plantaricin A, a bacteriocin-like peptide whose gene (plnA) is located in the same operon as a two-component regulatory system (plnBCD). When L. plantarum C11 cultures were depleted for plantaricin A, either by growing individual colonies on agar plates or by starting a new culture with a highly diluted inoculum, no bacteriocin was produced during the following growth. When chemically synthesized plantaricin A or purified bacterially produced plantaricin A was added to non-producing cultures, bacteriocin production was induced. Only 1 ng ml-1 plantaricin A is sufficient to induce the bacteriocin production in non-producing L. plantarum C11, and bacteriocin activity appears in the growth medium approximately 150 min after induction. Northern analyses, using a plnA-specific probe, demonstrated that plantaricin A is able to induce its own synthesis by transcription of the plnABCD operon, and this is observed approximately 15 min after adding plantaricin A. Furthermore, heterologous expression of the plnABCD operon in a Lactobacillus sake strain showed that the conditioned growth medium contained the active induction factor. Neither synthetic nor expressed plantaricin A from the heterologous system possesses any bacteriocin activity, suggesting that plantaricin A is primarily an induction factor and not a bacteriocin as claimed earlier.