Vanesa Estepa

Wild boars as reservoirs of extended‐spectrum beta‐lactamase (ESBL) producing Escherichia coli of different phylogenetic groups

ESBL‐producing E. coli isolates have been isolated from eight of seventy seven faecal samples (10.4%) of wild boars in Portugal. The ESBL types identified by PCR and sequencing were blaCTX‐M‐1 (6 isolates) and blaCTX‐M‐1 + blaTEM1‐b (2 isolates). Further resistance genes detected included tet (A) or tet (B) (in three tetracycline‐resistant isolates), aad A (in three streptomycin‐resistant isolates), cml A (in one chloramphenicol‐resistant isolate), sul 1 and/or sul 2 and/or sul 3 (in all sulfonamide‐resistant isolates). The intI 1 gene encoding class 1 integrase was detected in all ESBL‐producing E. coli isolates. One isolate also carried the intI 2 gene, encoding class 2 integrase. The ESBL‐producing E. coli isolates could be assigned to phylogenetic groups B1 (3 isolates), B2 (3 isolates) or A (2 isolates). Amino acid change in GyrA protein (Ser83Leu or Asp87Tyr) was detected in three nalidixic acid‐resistant and ciprofloxacin‐susceptible isolates. Two amino acid changes in GyrA (Ser83Leu + Asp87Asn) and one in ParC (Ser80Ile) were identified in two nalidixic acid‐ and ciprofloxacin‐resistant isolates. As evidenced by this study wild boars could be a reservoir of antimicrobial resistance genes. (© 2009 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)

Prevalence of broad-spectrum cephalosporin-resistant Escherichia coli isolates in food samples in Tunisia, and characterization of integrons and antimicrobial resistance mechanisms implicated

The presence of broad-spectrum-cephalosporin-resistant Escherichia coli isolates and the implicated mechanisms of resistance were investigated in 79 food samples of animal origin obtained in different supermarkets and local butcheries in Tunisia. Ten of these samples (12.6%) harbored extended-spectrum beta-lactamase (ESBL) producing E. coli isolates and 13 ESBL-positive isolates were recovered (one or two/sample), which exhibited nine different Pulsed-Field-Gel-Electrophoresis (PFGE) patterns. ESBLs detected were the following: CTX-M-1 (10 strains), CTX-M-1+TEM-1b (2 strains) and CTX-M-1+TEM-20 (1 strain). The orf477 sequence was identified downstream of bla(CTX-M-1) gene in all 13 strains and ISEcp1 upstream in 9 strains. All ESBL-positive strains were included into phylogenetic group A or B1 (4 and 9 strains, respectively). Three of the 79 food samples (3.8%) contained broad-spectrum-cephalosporin-resistant and ESBL-negative E. coli isolates with AmpC phenotype. One isolate per sample was studied, and they showed unrelated PFGE patterns. The CMY-2 type beta-lactamase was identified in one of these 3 strains and specific point mutations in the promoter/attenuator region of ampC gene (at positions -42, -18, -1 and +58) were detected in the remaining two strains. Twelve ESBL-positive and one ESBL-negative E. coli strains contained class 1 integrons with the following gene cassette arrangements: dfrA1+aadA (6 strains) and dfrA17+aadA5 (7 strains). E. coli strains from food samples could represent a reservoir of ESBL-encoding genes and integrons that could be transmitted to humans through the food chain.

Prevalence and characterization of extended-spectrum beta-lactamase (ESBL)- and CMY-2-producing Escherichia coli isolates from healthy food-producing animals in Tunisia.

The prevalence of extended-spectrum beta-lactamase (ESBL)- and plasmidic AmpC-beta-lactamase (pAmpC-BL)-producing Escherichia coli isolates has been studied in food-producing animals at the farm level in Tunisia, and recovered isolates were characterized for the presence of other resistance genes and integrons. Eighty fecal samples of food-producing animals (23 sheep, 22 chickens, 22 cattle, six horses, five rabbits, and two dromedaries) were obtained from 35 different farms in Tunisia in 2011. Samples were inoculated onto MacConkey agar plates supplemented with cefotaxime (2 mg/L) for cefotaxime-resistant (CTX(R)) E. coli recovery. CTX(R) E. coli isolates were detected in 11 out of 80 samples (13.8%), and one isolate per sample was further characterized (10 from chickens and one from a dromedary). The 11 CTX(R) isolates were distributed into phylogroups: B1 (five isolates), A (two isolates), D (three isolates), and B2 (one isolate). The following beta-lactamase genes were detected: bla(CTX-M-1) (seven isolates), bla(CTX-M-1)+bla(TEM-135) (one isolate), bla(CTX-M-1)+bla(TEM-1b) (one isolate), and bla(CMY-2) (two isolates). All ESBL- and pAmpC-BL-producing E. coli strains showed unrelated pulsed-field gel electrophoresis patterns. Seven isolates contained class 1 integrons with four gene cassette arrangements: dfrA17-aadA5 (three isolates), dfrA1-aadA1 (two isolates), dfrA15-aadA1 (one isolate), and aadA1 (one isolate). All isolates showed tetracycline resistance and contained the tet(A) +/- tet(B) genes. Virulence genes detected were as follows (number of isolates in parentheses): fimA (10); aer (eight); papC (two); and papGIII, hly, cnf, and bfp (none). Chicken farms constitute a reservoir of ESBL- and pAmpC-BL-producing E. coli isolates of the CTX-M-1 and CMY-2 types that potentially could be transmitted to humans via the food chain or by direct contact.

Diversity of Genetic Lineages Among CTX-M-15 and CTX-M-14 Producing Escherichia coli Strains in a Tunisian Hospital

Fourteen broad-spectrum-cephalosporin-resistant Escherichiacoli isolates were recovered between June and December 2007 in a Tunisian hospital. Genes encoding extended-spectrum-beta-lactamases (ESBL) and other resistance genes were characterized by PCR and sequencing. The following ESBL genes were identified: blaCTX-M-15 (12 isolates), blaCTX-M-14a (one isolate), and blaCTX-M-14b (one isolate). The blaOXA-1 gene was detected in 13 blaCTX-M-producing strains and a blaTEM-1 gene in 6 of them. The ISEcp1 sequence was found upstream of blaCTX-M genes in 8 of 14 strains, and orf477 or IS903 downstream of this gene in 13 strains. Nine of the strains carried class 1 integrons and five different gene cassette arrangements were detected, dfrA17–aadA5 being the most common. One of the strains (blaCTX-M-14a-positive) harbored three class 1 integrons, and one of them was non-previously described containing as gene cassettes new variants of aac(6′)-Ib and cmlA1 genes and it was linked to the blaCTX-M-14a gene flanked by a truncated ISEcp1 sequence (included in GenBank with accession number JF701188). CTX-M-15-producing strains were ascribed to phylogroup B2 (six isolates) and D (six isolates). Multilocus-sequence-typing revealed ten different sequence-types (STs) among ESBL-positive E.coli strains with prevalence of ST405 (four strains of phylogroup D) and ST131 types (two strains of phylogroup B2 and serogroup O25b). A high clonal diversity was also observed among studied strains by pulsed-field-gel-electrophoresis (11 unrelated profiles). CTX-M-15 is an emergent mechanism of resistance in the studied hospital and the world-disseminated 0:25b-ST131-B2 and ST405-D clones have been identified among CTX-M-15-producing isolates.

First detection of CTX-M-1, CMY-2, and QnrB19 resistance mechanisms in fecal Escherichia coli isolates from healthy pets in Tunisia.

Our objective was to analyze the carriage rate of extended-spectrum β-lactamase (ESBL)- and plasmidic AmpC β-lactamase (pAmpC)-producing Escherichia coli isolates in fecal samples of healthy pets (dogs and cats) and to characterize the recovered isolates for the presence of other resistance genes and integrons. Eighty fecal samples of healthy pets were inoculated in MacConkey agar plates supplemented with cefotaxime (2 μg/mL) for cefotaxime-resistant (CTX(R)) E. coli recovery. CTX(R) E. coli isolates were detected in 14 of the 80 fecal samples (17.5%) and the following β-lactamase genes (number of isolates) were detected: bla(CTX-M-1) (8), bla(CTX-M-1)+bla(TEM-1b) (3)(,) bla(CTX-M-1)+bla(TEM-1c) (1), bla(CTX-M-1)+bla(TEM-135) (1), and bla(CMY-2)+bla(TEM-1b) (1). The 14 E. coli were distributed into the phylogroups B1 (6 isolates), A (5), and D (3). The qnrB19 gene was detected in one CTX-M-1-producing strain of phylogroup D. Five isolates contained class 1 integrons with the following arrangements: dfrA17-aadA5 (2 isolates), dfrA1-aadA1 (1), and dfrA17-aadA5/ dfrA1-aadA1 (2 isolates). The virulence genes fimA and/or aer were detected in all CTX(R) strains. In this study, the pet population harbored β-lactamase and quinolone resistance genes of special interest in human health that potentially could be transmitted to humans in close contact with them.

Lineages and Virulence Gene Content among Extended-Spectrum β-Lactamase–Producing Escherichia coli Strains of Food Origin in Tunisia

Nineteen extended-spectrum β-lactamase (ESBL)-positive Escherichia coli strains recovered from food samples in Tunisia were characterized by multilocus sequence typing and phylogenetic typing, and the virulence gene and plasmid content were also determined. These strains presented unrelated pulsed-field gel electrophoresis patterns and contained genes coding for the following ESBLs (the number of strains is in parentheses): CTX-M-1 (15), CTX-M-14 (2), CTX-M-8 (1), and SHV-5 (1). Twelve different sequence types (STs) were identified among the 19 ESBL-positive strains, which included two new STs (ST2022 in 2 bla(CTX-M-14)-containing strains and ST1970 in 2 bla(CTX-M-1)-containing strains). ST155 and ST602 were detected in four and three bla(CTX-M-1)-containing strains, respectively, and ST405 was detected in one bla(CTX-M-8)-producing strain. All ESBL-positive strains were ascribed to the phylogenetic groups A and B1. Most of the bla(CTX-M-1)-containing strains harbored an IncI1 plasmid, except for the four bla(CTX-M-1)-positive strains of beef origin and ST155, which harbored an IncN plasmid. The two bla(CTX-M-14)-containing strains contained an IncI1 plasmid. The virulence gene fimA was detected in all strains. Most strains also carried the aer gene, and six strains carried the eae gene. All strains were negative for the virulence genes sxt, papG-III, papC, hly, cnf1, and bfp. We conclude that ESBL-producing E. coli strains of food origin in Tunisia show high diversity and that plasmids harboring ESBL genes could be implicated in the dissemination of this resistance phenotype.

Antibiotic Resistance and Extended-Spectrum β-Lactamases in Isolated Bacteria from Seawater of Algiers Beaches (Algeria)

The aim of the study was to evaluate bacterial antibiotic resistance in seawater from four beaches in Algiers. The most significant resistance rates were observed for amoxicillin and ticarcillin, whereas they were relatively low for ceftazidime, cefotaxime and imipenem. According to sampling sites, the highest resistance rates were recorded for 2 sites subjected to chemical and microbiological inputs (amoxicillin, 43% and 52%; ticarcillin, 19.6% and 47.7%), and for 2 sites relatively preserved from anthropogenic influence, resistance rates were lowest (amoxicillin, 1.5% and 16%; ticarcillin, 0.8% and 2.6%). Thirty-four bacteria resistant to imipenem (n=14) or cefotaxime (n=20) were identified as Pseudomonas aeruginosa (n=15), Pseudomonas fluorescens(7), Stenotrophomonas maltophilia(4), Burkholderia cepacia(2), Bordetella sp. (1), Pantoea sp. (1), Acinetobacter baumannii(1), Chryseomonas luteola(1), Ochrobactrum anthropi(1) and Escherichia coli(1). Screening for extended spectrum β-lactamase showed the presence of CTX-M-15 β-lactamase in the E. coli isolate, and the encoding gene was transferable in association with the IncI1 plasmid of about 50 kbp. Insertion sequence ISEcp1B was located upstream of the CTX-M-15 gene. This work showed a significant level of resistance to antibiotics, mainly among environmental saprophytic bacteria. Transmissible CTX-M-15 was detected in E. coli; this may mean that contamination of the environment by resistant bacteria may cause the spread of resistance genes.

Detection of extended-spectrum beta-lactamase-producing Escherichia coli isolates in faecal samples of Iberian lynx.

Aims:  To characterize the diversity of extended‐spectrum beta‐lactamase (ESBL)‐producing Escherichia coli isolates recovered within the faecal microbiota of Iberian lynx. The identification of other associated resistance genes and the analysis of clonal relationship were also focused in this study.

Iberian wolf as a reservoir of extended-spectrum β-lactamase-producing Escherichia coli of the TEM, SHV, and CTX-M groups.

The intensive use of antibiotics in human and veterinary medicine, associated with mechanisms of bacterial genetic transfer, caused a selective pressure that contributed to the dissemination of antimicrobial resistance in different bacteria groups and throughout different ecosystems. Iberian wolf, due to his predatory and wild nature, may serve as an important indicator of environmental contamination with antimicrobial resistant bacteria. The aim of this study was to characterize the diversity of extended-spectrum β-lactamase (ESBL)-producing Escherichia coli isolates within the fecal microbiota of Iberian wolf. Additionally, the identification of other associated resistance genes, phylogenetic groups, and the detection of virulence determinants were also focused on in this study. From 2008 to 2009, 237 fecal samples from Iberian wolf were collected in Portugal. E. coli isolates with TEM-52, SHV-12, CTX-M-1, and CTX-M-14-type ESBLs were detected in 13 of these samples (5.5%). This study reveals the presence of ESBL-producing E. coli isolates, in a wild ecosystem, which could be disseminated through the environment. Moreover, the presence of resistant genes in integrons and the existence of virulence determinants were shown. The association between antibiotic resistance and virulence determinants should be monitored, as it constitutes a serious public health problem.

Detection of CTX-M-15-producing Escherichia coli isolates of lineages ST410-A, ST617-A and ST354-D in faecal samples of hospitalized patients in a Mauritanian hospital

Detection of CTX-M-15-producing Escherichia coli isolates of lineages ST410-A, ST617-A and ST354-D in faecal samples of hospitalized patients in a Mauritanian hospital Rym Ben Sallem, Karim Ben Slama, Vanesa Estepa, Elmoustapha Ould Cheikhna, Aminetou Mint Mohamed, Sarra Chairat, Fernanda Ruiz-Larrea, Abdellatif Boudabous, Carmen Torres Laboratoire Microorganismes et Biomolecules Actives, Faculte des Sciences de Tunis, Universite Tunis-El Manar, Tunisia, Area Bioquimica y Biologia Molecular, Universidad de La Rioja, Logrono, Spain, Departement de Biologie, Faculte des Sciences et Techniques, Universite des Sciences, de Technologie et de Medecine, Nouakchott, Mauritanie