Plasmids play a crucial role in the dissemination of CTX-M type extended-spectrum β-lactamases (ESBLs), and their characterization may provide important insight into understanding multidrug-resistant bacterial strains. β-Lactams are among the most widely used antimicrobial agents for the treatment of bacterial infections. However, the intensive exposure of bacteria to β-lactam antibiotics has induced the emergence of several antibiotic resistance strategies, with the development of β-lactamases capable of inactivating β-lactams being one of the most relevant. In gram-negative bacteria, the production of ESBLs is the principal cause of resistance to β-lactam antibiotics.1,2 Plasmids encoding CTX-M-type cefotaximase were reported in Germany in the late 1980s,3,4 and they are currently distributed worldwide, including North America,5 Latin America6 and Asia.7 CTX-M has become so widespread that it is now considered to be the most prevalent β-lactamase among clinical isolates of Escherichia coli worldwide.8 Diverse studies in Hong Kong,9,10 China,11 and South Korea12 have reported that CTX-M-14 is the most frequently found β-lactamase enzyme in E. coli, Klebsiella pneumoniae, and Shigella isolates. In Mexico, the presence of GES and CTX-M type β-lactamases have been found in Enterobacteriaceae clinical isolates.13 In a previous study, we sampled multidrug-resistant E. coli strains from cattle presenting severe diarrheic symptoms in the State of Querétaro, Mexico, and analyzed their drug resistance spectra, plasmid profiles and conservation using shock waves.14 In this study, we analyzed the complete nucleotide sequence of the pMEX01 plasmid from E. coli strain CM6, which has a high similarity with the previously described pHK01-like plasmids.15

This study demonstrated the presence of a pHK01-like plasmid (pMEX01) in E. coli strain CM6 that was isolated from fecal samples of cattle in the State of Querétaro, Mexico. Although pMEX01 is high similar to pHK17a (99%), several open reading frames significantly differ between the two plasmids. For instance, CDS10 and 17, which are involved in transposition, have identities of 40.4% and 81.5%, respectively, when compared with their corresponding open reading frames in pHK17a. CDS37, which codes for a putative ydaA, has 62.2% identity and has a premature stop codon. Interestingly, CDS88, which encodes the Type IV conjugative transfer system coupling protein TraD, is 85.5% identical to the corresponding TraD in pHK17a and has a premature stop codon. These changes in this open reading frame may have a significant impact on the fitness of pMEX01 since the last 37 amino acid residues are involved in plasmid specificity and transfer efficiency,24 although this has to be verified experimentally.

In the pMEX01 plasmid, blaCTX-M-14 was the only β-lactam resistant determinant found. We compared the antibiotic resistance profile of CM6 against the E. coli BL21 STAR transformant carrying the pMEX01 plasmid. Although both CM6 and the E. coli BL21 STAR transformant exhibited resistance to a wide range of β-lactams, both strains did not exhibit similar resistance to kanamycin, spectinomycin, streptomycin or chloramphenicol, indicating that these resistance traits might be encoded on a different extra-chromosomal element present in the CM6 isolate. Indeed, pMEX01 was not the only plasmid detected when total CM6 DNA was analyzed by PFGE (data not shown). The aminoglycoside and chloramphenicol resistances displayed by CM6, along with the resistance to different generations of β-lactams, may explain why the afflicted cattle were not responsive to standard treatment.

The CTX-M enzymes are a subfamily of the extended-spectrum β-lactamases (ESBLs) that confer resistance to β-lactam antibiotics. More than one hundred types of CTX-M enzymes have been reported and are classified into five classes (CTX-M-1, CTX-M-2, CTX-M-8, CTX-M-9 and CTX-M-25); these enzymes are associated with ISEcp1-like insertion sequences (IS) for mobilization and are the most broadly distributed enzymes among a wide range of bacteria, particularly the Enterobacteriaceae family.25,26 The CTX-M-14 enzyme identified in the E. coli strain CM6 pMEX01 plasmid has been sub-classified into the CTX-M-9 group.27 Although E. coli is recognized as the major source of ESBLs,28 it is accepted that the CTX-M group has a chromosomal origin from Kluyvera georgiana and is the likely source of CTX-M-9 family, of which the pMEX01 CTX-M-14 enzyme is a member.29 Members of the CTX-M-5 family have been reported in North America,25 but to the best of our knowledge, this is the first report of a member of the CTX-M-9 family in this region. This finding suggests that multiple genetic processes are involved in the evolution and persistence of the pHK01-like plasmids in diverse countries.12 The β-lactam resistance gene present in pMEX01 likely emerged from a bacterial lineage with multidrug resistance and maintenance of a pHK01-like plasmid. The pMEX01 plasmid has a potential transposon comprised of an IS903, the blaCTX-M-14 gene and an ISEcp1 element, which has important epidemiological implications for the dissemination of this β-lactamase.30 In fact, diverse studies have demonstrated the wide dissemination of pHK01 plasmid among E. coli isolates obtained from patients with urinary tract infections in Hong Kong.31 Plasmid variants closely related to pHK01 have also been isolated among E. coli isolates from pigs (pHK17a) and human fecal samples (pHK09) in Hong Kong.32 The dissemination of pHK01-like plasmids has also been detected among K. pneumonia isolates from human-fecal samples (pKF3-70) in China26 and among S. sonnei isolates from human fecal samples (pEG356) circulating in southern Vietnam.33 Previous studies have shown that Shiga toxin-producing E. coli (STEC) are medically important foodborne pathogens responsible for diverse outbreaks of hemorrhagic colitis and hemolytic uremic syndrome. These bacteria often carry a variety of plasmids that encode virulence factors and antibiotic-resistance genes, such as the pO26-L plasmid, a closely related variant of pHK01 that has a tetracycline resistance operon; this plasmid was isolated from E. coli 026:H11 strain H30, which was isolated from a child presenting diarrheic symptoms in Canada.34 Considering these studies and the fact that the pMEX01 plasmid has a similar structure as several other plasmids isolated from diverse parts of the world, we can infer that not only are cattle an important reservoir, but also that farm workers could be important for the dissemination of E. coli strains with multidrug resistance and for the persistence of pHK01-like plasmids.

The economic importance of cattle in the State of Querétaro, Mexico, as well as the diverse federal regulations for their transport has forced public health authorities to create diverse strategies to reduce the transfer of these multi-drug-resistant bacteria in human and animal populations, and understand the role of these E. coli strains and its plasmids in pathogenesis. Therefore, a detailed molecular characterization of this plasmid from diverse farms and geographical origins in the State of Querétaro, Mexico should be investigated to identify the epidemiologic pattern of pMEX01 plasmid sequences and changes over time.

The authors declare no conflicts of interest.