SUMMARY
Colistin resistance mediated by the mcr-1 gene has been reported worldwide, but to date not from the Andean region, South America. We report the first clinical isolate of Escherichia coli harbouring the mcr-1 gene in Ecuador. The strain was isolated from peritoneal fluid from a 14-year-old male with acute appendicitis, and subjected to molecular analysis. The minimum inhibitory concentration of colistin for the strain was 8 mg/ml and it was susceptible to carbapenems but resistant to tigecycline. The strain harboured mcr-1 and blaCTX-M-55 genes and was of sequence type 609. The recognition of an apparently commensal strain of E. coli harbouring mcr-1 serves as an alert to the presence in the region of this recently described resistance mechanism to one of the last line of drugs available for the treatment of multi-resistant Gram-negative infections.
Key words: Ecuador, Escherichia coli, mcr-1
The most important antimicrobial drug-resistance genetic determinants are those related to mobile extrachromosomal elements because of their potential for rapid spread and global dissemination of resistance [1]. Until recently, only chromosomally encoded resistance to polymyxins, including colistin, had been reported in the Enterobacteriaceae. However, in late 2015, horizontal transmission of low to moderate levels of colistin resistance mediated by the presence of the plasmid-borne gene mcr-1 was described first in China by Liu et al. [2] and subsequently in several other countries. This was a novel antimicrobial resistance mechanism with an enhanced capacity for dispersion and the report raised global concern owing to the use of polymyxins as a last-resort antibiotic for the treatment of serious infections caused by carbapenem-resistant Gram-negative bacteria [2]. To date, mcr-1 has been detected in clinical isolates from four of the five continents and there is evidence from analysis of whole genome databases of its circulation since 2009 or earlier [3]. However, to our knowledge, there are no reports in the indexed literature of the isolation of Enterobacteriaceae harbouring the mcr-1 gene in the Andean region. We record here the first isolation in Ecuador of a strain of Escherichia coli from a clinical infection harbouring the mcr-1 gene.
Since March 2016, all clinical isolates of Enterobacteriaceae showing resistance to colistin identified in our laboratory were screened for the presence of the mcr-1 gene. Five such isolates (four Klebsiella pneumoniae and one E. coli) were identified, but only the E. coli isolate proved positive for the mcr-1 gene. The isolate originated from a 14-year-old male patient admitted to the emergency service with a diagnosis of acute appendicitis. The appendix was removed by laparoscopy, and the presence of necrotic areas was confirmed. Samples of peritoneal liquid were taken for culture, resulting in the isolation of the colistin-resistant E. coli strain Z&Z1409 (susceptible to carbapenems, amikacin and gentamicin and resistant to tigecycline, ciprofloxacin and cephalosporins, according to CLSI guidelines [4] (Table 1). Species identification and antimicrobial susceptibility profiling were performed using the VITEK 2 system (bioMérieux, France). Total DNA was isolated using a High Pure PCR Template Preparation kit (Roche Diagnostics, Switzerland) and ESBL genes (blaSHV, blaTEM, blaCTX) were amplified and sequenced as previously described [5–7]. The mcr-1 gene was screened, and the complete coding sequence was obtained with an in-house approach designed for this study (Fig. 1). Multi-locus sequence typing analysis of the strain was performed according to the scheme of Wirth et al. [8]. The E. coli strain Z&Z1409 was of sequence type (ST) 609. This rare genotype had previously been reported in isolates from rooks (Corvus frugilegus) in Poland (harbouring blaCTX-M-1) [9], Glaucous-winged gulls (Larus glaucescens) from Russian islands (harbouring blaCTX-M-14) [10], dog faeces from public gardens in Denmark (harbouring blaCTX-M-15) [11], and from a patient in Canada (harbouring blaCTX-M-14) [12]. These reports highlight the commensal nature of ST609 in wild and companion animals and its capacity to cause human infections. It is noteworthy that the ESBL gene (blaCTX-M-55) gene identified in our isolate (GenBank accession no. KU896134) has not previously been reported in this sequence type.
Table 1.
Antimicrobial susceptibility profile of the strains analysed using the VITEK 2 system
| MIC, mg/l (S/R) | ||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Isolate | FOX | CAZ | CRO | FEP | DOR | ETP | IMI | MER | AMK | CN | CIP | TGC | COL | mcr-1 | bla | ST |
| KPN 238 | ⩽4 (S) | ⩽1 (S) | ⩽1 (S) | ⩽1 (S) | ⩽0·12 (S) | ⩽0·5 (S) | ⩽0·25 (S) | ⩽0·25 (S) | ⩽2 (S) | ⩽1 (S) | 0·5 (S) | 2 (R) | 16 (R) | − | − | n.d. |
| KPN 1204191 | ⩾6 (R) | ⩾64 (R) | ⩾64 (R) | ⩾64 (R) | ⩾8 (R) | ⩾8 (R) | ⩾16 (R) | ⩾16 (R) | ⩾64 (R) | ⩾16 (R) | ⩾4 (R) | 4 (R) | ⩾16 (R) | − | KPC-2 | n.d. |
| KPN 1220672 | ⩾6 (R) | ⩾64 (R) | ⩾64 (R) | ⩾64 (R) | ⩾8 (R) | ⩾8 (R) | ⩾16 (R) | ⩾16 (R) | ⩾64 (R) | ⩾16 (R) | ⩾4 (R) | 4 (R) | ⩾16 (R) | − | KPC-2 | n.d. |
| ECO Z&Z1409 | ⩽4 (S) | 16 (R) | ⩾64 (R) | 2 (R) | ⩽0·12 (S) | ⩽0·5 (S) | ⩽0·25 (S) | ⩽0·25 (S) | ⩽2 (S) | ⩽1 (S) | ⩾4 (R) | 2 (R) | 8 (R) | + | CTX-M-55 | 609 |
FOX, Cefoxitin; CAZ, ceftazidime; CRO, ceftriaxone; FEP, cefepime; DOR, doripenem; ETP, ertapenem; IMI, imipenem; MER, meropenem; AMK, amikacin; CIP, ciprofloxacin; TGC, tigecycline; COL, colistin; ST, sequence type; n.d., not determined.
Fig. 1.
Screening of mcr-1 and sequencing approach. (A) 389 bp mrc-1 DNA-positive control synthesized by Invitrogen (USA) in a pMA-T plasmid. (B) Primers used for amplification and sequencing. (C) Internal sequencing primers.
Of the four K. pneumoniae isolates resistant to colistin, but negative for mcr-1, one showed a minimum inhibitory concentration (MIC) of 8 mg/l which was within the 4–8 mg/l range recorded by Liu et al. [2] in their E. coli mcr-1-positive isolates; the remaining K. pneumoniae isolates gave MICs of 16 mg/l. The mcr-1-positive E. coli strain Z&Z1409 colistin MIC was consistent with the colistin MIC levels in the E. coli isolates observed by Liu et al. [2]. However, low colistin MICs (2 mg/l) have been described in K. pneumoniae harbouring mcr-1 [13], raising the possibility of differences in phenotypic expression of resistance in clinical isolates and highlighting the necessity of additional research to establish the range of colistin MICs in Gram-negative bacteria other than E. coli harbouring this gene. The complete sequence of mcr-1 (GenBank accession no. KU886144) described here has maximum identity to the sequences deposited in GenBank, suggesting a unique mcr-1 origin and supporting the reports of global dissemination of the gene [14]. To date, this resistance determinant has been the subject of over 30 reports from 17 countries worldwide and found in isolates from food, food animals and river water as well as infections in hospitalized patients [2, 13, 15]. The fact that our isolate was recovered from a case of acute appendicitis presenting as an emergency from the community strongly suggests that the strain was part of the patient's commensal gut flora. E. coli harbouring mrc-1 has been previously described as commensal flora in Dutch travellers, presumably acquired in the Andean region [16]. On the other hand, our patient recorded his residence in the outer urban area of Quito with frequent visits to an intensive food animal production area 160 km from Quito. The increasing incidence of mcr-1 strains has been proposed to be the result of the abuse of polymyxins in food animals [2], which can act as reservoirs and spread this resistance in the environment. In Ecuador polymyxins are approved for use in veterinary and animal food production, but the amount of usage is not available. Therefore, the contact of the patient with animal production areas was most likely a contributory risk factor for the acquisition of the strain from the environment and this is supported circumstantially by the reported association of the ST609 genotype with birds and animals [9–11]. Furthermore, the incident highlights the risk of maintaining resistant bacteria as part of the intestinal flora.
Our strain showed substantial differences in susceptibility profile and production of ESBL genes (CTX-M variant) from the clinical strains reported by Rapoport et al. in Argentina [17] and by Fernandes et al. in Brazil [18], which suggests a diversity of genetic backgrounds of mcr-1-positive strains and its dissemination in South America. Finally, although, the Z&Z1409 strain was not pan-resistant to antibiotics, the possible dissemination of the mcr-1 gene remains a great concern, especially for the risk of its acquisition by carbapenem-resistant Enterobacteriaceae strains present in the microbiota or the acquisition of more resistance determinants in plasmids harbouring mcr-1 which may result in infections that are virtually untreatable. Conjugation and plasmid analysis are currently in progress.
ACKNOWLEDGEMENTS
This work was supported by the Zurita & Zurita Laboratorios (Project MIC-012).
DECLARATION OF INTEREST
None.
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