Abstract
Background
The aim of this study was to detect CMY-type beta-lactamases in E. coli isolates obtained from paediatric patients.
Methods
In total, 404 infection-causing E. coli isolates resistant to third and fourth generation cephalosporins (3GC, 4GC) were collected from paediatric patients over a 2 years period. The identification and susceptibility profiles were determined with an automated microbiology system. Typing of blaCMY and other beta-lactamase genes (blaTEM, blaSHV, blaCTX-M, blaVIM, blaIMP, blaKPC, blaNDM, blaOXA and blaGES) was realized by PCR and sequencing. Phenotypic detection of AmpC-type enzymes was performed using boronic acid (20 mg/mL) and cloxacillin (20 mg/mL) as inhibitors, and the production of extended-spectrum beta-lactamases was determined with the double-disk diffusion test with cefotaxime (CTX) and ceftazidime (CAZ) discs alone and in combination with clavulanic acid. The CarbaNP test and modified carbapenem inhibition method (mCIM) were used for isolates with decreased susceptibility to carbapenems. The clonal origin of the isolates was established by pulsed-field gel electrophoresis (PFGE), phylotyping method and multilocus sequence typing.
Results
CMY-type beta-lactamases were detected in 18 isolates (4.5%). The allelic variants found were CMY-2 (n = 14) and CMY-42 (n = 4). Of the E. coli strains with CMY, the AmpC phenotypic production test was positive in 11 isolates with cloxacillin and in 15 with boronic acid. ESBL production was detected in 13 isolates. Coexistence with other beta-lactamases was observed such as CTX-M-15 ESBL and original spectrum beta-lactamases TEM-1 and TEM-190. In one isolate, the CarbaNP test was negative, the mCIM was positive, and OXA-48 carbapenemase was detected. Phylogroup A was the most frequent (n = 9) followed by B2, E and F (n = 2, respectively), and through PFGE, no clonal relationship was observed. Eleven different sequence types (ST) were found, with ST10 high-risk clone being the most frequent (n = 4). Seventy-two percent of the isolates were from health care-associated infections; the mortality rate was 11.1%.
Conclusions
This is the first report in Mexico of E. coli producing CMY isolated from paediatric patients, demonstrating a frequency of 4.5%. In addition, this is the first finding of E. coli ST10 with CMY-2 and OXA-48.
Keywords: CMY beta-lactamases, AmpC, E. coli, Paediatrics, Mexico
Background
Of the family Enterobacteriaceae, Escherichia coli is one of the main causative agents of infections, both in the hospital environment and in the community [1]. In E. coli, the main mechanism of resistance to beta-lactam antibiotics is the production of beta-lactamases [2]. Among the different types of beta-lactamases, the AmpC-type has emerged as an important group of enzymes [3]. AmpC types are present in the chromosome of some enterobacteria but can pass to mobile genetic elements, such as plasmids, and be transferred horizontally between different species. These enzymes confer resistance to oxyimino-cephalosporins (ceftazidime, cefotaxime), cephamycins (cefoxitin) and monobactams (aztreonam). However, this spectrum of hydrolysis can be extended and affect fourth generation cephalosporins (4GC) (cefepime) [4]. Eight families of plasmid AmpC have been described based on differences in the amino acid sequence: CMY (cephamycin), FOX (cefoxitin), ACC (Ambler class C), LAT (latamoxef), MIR (Miriam hospital in Providence), ACT (AmpC type), MOX (moxalactam), and DHA (Dhahran hospital in Saudi Arabia) [3, 5]. Of these groups, CMY-2 is the most common type in E. coli and has been reported in Asia, Europe and North America [6–9]. In 2014, as part of the International Network for Optimal Resistance Monitoring (INFORM) program, 2,813 E. coli isolates were collected in 69 hospital centres in the USA, and CMY-2 was reported in 74 isolates (2.6%) [10]. In the Study for Monitoring Antimicrobial Resistance Trends (SMART) performed in 12 countries of the Asia–Pacific region in the 2008–2014 period, CMY-2 was reported in 1739 E. coli isolates at a frequency of 10.2% (n = 178) [11]. There have been reports of CMY-2 in Latin America: Argentina (0.9%), Colombia (3.5%) and Brazil (0.5%) [12–14]. In Mexico, only one study has reported E. coli producing CMY, causing a urinary tract infection in an adult patient [15]. Other studies have reported the presence of these enzymes in isolates obtained from animal origin, such as dogs (11.3%), sheep (0.64%) and turtles (9.8%) [16–18]. However, there is no information on the molecular or epidemiological characteristics of E. coli isolates producing CMY-type beta-lactamases in the Mexican paediatric population.
The aim of this study was to detect CMY-type beta-lactamases in isolates from E. coli obtained from paediatric patients attended at a tertiary care hospital.
Methods
Study site
The National Institute of Paediatrics (INP) is a tertiary care and teaching hospital in Mexico City with 235 beds and 40 medical subspecialties. In 2018, the INP had 6072 discharges.
Isolates
In total, 404 non-duplicate 3GC and/or 4GC resistant E. coli isolates were collected from paediatric patients (0 to < 18 years) from the National Institute of Paediatrics (INP) over a 2-years period (February 2013–January 2015). These isolates were obtained from various clinical samples causing confirmed infections. We reviewed the medical files in order to collect clinical information such as: date of admission, gender, age, antibiotic treatments, among others. An infection was considered HAI if it appeared on or after the 3rd day of admission, according to the definitions of the Centers for Disease Control and Prevention (CDC) [19]. The strains were identified using the Phoenix Automated Microbiology System® (Becton Dickinson, New Jersey, USA).
Antimicrobial susceptibility profiles of E. coli isolates
The susceptibility profile of the isolates was determined using the Phoenix® automated system (Becton Dickinson, New Jersey, USA). The tested antibiotics were ceftriaxone (CRO), ceftazidime (CAZ), cefepime (FEP), imipenem (IMP), meropenem (MEM) and ertapenem (ETP). The minimum inhibitory concentration (MIC) to cefoxitin was determined using the broth microdilution method following the guidelines of M07 of the Clinical and Laboratory Standards Institute [20]. The interpretation of the results was performed in accordance with CLSI document M100 [21].
Molecular detection of blaCMY and other beta-lactamase genes
Total DNA extraction was performed using the QIAamp® DNA Mini Kit (QIAGEN, Hilden, Germany) following the manufacturer's instructions. Detection of blaCMY and other beta-lactamases (blaCTX-M-1, blaCTX-M-2, blaCTX-M-9, blaCTX-M8/25, blaTEM and blaSHV) was performed by end-point monoplex PCR. For the isolates with decreased susceptibility or resistance to carbapenems, carbapenemase genes were amplified; multiplex PCR (blaVIM, blaIMP and blaKPC), and blaNDM, blaOXA-48 and blaGES were individually amplified. We used previously published primers [22–25]. The reaction was performed in an AB9700 thermocycler (Applied Biosystems, Foster City, CA, USA) using AmpliTaq Gold® 360 MasterMix (Applied Biosystems, Foster City CA, USA). The fragments obtained were purified with a QIAquick PCR purification kit (QIAGEN, Hilden, Germany) and sequenced on a 3500 XL system (Applied Biosystems, Foster City, CA, USA). The sequences were analysed with the blastn program [26, 27], and multiple alignments were made with the BioEdit v7.2 program (Ibis Biosciences, Carlsbad CA, USA) to determine the beta-lactamase subtype.
Phenotypic tests for AmpC, ESBL and carbapenemases
The phenotypic detection of AmpC enzymes was performed with double-disc synergy using ceftazidime disks (Becton Dickinson, New Jersey, USA) alone and in combination with cloxacillin (20 mg/mL) and boronic acid (20 mg/mL) (Sigma Aldrich, Milwaukee, WI). A test was considered positive if there was an increase in the inhibition diameter ≥ 5 mm of the ceftazidime in the presence of cloxacillin or boronic acid compared to the diameter of the ceftazidime without inhibitor [28].
The phenotypic detection of ESBL was performed by the combined disc method, using disks of cefotaxime (30 μg) and ceftazidime (30 μg) alone and in combination with clavulanic acid (30 μg/10 μg) (Becton Dickinson, New Jersey, USA) following the guidelines of the CLSI The presence of ESBL was confirmed by an increase of > 5 mm in the diameter of the zone of inhibition for any agent tested in combination with clavulanic acid compared with the diameter of the zone of inhibition for the agent alone [21].
Isolates with decreased susceptibility or resistance to carbapenems (IMP, MEM, ETP) were tested for carbapenemases production using CarbaNP and mCIM according to the guidelines of the CLSI [21].
Molecular typing
The phylogenetic group of the isolates was obtained with the Clermont method [29]. The clonal relationship was determined using PFGE following the protocol for E. coli O157:H7 from PulseNet (CDC, Atlanta, GA) [30]. The Salmonella enterica serotype Braenderup ATCC BAA-664 strain was used as a molecular size marker. The band patterns were interpreted using Tenover criteria [31]. The ImageLab v5.2.1 program (Bio-Rad, Hercules, CA, USA) was used to create a 0/1 matrix, and DendroUpGMA (https://genomes.urv.cat/UPGMA/) and MEGA-X programs [32] were used to construct the dendrogram.
For detection of the E. coli ST131-O25b clone, trpA, pabB and rfb genes were amplified [33].
The MLST technique was performed by amplifying seven housekeeping genes (adk, fumC, gyrB, icd, mdh, purA and recA) using primers and conditions previously reported [34]. The sequences were analysed using the database available at https://enterobase.warwick.ac.uk/species/index/ecoli.
Results
Detection of blaCMY and other beta-lactamase genes
Of the 404 E. coli isolates, CMY-type beta-lactamases were detected in 18 (4.5%). The susceptibility profile of the isolates with CMY was FEP 22.3% (n = 4), IMP 94.4% (n = 17), MEM 94.4% (n = 17) and ETP 77.7% (n = 14); three isolates were intermediate to CAZ, one was to FOX and none was susceptible to ceftriaxone. The allelic variants found were CMY-2 (n = 14) and CMY-42 (n = 4). In 15 isolates, coexistence with other beta-lactamase genes was observed such as CTX-M-15 ESBL, TEM-1 and TEM-190 OSBL and OXA-48 carbapenemase. The genes blaSHV, blaCTX-M-2, blaCTX-M-9, blaCTX-M-8/25, blaGES, blaKPC, blaNDM, blaVIM, blaIMP were not detected (Table 1).
Table 1.
Key | MIC (μg/mL) | CAZ CLOX |
CAZ BOR |
AmpC type | ESBL test | Other enzymes | PFGE | ST131-O25b clone | Phylogroup | MLST | CC | ||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
CRO | CAZ | FEP | FOX | IMP | MEM | ETP | |||||||||||
Ec 24 | > 32 | ≥ 16 | ≥ 16 | 128 | ≤ 1 | ≤ 1 | 1 | − | + | CMY-2 | + | CTX-M-15 | NT | − | D | ST405 | 405 |
Ec 35 | > 32 | ≥ 16 | ≥ 16 | > 128 | ≤ 1 | ≤ 1 | ≤ 0.5 | − | + | CMY-2 | + | CTX-M-79 | NR | − | F | ST457 | ND |
Ec 41 | > 32 | ≥ 16 | ≥ 16 | 64 | ≤ 1 | ≤ 1 | ≤ 0.5 | − | − | CMY-2 | + | TEM-1, CTX-M-15 | NR | − | F | ST648 | 648 |
Ec 55 | > 32 | ≥ 16 | ≥ 16 | > 128 | ≤ 1 | ≤ 1 | ≤ 0.5 | + | + | CMY-2 | + | CTX-M-15 | NR | − | A | ST10 | 10 |
Ec 65 | > 32 | ≥ 16 | ≥ 16 | 128 | ≤ 1 | ≤ 1 | ≤ 0.5 | + | + | CMY-2 | + | CTX-M-15 | NR | − | B2 | ST12 | 12 |
Ec 109 | > 32 | ≥ 16 | ≥ 16 | 16 | ≤ 1 | ≤ 1 | ≤ 0.5 | − | − | CMY-2 | + | CTX-M-15 | NR | − | A | ST10 | 10 |
Ec 223 | > 32 | 8 | ≥ 16 | 128 | ≤ 1 | ≤ 1 | ≤ 0.5 | − | + | CMY-2 | + | CTX-M-15 | NR | + | B2 | ST131 | ND |
Ec 278 | > 32 | ≥ 16 | ≤ 2 | 128 | ≤ 1 | ≤ 1 | ≤ 0.5 | + | + | CMY-2 | − | Absent | NR | − | A | ST168 | 168 |
Ec 394 | > 32 | ≥ 16 | ≥ 16 | > 128 | ≤ 1 | ≤ 1 | ≤ 0.5 | + | + | CMY-42 | − | TEM-190 | NR | − | A | ST1284 | 10 |
Ec 445 | > 32 | ≥ 16 | ≥ 16 | 128 | ≥ 4 | ≥ 4 | ≥ 2 | − | − | CMY-2 | + | CTX-M-15, OXA-48 | NR | − | A | ST10 | 10 |
Ec 480 | > 32 | ≥ 16 | ≥ 16 | > 128 | ≤ 1 | ≤ 1 | ≤ 0.5 | + | + | CMY-42 | − | Absent | NT | − | A | ST361 | ND |
Ec 481 | > 32 | ≥ 16 | ≥ 16 | 128 | ≤ 1 | ≤ 1 | ≤ 0.5 | + | + | CMY-42 | + | TEM-190 | NR | − | C | ST23 | 23 |
Ec 599 | 16 | ≥ 16 | ≤ 2 | 64 | ≤ 1 | ≤ 1 | ≤ 0.5 | − | + | CMY-2 | − | TEM-1 | NR | − | A | ST101 | 101 |
Ec 668 | > 32 | ≥ 16 | ≥ 16 | 128 | ≤ 1 | ≤ 1 | 1 | + | + | CMY-42 | + | CTX-M-15 | NR | − | A | ST10 | 10 |
Ec 678 | 8 | 8 | ≤ 2 | 128 | ≤ 1 | ≤ 1 | ≤ 0.5 | + | + | CMY-2 | − | Absent | NR | − | E | ST350 | 350 |
Ec 686 | > 32 | ≥ 16 | ≥ 16 | 128 | ≤ 1 | ≤ 1 | 1 | + | + | CMY-2 | + | CTX-M-15 | NR | − | D | ST69 | 69 |
Ec 689 | 8 | 8 | ≤ 2 | 64 | ≤ 1 | ≤ 1 | ≤ 0.5 | + | + | CMY-2 | − | TEM-1 | NR | − | A | ND | ND |
Ec 714 | > 32 | ≥ 16 | ≥ 16 | 64 | ≤ 1 | ≤ 1 | ≤ 0.5 | + | + | CMY-2 | + | CTX-M-15 | NR | − | Clade I | ND | ND |
In bold are the high-risk clone
MIC minimum inhibitory concentration, CRO ceftriaxone, CAZ ceftazidime, FEP cefepime, FOX cefoxitin, IMP imipenem, MEM meropenem, ETP ertapenem, CLOX cloxacillin, BOR boronic acid, ESBL extended-spectrum beta-lactamases, PFGE pulsed-field gel electrophoresis, MLST multilocus sequence typing, CC clonal complex, NT non-typeable, ND not determined, NR not related
Phenotypic tests
The AmpC phenotypic production test was positive in 11 isolates with cloxacillin (61.1%) and 15 isolates with boronic acid (83.3%); 13 isolates were positive for the ESBL confirmatory phenotypic test. Of the four strains of E. coli with decreased susceptibility to ertapenem, one was negative for the CarbaNP test and positive for mCIM (Ec445). The remaining three strains were negative for both tests (Ec24, Ec668 and Ec686) (Table 1).
Molecular typing
Regarding molecular typing in the CMY-producing E. coli isolates, phylogroup A was the most frequent (six isolates with CMY-2 and three with CMY-42) (Table 1). Using PFGE, no clonal relationship was observed between isolates, two of which were non-typable by this technique (Fig. 1). Eleven different STs were found: ST10 (n = 5), three isolates with CMY-2 and two with CMY-42 (Table 1). One isolate corresponded to ST131-O25b clone (Ec223). The known high-risk clones ST10, ST69, ST405 and ST648 were detected. It was not possible to assign the ST in two isolates.
Regarding epidemiological analysis of patients with CMY-producing E. coli, 83% had comorbidities, 56% were male, and the median age was 3.5 years (range 0.6–14 years). Seventy-two percent of the isolates were from health care-associated infections. The main sample was urine (50%), followed by secretion (wound and intra-abdominal, 22.2%) and blood (16.7%). Eleven patients received 3GC as empirical treatment. Ten patients received carbapenems as definitive treatment, and just two received cefepime. The largest number of isolates was reported in 2014 (n = 10). Two patients died from septic shock (Table 2).
Table 2.
Key | Gender | Age | Date | Comorbidity | Infection | Sample | Empirical treatment | Definitive treatment | Acquisition | Outcome |
---|---|---|---|---|---|---|---|---|---|---|
Ec 24 | F | Preschooler | Feb-2013 | Idiopathic ascites | UTI | Urine | FEP | FEP | H | Alive |
Ec 35 | F | Preschooler | Mar-2013 | Aplastic anaemia | UTI | Urine | CRO | MEM | H | Alive |
Ec 41 | M | Adolescent | Apr-2013 | Common variable immunodeficiency | Pneumonia | Bronchial aspirate | CRO | MEM/PTZ | H |
Dead Septic shock |
Ec 55 | M | Infant | Apr -2013 | Primary immunodeficiency | Perianal abscess | Secretion | CRO | CRO | H | Alive |
Ec 65 | F | Infant | May-2013 | Down syndrome | UTI | Urine | MEM | MEM | H | Alive |
Ec 109 | F | School-age | Jun-2013 | Neurogenic bladder | UTI | Urine | CFM | CFM | C | Alive |
Ec 223 | F | Infant | Oct-2013 |
Down syndrome Congenital heart disease |
UTI | Urine | CRO | ETP | H | Alive |
Ec 278 | F | Preschooler | Jan-2014 | Pyelonephritis | Bacteraemia | Blood | CRO | MEM | H | Alive |
Ec 394 | M | School-age | Apr-2014 | Appendectomy | Wound infection | Intra-abdominal and wound secretion | CRO | CFM | C | Alive |
Ec 445 | M | Adolescent | Aug-2014 | ALL | Perianal abscess | Secretion | MEM, PTZ | MEM/AK | H | Alive |
Ec 480 | F | Infant | Aug-2014 | Neurogenic bladder | UTI | Urine | CRO | ETP | C | Alive |
Ec 481 | M | Adolescent | Sep-2014 | Aplastic anaemia | Septic shock | Blood | MEM | MEM | H |
Dead Septic shock |
Ec 599 | F | Adolescent | Nov-2014 | None | UTI | Urine | CRO | CRO | H | Alive |
Ec 668 | M | School-age | Dec-2014 | Uretero-pyelocaliceal stenosis | UTI | Urine | NIF | NIF | C | Alive |
Ec 678 | M | Infant | Dec -2014 | Anorectal malformation | UTI | Urine | CRO | CRO | C | Alive |
Ec 686 | M | Infant | Dec -2014 | Congenital hydrocephalus | Ventriculitis | CSF | MEM | MEM | H | Alive |
Ec 689 | M | Adolescent | Dec-2014 | Right femur osteosarcoma | Catheter-associated infection | Blood | CRO | FEP | H | Alive |
Ec 714 | M | School-age | Jan-2015 | Hydrocephalus | Cerebral abscess | Secretion | MEM | MEM | H | Alive |
ALL acute lymphoblastic leukaemia, UTI urinary tract infection, CSF cerebrospinal fluid, FEP cefepime, CRO ceftriaxone, MEM meropenem, CFM cefixime, PTZ piperacillin/tazobactam, NIF nitrofurantoin, ETP ertapenem, AK amikacin, H hospital, C community
Discussion
This study represents the first report in Mexico of E. coli isolates producing CMY in the paediatric population. Previous studies in our country have documented the presence of these enzymes only in adult patients and animals [16–18]. In this study, the frequency of blaCMY in E. coli was 4.5%, like that reported in three paediatric hospitals in Chicago, USA. (4.4%) [35]. Another study in the same country found 27.9% of E. coli isolates with CMY [36]. In contrast, in Chinese children, CMY was reported only in 1% of isolates [37]. Although ESBL, specifically CTX-M-15, are predominant in E. coli, in recent years, there have been an increase in reports of strains producing AmpC, mainly CMY.
CMY-2 is the most frequent AmpC-type beta-lactamase in E. coli, according to reports from countries, such as Spain and Japan [38, 39]. In our study, this subtype was present in 77.8% of isolates with CMY, and the rest was CMY-42. This variant has been described mainly in India and Egypt [40, 41]. The selection pressure has caused the emergence of variants with hydrolytic activity towards extended-spectrum cephalosporins.
Resistance to cefoxitin, together with sensitivity to cefepime, has been used as a marker of AmpC-type enzyme production. However, in this study, an isolate with CMY presented intermediate sensitivity to cefoxitin, and 14 (78%) were resistant to cefepime. Twelve isolates (67%) were positive for the ESBL phenotypic test, higher than reported in the literature (9.9–36%) [42], which explains the resistance to cefepime. In two isolates with a negative ESBL test (Ec394, Ec480), CMY-42 could have been responsible for resistance to cefepime. The detection of these enzymes is complicated due to the simultaneous production of ESBL and AmpC in an isolate, which makes difficult the interpretation of the antimicrobial susceptibility test.
Due to the lack of standardized methods for the phenotypic detection of these enzymes, their prevalence may be underestimated. One of the phenotypic methods for this purpose is based on the use of cloxacillin and boronic acid as inhibitors with a specificity of 50–90% [43, 44]. In this study, boronic acid was a better inhibitor (83.3%) than cloxacillin (61.1%). In contrast, other reports have indicated greater sensitivity using cloxacillin (77–94%) [28, 41]. However, three isolates with CMY were negative for the phenotypic test with both inhibitors. Given the limitations of phenotypic tests and the lack of standardized methods by international guidelines, such as CLSI or EUCAST, molecular methods, such as PCR, should be considered for the detection of these enzymes.
The presence of ESBL and CMY was observed in 11 isolates (61.1%), all with CTX-M group enzymes, mainly CMY-2 with CTX-M-15 (n = 9). In Japan, CTX-M-15 was detected with CMY in 72% of E. coli strains [45]. In one isolate (Ec394) with a positive ESBL test, only TEM-190 was detected, which is not an ESBL, thus the ESBL profile may have been due to another enzyme that was not determined in this work. Although the frequency of CMY is lower than that of ESBL, it is clinically significant because when combined with the loss of porins (OmpC, OmpF), it can confer resistance to carbapenems, one of the last-line antibiotics for the treatment of infections [46]. On the other hand, CMY enzymes have relevance in resistance to recently introduced antimicrobials, for instance in a study carried out in centers in USA; two E. coli isolates were found, in which genes encoding the CTX-M-15 and CMY-2-like beta-lactamases coexisted; both isolates were resistant to ceftolozane-tazobactam with MIC 64 µg/mL and 128 µg/mL, respectively [47]. The existence of these two mechanisms of resistance in the same isolate can complicate the interpretation of the antibiogram and, consequently, the proper selection of antimicrobial treatment.
In one isolate (Ec445), co-production of CMY-2 with the carbapenemase OXA-48 was detected, which represents the first report of this coexistence in Mexico. This combination was reported in the USA, in isolates obtained from dogs and cats [48]. In other studies, the simultaneous production of CMY with other carbapenemases has been reported. CMY-42 has been described in coexistence with NMD-5 in Italy [49] and Spain [50], and the presence of CMY-42 with NDM-1 and CTX-M-15 has been reported in China [51] and CMY-42 with OXA-181 in India [52]. The simultaneous production of different beta-lactamases decreases the therapeutic options for the treatment of infections.
In Malaysia and the USA, patients colonized by CMY-2-producing E. coli have been described at frequencies of 6.4% and 24%, respectively [53, 54]. In the Netherlands, it was reported that 1.1% of adult carriers were colonized by E. coli with CMY-2 [55]. In Mozambique, E. coli was detected with CMY-2 in 20% of university students [56]. The presence of these enzymes has also been documented in dogs and cats, with frequencies ranging from 3.8 to 85% [57, 58]. In addition, the coexistence of CMY-2 with the mcr-1 gene has been detected in poultry, in Germany [59] and in food-producing animals, in Portugal [60]. These studies indicate that people and animals are reservoirs for the dissemination of E. coli strains with this type of enzyme or can transfer resistance genes to other species.
Fifty percent of E. coli isolates with CMY were classified into commensal phylogroup A (33.3% CMY-2, 16.7% CMY-42), in contrast to that reported in Spain, where pathogenic phylogroup B2 was the most frequent among E. coli with CMY-2 [61]. Other studies in New Zealand and the USA, have reported D as the main phylogroup [62, 63]. In France, a higher frequency was reported in commensal phylogroups (A, B1 and C) than in pathogenic phylogroups (B2, D and F) [64]. Thus, CMY presents a heterogeneous distribution among phylogroups, and commensal E. coli can acquire resistance genes as well as the capacity to cause infections.
There are reports indicating that the dissemination of E. coli isolates producing CMY is non-clonal [61, 62]. In this study, 11 different STs were obtained, and the main was ST10, which is considered a high-risk clone. This ST has been reported in isolates from humans and in chicken meat in Germany [59]. High-risk clones ST69, ST405 and ST648 were also detected. ST69 with CMY-2 has been described in dairy cows in the Czech Republic [65] and in an E. coli strain with mcr-1 obtained from a urinary tract infection case, in England [66]. ST405 and ST648 with CMY-2 have been described in strains isolated from pets in the USA coexisting with OXA-48 [48]. E. coli ST457 with CMY-2 has been reported in molluscs and poultry in Brazil [67, 68] and in an isolate obtained from a paediatric patient in the USA [69]. E. coli ST23 with CMY-2 has been detected in chicken faeces and meat in Denmark [70], and a strain of E. coli ST361 with CMY-42 from the urinary tract was reported in India [40]. In this study, these two clones (Ec480-ST361 and Ec481-ST23) had CMY-42. On the other hand, E. coli ST12 with CMY-2 was reported in poultry in Italy [71], E. coli ST350 in chicken carcasses in Brazil [72], E. coli ST101 with CMY-42 was described in a paediatric patient with bacteraemia [69] and E. coli ST1284 with CMY-2 in a dog with skin and soft tissue infection [73]. Due to the diversity of ST found in this study and those reported in other studies, the dissemination of CMY enzymes seems not to be related to a specific lineage of E. coli, but rather to the transfer of mobile genetic elements. Likewise, there are several reservoirs for these beta-lactamases, such as animals, food and aquatic environments.
In this study, only one isolate with CMY-2 belonged to the E. coli ST131-O25b clone, which is responsible for the global dissemination of CTX-M-15. This ST with CMY has been reported in strains that cause urinary tract infections and bacteraemia [62, 74, 75] and in strains obtained from chickens in Germany [59]. Although there are few reports of E. coli ST131-O25b with CMY, it is important to surveillance the distribution of this clone due to its epidemic potential.
Different risk factors associated with the acquisition of E. coli with AmpC, such as comorbidities, previous use of antimicrobials, use of medical devices, urinary tract abnormalities and prolonged hospital stay have been described in adult patients [76, 77] In the current study, most of the patients had comorbidities and had previously received broad-spectrum antimicrobials (3GC, 4GC and carbapenems). Three patients had urinary tract pathologies, which could have caused greater susceptibility to urinary tract infections. Two patients died from septic shock derived from CMY-producing E. coli infections.
Conclusions
This study represents the first report of E. coli producing CMY in the paediatric population in Mexico, with a frequency of 4.5%. The dissemination of these enzymes in our study was associated with high clonal diversity. A high proportion of E. coli producing CMY also harbour ESBL enzymes. The difficulty of detecting CMY only by phenotypic tests, makes the use of molecular techniques essential.
Due to the emergence of high-risk E. coli clones in our hospital, it is necessary to maintain an epidemiological surveillance programme that allows the timely detection of these strains to prevent outbreaks.
In addition, this is the first report of E. coli ST10 with CMY-2 and OXA-48 in Mexico.
Abbreviations
- ESBL
Extended-spectrum beta-lactamases
- OSBL
Original spectrum beta-lactamases;
- mCIM
Modified carbapenem inhibition method
- PFGE
Pulsed-field gel electrophoresis
- MLST
Multilocus sequence typing
- 3GC
Third generation cephalosporins
- 4GC
Fourth generation cephalosporins
- CMY
Cephamycin
- FOX
Cefoxitin
- ACC
Ambler class C
- LAT
Latamoxef
- MIR
Miriam hospital in Providence
- ACT
AmpC type
- MOX
Moxalactam
- DHA
Dhahran hospital in Saudi Arabia
- MIC
Minimum inhibitory concentration
- UPGMA
Unweighted pair group method with arithmetic mean
Authors’ contributions
AAA and ADC designed the study; JMV and AAA performed the experiments; ADC and YCC collected the microbiological and epidemiological data; JMV and AAA analysed the data and wrote the first draft of the manuscript. All authors read and approved the final manuscript.
Funding
This work was supported by CONACYT through the projects FOSSIS-2012-1-181041 and FOSSIS-2017-1-289537 and by the fiscal resources of the A-modality INP-2019 and INP-2020 (Recurso Fiscal Modalidad A del Instituto Nacional de Pediatria 2019–2020) under registration INP-2018/017. They had no role in the design of the study and collection, analysis, and interpretation of data and in writing the manuscript.
Availability of data and materials
All the data supporting our findings is contained within the manuscript.
Ethics approval and consent to participate
This study was approved by the Research and Ethics Committees of the INP (IRB: 00008064, IRB: 00008065 Registry Number 066/2013). The ethics committee exempted informed consent because the isolates were obtained as part of standard patient care.
Competing interests
The authors declare that they have no competing interests.
Footnotes
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
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Data Availability Statement
All the data supporting our findings is contained within the manuscript.