Abstract
Background
Escherichia coli isolates of equine faecal origin were investigated for antibiotic resistance, resistance genes and their ability to perform horizontal transfer.
Methods
In total, 264 faecal samples were collected from 138 horses in hospital and community livery premises in northwest England, yielding 296 resistant E. coli isolates. Isolates were tested for susceptibility to antimicrobial drugs by disc diffusion and agar dilution methods in order to determine minimum inhibitory concentrations (MIC). PCR amplification was used to detect genes conferring resistance to: ampicillin (TEM and SHV beta-lactamase), chloramphenicol (catI, catII, catIII and cml), tetracycline (tetA, tetB, tetC, tetD, tet E and tetG), and trimethoprim (dfrA1, dfrA9, dfrA12, dfrA13, dfr7, and dfr17).
Results
The proportion of antibiotic resistant isolates, and multidrug resistant isolates (MDR) was significantly higher in hospital samples compared to livery samples (MDR: 48% of hospital isolates; 12% of livery isolates, p < 0.001). Resistance to ciprofloxacin and florfenicol were identified mostly within the MDR phenotypes. Resistance genes included dfr, TEM beta-lactamase, tet and cat, conferring resistance to trimethoprim, ampicillin, tetracycline and chloramphenicol, respectively. Within each antimicrobial resistance group, these genes occurred at frequencies of 93% (260/279), 91%, 86.8% and 73.5%, respectively; with 115/296 (38.8%) found to be MDR isolates. Conjugation experiments were performed on selected isolates and MDR phenotypes were readily transferred.
Conclusions
Our findings demonstrate that E. coli of equine faecal origin are commonly resistant to antibiotics used in human and veterinary medicine. Furthermore, our results suggest that most antibiotic resistance observed in equine E. coli is encoded by well-known and well-characterized resistant genes common to E. coli from man and domestic animals. These data support the ongoing concern about antimicrobial resistance, MDR, antimicrobial use in veterinary medicine and the zoonotic risk that horses could potentially pose to public health.
Introduction
Bacterial resistance to antimicrobials is a global problem, and understanding the molecular basis of resistance acquisition and transmission can contribute to the development of new strategies to combat this phenomenon. Furthermore, a zoonotic component to bacterial antimicrobial resistance has been demonstrated [1-3]. Horses can be a reservoir of antibiotic resistant organisms and genetic determinants of resistance, that may affect veterinary treatment of animals, affect welfare and have economic implications. Such resistance can persist even without selective pressure [1]. Furthermore, antimicrobial use in animals can select for resistance genes that subsequently pose a risk to human public health through compromising the ability to treat infections [2-5]. The use of common antimicrobials in equine veterinary practices, the close contact between humans and horses, along with the risks and consequences such practices place on human health and therapy needs to be reassessed.
Commensal E. coli strains from humans and animals have been reported to express high resistance to common antimicrobial agents, harbouring antibiotic resistance genes such as dfrA17 and dfrA12 [6]. These resistance genes are commonly present on mobile genetic elements such as plasmids and integrons in clinical isolates of Gram-negative microorganisms [4]. Furthermore, resistance genes selected for in non-pathogenic bacteria may later transfer the acquired resistance to pathogenic bacterial species [7,8]. Thus, normal bacterial flora can play a key role as an acceptor and donor of antimicrobial resistance [9]. It has been suggested that in the UK, antibiotic resistance in E. coli of animal origin may arise by acquisition of resistance genes present in MDR bacteria in farm soil. Thus, these bacteria could play an important role in the dissemination of antimicrobial resistance genes to other soil microbes and gastrointestinal bacteria of grazing animals [10].
Whilst several studies in different animals including horses have analysed E. coli for their susceptibility to antimicrobial agents and genetic determinants [1,9,11,12], zoonotic components of antimicrobial resistance varies between countries [13] and studies of Enterobacteriaceae of equine origin in the UK are limited. To investigate factors that may influence zoonotic transmission of antibiotic resistant E. coli through faecal shedding by hospitalized and non-hospitalized horses we describe the prevalence and mechanisms of antibiotic resistance in E. coli isolated from equine faecal samples and analysed by susceptibility testing, PCR analysis and conjugation experiments.
Methods
Source of isolates
Faecal samples were collected over a six month period from an equine veterinary hospital and from two livery stables on the Wirral Peninsula, in north-west England. A total of 264 faecal samples were collected from 138 horses; 109 of these faecal samples (from 66 horses) came from the Philip Leverhulme Equine Hospital (PLEH) at the University of Liverpool and 155 faecal samples (from 72 horses) were randomly sampled at livery yards, comprising on average two faecal samples per horse. When scoring for the presence or absence of antibiotic resistant E. coli, faecal samples were taken as the unit of analysis. To investigate the antibiotic resistance profiles of E. coli shed in faecal samples, three E. coli colonies were isolated at random from each sample using semi-selective media (brilliant green broth and eosin methylene blue agar) and further confirmed biochemically using Api20E (bioMerieux) test.
Antimicrobial Susceptibility testing
Antimicrobial susceptibility testing was performed using both disc diffusion and agar dilution methods, according to the British Society for Antimicrobial Chemotherapy BSAC guidelines.
Disc diffusion method
Isolates were then subjected to disc diffusion testing according to the British Society for Antimicrobial Chemotherapy (BSAC) guidelines as described [14]. All faecal E. coli isolates resistant to at least one antimicrobial agent were stored at-80°C, until further analysis. Isolates were tested for resistance to the following antibiotics: ampicillin (30 μg) (and to cefotaxime (30 μg) and ceftazidime (30 μg) for extended resistance to cephalosporines and referred in this paper as potential ESBL producers for ampicillin resistant isolates), apramycin (30 μg), chloramphenicol (30 μg) (and to florfenicol (30 μg) for chloramphenicol resistant isolates), nalidixic acid (30 μg) (and ciprofloxacin(1 μg) for nalidixic acid resistant isolates), tetracycline (30 μg), trimethoprim (2.5 μg), streptomycin (10 μg), spectinomycin (25 μg), sulphonamides (100 μg) and gentamicin (10 μg). Stringent criteria were adopted for defining multidrug drug resistance (MDR), including resistance to at least four classes of antimicrobial agents. Extended resistance to cephalosporins was provisionally assigned following BSAC recommendations and these strains thereafter referred to as potential ESBL producers. To determine florfenicol resistance in chloramphenicol resistant isolates we adopted a criterion of R ≤ 18 mm and R ≤ 13 mm for apramycin resistance, following personal communication with J. M. Andrews, BSAC.
Minimum inhibitory concentration (MIC) determination using agar dilution method
The MICs of resistant E. coli isolates were determined for each of the following antibiotics: ampicillin, chloramphenicol, ciprofloxacin, tetracycline and trimethoprim using the agar dilution method as described previously [15], and evaluated according to BSAC guidelines.
Identification of antibiotic resistance genes
PCR amplification was used to identify genes responsible for resistance to: ampicillin, chloramphenicol, trimethoprim and tetracycline. In total, six different PCR protocols were applied and 18 antibiotic resistant genes were investigated. The method for DNA extraction was adapted from a method described by Kimata et al. [16]. Six PCR protocols were applied to detect specific genes according to the resistance phenotype, as follows: TEM and SHV β-lactamase genes for isolates exhibiting ampicillin resistance [17]; catI, catII, catIII, [18] and cmlA [19] for chloramphenicol resistance; tetA, tetB, tetC, tetD, tetE and tetG for six genes responsible for tetracycline resistance [20];dfrA1, dfrA9 [21] and dfrA12, dfrA13, dfrA7, dfrA17 [22] for trimethoprim resistance genes. PCR products of dfrA7 and dfrA17, dfrA12 and dfrA13 were cleaved using 20 U EcoRV and pst1 (Sigma) respectively. Positive controls were laboratory strains 7071 (dfr12) and 7082a (dfr17). Positive controls for the other resistance genes were DNA samples from bacterial isolates previously characterized and sequenced in-house. Table 1 lists all primer pairs used.
Table 1.
Primers sequences 5' to 3' | amplicon size (bp) |
---|---|
Shv: CACTCAAGGATGTATTGTG, TTAGCGTTGCCAGTGC | 885 |
Tem: TCGGGGAAATGTGCGCG, TGCTTAATCGTGAGGCACC | 971 |
CatI: AGTTGCTCAATGTACCTATAACC, TTGTAATTCATTAAGCATTCTGCC | 585 |
CatII: ACACTTTGCCCTTTATCGTC, TGAAAGCCATCACATACTGC | 495 |
CatIII: TTCGCCGTGAGCATTTTG, TCGGATGAGTATGGGCAAC | 508 |
cmlA: CCGCCACGGTGTTGTTGTTATC, CACCTTGCCTGCCCATCATTAG | 698 |
tetB: TTGGTTAGGGGCAAGTTTTG, GTAATGGGCCAATAACACCG | 659 |
tetC: CTTGAGAGCCTTCAACCCAG, ATGGTCCTCATCTACCTGCC | 418 |
tetD: AAACCATTACGGCATTCTGC, GACCGGATACACCATCCATC | 787 |
tetA: GCTACATCCTGCTTGCCTTC, CATAGATCGCCGTGAAGAGG | 210 |
tetE: AAACCACATCCTCCATACGC, AAATAGGCCACAACCGTCAG | 278 |
tetG: GCTCGGTGGTATCTCTGCTC, AGCAACAGAATCGGGAACAC | 210 |
dfr1: ACGGATCCTGGCTGTTGGTTGGACGC, CGGAATTCACCTTCCGGCTCGATGTC | 254 |
dfr9: ATGAATTCCCGTGGCATGAACCAGAAGAT, ATGGATCCTTCAGTAATGGTCGGGACCTC | 399 |
dfrA7, dfrA17: GTCGCCCTAAAACAAAGTTA, CGCCCATAGAGTCAAATGT | 195 |
dfr12, dfr13: CCGTGGGTCGATGTTTGATG, GCATTGGGAAGAAGGCGTTCAC | 485 |
E. coli conjugation
Conjugation experiments were carried out on isolates susceptible to nalidixic acid and resistant to ampicillin (n = 35), using the nalidixic acid resistant E. coli K12 (developed using E. coli NTCC 10536) as a recipient strain. E. coli K12 was inoculated into 20 ml nutrient broths (LabM) and incubated overnight at 37°C. Resistant E. coli strains (donor strains) were inoculated into separate 3 ml nutrient broths and incubated overnight; 4 ml of recipient strain was then added to the donor strain and incubated at 37°C for one hour. Broths were then streaked onto agar plates containing nalidixic acid (30 μg/ml) plus ampicillin (8 μg/ml). Plates were incubated for 24 hours. Successful transconjugants were subcultured onto nutrient agar for susceptibility testing by disc diffusion as previously described. The resistance profiles of the transconjugants were compared to the resistance profile of the original strains. Gene profiles of the donor isolates, characterized by PCR, were described prior to the tranconjugation experiments
Statistical analysis
Data was analysed with SPSS statistical software, using the z test for comparing two proportions.
Results
Antibiotic resistant E. coli isolates were obtained from both sources of faeces, but with a significant difference in the prevalence of resistant isolates between the hospital and livery premises. For an overview of the frequency of antibiotic resistant faecal E. coli, comparison was made at the level of the faecal sample, the unit probably most closely associated with zoonotic transmission. Among samples from the hospitalized horses, 89/109 contained at least one antibiotic-resistant E. coli isolate, whereas only 38/155 of the livery-derived equine samples contained resistant isolates, (p < 0.001). A collection of 296 antibiotic resistant E. coli isolates, consisting of 219 and 77 resistant isolates from the hospital and livery premises respectively, were selected for further analysis, allowing comparison of resistance phenotypes (including MDR) in individual isolates (summarised in Table 2). The proportion of MDR resistant isolates, identified by disk diffusion, was significantly greater in the hospital-derived isolates (106/219; 48%) than in livery-derived isolates (9/77; 12%, p < 0.001). MIC testing confirmed these resistance phenotypes in >90% of the isolates.
Table 2.
Abs | No. of faecal samples with at least one resistant E. coli; disc diffusion method (%) | No E. coli isolates exhibiting resistant phenotype | Proportion of isolates resistant by disc diffusion method, which were confirmed by MIC | No MDR-positive faecal samples (% faecal samples) |
---|---|---|---|---|
AMP | 89 (33.7%) | 191 | 93.0% | 57 (21.6%) |
APR | 1 (0.4%) | 1 | - | 1 (0.4%) |
NAL | 36 (13.6%) | 72 | - | 35 (13.3%) |
CIP | 28 (10.6%) | 65 | 93.8% | 28 (10.6%) |
CHL | 49 (18.6%) | 102 | 100% | 47 (17.8%) |
FLO | 9 (3.4%) | 14 | - | 9 (3.4%) |
TET | 92 (34.8%) | 198 | 93.4% | 57 (21.6%) |
TRI | 135 (51.0%) | 279 | 95.0% | 57 (21.6%) |
Abbreviation: ABs, antimicrobials; AMP, ampicillin; APR, apramycin; NAL, nalidixic acid; CIP, ciprofloxacin; CHL, chloramphenicol; FLO, florfenicol; TET, tetracyclin; TRI, trimethoprim
Antimicrobial resistance and multidrug resistant (MDR) E. coli
The number of isolates showing resistance to each antimicrobial agent were: trimethorpim (n = 279), tetracycline (n = 198), ampicillin (n = 191), potential ESBLs (n = 17), chloramphenicol (n = 102), florfenicol (n = 14), nalidixic acid (n = 72), ciprofloxacin (n = 65), apramycin (n = 1), aminoglycosides (n = 249), sulphonamides (n = 282) and gentamicin (n = 59) (Table 2). Results obtained through MIC testing were in good agreement (>93%) with those obtained by the disc diffusion test (Table 2).
Overall, 115 (38.8%) isolates demonstrated an MDR phenotype (resistance to four or more classes of antibiotics): 106 MDR isolates were of hospital origin and nine isolates were from livery premises. The resistance profiles of the MDR isolates fell mostly into three distinct groups: AMP, CHL, TET, TRI, NAL (n = 27/23.4%); AMP, CHLTET, TRI (n = 21/18.2%); AMP, TET, TRI, NAL (n = 9/7.8%).
Antimicrobial resistance genes
In total, nine resistance genes were identified (Table 3). Trimethoprim resistance was attributable to dfr genes in 93% (260/279) at the following frequencies: dfr1 (40.3%), dfr17 (28%), dfr12 (17.3%) and dfr9 (0.3%). Of the tetracycline resistant isolates, 86.8% (172/198) were positive by PCR for tet genes, with tetB the most prevalent gene (71%), followed by tetA at 18% and tet(A+B) at 11%. Amplicons of the catI gene were obtained from 73.5% (75/102) of chloramphenicol resistant isolates, all of which were of hospital origin. Only one of these was also resistant to florfenicol. Of the ampicillin resistant isolates, the TEM β-lactamase genes was identified in 91% (174/191) and only one isolate was positive for the SHV β-lactamase genes.
Table 3.
Antibiotic(No. of resistant isolates investigated) |
Source and number(N) of isolates | Identified by PCR |
Not identified by PCR |
Antibiotic resistance gene composition tested by PCR (details in table legend) |
---|---|---|---|---|
AMP (191) | Hospital n = 177 Livery n = 14 |
169 5 |
8 9 |
TEM & SHV β-lactamase genes |
CHL (102) | Hospital n = 97 Livery n = 5 |
75 0 |
22 5 |
catI catII catIII cmlA |
TET (198) | Hospital n = 177 Livery n = 21 |
154 18 |
23 3 |
tetB tetA tetC tetD tetE tetG |
TRI (279) | Hospital n = 209 Livery n = 70 |
195 65 |
14 5 |
dfrA1 dfrA17 dfrA12 dfrA9 dfrA7, dfrA13 |
All genes listed were tested by PCR amplification using gene-specific primer pairs listed in Table 1. Genes positively identified by PCR are shown in bold, and are listed according to their frequency of occurrence within each resistance group: AMP, TEM lactamase genes 91%, SHV β-lactamase genes 0.6%; CHL, catI 73.5%; TET, tetB 71%, tetA 18%,tetA+B 11%; TRI, dfrA1 40.3%, dfrA17 28%, dfrA12 17.3%, dfrA9 0.3%. Those genes failed to give rise to detectable levels of PCR product are listed in normal type.
Abbreviations: AMP, ampicillin; CHL, chloramphenicol; TET, tetracycline; TRI, trimethoprim
Conjugation experiments
Eight transconjugants (8/35) were obtained, and all were from hospital isolates (Table 4). The resistance profiles of the transconjugants were re-confirmed by disc diffusion testing and found to be identical to those of the donors. The resistance phenotype AMP, CHL, TET, TRI was the dominant (n = 6) followed by AMP, TET, TRI (n = 2).
Table 4.
Antibiogram | Donor genes contributing to the phenotype of each isolate |
---|---|
AMP, CHL, TET, TRI (n = 6) | dfrA17, tetA, catI,TEM β-lactamase genes |
dfrA17, catI,TEM β-lactamase genes | |
tetA, dfr1, dfrA17,TEM β-lactamase genes | |
dfrA17, dfrA12, tetB,TEM β-lactamase genes | |
dfrA12, tetA, tetB,TEM β-lactamase genes, catI | |
dfrA1, dfrA1, tetB,TEM β-lactamase genes, catI | |
AMP, TET, TRI (n = 2) | dfrA17, dfrA12, tetB,TEM β-lactamase genes |
dfrA1, tetB,TEM β-lactamase genes |
Abbreviations: AMP, ampicillin; CHL, chloramphenicol; TET, tetracycline; TRI, trimethoprim; n = number of isolates
Discussion
Our results show that hospitalized horses are more likely to shed antibiotic resistant E. coli strains, and their faeces are more likely to harbour MDR than those of horses in livery premises. The significantly higher prevalence of antibiotic resistance and of MDR found in hospitalized horses in this study fits well with previous observations [23]. All the horses at the PLEH are referrals from private veterinary practices, so many of the horses will have undergone treatment, which may include prior antibiotic administration. Thus, the higher prevalence of resistant E. coli in hospitalized horses could reflect conditions prior to arrival at the PLEH. Transportation and other stress factors have also been shown to increase the shedding of antibiotic resistant enteric bacteria [23], and this may also have influenced the prevalence of resistant E. coli strains in samples collected from the PLEH.
Ampicillin resistance in E. coli isolates described in this paper was largely associated with TEM β-lactamase genes, with only one isolate positive for SHV β-lactamase genes. This agrees with other reports that TEM β-lactamase genes (i.e. TEM-1 β-lactamase gene) are the most prevalent in ampicillin resistant E. coli of animal origin, as well as being commonly reported in human E. coli isolates of hospital origin [23]. Furthermore, this study identified 17 isolates as resistant to cephalosporins (i.e. potential ESBL producers), all of which were positive for TEM β-lactamase genes, with MICs for ampicillin ≥ 256 μg/ml (except for two isolates against, which the MICs = 128 μg/ml). The prevalence of extended spectrum beta-lactamase (ESBL) resistance in European countries of E. coli human isolates is reported to be around 3.9% [24] with variations between countries. ESBL-targeted drugs are being used more frequently, but may result in mutations of TEM and SHVβ-lactamase genes, as well as the widely prevalent ctx-m types [25]. For the potential ESBL producers more identification and confirmation is required and further genotypic analysis in needed. Our results showed that E. coli resistance genes from horses are similar to those found in other animals and humans, however these need further investigation, specifically by sequencing the TEMβ-lactamase PCR products.
In our study, the tetB gene was the most prevalent (71%) tetracycline resistance gene, followed by tetA (18%), and no other tet gene was identified. This prevalence pattern has also been reported in E. coli strains from various animals, including horses [26]. The tetB gene has the widest host range among gram-negative pathogens [27]. In gram-negative bacteria, tetA and tetB efflux genes are widely distributed and normally associated with plasmids, of which most are conjugative [27] and there is evidence for a correlation between the widespread distribution of tetracycline resistance genes and the sub-therapeutic antimicrobial use of tetracycline [28]. However, in the UK, tetracyclines are used relatively rarely in equine veterinary medicine, suggesting that the tet resistance genes identified here may have been acquired by co-selection mechanisms, as discussed below.
The catI gene, responsible for most of the plasmid-mediated resistance to chloramphenicol, was the only cat gene detected in the chloramphenicol resistant isolates. Most of chloramphenicol resistant isolates (47/102) were of the MDR phenotype (Table 2), suggesting that resistance to chloramphenicol is likely to be part of a multiple resistance system. The non-enzymatic chloramphenicol resistance gene (cmlA) also confers resistance to florfenicol. However, that cmlA gene was not identified by PCR, suggesting that the observed flofenicol resistance was possibly due to flo gene, although some chloramphenicol resistant genes can also be responsible for flofenicol resistance [29]. The use of chloramphenicol in UK veterinary medicine is generally restricted to topical application as a treatment for ophthalmic conditions, and is hardly ever used systemically. Chloramphenicol resistance was almost exclusively found in hospital-derived samples indicating that, as with tetracycline resistance, chloramphenicol resistance has most probably been co-selected via linked trimethoprim and ampicillin resistance genes.
A large proportion (93%) of the trimethoprim resistant isolates were positive for at least one of the dfr genes, that are commonly encoded on mobile genetic elements. Particularly, dfrA1 has spread rapidly on the transposon Tn7 to become the most prevalent gene responsible for trimethoprim resistance in the UK [30], and the most prevalent in our study, followed by dfrA12 and dfrA17. The dfrA9 was found only in one isolate in the present study. The dfrA9 gene, first reported in porcine E. coli strains, has also been reported in veterinary isolates and spread to human strains probably as a consequence of the extensive use of potentiated sulphonamide products (e.g. Sulfadiazine/trimethoprim) in veterinary medicine [31]. Reportedly, dfr genes are mostly conjugally transferable [6,32].
A previous study on horses has documented in vitro conjugal transfer of antibiotic resistant genes between genera of Enterobacteriaceae [12]. In studies on E. coli isolates of human origin, the wide dissemination of dfrA17 in urinary E. coli isolates is due mainly to the horizontal transfer of class 1 integrons, via conjugative plasmids [32]. Similarly, horizontal transfer through conjugative plasmids has been reported to be responsible for the wide dissemination of mobile genetic elements (e.g. class 1 integrons) in E. coli isolates from humans and animals [6]. Classes of integrons are widely reported in Enterobacteriaceae from animals [6,10] and in E. coli of animal origin, including horses [1]. Some of our isolates possess the ability to transfer resistance to a recipient (E. coli K12), see table 4, clearly indicating that the resistance is harboured on mobile genetic elements.
Our MIC determination and genetic analysis of resistant isolates suggests that in horses, antibiotic resistance is conferred by the same E. coli resistance genes found in other animal species. In total, 115/296 (38.8%) of our isolates showed MDR. Interestingly, MDR transferred in the conjugation studies, in which all transconjugants showed resistance to ampicillin and trimethoprim (table 4), indicating that both resistance profiles are encoded on mobile genetic elements. Antibiotic resistance can arise in the absence of selective pressures where antibiotic resistance genes are linked on a mobile genetic element; in these cases, exposure to a single antimicrobial agent has been shown to give rise to co-selection of multiple antibiotic resistance genes. Furthermore, stopping treatment, and consequent removal of selective pressure, does not necessarily lead to the loss of resistance [4,33]. Resistance to a range of antimicrobials can thus be selected for by administrating one, or a subset, of antimicrobials [9]. The shedding of resistant bacteria could thus produce a reservoir of resistant bacteria in the environment [4,10]. This type of mechanism may account for the presence of genes conferring resistance to tetracyclines and chloramphenicol, which are very rarely used therapeutically in equine veterinary medicine in the UK. Further work is required to define the multidrug resistant mechanisms, that may be responsible for the high level of prevalence of the resistance profiles (AMP, CHL, TET, TRI, NAL; AMP, CHL, TET, TRI; AMP, TET, TRI, NAL) we have identified. That most of these were from hospital sources might explain the possible role of antimicrobials in the dissemination and development of resistance in this environment.
Conclusions
To our knowledge this is the first study of antibiotic resistant E. coli in equine faeces in the UK. Many of the genes we have identified as responsible for antibiotic resistance in equine E. coli are commonly found in other domestic animals and humans. Antibiotic resistance found in horses probably originates from, and is selected by, the same sources and mechanisms as in other animal species. Thus, in the UK, horses may be both recipients, and sources of the zoonotic transmission of antibiotic resistance and MDR, as well as providing an extensive reservoir for antimicrobial resistance genes.
Competing interests
The authors declare no relationship (commercial or otherwise) that may constitute a dual or conflicting interest.
Authors' contributions
MOA was responsible for study design, data collection and writing the manuscript. NJW provided strains and resistance data, and PDC organized samples collection within the hospital. All the authors contributed to the study design, the analysis of the results and writing this manuscript. All authors read and approved the final manuscript.
Contributor Information
Mohamed O Ahmed, Email: mhmd73@lttnet.net.
Peter D Clegg, Email: P.D.Clegg@liverpool.ac.uk.
Nicola J Williams, Email: njwillms@liverpool.ac.uk.
Keith E Baptiste, Email: keb@life.ku.dk.
Malcolm Bennett, Email: m.bennett@liverpool.ac.uk.
Acknowledgements
Authors are grateful to all staff members at Philip Leverhulme Equine Hospital (PLEH) and the livery stables for their help and support throughout this work.
References
- Kadlec K, Schwarz S. Analysis and distribution of class 1 and class 2 integrons and associated gene cassettes among Escherichia coli isolates from swine, horses, cats and dogs collected in the BfT-GermVet monitoring study. J Antimicrob Chemother. 2008;62(3):469–473. doi: 10.1093/jac/dkn233. [DOI] [PubMed] [Google Scholar]
- Nunnery J, Angulo FJ, Tollefson L. Public health and policy. Prev Vet Med. 2006;73(2-3):191–195. doi: 10.1016/j.prevetmed.2005.09.014. [DOI] [PubMed] [Google Scholar]
- Angulo FJ, Nunnery JA, Bair HD. Antimicrobial resistance in zoonotic enteric pathogens. Rev Sci Tech. 2004;23(2):485–496. doi: 10.20506/rst.23.2.1499. [DOI] [PubMed] [Google Scholar]
- Alekshun MN, Levy SB. Molecular mechanisms of antibacterial multidrug resistance. Cell. 2007;128(6):1037–1050. doi: 10.1016/j.cell.2007.03.004. [DOI] [PubMed] [Google Scholar]
- Scott Weese J. Antimicrobial resistance in companion animals. Anim Health Res Rev. 2008;9(2):169–176. doi: 10.1017/S1466252308001485. [DOI] [PubMed] [Google Scholar]
- Kang HY, Jeong YS, Oh JY, Tae SH, Choi CH, Moon DC, Lee WK, Lee YC, Seol SY, Cho DT. Characterization of antimicrobial resistance and class 1 integrons found in Escherichia coli isolates from humans and animals in Korea. J Antimicrob Chemother. 2005;55(5):639–644. doi: 10.1093/jac/dki076. [DOI] [PubMed] [Google Scholar]
- Phillips I, Casewell M, Cox T, De Groot B, Friis C, Jones R, Nightingale C, Preston R, Waddell J. Does the use of antibiotics in food animals pose a risk to human health? A critical review of published data. J Antimicrob Chemother. 2004;53(1):28–52. doi: 10.1093/jac/dkg483. [DOI] [PubMed] [Google Scholar]
- Wassenaar TM. Use of antimicrobial agents in veterinary medicine and implications for human health. Crit Rev Microbiol. 2005;31(3):155–169. doi: 10.1080/10408410591005110. [DOI] [PubMed] [Google Scholar]
- Saenz Y, Brinas L, Dominguez E, Ruiz J, Zarazaga M, Vila J, Torres C. Mechanisms of resistance in multiple-antibiotic-resistant Escherichia coli strains of human, animal, and food origins. Antimicrob Agents Chemother. 2004;48(10):3996–4001. doi: 10.1128/AAC.48.10.3996-4001.2004. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Srinivasan V, Nam HM, Sawant AA, Headrick SI, Nguyen LT, Oliver SP. Distribution of tetracycline and streptomycin resistance genes and class 1 integrons in Enterobacteriaceae isolated from dairy and nondairy farm soils. Microb Ecol. 2008;55(2):184–193. doi: 10.1007/s00248-007-9266-6. [DOI] [PubMed] [Google Scholar]
- Dunowska M, Morley PS, Traub-Dargatz JL, Hyatt DR, Dargatz DA. Impact of hospitalization and antimicrobial drug administration on antimicrobial susceptibility patterns of commensal Escherichia coli isolated from the feces of horses. J Am Vet Med Assoc. 2006;228(12):1909–1917. doi: 10.2460/javma.228.12.1909. [DOI] [PubMed] [Google Scholar]
- Vo AT, van Duijkeren E, Fluit AC, Gaastra W. Characteristics of extended-spectrum cephalosporin-resistant Escherichia coli and Klebsiella pneumoniae isolates from horses. Vet Microbiol. 2007;124(3-4):248–255. doi: 10.1016/j.vetmic.2007.04.027. [DOI] [PubMed] [Google Scholar]
- de Jong A, Bywater R, Butty P, Deroover E, Godinho K, Klein U, Marion H, Simjee S, Smets K, Thomas V. A pan-European survey of antimicrobial susceptibility towards human-use antimicrobial drugs among zoonotic and commensal enteric bacteria isolated from healthy food-producing animals. J Antimicrob Chemother. 2009;63(4):733–744. doi: 10.1093/jac/dkp012. [DOI] [PubMed] [Google Scholar]
- Andrews JM. BSAC standardized disc susceptibility testing method (version 7) J Antimicrob Chemother. 2008;62(2):256–278. doi: 10.1093/jac/dkn194. [DOI] [PubMed] [Google Scholar]
- Andrews JM. Determination of minimum inhibitory concentrations. J Antimicrob Chemother. 2001;48(Suppl 1):5–16. doi: 10.1093/jac/48.suppl_1.5. [DOI] [PubMed] [Google Scholar]
- Kimata K, Shima T, Shimizu M, Tanaka D, Isobe J, Gyobu Y, Watahiki M, Nagai Y. Rapid categorization of pathogenic Escherichia coli by multiplex PCR. Microbiol Immunol. 2005;49(6):485–492. doi: 10.1111/j.1348-0421.2005.tb03752.x. [DOI] [PubMed] [Google Scholar]
- Pitout JD, Thomson KS, Hanson ND, Ehrhardt AF, Moland ES, Sanders CC. beta-Lactamases responsible for resistance to expanded-spectrum cephalosporins in Klebsiella pneumoniae, Escherichia coli, and Proteus mirabilis isolates recovered in South Africa. Antimicrob Agents Chemother. 1998;42(6):1350–1354. doi: 10.1128/aac.42.6.1350. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Vassort-Bruneau C, Lesage-Descauses MC, Martel JL, Lafont JP, Chaslus-Dancla E. CAT III chloramphenicol resistance in Pasteurella haemolytica and Pasteurella multocida isolated from calves. J Antimicrob Chemother. 1996;38(2):205–213. doi: 10.1093/jac/38.2.205. [DOI] [PubMed] [Google Scholar]
- Keyes K, Hudson C, Maurer JJ, Thayer S, White DG, Lee MD. Detection of florfenicol resistance genes in Escherichia coli isolated from sick chickens. Antimicrob Agents Chemother. 2000;44(2):421–424. doi: 10.1128/AAC.44.2.421-424.2000. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Ng LK, Martin I, Alfa M, Mulvey M. Multiplex PCR for the detection of tetracycline resistant genes. Mol Cell Probes. 2001;15(4):209–215. doi: 10.1006/mcpr.2001.0363. [DOI] [PubMed] [Google Scholar]
- Gibreel A, Skold O. High-level resistance to trimethoprim in clinical isolates of Campylobacter jejuni by acquisition of foreign genes (dfr1 and dfr9) expressing drug-insensitive dihydrofolate reductases. Antimicrob Agents Chemother. 1998;42(12):3059–3064. doi: 10.1128/aac.42.12.3059. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Lee JC, Oh JY, Cho JW, Park JC, Kim JM, Seol SY, Cho DT. The prevalence of trimethoprim-resistance-conferring dihydrofolate reductase genes in urinary isolates of Escherichia coli in Korea. J Antimicrob Chemother. 2001;47(5):599–604. doi: 10.1093/jac/47.5.599. [DOI] [PubMed] [Google Scholar]
- Brinas L, Zarazaga M, Saenz Y, Ruiz-Larrea F, Torres C. Beta-lactamases in ampicillin-resistant Escherichia coli isolates from foods, humans, and healthy animals. Antimicrob Agents Chemother. 2002;46(10):3156–3163. doi: 10.1128/AAC.46.10.3156-3163.2002. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Hanberger H, Arman D, Gill H, Jindrak V, Kalenic S, Kurcz A, Licker M, Naaber P, Scicluna EA, Vanis V. Surveillance of microbial resistance in European Intensive Care Units: a first report from the Care-ICU programme for improved infection control. Intensive Care Med. 2009;35(1):91–100. doi: 10.1007/s00134-008-1237-y. [DOI] [PubMed] [Google Scholar]
- Paterson DL, Bonomo RA. Extended-spectrum beta-lactamases: a clinical update. Clin Microbiol Rev. 2005;18(4):657–686. doi: 10.1128/CMR.18.4.657-686.2005. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Bryan A, Shapir N, Sadowsky MJ. Frequency and distribution of tetracycline resistance genes in genetically diverse, nonselected, and nonclinical Escherichia coli strains isolated from diverse human and animal sources. Appl Environ Microbiol. 2004;70(4):2503–2507. doi: 10.1128/AEM.70.4.2503-2507.2004. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Chopra I, Roberts M. Tetracycline antibiotics: mode of action, applications, molecular biology, and epidemiology of bacterial resistance. Microbiol Mol Biol Rev. 2001;65(2):232–260. doi: 10.1128/MMBR.65.2.232-260.2001. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Stine OC, Johnson JA, Keefer-Norris A, Perry KL, Tigno J, Qaiyumi S, Stine MS, Morris JG Jr. Widespread distribution of tetracycline resistance genes in a confined animal feeding facility. Int J Antimicrob Agents. 2007;29(3):348–352. doi: 10.1016/j.ijantimicag.2006.11.015. [DOI] [PubMed] [Google Scholar]
- Singer RS, Patterson SK, Meier AE, Gibson JK, Lee HL, Maddox CW. Relationship between phenotypic and genotypic florfenicol resistance in Escherichia coli. Antimicrob Agents Chemother. 2004;48(10):4047–4049. doi: 10.1128/AAC.48.10.4047-4049.2004. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Towner KJ, Brennan A, Zhang Y, Holtham CA, Brough JL, Carter GI. Genetic structures associated with spread of the type Ia trimethoprim-resistant dihydrofolate reductase gene amongst Escherichia coli strains isolated in the Nottingham area of the United Kingdom. J Antimicrob Chemother. 1994;33(1):25–32. doi: 10.1093/jac/33.1.25. [DOI] [PubMed] [Google Scholar]
- Jansson C, Franklin A, Skold O. Spread of a newly found trimethoprim resistance gene, dhfrIX, among porcine isolates and human pathogens. Antimicrob Agents Chemother. 1992;36(12):2704–2708. doi: 10.1128/aac.36.12.2704. [DOI] [PMC free article] [PubMed] [Google Scholar]
- Yu HS, Lee JC, Kang HY, Jeong YS, Lee EY, Choi CH, Tae SH, Lee YC, Seol SY, Cho DT. Prevalence of dfr genes associated with integrons and dissemination of dfrA17 among urinary isolates of Escherichia coli in Korea. J Antimicrob Chemother. 2004;53(3):445–450. doi: 10.1093/jac/dkh097. [DOI] [PubMed] [Google Scholar]
- Sundqvist M, Geli P, Andersson DI, Sjolund-Karlsson M, Runehagen A, Cars H, Abelson-Storby K, Cars O, Kahlmeter G. Little evidence for reversibility of trimethoprim resistance after a drastic reduction in trimethoprim use. J Antimicrob Chemother. 2009. [DOI] [PubMed]