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Occurrence and characterization of quinolone resistant Escherichia coli from Norwegian turkey meat and complete sequence of an IncX1 plasmid encoding qnrS1

  • Jannice Schau Slettemeås ,

    Roles Formal analysis, Funding acquisition, Investigation, Methodology, Validation, Visualization, Writing – original draft, Writing – review & editing

    jannice.schau-slettemeas@vetinst.no

    Affiliation Section of Food Safety and Emerging Health Threats, Department of Animal Health and Food Safety, Norwegian Veterinary Institute, Oslo, Norway

  • Marianne Sunde,

    Roles Conceptualization, Funding acquisition, Methodology, Project administration, Supervision, Writing – original draft, Writing – review & editing

    Affiliation Section of Food Safety and Emerging Health Threats, Department of Animal Health and Food Safety, Norwegian Veterinary Institute, Oslo, Norway

  • Charlotte Rosenberg Ulstad,

    Roles Formal analysis, Methodology, Writing – original draft, Writing – review & editing

    Affiliation Division of Infectious Disease Control, Norwegian Institute of Public Health, Oslo, Norway

  • Madelaine Norström,

    Roles Funding acquisition, Writing – original draft, Writing – review & editing

    Affiliation Section of Epidemiology, Department of Analysis and Diagnostics, Norwegian Veterinary Institute, Oslo, Norway

  • Astrid Louise Wester,

    Roles Methodology, Writing – review & editing

    Affiliations Division of Infectious Disease Control, Norwegian Institute of Public Health, Oslo, Norway, Water and Sanitation Unit, Department for Public Health, Environmental and Social Determinants of Human Health, World Health Organization, Genève, Switzerland

  • Anne Margrete Urdahl

    Roles Conceptualization, Funding acquisition, Project administration, Supervision, Writing – original draft, Writing – review & editing

    Affiliation Section of Food Safety and Emerging Health Threats, Department of Animal Health and Food Safety, Norwegian Veterinary Institute, Oslo, Norway

Correction

23 May 2019: The PLOS ONE Staff (2019) Correction: Occurrence and characterization of quinolone resistant Escherichia coli from Norwegian turkey meat and complete sequence of an IncX1 plasmid encoding qnrS1. PLOS ONE 14(5): e0217321. https://doi.org/10.1371/journal.pone.0217321 View correction

Abstract

Plasmid-mediated quinolone resistance (PMQR) is frequent among Escherichia coli from various food products and animals in several countries. The objective of this study was to characterize quinolone resistant E. coli (QREC) from Norwegian turkey meat regarding resistance profiles, genetic mechanisms for quinolone resistance, genetic relatedness, and to investigate whether PMQR genes were present. In total, 78 QREC were isolated by a selective method from 156 samples throughout 2013. Isolates were subjected to susceptibility testing, characterization of resistance mechanisms, serotyping, phylotyping and multi-locus variable-tandem repeat analysis (MLVA). All 78 isolates were resistant to ciprofloxacin, while 77 were also resistant to nalidixic acid. The nalidixic acid sensitive isolate had a resistance profile indicating the presence of a PMQR gene. Both PCR and whole genome sequencing confirmed the presence of a 47 304 kb IncX1 plasmid containing the qnrS1 gene. The mechanism conferring quinolone resistance in the remaining isolates was mediated by mutations in the quinolone resistance-determining region of the chromosomal gyrA gene and for most of the isolates also in the parC gene. Molecular typing by MLVA showed a high degree of genetic diversity, although four clusters dominated. Two clusters contained strains belonging to phylogroup D/serogroup O176, the third contained isolates of phylogroup B1/serogroup O19, whereas the fourth contained isolates of phylogroup B1/non-typeable serogroup. Isolates within the latter cluster had MLVA profiles identical to QREC isolated from day-old imported turkey parent animals investigated in a preliminary study at the Norwegian Veterinary Institute. This finding suggests that QREC obtained from turkey may have been introduced via import of breeding animals to Norway. This is the first time the qnrS1 gene is described from E. coli isolated from Norwegian turkey meat. Compared to available qnrS1 carrying plasmids in Genbank, the current IncX1 plasmid showed high degree of similarity to other IncX1 plasmids containing qnrS1 isolated from both Shigella flexneri and E. coli found in different geographical areas and sources. To conclude, this study showed that mutations in gyrA and parC are the main mechanism conferring quinolone resistance in E. coli isolated from Norwegian turkey meat, and that PMQR has not been widely dispersed throughout the E. coli population in Norwegian turkey.

Introduction

Fluoroquinolones (FQ) are listed by the World Health Organization as critically important antimicrobials (CIA) for the treatment of human infections [1]. In the Norwegian livestock production, the usage of FQ is very low [2]. Furthermore, the quinolone resistance among bacteria from production animals has been rare. This is well documented in the Norwegian monitoring programme for antimicrobial resistance in feed, food and animals (NORM-VET, http://www.vetinst.no/overvaking/antibiotikaresistens-norm-vet) [3]. However, in 2009, the NORM-VET programme discovered a small peak compared to earlier findings showing 8% quinolone resistance in randomly tested intestinal E. coli isolated from healthy broilers [4]. Furthermore, in 2012, there was a single finding of plasmid-mediated quinolone resistance (S1 Table) in an E. coli from chicken meat produced in Norway [5]. These findings raised questions of whether poultry was associated with a higher level of quinolone resistant bacteria than previously assumed and if PMQR had dispersed among E. coli in the poultry reservoir in the same way as seen in extended-spectrum cephalosporin (ESC) resistant E. coli [6,7]. Based on this, a selective method for the detection of quinolone resistant E. coli (QREC) was introduced into the NORM-VET programme in 2013 and applied to Norwegian produced turkey meat samples. This resulted in the finding of QREC in 78 out of the 156 investigated turkey unique meat samples (50%) [8].

E. coli has three main mechanisms conferring quinolone resistance; two of these are chromosomal mutations, whereas the third is plasmid-mediated. Chromosomal mutations occur either in genes involved in quinolone target enzymes like DNA gyrase and topoisomerase, or in genes encoding regulatory proteins for the expression of porins or efflux pumps, resulting in a lower intracellular accumulation of quinolones [911]. Accumulation of chromosomal mutations in the quinolone resistance-determining region (QRDR) of the gyrA and/or parC genes typically results in high-level resistance, with ciprofloxacin and nalidixic acid MIC values of ≥1 mg/L and ≥256 mg/L, respectively. In contrast, strains harbouring PMQR genes tends to exhibit ciprofloxacin MIC values between 0.06–1 mg/L and nalidixic acid MIC values between 8–32 mg/L as shown by Veldman et al 2011 [12]. Co-existence of PMQR and QRDR mutations, may, however, lead to high-level FQ resistance [11,13,14], and it is also shown that strains harbouring PMQR genes tend to mutate more easily in the QRDR [15,16]. Plasmid-mediated genes known to encode quinolone resistance are: qnrA, qnrB, qnrC, qnrD, qnrS, qnrVC, aac(6’)-lb-cr, qepA, and oqxAB [17,18].

PMQR is of special concern, as these genes may be located on conjugative plasmids that are able to spread horizontally between bacteria. Moreover, the plasmids carrying PMQR genes may also harbour genes conferring resistance to extended-spectrum cephalosporin’s (ESC) and/or resistance to other classes of antimicrobial agents [15,1928]. PMQR genes have been shown to exist on transferable plasmids also carrying blaCMY-2 and/or blaCTX-M found in E. coli isolated from Brazilian chicken meat [29]. In a Turkish study, qnrB and qnrS were found on extended-spectrum beta-lactamase (ESBL) carrying plasmids in E. coli from chicken meat [30].

The aim of the present study was to characterize 78 QREC isolated from Norwegian produced turkey meat regarding antimicrobial resistance profiles, genetic mechanisms for FQ resistance and genetic relatedness of the strains. Furthermore, the sequence of a PMQR plasmid was determined, a comparative analysis to published plasmids was performed, and the plasmids’ ability to conjugate was studied.

Material and methods

Bacterial isolates

A total of 78 QREC isolates originally isolated by selective cultivation from 156 turkey meat samples in the auspices of NORM-VET [31] were included in the present study. Meat samples were collected at retail throughout 2013 in the counties of Oslo, Akershus and Vestfold following a proportionate stratified sampling scheme, representing the market share of the small number of turkey meat production companies in Norway. The metadata regarding the samples are presented in S3 Table.

In short, five grams of turkey meat were cultured at 41°C in MacConkey broth for 24 hours before plating out onto two MacConkey agar plates (BD Difco™, Beckton, Dickinson and Company, Franklin Lakes, New Jersey, USA) containing 0.25 mg/L and 0.5 mg/L ciprofloxacin (Fluka™, Sigma–Aldrich, St. Louis, Missouri, USA), respectively. Typical E. coli colonies were subcultured on blood agar (Heart infusion agar, Difco Laboratories, Fischer Scientific, New Hampshire, USA) containing 5% bovine blood and incubated at 37°C for 24 hours, before being confirmed as E. coli by using a PCR to detect the E. coli specific uidA gene [32]. One isolate per unique meat sample were selected for further investigation and included in the present study.

Susceptibility testing

Susceptibility testing was performed using a broth microdilution method on the Sensititre™ TREK EUVSEC plate (Trek Diagnostic System Ltd., United Kingdom). Isolates resistant to the cephalosporins; cefotaxime and/or ceftazidime were tested on the Sensititre™TREK EUVSEC2 plate in order to determine if the cephalosporin resistance was caused by ESBL or AmpC beta-lactamases. Epidemiological cut-off values (ECOFF) as recommended by the European Committee on Antimicrobial Susceptibility Testing (EUCAST, www.eucast.org) were used to categorize the isolates as susceptible or resistant. The fully susceptible E. coli ATCC 25922, and the cephalosporin-resistant strains E. coli K8-1 (blaCTX-M positive) and E. coli K5-20 (blaCMY-2 positive), were included as quality controls.

Characterization of resistance mechanisms

The isolates were subjected to PCR and sequencing of the gyrA gene by using a method previously described to detect mutations [33]. A 435 bp fragment of the parC gene was amplified using in-house designed primers; PARC.F 5'-ATATGGCAGAGCGCCTTGCGC-3’ and PARC.R 5'-CGAAGTTTGGCACCCAGTC-3 and annealing temperature was set to 53°C. PCR products were sequenced on a 3130xl or 3500 Genetic Analyzer (Applied Biosystems, Foster By, California, USA) using BigDye V3.1 cycle sequencing kit (Applied Biosystems). Sequences were processed and analysed in CLC Main Workbench (CLC Bio, QIAGEN, Aarhus, Denmark).

One isolate with a ciprofloxacin MIC above ECOFF and nalidixic acid MIC below ECOFF indicating the presence of PMQR genes [12], were subjected to PCR for the detection of; qnrA, qnrB, qnrD, qnrS and aac(6’)-lb-cr according to previously described methods [12,34,35]. The following positive control strains were included in the respective run: Enterobacter cloacea 03–577 (qnrA1+/CTX-M-9+), Klebsiella pneumoniae Kp15 (qnrB1+), Salmonella enterica Newport 2007601863–1 (qnrB5+), E. coli transformant p2007057 TF1 (qnrD+), Salmonella enterica Saintpaul 200860-85-2 (qnrS1+), and Salmonella enterica Typhimurium GSS-HN-2007-003 (aac(6’)lb-cr). E. coli ATCC 25922 was included as a negative control strain.

Isolates resistant to ESC and displaying a phenotype resembling an AmpC profile were subjected to real-time PCR in order to detect the plasmid-mediated AmpC gene blaCMY-2 and closely related variants [36]. Positive and negative control strains were included in the run. In case of negative results by blaCMY-2 real-time PCR, the isolates were further investigated for up-regulated AmpC production due to mutations in the promoter/attenuator region by a previously described method [3739].

Whole genome sequencing of PMQR isolate

In depth characterization of the isolate found to be positive for the PMQR gene qnrS1 (NVI-2422) was performed by paired-end sequencing at the Norwegian Sequencing Centre on an Illumina HiSeq 2500 (Illumina Inc., San Diego, California, USA) using rapid run mode with a read length of 2x250bp. The whole genome sequencing (WGS) data were quality controlled (QC) by adapter and quality trimming using Trimmomatic [40], and assembled using SPAdes v3.11.0 using the “—careful” parameter [41]. Genetic characterization of the isolate was performed using the following online tools with default settings from the Center for Genomic Epidemiology (http://www.genomicepidemiology.org): ResFinder 3.0, PlasmidFinder 3.1, MLST 1.8 and SeroTypeFinder 1.1. The MLST scheme Escherichia coli #1 developed by Wirth et al 2006 was used to assign allele numbers [42].

A draft sequence of the plasmid was identified in an assembled scaffold containing the qnrS1 gene sequence. The scaffold was 46710 bp in size and identified using CLC Main Workbench (CLC Bio, QIAGEN). To investigate if the scaffold could be circularized, PCR was performed followed by Sanger sequencing with primers hybridizing to both ends of the scaffold. Boiled DNA was used as template for the amplification of the region mentioned above. Primers were designed using CLC Main Workbench and the nucleotide sequence of the PCR product obtained was determined using BigDye Terminator v3.1/1.1 cycle sequencing kit and a 3500 Genetic Analyzer (both Applied Biosystems). The nucleotide sequence of the complete plasmid (pNVI2422, 47304 bp) was annotated by automated annotation using the Rapid Annotation using Subsystems Technology (RAST) server V2.0 [43] and PROKaryotic Annotation (Prokka) [44] together with manual annotation in CLC Main Workbench (CLC Bio, QIAGEN). The BLAST Ring Image Generator (BRIG) was used to visualize the comparison to other plasmids [45].

Conjugation experiments

Conjugation experiments in liquid media were performed as described previously by Mo et al. [7] with E. coli OneShot™ cells with pCR™ II vector containing a kanamycin resistance gene (Invitrogen™, LifeTechnologies, Thermo Fisher Scientific Inc., Waltham, MA, USA) as the recipient strain. The experiments on solid media were performed using the same donor and recipient strains. Overnight cultures of recipient and donor was mixed 1:10 on Trypton Soy Agar (Oxoid, Thermo Fisher Scientific Inc.) and incubated at 37°C. Sampling of mating pairs in both experiments was performed after 4 or 24 hours by plating material from the mating pairs onto Mueller Hinton agar (Difco Laboratories, Fischer Scientific) containing 0.06 mg/L ciprofloxacin (Fluka, Sigma-Aldrich) and 50 mg/L kanamycin (Fluka, Sigma-Aldrich). The plates were incubated at 37°C for 24–48 hours. The morphology of the colonies was visually inspected for the typical characteristics of the recipient strain [46]. To confirm conjugative transfer, the transconjugants were subjected to PCR as previously described in order to verify phylogroup D of the recipient strain as well as the presence of the qnrS gene.

Phenotypic serotyping

All isolates were O-serogrouped at the Norwegian Institute of Public Health using polyvalent and monovalent E. coli antisera according to the producer’s manual (https://www.sifin.de/download/T/ts2216/TS2216-GA-EN_2016_03_24_10_10.pdf). The isolates were tested against polyvalent antisera SSI pool 2 and pool 3 (SSI Diagnostica, Copenhagen, Denmark) and Anti-Coli I, Anti-Coli II, and Anti-Coli III (all from SIFIN Diagnostics gmbh, Berlin, Germany) (S5 Table). In addition, the following monovalent O antisera were used; SSI O19, O101, O176 and O8, and SSI OK O121 and O45 (SSI Diagnostica). Some of the specific monovalent antisera were included because of serogroup findings in ciprofloxacin resistant E. coli isolated from turkeys in the UK [47]. For testing against O antisera from SSI Diagnostica, a boiled culture was mixed with antiserum in a tube, incubated overnight in humid atmosphere at 52°C, and controlled for granulation (positive test). For testing against the polyvalent antisera from SIFIN (SIFIN Diagnostics gmbh) and monovalent SSI OK antisera (SSI Diagnostica), 20 μL antiserum was applied on a slide, together with 5–10 colonies from an overnight culture, mixed to a homogenous suspension and controlled for agglutination. If positive for agglutination in the polyvalent SIFIN antisera, the isolates were further tested against SIFIN monospecific antisera by microtiter plate agglutination and confirmed by agglutination in a Widal tube test, according to the producer’s manual (https://www.sifin.de/download/T/ts2216/TS2216-GA-EN_2016_03_24_10_10.pdf). NaCl was used as negative control for spontaneous agglutination.

Determination of phylogroups

Phylotyping of all isolates was conducted using a multiplex PCR amplifying the three phylogenetic markers chuA, yjaA and TSPE4.C2, with primers as previously described [48]. Primers for the gadA gene were implemented as an internal amplification control. Isolates were grouped into the four phylogenetic groups A, B1, B2 and D according to the dichotomous decision tree for phylogenetic grouping established by Clermont et al 2000 [49]. An isolate belonging to the B2 group (E. coli 2003500827) exhibiting all four target genes was included as a positive control [46].

Multi-locus variable-tandem repeat analysis

Multi-locus variable-tandem repeat analysis (MLVA) was conducted on all isolates using a previously described protocol by Lobersli et al. 2012 [50,51]. Altogether, ten loci were amplified (CVN001, CVN002, CVN003, CVN004, CVN007, CVN014, CVN015, CVN016, CVN017 and CCR001), by three multiplex and one singleplex PCR. The amplifications were mixed and multi fluorolabelled products were separated by capillary electrophoresis on a 3130xl Genetic Analyzer (Applied Biosystems). Each peak was normalized and identified according to colour and size using the Peak Scanner Software V2 (Applied Biosystems). An allele number was assigned based on fragment size. In case of no amplicons, allele number was designated as -2. Allele numbers were entered in BioNumerics as character values (BioNumerics version 6.6, Applied Maths NV, Sint-Martens-Latem, Belgium). The strain EDL933 was run as a positive control for the analysis.

Similarity between MLVA profiles were calculated using categorical coefficients and the unweighted pair group method with arithmetic mean (UPGMA) algorithm [52], and by the minimum spanning tree (MST) algorithm [53].

Results

Resistance to antimicrobial agents

Results of the susceptibility testing of the 78 QREC isolates are presented in Table 1. All isolates displayed MIC values above the ECOFF for ciprofloxacin at 0.06 mg/L. Except for one isolate, they also expressed resistance to nalidixic acid with MIC values above the ECOFF at 16 mg/L.

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Table 1. Minimum Inhibitory Concentrations (MICs) and antimicrobial resistance in Escherichia coli resistant to fluoroquinolones (n = 78) isolated from turkey meat in Norway in 2013.

https://doi.org/10.1371/journal.pone.0212936.t001

The most common co-resistance, found in this study, was resistance to sulfamethoxazole (60.3%), ampicillin (57.7%), tetracycline (34.6%), and trimethoprim (34.6%). Resistance to gentamicin and chloramphenicol were detected in 15.4% and 10.3% of the isolates, respectively.

Resistance to ESC occurred in 16 (20.5%) of the isolates. All isolates displayed a phenotypic profile corresponding to be an AmpC producer according to the EFSA summary report of 2018 [54] with MIC values to cefoxitin >8 mg/L, and cefotaxime and ceftazidime >1 mg/L. Further, all isolates were susceptible to meropenem with MIC values ≤0.03 mg/L and synergy with clavulanic acid was not detected.

Genetic characterization

In 44 (56.4%) of the 78 isolates, quinolone resistance was caused by two mutations in gyrA at codon 83 and 87, and one mutation in parC at codon 80. In gyrA, the mutation Serine → Leucine (S83L), together with Aspartic acid → Asparagine at codon 87 (D87N) were detected. In parC, the mutation Serine → Isoleucine (S80I) was detected in 35 isolates, and Serine → Asparagine (S80R) in the remaining 9 of the 44 isolates. All the 44 isolates exhibited MIC of ciprofloxacin of ≥4 mg/L and nalidixic acid MIC of >128 mg/L. Single gyrA S83L mutation was detected in another 33 (42.3%) of the 78 isolates. Of the 33 isolates, one had additional S80R mutation in the parC gene and exhibited MIC of ciprofloxacin of 1 mg/L and nalidixic acid MIC of >128 mg/L. The remaining 32 of the 33 isolates exhibited MIC of ciprofloxacin of 0.25–0.5 mg/L and nalidixic acid of ≥64 mg/L and contained no mutations in the parC gene. One isolate did not contain any mutations in the gyrA nor parC genes and was suspected to carry a PMQR gene because of the MIC profile of ciprofloxacin of 0.5 mg/L and nalidixic acid of 8 mg/L.

Resistance to ESC was in 15 of the strains caused by nucleotide substitutions at position -42, -18 and +81 in the promoter/attenuator region of the chromosomally located ampC gene corresponding to promoter sequence variant 1 [38]. In the last strain, ESC was caused by nucleotide substitutions at position -18 and +81 corresponding to promoter sequence variant 11. All 16 ESC resistant E. coli isolates were also resistant to sulfamethoxazole and tetracycline, whereas 12 were simultaneously resistant to gentamicin.

Compilation of results from serotyping and phylotyping showed that approximately 45% of the isolates grouped into serogroup O176/phylogroup D (n = 14, 17.9%), serogroup O19/phylogroup B1 (n = 13, 16.7%), serogroup O8/phylogroup B1 (n = 3, 3.8%), and serogroup O8/phylogroup A (n = 1, 1.3%), Table 2 and S3 Table. The remaining 47 (60.3%) isolates could not be allocated to any of the O-groups included in the test panel using phenotypic serotyping, although one of them was grouped into O2:H5 using WGS data and belonged to phylogroup B2. The 46 (59.0%) non-typeable isolates were grouped in the following phylogenetic groups: D (n = 34, 43.6%), B1 (n = 10, 12.8%), B2 (n = 1, 1.3%) and A (n = 1, 1.3%).

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Table 2. Characteristics of the four dominating clusters regarding phylogroup, phenotypic serogrouping, resistance profile and mutations in gyrA and parC.

https://doi.org/10.1371/journal.pone.0212936.t002

Plasmid characterization

The isolate without mutations in the gyrA and parC genes was suspected to carry a PMQR gene and was further investigated. PCR detected the qnrS gene and conjugation experiments indicated the presence of a self-transferrable PMQR carrying plasmid. The genome of this isolate was sequenced, and the sequence data showed the presence of a qnrS1 gene on a conjugative IncX1 plasmid (pNVI2422, Fig 1). The nucleotide sequence of pNVI2422 was reconstructed and closed by Sanger sequencing to close the gap in the original scaffold (46170 bp). The amplification and sequencing of the gap showed a ~1.3 kb fragment that was found on another small scaffold (1286 bp) of the WGS data.

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Fig 1. Illustration of the qnrS1 bearing IncX1 plasmid pNVI2422.

Dark grey colour indicates transfer associated genes, orange colour indicates plasmid stability system, green colour indicates antimicrobial resistance genes, red colour indicates pilus associated genes, dark green colour indicates replication associated genes, yellow colour indicates other proteins, light grey colour indicates hypothetical proteins, and light blue colour indicates transposon associated genes.

https://doi.org/10.1371/journal.pone.0212936.g001

The plasmid had a total length of 47304 bp and carried qnrS1 associated with an IS2-like element and a blaTEM-1B gene on a Tn3-like transposon conferring ampicillin resistance. The strain carrying the plasmid belonged to sequence type (ST) 355, serogroup O2:H5 and grouped into phylogroup B2. Plasmid pNVI2422 was highly similar to plasmids previously described as shown in Fig 2. The three most similar plasmids were isolated from Shigella flexneri strains. Of these, three were isolated from human sources in China; accession number CP020088, KJ201886, CP012734. The plasmid pNVI2422 was also similar to a plasmid isolated from an E. coli strain from an equine source in the Czech Republic (acc. no. KF362122) [55]. The pNVI2422 IncX1 backbone consisted mainly of genes associated with conjugal transfer and transcription. In addition, the plasmid stability system relBE/stbDE was present on the plasmid backbone. The genetic load region illustrated in Fig 3 showed higher degree of similarity to the genetic load region on plasmids KF362122 and CP012734 as compared to KJ201886 and CP020088. The nucleotide sequence of pNVI2422 from strain 2422 was submitted to GenBank with accession number MH507589.

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Fig 2. BRIG illustration of pNVI2422 compared to plasmids from three Shigella flexneri strains: 1a (CP020088), 4c (KJ201886), and 1a (CP012734). CP020088 was used as the reference genome.

https://doi.org/10.1371/journal.pone.0212936.g002

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Fig 3. Illustration of the genetic load region of plasmid pNVI2422 compared to plasmids with high similarity.

The annotation is performed on pNVI2422 and the resistance genes are in green colour. Blue areas and lines denote nucleotides missing or different compared to pNVI2422.

https://doi.org/10.1371/journal.pone.0212936.g003

Genetic relationship

A total of 23 MLVA profiles were detected among the 78 QREC isolates (S3 Table). Cluster analyses demonstrated four dominating clusters as shown in Fig 4. They contained isolates belonging to serogroup O176 or unknown O-group/phylogroup D isolates (n = 29, 37.2%), serogroup O176 or unknown O-group /phylogroup D isolates (n = 17, 21.8%), serogroup O19 or unknown O-group /phylogroup B1 isolates (n = 15, 19.2%), and one small cluster (n = 7, 9%) with phylogroup B1 isolates belonging to unknown O-group(s), respectively (Fig 4, Table 2). The isolates in the cluster comprising serogroup O19/phylogroup B1 were also resistant to ESCs. The PMQR isolate pNVI2422 belonged to phylogroup B2 and was genetically distinct from the other isolates.

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Fig 4. Minimum Spanning Tree of MLVA data showing the distribution of phylogroups and serogroups among the 78 QREC from turkey meat.

The parts of the circles represent number of isolates. Dark green areas indicate serogroup O176, yellow serogroup O8, and blue serogroup O19. White areas indicate non-typeable isolates. Blue circles indicate phylogroup D and red circles phylogroup B1. Green circle indicates plasmid pNVI2422 (phylogroup B2, serogroup 02:H5).

https://doi.org/10.1371/journal.pone.0212936.g004

Discussion

This study indicates that mutations in gyrA and parC are the dominating mechanism for quinolone resistance in E. coli from the Norwegian turkey production. Although we only looked at isolates from 2013, the results indicate that PMQR has been less widely dispersed throughout the Norwegian turkey E. coli population compared to other animal populations [56].

We detected only one isolate in the present study that carried plasmid encoding quinolone resistance (pNVI2422), identified as qnrS1 on a typical IncX1 plasmid backbone, in the same way as described by Norman et al [57]. IncX1 plasmids are widely distributed and have been detected in species of Salmonella, Klebsiella, Shigella and E. coli [55,58]. Dobiasova and Dolesjka [58] investigated a collection of Enterobacteriaceae from several sources (wildlife, municipal wastewater, humans, food producing animals, and captive animals from different continents) and a high occurrence of IncX1 plasmids containing qnrS1 was found in E. coli strains with reduced susceptibility to ciprofloxacin (0.05 mg/L). These findings suggest that IncX1 plasmids containing qnrS1 are successful and widely disseminated.

A study by Veldman et al published in 2011 [12] where they characterized PMQR suspected Salmonella and E. coli isolates from various food products and animal species, including turkey in thirteen European countries, showed that qnrS1 was frequently identified. Like our result, one of the qnrS1 positive E. coli isolate from broiler in the Dutch study was resistant to ESC [12,59]. In contrast to our results, however, the isolate from the Netherlands contained three different plasmids, all with a qnrS1 gene together with an ESC resistance gene: qnrS1 + blaSHV-12 on a 45 kb non-typeable plasmid, qnrS1 + blaCMY-2 on an 80 kb IncK plasmid, and qnrS1 + blaCTX-M-1 on a 100 kb IncI1 plasmid, respectively.

In this study only one isolate was investigated for the presence of PMQR genes. This isolate lacked mutations in the gyrA and parC genes in combination with having low MIC values for ciprofloxacin and nalidixic acid of 0.5 mg/L and 8 mg/L, respectively. None of the remaining QREC isolates were investigated for PMQR genes. Consequently, additional PMQR genes cannot be ruled out, especially in the isolates with high ciprofloxacin and nalidixic acid MIC values (≥4 mg/L and >128 mg/L, respectively). All these isolates had two mutations in gyrA and one mutation in parC. In the NORM-VET monitoring programme there has previously been a sole indication of an isolate encoding PMQR genes based on characteristic MIC spans of ciprofloxacin MIC values between 0.06–1 mg/L and simultaneously nalidixic acid MIC values between 8–32 mg/L. This E. coli isolate originated from domestically produced chicken meat (S1 Table).

In the present study, most of the isolates were quinolone resistant due to one or two mutations in the gyrA gene and one mutation in the parC gene. Although isolates belonged to a total of 23 MLVA profiles, the clustering of the isolates into four dominating clusters indicate a relationship between the comprised isolates. This relatedness indicates dissemination of clonally related E. coli in the turkey production, which is further supported by the serotyping, phylotyping and resistance profiling results.

It is unknown, though, when, why and how QREC in turkey have emerged as there is no selection pressure from the use of quinolones in the Norwegian turkey production. The overall usage of antimicrobial agents in production animals in Norway is low [60]. However, the turkey production in Norway depends on import of breeding animals. It is therefore a possibility that QREC has been imported via breeding animals as is shown for ESC resistant E. coli in the poultry production [6,61]. This is supported by preliminary results from a Norwegian study of ESC resistant E. coli found in imported turkey parent flocks (S2 Table) where ESC resistant E. coli was found in three different flocks. Similar to the findings in this current study, isolates showed co-resistance to ciprofloxacin, nalidixic acid, gentamicin and tetracycline. In addition, the ESC resistance was due to an up-regulation of the chromosomal ampC gene caused by mutations in the promoter and attenuator region. Moreover, the isolates had identical MLVA profiles as found for the 13 isolates in the O19/phylogroup B1 cluster in our study. Further, a recent study from Sweden showed that QREC isolates with MLVA profiles similar to that of the above-mentioned cluster were found in both grand-parent birds on arrival to Sweden, as well as in all levels of the broiler production pyramid [62]. Although the Swedish study was performed on broiler and not turkey, it supports our hypothesis that the import of poultry breeding animals may be the source of the quinolone resistant bacteria. This is further followed by vertical transmission downwards in the production pyramid. We cannot rule out other routes of development and dissemination of antimicrobial resistance as it can occur through other unidentified or less characterized mechanisms. For instance, common bacterial stress factors for chromosomal mutations leading to quinolone resistance may be present in the turkey production both nationally and internationally [63].

Our findings of QREC in Norwegian turkey might seem comparable with findings in other European studies. However, in these European studies, quinolone resistance was found in 30–90% of E. coli tested without applying a selective method [54,64]. In Norway, similar investigations show very low levels of quinolone resistance among the tested E. coli (1.3% for turkey and 3.6% for broilers) as documented through the NORM-VET monitoring programme [3]. Further, a non-selective procedure testing for quinolone resistance among randomly chosen E. coli from the same turkey samples as included in the present study found quinolone resistance in 0.9% of the isolates only [31]. QREC is thus commonly found by using selective methods, but most probably they are present in very low numbers among the total E. coli isolates, similar to the findings of ESC resistant E. coli in broilers [65].

The presence of QREC in food-producing animals is of concern in many countries. Of special interest are those bacteria harbouring PMQR genes because of their potential to disseminate these genes into human faecal pathogenic bacterial populations. The present study shows that the dominating resistance mechanism among QREC isolates from Norwegian turkey meat is due to chromosomally located mutations, though strains harboring PMQR genes might occur. However, this favourable situation may change over time, and further surveillance is recommended to monitor the situation in the years to come.

Supporting information

S1 Table. Supplemental data file containing the antibiogram and genotype data on the E. coli containing a plasmid-mediated resistance gene isolated from chicken meat produced in Norway in 2012.

https://doi.org/10.1371/journal.pone.0212936.s001

(XLSX)

S2 Table. Supplemental data file containing metadata and MLVA, PFGE, phenotypic and genotypic results on the seven QREC resistant to beta-lactams from a small study on turkey parent breeding animals imported to Norway in 2011.

https://doi.org/10.1371/journal.pone.0212936.s002

(XLSX)

S3 Table. Supplemental data file containing the results on MLVA, phylotyping, phenotypic serotyping, susceptibility testing and AMR genotyping results on the 78 QREC isolated from Norwegian turkey meat.

https://doi.org/10.1371/journal.pone.0212936.s003

(XLSX)

S4 Table. Supplemental data file containing the metadata on the 78 QREC isolated from Norwegian turkey meat.

https://doi.org/10.1371/journal.pone.0212936.s004

(XLSX)

S5 Table. Supplemental data file containing data on 2013-01-2422 wild type, vector and transconjugant.

https://doi.org/10.1371/journal.pone.0212936.s005

(XLSX)

S6 Table. Supplemental data file containing data on the monovalent and polyvalent antisera used in the phenotypic serotyping.

https://doi.org/10.1371/journal.pone.0212936.s006

(XLSX)

Acknowledgments

We thank Anne-Marie Sørgaard at the Norwegian Institute for Public Health for her technical assistance on the serogrouping of the isolates, and Karin Lagesen at the Norwegian Veterinary Institute for her assistance on the bioinformatic analyses.

Part of the study was presented at the 6th Symposium on Antimicrobial Resistance in Animals and the Environment, Tours, France, in July 2015, and also shortly mentioned in the NORM/ NORM-VET 2013 report [8].

We would like to thank the following institutions and persons for providing positive control strains; the University Hospital of North Norway (K5-20, blaCMY-2 positive and K8-1, blaCTX-M), Armand Paauw at University Medical Center, the Netherlands (qnrA), Laurent Poirel at the University of Fribourg, Switzerland (qnrB1), Lina Cavaco at the Technical University of Denmark (qnrB5, qnrD, qnrS1), Shengli Xia at the Henan Center for Disease Control and Prevention, People's Republic of China (aac(6’)lb-cr) and Professor Minghua Wang at the Huashan Hospital, the People's Republic of China (qnrC).

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