Introduction
Helicobacter pylori (H. pylori) is an important human pathogen causing gastroduodenal inflammation that can result in duodenal ulcer, gastric ulcer, gastric adenocarcinoma and primary B-cell gastric lymphoma [1,2]. H. pylori has also been related to extragastric diseases, including iron deficiency anemia, idiopathic thrombocytopenic purpura and even colon adenocarcinoma [3]. The National Institutes of Health in the United States, the Maastricht Consensus conferences in Europe, Second Asia-Pacific Consensus Guidelines for H. pylori infection and the Canadian Consensus all recommended H. pylori eradication for the treatment/or prevention of these disorders in addition to reducing occurrence of new gastric cancers [4–9]. An increase H. pylori resistance to standard antibiotics such as clarithromycin, and metronidazole has been reported. Therefore, a reduction in triple therapy (proton pump inhibitors (PPI) plus clarithromycin and amoxicillin) treatment success has fallen below 80% for most countries. Escalating resistance to clarithromycin has urged the necessity to identify other treatment options [10–12]. Levofloxacin is a levorotary isomer of ofloxacin with known broad activity against Gram-negative and Gram-positive bacteria [13]. Levofloxacin mode of action is via bacterial type II topoisomerase inhibition, namely DNA gyrase and topoisomerase IV. The potential advantages of levofloxacin-containing triple therapy include the presence of an “in vivo” synergistic effect between quinolone antimicrobial agents and PPIs against H. pylori strains. However, quinolone resistance in H. pylori has been reported to be increasing and could undermine its efficacy [14–20].
The most common mechanism of fluoroquinolone resistance involves mutations in DNA gyrase and in DNA topoisomerase IV. These genes encode large enzymatic quaternary structures that consist of two pairs of subunits: GyrA and GyrB (DNA gyrase) and ParC and ParE (DNA topoisomerase IV). However, H. pylori lacks topoisomerase IV, thus fluoroquinolone resistance is likely due to mutations in the DNA gyrase gene (gyrA), encoding the DNA gyrase subunit A (GyrA) [14–19,21]. The absence of a secondary target for fluoroquinolones suggests a single modification in the gyrA gene could be sufficient to result in a fluoroquinolone-resistant phenotype. The amino acid substitutions observed in clinical strains have been primarily reported at positions 87 (Asn to Lys) and 91 (Asp to Gly, Asp to Asn, or Asp to Tyr) [22,23]. The presence of levofloxacin resistance in levofloxacin-containing therapy has a dramatic detrimental effect on treatment success [18]. Therefore, levofloxacin prescription therapy should be based on local resistance prevalence. The aims of the present study were to determine the rate of primary levofloxacin resistance in H. pylori (prevalence and changes) in patients from Bogotá, Colombia from 2009 to 2014. In addition, we determined gyrA sequence diversity of resistant strains.
Discussion
Cammarota et al. proposed fluoroquinolones, such as levofloxacin as a first line of treatment as an alternative to clarithromycin against H. pylori [13]. In this work, we evaluated changes in the prevalence of “primary” levofloxacin resistance of H. pylori in isolates obtained in Bogotá, Colombia from January 2009 to August 2014. Distribution of patients per year is shown in fig 1, depicting the irregular nature of patient entry, since several other institutions performed endoscopies and did not participate in this study. Although the inclusion of patients was consecutive the referrals to our unit for endoscopy varied over time. In addition, the culture recovery rate for H. pylori from biopsy was more stable (90 to 94%) between 2011 and 2014 (Fig 1). Hence, prevalence of resistance to levofloxacin could be possibly higher than reported in this paper.
During the observation period, levofloxacin resistance significantly increased (p = 0.001) from 11.8% (12/102) in 2009 to 27.3% (21/77) in 2014 (Fig 2). Remarkably, only 14 years after it was introduced as an alternative treatment for H. pylori eradication, levofloxacin resistance increased to the point it was no longer an acceptable choice as an empiric therapy. Indeed, given that patients did not receive previous H. pylori treatment, most likely resistance could be the result of treatment for other infections such as respiratory infections, urinary tract infections, or diarrheal diseases. In addition, it is not possible to document fluoroquinolone consumption in Colombia (dose per 1,000 inhabitants/day) because it is possible to purchase this antibiotic without medical prescription; which allows for self-medication, favoring an increase in resistance. Camargo et al., (2014) study support this hypothesis, where H. pylori resistance to quinolones was reported to be approximately 15% in Latin America [31].
In Colombia the first line of treatment is triple therapy containing metronidazole, clarithromycin or levofloxacin in addition to amoxicillin and proton pump inhibitors for seven days. Various studies performed in Colombia since 1998 have evaluated H. pylori resistance to metronidazole. Since then, resistance to this antimicrobial agent has been reported to be greater than 80% [32]. In contrast, clarithromycin resistance has been reported to be low. A first study in 2007 by Alvarez et al., in the coffee growing region of the country reported a low resistance of 2.2% [33]. These results contrast with those from Bogota, the country’s capital where Trespalacios et al., (2013) reported a 13.6% resistance [34]. In addition, for the south of Colombia Acosta et al., (2014) reported a clarithromycin resistance of 4% [35]. Given these resistance variability’s for clarithromycin and few available studies for the different regions of the country, many gastroenterologists prefer to prescribe clarithromycin in regions where resistance to this antimicrobial is low. In contrast, for Bogota levofloxacin is commonly prescribed for first and second line therapies.
The scheme for second line of treatment mostly used is therapy with levofloxacin or quadruple therapies. However, a Colombian survey revealed physicians don’t follow these recommendations or international guidelines, but in an intuitive manner prescribe different regimens that for the most part have not been previously investigated [36]. However, this is the first study carried-out in Colombia to evaluate H. pylori resistance to levofloxacin in Bogota.
Other countries have also reported an increase in quinolone resistance. A systematic review published in 2010 indicated a global worldwide levofloxacin resistance of 16.2% (95% CI 14.4–18.0) with the highest level of resistance in Europe (24.1%); followed by a mid- resistance level in Asia (11.6%), with differences among Asian countries: Japan (14.9%), Taiwan 11.9% and Hong Kong 2.6% [15]. In addition, recent reports have suggested that prevalence of levofloxacin-resistant H. pylori strains is increasing. A recently steady annual increase has been observed, ranging from 18% up to >30% for Europe and Asia, Italy (18%), Turkey (23.8 to 29.5%), Vietnam (41.3%) and China (Beijing, 54.8%), [37–41]. Based on these findings it is advisable to restrict the empiric use of levofloxacin [42].
Quinolone resistance-determining region mutations in levofloxacin resistant H. pylori isolates had previously been reported. For strains isolated in our study we did not find any correlation between the mutation present and the level of resistance. However, higher levels of resistance were most likely in isolates with N87I and D91G mutations, i.e. with MIC values of 32 μg/mL. Our data agrees with reports from Asia and Europe [14–16]. Two of our susceptible strains had N87I mutations with MICs close to breakpoint (0.5 μg/mL). Conflicting results between genotypic and phenotypic resistance (Table 1) were found in those with gyrA wild-type sequences. 1/4 (25%), of resistant isolates without mutations in gyrA, had the mutation E463K in gyrB, hence this mutation is a candidate explaining isolate resistance. No mutations were identified in gyrB for the other 3/4 (75%) resistant isolates, without mutations in gyrA, (supplementary material). These data suggest the presence of additional resistant mechanisms involved in levofloxacin resistance [16,43]. According Rimbara et al., (2012) results, H. pylori isolates resistant to fluoroquinolones and without gyrA mutations are likely to have mutations in gyrB at positions 463 (supplementary material).
Discordant results were observed in four patients, where no phenotypic resistance was observed in the presence of gyrA sequence mutation (Table 1). These results may be possibly due to the levofloxacin resistance breakpoint used in this study (1 μg/mL). However, other studies describe isolates with gyrA mutations with a MIC of 0.5 μg/mL [44]. Additional studies are needed to correlate MIC and gyrA mutations, in order to obtain an accurate breakpoint for levofloxacin.
Overall, QRDR mutations were most often found at positions 87 and 91, and included N87I, N87K, N87Y, D91G, D91N and D91Y (Table 1). In 75/80 (94%) patients with resistant strains (MIC > 1 μg/mL), mutations occurred in the gyrA gene. This finding is consistent with mutations in gyrA occurrence, as a principal mechanism for levofloxacin resistance. As previously stated, four of our patients with resistant strains (MICs from 1 to 8 μg/mL) did not have a detectable mutation in QRDR of the gyrA gene. Thus, further studies are necessary to identify the resistance mechanism in those strains. As a case in point, Rimbara et al., (2011, 2012) reported gyrB mutations as a potential novel mechanism of resistance to fluoroquinolones in H. pylori [2,43]. However, other still unknown mechanisms could be also involved.
N87I mutation was detected in 43.8% (35/80) of resistant strains followed by D91G with a frequency of 28.8% (23/80) and N87K present in 11.3% (9/80), (Table 1). This distribution is different from that reported in Europe, Asia or Canada (North America), where the major mutation sites were N87K and D91G [14,45]. N87I mutation results from amino acid wild type H. pylori J99 substitution of aminoacid Thr87 to Ileu, with a C to T substitution at codon 87 ACC→ATC [21], (Table 1).
In conclusion, the prevalence of primary resistance to levofloxacin has been increasing in Colombia. Although, levofloxacin resistance was due to point mutation in gyrA, the mutations pattern differed from than reported in Europe. Results from this study evidenced the most common mutation in isolates resistant to levofloxacin was gyrA mutation N87I. This result contrasts with studies performed in France, where the most frequent mutation was N87K, followed by D91N, D91G and D91Y [46]. Mutation N87I has not been reported by the aforementioned studies. In a similar manner studies carried-out in Malaysia and Beijing report the most frequent gyrA mutations were: N87K, D91N, D91G, D91Y [16,47]. These results are different from those reported from Senegal, Africa; where the most common mutation was N87I followed by D91N. Low frequencies were reported for D91G and D91Y [45,48]. These last results agree with the ones reported in our study, where the most frequent mutation was N87I, followed by D91G and N87K. Therefore, it is important to continue performing studies that allow identifying gyrA mutations responsible for fluoroquinolone resistance and the geographical explanation for these differences. Surveillance of quinolone resistance in H. pylori should include assessment of new responsible mutations. The geographical area should be considered, to update the increasingly popular molecular tests.
Materials and Methods
Patients
Adult outpatients referred for gastroscopy at the Gastroenterology Unit of “Clínica Fundadores”, Bogotá D.C., Colombia, between January 2009 and August 2014, both positive for H. pylori rapid urease test (RUT) and histopathology (Giemsa stain) were enrolled. Written informed consent was obtained from each participating patient before enrolling the study. Research protocol was approved by the ethical committee of “Pontificia Universidad Javeriana” and “Clínica Fundadores” in Bogotá D.C., Colombia. Patients were excluded if they were taking PPI or H2-receptor antagonists four weeks prior to enrollment. Since the objective of the study was to assess primary resistance, those with previous anti-H. pylori treatment were also excluded, as were patients with concomitant illness. Biopsies from antrum and body of the stomach underwent bacterial culture and susceptibility testing and DNA extraction.
Bacterial strains, culture conditions, and determination of susceptibility to levofloxacin
Biopsies samples from antrum and body of the stomach were crushed in 0.5 mL PBS and cultured in Wilkins Chalgren Agar (Becton Dickinson, Heidelberg, Germany) containing 7% (v/v) horse blood, vancomycin (10 mg/L) and trimethoprim (5 mg/L). Petri dishes were incubated at 37°C under microaerophilic conditions for up to 14 days. H. pylori growth was confirmed by typical colony morphology, Gram stain, positive oxidase, catalase and urease tests.
Levofloxacin MICs for the recovered H. pylori strains were measured using the agar dilution method according to the guidelines of the National Committee for Clinical Laboratory Standards (CLSI), [49]. The resistance breakpoint was defined as ≥1 μg/mL [50,51]. The agar dilution method was performed by serial two fold dilution, mixing the antibiotic with molten Mueller-Hinton agar II, supplemented with 5% (v/v) sheep blood and 0.4% (v/v) Isovitalex (Becton Dickinson, MD) to reach the desired antibiotic concentration. 1 to 3 μL of a McFarland 2.0 adjusted inoculum were dropped on the surface of the Petri dishes; containing the solid media, followed by 35 ± 2°C for 72 h under microaerophilic conditions. For quality control H. pylori NCTC 11637, was used.
DNA Extraction, PCR Amplification and Nucleotide Sequence Analysis
Genomic DNA of H. pylori strains was extracted using DNAzol® kits (Invitrogen—USA). DNA was stored at -20°C until use. To detect gene mutations in the QRDRs subunit A of the DNA gyrase (gyrA), degenerated oligonucleotide primers reported by Tankovic et al., (2003); 5’-TTT RGC TTA TTC MAT GAG CGT-3’ and 5’-GCA GAC GGC TTG GTA RAA TA-3’ were used. Primers were synthesized by Invitrogen-USA. The size of the amplified fragments of gyrA was 428 bp. The PCR was performed with PCR Master Mix—Promega (WI, USA) using 1.0 μL DNA template, 1.0 pmol/L of each primer, in a final mix reaction volume of 50 μL. The cycling conditions were first 3 minutes at 94°C followed by 35 cycles of 1 min denaturation at 94°C, 1 min annealing at 57°C and 1 min extension at 72°C [52]. PCR products were analyzed by visualizing in 1.5% (w/v) agarose gel electrophoresis, followed by SYBR Green (Invitrogen-USA) staining for 30 minutes. PCR product purification and direct sequencing was performed by Macrogen, Korea. The oligonucleotides used for gyrA PCR were also used for DNA sequencing. The sequences were compared to H. pylori gyrA gene published sequence (GeneBank accession No. L29481). PCR was performed for all strains (susceptible and resistant) and direct sequencing was obtained for all PCR products.
Data Analysis
Frequencies and percentages were used to describe H. pylori antimicrobial isolate resistance. Statistical significances for resistance rates among the different collection years were analyzed by the chi-squared test (χ2) with p < 0.05 considered as statistically significant. Phenotypic susceptibility was evaluated by MIC in μg/mL. Genotypic resistance was determined by the presence or lack of a mutation involved with resistance. Degree of agreement (concordance) between phenotypic and genotypic resistance was performed using Cohen’s kappa coefficient. All statistical analyses were performed using the statistical software package SPSS 18.0 for Windows (SPSS, Chicago, IL, USA).