Genetic diversity of Helicobacter pylori isolates from patients with gastric diseases in Isfahan
Jina Vazirzadeh1, Vajihe Karbasizadeh1, Jamal Falahi2, Sharareh Moghim1, Tahmineh Narimani1, Rahmatollah Rafiei3
1 Department of Microbiology, School of Medicine, Isfahan University of Medical Sciences, Isfahan, Iran
2 Department of Internal Medicine, Najafabad Branch, Islamic Azad University, Isfahan, Iran
3 Health Clinical Sciences Research Center, Zahedan Branch, Islamic Azad University, Zahedan, Iran
|Date of Submission||03-Feb-2021|
|Date of Acceptance||26-May-2021|
|Date of Web Publication||31-Jan-2022|
Dr. Vajihe Karbasizadeh
Department of Microbiology, School of Medicine, Isfahan University of Medical Sciences, Isfahan
Source of Support: None, Conflict of Interest: None
Background: Helicobacter pylori (H. pylori), a spiral-shaped bacterium colonizing the human stomach, is generally acquired in childhood. This pathogen is highly diverse and can be used as genetic markers for predict the history of human migrations. This study aimed to determine the genetic diversity of H. pylori isolates from patients with dyspepsia by the multi-locus sequence typing (MLST) and update data on the prevalence of H. pylori among Iranian dyspeptic patients. Materials and Methods: In this descriptive cross-sectional study, 165 gastric biopsy specimens were obtained from patients with dyspepsia referred to Dr. Shariati Hospital of Isfahan, Iran, from April to July 2018. The status of H. pylori infection was determined by FISH in paraffin-embedded biopsy specimens. MLST of seven housekeeping genes was performed for 20 H. pylori isolates. The phylogenetic tree was plotted using CLC v8 and iTol software. Results: The overall prevalence of H. pylori infection was 53.3%. In the results of the analysis of MLST, a total of 14 new STs were recorded. The results of the global analysis showed that all the isolates, with a wide diversity, have a genetic affinity with members of the European population, such as Italy and Russia, and are in the hpEurope haplotype. Conclusion: Given the high prevalence of H. pylori infection in this region, early and accurate identification of patients seems necessary. Sequence analysis and determination of the origin of the phylogeny of strains can be effective in clinical management and monitoring of risk factors for chronic and recurrence of infection.
Keywords: Helicobacter pylori, multilocus sequence typing, prevalence
|How to cite this article:|
Vazirzadeh J, Karbasizadeh V, Falahi J, Moghim S, Narimani T, Rafiei R. Genetic diversity of Helicobacter pylori isolates from patients with gastric diseases in Isfahan. Adv Biomed Res 2022;11:4
|How to cite this URL:|
Vazirzadeh J, Karbasizadeh V, Falahi J, Moghim S, Narimani T, Rafiei R. Genetic diversity of Helicobacter pylori isolates from patients with gastric diseases in Isfahan. Adv Biomed Res [serial online] 2022 [cited 2023 Jan 27];11:4. Available from: https://www.advbiores.net/text.asp?2022/11/1/4/336921
| Introduction|| |
Helicobacter pylori (H. pylori) is a Gram-negative spiral bacillus isolated from patients with chronic gastritis (CG) by Marshall and Warren in 1984. Infections caused by this bacterium are usually acquired in childhood and can remain asymptomatic for several years. Extensive allelic diversity, genetic variability, mutations, and high recombination are prominent features of this microorganism. H. pylori is naturally competent and can integrate a foreign DNA with homologous recombination into its genome. This feature allows the exchange of genetic matter between different strains living together in a stomach. Therefore, H. pylori is a panmictic species in which no diagnosable strong clonal structure exists. Given that the microorganism has been probably in the human stomach for millions of years, it is considered to have evolved with its host. Therefore, it can be used as a reliable biological marker for the simultaneous evolution of host–pathogen and ancient human migration based on the diversity of sequences at the selected gene site.,
Genetic studies indicate that geographical and climatic contexts affect a high diversity of H. pylori strains. For instance, H. pylori strains of East Asia (Singapore and Korea) are distinct from European strains., Besides, differences in gastric adenocarcinoma, chronic atrophic gastritis, and duodenal ulcers are partly associated with the geographical origins of strains. Despite the high prevalence of infection in Africa and South Asia, the incidence of gastric cancer is much lower in these areas than in other countries, and the malignancies of this infection decrease from North to Southeast Asia. Therefore, genetic studies of H. pylori population are clinically important.,
H. pylori genotyping methods include multi-locus sequence typing (MLST), random amplification of polymorphic DNA, pulsed-field gel electrophoresis, whole-genome sequencing, amplified fragment length polymorphism, and others. MLST is a rapid and reliable method that based on allelic variation using the polymorphism of seven housekeeping genes has the advantages of high repeatability and high resolution and can provide more detailed information on human migration than human genetic analysis to a certain extent. In this technique, the data saved in the central database are accessible via the Internet and provides a potential source for global epidemiological study. However, MLST only reflects the variability of several housekeeping genes and the method is costly.,
H. pylori strains are divided into seven types based on their geographical associations: HpEurope, hpEastAsia, hpAfrica1, hpAfrica2, hpAsia2, hpNEAfrica, and hpSahul., In a study performed in Iran by Farzi et al., the phylogenetic analyses showed that most of the strains fall into distinct clusters and were originally comparable to the ancestry of the hpEurope type. It is estimated that 69% of Iran's population are now hosts of H. pylori. Therefore, the infection caused by this bacterium is a major concern in Iran. Furthermore, Iran is a large country with multiple neighbors and more than 14 diverse ethnic groups and is at the intersection of Europe, Asia, and Africa and it appears that a diverse genetic population of H. pylori strains exists in this country. Studies on the analysis of H. pylori population in the capital of Iran (Tehran) also indicated various alleles in the strains. However, there is no study on molecular typing of H. pylori strains in Isfahan Province, which is located in the center of Iran.
The present study aimed to determine the genetic diversity of H. pylori strains isolated from the adult population of Isfahan Province using the MLST method and update information on the prevalence of gastrointestinal infections caused by the bacterium.
| Materials and Methods|| |
A total of 165 patients with dyspeptic symptoms were referred to the Outpatient Gastroenterology Clinic and Endoscopy Unit in Dr. Shariati Hospital of Isfahan, Iran, as a participating center in the Global Antimicrobial Resistance Surveillance System Project of the World Health Organization. These patients underwent gastric endoscopy between April 2018 and July 2018. Patients with upper abdominal pain, dysphagia, nausea, vomiting, dyspepsia, and gastroesophageal reflux were included in this study. Patients who had received antibiotics, H2-receptor blockers, proton-pump inhibitors, and nonsteroidal anti-inflammatory drugs within 15 days prior to endoscopy were excluded from the study. Clinical findings and detailed epidemiological were determined for each patient. Two antrum and corpus biopsies were obtained from each patient. One set was fixed and transported in 10% buffered formalin for histopathological examination; a second set of biopsies was placed in sterile Eppendorf tubes, containing 1 ml sterile physiological solution (0.9%Nacl), and immediately transported to the microbiology laboratory for H. pylori culturing.,
The biopsy tissues in 10% formalin were processed for histopathology using an automated tissue processor (ATP). Formalin-fixed paraffin-embedded tissue blocks were sectioned using a microtome, cut into 3–4 μm sections, and dewaxed and used for histopathological staining. Slides were stained with H and E and Giemsa by routine protocols. All samples were evaluated independently by two pathologists. In addition, cases of CG were graded according to the grading system provided by Houston-updated Sydney System which was depended on the severity of inflammatory cell infiltration in the lamina propria into four scales as follows:
- Grade 0 – Absent inflammation
- Grade 1 – Mild inflammation
- Grade 2 – Moderate inflammation
- Grade 3 – Severe inflammation.
Determination of Helicobacter pylori infection
H. pylori prevalence was determined by FISH. Briefly, for the hybridization of the samples, each slide of the tissue sections was overlaid with 50 μl of hybridization buffer (0.9 M NaCl, 20 mM Tris-HCl, pH 8, 0.01%SDS, and 20% formamide) containing 5 ng/μl of fluorescein isothiocyanate-labeled oligonucleotide Hpy-1.
Probe Hpy-1 (5-CACACCTGACTGACTATCCCG-3) targeted to a 16S rRNA position was used to specifically identify H. pylori.,
Biopsy specimens were sent to the clinical microbiology lab within half an hour of sampling in sterile tubes. Then, the specimens were homogenized in saline and inoculated on selective medium Columbia Agar (Gibco, USA) supplemented with 7% sheep blood and 10% fetal calf serum (FCS) and H. pylori selective supplement (DENT) (Oxoid). The plates were incubated for 5–10 days at 37°C in a microaerophilic environment (Anoxomat; MART Microbiology BV, Drachten, The Netherlands). H. pylori was identified based on colony morphology, Gram stain as a gull wing-shape bacteria, and also by positive reactions for oxidase, catalase, and strong urease activity. The strains were then stored in brain heart infusion broth with 30% glycerol and 7% FCS at −70°C until molecular typing was performed.
Multi-locus sequence typing analysis
After the recovery of strains in liquid medium BHI and culturing on Columbia agar, one or more single colonies were isolated from each of 20 patients and used for MLST analysis. The criterion for selecting isolates for MLST was pathology findings of patients. The characteristics of these strains are shown in [Table 1].
|Table 1: Characteristics of strains for phylogenetic analysis used in this study|
Click here to view
DNA was extracted using a DNA extraction kit NucleoSpin Microbial (MACHEREY-NAGEL, Germany) according to the manufacturer's instructions. The isolates were further confirmed as H. pylori using PCR amplification of an ureC (glmM) fragment. PCR was performed as described by Nafisi et al. The presence of the cagA gene was determined by cagA PCR. PCR conditions have been previously reported. The primers are listed in [Table 2].
|Table 2: Primers used for the amplification of Helicobacter pylori genes|
Click here to view
For phylogeographic, typing the seven standard MLST genes (atpA, efp, mutY, ppa, trpC, ureI, and yphC) were amplified for each strain. Primer pairs were purchased from Metabion, Munich, Germany [Table 3]. Each PCR product was purified and then sequenced by the Sanger method (micro synth-Swiss) using forward and reverse primers.
|Table 3: Primer sequences used for polymerase chain reaction amplification and sequencing of the seven housekeeping genes for Helicobacter pylori and expected product sizes for each reaction|
Click here to view
All chromatograms were analyzed and edited using Chromas software (Version 2.6.5) Technelysium Pty Ltd (http://www.technelsium.com au). Then, the sequences were submitted to the H. pylori MLST database (http://pubmlst. org/Helicobacter) for allele and sequence type identification. The allele numbers assigned to each of the seven genes for each isolate were recorded in the MLST profile, and the sequence types for each isolate were determined. The phylogenetic three of 20 Iranian H. pylori isolates based on concatenated nucleotide sequences of 7 gene loci were constructed using the Neighbor-Joining algorithm implemented in CLC Sequence Viewer 8 (http://www. clcbio. com). Then, 25 isolates were selected and a phylogenetic tree was created to compare Iranian isolates with Asian countries in iTol software (https://pubmlst. org/helicobacter/). To analyze the population structure and determine the relatedness of Iranian H. pylori to worldwide populations, 103 sequences from hpEurope, hpEastAsia, hpAfrica2, hspWAfrica1, hpSahul, hpNEAfrica, and hpAsia2 strains were selected. Bootstrap analysis was performed with 1000 replications, and Phylogenetic tree was edited by using iTol software. Analyses were performed in SPSS version 20.
| Results|| |
Prevalence of Helicobacter pylori infection
A total of 165 patients, including 84 males and 81 females, enrolled in this cross-sectional study. The mean age was 50.3 ± 15.5 years old with the age ranging between 15 and 83 years. Eighty-eight of 165 patients (53.3%) were diagnosed as H. pylori positive by FISH. Among 88 H. pylori positive patients, 81 (49%) were positive by histology. By culture, 83 (50.3%) patients were positive. Agreement was found between the results of the diagnostic tests (P < 0.001).
In gastric biopsies, gastritis was found in 155 cases (94%), of which 86 (52.1%) patients were identified as CG, 36 (21.8%) as chronic active gastritis, 31 (18.8%) as erosive gastritis (EG), and 2 (1.2%) gastric cancer. Pathological changes such as intestinal metaplasia in 6 patients with CG were also observed. The most common type of inflammation was Grade 1 (43.6%). The results are shown in [Figure 1]. H. pylori colonization was seen in 81 biopsies.
|Figure 1: The frequency of grading the severity of inflammation of the samples studied, according to the Sydney System|
Click here to view
Identified alleles and nucleotide diversity of the housekeeping genes
Among the 83 H. pylori strains recovered from cultured biopsy specimens, 20 strains were used for molecular typing. MLST showed that 77 new alleles were identified for the genes included in the scheme. These were distributed as follows: 13 new alleles for the gene atpA, 9 for efp, 11 for mutY, 11 for ppa, 13 for trpC, 7 for ureI, and 13 for yhpC. The highest allelic diversity was in the three genes, trpC, atpA, and yphC and the lowest in the ureI gene. In three of the 20 isolates (15%), all seven alleles sequenced were described for the first time. The allelic profile for each isolate indicates that each of the 20 sequence types is unique and not previously described in the MLST database [Table 4]. This new sequences were uploaded to the H. pylori Public MLST Database (http://pubmlst. org/helicobacter/) [Supplementary Files] [Additional file 1].
Population structure and phylogenetic analysis
A phylogenetic tree was constructed based on sequence datasets obtained from the seven housekeeping genes of 20 Iranian H. pylori strains in software CLC Sequence Viewer 8. The isolates recorded in this study were clustered into three groups. In the first cluster, only one ST was observed, in the second cluster, 15 STs, and in a third of the cluster, 4 STs were observed [Figure 2]. The Simpson 'Diversity Index 77% was calculated.
|Figure 2: Analysis of MLST 20 Isolated Iranian Helicobacter pylori. Phylogenetic tree using neighbor-joining-tree algorithm in software Viewer 8 CLC Sequence been plotted|
Click here to view
In [Figure 3], the isolates of this study were compared to those of the neighboring countries of Iran in the iTol software. The phylogenetic analyses revealed that 45% of the Iranian H. pylori strains were clustered together with the isolates from Turkey, Saudi Arabia, Palestine, and Lebanon. The other isolates were clustered into five other groups.
|Figure 3: Phylogenetic analysis of 20 isolated Iranian Helicobacter pylori isolates with 25 isolates from neighboring Asian countries using data from 7 housekeeping genes in the iTol software|
Click here to view
The results of the global analysis of the H. pylori sequences of different geographical regions and ethnic groups different from other populations and Iranian isolates indicated that these strains were comparable to European ancestors and fell into the hpEurope haplotype containing isolates from Russia and Italy [Figure 4].
|Figure 4: Global analysis of 20 Iranian isolates with103 strains from other countries using 7 housekeeping genes in the iTol Software based on population structure of isolates (H. pylori strains of Isfahan are red)|
Click here to view
CagA is one important H. pylori virulence factor secreted by the type IV secretion pathway. Seventeen Isfahan strains (%85) were cagA-positive strains.
| Discussion|| |
H. pylori has been reported from all over the world, and it plays an important role in the development of upper gastrointestinal tract diseases. In the present study, the prevalence of H. pylori in patients with gastrointestinal symptoms in Isfahan was 53.3%.
The prevalence of H. pylori infection in Iran is relatively high and varied in terms of geographical distribution, which is reported from 40% to 90% in different regions (south to north of Iran). In one study conducted in western Iran, the prevalence of positive cases was reported to be 71% that was higher than previously published data. Bayati et al. isolated H. pylori in biopsy specimens of 32% of participants by the culture method in Tehran. Studies indicate the existence of various H. pylori infections in different countries. The highest rate belonged to Nigeria (89.7%), and the lowest rate was for Yemen (8.9%). In general, the infection was more common in developing countries (50.8%) than in developed countries (34.7%). Various factors such as health and socioeconomic conditions and even the lack of effective methods for purification of drinking water in some regions as well as the transmission to humans due to the reuse of treated water for agricultural purposes, livestock and industry in arid and semi-arid areas in the world, like Iran, can be the justification for the disease at a younger age in this geographical region. However, more research is needed to determine whether changes in the prevalence of H. pylori infection affect the global burden of upper gastrointestinal diseases.
Determination of the genetic characteristics of pathogenic microorganisms plays a crucial role in understanding the epidemiology of infectious diseases in the development of diseases. Countries with ethnically diverse populations provide us with a good opportunity to learn more about the structure of H. pylori populations., Iran is a vast country with diverse ethnic groups (a combination of ethnicities, including Kurds, Lors, Fars, Gilaks, Arabs, and Azeris) and is located at the intersection of Europe, Asia, and Africa. Ethnic and geographical diversity in Iran is a reflection of historical interaction with other populations. For instance, the Arab population of Iran entered the country in the 7th and 8th centuries AD during the victory of Islam over the Iranian Empire. The Kurdish population in northwestern Iran has historical ties with Turkish Kurds and other Turks throughout history, including the Ottoman Empire and World War I. In the present study, there was a genetic similarity between H. pylori isolated from the Iranian population and similar geographical species in neighboring countries such as Turkey and Kazakhstan. Genetic similarity existed between isolates from Iran and the isolates in Palestine, Lebanon, Russia, and Saudi Arabia. The finding was consistent with one study conducted by Latifi-Navid et al. in Iran and could reflect continuous historical contacts over the years.
The gastrointestinal infections caused by this bacterium in the incidence of gastric cancer, as the deadliest type of cancer in Iran, are estimated to be 75%–80%. It has been found that the frequency of gastric ulcers and cancer is considerably influenced by geographical conditions and ethnic groups. Throughout history, Iran has had a population of diverse ethnic groups. Therefore, the probability of transmission of DNA between strains of different genotypes may be higher in the country than in other countries. In the present study, the genetic analysis of H. pylori by MLST indicated that strains had panmictic structures, and no clonal structure was observed. Horizontal gene transfers and repeated recombination can lead to extensive genetic rearrangement. H. pylori appears to have a clonal structure only in short periods, such as a change from one host to another. However, the evidence suggests that mutations may play roles in the genetic diversity of H. pylori.
In the present study, most alleles were first recorded in Pub MLST, and thus, the isolates had different STs probably due to the occurrence of extensive single-nucleotide polymorphisms, homologous recombination, and the emergence of pseudogenes through homopolynucleotide mutations in the genome. The MLST analysis indicated that the ureI gene was the most common allele among the Iranian H. pylori. In one study on the Malay population by Tai et al., trpC was the most diverse gene in all patients, except for the Chinese population of Malaysia with the highest diversity of approximately 7.6%, while the lowest gene diversity belonged to atpA with 2.6%. On the contrary, based on the sequence analysis of MLST in the data set obtained from this study, three genes, atpA, yphC, and trpC, showed the greatest diversity than the other genes did.
In a study performed in Iran by Farzi et al., 38% of the Iranian H. pylori strains were similar in at least three gene loci and the ureI gene as the most identical allele among Iranian H. pylori strains. The difference between H. pylori isolates may be for various reasons such as chromosome rearrangement, point mutations in protected genes, and the presence of unprotected genes like cagA.
de Sablet et al. conducted one study investigating the roles of phylogenetic origins of strains as determinants of gastric cancer risk in cagA-positive patients in two high-risk and low-risk regions for gastric cancer in Colombia. They found that hpEurope-dependent and hpAfrica1-dependent strains were in the high-risk and low-risk regions of stomach cancer, respectively. People infected with hpEurope strains had more advanced histological lesions and further damage to the DNA of the stomach epithelial cells. Therefore, the ancestral origin of strains was introduced as a strong predictor of gastric cancer risk.
In this study, the relationship between the etiology of phylogeny and clinical results could not be examined owing to the small number of strains used in the analysis of MLST and the uncertainty of people with high risk and low risk of gastric cancer; however, a global analysis of 103 strains of the H. pylori reference from 7 phylogenetic populations indicated that strains isolated from Isfahan were in the hpEurope type population. Latifi-Navid et al. reported findings similar to our study results by evaluating the H. pylori species isolated from different geographical regions of Iran. In the current study, among 20 isolates, 14 new STs not previously recorded in the MLST database were reported, demonstrating the high level of recombination between the isolated strains. In line with our study, Alvandi et al. suggested that the H. pylori populations have no clonal structure and all strains isolated from Kermanshah close to the population of Spain–Estonia belonging to the hpEurope. Latifi-Navid et al. in 2010 reported that sequence types were close to strains isolated from Europe–Western Asia which confirms the findings of the current study.
It is recommended that more extensive studies be conducted among different geographical populations in Iran to study the genetic diversity and find the relationship between the geographical origins of strains and the severity of H. pylori pathogenesis.
However, the typing of H. pylori population can be utilized as a useful tool to map human migration patterns and highlight the roles of ancestral origins in the development of gastric cancer.
| Conclusion|| |
The present study results indicated that the prevalence of H. pylori infection was high in patients with gastrointestinal symptoms in Isfahan. Therefore, it is important to adopt rapid, reliable, and cost-effective diagnostic methods in these geographical regions. Typing of the strains selected in the present study indicated that the isolates were in the hpEurope population. Determination of the phylogeny source of H. pylori strains may provide a useful strategy for clinical management, including the intensification of eradication programs and monitoring of the risk factors for gastric cancer caused by this infection.
The study was approved by the Research Ethics Committee of the Isfahan University of Medical Sciences (No: IR. Mui. rec. 1396.3.878), Isfahan, Iran.
Financial support and sponsorship
This study was supported by the Department of Microbiology, Faculty of Medicine, Isfahan University of Medical Sciences, Isfahan, Iran, Grant no. 127639.
Conflicts of interest
There are no conflicts of interest.
| References|| |
Ahmed F, Ahmed J, Ahmed H. Advances in research progress of H. pylori
. JPRI 2018;21:1-8.
Aftab H, Miftahussurur M, Subsomwong P, Ahmed F, Khan AKA, Matsumoto T, et al.
Two populations of less-virulent Helicobacter pylori
genotypes in Bangladesh. PLoS One 2017;12:e0182947.
Ailloud F, Didelot X, Woltemate S, Pfaffinger G, Overmann J, Bader RC, et al.
Within-host evolution of Helicobacter pylori
shaped by niche-specific adaptation, intragastric migrations and selective sweeps. Nat Commun 2019;10:2273.
Farzi N, Sayadi S, Shokrzadeh L, Mirzaei T, Zojaji H, Yadegar A. Analysis and comparison of the phylogenetic diversity within Helicobacter pylori
isolates from iranian and global populations by multi-locus sequence typing. Arch Clin Infect Dis 2019;14:22-8.
Hanafiah A, Lopes BS. Genetic diversity and virulence characteristics of Helicobacter pylori
isolates in different human ethnic groups. Infect Genet Evol 2020;78:104135.
Shiota S, Suzuki R, Matsuo Y, Miftahussurur M, Tran TT, Binh TT, et al. Helicobacter pylori
from gastric cancer and duodenal ulcer show same phylogeographic origin in the Andean region in Colombia. PLoS One 2014;9:e105392.
de Sablet T, Piazuelo MB, Shaffer CL, Schneider BG, Asim M, Chaturvedi R, et al.
Phylogeographic origin of Helicobacter pylori
is a determinant of gastric cancer risk. Gut 2011;60:1189-95.
Bie M, Wen J, Wang H, Zhou L, Yang L, Pan Y, et al.
Phylogenetic analysis of clinical strains of Helicobacter pylori
isolated from patients with gastric diseases in Tibet. Ann Transl Med 2019;7:320-9.
Keikha M. Ancestral European Origins and Population Structure of Helicobacter pylori
Strains from an Iranian Population. J Genet Genome Res 2020;7:049.
Matsunari O, Shiota S, Suzuki R, Watada M, Kinjo N, Murakami K, et al.
Association between Helicobacter pylori
virulence factors and gastroduodenal diseases in Okinawa, Japan. J Clin Microbiol 2012;50:876-83.
Breurec S, Raymond J, Thiberge JM, Hem S, Monchy D, Seck A, et al.
Impact of human migrations on diversity of Helicobacter pylori
in Cambodia and New Caledonia. Helicobacter 2013;18:249-61.
Alvandi AH, Abiri R, Ahmadi-Jouybari T, Souri N. Genetic diversity of Helicobacter pylori
strains isolated from patients with gastroduodenal diseases using multilocus sequence typing in Kermanshah. Jundishapur J Microbiol 2019;12:1-11.
Latifi-Navid S, Ghorashi SA, Siavoshi F, Linz B, Massarrat S, Khegay T, et al.
Ethnic and geographic differentiation of Helicobacter pylori
within Iran. PLoS One 2010;5:e9645.
Demiray-Gürbüz E, Yılmaz Ö, Olivares AZ, Gönen C, Sarıoğlu S, Soytürk M, et al.
Rapid identification of Helicobacter pylori
and assessment of clarithromycin susceptibility from clinical specimens using FISH. J Pathol Clin Res 2017;3:29-37.
Ramis IB, de Moraes EP, Fernandes MS, Mendoza-Sassi R, Rodrigues O, Juliano CR, et al.
Evaluation of diagnostic methods for the detection of Helicobacter pylori
in gastric biopsy specimens of dyspeptic patients. Braz J Microbiol 2012;43:903-8.
Bamanikar S, Khandelwal A, Shah K. Detection of Helicobacter pylori
in gastric biopsies of patients with chronic gastritis: Histopathological and immunohistochemical study. Int J Med Sci Public Health 2018;8:39-47.
Vazirzadeh J, Falahi J, Moghim S, Narimani T, Rafiei R, Karbasizadeh V. Molecular assessment of resistance to clarithromycin in Helicobacter pylori
strains isolated from patients with dyspepsia by fluorescent in situ
hybridization in the center of Iran. Biomed Res Int 2020;2020:2304173.
Bińkowska A, Biernat MM, Łaczmański Ł, Gościniak G. Molecular patterns of resistance among Helicobacter pylori
strains in South-Western Poland. Front Microbiol 2018;9:3154.
Nafisi MR, Karimi A, Rahimian G, Fooladi A. PCR and RFLP of ureC (glmM) gene for identification and typing of Helicobacter pylori
strains isolated from gastric biopsy specimens of gastric patients. Trauma Monthly 2009;14:44-9.
Essawi T, Hammoudeh W, Sabri I, Sweidan W, Farraj MA. Determination of Helicobacter pylori
virulence genes in gastric biopsies by PCR. ISRN Gastroenterol 2013;2013:606258.
Harrison U, Fowora MA, Seriki AT, Loell E, Mueller S, Ugo-Ijeh M, et al. Helicobacter pylori
strains from a Nigerian cohort show divergent antibiotic resistance rates and a uniform pathogenicity profile. PLoS One 2017;12:e0176454.
Gutiérrez-Escobar AJ, Trujillo E, Acevedo O, Bravo MM. Phylogenomics of colombian Helicobacter pylori
isolates. Gut Pathog 2017;9:2-9.
de Brito BB, da Silva FAF, Soares AS, Pereira VA, Santos ML, Sampaio MM, et al.
Pathogenesis and clinical management of Helicobacter pylori
gastric infection. World J Gastroenterol 2019;25:e5578.
Abadi AT. Helicobacter pylori
infection in Iran: A new perspective. J Gastroenterol Hepatol 2014;3:1181-5.
Alizadeh AH, Ansari S, Ranjbar M, Shalmani HM, Habibi I, Firouzi M, et al.
Seroprevalence of Helicobacter pylori
in Nahavand: A population-based study. East Mediterr Health J 2009;15:129-35.
Bayati S, Amirmozafari N, Alebouyeh M, Farzi N, Ebrahimi Daryani N, Zali MR. Antibiotic resistance among Helicobacter pylori
strains isolated from patients with histopathological changes of the gastric tissue towards metronidazole, clarithromycin, and ciprofloxacin. Arch Clin Infect Dis 2019;14:e55015.
Zamani M, Ebrahimtabar F, Zamani V, Miller W, Alizadeh-Navaei R, Shokri-Shirvani J. Systematic review with meta-analysis: The worldwide prevalence of Helicobacter pylori
infection. Aliment Pharmacol Ther 2018;47:868-76.
Yamaoka Y. Helicobacter pylori
typing as a tool for tracking human migration. Clin Microbiol Infect 2009;15:829-34.
Ono T, Cruz M, Jiménez Abreu JA, Nagashima H, Subsomwong P, Hosking C, et al.
Comparative study between Helicobacter pylori
and host human genetics in the Dominican Republic. BMC Evol Biol 2019;4:191-12.
Tay CY, Mitchell H, Dong Q, Goh KL, Dawes IW, Lan R. Population structure of Helicobacter pylori
among ethnic groups in Malaysia: Recent acquisition of the bacterium by the Malay population. BMC Microbiol 2009;9:126.
[Figure 1], [Figure 2], [Figure 3], [Figure 4]
[Table 1], [Table 2], [Table 3], [Table 4]