C. Figueiredo, Instituto de Patologia e Imunologia Molecular da Universidade do Porto (IPATIMUP), Porto, Portugal, and Delft Diagnostic Laboratory, Delft, The Netherlands; J. C. Machado, R. Seruca, IPATIMUP, and Faculty of Medicine, University of Porto, Porto; P. Pharoah (Departments of Oncology and Public Health), C. Caldas (Department of Oncology), University of Cambridge, Cambridge, U.K.; S. Sousa, R. Carvalho, IPATIMUP, Porto; A. F. Capelinha, Hospital S. João, Porto; W. Quint, L.-J. van Doorn, Delft Diagnostic Laboratory, Delft; F. Carneiro, M. Sobrinho-Simões, IPATIMUP, Porto, Faculty of Medicine, Porto, and Hospital S. João, Porto.
Correspondence to: Céu Figueiredo, Ph.D., IPATIMUP, Rua Dr Roberto Frias s/n, 4200-465 Porto, Portugal (e-mail: cfigueiredo{at}ipatimup.pt).
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ABSTRACT |
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INTRODUCTION |
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H. pylori are genetically highly diverse bacteria, and several genotypes have been associated with virulence and gastric disease risk (5,6). The vacA gene, which encodes a vacuolating cytotoxin, is present in all H. pylori strains. This gene comprises two variable regions (7): the s region, which exists as an s1a, s1b, s1c, or s2 allele, and the m region, which occurs as an m1, m2a, or m2b allele (8). H. pylori vacA type s1 strains appear to be more virulent than type s2 strains and are associated with higher risks for peptic ulcer disease, gastric atrophy, and gastric carcinoma (9,10). The vacAs1 and vacAm1 strains are also strongly associated with a higher degree of inflammation and epithelial damage in the gastric mucosa (11,12).
The H. pylori cagA gene is a marker for the presence of the cag pathogenicity island (PAI) (13). The CagA protein is translocated by a type IV secretion system (encoded by the cag PAI) into gastric epithelial cells, where it induces changes in the tyrosine phosphorylation states of distinct cellular proteins (14). Several genes of the cag PAI encode proteins that increase the production of the pro-inflammatory interleukin 8 (IL-8) by the gastric epithelium (15). There is an association between infection with cagA-positive strains and risk for peptic ulcer disease (7,9), and for development of atrophic gastritis and carcinoma of the stomach (10,11,16,17).
Human genetic polymorphisms also appear to play a role in the disease susceptibility of the host. Recently, polymorphisms of the interleukin 1 beta (IL-1B) gene and the IL-1 receptor antagonist gene (IL-1RN) have been associated with an increased risk of both hypochlorhydria and gastric carcinoma (18,19). IL-1B encodes IL-1, a potent pro-inflammatory cytokine and powerful inhibitor of gastric acid secretion that plays a major role in initiating and amplifying the inflammatory response to H. pylori infection (20,21). A polymorphic allele with a T instead of a C at position 511 of the regulatory region of the IL-1B gene (IL-1B-511*T) is associated with increased IL-1
production (18). IL-1RN encodes the IL-1 receptor antagonist (IL-1ra), an anti-inflammatory cytokine that competitively binds to IL-1 receptors, and thereby modulates the potentially damaging effects of IL-1 (22). The IL-1RN gene has a variable number of tandem repeats in intron 2, resulting in a short allele (IL-1RN*2, with two repeats) or long alleles (IL-1RN*L, with three to six repeats). The IL-1RN*2 allele is associated with increased IL-1b production (23,24). H. pylori infection in individuals with these alleles may therefore result in increased production of gastric IL-1b, leading to severe and sustained inflammation, gastric atrophy, and hypochlorhydria, and ultimately to the development of gastric carcinoma (18,25).
In this study we investigated whether there are combinations of bacterial and host genotypes that are highly associated with the occurrence of gastric carcinoma. Our aim was to relate H. pylori vacA and cagA virulence-associated genes and human IL-1B and IL-1RN susceptibility polymorphisms with the histopathologic features of gastritis and the risk for development of gastric carcinoma.
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MATERIALS AND METHODS |
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In total, 443 subjects were analyzed: 221 subjects with chronic gastritis and 222 with gastric carcinoma. Subjects with chronic gastritis (mean age = 43 years, median age = 43 years, range = 2462 years, and male/female ratio of 13 : 1) were recruited from a group of shipyard workers and underwent standard gastroscopy in 1998 at the Hospital de S. João (Porto, Portugal) during a screening program for premalignant lesions of the gastric mucosa. Only individuals without evidence of past or present peptic ulcer disease were included. Patients with gastric carcinoma (mean age = 62 years, median age = 63 years, range = 2690 years, and male/female ratio of 1.7 : 1) were diagnosed and underwent resection of cancer at the Hospital S. João/Medical Faculty and Instituto de Patologia e Imunologia Molecular da Universidade do Porto (IPATIMUP), Porto, Portugal. The cancers included 119 (53.6%) antral, 50 (22.5%) corpus, 4 (1.8%) fundus, and 39 (17.6%) cardia carcinomas. In 10 (4.5%) case patients, the tumors involved more than one anatomic region of the stomach. All procedures followed in the study were in accordance with the institutional ethical standards. All samples were delinked and unidentified from their donors. All individuals provided written informed consent.
Histopathology
Biopsy specimens from the antrum and corpus mucosa of chronic gastritis subjects and gastric carcinoma surgical specimens were formalin fixed, paraffin embedded, and stained with hematoxylineosin, Alcian blueperiodic acid-Schiff, and modified Giemsa. All 221 subjects with chronic gastritis had antral biopsy specimens but only 219 had corpus biopsy specimens available. All the available samples were accepted for histologic assessment. H. pylori density, chronic inflammation, polymorphonuclear activity, epithelial damage, glandular atrophy, and intestinal metaplasia were scored according to the updated Sydney system (26). Inflammation and activity scores were added, as previously described (27), for a combined (acute and chronic) inflammatory score with a maximum possible value of 6. Gastric carcinoma case patients were classified according to Lauréns classification (28) as intestinal (n = 116), diffuse (n = 52), or atypical (n = 54) carcinomas. Histologic slides were examined by two experienced pathologists (F. Carneiro and M. Sobrinho-Simões), blinded to the clinical information of the patients.
DNA Isolation
DNA was extracted from gastric antral biopsy specimens using the method described by Boom (29). Briefly, biopsy specimens were homogenized in guanidinium isothiocyanate with a sterile micropestle. DNA was captured onto silica particles, washed, and then eluted in 100 µL of 10 mM TrisHCl (pH 8.3). DNA from non-neoplastic gastric mucosa of gastric carcinoma surgical specimens was isolated using a standard phenol/chloroform extraction procedure.
H. pylori vacA and cagA Genotyping
H. pylori DNA that was extracted from either gastric antral biopsies or surgical specimens was used for vacA and cagA genotyping. Two hundred eighteen (98.6%) of the 221 chronic gastritis subjects and 130 (58.6%) of the 222 carcinoma case subjects had material available for H. pylori genotyping. Genotyping was performed by multiplex polymerase chain reaction (PCR) followed by reverse hybridization on a line probe assay (LiPA), as described (8,30). Genotypes were obtained for all case subjects for the vacA s region and for 339 (97.4%) of the case subjects for the m region.
IL-1B-511 and IL-1RN Variable Number Tandem Repeats Genotyping
Two hundred seventeen (98.2%) chronic gastritis subjects and 221 (99.5%) carcinoma case subjects were genotyped for the IL-1B-511 polymorphism, and all subjects were genotyped for IL-1RN variable number tandem repeats (VNTR) in intron 2. The IL-1B-511*C/IL-1B-511*T bi-allelic polymorphism was genotyped by PCRSSCP (polymerase chain reactionsingle-strand conformation polymorphism), and the IL-1RN penta-allelic VNTR was genotyped by PCRstandard agarose gel electrophoresis, as previously described (19). The IL-1RN alleles were coded as follows: allele 1 = four repeats, allele 2 = two repeats, allele 3 = five repeats, allele 4 = three repeats, and allele 5 = six repeats. For the purpose of statistical analysis and because of the rarity of alleles 3, 4, and 5, this polymorphism was treated as bi-allelic by dividing alleles into short and long (L) categories; those in the short allele category are those with two repeats (allele 2), and those in the long allele category are those with three or more repeats (alleles 1, 3, 4, and 5) (19). Genotype notation is as follows: C homozygote = IL-1B-511*C/*C, T carrier = IL-1B-511*T/*T or IL-1B-511*T/*C, L carrier = IL-1RN*L/*L or IL-1RN*L/*2, and 2 homozygote = IL-1RN*2/*2.
Statistical Analysis
Differences in combined inflammatory score and gastric bacterial colonization density among different genotypes were evaluated with the MannWhitney test. Associations between genotypes and the presence of epithelial damage, glandular atrophy, and intestinal metaplasia were assessed by the 2 test. Only subjects containing single H. pylori genotypes were included in the analyses of the histopathologic features of gastritis. Associations between bacterial genotypes and host genotypes and comparison of genotype frequencies between carcinoma patients and gastritis control subjects were assessed by the
2 test. Comparison of genotype frequencies between groups defined by age, sex, anatomic site, and histologic type was performed by the
2 test. The control group consisted of 136 individuals with no evidence of glandular atrophy or intestinal metaplasia. These 136 individuals were a subset of the 221 chronic gastritis subjects. Odds ratios (ORs) with 95% confidence intervals (CIs) and unconditional logistic regression models were computed with SPSS software (version 9; SPSS Science, Chicago, IL). Differences were considered statistically significant when P<.05. All statistical tests were two-sided.
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RESULTS |
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In patients with gastritis, H. pylori vacAs1-, vacAm1-, and cagA-positive genotypes were each associated with higher combined inflammatory scores in corpus and antrum (Table 1). Statistically significant associations were also shown, both in corpus and in antrum, between the same H. pylori genotypes and active and chronic inflammatory scores when both parameters were examined independently.
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Individuals who were IL-1B-511*T carriers and homozygous for IL-1RN*2 had a more marked corpus gastritis and a higher corpus H. pylori density than IL-1B-511*C homozygotes/IL-1RN*L carriers (Table 1). IL-1B-511*T carriers/IL-1RN*2 homozygotes also had a high risk of epithelial damage in both corpus and antrum (Fig. 1, B
). These individuals also had a higher risk of glandular atrophy and intestinal metaplasia (Fig. 2, A and B
).
H. pylori and IL-1B/IL-1RN Genotypes in Gastric Carcinomas Compared With Gastritis
To explore the effect of H. pylori strains on gastric disease phenotype and to assess the nature of any interaction with IL-1B/IL-1RN genotypes, we compared the strain and genotype data in the patients with gastric carcinoma with those data in the 136 individuals who had gastritis without evidence of glandular atrophy or metaplasia. Information regarding H. pylori strain was not available for the disease-free control group, and individuals with atrophic gastritis or intestinal metaplasia were excluded because of the well-documented association of these histologic features with gastric carcinoma.
Among individuals infected with single H. pylori vacAs and vacAm strains, vacAs1 and vacAm1 strains were statistically significantly more prevalent in patients with gastric carcinoma (92% [98/107] and 69% [68/98], respectively) than in subjects with non-atrophic gastritis (39% [39/101] and 25% [27/107], respectively), with ORs and 95% CIs for developing gastric carcinoma of 17 (7.8 to 38) and 6.7 (3.6 to 12), respectively (Table 2). cagA-Positive strains were also statistically significantly more prevalent in gastric carcinoma patients (91% [118/130]) than in non-atrophic gastritis subjects (40% [54/135]), with an OR (95% CI) for gastric carcinoma of 15 (7.4 to 29) (Table 2
).
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In the gastric carcinoma patients, IL-1B-511*T carriers represented 69% (152/221) of the case subjects, which is statistically significantly higher than the proportion of this genotype in the non-atrophic gastritis group (55%) with an OR of 1.8 (95% CI = 1.2 to 2.8) (Table 3). The observed association between IL-1RN VNTR genotype and the risk of gastric carcinoma was not statistically significant. Genotype frequencies did not vary by sex or age in either control subjects or gastric carcinoma case patients.
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To assess the nature of the interaction between the high-risk bacterial and host genotypes, we compared the combined bacterial/host genotype frequencies in gastritis control subjects with those in case patients with gastric carcinoma (Tables 5 and 6). For each combination, the odds of having gastric carcinoma were greatest in those with high-risk genotypes in both the bacteria and the host. The highest risk was seen in IL-1B-511*T carriers infected with H. pylori of the vacAs1 genotype (Table 5
). Such individuals represented 66% of the gastric carcinoma patients (71/107), although they made up only 22% of individuals with non-atrophic gastritis (22/101). Deviation from a multiplicative interaction model, which assumes independent effects for each risk factor, was assessed by including an interaction term in an unconditional logistic regression model. No interaction term was statistically significant, suggesting that the effects of the bacterial and host genotypes are independent. Subject numbers were too small to assess possible three-way interactions.
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DISCUSSION |
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It has been shown recently that specific genotypes of the IL-1B and IL-1RN genes increase the likelihood of hypochlorhydria and the development of gastric carcinoma (18,19). We confirmed that these pro-inflammatory genotypes (IL-1B-511*T carriers/IL-1RN*2 homozygotes) are statistically significantly more prevalent among patients with gastric carcinoma than among subjects in a control group with gastritis only. We observed an increased risk for gastric carcinoma in IL-1B-511*T allele carriers who are homozygous for the IL-1RN*2 allele, with an OR of 3.3. We have also shown that IL-1B-511*T carriers/IL-1RN*2 homozygotes have more severe gastritis, i.e., higher combined inflammatory score in the corpus, epithelial damage in both corpus and antrum, and presence of glandular atrophy. These results provide indirect evidence of the increased pro-inflammatory effect associated with the IL-1B-511*T and IL-1RN*2 alleles. Moreover, the association between higher inflammatory scores in the corpus and pro-inflammatory IL-1 genotypes fits in with the pattern of gastritis typically associated with H. pylori-induced gastric carcinogenesis, i.e., gastritis involving the acid-secreting corpus leading to hypochlorhydria, gastric atrophy, and increased risk of gastric carcinoma (31). In contrast, gastritis confined to the antral region is associated with excessive acid production and higher risk of duodenal ulcer disease (31).
Analysis of the combined bacterial and host genotypes showed that, for each combination, the odds of having gastric carcinoma were greatest in those individuals with both the bacterial and the host high-risk genotypes. IL-1B-511*T carriers infected with vacAs1-, vacAm1-, and cagA-positive strains were found to have increased risk for developing gastric carcinoma, with ORs of 87, 7.4, and 25, respectively. IL-1RN*2 homozygotes infected with vacAs1-, vacAm1-, and cagA-positive strains also had increased risk for developing gastric carcinoma, with ORs of 32, 8.8, and 23, respectively. Statistical analysis did not reveal any significant interaction between these two groups of factors, suggesting that the risks for developing gastric carcinoma conferred by the H. pylori and IL-1 genotypes are independent. However, given our sample size, our power to detect a small interaction was low. The analysis of the distribution of H. pylori vacA and cagA genotypes and human IL-1 polymorphisms in subjects with gastritis and/or in patients with gastric carcinoma showed no statistically significant associations, which indicates that there is no preferential colonization of specific hosts (as defined by these IL-1 polymorphisms) by specific bacterial strains.
Our results support the hypothesis that the extent of gastric mucosal injury may be related to H. pylori strain differences, inflammatory responses governed by host genetics, and interactions between host and bacterial determinants (4). The combination of these factors, favoring a set of responses with higher magnitude, can eventually result in hypochlorhydria, corpus atrophy, and an increased risk of gastric carcinoma. Nevertheless, we observed several individuals with high-risk IL-1 genotypes who were infected with virulent H. pylori strains but had only gastritis. Conversely, several gastric carcinoma patients had low-risk IL-1 genotypes and were infected with vacAs2-, vacAm2-, or cagA-negative strains. Gastric carcinogenesis is a complex and multifactorial cascade of events in which additional factors probably play a crucial role (2). Bacterial virulence factors such as babA (related to binding to blood-group antigens) and other outer membrane proteins have been shown to influence H. pylori virulence (32). Other host genetic factors associated with the inflammatory response, such as human leukocyte antigen and tumor necrosis factor- polymorphisms (25,33), may also be associated with the outcome of infection. Finally, it is likely that the genetic background of gastric acid production plays a role in determining the topography of H. pylori stomach colonization and in the development of gastric carcinoma-associated corpus gastritis (31).
The extent to which H. pylori eradication decreases the risk of gastric carcinoma is unknown and controversial, raising the question of whether population-based H. pylori screening and treatment should be undertaken (3436). Insufficient evidence of costs and benefits of gastric carcinoma prevention, the increase in antibiotic resistance, and the controversial hypothesis of potential negative effects of eradication in certain clinical entities have been hampering this practice (34). Our findings indicate that H. pylori and host genotyping can be important in better defining disease risk and preferentially targeting H. pylori eradication to high-risk individuals.
These findings address a major health issue, especially in countries where the prevalence of H. pylori is very high. As put forward by Peek and Blaser (4), individuals with genetic polymorphisms associated with high levels of IL-1b expression who are colonized by, for example, vacAs1- or cagA-positive strains are most likely to benefit from H. pylori eradication because such treatment could result in substantially reduced gastric carcinoma risk. According to our results, an intervention aimed at the 22% of gastritis individuals with the very high risk host/bacterial genotype (i.e., IL-1B-511*T carrier infected with vacAs1 genotype) has the potential to reduce gastric cancer substantially because this group accounts for 66% of the carcinoma patients.
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NOTES |
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Manuscript received February 20, 2002; revised August 20, 2002; accepted September 11, 2002.
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