It has been reported that interleukin-1beta (IL-1B) genes play a crucial role in the genetic predisposition to gastric cancer although there is no information about their role in different subtypes of gastric cancer. We performed single nucleotide polymorphism analysis of IL-1B in 241 gastric cancers including early onset gastric cancers (EOGC), conventional gastric cancers, and gastric stump cancers (GSCs) as well as 100 control patients, using real-time polymerase chain reaction and sequence analysis. The C allele was present in 60% of EOGCs, 59% of conventional gastric cancers, and 90% of GSCs, compared to 62% in the control group. Interestingly, there was no difference between early onset and conventional gastric cancer with respect to the IL-1B −31T>C polymorphism distribution. A statistically significant difference in the presence of the C allele compared to the control group was found in patients with gastric stump cancer (p = 0.008) with the T allele conferring protection against gastric stump cancer. In summary, we have shown that the IL-1B −31C allele promoter polymorphism is significantly associated with gastric stump cancer compared to the control group. Although several molecular differences have been identified between conventional gastric cancer and early onset gastric cancer, the IL-1B −31 allele distribution is similar between these two groups.
Introduction
Although gastric cancer incidence decreases worldwide, it is still the second most common cause of cancer-related death in the world [35]. According to the Lauren classification [24], gastric cancer is divided into two main histological types, diffuse and intestinal. Gastric cancer results from a combination of environmental factors and accumulation of specific genetic alterations. In conventional gastric cancer (presenting >45 years old), environmental factors play a more important role, compared to early onset gastric cancer (EOGC, presenting at ≤45 years old) where it is postulated that genetic factors may be more important [20]. We have previously shown that molecular differences exist between conventional gastric cancer and EOGC [4‐6, 29‐32]. Apart from cases of hereditary gastric cancer, it remains unclear what predisposes the young patients to gastric cancer at such an early age.
Helicobacter pylori, is a class I carcinogen [16] and is the main environmental factor causing gastric cancer [11, 36]. H. pylori infection has been shown to range from approximately 60% in the general population to approximately 84% in patients with gastric cancer [36]. Only a few papers about H. pylori infection in gastric cancer patients younger than 40 years have been published, all showing an association between gastric cancer and H. pylori infection [21, 28, 37]. H. pylori is involved in both intestinal and diffuse types of gastric cancer, the latter type being more common in EOGC [37].
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Interleukin-1beta (IL-1B) is a key pro-inflammatory cytokine, which regulates the expression of several genes involved in inflammation. IL-1B is an endogenous inhibitor of gastric acid secretion and is important in initiating and enhancing the inflammatory response to H. pylori infection [34, 43]. Although the production of IL-1B depends on several factors, there is increasing evidence that the genetic background plays a major role. Therefore, single nucleotide polymorphisms (SNPs) in the IL-1B gene may be of importance in gene transcriptional activity.
Several single nucleotide polymorphisms in IL-1B have been studied, but many of these seem to be functionally insignificant and not associated with predisposition to cancer [7]. There are two biallelic polymorphisms at positions −31 and −511 in the promoter region of IL-1B, of which the −31C allele and the −511T allele are in positive linkage disequilibrium and associated with gastric cancer risk. It has been reported that carriers of the IL-1B −31C allele, showed higher plasmatic concentrations of IL-1B than subjects with wild-type IL-1B genotype [14]. Upregulation of IL-1B is involved in tumor-promoting effects such as invasiveness [40], angiogenesis [38], and metastasis [45] and has been recognized as negative prognostic factor, mainly in metastatic cancer [27]. Conversely, an association between peptic ulcer and the IL-1B −31T polymorphism has been described [8, 9]. Bearing this information in mind, the IL-1B status of patients with EOGC is of great interest. Whether these patients have a genetic predisposition for the carcinogenic pathway in response to H. pylori infection has never been investigated.
Several independent groups have found an association between partial gastrectomy (mostly after gastroduodenal ulcers) and increased risk for development of gastric cancer [33, 39]. These so-called gastric stump cancers (GSCs) are carcinomas occurring in the gastric remnant at least 5 years after surgery for a benign disease [42]. This represents a novel group in terms of IL-1B polymorphisms in that they are patients who have a predisposition for gastroduodenal ulcers yet have also developed gastric cancer. The IL-1B status of gastric stump cancers has never been studied to date.
In this study, we examined the distribution of the IL-1B −31T>C polymorphism in 241 gastric cancers including EOGC, conventional gastric cancer and GSC using real-time polymerase chain reaction (PCR) and sequence analysis and we investigated the relationship of IL-1B status with histology and location of the tumor.
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Materials and methods
Patients
We used 96 conventional gastric cancers (>45 years old) obtained from the Academic Medical Centre, Amsterdam diagnosed between 1993 and 2003. One hundred and fifteen early onset gastric cancers (≤45 years old) diagnosed between 1980 and 2002, were obtained from 24 different institutions throughout The Netherlands through the nationwide database system and from the Department of Pathology at the Jorvi Hospital (Espoo, Finland) and 30 gastric stump cancers from the Amsterdam post-gastrectomy cohort [41]. The control group consisted of 100 DNA samples from the Department of Endocrinology at the Academic Medical Center, Amsterdam as published previously [44]. The tumors were classified by an experienced gastrointestinal pathologist (GJAO) according to the Lauren classification, as can be seen in Table 1. H. pylori vacA s region genotype and the presence of the cagA gene were known for 29 of the EOGC cases as detected by PCR followed by agarose gel electrophoresis and as published previously [6]. H. pylori infection was detected in 11 of 29 (37.9%) of these cases, a percentage which is in accordance with published data concerning The Netherlands population [25].
Table 1
Patients’ characteristics
No. of patients
Age (range)
Histology
Location
Early onset gastric cancer (EOGC)
115
≤45 (21–45 years)
Intestinal—25 (22%)
Cardia—9 (8%)
Diffuse—80 (70%)
Non-cardia—66 (57%)
Mixed—10 (9%)
Unknown—40 (35%)
Conventional gastric cancer
96
>45 (47–86 years)
Intestinal—49 (51%)
Cardia—49 (51%)
Diffuse—36 (38%)
Non-cardia—41 (43%)
Mixed—11 (11%)
Unknown—6 (6%)
Gastric stump cancer (GSC)
30
(54–85 years)
Intestinal—26 (87%)
Unknown
Diffuse—2 (7%)
Mixed—2 (7%)
Control group
100
(22–52 years)
None
None
DNA isolation
DNA was isolated from formalin-fixed tissue using the QIAamp DNA mini kit (Qiagen, Venlo, The Netherlands) or the Puregene DNA isolation kit (Gentra, Minneapolis, USA) according to the manufacturer’s instructions. Normal tissue was obtained from a tumor-free lymph node, or where necessary, from tissue with a small component of neoplastic cells. DNA concentrations were measured using the NanoDrop spectrophotometer (Isogen Life Science, IJsselstein, The Netherlands).
Real-time PCR
The polymorphism −31T>C in the promoter region of IL-1B was detected using the LightCycler 2.0 (Roche, Mannheim, Germany) with 5′-cccctttcctttaacttgattgtgaaatc-3′ and 5′-aggtttggtatctgccagtttctc-3′ (Applied Biosystems, Foster City, USA) as primers and the fluorescent probes 6-FAM-5′-CTGTTTTTATAGCTTTCA-3-MBG′, and VIC-5′-CTGTTTTTATGGCTTTCA-3′-MGB (Applied Biosystems) in a 20-μl reaction mixture containing 10 μl QuantiTect Probe PCR Kit (Qiagen, Leusden, The Netherlands), 10 pmol forward and reverse primer, 2 pmol of each probe, and 50 ng genomic DNA. PCR conditions were as follows: 94°C for 15 min followed by 45 cycles of 94°C for 15 s and 60°C for 30 s. In each run, three positive control samples (TT, TC, and CC allele) as confirmed twice on sequencing were used together with water as a negative control.
Sequencing
To confirm the results from the real-time PCR, 10% of the samples were sequenced. The promoter region was amplified using the primers (forward) 5′-cccctttcctttaacttgattgtgaaatc-3′ and (reverse) 5′-aggtttggtatctgccagtttctc-3′ (Applied Biosystems). PCR products were purified using the QIAquick PCR purification kit (Qiagen), according to the manufacturer’s instructions. The sequences were analyzed on an ABI 3100 automated sequencer (Applied Biosystems) using the ABI Big Dye Terminator Cycle Sequence Kit (Applied Biosystems) and the Genescan 2.1 software.
Statistics
The SPSS 14.0 software package was used for statistical analysis. A chi-squared test was applied to determine whether there was a statistical difference between the presence of the C and T allele (p < 0.05). The Hardy–Weinberg equilibrium was assessed using the chi-squared test. A multinominal logistic regression model was used to calculate the odds ratio for developing gastric cancer depending on SNP status, and also for adjusting for histological type and location (proximal versus distal only for EOGC and conventional gastric cancer).
Results
The identification of a genetic risk profile for gastric cancer could help the populations most at risk. Therefore, we evaluated the role of IL-1B −31T>C promoter polymorphism in different subtypes of gastric cancer. The distribution of the IL-1B −31T>C polymorphism was examined by real-time PCR (see Fig. 1) in 241 cases of gastric cancer, including 96 conventional gastric cancers, 115 EOGCs, and 30 GSCs as well as in 100 healthy control cases, and these results can be seen in Table 2, where the number of each specific genotype can be seen for each subtype of gastric cancer. In terms of carriage of the C allele, this was found in 60% of EOGCs, 59% of conventional gastric cancer, 90% of GSCs, and 62% of controls, as seen in the bottom row of Table 2. The IL-1B polymorphism status was confirmed in 10% of our study populations, using sequence analysis, an example of which can be seen in Fig. 1. All genotypic distributions were in Hardy–Weinberg equilibrium (p ≥ 0.05).
Fig. 1
Result of sequencing and LightCycler analysis. a An example of the sequence analysis of the CC, CT, and TT IL-1B polymorphism. b LightCycler analysis of CC, CT, and TT SNP genotypes at the −31 position of the promoter region of IL-1B using MGB probes. Upper panel shows the FAM-labeled probe, visualized at 530 nm for detection of the T allele; lower panel shows the VIC-labeled probe, visualized at 560 nm for detection of the C allele
Table 2
Prevalence of IL-1B −31T>C genotype
Genotype of IL-1B −31T>C
Early onset gastric cancer
Conventional gastric cancer
Gastric stump cancer
Controls
CC
17/115 (15%)
21/96 (22%)
8/30 (27%)
19 (19%)
TC
52/115 (45%)
36/96 (37%)
19/30 (63%)
43 (43%)
TT
46/115 (40%)
39/96 (41%)
3/30 (10%)
38 (38%)
Carriage of the C allele
60%
59%
90%
62%
All percentages rounded to the nearest digit.
×
A logistic regression model was used to determine the statistical likelihood of developing different subtypes of gastric cancer depending on the IL-1B SNP status. In this regression model, carriage of the C allele was compared between the different types of gastric cancer, with adjustments made for both histology and location of the tumor (for the categories of EOGC and conventional gastric cancer) and corrected for histology only in the case of stump cancers. In patients with GSC, carriage of the C allele conferred a significant increased risk of the development of gastric cancer with respect to the controls (p = 0.008, OR = 5.52, 95% confidence interval 1.57–19.43). Carriage of the C allele (genotypes CT and CC) in both EOGC and conventional gastric cancer did not confer an increased risk of gastric cancer with respect to the control group (p = 0.76, OR 0.92, 95% confidence interval 0.53–1.59 and p = 0.71, OR 0.9, 95% confidence interval 0.51–1.59, respectively).
Using a logistic regression model, the genotype distribution was also compared between EOGC, conventional gastric cancer, GSC, and the control group. In the gastric stump cancer group, the CC and CT genotypes predisposed to gastric cancer with an OR of 5.33 (p = 0.022, 95% confidence interval 1.27–22.44) and 5.6 (p = 0.009, 95% confidence interval 1.54–20.40), respectively. No difference was found in genotype distribution between EOGCs and conventional gastric cancers and the control group.
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In addition, the IL-1B −31T>C genotype or carriage of the C allele did not predispose to a specific location of gastric cancer (cardia versus non-cardia, applicable to EOGC and conventional gastric cancers only) or to a histological type.
Discussion
Inflammation is a central component of several chronic diseases. IL-1B is an inducible gene that plays an important role in both inflammation and carcinogenesis. The expression of IL-1B depends on varying individual susceptibility, geographical location, and genetic factors. Genetic polymorphisms that alter the levels of IL-1B may have substantial influence on cancer activity. In the present study, we focused on the distribution of the −31T>C promoter polymorphism of the human IL-1B gene in conventional gastric cancer, EOGC, and GSC.
The IL-1B −31C allele is reported to be associated with higher risk of gastric cancer [8, 9]. Interestingly, we did not find an association between the pro-inflammatory genotype of IL-1B −31 and predisposition to conventional or early onset gastric cancer. The role of IL-1B −31T>C polymorphism in gastric cancer has been variable and the literature is inconclusive. Positive associations between pro-inflammatory genotypes of IL-1B −31 and higher risk of gastric cancer have been previously reported in populations from Poland, Scotland, and Mexico [8, 9, 12]. This is in contrast to studies in Finland [18] and Brazil [13], and our current findings are also in line with two published meta-analyses about the association of IL-1B polymorphisms with gastric cancer in a Caucasian population [3, 19]. It does appear that not all Asian or white populations have demonstrated a predisposition for gastric cancer in association with pro-inflammatory IL-1 polymorphisms and in some instances, studies found that there was a positive association, but with novel markers of the IL-1B gene [1]. So far, there is no clear explanation for these conflicting results although the relatively small number of gastric cancer cases (211) included in this particular study may provide an explanation for the negative association between the IL-1B marker and risk of GC. Zeng et al. [46] reported that the IL-1B-genotype-dependent risk of gastric cancer was limited to specific areas where the prevalence of gastric cancer was low. This hypothesis, however, conflicts with data showing an association between the IL-1B −31C allele and gastric cancer in Poland and Portugal, two countries both with high prevalence rates of gastric cancer [8, 9, 35]. The effect of differing genetic and environmental factors on different populations may provide an explanation for these conflicting reports. The importance of haplotype context has been highlighted in recent literature where polymorphisms in metabolic genes and in CDH1 have been shown to act in combination with smoking, alcohol consumption, and H. pylori infection in the development of gastric cancer [2, 17].
EOGC is a separate entity within gastric cancer and may result from different genetic alterations that accumulate more rapidly compared to conventional gastric cancer [6]. This is the first study that investigates the pro-carcinogenic background of EOGC by evaluating the role of the IL-1B −31T>C polymorphism in predisposition to EOGC. We demonstrated that the distribution of the IL-1B −31T>C polymorphism is not different between EOGC and the control group and that there is no difference between conventional gastric cancer and EOGC for the IL-1B −31 polymorphism. Thus, once infected by H. pylori (which appears to occur at the same rate as in conventional gastric cancers [6]), the IL-1B status does not explain the increased risk of gastric cancer in these young patients.
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An intriguing subtype of gastric cancer is gastric stump cancer, due to its gastroduodenal ulcer and partial gastrectomy history and subsequent gastric cancer development. It is described that gastric cancer and duodenal peptic ulcer disease are inversely associated, have distinct gastric acid secretion [10], and possess a distinct IL-1B −31T>C genotype distribution. It is believed that subjects who develop duodenal ulcers are actually protected from developing gastric cancer, suggesting that the two outcomes are mutually exclusive [15].
In the GSC patients, who developed peptic ulcer and gastric cancer, we found a statistically significant difference in IL-1B −31T>C polymorphism compared to the control group, with the C allele being associated with cancer. These findings are surprising as although the patients in this unique subgroup have a strong history of gastroduodenal ulcer, they do not have the polymorphism reportedly associated with ulcers but rather have a predilection for the C allele, which may explain the increased cancer risk in these patients. Although our gastric stump cancer group is small (30 patients), it seems that the IL-1B −31T>C polymorphism influences the prognosis of patients after partial gastrectomy. Although individuals with duodenal ulcers generally do not have the C polymorphism, the minority does appear to be at risk of developing gastric stump cancer. Surgery removes the inflamed and H. pylori-ridden antrum and induces acid suppression, thus converting these from an antrum-predominant into a corpus-predominant phenotype (to some extent comparable to the pharmacological acid suppression group) [22, 23]. In addition, these patients with the C genotype are known to have an associated high IL-1B output which further increases the acid suppression thus increasing their risk of subsequent development of gastric cancer.
Researchers have reported significant associations between IL-1B promoter region polymorphisms and the anatomic site of the tumor and histology. Machado et al. reported that the IL-1B −511T (−31C) genotype is associated with an intestinal type of gastric cancer in a Portuguese population [26] and Garza-Gonzalez et al. described the association between the IL-1B −31C genotype and the risk of distal gastric cancer in a Hispanic population [12]. We examined the associations between IL-1B −31T>C polymorphisms and location of the tumor or the histology and found no relation. This discrepancy is most likely due to study size, as in our study, where we have assessed a total of 241 gastric cancers, in contrast to the 152 and 63 used by Machado et al. and Garza-Gonzalez et al., respectively, and thus, it is likely that there is no correlation between histology and IL-1B genotype. On the other hand, the high rate of H. pylori infection in countries such as Portugal may result in the IL-1B polymorphism playing a more important role in the development of intestinal gastric cancer in this particular population.
In summary, this is the first study describing the role of the IL-1B −31T>C polymorphism in EOGC and GSC. Although EOGC appears to have a different genetic background compared to conventional gastric cancer, we did not find any differences in the IL-1B −31T>C polymorphism distribution. Interestingly, our study has shown that the IL-1B −31C genotype can contribute significantly to the development of GSC.
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Acknowledgments
The authors thank Sjoerd Repping from the Endocrinology Department, Academic Medical Centre, Amsterdam, for provision of the control group. Robert Sitarz, first author, is funded by the Stella Major Foundation.
Conflict of interest statement
We declare that we have no conflict of interest.
Open Access
This article is distributed under the terms of the Creative Commons Attribution Noncommercial License which permits any noncommercial use, distribution, and reproduction in any medium, provided the original author(s) and source are credited.
Open AccessThis is an open access article distributed under the terms of the Creative Commons Attribution Noncommercial License (https://creativecommons.org/licenses/by-nc/2.0), which permits any noncommercial use, distribution, and reproduction in any medium, provided the original author(s) and source are credited.
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