Abstract
Background/Aim: Interleukin-6 is an important modulator of inflammation, which is one of the factors involved in prostate cancer. The aim of the study was to evaluate the possible association of the IL-6 -174 polymorphism (rs1800795) with the risk of prostate cancer development and progression. Materials and Methods: The study population consisted of 446 prostate cancer patients, 377 benign prostatic hyperplasia (BHP) patients and 276 healthy men. Genotyping was performed by PCR-RFLP analysis. IL-6 plasma levels were measured by the ELISA method. Results: The GC genotype (OR=0.61, p=0.005) and C allele (OR=0.8, p=0.04) of the IL-6 -174 polymorphism were significantly associated with prostate cancer. No genotype was associated with BHP. IL-6 plasma levels were significantly increased in prostate cancer patients compared to both healthy men (p=0.02) and BHP patients (p=0.008). No significant differences were observed in IL-6 plasma levels in connection with IL-6 -174 genotypes. Conclusion: The IL-6 -174 polymorphism was significantly associated with prostate cancer in Slovak patients.
Interleukin-6 (IL-6) is a multifactorial pro-inflammatory cytokine belonging to the family of IL-1 cytokines. It is produced by different types of cells, including activated macrophages, monocytes, fibroblasts, activated T lymphocytes and B lymphocytes, endothelial cells, as well as cancer cells. IL-6 mediates several important physiological functions including control of the acute phase response during inflammation, production of adhesion molecules and induction of secretion of other inflammation mediators such as tumor necrosis factor. IL-6 may also mediate carcinogenesis by several mechanisms, including stimulation of cell proliferation, reduction of apoptosis, alteration of enzymes involved in tumor invasion and promotion of bone metastases (1). IL-6 is also one of the factors that may contribute to increased growth of prostate cancer cells in the absence of androgens by activation of androgen receptor (2). IL-6 can also contribute to the transformation of benign prostate cells into malignant cells and promote epithelial mesenchymal transition (3). The levels of IL-6 also correlate with prostate tumor burden, serum prostate-specific antigen and metastasis (4).
The human IL-6 gene is located at the short arm of chromosome 7 (7p15-21) and includes 5 exons and 4 introns (5). The expression of IL-6 gene as well as the concentration of IL-6 might be influenced by the presence of polymorphic sites in the gene. Single nucleotide polymorphisms in the promoter may result in alterations in expression and functional activity of IL-6. Increased expression of IL-6 and its receptor was detected in malignant prostate tissue and high-grade prostatic intraepithelial neoplasia lesions (6). The G/C transition in IL-6 gene (rs1800795) is suggested to be associated with altered production of IL-6, because of its localization in the promoter region where gates GATA1 access (7). The polymorphism is also located in region with partial sequence homology with the Smad4-binding element. It is supposed that the C allele may bind Smad4 more effectively and inhibit IL-6 transcription (8). The G allele was found to be the higher IL-6 expressing variant (5).
The aim of the study was to analyze the possible association of the promoter polymorphism at position -174 (rs1800795) of the IL-6 gene and the risk of prostate cancer development and progression in a group of Slovak prostate cancer patients.
Materials and Methods
Study population. The present study included 446 patients with histologically verified prostate cancer, 377 patients with benign prostatic hyperplasia (BHP) and 276 healthy men. Patients were recruited at the Department of Urology, University Hospital Martin in Slovakia, during the time period 2005-2017. Healthy volunteers were randomly selected from men that attended routine urological examinations and who did not have a cancer history as well as any prostate disease. The study was approved by the Ethics Committee of Comenius University in Bratislava, Jessenius Faculty of Medicine in Martin and both patients and healthy men gave their informed consent to participate in the study. The clinical characteristics of the subjects are summarized in Table I.
Genotyping. Genomic DNA was isolated from whole blood samples using Wizard® Genomic DNA Purification Kit (Promega, Madison, WI, USA) and stored at −20°C until genotype analysis. The polymorphism in the promoter region of IL-6 gene, -174 G/C (rs1800795), was determined by polymerase-chain reaction-restriction fragment length polymorphism (PCR-RFLP) analysis. The DNA fragments were amplified in a 12 μl reaction mixture containing 1 μl of genomic DNA (0.1 μg/μl), 0.4 μl of each primer (25 μmol/μl), 6 μl of DreamTaq Green PCR Master mix (2x) and 4.2 μl of DNase free water. The primer sequences used for detection of IL-6 -174 G/C polymorphism were: F 5’-ATG CCA AGT GCT GAG TCA CTA-3’, R 5’-GGA AAA TCC CAC ATT TGA TA-3’. The PCR amplification conditions for IL-6 -174 G/C were as follows: 5 min initial denaturation at 94°C, and 40 cycles of 30 sec at 94°C, 45 sec at 52.8°C and 1 min at 72°C, followed by a final elongation at 72°C for 7 min. After amplification, 226 bp PCR products were digested with NIaIII restriction enzyme for 15 min at 37°C. Digested products were separated by electrophoresis on 2% agarose gel and visualized by ethidium bromide staining. When the C allele was found at the -174 position, two fragments of 117 and 109 bp were produced. The 226 bp fragment was not cleaved when the G allele was present.
Plasma separation and determination of IL-6 plasma levels. All patient blood samples were collected in K2EDTA tubes, to prevent clotting, in the morning between 7:00 am - 10:00 am after a night of fasting. All blood samples were examined in the same laboratory. Plasma samples were obtained immediately after blood collection by centrifugation at 2,000 r/min for 20 min at 4°C, aliquoted to prevent freeze and thaw cycles and stored at −80°C for later use. For determination of IL-6 levels, plasma samples of 44 prostate cancer patients, 104 patients with BHP and 10 healthy men were collected and assessed using a commercially available ELISA kit.
Statistical analysis. Genotype frequencies were estimated for both patients with prostate cancer and BHP as well as for healthy controls. Comparisons between genotype distribution and association with selected clinical data were performed with the Chi-square test and Fisher's exact test. The genotype frequencies were tested for Hardy-Weinberg equilibrium in the control group. Comparison of IL-6 plasma levels between studied groups as well as their association with different genotypes was performed by Mann-Whitney test. All p-values were derived from two-sided tests and were considered to be statistically significant if p<0.05. Statistical analysis was performed using StatsDirect statistical package version 2.7.8.
Results
Genotype distribution of IL-6 -174 polymorphisms. Screening for the polymorphism in the IL-6 gene, rs1800795, located at the -174 position of the promoter region was performed in this study. The distribution of genotypes was in agreement with the Hardy-Weinberg equilibrium (p=0.27) in the control group. Distribution of alleles and genotypes in the group of patients with prostate cancer, BHP as well as in the control group are summarized in Table II.
Statistically significant association of the -174 GC genotype (OR=0.61; 95%CI=0.43-0.86; p=0.005) and C allele (OR=0.80; 95%CI=0.64-0.99; p=0.04) with the decreased risk of prostate cancer development was observed. The association of the IL-6 -174 polymorphism was significant also in the dominant model (GG versus GC + CC) (OR=0.63; 95%CI=0.46-0.88; p=0.006). No significant association of IL-6 -174 polymorphism with the risk of BHP development was found. The association of the GC genotype of the IL-6 -174 polymorphism was on the border of the statistical significance (p=0.08) if we compared genotype frequencies between prostate cancer patients and BHP patients. The results are summarized in Table II.
To detect a possible correlation between IL-6 -174 polymorphism and aggressiveness of prostate cancer, patients were stratified according to Gleason score (Gleason score<7 and Gleason score ≥7). When compared to the control group, the GC genotype was significantly associated with a decreased risk of development of both low-grade (Gleason score<7) and high-grade (Gleason score ≥7) carcinomas (OR=0.48; 95%CI=0.30-0.76; p=0.006 and OR=0.62; 95%CI=0.41-0.94; p=0.02, respectively). Results are summarized in Table III.
IL-6 plasma levels and association with IL-6 -174 genotypes. IL-6 plasma levels were significantly elevated in prostate cancer patients in comparison to both healthy men (p=0.02) as well as BHP patients (p=0.008). Results are shown in Table IV. No association was observed between the presence of the IL-6 -174 genotypes and IL-6 plasma levels (Table V).
Discussion
Polymorphisms located in the promoter region of the IL-6 gene can result in variations in transcription and influence the susceptibility to various diseases, including prostate cancer. In our study the association between -174 promoter polymorphisms of IL-6 and prostate cancer in Slovak patients was investigated. The importance of studying the particular polymorphism in different populations is underlined by the fact that there are important ethnic differences in the distribution of the -174 alleles. Bao et al. showed that, in Han people of China, there was no variation at the -174 position and all subjects have only the GG genotype (9). In this study, the GC genotype was significantly associated with decreased risk of prostate cancer development in Slovak prostate cancer patients. However, the polymorphism was not significantly associated with BHP. Similarly, to our results, Lopez et al. observed that IL-6 -174 polymorphism is not associated with BHP (10).
The previous studies on the association between IL-6 -174 polymorphism and prostate cancer risk reported inconsistent results. Pierce et al. found an increased risk of prostate cancer associated with the C allele (11). The magnitude of this association was stronger in the more aggressive prostate carcinomas than in the less aggressive cases (11). Similarly, Tan et al. observed a significant association between this polymorphism and increased risk of prostate cancer. They also found that distribution of -174 genotypes was significantly different between stages T3-T4 and T1-T2 (12). On the other hand, Mandal et al. revealed that the GG genotype was associated with 72% higher risk of prostate cancer (OR=1.72, p=0.0257) compared to the GC and CC genotypes (13). In contrast, we observed a decreased risk of prostate cancer to be significantly associated with the presence of the GC or CC genotypes which points to the fact that the GG genotype is associated with an increased risk. The study in the North Indian population suggests that IL-6 -174 polymorphism is associated with a two-fold increase in the risk of progression to bone metastases (14). In contrast, there are also studies that found no significant association between IL-6 -174 genotypes and overall risk of prostate cancer (15-19). Michaud et al. did not also observe any association of either IL-6 -174 genotype with both early and advanced stage prostate cancer (15).
In addition to analysis of the IL-6 -174 polymorphisms, we also observed that IL-6 plasma levels were significantly higher in prostate cancer patients in comparison to both healthy men and BHP patients. Similarly to our findings, Stark et al. observed that IL-6 levels are higher in prostate cancer patients. They found that pre-diagnostic IL-6 levels were significantly associated with the time of prostate cancer progression to metastatic disease or to death among healthy weight patients (16). However, it is assumed that IL-6 serum levels do not indicate the presence of metastasis, but rather that the tumor has the potential to metastasize (20). Alcover et al. also observed that preoperative levels of IL-6 were predictors of biochemical recurrence (21). Johnke et al. also detected higher IL-6 plasma concentrations in prostate cancer patients compared to healthy controls (22). On the other hand, Pierce et al. found no significant association between prostate cancer risk and blood IL-6 (11). Results of the study published by Yu et al. indicate that IL-6 is not produced by prostate adenocarcinoma cells. The expression of IL-6 mRNA is restricted, nearly exclusively, to the stromal compartment and is highly upregulated in areas of acute inflammation and prostatic atrophy. Therefore, it is assumed that IL-6 most likely signals in a paracrine fashion through IL-6 receptor and thus contributes to prostate cancer development and progression (23).
We also tried to assess if the observed increase in the IL-6 plasma levels was associated with the presence of -174 polymorphism in the promoter region of IL-6 gene, which has been reported to suppress gene transcription in vitro (5). Neither IL-6 -174 genotype was associated with a significantly changed IL-6 plasma levels in our study. However, our results might be misleading, because a limited number of plasma samples was analyzed. Previous studies that examined the influence of this polymorphism on the levels of IL-6 presented conflicting results. Some confirmed our observation of no association (16, 24), but other described a change in IL-6 levels due to the presence of different IL-6 -174 genotypes (5, 25). These conflicting results might be explained by the probability that more than one polymorphic sites in IL-6 gene are functional and influence IL-6 transcription (26).
In the presented study, a significant protective role of the GC genotype of IL-6 -174 polymorphism was demonstrated in patients with prostate cancer. However, there are several limitations of our study. All cases and controls were selected from one hospital and, therefore may not ideally represent the general population. Chronic inflammation, considered as an important promoting factor of prostate cancer, is multifactorial and a complex process influenced by many other genetic factors. Therefore, our study offers only a partial insight into the process of prostate carcinogenesis.
Acknowledgements
This publication is the result of the project implementation, Biomedical Center Martin“ ITMS code: 26220220187, supported by the Operational Programme Research and Innovation funded by the ERDF, by the Agency of Ministry of Education, Science, Research, and Sport of the Slovak Republic under Grant VEGA No. 1/0172/18, by the grant APVV-15-0217 “The molecular mechanisms of the statins effect on inhibition, proliferation and differentiation of selected stem and tumour cells and their application in regenerative medicine.” and grant UK/121/2018.
- Received March 16, 2018.
- Revision received April 26, 2018.
- Accepted April 30, 2018.
- Copyright© 2018, International Institute of Anticancer Research (Dr. George J. Delinasios), All rights reserved