Figures
Abstract
Background
A recent genome-wide association study has identified a new susceptibility locus, kinesin family member 1B gene (KIF1B), strongly associated with progression from chronic hepatitis B (CHB) to hepatitis B virus-related hepatocellular carcinoma (HCC) in Chinese population, this study was carried out to explore the role of the genetic variants in KIF1B in the development of chronic hepatitis B.
Methodology/Principal Findings
Three KIF1B polymorphisms (rs8019, rs17401924, and rs17401966) were selected and genotyped in 473 CHB patients and 580 controls with no history of CHB. Odds ratios (ORs) and 95% confidence intervals (CIs) were calculated by logistic regression model. None of these three SNPs showed association with CHBs after adjusting for age and gender. Equivalence-based method analysis confirmed the absence of association. In the further haplotype analysis, three common haplotypes were observed in this study population, but no significant effect was also found for haplotypes in the progression to CHB.
Conclusions/Significance
This study showed the new locus identified for HCC, KIF1B, was not associated with progression to CHB, implying distinct genetic susceptibility factor contributes to the progression from hepatitis B virus infection to HCC. Nevertheless, further comprehensive analyses are warranted to dissect the mechanism.
Citation: Zhong R, Tian Y, Liu L, Qiu Q, Wang Y, Rui R, et al. (2012) HBV-Related Hepatocellular Carcinoma Susceptibility Gene KIF1B Is Not Associated with Development of Chronic Hepatitis B. PLoS ONE 7(2): e28839. https://doi.org/10.1371/journal.pone.0028839
Editor: Masaru Katoh, National Cancer Center, Japan
Received: May 16, 2011; Accepted: November 16, 2011; Published: February 21, 2012
Copyright: © 2012 Zhong et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was supported by National Key Project of Infectious Disease (Grant number: 2009ZX10004-903 and 2008ZX10002-001), Science Fund for Creative Research Groups (Grant number: 30721063), Foundation of Institute of Basic Medical Sciences, Chinese Academy of Medical Sciences (Grant number: 2009PY16), the fundamental research funds for the central universities (HUST: NO.2011TS019). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Hepatitis B virus (HBV) infection is one of most challenging global public health problems, with more than 2 billion people infected [1], [2]. Epidemiological studies have shown a regional diversity of prevalence, with low rate (0.1–2.0%) in the USA and western Europe and high rate (8.0–20.0%) in southeast Asia and sub-Saharan regions [1]. While in China, a national survey in 2006 reported a 7.18% rate of HBsAg in the general population aged 1–59 [3], [4], [5]. HBV infection leads to a wide spectrum of outcomes. It has been estimated that 90–95% of individuals can successfully clarify HBV, and only 5–10% would develop chronic hepatitis B (CHB) [6]. Among those CHB individuals, 20–30% would develop liver cirrhosis and 5% further progress to hepatocellular carcinoma (HCC) [7]. HCC is the third most common cause of cancer-related death, and more than 80% of HCC cases can be attributable to chronic infection with HBV in hyper-endemic regions, suggesting CHB was a major risk factor for development of HCC [8]. The enormous variation in clinical outcome of HBV infection highlights the importance of identification of mechanism underlying the progression of HBV exposure to CHB for prevention against HBV-induced fatal liver disease. Although the environmental factors such as alcohol abuse, infection age, and co-infection with other hepatitis virus unveiled as risk factors of HBV-induced liver disease, genetic factors may also influence clinical progression after HBV exposure, which is indicated by familial studies [9]. In fact, multiple candidate genes, such as IFNG, TNF, VDR, and HLA loci, have been extensively investigated in the progression to CHB, but results were inclusive [10]–[13]. A recent genome-wide association study (GWAS) by Kamatani et al. in Japanese population has suggested two SNPs of rs3077 and rs9277535 in HLA-DP region strongly associated with risk of persistent infection of HBV [14]. Immediately, we successfully validated these SNPs in two Chinese independently population [15]. However, these two variants could account for only a small portion of CHB, and additional variants remains to be identified.
Interestingly, a GWAS conducted in Chinese population by Zhang H et al. raised a new susceptibility locus (rs17401966) in kinesin family member 1B gene (KIF1B) at chromosome 1p36.22, which was reported to be associated with HBV-related HCC in six independent populations [16]. However, no comprehensive analysis has been performed to explore this genetic variant on the progression of CHB. Given the established relationship between HBV infection and HCC, a hypothesis was therefore raised naturally that this new identified loci was also involved on the progression of CHB. To test this hypothesis, a case-control study containing 473 CHB patients and 580 controls matched in age and gender with no history of CHB, was conducted to explore the associations between the progression to CHB and three candidate SNPs in KIF1B, one SNP rs17401966 from GWAS study [16], and two SNPs of rs8019 and rs17401924 from functional prediction analysis.
Materials and Methods
Study subjects
This study consisted of 473 CHB cases and 580 controls. All subjects were unrelated Han Chinese from Beijing city and its surrounding region. CHB patients were recruited from two infectious diseases hospital, Beijing Ditan Hospital and Beijing You'an Hospital between November 2001 and August 2004. The diagnosis of CHB was conducted based on HBsAg seropositive, anti-HBs seronegative, and continuously abnormal alanine aminotransferase (ALT) and asparate aminotransferase (AST) for more than six months. Controls matched in age and gender were selected from a physical examination in Peking Union Medical College Hospital in 2004, who had no medical history of chronic hepatitis B and HBV vaccination. Subjects who were positive for HBsAg were excluded from the controls. At recruitment, written informed consent was obtained from each subject and personal information from each participant regarding demographic characteristics such as gender, age, and history of HBV vaccination were collected by questionnaire. This study was approved by the institutional review boards of the Chinese Academy of Medical Sciences Cancer Institute and Tongji Medical College of Huazhong University of Science and Technology.
Serological testing
Enzyme-linked immunoadsorbent assay (ELISA) was used to detect the serum HBsAg, anti-HBs and anti-HBc (IMX; Abbott Diagnostics, North Chicago, IL, USA).
Identification of Candidate SNPs
In addition to the SNP of rs17401966 identified by the GWAS in Chinese population, two other candidate SNPs in the intron of KIF1B gene were identified by bioinformatics analysis. The SNP of rs8019, which may located in the binding site of microRNA, was selected using an integrated bioinformatics tool “SNP Info”(http://manticore.niehs.nih.gov/snpfunc.htm) [17]. And rs17401924 was predicted to influence the gene splicing, which was analyzed by “ESE finder” (http://rulai.cshl.edu/cgi-bin/tools/ESE3/esefinder.cgi?process=home) [18].
Polymorphism genotyping
Genomic DNA was extracted from peripheral blood lymphocytes. All subjects were genotyped using TaqMan real-time polymerase chain reaction (Applied Biosystems, Foster City, CA) without knowledge of subjects' infection status. The program was heating to 95°C for 10 minutes followed by 40 cycles of 95°C for 15 seconds and 60°C for 1 minute. The ABI Prism 7900HT Sequence Detection System was used to read the reacted plates and analyze the endpoint fluorescence. To ensure the accuracy of genotyping, a 15% random sample was tested twice by different investigators. The results were concordant for all of the duplicate sets.
Statistical analysis and haplotype construction
The differences in distribution of genotype between CHB cases and controls were tested by χ2 test. Logistic regression was used to evaluate the associations between KIF1B genotypes or haplotypes and the outcome of HBV infection. Odds ratios (ORs) and their 95% confidence intervals (CIs) were calculated after adjustment for age and sex where appropriate. Nonsuperiority test was used to confirm the absence of association between all SNPs detected and progression to CHB [19]. All statistical analyses were conducted by Statistical Analysis System Software (version 9.2; SAS Institute, Cary NC). Linkage disequilibrium (LD) of the three SNPs was estimated using Haploview [20]. Haplotypes were reconstructed and Haplotype frequencies were analyzed using Phase 2.1 [21].
Results
Subjects characteristics
A total of 473 chronic HB patients (377 males and 96 females) and 580 controls (462 males and 118 females) were enrolled in this study, with mean age of 34.13±13.56 years. Both age and gender distribution was comparable between CHB and controls. The baseline characteristic of CHB patients and controls were shown in Table 1.
KIF1B SNPs genotypes and risk of CHB
The genotype distributions of KIF1B candidate SNPs are shown in Table 2. The minor allelic frequencies (MAF) for the rs17401966, rs8019 and rs17401924 variants were 0.26, 0.38, and 0.27 in CHB patients and 0.28, 0.37, and 0.28 in controls, respectively. No significant differences were found in the genotype frequencies between CHB patients and controls. Also, no significant association was observed between the rs17401966 AG (OR = 1.01; 95% CI, 0.79–1.31) or GG genotype (OR = 0.70; 95% CI, 0.43–1.14) and progression to CHB after adjusting for age and gender using logistic regression analysis (table 2). Similarly, the other two SNPs, rs8019 and rs17401924, also showed no significant association with progression to CHB (table 2).
Haplotypes and risk of CHB
We further performed haplotypes analysis of these three SNPs (in the order of rs8019, rs17401924, and rs17401966, data is showed in Table 3). LD analysis showed that these three SNPs were in strong linkage disequilibrium, with a D′ of 0.972 (r2 = 0.595) for rs8019 and rs17401924, 0.921 (r2 = 0.524) for rs8019 and rs17401966, and 0.931 (r2 = 0.853) for rs17401924 and rs17401966 in our study population. Eight haplotypes were observed in the present study, of which, only three haplotypes AAA, CGG and CAA were the most prevalent haplotypes both in CHB patients and controls owing to strong LD in these three SNPs. Haplotype analysis found that individuals carrying the CAA or CGG haplotype showed no increased risk of progression to CHB with reference of the AAA haplotype. Meanwhile other five haplotypes composing these three SNPs with frequencies smaller than 5% would not be evaluated in the haplotype association study.
Equivalence-based method to confirm the absence of association between KIF1b SNPs and risk of CHB
Nonsuperiority test was used to confirm the absence of association of rs8019*C, rs17401966*G, and rs17401924*G with the progression of CHB. The null hypothesis is that the frequency of rs8019*C, rs17401966*G, and rs17401924*G in CHB patients is greater by Δ compared to the frequency in controls. The specified amount Δ was set by 5% because the lowest difference of rs17401966*G between CHB and HCC patients in five independently populations in the GWAS data were 7.2%. So, a 5% excess in cases can be regard as a stringent margin.
The corresponding nonsuperiority P-values for rs8019, rs17401966 and rs17401924 was 0.002, 0.05 and 0.017, respectively, which support the absence of association between these three SNPs and development of CHB.
Discussion
In the study, we conducted a case-control study to firstly investigate whether a new genetic susceptibility locus associated with HBV-related HCC identified by GWAS, KIF1B, was involved in development of CHB. However, none of the three candidate SNPs (rs8019, rs17401924, and rs17401966) in KIF1B was significantly associated with the progression to CHB, and equivalence-based test confirmed the absence of association.
Since CHB has been verified to be closely associated with HCC, identification of the genetic predictors of CHB development is very important for fighting against HBV-related HCC. Although researchers have paid much attention to identify genetic susceptibility loci to CHB during past decades, the specific genetic alteration underlying progression to CHB was far from clear. Recently, a new susceptibility locus, KIF1B rs17401966 at 1p36.22 region, was identified to be involved in the progression from CHB to HCC by a GWAS study in Chinese population [16], but the effect of this SNP was unclear in the progression from HBV exposure to CHB. In this study, we investigated this SNP and other two predicted functional SNPs in KIFIB in 473 CHB cases and 580 controls with no medical history of CHB, and no significantly associations were observed between these three SNPs and the progression to CHB after adjusting age and gender. The results indicate that the genetic variants in KIF1B may only play role in the progression from CHB to HCC, but not in the progression to CHB. Similarly result was found by a recent GWAS in Japanese that a identified genetic locus for hepatitis C virus-related HCC was not associated with chronic hepatitis C susceptibility [22], implying that distinct genetic mechanism may contribute to corresponding step of HCV-induced HCC development . The genome-wide analyses on loss of heterozygosity (LOH) in HCC by Li et al. further support our current result, which suggested the LOH of 1p36.21–36.32 region was significant related to HCC development, but not associated with the progression to CHB [23]. Noteworthy, the new identified KIF1B locus for HCC is located at 1p36 region, which encodes two spliced isoforms of kinesin protein (KIF1Bα and KIF1Bβ) involved in the transport of organelles and vesicles [24]. Of these two isoforms, KIF1Bβ has been elucidated to act as a tumor suppressor in multiple cancers by acting a variety of inhibitors of cell proliferation and/or activators of apoptotic cell death [25], [26]. Moreover, because a non-significant difference test cannot be interpreted as acceptance of the null hypothesis, equivalence-based method that provide the probability of observing a lack of association by chance was conducted to avoid the false-negative results in this study. P-values of nonsuperiority test for rs8019, rs17401966 and rs17401924 is 0.002, 0.050 and 0.017, respectively, and the nonexistence of association between KIF1B and CHB progression is confirmed. Taken together, our current result, plus these published evidence, outlined a hypothetical theory that variable genetic susceptibility mechanisms underlie different procedural steps from HBV infection to hepatocarcinogenesis, and strongly indicated that the genetic variants in KIF1B significantly contributed to the progression of CHB to HCC, but not the CHB susceptibility.
In conclusion, this current study highlights the specificity of the KIF1B genetic variants for the progression from CHB to HCC, and the genetic susceptibility mechanism underlying the progression to CHB emergently needs further comprehensive analyses to elucidate.
Author Contributions
Conceived and designed the experiments: LW XM RZ LL YT. Performed the experiments: RZ LL YT. Analyzed the data: RZ JS. Contributed reagents/materials/analysis tools: QQ YW RR SD. Wrote the paper: XM LW HL RZ YT LL. Collected the data: BY SD.
References
- 1. Liaw YF, Chu CM (2009) Hepatitis B virus infection. Lancet 373: 582–592.
- 2. Hoofnagle JH, Doo E, Liang TJ, Fleischer R, Lok AS (2007) Management of hepatitis B: summary of a clinical research workshop. Hepatology 45: 1056–1075.
- 3. Liang X, Bi S, Yang W, Wang L, Cui G, et al. (2009) Epidemiological serosurvey of hepatitis B in China–declining HBV prevalence due to hepatitis B vaccination. Vaccine 27: 6550–6557.
- 4. Sun Z, Ming L, Zhu X, Lu J (2002) Prevention and control of hepatitis B in China. J Med Virol 67: 447–450.
- 5. Lu FM, Zhuang H (2009) Management of hepatitis B in China. Chin Med J (Engl) 122: 3–4.
- 6. Hohler T, Gerken G, Notghi A, Lubjuhn R, Taheri H, et al. (1997) HLA-DRB1*1301 and *1302 protect against chronic hepatitis B. J Hepatol 26: 503–507.
- 7. Wang FS (2003) Current status and prospects of studies on human genetic alleles associated with hepatitis B virus infection. World J Gastroenterol 9: 641–644.
- 8.
Hann HWL, Feitelson M (2010) Hepatocellular Carcinoma Associated with Hepatitis B Virus. In: Carr BI, editor. Hepatocellular Carcinoma. New York: Humana Press. pp. 235–257.
- 9. Lin TM, Chen CJ, Wu MM, Yang CS, Chen JS, et al. (1989) Hepatitis B virus markers in Chinese twins. Anticancer Res 9: 737–741.
- 10. Abbott W, Gane E, Winship I, Munn S, Tukuitonga C (2007) Polymorphism in intron 1 of the interferon-gamma gene influences both serum immunoglobulin E levels and the risk for chronic hepatitis B virus infection in Polynesians. Immunogenetics 59: 187–195.
- 11. Guo X, Zhang Y, Li J, Ma J, Wei Z, et al. (2010) Strong influence of human leukocyte antigen (HLA)-DP gene variants on development of persistent chronic hepatitis B virus carriers in the han Chinese population. Hepatology.
- 12. Carroll MB, Forgione MA (2010) Use of tumor necrosis factor alpha inhibitors in hepatitis B surface antigen-positive patients: a literature review and potential mechanisms of action. Clin Rheumatol 29: 1021–1029.
- 13. Suneetha PV, Sarin SK, Goyal A, Kumar GT, Shukla DK, et al. (2006) Association between vitamin D receptor, CCR5, TNF-alpha and TNF-beta gene polymorphisms and HBV infection and severity of liver disease. J Hepatol 44: 856–863.
- 14. Kamatani Y, Wattanapokayakit S, Ochi H, Kawaguchi T, Takahashi A, et al. (2009) A genome-wide association study identifies variants in the HLA–DP locus associated with chronic hepatitis B in Asians. Nat Genet 41: 591–595.
- 15. Wang L, Wu XP, Zhang W, Zhu DH, Wang Y, et al. (2011) Evaluation of genetic susceptibility loci for chronic hepatitis B in Chinese: two independent case-control studies. PLoS One 6: e17608.
- 16. Zhang H, Zhai Y, Hu Z, Wu C, Qian J, et al. (2010) Genome-wide association study identifies 1p36.22 as a new susceptibility locus for hepatocellular carcinoma in chronic hepatitis B virus carriers. Nat Genet 42: 755–758.
- 17. Yang CH, Chuang LY, Cheng YH, Wen CH, Chang PL, et al. (2008) SNP ID-info: SNP ID searching and visualization platform. OMICS 12: 217–226.
- 18. Cartegni L, Wang J, Zhu Z, Zhang MQ, Krainer AR (2003) ESEfinder: A web resource to identify exonic splicing enhancers. Nucleic Acids Res 31: 3568–3571.
- 19. Gourraud PA, the International Multiple Sclerosis Genetic Consortium (2011) When is the absence of evidence, evidence of absence? Use of equivalence-based analyses in genetic epidemiology and a conclusion for the KIF1B rs10492972*C allelic association in multiple sclerosis. Genet Epidemiol. (online advance, DOI: 10.1002/gepi.20592).
- 20. Barrett JC, Fry B, Maller J, Daly MJ (2005) Haploview: analysis and visualization of LD and haplotype maps. Bioinformatics 21: 263–265.
- 21. Stephens M, Smith NJ, Donnelly P (2001) A new statistical method for haplotype reconstruction from population data. Am J Hum Genet 68: 978–989.
- 22. Kumar V, Kato N, Urabe Y, Takahashi A, Muroyama R, et al. (2011) Genome-wide association study identifies a susceptibility locus for HCV-induced hepatocellular carcinoma. Nat Genet 43: 455–458.
- 23. Li SP, Wang HY, Li JQ, Zhang CQ, Feng QS, et al. (2001) Genome-wide analyses on loss of heterozygosity in hepatocellular carcinoma in Southern China. J Hepatol 34: 840–849.
- 24. Nangaku M, Sato-Yoshitake R, Okada Y, Noda Y, Takemura R, et al. (1994) KIF1B, a novel microtubule plus end-directed monomeric motor protein for transport of mitochondria. CELL 79: 1209–1220.
- 25. Munirajan AK, Ando K, Mukai A, Takahashi M, Suenaga Y, et al. (2008) KIF1Bbeta functions as a haploinsufficient tumor suppressor gene mapped to chromosome 1p36.2 by inducing apoptotic cell death. J Biol Chem 283: 24426–24434.
- 26. Sherr CJ (2004) Principles of tumor suppression. CELL 116: 235–246.