Genome-wide exploration of genetic interactions for bladder cancer risk

IF 5.7 2区 医学 Q1 ONCOLOGY
Evan Yi-Wen Yu, Qiu-Yi Tang, Ya-Ting Chen, Yan-Xi Zhang, Ya-Nan Dai, Yu-Xuan Wu, Wen-Chao Li, Siamak Mehrkanoon, Shi-Zhi Wang, Maurice P. Zeegers, Anke Wesselius
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Abstract

Although GWASs have been conducted to investigate genetic variation of bladder tumorigenesis, little is known about genetic interactions that may influence bladder cancer (BC) risk. By leveraging large-scale participants from UK Biobank, we established a discovery database with 4000 Caucasian participants (2000 cases vs 2000 non-cases), a database with 1648 Caucasian participants (824 cases vs 824 non-cases) and 856 non-Caucasian participants (428 cases vs 428 non-cases) as validation. We then performed a genome-wide SNP-SNP interaction investigation related to BC risk based a machine learning approach (ie, GenEpi). Moreover, we used the selected interactions to build a BC screening model with an integrated interaction-empowered polygenic risk score (iPRS) based on Cox proportional hazard model. With Bonferroni correction, we identified 10 statistically significant pairs of SNPs, which located in 17 chromosomes. Of these, four SNP-SNP interactions were found to be positively associated with BC risk among Caucasian participants (ORs 1.57-2.03), while six SNP-SNP interactions showed negatively associated with BC risk (ORs 0.54-0.65). Only four of the SNP-SNP interactions were consistently identified in non-Caucasian participants located in ST7L-ADSS2, FHIT-CHDH, LARP4B-LHPP and RBFOX3-MPRIP. In addition, the iPRS showed a HR of 1.81 (95% CI: 1.46-2.09) compared the highest tertile to the lowest tertile, with an enhanced AUC (0.91; 95% CI:0.85-0.97) than PRS (AUC: 0.86; 95% CI:0.76-0.95; P-DeLong test = 2.2 × 10−4). In summary, this study identified several important SNP-SNP interactions for BC risk, and developed an iPRS model for BC screening, which may help to identify the people at high-risk state of BC before early manifestation.

Abstract Image

膀胱癌风险基因相互作用的全基因组探索。
尽管GWASs已被用于研究膀胱肿瘤发生的遗传变异,但对可能影响膀胱癌(BC)风险的遗传相互作用知之甚少。通过利用来自UK Biobank的大规模参与者,我们建立了一个包含4000名高加索参与者(2000例对2000例非病例)的发现数据库,一个包含1648名高加索参与者(824例对824例)和856名非高加索参与者(428例对428例非病例)的数据库作为验证。然后,我们基于机器学习方法(即GenEpi)进行了与BC风险相关的全基因组SNP-SNP相互作用调查。此外,我们利用选定的相互作用建立了一个基于Cox比例风险模型的综合相互作用多基因风险评分(iPRS)的BC筛查模型。通过Bonferroni校正,我们确定了10对具有统计学意义的snp,它们位于17条染色体上。其中,4个SNP-SNP相互作用与白种人的BC风险呈正相关(or为1.57-2.03),而6个SNP-SNP相互作用与BC风险负相关(or为0.54-0.65)。在位于ST7L-ADSS2、FHIT-CHDH、LARP4B-LHPP和RBFOX3-MPRIP的非高加索参与者中,只有四种SNP-SNP相互作用被一致地鉴定出来。此外,iPRS的最高分蘖与最低分蘖的比值为1.81 (95% CI: 1.46 ~ 2.09), AUC (0.91;95% CI:0.85-0.97)高于PRS (AUC: 0.86;95%置信区间:0.76—-0.95;P-DeLong检验= 2.2 × 10-4)。综上所述,本研究确定了几个重要的SNP-SNP相互作用对BC风险的影响,并建立了一个用于BC筛查的iPRS模型,这可能有助于在早期表现之前识别BC高危状态的人群。
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来源期刊
CiteScore
13.40
自引率
3.10%
发文量
460
审稿时长
2 months
期刊介绍: The International Journal of Cancer (IJC) is the official journal of the Union for International Cancer Control—UICC; it appears twice a month. IJC invites submission of manuscripts under a broad scope of topics relevant to experimental and clinical cancer research and publishes original Research Articles and Short Reports under the following categories: -Cancer Epidemiology- Cancer Genetics and Epigenetics- Infectious Causes of Cancer- Innovative Tools and Methods- Molecular Cancer Biology- Tumor Immunology and Microenvironment- Tumor Markers and Signatures- Cancer Therapy and Prevention
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