Integrative eQTL analysis of tumor and host omics data in individuals with bladder cancer

LASSO; APBEC3B gene; Article; Chromosomes, Human; Computer Simulation; Genomics; Humans; Linear Models; Models, Genetic; Multivariate Analysis; Polymorphism, Single Nucleotide; Quantitative Trait Loci; Urinary Bladder Neoplasms

Abstract :

[en] Integrative analyses of several omics data are emerging. The data are usually generated from the same source material (i.e., tumor sample) representing one level of regulation. However, integrating different regulatory levels (i.e., blood) with those from tumor may also reveal important knowledge about the human genetic architecture. To model this multilevel structure, an integrative-expression quantitative trait loci (eQTL) analysis applying two-stage regression (2SR) was proposed. This approach first regressed tumor gene expression levels with tumor markers and the adjusted residuals from the previous model were then regressed with the germline genotypes measured in blood. Previously, we demonstrated that penalized regression methods in combination with a permutation-based MaxT method (Global-LASSO) is a promising tool to fix some of the challenges that high-throughput omics data analysis imposes. Here, we assessed whether Global-LASSO can also be applied when tumor and blood omics data are integrated. We further compared our strategy with two 2SR-approaches, one using multiple linear regression (2SR-MLR) and other using LASSO (2SR-LASSO). We applied the three models to integrate genomic, epigenomic, and transcriptomic data from tumor tissue with blood germline genotypes from 181 individuals with bladder cancer included in the TCGA Consortium. Global-LASSO provided a larger list of eQTLs than the 2SR methods, identified a previously reported eQTLs in prostate stem cell antigen (PSCA), and provided further clues on the complexity of APBEC3B loci, with a minimal false-positive rate not achieved by 2SR-MLR. It also represents an important contribution for omics integrative analysis because it is easy to apply and adaptable to any type of data. © 2017 WILEY PERIODICALS, INC.

Disciplines :

Life sciences: Multidisciplinary, general & others

Author, co-author :

Pineda, S.; Genetic and Molecular Epidemiology Group, Spanish National Cancer Research Centre (CNIO), Madrid, Spain, Systems and Modeling Unit, Montefiore Institute, University of Liège, Liège, Belgium

Van Steen, Kristel ; Université de Liège - ULiège > Dép. d'électric., électron. et informat. (Inst.Montefiore) > Bioinformatique

Malats, N.; Genetic and Molecular Epidemiology Group, Spanish National Cancer Research Centre (CNIO), Madrid, Spain

Language :

English

Title :

Integrative eQTL analysis of tumor and host omics data in individuals with bladder cancer

Publication date :

2017

Journal title :

Genetic Epidemiology

ISSN :

0741-0395

eISSN :

1098-2272

Publisher :

Wiley-Liss Inc.

Volume :

Issue :

Pages :

567-573

Peer reviewed :

Peer Reviewed verified by ORBi

Funders :

La Caixa [ES]
ISCIII - Instituto de Salud Carlos III [ES]

Available on ORBi :

since 13 June 2018

Statistics

Number of views

33 (2 by ULiège)

Number of downloads

1 (1 by ULiège)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

Bibliography

Benjamini, Y., & Yekutieli, D. (2001). The control of the false discovery rate in multiple testing under dependency. Annals of Statistics, 29(4), 1165–1188.
Che, R., Motsinger-Reif, A. A., & Brown, C. C. (2012). Loss of power in two-stage residual-outcome regression analysis in genetic association studies. Genetic Epidemiology, 36(8), 890–894.
Chen, Q.-R., Hu, Y., Yan, C., Buetow, K., & Meerzaman, D. (2014). Systematic genetic analysis identifies Cis-eQTL target genes associated with glioblastoma patient survival. PLoS One, 9(8), e105393.
Demissie, S., & Cupples, L. A. (2011). Bias due to two-stage residual-outcome regression analysis in genetic association studies. Genetic Epidemiology, 35(7), 592–596.
Fredriksson, N. J., Ny, L., Nilsson, J. A., & Larsson, E. (2014). Systematic analysis of noncoding somatic mutations and gene expression alterations across 14 tumor types. Nature Genetics, 46(12), 1258–1263.
Fu, Y.-P., Kohaar, I., Rothman, N., Earl, J., Figueroa, J. D., Ye, Y., … Prokunina-Olsson, L. (2012). Common genetic variants in the PSCA gene influence gene expression and bladder cancer risk. Proceedings of the National Academy of Sciences of the United States of America, 109(13), 4974–4979.
Gibbs, J. R., van der Brug, M. P., Hernandez, D. G., Traynor, B. J., Nalls, M. A., Lai, S. L., … Singleton, A. B. (2010). Abundant quantitative trait loci exist for DNA methylation and gene expression in human brain. PLoS Genetics, 6(5), e1000952.
Goeman, J. J., & Solari, A. (2014). Multiple hypothesis testing in genomics. Statistics in Medicine, 33(11), 1946–1978.
Hastie, T., Tibshirani, R., & Friedman, J. (2001). The elements of statistical learning, Springer Series in Statistics. Springer, New York.
Kristensen, V. N., Edvardsen, H., Tsalenko, A., Nordgard, S. H., Sørlie, T., Sharan, R., … Børresen-Dale, A. L. (2006). Genetic variation in putative regulatory loci controlling gene expression in breast cancer. Proceedings of the National Academy of Sciences of the United States of America, 103(20), 7735–7740.
Krzywinski, M., & Altman, N. (2015). Points of significance: Multiple linear regression. Nature Methods, 12(12), 1103–1104.
Li, Q., Seo, J. H., Stranger, B., McKenna, A., Pe'er, I., Laframboise, T., … Freedman, M. L. (2013). Integrative eQTL-based analyses reveal the biology of breast cancer risk loci. Cell, 152(3), 633–641.
Li, Q., Stram, A., Chen, C., Kar, S., Gayther, S., Pharoah, P., … Freedman, M. L. (2014). Expression QTL-based analyses reveal candidate causal genes and loci across five tumor types. Human Molecular Genetics, 23(19), 5294–5302.
Loo, L. W. M., Cheng, I., Tiirikainen, M., Lum-Jones, A., Seifried, A., Dunklee, L. M., … Le Marchand, L. (2012). cis-Expression QTL analysis of established colorectal cancer risk variants in colon tumors and adjacent normal tissue. PLoS One, 7(2), e30477.
Mankoo, P. K., Shen, R., Schultz, N., Levine, D. A., & Sander, C. (2011). Time to recurrence and survival in serous ovarian tumors predicted from integrated genomic profiles. PLoS One, 6(11), e24709.
Middlebrooks, C. D., Banday, A. R., Matsuda, K., Udquim, K. I., Onabajo, O. O., Paquin, A., … Prokunina-Olsson, L. (2016). Association of germline variants in the APOBEC3 region with cancer risk and enrichment with APOBEC-signature mutations in tumors. Nature Genetics, 48(11), 1330–1338.
Pineda, S., Real, F. X., Kogevinas, M., Carrato, A., Chanock, S. J., Malats, N., & Van Steen, K. (2015). Integration analysis of three omics data using penalized regression methods: An application to bladder cancer. PLoS Genetics, 11(12), e1005689.
Tibshirani, R. (1996). Regression shrinkage and selection via the Lasso. Journal of the Royal Statistical Society. Series B (Methodological), 58(1), 267–288.
Van Eijk, K. R., de Jong, S., Boks, M. P., Langeveld, T., Colas, F., Veldink, J. H., … Ophoff, R. A. (2012). Genetic analysis of DNA methylation and gene expression levels in whole blood of healthy human subjects. BMC Genomics, 13, 636.
Watson, I. R., Takahashi, K., Futreal, P. A., & Chin, L. (2013). Emerging patterns of somatic mutations in cancer. Nature Reviews Genetics, 14(10), 703–718.
Westfall, P. H., & Young, S. S. (1993). Resampling-based multiple testing: Examples and methods for p-value adjustment. New York: Wiley-Interscience.
Wu, X.-R. (2005). Urothelial tumorigenesis: A tale of divergent pathways. Nature Reviews Cancer, 5(9), 713–725.
Zeegers, M., Rijsdijk, F., & Sham, P. (2004). Adjusting for covariates in variance components QTL linkage analysis. Behavior Genetics, 34(2), 127–133.
Zhang, D., Cheng, L., Badner, J. A., Chen, C., Chen, Q., Luo, W., … Liu, C. (2010). Genetic control of individual differences in gene-specific methylation in human brain. American Journal of Human Genetics, 86(3), 411–419.
Zhu, Y., Qiu, P., & Ji, Y. (2014). TCGA-assembler: Open-source software for retrieving and processing TCGA data. Nature Methods, 11(6), 599–600.