Deep Targeted Sequencing of 12 Breast Cancer Susceptibility Regions in 4611 Women Across Four Different Ethnicities

Overview

Journal Breast Cancer Res

Specialty Oncology

Date 2016 Nov 6

PMID 27814745

Citations 3

Authors

Sara Lindstrom

Akweley Ablorh

Brad Chapman

Alexander Gusev

Gary Chen

Constance Turman

A Heather Eliassen

Alkes L Price

Brian E Henderson

Loic Le Marchand

Oliver Hofmann

Christopher A Haiman

Peter Kraft

Affiliations

Soon will be listed here.

Abstract

Background: Although genome-wide association studies (GWASs) have identified thousands of disease susceptibility regions, the underlying causal mechanism in these regions is not fully known. It is likely that the GWAS signal originates from one or many as yet unidentified causal variants.

Methods: Using next-generation sequencing, we characterized 12 breast cancer susceptibility regions identified by GWASs in 2288 breast cancer cases and 2323 controls across four populations of African American, European, Japanese, and Hispanic ancestry.

Results: After genotype calling and quality control, we identified 137,530 single-nucleotide variants (SNVs); of those, 87.2 % had a minor allele frequency (MAF) <0.005. For SNVs with MAF >0.005, we calculated the smallest number of SNVs needed to obtain a posterior probability set (PPS) such that there is 90 % probability that the causal SNV is included. We found that the PPS for two regions, 2q35 and 11q13, contained less than 5 % of the original SNVs, dramatically decreasing the number of potentially causal SNVs. However, we did not find strong evidence supporting a causal role for any individual SNV. In addition, there were no significant gene-based rare SNV associations after correcting for multiple testing.

Conclusions: This study illustrates some of the challenges faced in fine-mapping studies in the post-GWAS era, most importantly the large sample sizes needed to identify rare-variant associations or to distinguish the effects of strongly correlated common SNVs.

Citing Articles

Refining the genetic risk of breast cancer with rare haplotypes and pattern mining.

Letsou W, Wang F, Moon W, Im C, Sapkota Y, Robison L Life Sci Alliance. 2023; 6(10).

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Supervariants identification for breast cancer.

Hu J, Li T, Wang S, Zhang H Genet Epidemiol. 2020; 44(8):934-947.

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Novel applications of next-generation sequencing in breast cancer research.

Ma R, Gong J, Jiang X Genes Dis. 2018; 4(3):149-153.

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