Validation of a Multi-ancestry Polygenic Risk Score and Age-specific Risks of Prostate Cancer: A Meta-analysis Within Diverse Populations

Overview

Journal Elife

Specialty Biology

Date 2022 Jul 8

PMID 35801699

Authors

Fei Chen

Burcu F Darst

Ravi K Madduri

Alex A Rodriguez

Xin Sheng

Christopher T Rentsch

Caroline Andrews

Wei Tang

Adam S Kibel

Anna Plym

Kelly Cho

Mohamed Jalloh

Serigne Magueye Gueye

Lamine Niang

Olufemi J Ogunbiyi

Olufemi Popoola

Akindele O Adebiyi

Oseremen I Aisuodionoe-Shadrach

Hafees O Ajibola

Mustapha A Jamda

Olabode P Oluwole

Maxwell Nwegbu

Ben Adusei

Sunny Mante

Afua Darkwa-Abrahams

James E Mensah

Andrew Anthony Adjei

Halimatou Diop

Joseph Lachance

Timothy R Rebbeck

Stefan Ambs

J Michael Gaziano

Amy C Justice

David V Conti

Christopher A Haiman

Affiliations

Soon will be listed here.

Abstract

Background: We recently developed a multi-ancestry polygenic risk score (PRS) that effectively stratifies prostate cancer risk across populations. In this study, we validated the performance of the PRS in the multi-ancestry Million Veteran Program and additional independent studies.

Methods: Within each ancestry population, the association of PRS with prostate cancer risk was evaluated separately in each case-control study and then combined in a fixed-effects inverse-variance-weighted meta-analysis. We further assessed the effect modification by age and estimated the age-specific absolute risk of prostate cancer for each ancestry population.

Results: The PRS was evaluated in 31,925 cases and 490,507 controls, including men from European (22,049 cases, 414,249 controls), African (8794 cases, 55,657 controls), and Hispanic (1082 cases, 20,601 controls) populations. Comparing men in the top decile (90-100% of the PRS) to the average 40-60% PRS category, the prostate cancer odds ratio (OR) was 3.8-fold in European ancestry men (95% CI = 3.62-3.96), 2.8-fold in African ancestry men (95% CI = 2.59-3.03), and 3.2-fold in Hispanic men (95% CI = 2.64-3.92). The PRS did not discriminate risk of aggressive versus nonaggressive prostate cancer. However, the OR diminished with advancing age (European ancestry men in the top decile: ≤55 years, OR = 7.11; 55-60 years, OR = 4.26; >70 years, OR = 2.79). Men in the top PRS decile reached 5% absolute prostate cancer risk ~10 years younger than men in the 40-60% PRS category.

Conclusions: Our findings validate the multi-ancestry PRS as an effective prostate cancer risk stratification tool across populations. A clinical study of PRS is warranted to determine whether the PRS could be used for risk-stratified screening and early detection.

Funding: This work was supported by the National Cancer Institute at the National Institutes of Health (grant numbers U19 CA214253 to C.A.H., U01 CA257328 to C.A.H., U19 CA148537 to C.A.H., R01 CA165862 to C.A.H., K99 CA246063 to B.F.D, and T32CA229110 to F.C), the Prostate Cancer Foundation (grants 21YOUN11 to B.F.D. and 20CHAS03 to C.A.H.), the Achievement Rewards for College Scientists Foundation Los Angeles Founder Chapter to B.F.D, and the Million Veteran Program-MVP017. This research has been conducted using the UK Biobank Resource under application number 42195. This research is based on data from the Million Veteran Program, Office of Research and Development, and the Veterans Health Administration. This publication does not represent the views of the Department of Veteran Affairs or the United States Government.

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