Additional SNPs improve risk stratification of a polygenic hazard score for prostate cancer

Roshan A. Karunamuni; Minh Phuong Huynh-Le; Chun C. Fan; Wesley Thompson; Rosalind A. Eeles; Zsofia Kote-Jarai; Kenneth Muir; Artitaya Lophatananon; Johanna Schleutker; Nora Pashayan; Henrik Grönberg; Jyotsna Batra; The PRACTICAL (Prostate Cancer Association Group to Investigate Cancer-Associated Alterations in the Genome) Consortium

doi:10.1038/s41391-020-00311-2

Additional SNPs improve risk stratification of a polygenic hazard score for prostate cancer

Roshan A. Karunamuni^*
, Minh Phuong Huynh-Le
, Chun C. Fan
, Wesley Thompson
, Rosalind A. Eeles
, Zsofia Kote-Jarai
, Kenneth Muir
, Artitaya Lophatananon
, Johanna Schleutker
, Nora Pashayan
, Henrik Grönberg
, Jyotsna Batra
, The PRACTICAL (Prostate Cancer Association Group to Investigate Cancer-Associated Alterations in the Genome) Consortium

^*Corresponding author for this work

Research output: Contribution to journal › Article › Research › peer-review

17 Citations (Scopus)

Abstract

Background: Polygenic hazard scores (PHS) can identify individuals with increased risk of prostate cancer. We estimated the benefit of additional SNPs on performance of a previously validated PHS (PHS46).

Materials and method: 180 SNPs, shown to be previously associated with prostate cancer, were used to develop a PHS model in men with European ancestry. A machine-learning approach, LASSO-regularized Cox regression, was used to select SNPs and to estimate their coefficients in the training set (75,596 men). Performance of the resulting model was evaluated in the testing/validation set (6,411 men) with two metrics: (1) hazard ratios (HRs) and (2) positive predictive value (PPV) of prostate-specific antigen (PSA) testing. HRs were estimated between individuals with PHS in the top 5% to those in the middle 40% (HR95/50), top 20% to bottom 20% (HR80/20), and bottom 20% to middle 40% (HR20/50). PPV was calculated for the top 20% (PPV80) and top 5% (PPV95) of PHS as the fraction of individuals with elevated PSA that were diagnosed with clinically significant prostate cancer on biopsy.

Results: 166 SNPs had non-zero coefficients in the Cox model (PHS166). All HR metrics showed significant improvements for PHS166 compared to PHS46: HR95/50 increased from 3.72 to 5.09, HR80/20 increased from 6.12 to 9.45, and HR20/50 decreased from 0.41 to 0.34. By contrast, no significant differences were observed in PPV of PSA testing for clinically significant prostate cancer.

Conclusions: Incorporating 120 additional SNPs (PHS166 vs PHS46) significantly improved HRs for prostate cancer, while PPV of PSA testing remained the same.

Original language	English
Pages (from-to)	532-541
Number of pages	10
Journal	Prostate Cancer and Prostatic Diseases
Volume	24
Issue number	2
DOIs	https://doi.org/10.1038/s41391-020-00311-2
Publication status	Published - 1 Jun 2021
Externally published	Yes

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10.1038/s41391-020-00311-2

Cite this

Karunamuni, R. A., Huynh-Le, M. P., Fan, C. C., Thompson, W., Eeles, R. A., Kote-Jarai, Z., Muir, K., Lophatananon, A., Schleutker, J., Pashayan, N., Grönberg, H., Batra, J., & The PRACTICAL (Prostate Cancer Association Group to Investigate Cancer-Associated Alterations in the Genome) Consortium (2021). Additional SNPs improve risk stratification of a polygenic hazard score for prostate cancer. Prostate Cancer and Prostatic Diseases, 24(2), 532-541. https://doi.org/10.1038/s41391-020-00311-2

@article{c41be922312443859345f7e421d3b0bd,

title = "Additional SNPs improve risk stratification of a polygenic hazard score for prostate cancer",

abstract = "Background: Polygenic hazard scores (PHS) can identify individuals with increased risk of prostate cancer. We estimated the benefit of additional SNPs on performance of a previously validated PHS (PHS46). Materials and method: 180 SNPs, shown to be previously associated with prostate cancer, were used to develop a PHS model in men with European ancestry. A machine-learning approach, LASSO-regularized Cox regression, was used to select SNPs and to estimate their coefficients in the training set (75,596 men). Performance of the resulting model was evaluated in the testing/validation set (6,411 men) with two metrics: (1) hazard ratios (HRs) and (2) positive predictive value (PPV) of prostate-specific antigen (PSA) testing. HRs were estimated between individuals with PHS in the top 5\% to those in the middle 40\% (HR95/50), top 20\% to bottom 20\% (HR80/20), and bottom 20\% to middle 40\% (HR20/50). PPV was calculated for the top 20\% (PPV80) and top 5\% (PPV95) of PHS as the fraction of individuals with elevated PSA that were diagnosed with clinically significant prostate cancer on biopsy. Results: 166 SNPs had non-zero coefficients in the Cox model (PHS166). All HR metrics showed significant improvements for PHS166 compared to PHS46: HR95/50 increased from 3.72 to 5.09, HR80/20 increased from 6.12 to 9.45, and HR20/50 decreased from 0.41 to 0.34. By contrast, no significant differences were observed in PPV of PSA testing for clinically significant prostate cancer. Conclusions: Incorporating 120 additional SNPs (PHS166 vs PHS46) significantly improved HRs for prostate cancer, while PPV of PSA testing remained the same.",

author = "Karunamuni, \{Roshan A.\} and Huynh-Le, \{Minh Phuong\} and Fan, \{Chun C.\} and Wesley Thompson and Eeles, \{Rosalind A.\} and Zsofia Kote-Jarai and Kenneth Muir and Artitaya Lophatananon and Johanna Schleutker and Nora Pashayan and Henrik Gr{\"o}nberg and Jyotsna Batra and \{The PRACTICAL (Prostate Cancer Association Group to Investigate Cancer-Associated Alterations in the Genome) Consortium\} and Walsh, \{Eleanor I.\} and Turner, \{Emma L.\} and Athene Lane and Martin, \{Richard M.\} and Neal, \{David E.\} and Donovan, \{Jenny L.\} and Hamdy, \{Freddie C.\} and Nordestgaard, \{B{\o}rge G.\} and Tangen, \{Catherine M.\} and MacInnis, \{Robert J.\} and Alicja Wolk and Demetrius Albanes and Haiman, \{Christopher A.\} and Travis, \{Ruth C.\} and Stanford, \{Janet L.\} and Mucci, \{Lorelei A.\} and West, \{Catharine M.L.\} and Nielsen, \{Sune F.\} and Kibel, \{Adam S.\} and Fredrik Wiklund and Olivier Cussenot and Berndt, \{Sonja I.\} and Stella Koutros and S{\o}rensen, \{Karina Dalsgaard\} and Cezary Cybulski and Grindedal, \{Eli Marie\} and Park, \{Jong Y.\} and Ingles, \{Sue A.\} and Christiane Maier and Hamilton, \{Robert J.\} and Rosenstein, \{Barry S.\} and Ana Vega and Manolis Kogevinas and Penney, \{Kathryn L.\} and Teixeira, \{Manuel R.\} and Hermann Brenner and John, \{Esther M.\} and Radka Kaneva and Logothetis, \{Christopher J.\} and Neuhausen, \{Susan L.\} and Azad Razack and Newcomb, \{Lisa F.\} and Marija Gamulin and Nawaid Usmani and Frank Claessens and Manuela Gago-Dominguez and Townsend, \{Paul A.\} and Roobol, \{Monique J.\} and Wei Zheng and Mills, \{Ian G.\} and Andreassen, \{Ole A.\} and Dale, \{Anders M.\} and Seibert, \{Tyler M.\}",

year = "2021",

month = jun,

day = "1",

doi = "10.1038/s41391-020-00311-2",

language = "English",

volume = "24",

pages = "532--541",

journal = "Prostate Cancer and Prostatic Diseases",

issn = "1365-7852",

publisher = "Springer",

number = "2",

}

Karunamuni, RA, Huynh-Le, MP, Fan, CC, Thompson, W, Eeles, RA, Kote-Jarai, Z, Muir, K, Lophatananon, A, Schleutker, J, Pashayan, N, Grönberg, H, Batra, J & The PRACTICAL (Prostate Cancer Association Group to Investigate Cancer-Associated Alterations in the Genome) Consortium 2021, 'Additional SNPs improve risk stratification of a polygenic hazard score for prostate cancer', Prostate Cancer and Prostatic Diseases, vol. 24, no. 2, pp. 532-541. https://doi.org/10.1038/s41391-020-00311-2

TY - JOUR

T1 - Additional SNPs improve risk stratification of a polygenic hazard score for prostate cancer

AU - Karunamuni, Roshan A.

AU - Huynh-Le, Minh Phuong

AU - Fan, Chun C.

AU - Thompson, Wesley

AU - Eeles, Rosalind A.

AU - Kote-Jarai, Zsofia

AU - Muir, Kenneth

AU - Lophatananon, Artitaya

AU - Schleutker, Johanna

AU - Pashayan, Nora

AU - Grönberg, Henrik

AU - Batra, Jyotsna

AU - The PRACTICAL (Prostate Cancer Association Group to Investigate Cancer-Associated Alterations in the Genome) Consortium

AU - Walsh, Eleanor I.

AU - Turner, Emma L.

AU - Lane, Athene

AU - Martin, Richard M.

AU - Neal, David E.

AU - Donovan, Jenny L.

AU - Hamdy, Freddie C.

AU - Nordestgaard, Børge G.

AU - Tangen, Catherine M.

AU - MacInnis, Robert J.

AU - Wolk, Alicja

AU - Albanes, Demetrius

AU - Haiman, Christopher A.

AU - Travis, Ruth C.

AU - Stanford, Janet L.

AU - Mucci, Lorelei A.

AU - West, Catharine M.L.

AU - Nielsen, Sune F.

AU - Kibel, Adam S.

AU - Wiklund, Fredrik

AU - Cussenot, Olivier

AU - Berndt, Sonja I.

AU - Koutros, Stella

AU - Sørensen, Karina Dalsgaard

AU - Cybulski, Cezary

AU - Grindedal, Eli Marie

AU - Park, Jong Y.

AU - Ingles, Sue A.

AU - Maier, Christiane

AU - Hamilton, Robert J.

AU - Rosenstein, Barry S.

AU - Vega, Ana

AU - Kogevinas, Manolis

AU - Penney, Kathryn L.

AU - Teixeira, Manuel R.

AU - Brenner, Hermann

AU - John, Esther M.

AU - Kaneva, Radka

AU - Logothetis, Christopher J.

AU - Neuhausen, Susan L.

AU - Razack, Azad

AU - Newcomb, Lisa F.

AU - Gamulin, Marija

AU - Usmani, Nawaid

AU - Claessens, Frank

AU - Gago-Dominguez, Manuela

AU - Townsend, Paul A.

AU - Roobol, Monique J.

AU - Zheng, Wei

AU - Mills, Ian G.

AU - Andreassen, Ole A.

AU - Dale, Anders M.

AU - Seibert, Tyler M.

PY - 2021/6/1

Y1 - 2021/6/1

N2 - Background: Polygenic hazard scores (PHS) can identify individuals with increased risk of prostate cancer. We estimated the benefit of additional SNPs on performance of a previously validated PHS (PHS46). Materials and method: 180 SNPs, shown to be previously associated with prostate cancer, were used to develop a PHS model in men with European ancestry. A machine-learning approach, LASSO-regularized Cox regression, was used to select SNPs and to estimate their coefficients in the training set (75,596 men). Performance of the resulting model was evaluated in the testing/validation set (6,411 men) with two metrics: (1) hazard ratios (HRs) and (2) positive predictive value (PPV) of prostate-specific antigen (PSA) testing. HRs were estimated between individuals with PHS in the top 5% to those in the middle 40% (HR95/50), top 20% to bottom 20% (HR80/20), and bottom 20% to middle 40% (HR20/50). PPV was calculated for the top 20% (PPV80) and top 5% (PPV95) of PHS as the fraction of individuals with elevated PSA that were diagnosed with clinically significant prostate cancer on biopsy. Results: 166 SNPs had non-zero coefficients in the Cox model (PHS166). All HR metrics showed significant improvements for PHS166 compared to PHS46: HR95/50 increased from 3.72 to 5.09, HR80/20 increased from 6.12 to 9.45, and HR20/50 decreased from 0.41 to 0.34. By contrast, no significant differences were observed in PPV of PSA testing for clinically significant prostate cancer. Conclusions: Incorporating 120 additional SNPs (PHS166 vs PHS46) significantly improved HRs for prostate cancer, while PPV of PSA testing remained the same.

AB - Background: Polygenic hazard scores (PHS) can identify individuals with increased risk of prostate cancer. We estimated the benefit of additional SNPs on performance of a previously validated PHS (PHS46). Materials and method: 180 SNPs, shown to be previously associated with prostate cancer, were used to develop a PHS model in men with European ancestry. A machine-learning approach, LASSO-regularized Cox regression, was used to select SNPs and to estimate their coefficients in the training set (75,596 men). Performance of the resulting model was evaluated in the testing/validation set (6,411 men) with two metrics: (1) hazard ratios (HRs) and (2) positive predictive value (PPV) of prostate-specific antigen (PSA) testing. HRs were estimated between individuals with PHS in the top 5% to those in the middle 40% (HR95/50), top 20% to bottom 20% (HR80/20), and bottom 20% to middle 40% (HR20/50). PPV was calculated for the top 20% (PPV80) and top 5% (PPV95) of PHS as the fraction of individuals with elevated PSA that were diagnosed with clinically significant prostate cancer on biopsy. Results: 166 SNPs had non-zero coefficients in the Cox model (PHS166). All HR metrics showed significant improvements for PHS166 compared to PHS46: HR95/50 increased from 3.72 to 5.09, HR80/20 increased from 6.12 to 9.45, and HR20/50 decreased from 0.41 to 0.34. By contrast, no significant differences were observed in PPV of PSA testing for clinically significant prostate cancer. Conclusions: Incorporating 120 additional SNPs (PHS166 vs PHS46) significantly improved HRs for prostate cancer, while PPV of PSA testing remained the same.

UR - https://www.scopus.com/pages/publications/85102762943

U2 - 10.1038/s41391-020-00311-2

DO - 10.1038/s41391-020-00311-2

M3 - Article

C2 - 33420416

AN - SCOPUS:85102762943

SN - 1365-7852

VL - 24

SP - 532

EP - 541

JO - Prostate Cancer and Prostatic Diseases

JF - Prostate Cancer and Prostatic Diseases

IS - 2

ER -

Additional SNPs improve risk stratification of a polygenic hazard score for prostate cancer

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