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

UKGPCS collaborators; APCB BioResource (Australian Prostate Cancer BioResource); The IMPACT Study Steering Committee and Collaborators; Canary PASS Investigators; The Profile Study Steering Committee; The PRACTICAL consortium

doi:10.1038/s41391-020-00311-2

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

UKGPCS collaborators
, APCB BioResource (Australian Prostate Cancer BioResource)
, The IMPACT Study Steering Committee and Collaborators
, Canary PASS Investigators
, The Profile Study Steering Committee
, The PRACTICAL consortium

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

16 Scopus citations

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
State	Published - Jun 2021
Externally published	Yes

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10.1038/s41391-020-00311-2

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UKGPCS collaborators, APCB BioResource (Australian Prostate Cancer BioResource), The IMPACT Study Steering Committee and Collaborators, Canary PASS Investigators, The Profile Study Steering Committee, & The PRACTICAL 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{46cf9422744b4e4ebbfe2dbc81e0e8e7,

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 = "\{UKGPCS collaborators\} and \{APCB BioResource (Australian Prostate Cancer BioResource)\} and \{The IMPACT Study Steering Committee and Collaborators\} and \{Canary PASS Investigators\} and \{The Profile Study Steering Committee\} and \{The PRACTICAL consortium\} and 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 Jyotsna Batra and Henrik Gr{\"o}nberg 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",

note = "Publisher Copyright: {\textcopyright} 2021, The Author(s), under exclusive licence to Springer Nature Limited part of Springer Nature.",

year = "2021",

month = jun,

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

language = "Ingl{\'e}s",

volume = "24",

pages = "532--541",

journal = "Prostate Cancer and Prostatic Diseases",

issn = "1365-7852",

publisher = "Nature Publishing Group",

number = "2",

}

UKGPCS collaborators, APCB BioResource (Australian Prostate Cancer BioResource), The IMPACT Study Steering Committee and Collaborators, Canary PASS Investigators, The Profile Study Steering Committee & The PRACTICAL 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

Additional SNPs improve risk stratification of a polygenic hazard score for prostate cancer. / UKGPCS collaborators; APCB BioResource (Australian Prostate Cancer BioResource); The IMPACT Study Steering Committee and Collaborators et al.
In: Prostate Cancer and Prostatic Diseases, Vol. 24, No. 2, 06.2021, p. 532-541.

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

TY - JOUR

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

AU - UKGPCS collaborators

AU - APCB BioResource (Australian Prostate Cancer BioResource)

AU - The IMPACT Study Steering Committee and Collaborators

AU - Canary PASS Investigators

AU - The Profile Study Steering Committee

AU - The PRACTICAL consortium

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 - Batra, Jyotsna

AU - Grönberg, Henrik

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

PY - 2021/6

Y1 - 2021/6

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 - Artículo

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 -

UKGPCS collaborators, APCB BioResource (Australian Prostate Cancer BioResource), The IMPACT Study Steering Committee and Collaborators, Canary PASS Investigators, The Profile Study Steering Committee, The PRACTICAL consortium. Additional SNPs improve risk stratification of a polygenic hazard score for prostate cancer. Prostate Cancer and Prostatic Diseases. 2021 Jun;24(2):532-541. doi: 10.1038/s41391-020-00311-2

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

Abstract

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