Prediction of Individual Genetic Risk to Prostate Cancer Using a Polygenic Score

被引：47

作者：

Szulkin, Robert ^{[1
]}

Whitington, Thomas ^{[1
]}

Eklund, Martin ^{[1
]}

Aly, Markus ^{[1
,2
]}

Eeles, Rosalind A. ^{[3
,4
,5
]}

Easton, Douglas ^{[6
]}

Kote-Jarai, ZSofia ^{[3
]}

Al Olama, Ali Amin ^{[6
]}

Benlloch, Sara ^{[6
]}

Muir, Kenneth ^{[7
,8
]}

Giles, Graham G. ^{[9
,10
]}

Southey, Melissa C. ^{[11
]}

Fitzgerald, Liesel M. ^{[9
]}

Henderson, Brian E. ^{[12
]}

Schumacher, Fredrick ^{[12
]}

Haiman, Christopher A. ^{[12
]}

Schleutker, Johanna ^{[13
,14
,15
]}

Wahlfors, Tiina ^{[14
,15
]}

Tammela, Teuvo L. J. ^{[16
,17
]}

Nordestgaard, Borge G. ^{[18
,19
]}

Key, Tim J. ^{[20
]}

Travis, Ruth C. ^{[20
]}

Neal, David E. ^{[21
,22
]}

Donovan, Jenny L. ^{[23
]}

Hamdy, Freddie C. ^{[24
]}

Pharoah, Paul ^{[25
]}

Pashayan, Nora ^{[25
,26
]}

Khaw, Kay-Tee ^{[27
]}

Stanford, Janet L. ^{[28
,29
]}

Thibodeau, Stephen N. ^{[30
]}

McDonnell, Shannon K. ^{[30
]}

Schaid, Daniel J. ^{[30
]}

Maier, Christiane ^{[31
]}

Vogel, Walther ^{[32
]}

Luedeke, Manuel ^{[31
]}

Herkommer, Kathleen ^{[33
]}

Kibel, Adam S. ^{[34
]}

Cybulski, Cezary ^{[35
]}

Lubinski, Jan ^{[35
]}

Kluzniak, Wojciech ^{[35
]}

Cannon-Albright, Lisa ^{[36
,37
]}

Brenner, Hermann ^{[38
,39
,40
]}

Butterbach, Katja ^{[38
]}

Stegmaier, Christa ^{[41
]}

Park, Jong Y. ^{[42
]}

Sellers, Thomas ^{[42
]}

Lim, Hui-Yi ^{[43
]}

Slavov, Chavdar ^{[44
,45
]}

Kaneva, Radka ^{[46
]}

Mitev, Vanio ^{[46
]}

机构：

[1] Karolinska Inst, Dept Med Epidemiol & Biostat, Box 281, SE-17177 Stockholm, Sweden

[2] Danderyd Hosp, Dept Clin Sci, Stockholm, Sweden

[3] Inst Canc Res, London SW3 6JB, England

[4] Royal Marsden Natl Hlth Serv NHS Fdn Trust, London, England

[5] Royal Marsden Natl Hlth Serv NHS Fdn Trust, Sutton, Surrey, England

[6] Univ Cambridge, Strangeways Lab, Dept Publ Hlth & Primary Care, Ctr Canc Genet Epidemiol, Cambridge, England

[7] Univ Manchester, Inst Populat Hlth, Manchester, Lancs, England

[8] Univ Warwick, Warwick Med Sch, Coventry CV4 7AL, W Midlands, England

[9] Canc Council Victoria, Canc Epidemiol Ctr, Melbourne, Vic, Australia

[10] Univ Melbourne, Melbourne Sch Populat & Global Hlth, Ctr Epidemiol & Biostat, Melbourne, Vic 3010, Australia

[11] Univ Melbourne, Dept Pathol, Genet Epidemiol Lab, Melbourne, Vic 3010, Australia

[12] Univ So Calif, Keck Sch Med, Dept Prevent Med, Norris Comprehens Canc Ctr, Los Angeles, CA 90033 USA

[13] Univ Turku, Inst Biomed Kiinamyllynkatu 10, Dept Med Biochem & Genet, SF-20500 Turku, Finland

[14] Univ Tampere, BioMediTech, FIN-33101 Tampere, Finland

[15] FimLab Labs, Tampere, Finland

[16] Univ Tampere, Dept Urol, Tampere Univ Hosp, FIN-33101 Tampere, Finland

[17] Univ Tampere, Sch Med, FIN-33101 Tampere, Finland

[18] Copenhagen Univ Hosp, Herlev Hosp, Dept Clin Biochem, Herlev, Denmark

[19] Univ Copenhagen, Fac Hlth & Med Sci, DK-1168 Copenhagen, Denmark

[20] Univ Oxford, Nuffield Dept Populat Hlth, Canc Epidemiol, Oxford, England

[21] Univ Cambridge, Dept Oncol, Addenbrookes Hosp, Cambridge CB2 1TN, England

[22] Li Ka Shing Ctr, Canc Res UK Cambridge Res Inst, Cambridge, England

[23] Univ Bristol, Sch Social & Community Med, Bristol, Avon, England

[24] Univ Oxford, John Radcliffe Hosp, Fac Med Sci, Nuffield Dept Surg Sci, Oxford OX3 9DU, England

[25] Univ Cambridge, Dept Oncol, Strangeways Res Lab, Ctr Canc Genet Epidemiol, Cambridge, England

[26] UCL, London, England

[27] Univ Cambridge, Clin Gerontol Unit, Cambridge, England

[28] Fred Hutchinson Canc Res Ctr, Div Publ Hlth Sci, Seattle, WA 98104 USA

[29] Univ Washington, Sch Publ Hlth, Dept Epidemiol, Seattle, WA 98195 USA

[30] Mayo Clin, Rochester, MN USA

[31] Univ Hosp Ulm, Dept Urol, Ulm, Germany

[32] Univ Hosp Ulm, Inst Human Genet, Ulm, Germany

[33] Techn Univ Muenchen, Klinikum Rechts Isar, Dept Urol, Munich, Germany

[34] Brigham & Womens Hosp, Dana Farber Canc Inst, Div Urol Surg, Boston, MA 02115 USA

[35] Pomeranian Med Univ, Dept Genet & Pathol, Int Hereditary Canc Ctr, Szczecin, Poland

[36] Univ Utah, Sch Med, Dept Med, Div Genet Epidemiol, Salt Lake City, UT USA

[37] George E Wahlen Dept Vet Affairs Med Ctr, Salt Lake City, UT USA

[38] German Canc Res Ctr, Div Clin Epidemiol & Aging Res, Heidelberg, Germany

[39] German Canc Res Ctr, Div Prevent Oncol, Heidelberg, Germany

[40] German Canc Res Ctr, German Canc Consortium DKTK, Heidelberg, Germany

[41] Saarland Canc Registry, Saarbrucken, Germany

[42] H Lee Moffitt Canc Ctr & Res Inst, Dept Canc Epidemiol, Tampa, FL USA

[43] H Lee Moffitt Canc Ctr & Res Inst, Biostat Program, Tampa, FL USA

[44] Med Univ Sofia, Dept Urol, Sofia, Bulgaria

[45] Med Univ Sofia, Alexandrovska Univ Hosp, Sofia, Bulgaria

[46] Med Univ Sofia, Mol Med Ctr, Dept Med Chem & Biochem, Sofia, Bulgaria

[47] Queensland Univ Technol, Australian Prostate Canc Res Centre Qld, Inst Hlth & Biomed Innovat, Brisbane, Qld 4001, Australia

[48] Queensland Univ Technol, Sch Biomed Sci, Brisbane, Qld 4001, Australia

[49] Australian Prostate Canc BioResource, Brisbane, Qld, Australia

[50] Queensland Inst Med Res, Mol Canc Epidemiol Lab, Brisbane, Qld 4006, Australia

来源：

PROSTATE | 2015年 / 75卷 / 13期

基金：

英国医学研究理事会;

关键词：

prostate cancer; polygenic risk score; risk prediction; SUSCEPTIBILITY LOCI; BREAST; BRCA2; CONSORTIUM; VARIANTS;

D O I：

10.1002/pros.23037

中图分类号：

R5 [内科学];

学科分类号：

1002 ; 100201 ;

摘要：

BACKGROUND. Polygenic risk scores comprising established susceptibility variants have shown to be informative classifiers for several complex diseases including prostate cancer. For prostate cancer it is unknown if inclusion of genetic markers that have so far not been associated with prostate cancer risk at a genome-wide significant level will improve disease prediction. METHODS. We built polygenic risk scores in a large training set comprising over 25,000 individuals. Initially 65 established prostate cancer susceptibility variants were selected. After LD pruning additional variants were prioritized based on their association with prostate cancer. Six-fold cross validation was performed to assess genetic risk scores and optimize the number of additional variants to be included. The final model was evaluated in an independent study population including 1,370 cases and 1,239 controls. RESULTS. The polygenic risk score with 65 established susceptibility variants provided an area under the curve (AUC) of 0.67. Adding an additional 68 novel variants significantly increased the AUC to 0.68 (P-0012) and the net reclassification index with 0.21 (P-8.5 E-08). All novel variants were located in genomic regions established as associated with prostate cancer risk. CONCLUSIONS. Inclusion of additional genetic variants from established prostate cancer susceptibility regions improves disease prediction. (C) 2015 Wiley Periodicals, Inc.

引用

页码：1467 / 1474

页数：8

共 24 条

[1] Risk Analysis of Prostate Cancer in PRACTICAL, a Multinational Consortium, Using 25 Known Prostate Cancer Susceptibility Loci
Al Olama, Ali Amin
Benlloch, Sara
Antoniou, Antonis C.
Giles, Graham G.
Severi, Gianluca
Neal, David E.
Hamdy, Freddie C.
Donovan, Jenny L.
Muir, Kenneth
Schleutker, Johanna
Henderson, Brian E.
Haiman, Christopher A.
Schumacher, Fredrick R.
Pashayan, Nora
Pharoah, Paul D. P.
Ostrander, Elaine A.
Stanford, Janet L.
Batra, Jyotsna
Clements, Judith A.
Chambers, Suzanne K.
Weischer, Maren
Nordestgaard, Borge G.
Ingles, Sue A.
Sorensen, Karina D.
Orntoft, Torben F.
Park, Jong Y.
Cybulski, Cezary
Maier, Christiane
Doerk, Thilo
Dickinson, Joanne L.
Cannon-Albright, Lisa
Brenner, Hermann
Rebbeck, Timothy R.
Zeigler-Johnson, Charnita
Habuchi, Tomonori
Thibodeau, Stephen N.
Cooney, Kathleen A.
Chappuis, Pierre O.
Hutter, Pierre
Kaneva, Radka P.
Foulkes, William D.
Zeegers, Maurice P.
Lu, Yong-Jie
Zhang, Hong-Wei
Stephenson, Robert
Cox, Angela
Southey, Melissa C.
Spurdle, Amanda B.
FitzGerald, Liesel
Leongamornlert, Daniel
[J]. CANCER EPIDEMIOLOGY BIOMARKERS & PREVENTION, 2015, 24 (07) : 1121 - 1129
[2] A meta-analysis of 87,040 individuals identifies 23 new susceptibility loci for prostate cancer
Al Olama, Ali Amin
Kote-Jarai, Zsofia
Berndt, Sonja I.
Conti, David V.
Schumacher, Fredrick
Han, Ying
Benlloch, Sara
Hazelett, Dennis J.
Wang, Zhaoming
Saunders, Ed
Leongamornlert, Daniel
Lindstrom, Sara
Jugurnauth-Little, Sara
Dadaev, Tokhir
Tymrakiewicz, Malgorzata
Stram, Daniel O.
Rand, Kristin
Wan, Peggy
Stram, Alex
Sheng, Xin
Pooler, Loreall C.
Park, Karen
Xia, Lucy
Tyrer, Jonathan
Kolonel, Laurence N.
Le Marchand, Loic
Hoover, Robert N.
Machiela, Mitchell J.
Yeager, Merideth
Burdette, Laurie
Chung, Charles C.
Hutchinson, Amy
Yu, Kai
Goh, Chee
Ahmed, Mahbubl
Govindasami, Koveela
Guy, Michelle
Tammela, Teuvo L. J.
Auvinen, Anssi
Wahlfors, Tlina
Schleutker, Johanna
Visakorpi, Tapio
Leinonen, Katri A.
Xu, Jianfeng
Aly, Markus
Donovan, Jenny
Travis, Ruth C.
Key, Tim J.
Siddiq, Afshan
Canzian, Federico
[J]. NATURE GENETICS, 2014, 46 (10) : 1103 - 1109
[3] Polygenic Risk Score Improves Prostate Cancer Risk Prediction: Results from the Stockholm-1 Cohort Study
Aly, Markus
Wiklund, Fredrik
Xu, Jianfeng
Isaacs, William B.
Eklund, Martin
D'Amato, Mauro
Adolfsson, Jan
Gronberg, Henrik
[J]. EUROPEAN UROLOGY, 2011, 60 (01) : 21 - 28
[4] Targeted Prostate Cancer Screening in BRCA1 and BRCA2 Mutation Carriers: Results from the Initial Screening Round of the IMPACT Study
Bancroft, Elizabeth K.
Page, Elizabeth C.
Castro, Elena
Lilja, Hans
Vickers, Andrew
Sjoberg, Daniel
Assel, Melissa
Foster, Christopher S.
Mitchell, Gillian
Drew, Kate
Maehle, Lovise
Axcrona, Karol
Evans, D. Gareth
Bulman, Barbara
Eccles, Diana
McBride, Donna
van Asperen, Christi
Vasen, Hans
Kiemeney, Lambertus A.
Ringelberg, Janneke
Cybulski, Cezary
Wokolorczyk, Dominika
Selkirk, Christina
Hulick, Peter J.
Bojesen, Anders
Skytte, Anne-Bine
Lam, Jimmy
Taylor, Louise
Oldenburg, Rogier
Cremers, Ruben
Verhaegh, Gerald
van Zelst-Stams, Wendy A.
Oosterwijk, Jan C.
Blanco, Ignacio
Salinas, Monica
Cook, Jackie
Rosario, Derek J.
Buys, Saundra
Conner, Tom
Ausems, Margreet G.
Ong, Kai-ren
Hoffman, Jonathan
Domchek, Susan
Powers, Jacquelyn
Teixeira, Manuel R.
Maia, Sofia
Foulkes, William D.
Taherian, Nassim
Ruijs, Marielle
Helderman-van den Enden, Apollonia T.
[J]. EUROPEAN UROLOGY, 2014, 66 (03) : 489 - 499
[5] Breast Canc Linkage Consortium, 1999, JNCI-J NATL CANCER I, V91, P1310
[6] Projecting the performance of risk prediction based on polygenic analyses of genome-wide association studies
Chatterjee, Nilanjan
Wheeler, Bill
Sampson, Joshua
Hartge, Patricia
Chanock, Stephen J.
Park, Ju-Hyun
[J]. NATURE GENETICS, 2013, 45 (04) : 400 - 405
[7] COMPARING THE AREAS UNDER 2 OR MORE CORRELATED RECEIVER OPERATING CHARACTERISTIC CURVES - A NONPARAMETRIC APPROACH
DELONG, ER
DELONG, DM
CLARKEPEARSON, DI
[J]. BIOMETRICS, 1988, 44 (03) : 837 - 845
[8] Dubridge F, 2013, PLOS GENET, V9
[9] Identification of 23 new prostate cancer susceptibility loci using the iCOGS custom genotyping array
Eeles, Rosalind A.
Al Olama, Ali Amin
Benlloch, Sara
Saunders, Edward J.
Leongamornlert, Daniel A.
Tymrakiewicz, Malgorzata
Ghoussaini, Maya
Luccarini, Craig
Dennis, Joe
Jugurnauth-Little, Sarah
Dadaev, Tokhir
Neal, David E.
Hamdy, Freddie C.
Donovan, Jenny L.
Muir, Ken
Giles, Graham G.
Severi, Gianluca
Wiklund, Fredrik
Gronberg, Henrik
Haiman, Christopher A.
Schumacher, Fredrick
Henderson, Brian E.
Le Marchand, Loic
Lindstrom, Sara
Kraft, Peter
Hunter, David J.
Gapstur, Susan
Chanock, Stephen J.
Berndt, Sonja I.
Albanes, Demetrius
Andriole, Gerald
Schleutker, Johanna
Weischer, Maren
Canzian, Federico
Riboli, Elio
Key, Tim J.
Travis, Ruth C.
Campa, Daniele
Ingles, Sue A.
John, Esther M.
Hayes, Richard B.
Pharoah, Paul D. P.
Pashayan, Nora
Khaw, Kay-Tee
Stanford, Janet L.
Ostrander, Elaine A.
Signorello, Lisa B.
Thibodeau, Stephen N.
Schaid, Dan
Maier, Christiane
[J]. NATURE GENETICS, 2013, 45 (04) : 385 - 391
[10] The impact of genotype frequencies on the clinical validity of genomic profiling for predicting common chronic diseases
Janssens, A. Cecile J. W.
Moonesinghe, Ramal
Yang, Quahne
Steyerberg, Ewout W.
van Duijn, Cornelia M.
Khoury, Muin J.
[J]. GENETICS IN MEDICINE, 2007, 9 (08) : 528 - 535

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