Your search keyword '"Kolonel, LN"' showing total 727 results

1. Population Genetic Structure and Origins of Native Hawaiians in the Multiethnic Cohort Study

Author

Wall, Jeffrey, Kim, SK, Gignoux, CR, Wall, JD, Lum-Jones, A, Wang, H, Haiman, CA, Chen, GK, Henderson, BE, Kolonel, LN, and Le, L

Abstract

The population genetic structure of Native Hawaiians has yet to be comprehensively studied, and the ancestral origins of Polynesians remain in question. In this study, we utilized high-resolution genome-wide SNP data and mitochondrial genomes of 148 and 16

Published

2012

2. Genome-wide meta-analyses of smoking behaviors in African Americans.

Author

David, SP, Hamidovic, A, Chen, GK, Bergen, AW, Wessel, J, Kasberger, JL, Brown, WM, Petruzella, S, Thacker, EL, Kim, Y, Nalls, MA, Tranah, GJ, Sung, YJ, Ambrosone, CB, Arnett, D, Bandera, EV, Becker, DM, Becker, L, Berndt, SI, Bernstein, L, Blot, WJ, Broeckel, U, Buxbaum, SG, Caporaso, N, Casey, G, Chanock, SJ, Deming, SL, Diver, WR, Eaton, CB, Evans, DS, Evans, MK, Fornage, M, Franceschini, N, Harris, TB, Henderson, BE, Hernandez, DG, Hitsman, B, Hu, JJ, Hunt, SC, Ingles, SA, John, EM, Kittles, R, Kolb, S, Kolonel, LN, Le Marchand, L, Liu, Y, Lohman, KK, McKnight, B, Millikan, RC, Murphy, A, Neslund-Dudas, C, Nyante, S, Press, M, Psaty, BM, Rao, DC, Redline, S, Rodriguez-Gil, JL, Rybicki, BA, Signorello, LB, Singleton, AB, Smoller, J, Snively, B, Spring, B, Stanford, JL, Strom, SS, Swan, GE, Taylor, KD, Thun, MJ, Wilson, AF, Witte, JS, Yamamura, Y, Yanek, LR, Yu, K, Zheng, W, Ziegler, RG, Zonderman, AB, Jorgenson, E, Haiman, CA, and Furberg, H

Subjects

Chromosomes, Human, Pair 10, Chromosomes, Human, Pair 15, Humans, Genetic Predisposition to Disease, Proteoglycans, Receptors, Nicotinic, Nerve Tissue Proteins, Smoking, Genotype, Phenotype, Polymorphism, Single Nucleotide, Adult, Aged, Middle Aged, African Americans, Female, Male, Statistics as Topic, Genetic Variation, Genome-Wide Association Study, Genetic Loci, African American, genome-wide association, health disparities, nicotine, smoking, tobacco, Chromosomes, Human, Pair 10, Pair 15, Polymorphism, Single Nucleotide, Receptors, Nicotinic, Clinical Sciences, Public Health and Health Services, Psychology

Abstract

The identification and exploration of genetic loci that influence smoking behaviors have been conducted primarily in populations of the European ancestry. Here we report results of the first genome-wide association study meta-analysis of smoking behavior in African Americans in the Study of Tobacco in Minority Populations Genetics Consortium (n = 32,389). We identified one non-coding single-nucleotide polymorphism (SNP; rs2036527[A]) on chromosome 15q25.1 associated with smoking quantity (cigarettes per day), which exceeded genome-wide significance (β = 0.040, s.e. = 0.007, P = 1.84 × 10(-8)). This variant is present in the 5'-distal enhancer region of the CHRNA5 gene and defines the primary index signal reported in studies of the European ancestry. No other SNP reached genome-wide significance for smoking initiation (SI, ever vs never smoking), age of SI, or smoking cessation (SC, former vs current smoking). Informative associations that approached genome-wide significance included three modestly correlated variants, at 15q25.1 within PSMA4, CHRNA5 and CHRNA3 for smoking quantity, which are associated with a second signal previously reported in studies in European ancestry populations, and a signal represented by three SNPs in the SPOCK2 gene on chr10q22.1. The association at 15q25.1 confirms this region as an important susceptibility locus for smoking quantity in men and women of African ancestry. Larger studies will be needed to validate the suggestive loci that did not reach genome-wide significance and further elucidate the contribution of genetic variation to disparities in cigarette consumption, SC and smoking-attributable disease between African Americans and European Americans.

Published

2012

3. Germline variation at 8q24 and prostate cancer risk in men of European ancestry (vol 9, 4616, 2018)

Author

Matejcic, M, Saunders, EJ, Dadaev, T, Brook, MN, Wang, K, Sheng, X, Al Olama, AA, Schumacher, FR, Ingles, SA, Govindasami, K, Benlloch, S, Berndt, SI, Albanes, D, Koutros, S, Muir, K, Stevens, VL, Gapstur, SM, Tangen, CM, Batra, J, Clements, J, Gronberg, H, Pashayan, N, Schleutker, J, Wolk, A, West, C, Mucci, L, Kraft, P, Cancel-Tassin, G, Sorensen, KD, Maehle, L, Grindedal, EM, Strom, SS, Neal, DE, Hamdy, FC, Donovan, JL, Travis, RC, Hamilton, RJ, Rosenstein, B, Lu, Y-J, Giles, GG, Kibel, AS, Vega, A, Bensen, JT, Kogevinas, M, Penney, KL, Park, JY, Stanford, JL, Cybulski, C, Nordestgaard, BG, Brenner, H, Maier, C, Kim, J, Teixeira, MR, Neuhausen, SL, De Ruyck, K, Razack, A, Newcomb, LF, Lessel, D, Kaneva, R, Usmani, N, Claessens, F, Townsend, PA, Gago-Dominguez, M, Roobol, MJ, Menegaux, F, Khaw, K-T, Cannon-Albright, LA, Pandha, H, Thibodeau, SN, Schaid, DJ, Wiklund, F, Chanock, SJ, Easton, DF, Eeles, RA, Kote-Jarai, Z, Conti, DV, Haiman, CA, Henderson, BE, Stern, MC, Thwaites, A, Guy, M, Whitmore, I, Morgan, A, Fisher, C, Hazel, S, Livni, N, Cook, M, Fachal, L, Weinstein, S, Freeman, LEB, Hoover, RN, Machiela, MJ, Lophatananon, A, Carter, BD, Goodman, P, Moya, L, Srinivasan, S, Kedda, M-A, Yeadon, T, Eckert, A, Eklund, M, Cavalli-Bjoerkman, C, Dunning, AM, Sipeky, C, Hakansson, N, Elliott, R, Ranu, H, Giovannucci, E, Turman, C, Hunter, DJ, Cussenot, O, Orntoft, TF, Lane, A, Lewis, SJ, Davis, M, Key, TJ, Brown, P, Kulkarni, GS, Zlotta, AR, Fleshner, NE, Finelli, A, Mao, X, Marzec, J, MacInnis, RJ, Milne, R, Hopper, JL, Aguado, M, Bustamante, M, Castano-Vinyals, G, Gracia-Lavedan, E, Cecchini, L, Stampfer, M, Ma, J, Sellers, TA, Geybels, MS, Park, H, Zachariah, B, Kolb, S, Wokolorczyk, D, Lubinski, J, Kluzniak, W, Nielsen, SF, Weisher, M, Cuk, K, Vogel, W, Luedeke, M, Logothetis, CJ, Paulo, P, Cardoso, M, Maia, S, Silva, MP, Steele, L, Ding, YC, De Meerleer, G, De Langhe, S, Thierens, H, Lim, J, Tan, MH, Ong, AT, Lin, DW, Kachakova, D, Mitkova, A, Mitev, V, Parliament, M, Jenster, G, Bangma, C, Schroder, FH, Truong, T, Koudou, YA, Michael, A, Kierzek, A, Karlsson, A, Broms, M, Wu, H, Aukim-Hastie, C, Tillmans, L, Riska, S, McDonnell, SK, Dearnaley, D, Spurdle, A, Gardiner, R, Hayes, V, Butler, L, Taylor, R, Papargiris, M, Saunders, P, Kujala, P, Talala, K, Taari, K, Bentzen, S, Hicks, B, Vogt, A, Hutchinson, A, Cox, A, George, A, Toi, A, Evans, A, Van der Kwast, TH, Imai, T, Saito, S, Zhao, S-C, Ren, G, Zhang, Y, Yu, Y, Wu, Y, Wu, J, Zhou, B, Pedersen, J, Lobato-Busto, R, Manuel Ruiz-Dominguez, J, Mengual, L, Alcaraz, A, Pow-Sang, J, Herkommer, K, Vlahova, A, Dikov, T, Christova, S, Carracedo, A, Tretarre, B, Rebillard, X, Mulot, C, Adolfsson, J, Stattin, P, Johansson, J-E, Martin, RM, Thompson, IM, Chambers, S, Aitken, J, Horvath, L, Haynes, A-M, Tilley, W, Risbridger, G, Aly, M, Nordstrom, T, Pharoah, P, Tammela, TLJ, Murtola, T, Auvinen, A, Burnet, N, Barnett, G, Andriole, G, Klim, A, Drake, BF, Borre, M, Kerns, S, Ostrer, H, Zhang, H-W, Cao, G, Lin, J, Ling, J, Li, M, Feng, N, Li, J, He, W, Guo, X, Sun, Z, Wang, G, Guo, J, Southey, MC, FitzGerald, LM, Marsden, G, Gomez-Caamano, A, Carballo, A, Peleteiro, P, Calvo, P, Szulkin, R, Llorca, J, Dierssen-Sotos, T, Gomez-Acebo, I, Lin, H-Y, Ostrander, EA, Bisbjerg, R, Klarskov, P, Roder, MA, Iversen, P, Holleczek, B, Stegmaier, C, Schnoeller, T, Bohnert, P, John, EM, Ost, P, Teo, S-H, Gamulin, M, Kulis, T, Kastelan, Z, Slavov, C, Popov, E, Van den Broeck, T, Joniau, S, Larkin, S, Esteban Castelao, J, Martinez, ME, Van Schaik, RHN, Xu, J, Lindstrom, S, Riboli, E, Berry, C, Siddiq, A, Canzian, F, Kolonel, LN, Le Marchand, L, Freedman, M, Cenee, S, Sanchez, M, and Commission of the European Communities

Subjects

Multidisciplinary Sciences, Science & Technology, MD Multidisciplinary, Science & Technology - Other Topics, PRACTICAL Consortium

Abstract

Correction to: Nature Communications; https://doi.org/10.1038/s41467-018-06863-1, published online 5 November 2018.

Published

2019

4. Novel Common Genetic Susceptibility Loci for Colorectal Cancer

Author

Schmit, SL, Edlund, CK, Schumacher, FR, Gong, J, Harrison, TA, Huyghe, JR, Qu, C, Melas, M, Van den Berg, DJ, Wang, H, Tring, S, Plummer, SJ, Albanes, D, Alonso, MH, Amos, CI, Anton, K, Aragaki, AK, Arndt, V, Barry, EL, Berndt, SI, Bezieau, S, Bien, S, Bloomer, A, Boehm, J, Boutron-Ruault, M-C, Brenner, H, Brezina, S, Buchanan, DD, Butterbach, K, Caan, BJ, Campbell, PT, Carlson, CS, Castelao, JE, Chan, AT, Chang-Claude, J, Chanock, SJ, Cheng, I, Cheng, Y-W, Chin, LS, Church, JM, Church, T, Coetzee, GA, Cotterchio, M, Correa, MC, Curtis, KR, Duggan, D, Easton, DF, English, D, Feskens, EJM, Fischer, R, FitzGerald, LM, Fortini, BK, Fritsche, LG, Fuchs, CS, Gago-Dominguez, M, Gala, M, Gallinger, SJ, Gauderman, WJ, Giles, GG, Giovannucci, EL, Gogarten, SM, Gonzalez-Villalpando, C, Gonzalez-Villalpando, EM, Grady, WM, Greenson, JK, Gsur, A, Gunter, M, Haiman, CA, Hampe, J, Harlid, S, Harju, JF, Hayes, RB, Hofer, P, Hoffmeister, M, Hopper, JL, Huang, S-C, Huerta, JM, Hudson, TJ, Hunter, DJ, Idos, GE, Iwasaki, M, Jackson, RD, Jacobs, EJ, Jee, SH, Jenkins, MA, Jia, W-H, Jiao, S, Joshi, AD, Kolonel, LN, Kono, S, Kooperberg, C, Krogh, V, Kuehn, T, Kury, S, LaCroix, A, Laurie, CA, Lejbkowicz, F, Lemire, M, Lenz, H-J, Levine, D, Li, CI, Li, L, Lieb, W, Lin, Y, Lindor, NM, Liu, Y-R, Loupakis, F, Lu, Y, Luh, F, Ma, J, Mancao, C, Manion, FJ, Markowitz, SD, Martin, V, Matsuda, K, Matsuo, K, McDonnell, KJ, McNeil, CE, Milne, R, Molina, AJ, Mukherjee, B, Murphy, N, Newcomb, PA, Offit, K, Omichessan, H, Palli, D, Cotore, JPP, Perez-Mayoral, J, Pharoah, PD, Potter, JD, Raskin, L, Rennert, G, Rennert, HS, Riggs, BM, Schafmayer, C, Schoen, RE, Sellers, TA, Seminara, D, Severi, G, Shi, W, Shibata, D, Shu, X-O, Siegel, EM, Slattery, ML, Southey, M, Stadler, ZK, Stern, MC, Stintzing, S, Taverna, D, Thibodeau, SN, Thomas, DC, Trichopoulou, A, Tsugane, S, Ulrich, CM, van Duijnhoven, FJB, van Guelpan, B, Vijai, J, Virtamo, J, Weinstein, SJ, White, E, Win, AK, Wolk, A, Woods, M, Wu, AH, Wu, K, Xiang, Y-B, Yen, Y, Zanke, BW, Zeng, Y-X, Zhang, B, Zubair, N, Kweon, S-S, Figueiredo, JC, Zheng, W, Le Marchand, L, Lindblom, A, Moreno, V, Peters, U, Casey, G, Hsu, L, Conti, DV, Gruber, SB, Schmit, SL, Edlund, CK, Schumacher, FR, Gong, J, Harrison, TA, Huyghe, JR, Qu, C, Melas, M, Van den Berg, DJ, Wang, H, Tring, S, Plummer, SJ, Albanes, D, Alonso, MH, Amos, CI, Anton, K, Aragaki, AK, Arndt, V, Barry, EL, Berndt, SI, Bezieau, S, Bien, S, Bloomer, A, Boehm, J, Boutron-Ruault, M-C, Brenner, H, Brezina, S, Buchanan, DD, Butterbach, K, Caan, BJ, Campbell, PT, Carlson, CS, Castelao, JE, Chan, AT, Chang-Claude, J, Chanock, SJ, Cheng, I, Cheng, Y-W, Chin, LS, Church, JM, Church, T, Coetzee, GA, Cotterchio, M, Correa, MC, Curtis, KR, Duggan, D, Easton, DF, English, D, Feskens, EJM, Fischer, R, FitzGerald, LM, Fortini, BK, Fritsche, LG, Fuchs, CS, Gago-Dominguez, M, Gala, M, Gallinger, SJ, Gauderman, WJ, Giles, GG, Giovannucci, EL, Gogarten, SM, Gonzalez-Villalpando, C, Gonzalez-Villalpando, EM, Grady, WM, Greenson, JK, Gsur, A, Gunter, M, Haiman, CA, Hampe, J, Harlid, S, Harju, JF, Hayes, RB, Hofer, P, Hoffmeister, M, Hopper, JL, Huang, S-C, Huerta, JM, Hudson, TJ, Hunter, DJ, Idos, GE, Iwasaki, M, Jackson, RD, Jacobs, EJ, Jee, SH, Jenkins, MA, Jia, W-H, Jiao, S, Joshi, AD, Kolonel, LN, Kono, S, Kooperberg, C, Krogh, V, Kuehn, T, Kury, S, LaCroix, A, Laurie, CA, Lejbkowicz, F, Lemire, M, Lenz, H-J, Levine, D, Li, CI, Li, L, Lieb, W, Lin, Y, Lindor, NM, Liu, Y-R, Loupakis, F, Lu, Y, Luh, F, Ma, J, Mancao, C, Manion, FJ, Markowitz, SD, Martin, V, Matsuda, K, Matsuo, K, McDonnell, KJ, McNeil, CE, Milne, R, Molina, AJ, Mukherjee, B, Murphy, N, Newcomb, PA, Offit, K, Omichessan, H, Palli, D, Cotore, JPP, Perez-Mayoral, J, Pharoah, PD, Potter, JD, Raskin, L, Rennert, G, Rennert, HS, Riggs, BM, Schafmayer, C, Schoen, RE, Sellers, TA, Seminara, D, Severi, G, Shi, W, Shibata, D, Shu, X-O, Siegel, EM, Slattery, ML, Southey, M, Stadler, ZK, Stern, MC, Stintzing, S, Taverna, D, Thibodeau, SN, Thomas, DC, Trichopoulou, A, Tsugane, S, Ulrich, CM, van Duijnhoven, FJB, van Guelpan, B, Vijai, J, Virtamo, J, Weinstein, SJ, White, E, Win, AK, Wolk, A, Woods, M, Wu, AH, Wu, K, Xiang, Y-B, Yen, Y, Zanke, BW, Zeng, Y-X, Zhang, B, Zubair, N, Kweon, S-S, Figueiredo, JC, Zheng, W, Le Marchand, L, Lindblom, A, Moreno, V, Peters, U, Casey, G, Hsu, L, Conti, DV, and Gruber, SB

Abstract

BACKGROUND: Previous genome-wide association studies (GWAS) have identified 42 loci (P < 5 × 10-8) associated with risk of colorectal cancer (CRC). Expanded consortium efforts facilitating the discovery of additional susceptibility loci may capture unexplained familial risk. METHODS: We conducted a GWAS in European descent CRC cases and control subjects using a discovery-replication design, followed by examination of novel findings in a multiethnic sample (cumulative n = 163 315). In the discovery stage (36 948 case subjects/30 864 control subjects), we identified genetic variants with a minor allele frequency of 1% or greater associated with risk of CRC using logistic regression followed by a fixed-effects inverse variance weighted meta-analysis. All novel independent variants reaching genome-wide statistical significance (two-sided P < 5 × 10-8) were tested for replication in separate European ancestry samples (12 952 case subjects/48 383 control subjects). Next, we examined the generalizability of discovered variants in East Asians, African Americans, and Hispanics (12 085 case subjects/22 083 control subjects). Finally, we examined the contributions of novel risk variants to familial relative risk and examined the prediction capabilities of a polygenic risk score. All statistical tests were two-sided. RESULTS: The discovery GWAS identified 11 variants associated with CRC at P < 5 × 10-8, of which nine (at 4q22.2/5p15.33/5p13.1/6p21.31/6p12.1/10q11.23/12q24.21/16q24.1/20q13.13) independently replicated at a P value of less than .05. Multiethnic follow-up supported the generalizability of discovery findings. These results demonstrated a 14.7% increase in familial relative risk explained by common risk alleles from 10.3% (95% confidence interval [CI] = 7.9% to 13.7%; known variants) to 11.9% (95% CI = 9.2% to 15.5%; known and novel variants). A polygenic risk score identified 4.3% of the population at an odds ratio for developing CRC of at least 2.0. CONCLUSIONS: T

Published

2019

5. Discovery of common and rare genetic risk variants for colorectal cancer

Author

Huyghe, JR, Bien, SA, Harrison, TA, Kang, HM, Chen, S, Schmit, SL, Conti, DV, Qu, C, Jeon, J, Edlund, CK, Greenside, P, Wainberg, M, Schumacher, FR, Smith, JD, Levine, DM, Nelson, SC, Sinnott-Armstrong, NA, Albanes, D, Alonso, MH, Anderson, K, Arnau-Collell, C, Arndt, V, Bamia, C, Banbury, BL, Baron, JA, Berndt, SI, Bezieau, S, Bishop, DT, Boehm, J, Boeing, H, Brenner, H, Brezina, S, Buch, S, Buchanan, DD, Burnett-Hartman, A, Butterbach, K, Caan, BJ, Campbell, PT, Carlson, CS, Castellvi-Bel, S, Chan, AT, Chang-Claude, J, Chanock, SJ, Chirlaque, M-D, Cho, SH, Connolly, CM, Cross, AJ, Cuk, K, Curtis, KR, de la Chapelle, A, Doheny, KF, Duggan, D, Easton, DF, Elias, SG, Elliott, F, English, DR, Feskens, EJM, Figueiredo, JC, Fischer, R, FitzGerald, LM, Forman, D, Gala, M, Gallinger, S, Gauderman, WJ, Giles, GG, Gillanders, E, Gong, J, Goodman, PJ, Grady, WM, Grove, JS, Gsur, A, Gunter, MJ, Haile, RW, Hampe, J, Hampel, H, Harlid, S, Hayes, RB, Hofer, P, Hoffmeister, M, Hopper, JL, Hsu, W-L, Huang, W-Y, Hudson, TJ, Hunter, DJ, Ibanez-Sanz, G, Idos, GE, Ingersoll, R, Jackson, RD, Jacobs, EJ, Jenkins, MA, Joshi, AD, Joshu, CE, Keku, TO, Key, TJ, Kim, HR, Kobayashi, E, Kolonel, LN, Kooperberg, C, Kuehn, T, Kury, S, Kweon, S-S, Larsson, SC, Laurie, CA, Le Marchand, L, Leal, SM, Lee, SC, Lejbkowicz, F, Lemire, M, Li, CI, Li, L, Lieb, W, Lin, Y, Lindblom, A, Lindor, NM, Ling, H, Louie, TL, Mannisto, S, Markowitz, SD, Martin, V, Masala, G, McNeil, CE, Melas, M, Milne, RL, Moreno, L, Murphy, N, Myte, R, Naccarati, A, Newcomb, PA, Offit, K, Ogino, S, Onland-Moret, NC, Pardini, B, Parfrey, PS, Pearlman, R, Perduca, V, Pharoah, PDP, Pinchev, M, Platz, EA, Prentice, RL, Pugh, E, Raskin, L, Rennert, G, Rennert, HS, Riboli, E, Rodriguez-Barranco, M, Romm, J, Sakoda, LC, Schafmayer, C, Schoen, RE, Seminara, D, Shah, M, Shelford, T, Shin, M-H, Shulman, K, Sieri, S, Slattery, ML, Southey, MC, Stadler, ZK, Stegmaier, C, Su, Y-R, Tangen, CM, Thibodeau, SN, Thomas, DC, Thomas, SS, Toland, AE, Trichopoulou, A, Ulrich, CM, Van den Berg, DJ, van Duijnhoven, FJB, Van Guelpen, B, van Kranen, H, Vijai, J, Visvanathan, K, Vodicka, P, Vodickova, L, Vymetalkova, V, Weigl, K, Weinstein, SJ, White, E, Win, AK, Wolf, CR, Wolk, A, Woods, MO, Wu, AH, Zaidi, SH, Zanke, BW, Zhang, Q, Zheng, W, Scacheri, PC, Potter, JD, Bassik, MC, Kundaje, A, Casey, G, Moreno, V, Abecasis, GR, Nickerson, DA, Gruber, SB, Hsu, L, Peters, U, Huyghe, JR, Bien, SA, Harrison, TA, Kang, HM, Chen, S, Schmit, SL, Conti, DV, Qu, C, Jeon, J, Edlund, CK, Greenside, P, Wainberg, M, Schumacher, FR, Smith, JD, Levine, DM, Nelson, SC, Sinnott-Armstrong, NA, Albanes, D, Alonso, MH, Anderson, K, Arnau-Collell, C, Arndt, V, Bamia, C, Banbury, BL, Baron, JA, Berndt, SI, Bezieau, S, Bishop, DT, Boehm, J, Boeing, H, Brenner, H, Brezina, S, Buch, S, Buchanan, DD, Burnett-Hartman, A, Butterbach, K, Caan, BJ, Campbell, PT, Carlson, CS, Castellvi-Bel, S, Chan, AT, Chang-Claude, J, Chanock, SJ, Chirlaque, M-D, Cho, SH, Connolly, CM, Cross, AJ, Cuk, K, Curtis, KR, de la Chapelle, A, Doheny, KF, Duggan, D, Easton, DF, Elias, SG, Elliott, F, English, DR, Feskens, EJM, Figueiredo, JC, Fischer, R, FitzGerald, LM, Forman, D, Gala, M, Gallinger, S, Gauderman, WJ, Giles, GG, Gillanders, E, Gong, J, Goodman, PJ, Grady, WM, Grove, JS, Gsur, A, Gunter, MJ, Haile, RW, Hampe, J, Hampel, H, Harlid, S, Hayes, RB, Hofer, P, Hoffmeister, M, Hopper, JL, Hsu, W-L, Huang, W-Y, Hudson, TJ, Hunter, DJ, Ibanez-Sanz, G, Idos, GE, Ingersoll, R, Jackson, RD, Jacobs, EJ, Jenkins, MA, Joshi, AD, Joshu, CE, Keku, TO, Key, TJ, Kim, HR, Kobayashi, E, Kolonel, LN, Kooperberg, C, Kuehn, T, Kury, S, Kweon, S-S, Larsson, SC, Laurie, CA, Le Marchand, L, Leal, SM, Lee, SC, Lejbkowicz, F, Lemire, M, Li, CI, Li, L, Lieb, W, Lin, Y, Lindblom, A, Lindor, NM, Ling, H, Louie, TL, Mannisto, S, Markowitz, SD, Martin, V, Masala, G, McNeil, CE, Melas, M, Milne, RL, Moreno, L, Murphy, N, Myte, R, Naccarati, A, Newcomb, PA, Offit, K, Ogino, S, Onland-Moret, NC, Pardini, B, Parfrey, PS, Pearlman, R, Perduca, V, Pharoah, PDP, Pinchev, M, Platz, EA, Prentice, RL, Pugh, E, Raskin, L, Rennert, G, Rennert, HS, Riboli, E, Rodriguez-Barranco, M, Romm, J, Sakoda, LC, Schafmayer, C, Schoen, RE, Seminara, D, Shah, M, Shelford, T, Shin, M-H, Shulman, K, Sieri, S, Slattery, ML, Southey, MC, Stadler, ZK, Stegmaier, C, Su, Y-R, Tangen, CM, Thibodeau, SN, Thomas, DC, Thomas, SS, Toland, AE, Trichopoulou, A, Ulrich, CM, Van den Berg, DJ, van Duijnhoven, FJB, Van Guelpen, B, van Kranen, H, Vijai, J, Visvanathan, K, Vodicka, P, Vodickova, L, Vymetalkova, V, Weigl, K, Weinstein, SJ, White, E, Win, AK, Wolf, CR, Wolk, A, Woods, MO, Wu, AH, Zaidi, SH, Zanke, BW, Zhang, Q, Zheng, W, Scacheri, PC, Potter, JD, Bassik, MC, Kundaje, A, Casey, G, Moreno, V, Abecasis, GR, Nickerson, DA, Gruber, SB, Hsu, L, and Peters, U

Abstract

To further dissect the genetic architecture of colorectal cancer (CRC), we performed whole-genome sequencing of 1,439 cases and 720 controls, imputed discovered sequence variants and Haplotype Reference Consortium panel variants into genome-wide association study data, and tested for association in 34,869 cases and 29,051 controls. Findings were followed up in an additional 23,262 cases and 38,296 controls. We discovered a strongly protective 0.3% frequency variant signal at CHD1. In a combined meta-analysis of 125,478 individuals, we identified 40 new independent signals at P < 5 × 10-8, bringing the number of known independent signals for CRC to ~100. New signals implicate lower-frequency variants, Krüppel-like factors, Hedgehog signaling, Hippo-YAP signaling, long noncoding RNAs and somatic drivers, and support a role for immune function. Heritability analyses suggest that CRC risk is highly polygenic, and larger, more comprehensive studies enabling rare variant analysis will improve understanding of biology underlying this risk and influence personalized screening strategies and drug development.

Published

2019

6. Fine-mapping of prostate cancer susceptibility loci in a large meta-analysis identifies candidate causal variants

Author

Dadaev, T, Saunders, EJ, Newcombe, PJ, Anokian, E, Leongamornlert, DA, Brook, MN, Cieza-Borrella, C, Mijuskovic, M, Wakerell, S, Olama, AAA, Schumacher, FR, Berndt, SI, Benlloch, S, Ahmed, M, Goh, C, Sheng, X, Zhang, Z, Muir, K, Govindasami, K, Lophatananon, A, Stevens, VL, Gapstur, SM, Carter, BD, Tangen, CM, Goodman, P, Thompson, IM, Batra, J, Chambers, S, Moya, L, Clements, J, Horvath, L, Tilley, W, Risbridger, G, Gronberg, H, Aly, M, Nordström, T, Pharoah, P, Pashayan, N, Schleutker, J, Tammela, TLJ, Sipeky, C, Auvinen, A, Albanes, D, Weinstein, S, Wolk, A, Hakansson, N, West, C, Dunning, AM, Burnet, N, Mucci, L, Giovannucci, E, Andriole, G, Cussenot, O, Cancel-Tassin, G, Koutros, S, Freeman, LEB, Sorensen, KD, Orntoft, TF, Borre, M, Maehle, L, Grindedal, EM, Neal, DE, Donovan, JL, Hamdy, FC, Martin, RM, Travis, RC, Key, TJ, Hamilton, RJ, Fleshner, NE, Finelli, A, Ingles, SA, Stern, MC, Rosenstein, B, Kerns, S, Ostrer, H, Lu, Y-J, Zhang, H-W, Feng, N, Mao, X, Guo, X, Wang, G, Sun, Z, Giles, GG, Southey, MC, Macinnis, RJ, Fitzgerald, LM, Kibel, AS, Drake, BF, Vega, A, Gómez-Caamaño, A, Fachal, L, Szulkin, R, Eklund, M, Kogevinas, M, Llorca, J, Castaño-Vinyals, G, Penney, KL, Stampfer, M, Park, JY, Sellers, TA, Lin, H-Y, Stanford, JL, Cybulski, C, Wokolorczyk, D, Lubinski, J, Ostrander, EA, Geybels, MS, Nordestgaard, BG, Nielsen, SF, Weisher, M, Bisbjerg, R, Røder, MA, Iversen, P, Brenner, H, Cuk, K, Holleczek, B, Maier, C, Luedeke, M, Schnoeller, T, Kim, J, Logothetis, CJ, John, EM, Teixeira, MR, Paulo, P, Cardoso, M, Neuhausen, SL, Steele, L, Ding, YC, De Ruyck, K, De Meerleer, G, Ost, P, Razack, A, Lim, J, Teo, S-H, Lin, DW, Newcomb, LF, Lessel, D, Gamulin, M, Kulis, T, Kaneva, R, Usmani, N, Slavov, C, Mitev, V, Parliament, M, Singhal, S, Claessens, F, Joniau, S, Van Den Broeck, T, Larkin, S, Townsend, PA, Aukim-Hastie, C, Gago-Dominguez, M, Castelao, JE, Martinez, ME, Roobol, MJ, Jenster, G, Van Schaik, RHN, Menegaux, F, Truong, T, Koudou, YA, Xu, J, Khaw, K-T, Cannon-Albright, L, Pandha, H, Michael, A, Kierzek, A, Thibodeau, SN, McDonnell, SK, Schaid, DJ, Lindstrom, S, Turman, C, Ma, J, Hunter, DJ, Riboli, E, Siddiq, A, Canzian, F, Kolonel, LN, Le Marchand, L, Hoover, RN, Machiela, MJ, Kraft, P, Consortium, Practical (Prostate Cancer Association Group To Investigate Cancer-Associated Alterations In The Genome), Freedman, M, Wiklund, F, Chanock, S, Henderson, BE, Easton, DF, Haiman, CA, Eeles, RA, Conti, DV, Kote-Jarai, Z, Dadaev, Tokhir [0000-0002-8268-0438], Leongamornlert, Daniel A [0000-0002-3486-3168], Brook, Mark N [0000-0002-8969-2378], Olama, Ali Amin Al [0000-0002-7178-3431], Schumacher, Fredrick R [0000-0002-3073-7463], Muir, Kenneth [0000-0001-6429-988X], Batra, Jyotsna [0000-0003-4646-6247], Nordström, Tobias [0000-0003-4915-7546], Pharoah, Paul [0000-0001-8494-732X], Pashayan, Nora [0000-0003-0843-2468], Schleutker, Johanna [0000-0002-1863-0305], Sipeky, Csilla [0000-0002-8853-4722], Wolk, Alicja [0000-0001-7387-6845], Cancel-Tassin, Géraldine [0000-0002-9583-6382], Sorensen, Karina Dalsgaard [0000-0002-4902-5490], Kerns, Sarah [0000-0002-6503-0011], Ostrer, Harry [0000-0002-2209-5376], Fachal, Laura [0000-0002-7256-9752], Kogevinas, Manolis [0000-0002-9605-0461], Nordestgaard, Børge G [0000-0002-1954-7220], Lim, Jasmine [0000-0002-7501-1834], Truong, Thérèse [0000-0002-2943-6786], Xu, Jianfeng [0000-0002-1343-8752], Easton, Douglas F [0000-0003-2444-3247], Eeles, Rosalind A [0000-0002-3698-6241], Apollo - University of Cambridge Repository, National Institutes of Health, Urology, and Clinical Chemistry

Subjects

Male, Risk, Science, GENETIC, Quantitative Trait Loci, Black People, PRACTICAL (Prostate Cancer Association Group to Investigate Cancer-Associated Alterations in the Genome) Consortium, urologic and male genital diseases, ANNOTATION, Polymorphism, Single Nucleotide, Article, White People, REGION, GENETIC ASSOCIATION, SDG 3 - Good Health and Well-being, MD Multidisciplinary, Medicine and Health Sciences, ELEMENTS, Humans, Genetic Predisposition to Disease, GENOME-WIDE ASSOCIATION, lcsh:Science, Medicinsk genetik, MODEL SELECTION, BAYESIAN FRAMEWORK, Cancer och onkologi, Science & Technology, Chromosome Mapping, Prostatic Neoplasms, Bayes Theorem, Molecular Sequence Annotation, ASSOCIATION, JOINT ANALYSIS, RISK LOCI, STATISTICS, Multidisciplinary Sciences, Cancer and Oncology, Multivariate Analysis, Science & Technology - Other Topics, lcsh:Q, Medical Genetics, Algorithms, VARIABLE-SELECTION, Genome-Wide Association Study

Abstract

Prostate cancer is a polygenic disease with a large heritable component. A number of common, low-penetrance prostate cancer risk loci have been identified through GWAS. Here we apply the Bayesian multivariate variable selection algorithm JAM to fine-map 84 prostate cancer susceptibility loci, using summary data from a large European ancestry meta-analysis. We observe evidence for multiple independent signals at 12 regions and 99 risk signals overall. Only 15 original GWAS tag SNPs remain among the catalogue of candidate variants identified; the remainder are replaced by more likely candidates. Biological annotation of our credible set of variants indicates significant enrichment within promoter and enhancer elements, and transcription factor-binding sites, including AR, ERG and FOXA1. In 40 regions at least one variant is colocalised with an eQTL in prostate cancer tissue. The refined set of candidate variants substantially increase the proportion of familial relative risk explained by these known susceptibility regions, which highlights the importance of fine-mapping studies and has implications for clinical risk profiling., Prostate cancer (PrCa) involves a large heritable genetic component. Here, the authors perform multivariate fine-mapping of known PrCa GWAS loci, identifying variants enriched for biological function, explaining more familial relative risk, and with potential application in clinical risk profiling.

Published

2018

7. Circulating sex hormones in relation to anthropometric, sociodemographic and behavioural factors in an international dataset of 12,300 men

Author

Watts, EL, Appleby, PN, Albanes, D, Black, A, Chan, JM, Chen, C, Cirillo, PM, Cohn, BA, Cook, MB, Donovan, JL, Ferrucci, L, Garland, CF, Giles, GG, Goodman, PJ, Habel, LA, Haiman, CA, Holly, JMP, Hoover, RN, Kaaks, R, Knekt, P, Kolonel, LN, Kubo, T, Le Marchand, L, Luostarinen, T, Macinnis, RJ, Mäenpää, HO, Männistö, S, Metter, EJ, Milne, RL, Nomura, AMY, Oliver, SE, Parsons, JK, Peeters, PH, Platz, EA, Riboli, E, Ricceri, F, Rinaldi, S, Rissanen, H, Sawada, N, Schaefer, CA, Schenk, JM, Stanczyk, FZ, Stampfer, M, Stattin, P, Stenman, U-H, Tjønneland, A, Trichopoulou, A, Thompson, IM, Tsugane, S, Vatten, L, Whittemore, AS, Ziegler, RG, Allen, NE, Key, TJ, Travis, RC, and Hu, C

Abstract

Introduction Sex hormones have been implicated in the etiology of a number of diseases. To better understand disease etiology and the mechanisms of disease-risk factor associations, this analysis aimed to investigate the associations of anthropometric, sociodemographic and behavioural factors with a range of circulating sex hormones and sex hormone-binding globulin. Methods Statistical analyses of individual participant data from 12,330 male controls aged 25±85 years from 25 studies involved in the Endogenous Hormones Nutritional Biomarkers and Prostate Cancer Collaborative Group. Analysis of variance was used to estimate geometric means adjusted for study and relevant covariates. Results Older age was associated with higher concentrations of sex hormone-binding globulin and dihydrotestosterone and lower concentrations of dehydroepiandrosterone sulfate, free testosterone, androstenedione, androstanediol glucuronide and free estradiol. Higher body mass index was associated with higher concentrations of free estradiol, androstanediol glucuronide, estradiol and estrone and lower concentrations of dihydrotestosterone, testosterone, sex hormone-binding globulin, free testosterone, androstenedione and dehydroepiandrosterone sulfate. Taller height was associated with lower concentrations of androstenedione, testosterone, free testosterone and sex hormone-binding globulin and higher concentrations of androstanediol glucuronide. Current smoking was associated with higher concentrations of androstenedione, sex hormone-binding globulin and testosterone. Alcohol consumption was associated with higher concentrations of dehydroepiandrosterone sulfate, androstenedione and androstanediol glucuronide. East Asians had lower concentrations of androstanediol glucuronide and African Americans had higher concentrations of estrogens. Education and marital status were modestly associated with a small number of hormones. Conclusion Circulating sex hormones in men are strongly associated with age and body mass index, and to a lesser extent with smoking status and alcohol consumption.

Published

2017

8. Low Free Testosterone and Prostate Cancer Risk: A Collaborative Analysis of 20 Prospective Studies

Author

Watts, EL, Appleby, PN, Perez-Cornago, A, Bueno-de-Mesquita, HB, Chan, JM, Chen, C, Cohn, BA, Cook, MB, Flicker, L, Freedman, ND, Giles, GG, Giovannucci, E, Gislefoss, RE, Hankey, GJ, Kaaks, R, Knekt, P, Kolonel, LN, Kubo, T, Le Marchand, L, Luben, RN, Luostarinen, T, Mannisto, S, Metter, EJ, Mikami, K, Milne, RL, Ozasa, K, Platz, EA, Quiros, JR, Rissanen, H, Sawada, N, Stampfer, M, Stanczyk, FZ, Stattin, P, Tamakoshi, A, Tangen, CM, Thompson, IM, Tsilidis, KK, Tsugane, S, Ursin, G, Vatten, L, Weiss, NS, Yeap, BB, Allen, NE, Key, TJ, Travis, RC, Watts, EL, Appleby, PN, Perez-Cornago, A, Bueno-de-Mesquita, HB, Chan, JM, Chen, C, Cohn, BA, Cook, MB, Flicker, L, Freedman, ND, Giles, GG, Giovannucci, E, Gislefoss, RE, Hankey, GJ, Kaaks, R, Knekt, P, Kolonel, LN, Kubo, T, Le Marchand, L, Luben, RN, Luostarinen, T, Mannisto, S, Metter, EJ, Mikami, K, Milne, RL, Ozasa, K, Platz, EA, Quiros, JR, Rissanen, H, Sawada, N, Stampfer, M, Stanczyk, FZ, Stattin, P, Tamakoshi, A, Tangen, CM, Thompson, IM, Tsilidis, KK, Tsugane, S, Ursin, G, Vatten, L, Weiss, NS, Yeap, BB, Allen, NE, Key, TJ, and Travis, RC

Abstract

BACKGROUND: Experimental and clinical evidence implicates testosterone in the aetiology of prostate cancer. Variation across the normal range of circulating free testosterone concentrations may not lead to changes in prostate biology, unless circulating concentrations are low. This may also apply to prostate cancer risk, but this has not been investigated in an epidemiological setting. OBJECTIVE: To examine whether men with low concentrations of circulating free testosterone have a reduced risk of prostate cancer. DESIGN, SETTING, AND PARTICIPANTS: Analysis of individual participant data from 20 prospective studies including 6933 prostate cancer cases, diagnosed on average 6.8 yr after blood collection, and 12 088 controls in the Endogenous Hormones, Nutritional Biomarkers and Prostate Cancer Collaborative Group. OUTCOME MEASUREMENTS AND STATISTICAL ANALYSIS: Odds ratios (ORs) of incident overall prostate cancer and subtypes by stage and grade, using conditional logistic regression, based on study-specific tenths of calculated free testosterone concentration. RESULTS AND LIMITATIONS: Men in the lowest tenth of free testosterone concentration had a lower risk of overall prostate cancer (OR=0.77, 95% confidence interval [CI] 0.69-0.86; p<0.001) compared with men with higher concentrations (2nd-10th tenths of the distribution). Heterogeneity was present by tumour grade (phet=0.01), with a lower risk of low-grade disease (OR=0.76, 95% CI 0.67-0.88) and a nonsignificantly higher risk of high-grade disease (OR=1.56, 95% CI 0.95-2.57). There was no evidence of heterogeneity by tumour stage. The observational design is a limitation. CONCLUSIONS: Men with low circulating free testosterone may have a lower risk of overall prostate cancer; this may be due to a direct biological effect, or detection bias. Further research is needed to explore the apparent differential association by tumour grade. PATIENT SUMMARY: In this study, we looked at circulating testosterone levels and r

Published

2018

9. Functional characterization of a multi-cancer risk locus on chr5p15.33 reveals regulation of TERT by ZNF148

Author

Fang, J, Jia, J, Makowski, M, Xu, M, Wang, Z, Zhang, T, Hoskins, Jw, Choi, J, Han, Y, Zhang, M, Thomas, J, Kovacs, M, Collins, I, Dzyadyk, M, Thompson, A, O'Neill, M, Das, S, Lan, Q, Koster, R, Solomon, Rs, Kraft, P, Wolpin, Bm, Jansen, Pwtc, Olson, S, Mcglynn, Ka, Kanetsky, Pa, Chatterjee, N, Barrett, Jh, Dunning, Am, Taylor, Jc, Newton Bishop, Ja, Bishop, Dt, Andresson, T, Petersen, Gm, Amos, Ci, Iles, Mm, Nathanson, Kl, Landi, Mt, Vermeulen, M, Brown, Km, Amundadottir, Lt, Canzian, F, Kooperberg, C, Arslan, Aa, Bracci, Pm, Buring, J, Duell, Ej, Gallinger, S, Jacobs, Ej, Kamineni, A, Van Den Eeden, S, Klein, Ap, Kolonel, Ln, Li, D, Olson, Sh, Risch, Ha, Sesso, Hd, Visvanathan, K, Zheng, W, Albanes, D, Austin, Ma, Boutron Ruault, Mc, Bueno de Mesquita, Hb, Cotterchio, M, Gaziano, Jm, Giovannucci, El, Goggins, M, Gross, M, Hassan, M, Helzlsouer, Kj, Holly, Ea, Hunter, Dj, Jenab, M, Kaaks, R, Key, Tj, Khaw, Kt, Krogh, V, Kurtz, Rc, Lacroix, A, Le Marchand, L, Mannisto, S, Patel, Av, Peeters, Phm, Riboli, E, Shu, Xo, Sund, M, Thornquist, M, Tjønneland, A, Tobias, Gs, Trichopoulos, D, Wactawski Wende, J, Yu, H, Yu, K, Zeleniuch Jacquotte, A, Hoover, R, Hartge, P, Fuchs, C, Chanock, Sj, Stevens, V, Caporaso, Ne, Brennan, P, Mckay, J, Wu, X, Hung, Rj, Mclaughlin, Jr, Bickeboller, H, Risch, A, Wichmann, E, Houlston, R, Mann, G, Hopper, J, Aitken, J, Armstrong, B, Giles, G, Holland, E, Kefford, R, Cust, A, Jenkins, M, Schmid, H, Puig, S, Aguilera, P, Badenas, C, Barreiro, A, Carrera, C, Gabriel, D, Xavier, Pg, Iglesias Garcia, P, Malvehy, J, Mila, M, Pigem, R, Potrony, M, Batille, Ja, Marti, Gt, Hayward, N, Martin, N, Montgomery, G, Duffy, D, Whiteman, D, Gregor, Sm, Calista, D, Landi, G, Minghetti, P, Arcangeli, F, Bertazzi, Pa, Ghiorzo, Paola, Bianchi, Giovanna, Pastorino, Lorenza, Bruno, William, Andreotti, Virginia, Queirolo, P, Spagnolo, Francesco, Mackie, R, Lang, J, Gruis, N, van Nieuwpoort, Fa, Out, C, Bergman, W, Kukutsch, N, Bavinck, Jnb, Bakker, B, van der Stoep, N, Ter Huurne, J, van der Rhee, H, Bekkenk, M, Snels, D, van Praag, M, Brochez, L, Gerritsen, R, Crijns, M, Vasen, H, Janssen, B, Ingvar, C, Olsson, H, Jonsson, G, Borg, A, Harbst, K, Nielsen, K, Zander, As, Molvern, A, Helsing, P, Andresen, Pa, Rootwelt, H, Akslen, La, Bressac de Paillerets, B, Demenais, F, Avril, Mf, Chaudru, V, Jeannin, P, Lesueur, F, Maubec, E, Mohamdi, H, Bossard, M, Vaysse, A, Boitier, F, Caron, O, Caux, F, Dalle, S, Dereure, O, Leroux, D, Martin, L, Mateus, C, Robert, C, Stoppa Lyonnet, D, Thomas, L, Wierzbicka, E, Elder, D, Ming, M, Mitra, N, Debniak, T, Lubinski, J, Hocevar, M, Novakovic, S, Peric, B, Skerl, P, Hansson, J, Hoiom, V, Freidman, E, Azizi, E, Baron Epel, O, Scope, A, Pavlotsky, F, Cohen Manheim, I, Laitman, Y, Harland, M, Randerson Moor, J, Laye, J, Davies, J, Nsengimana, J, O'Shea, S, Chan, M, Gascoyne, J, Tucker, Ma, Goldstein, Am, and Yang, X. r.

Subjects

0301 basic medicine, Male, Lung Neoplasms, Skin Neoplasms, General Physics and Astronomy, Genome-wide association study, VARIANTS, Histones, Skin cancer, RNA, Small Interfering, Melanoma, Telomerase, GeneralLiterature_REFERENCE(e.g.,dictionaries,encyclopedias,glossaries), Pancreas cancer, Regulation of gene expression, Genetics, Zinc finger, Gene knockdown, Multidisciplinary, Proteomics and Chromatin Biology, TRICL Consortium, Chromosome Mapping, GenoMEL Consortium, PANCREATIC-CANCER, Multidisciplinary Sciences, DNA-Binding Proteins, Gene Expression Regulation, Neoplastic, Science & Technology - Other Topics, Chromosomes, Human, Pair 5, Female, Lung cancer, Signal Transduction, SUSCEPTIBILITY LOCI, Science, Locus (genetics), Single-nucleotide polymorphism, PROMOTES GROWTH, Biology, Polymorphism, Single Nucleotide, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, LUNG-CANCER, Testicular Neoplasms, Cell Line, Tumor, MD Multidisciplinary, Humans, Genetic Predisposition to Disease, QUANTITATIVE PROTEOMICS, GENOME-WIDE ASSOCIATION, Gene, PanScan Consortium, Càncer de pell, Càncer de pàncrees, Alleles, Science & Technology, Kirurgi, HUMAN-CELLS, Telomere Homeostasis, Correction, General Chemistry, Molecular biology, TERT-CLPTM1L LOCUS, Telomere, Pancreatic Neoplasms, 030104 developmental biology, Genetic Loci, TELOMERE LENGTH, Càncer de pulmó, Surgery, Genètica, Genome-Wide Association Study, Transcription Factors

Abstract

Genome wide association studies (GWAS) have mapped multiple independent cancer susceptibility loci to chr5p15.33. Here, we show that fine-mapping of pancreatic and testicular cancer GWAS within one of these loci (Region 2 in CLPTM1L) focuses the signal to nine highly correlated SNPs. Of these, rs36115365-C associated with increased pancreatic and testicular but decreased lung cancer and melanoma risk, and exhibited preferred protein-binding and enhanced regulatory activity. Transcriptional gene silencing of this regulatory element repressed TERT expression in an allele-specific manner. Proteomic analysis identifies allele-preferred binding of Zinc finger protein 148 (ZNF148) to rs36115365-C, further supported by binding of purified recombinant ZNF148. Knockdown of ZNF148 results in reduced TERT expression, telomerase activity and telomere length. Our results indicate that the association with chr5p15.33-Region 2 may be explained by rs36115365, a variant influencing TERT expression via ZNF148 in a manner consistent with elevated TERT in carriers of the C allele., Genetic variants at multiple loci of chr5p15.33 have been associated with susceptibility to numerous cancers. Here the authors show that the association of one of these loci may be explained by a variant, rs36115365, influencing telomerase reverse transcriptase (TERT) expression via ZNF148.

Published

2017

10. Relationship of Smoking to Other Life-Style Factors Among Several Ethnic Groups in Hawaii

Author

Le Marchand, L, Ntilivamunda, A, Kolonel, LN, Vanderford, MK, and Lee, J

Published

1988

11. Circulating sex hormones in relation to anthropometric, sociodemographic and behavioural factors in an international dataset of 12,300 men

Author

Hu, C, Watts, EL, Appleby, PN, Albanese, D, Black, A, Chan, JM, Chen, C, Cirillo, PM, Cohn, BA, Cook, MB, Donovan, JL, Ferrucci, L, Garland, CF, Giles, GG, Goodman, PJ, Habel, LA, Haiman, CA, Holly, JMP, Hoover, RN, Kaaks, R, Knekt, P, Kolonel, LN, Kubo, T, Le Marchand, L, Luostarinen, T, Maclnnis, RJ, Maenpaa, HO, Mannisto, S, Metter, EJ, Milne, RL, Nomura, AMY, Oliver, SE, Parsons, JK, Peeters, PH, Platz, EA, Riboli, E, Ricceri, F, Rinaldi, S, Rissanen, H, Sawada, N, Schaefer, CA, Schenk, JM, Stanczyk, FZ, Stampfer, M, Stattin, P, Stenman, U-H, Tjonneland, A, Trichopoulou, A, Thompson, IM, Tsugane, S, Vatten, L, Whittemore, AS, Ziegler, RG, Allen, NE, Key, TJ, Travis, RC, Hu, C, Watts, EL, Appleby, PN, Albanese, D, Black, A, Chan, JM, Chen, C, Cirillo, PM, Cohn, BA, Cook, MB, Donovan, JL, Ferrucci, L, Garland, CF, Giles, GG, Goodman, PJ, Habel, LA, Haiman, CA, Holly, JMP, Hoover, RN, Kaaks, R, Knekt, P, Kolonel, LN, Kubo, T, Le Marchand, L, Luostarinen, T, Maclnnis, RJ, Maenpaa, HO, Mannisto, S, Metter, EJ, Milne, RL, Nomura, AMY, Oliver, SE, Parsons, JK, Peeters, PH, Platz, EA, Riboli, E, Ricceri, F, Rinaldi, S, Rissanen, H, Sawada, N, Schaefer, CA, Schenk, JM, Stanczyk, FZ, Stampfer, M, Stattin, P, Stenman, U-H, Tjonneland, A, Trichopoulou, A, Thompson, IM, Tsugane, S, Vatten, L, Whittemore, AS, Ziegler, RG, Allen, NE, Key, TJ, and Travis, RC

Abstract

INTRODUCTION: Sex hormones have been implicated in the etiology of a number of diseases. To better understand disease etiology and the mechanisms of disease-risk factor associations, this analysis aimed to investigate the associations of anthropometric, sociodemographic and behavioural factors with a range of circulating sex hormones and sex hormone-binding globulin. METHODS: Statistical analyses of individual participant data from 12,330 male controls aged 25-85 years from 25 studies involved in the Endogenous Hormones Nutritional Biomarkers and Prostate Cancer Collaborative Group. Analysis of variance was used to estimate geometric means adjusted for study and relevant covariates. RESULTS: Older age was associated with higher concentrations of sex hormone-binding globulin and dihydrotestosterone and lower concentrations of dehydroepiandrosterone sulfate, free testosterone, androstenedione, androstanediol glucuronide and free estradiol. Higher body mass index was associated with higher concentrations of free estradiol, androstanediol glucuronide, estradiol and estrone and lower concentrations of dihydrotestosterone, testosterone, sex hormone-binding globulin, free testosterone, androstenedione and dehydroepiandrosterone sulfate. Taller height was associated with lower concentrations of androstenedione, testosterone, free testosterone and sex hormone-binding globulin and higher concentrations of androstanediol glucuronide. Current smoking was associated with higher concentrations of androstenedione, sex hormone-binding globulin and testosterone. Alcohol consumption was associated with higher concentrations of dehydroepiandrosterone sulfate, androstenedione and androstanediol glucuronide. East Asians had lower concentrations of androstanediol glucuronide and African Americans had higher concentrations of estrogens. Education and marital status were modestly associated with a small number of hormones. CONCLUSION: Circulating sex hormones in men are strongly associated

Published

2017

12. Three new pancreatic cancer susceptibility signals identified on chromosomes 1q32.1, 5p15.33 and 8q24.21

Author

Zhang, M, Wang, Z, Obazee, O, Jia, J, Childs, EJ, Hoskins, J, Figlioli, G, Mocci, E, Collins, I, Chung, CC, Hautman, C, Arslan, AA, Beane-Freeman, L, Bracci, PM, Buring, J, Duell, EJ, Gallinger, S, Giles, GG, Goodman, GE, Goodman, PJ, Kamineni, A, Kolonel, LN, Kulke, MH, Malats, N, Olson, SH, Sesso, HD, Visvanathan, K, White, E, Zheng, W, Abnet, CC, Albanes, D, Andreotti, G, Brais, L, Bueno-de-Mesquita, HB, Basso, D, Berndt, SI, Boutron-Ruault, M-C, Bijlsma, MF, Brenner, H, Burdette, L, Campa, D, Caporaso, NE, Capurso, G, Cavestro, GM, Cotterchio, M, Costello, E, Elena, J, Boggi, U, Gaziano, JM, Gazouli, M, Giovannucci, EL, Goggins, M, Gross, M, Haiman, CA, Hassan, M, Helzlsouer, KJ, Hu, N, Hunter, DJ, Iskierka-Jazdzewska, E, Jenab, M, Kaaks, R, Key, TJ, Khaw, K-T, Klein, EA, Kogevinas, M, Krogh, V, Kupcinskas, J, Kurtz, RC, Landi, MT, Landi, S, Le Marchand, L, Mambrini, A, Mannisto, S, Milne, RL, Neale, RE, Oberg, AL, Panico, S, Patel, AV, Peeters, PHM, Peters, U, Pezzilli, R, Porta, M, Purdue, M, Ramon Quiros, J, Riboli, E, Rothman, N, Scarpa, A, Scelo, G, Shu, X-O, Silverman, DT, Soucek, P, Strobel, O, Sund, M, Malecka-Panas, E, Taylor, PR, Tavano, F, Travis, RC, Thornquist, M, Tjonneland, A, Tobias, GS, Trichopoulos, D, Vashist, Y, Vodicka, P, Wactawski-Wende, J, Wentzensen, N, Yu, H, Yu, K, Zeleniuch-Jacquotte, A, Kooperberg, C, Risch, HA, Jacobs, EJ, Li, D, Fuchs, C, Hoover, R, Hartge, P, Chanock, SJ, Petersen, GM, Stolzenberg-Solomon, RS, Wolpin, BM, Kraft, P, Klein, AP, Canzian, F, Amundadottir, LT, Zhang, M, Wang, Z, Obazee, O, Jia, J, Childs, EJ, Hoskins, J, Figlioli, G, Mocci, E, Collins, I, Chung, CC, Hautman, C, Arslan, AA, Beane-Freeman, L, Bracci, PM, Buring, J, Duell, EJ, Gallinger, S, Giles, GG, Goodman, GE, Goodman, PJ, Kamineni, A, Kolonel, LN, Kulke, MH, Malats, N, Olson, SH, Sesso, HD, Visvanathan, K, White, E, Zheng, W, Abnet, CC, Albanes, D, Andreotti, G, Brais, L, Bueno-de-Mesquita, HB, Basso, D, Berndt, SI, Boutron-Ruault, M-C, Bijlsma, MF, Brenner, H, Burdette, L, Campa, D, Caporaso, NE, Capurso, G, Cavestro, GM, Cotterchio, M, Costello, E, Elena, J, Boggi, U, Gaziano, JM, Gazouli, M, Giovannucci, EL, Goggins, M, Gross, M, Haiman, CA, Hassan, M, Helzlsouer, KJ, Hu, N, Hunter, DJ, Iskierka-Jazdzewska, E, Jenab, M, Kaaks, R, Key, TJ, Khaw, K-T, Klein, EA, Kogevinas, M, Krogh, V, Kupcinskas, J, Kurtz, RC, Landi, MT, Landi, S, Le Marchand, L, Mambrini, A, Mannisto, S, Milne, RL, Neale, RE, Oberg, AL, Panico, S, Patel, AV, Peeters, PHM, Peters, U, Pezzilli, R, Porta, M, Purdue, M, Ramon Quiros, J, Riboli, E, Rothman, N, Scarpa, A, Scelo, G, Shu, X-O, Silverman, DT, Soucek, P, Strobel, O, Sund, M, Malecka-Panas, E, Taylor, PR, Tavano, F, Travis, RC, Thornquist, M, Tjonneland, A, Tobias, GS, Trichopoulos, D, Vashist, Y, Vodicka, P, Wactawski-Wende, J, Wentzensen, N, Yu, H, Yu, K, Zeleniuch-Jacquotte, A, Kooperberg, C, Risch, HA, Jacobs, EJ, Li, D, Fuchs, C, Hoover, R, Hartge, P, Chanock, SJ, Petersen, GM, Stolzenberg-Solomon, RS, Wolpin, BM, Kraft, P, Klein, AP, Canzian, F, and Amundadottir, LT

Abstract

Genome-wide association studies (GWAS) have identified common pancreatic cancer susceptibility variants at 13 chromosomal loci in individuals of European descent. To identify new susceptibility variants, we performed imputation based on 1000 Genomes (1000G) Project data and association analysis using 5,107 case and 8,845 control subjects from 27 cohort and case-control studies that participated in the PanScan I-III GWAS. This analysis, in combination with a two-staged replication in an additional 6,076 case and 7,555 control subjects from the PANcreatic Disease ReseArch (PANDoRA) and Pancreatic Cancer Case-Control (PanC4) Consortia uncovered 3 new pancreatic cancer risk signals marked by single nucleotide polymorphisms (SNPs) rs2816938 at chromosome 1q32.1 (per allele odds ratio (OR) = 1.20, P = 4.88x10 -15), rs10094872 at 8q24.21 (OR = 1.15, P = 3.22x10 -9) and rs35226131 at 5p15.33 (OR = 0.71, P = 1.70x10 -8). These SNPs represent independent risk variants at previously identified pancreatic cancer risk loci on chr1q32.1 ( NR5A2), chr8q24.21 ( MYC) and chr5p15.33 ( CLPTM1L- TERT) as per analyses conditioned on previously reported susceptibility variants. We assessed expression of candidate genes at the three risk loci in histologically normal ( n = 10) and tumor ( n = 8) derived pancreatic tissue samples and observed a marked reduction of NR5A2 expression (chr1q32.1) in the tumors (fold change -7.6, P = 5.7x10 -8). This finding was validated in a second set of paired ( n = 20) histologically normal and tumor derived pancreatic tissue samples (average fold change for three NR5A2 isoforms -31.3 to -95.7, P = 7.5x10 -4-2.0x10 -3). Our study has identified new susceptibility variants independently conferring pancreatic cancer risk that merit functional follow-up to identify target genes and explain the underlying biology.

Published

2016

13. CYP24A1 variant modifies the association between use of oestrogen plus progestogen therapy and colorectal cancer risk

Author

Garcia-Albeniz, X, Rudolph, A, Hutter, C, White, E, Lin, Y, Rosse, SA, Figueiredo, JC, Harrison, TA, Jiao, S, Brenner, H, Casey, G, Hudson, TJ, Thornquist, M, Le Marchand, L, Potter, J, Slattery, ML, Zanke, B, Baron, JA, Caan, BJ, Chanock, SJ, Berndt, SI, Stelling, D, Fuchs, CS, Hoffmeister, M, Butterbach, K, Du, M, Gauderman, WJ, Gunter, MJ, Lemire, M, Ogino, S, Lin, J, Hayes, RB, Haile, RW, Schoen, RE, SWarnick, G, Jenkins, MA, Thibodeau, SN, Schumacher, FR, Lindor, NM, Kolonel, LN, Hopper, JL, Gong, J, Seminara, D, Pflugeisen, BM, Ulrich, CM, Qu, C, Duggan, D, Cotterchio, M, Campbell, PT, Carlson, CS, Newcomb, PA, Giovannucci, E, Hsu, L, Chan, AT, Peters, U, Chang-Claude, J, Garcia-Albeniz, X, Rudolph, A, Hutter, C, White, E, Lin, Y, Rosse, SA, Figueiredo, JC, Harrison, TA, Jiao, S, Brenner, H, Casey, G, Hudson, TJ, Thornquist, M, Le Marchand, L, Potter, J, Slattery, ML, Zanke, B, Baron, JA, Caan, BJ, Chanock, SJ, Berndt, SI, Stelling, D, Fuchs, CS, Hoffmeister, M, Butterbach, K, Du, M, Gauderman, WJ, Gunter, MJ, Lemire, M, Ogino, S, Lin, J, Hayes, RB, Haile, RW, Schoen, RE, SWarnick, G, Jenkins, MA, Thibodeau, SN, Schumacher, FR, Lindor, NM, Kolonel, LN, Hopper, JL, Gong, J, Seminara, D, Pflugeisen, BM, Ulrich, CM, Qu, C, Duggan, D, Cotterchio, M, Campbell, PT, Carlson, CS, Newcomb, PA, Giovannucci, E, Hsu, L, Chan, AT, Peters, U, and Chang-Claude, J

Abstract

BACKGROUND: Menopausal hormone therapy (MHT) use has been consistently associated with a decreased risk of colorectal cancer (CRC) in women. Our aim was to use a genome-wide gene-environment interaction analysis to identify genetic modifiers of CRC risk associated with use of MHT. METHODS: We included 10 835 postmenopausal women (5419 cases and 5416 controls) from 10 studies. We evaluated use of any MHT, oestrogen-only (E-only) and combined oestrogen-progestogen (E+P) hormone preparations. To test for multiplicative interactions, we applied the empirical Bayes (EB) test as well as the Wald test in conventional case-control logistic regression as primary tests. The Cocktail test was used as secondary test. RESULTS: The EB test identified a significant interaction between rs964293 at 20q13.2/CYP24A1 and E+P (interaction OR (95% CIs)=0.61 (0.52-0.72), P=4.8 × 10(-9)). The secondary analysis also identified this interaction (Cocktail test OR=0.64 (0.52-0.78), P=1.2 × 10(-5) (alpha threshold=3.1 × 10(-4)). The ORs for association between E+P and CRC risk by rs964293 genotype were as follows: C/C, 0.96 (0.61-1.50); A/C, 0.61 (0.39-0.95) and A/A, 0.40 (0.22-0.73), respectively. CONCLUSIONS: Our results indicate that rs964293 modifies the association between E+P and CRC risk. The variant is located near CYP24A1, which encodes an enzyme involved in vitamin D metabolism. This novel finding offers additional insight into downstream pathways of CRC etiopathogenesis.

Published

2016

14. Female chromosome X mosaicism is age-related and preferentially affects the inactivated X chromosome

Author

Machiela, MJ, Zhou, W, Karlins, E, Sampson, JN, Freedman, ND, Yang, Q, Hicks, B, Dagnall, C, Hautman, C, Jacobs, KB, Abnet, CC, Aldrich, MC, Amos, C, Amundadottir, LT, Arslan, AA, Beane-Freeman, LE, Berndt, SI, Black, A, Blot, WJ, Bock, CH, Bracci, PM, Brinton, LA, Bueno-de-Mesquita, HB, Burdett, L, Buring, JE, Butler, MA, Canzian, F, Carreon, T, Chaffee, KG, Chang, I-S, Chatterjee, N, Chen, C, Chen, K, Chung, CC, Cook, LS, Bou, MC, Cullen, M, Davis, FG, De Vivo, I, Ding, T, Doherty, J, Duell, EJ, Epstein, CG, Fan, J-H, Figueroa, JD, Fraumeni, JF, Friedenreich, CM, Fuchs, CS, Gallinger, S, Gao, Y-T, Gapstur, SM, Garcia-Closas, M, Gaudet, MM, Gaziano, JM, Giles, GG, Gillanders, EM, Giovannucci, EL, Goldin, L, Goldstein, AM, Haiman, CA, Hallmans, G, Hankinson, SE, Harris, CC, Henriksson, R, Holly, EA, Hong, Y-C, Hoover, RN, Hsiung, CA, Hu, N, Hu, W, Hunter, DJ, Hutchinson, A, Jenab, M, Johansen, C, Khaw, K-T, Kim, HN, Kim, YH, Kim, YT, Klein, AP, Klein, R, Koh, W-P, Kolonel, LN, Kooperberg, C, Kraft, P, Krogh, V, Kurtz, RC, LaCroix, A, Lan, Q, Landi, MT, Le Marchand, L, Li, D, Liang, X, Liao, LM, Lin, D, Liu, J, Lissowska, J, Lu, L, Magliocco, AM, Malats, N, Matsuo, K, McNeill, LH, McWilliams, RR, Melin, BS, Mirabello, L, Moore, L, Olson, SH, Orlow, I, Park, JY, Patino-Garcia, A, Peplonska, B, Peters, U, Petersen, GM, Pooler, L, Prescott, J, Prokunina-Olsson, L, Purdue, MP, Qiao, Y-L, Rajaraman, P, Real, FX, Riboli, E, Risch, HA, Rodriguez-Santiago, B, Ruder, AM, Savage, SA, Schumacher, F, Schwartz, AG, Schwartz, KL, Seow, A, Setiawan, VW, Severi, G, Shen, H, Sheng, X, Shin, M-H, Shu, X-O, Silverman, DT, Spitz, MR, Stevens, VL, Stolzenberg-Solomon, R, Stram, D, Tang, Z-Z, Taylor, PR, Teras, LR, Tobias, GS, Van den Berg, D, Visvanathan, K, Wacholder, S, Wang, J-C, Wang, Z, Wentzensen, N, Wheeler, W, White, E, Wiencke, JK, Wolpin, BM, Wong, MP, Wu, C, Wu, T, Wu, X, Wu, Y-L, Wunder, JS, Xia, L, Yang, HP, Yang, P-C, Yu, K, Zanetti, KA, Zeleniuch-Jacquotte, A, Zheng, W, Zhou, B, Ziegler, RG, Perez-Jurado, LA, Caporaso, NE, Rothman, N, Tucker, M, Dean, MC, Yeager, M, Chanock, SJ, Machiela, MJ, Zhou, W, Karlins, E, Sampson, JN, Freedman, ND, Yang, Q, Hicks, B, Dagnall, C, Hautman, C, Jacobs, KB, Abnet, CC, Aldrich, MC, Amos, C, Amundadottir, LT, Arslan, AA, Beane-Freeman, LE, Berndt, SI, Black, A, Blot, WJ, Bock, CH, Bracci, PM, Brinton, LA, Bueno-de-Mesquita, HB, Burdett, L, Buring, JE, Butler, MA, Canzian, F, Carreon, T, Chaffee, KG, Chang, I-S, Chatterjee, N, Chen, C, Chen, K, Chung, CC, Cook, LS, Bou, MC, Cullen, M, Davis, FG, De Vivo, I, Ding, T, Doherty, J, Duell, EJ, Epstein, CG, Fan, J-H, Figueroa, JD, Fraumeni, JF, Friedenreich, CM, Fuchs, CS, Gallinger, S, Gao, Y-T, Gapstur, SM, Garcia-Closas, M, Gaudet, MM, Gaziano, JM, Giles, GG, Gillanders, EM, Giovannucci, EL, Goldin, L, Goldstein, AM, Haiman, CA, Hallmans, G, Hankinson, SE, Harris, CC, Henriksson, R, Holly, EA, Hong, Y-C, Hoover, RN, Hsiung, CA, Hu, N, Hu, W, Hunter, DJ, Hutchinson, A, Jenab, M, Johansen, C, Khaw, K-T, Kim, HN, Kim, YH, Kim, YT, Klein, AP, Klein, R, Koh, W-P, Kolonel, LN, Kooperberg, C, Kraft, P, Krogh, V, Kurtz, RC, LaCroix, A, Lan, Q, Landi, MT, Le Marchand, L, Li, D, Liang, X, Liao, LM, Lin, D, Liu, J, Lissowska, J, Lu, L, Magliocco, AM, Malats, N, Matsuo, K, McNeill, LH, McWilliams, RR, Melin, BS, Mirabello, L, Moore, L, Olson, SH, Orlow, I, Park, JY, Patino-Garcia, A, Peplonska, B, Peters, U, Petersen, GM, Pooler, L, Prescott, J, Prokunina-Olsson, L, Purdue, MP, Qiao, Y-L, Rajaraman, P, Real, FX, Riboli, E, Risch, HA, Rodriguez-Santiago, B, Ruder, AM, Savage, SA, Schumacher, F, Schwartz, AG, Schwartz, KL, Seow, A, Setiawan, VW, Severi, G, Shen, H, Sheng, X, Shin, M-H, Shu, X-O, Silverman, DT, Spitz, MR, Stevens, VL, Stolzenberg-Solomon, R, Stram, D, Tang, Z-Z, Taylor, PR, Teras, LR, Tobias, GS, Van den Berg, D, Visvanathan, K, Wacholder, S, Wang, J-C, Wang, Z, Wentzensen, N, Wheeler, W, White, E, Wiencke, JK, Wolpin, BM, Wong, MP, Wu, C, Wu, T, Wu, X, Wu, Y-L, Wunder, JS, Xia, L, Yang, HP, Yang, P-C, Yu, K, Zanetti, KA, Zeleniuch-Jacquotte, A, Zheng, W, Zhou, B, Ziegler, RG, Perez-Jurado, LA, Caporaso, NE, Rothman, N, Tucker, M, Dean, MC, Yeager, M, and Chanock, SJ

Abstract

To investigate large structural clonal mosaicism of chromosome X, we analysed the SNP microarray intensity data of 38,303 women from cancer genome-wide association studies (20,878 cases and 17,425 controls) and detected 124 mosaic X events >2 Mb in 97 (0.25%) women. Here we show rates for X-chromosome mosaicism are four times higher than mean autosomal rates; X mosaic events more often include the entire chromosome and participants with X events more likely harbour autosomal mosaic events. X mosaicism frequency increases with age (0.11% in 50-year olds; 0.45% in 75-year olds), as reported for Y and autosomes. Methylation array analyses of 33 women with X mosaicism indicate events preferentially involve the inactive X chromosome. Our results provide further evidence that the sex chromosomes undergo mosaic events more frequently than autosomes, which could have implications for understanding the underlying mechanisms of mosaic events and their possible contribution to risk for chronic diseases.

Published

2016

15. Associations between unprocessed red and processed meat, poultry, seafood and egg intake and the risk of prostate cancer: A pooled analysis of 15 prospective cohort studies

Author

Wu, K, Spiegelman, D, Hou, T, Albanes, D, Allen, NE, Berndt, SI, van den Brandt, PA, Giles, GG, Giovannucci, E, Goldbohm, RA, Goodman, GG, Goodman, PJ, Hakansson, N, Inoue, M, Key, TJ, Kolonel, LN, Mannisto, S, McCullough, ML, Neuhouser, ML, Park, Y, Platz, EA, Schenk, JM, Sinha, R, Stampfer, MJ, Stevens, VL, Tsugane, S, Visvanathan, K, Wilkens, LR, Wolk, A, Ziegler, RG, Smith-Warner, SA, Wu, K, Spiegelman, D, Hou, T, Albanes, D, Allen, NE, Berndt, SI, van den Brandt, PA, Giles, GG, Giovannucci, E, Goldbohm, RA, Goodman, GG, Goodman, PJ, Hakansson, N, Inoue, M, Key, TJ, Kolonel, LN, Mannisto, S, McCullough, ML, Neuhouser, ML, Park, Y, Platz, EA, Schenk, JM, Sinha, R, Stampfer, MJ, Stevens, VL, Tsugane, S, Visvanathan, K, Wilkens, LR, Wolk, A, Ziegler, RG, and Smith-Warner, SA

Abstract

Reports relating meat intake to prostate cancer risk are inconsistent. Associations between these dietary factors and prostate cancer were examined in a consortium of 15 cohort studies. During follow-up, 52,683 incident prostate cancer cases, including 4,924 advanced cases, were identified among 842,149 men. Cox proportional hazard models were used to calculate study-specific relative risks (RR) and then pooled using random effects models. Results do not support a substantial effect of total red, unprocessed red and processed meat for all prostate cancer outcomes, except for a modest positive association for tumors identified as advanced stage at diagnosis (advanced(r)). For seafood, no substantial effect was observed for prostate cancer regardless of stage or grade. Poultry intake was inversely associated with risk of advanced and fatal cancers (pooled multivariable RR [MVRR], 95% confidence interval, comparing ≥ 45 vs. <5 g/day: advanced 0.83, 0.70-0.99; trend test p value 0.29), fatal, 0.69, 0.59-0.82, trend test p value 0.16). Participants who ate ≥ 25 versus <5 g/day of eggs (1 egg ∼ 50 g) had a significant 14% increased risk of advanced and fatal cancers (advanced 1.14, 1.01-1.28, trend test p value 0.01; fatal 1.14, 1.00-1.30, trend test p value 0.01). When associations were analyzed separately by geographical region (North America vs. other continents), positive associations between unprocessed red meat and egg intake, and inverse associations between poultry intake and advanced, advanced(r) and fatal cancers were limited to North American studies. However, differences were only statistically significant for eggs. Observed differences in associations by geographical region warrant further investigation.

Published

2016

16. Interactions between genetic variants and breast cancer risk factors in thebreast and prostate cancer cohort consortium

Author

Campa D, Kaaks R, Le Marchand L, Haiman CA, Travis RC, Berg CD, Buring JE, Chanock SJ, Diver WR, Dostal L, Fournier A, Hankinson SE, Henderson BE, Hoover RN, Isaacs C, Johansson M, Kolonel LN, Kraft P, Lee IM, McCarty CA, Overvad K, Peeters PH, Riboli E, Sanchez MJ, Schumacher FR, Skeie G, Stram DO, Thun MJ, Trichopoulos D, Zhang S, Ziegler RG, Hunter DJ, Lindström S, Canzian F., PANICO, SALVATORE, Campa, D, Kaaks, R, Le Marchand, L, Haiman, Ca, Travis, Rc, Berg, Cd, Buring, Je, Chanock, Sj, Diver, Wr, Dostal, L, Fournier, A, Hankinson, Se, Henderson, Be, Hoover, Rn, Isaacs, C, Johansson, M, Kolonel, Ln, Kraft, P, Lee, Im, Mccarty, Ca, Overvad, K, Panico, Salvatore, Peeters, Ph, Riboli, E, Sanchez, Mj, Schumacher, Fr, Skeie, G, Stram, Do, Thun, Mj, Trichopoulos, D, Zhang, S, Ziegler, Rg, Hunter, Dj, Lindström, S, and Canzian, F.

Published

2011

17. Steroid hormone measurements from different types of assays in relation to body mass index and breast cancer risk in postmenopausal women: Reanalysis of eighteen prospective studies

Author

Key, TJ, Appleby, PN, Reeves, GK, Travis, RC, Brinton, LA, Dallal, CM, Helzlsouer, KJ, Hoffman-Bolton, J, Visvanathan, K, Dorgan, JF, Falk, RT, Gapstur, SM, Gaudet, MM, Kaaks, R, Riboli, E, Rinaldi, S, Key, T, Manjer, J, Hallmans, G, Giles, GG, Le Marchand, L, Kolonel, LN, Henderson, BE, Tworoger, SS, Hankinson, SE, Zeleniuch-Jacquotte, A, Koenig, K, Krogh, V, Sieri, S, Muti, P, Ziegler, RG, Schairer, C, Fuhrman, BJ, Barrett-Connor, E, Laughlin, GA, Grant, EJ, Cologne, J, Ohishi, W, Hida, A, Cauley, JA, Fourkala, E-O, Rohan, TE, Strickler, HD, Gunter, MJ, Key, TJ, Appleby, PN, Reeves, GK, Travis, RC, Brinton, LA, Dallal, CM, Helzlsouer, KJ, Hoffman-Bolton, J, Visvanathan, K, Dorgan, JF, Falk, RT, Gapstur, SM, Gaudet, MM, Kaaks, R, Riboli, E, Rinaldi, S, Key, T, Manjer, J, Hallmans, G, Giles, GG, Le Marchand, L, Kolonel, LN, Henderson, BE, Tworoger, SS, Hankinson, SE, Zeleniuch-Jacquotte, A, Koenig, K, Krogh, V, Sieri, S, Muti, P, Ziegler, RG, Schairer, C, Fuhrman, BJ, Barrett-Connor, E, Laughlin, GA, Grant, EJ, Cologne, J, Ohishi, W, Hida, A, Cauley, JA, Fourkala, E-O, Rohan, TE, Strickler, HD, and Gunter, MJ

Abstract

Epidemiological studies have examined breast cancer risk in relation to sex hormone concentrations measured by different methods: "extraction" immunoassays (with prior purification by organic solvent extraction, with or without column chromatography), "direct" immunoassays (no prior extraction or column chromatography), and more recently with mass spectrometry-based assays. We describe the associations of estradiol, estrone and testosterone with both body mass index and breast cancer risk in postmenopausal women according to assay method, using data from a collaborative pooled analysis of 18 prospective studies. In general, hormone concentrations were highest in studies that used direct assays and lowest in studies that used mass spectrometry-based assays. Estradiol and estrone were strongly positively associated with body mass index, regardless of the assay method; testosterone was positively associated with body mass index for direct assays, but less clearly for extraction assays, and there were few data for mass spectrometry assays. The correlations of estradiol with body mass index, estrone and testosterone were lower for direct assays than for extraction and mass spectrometry assays, suggesting that the estimates from the direct assays were less precise. For breast cancer risk, all three hormones were strongly positively associated with risk regardless of assay method (except for testosterone by mass spectrometry where there were few data), with no statistically significant differences in the trends, but differences may emerge as new data accumulate. Future epidemiological and clinical research studies should continue to use the most accurate assays that are feasible within the design characteristics of each study.

Published

2015

18. Genome-wide association study of colorectal cancer identifies six new susceptibility loci

Author

Schumacher, FR, Schmit, SL, Jiao, S, Edlund, CK, Wang, H, Zhang, B, Hsu, L, Huang, S-C, Fischer, CP, Harju, JF, Idos, GE, Lejbkowicz, F, Manion, FJ, McDonnell, K, McNeil, CE, Melas, M, Rennert, HS, Shi, W, Thomas, DC, Van Den Berg, DJ, Hutter, CM, Aragaki, AK, Butterbach, K, Caan, BJ, Carlson, CS, Chanock, SJ, Curtis, KR, Fuchs, CS, Gala, M, Giocannucci, EL, Gogarten, SM, Hayes, RB, Henderson, B, Hunter, DJ, Jackson, RD, Kolonel, LN, Kooperberg, C, Kury, S, LaCroix, A, Laurie, CC, Laurie, CA, Lemire, M, Levine, D, Ma, J, Makar, KW, Qu, C, Taverna, D, Ulrich, CM, Wu, K, Kono, S, West, DW, Berndt, SI, Bezieau, S, Brenner, H, Campbell, PT, Chan, AT, Chang-Claude, J, Coetzee, GA, Conti, DV, Duggan, D, Figueiredo, JC, Fortini, BK, Gallinger, SJ, Gauderman, WJ, Giles, G, Green, R, Haile, R, Harrison, TA, Hoffmeister, M, Hopper, JL, Hudson, TJ, Jacobs, E, Iwasaki, M, Jee, SH, Jenkins, M, Jia, W-H, Joshi, A, Li, L, Lindor, NM, Matsuo, K, Moreno, V, Mukherjee, B, Newcomb, PA, Potter, JD, Raskin, L, Rennert, G, Rosse, S, Severi, G, Schoen, RE, Seminara, D, Shu, X-O, Slattery, ML, Tsugane, S, White, E, Xiang, Y-B, Zanke, BW, Zheng, W, Le Marchand, L, Casey, G, Gruber, SB, Peters, U, Schumacher, FR, Schmit, SL, Jiao, S, Edlund, CK, Wang, H, Zhang, B, Hsu, L, Huang, S-C, Fischer, CP, Harju, JF, Idos, GE, Lejbkowicz, F, Manion, FJ, McDonnell, K, McNeil, CE, Melas, M, Rennert, HS, Shi, W, Thomas, DC, Van Den Berg, DJ, Hutter, CM, Aragaki, AK, Butterbach, K, Caan, BJ, Carlson, CS, Chanock, SJ, Curtis, KR, Fuchs, CS, Gala, M, Giocannucci, EL, Gogarten, SM, Hayes, RB, Henderson, B, Hunter, DJ, Jackson, RD, Kolonel, LN, Kooperberg, C, Kury, S, LaCroix, A, Laurie, CC, Laurie, CA, Lemire, M, Levine, D, Ma, J, Makar, KW, Qu, C, Taverna, D, Ulrich, CM, Wu, K, Kono, S, West, DW, Berndt, SI, Bezieau, S, Brenner, H, Campbell, PT, Chan, AT, Chang-Claude, J, Coetzee, GA, Conti, DV, Duggan, D, Figueiredo, JC, Fortini, BK, Gallinger, SJ, Gauderman, WJ, Giles, G, Green, R, Haile, R, Harrison, TA, Hoffmeister, M, Hopper, JL, Hudson, TJ, Jacobs, E, Iwasaki, M, Jee, SH, Jenkins, M, Jia, W-H, Joshi, A, Li, L, Lindor, NM, Matsuo, K, Moreno, V, Mukherjee, B, Newcomb, PA, Potter, JD, Raskin, L, Rennert, G, Rosse, S, Severi, G, Schoen, RE, Seminara, D, Shu, X-O, Slattery, ML, Tsugane, S, White, E, Xiang, Y-B, Zanke, BW, Zheng, W, Le Marchand, L, Casey, G, Gruber, SB, and Peters, U

Abstract

Genetic susceptibility to colorectal cancer is caused by rare pathogenic mutations and common genetic variants that contribute to familial risk. Here we report the results of a two-stage association study with 18,299 cases of colorectal cancer and 19,656 controls, with follow-up of the most statistically significant genetic loci in 4,725 cases and 9,969 controls from two Asian consortia. We describe six new susceptibility loci reaching a genome-wide threshold of P<5.0E-08. These findings provide additional insight into the underlying biological mechanisms of colorectal cancer and demonstrate the scientific value of large consortia-based genetic epidemiology studies.

Published

2015

19. Vitamin D Metabolic Pathway Genes and Pancreatic Cancer Risk

Author

Chang, JS, Arem, H, Yu, K, Xiong, X, Moy, K, Freedman, ND, Mayne, ST, Albanes, D, Arslan, AA, Austin, M, Bamlet, WR, Beane-Freeman, L, Bracci, P, Canzian, F, Cotterchio, M, Duell, EJ, Gallinger, S, Giles, GG, Goggins, M, Goodman, PJ, Hartge, P, Hassan, M, Helzlsouer, K, Henderson, B, Holly, EA, Hoover, R, Jacobs, EJ, Kamineni, A, Klein, A, Klein, E, Kolonel, LN, Li, D, Malats, N, Mannisto, S, McCullough, ML, Olson, SH, Orlow, I, Peters, U, Petersen, GM, Porta, M, Severi, G, Shu, X-O, Visvanathan, K, White, E, Yu, H, Zeleniuch-Jacquotte, A, Zheng, W, Tobias, GS, Maeder, D, Brotzman, M, Risch, H, Sampson, JN, Stolzenberg-Solomon, RZ, Chang, JS, Arem, H, Yu, K, Xiong, X, Moy, K, Freedman, ND, Mayne, ST, Albanes, D, Arslan, AA, Austin, M, Bamlet, WR, Beane-Freeman, L, Bracci, P, Canzian, F, Cotterchio, M, Duell, EJ, Gallinger, S, Giles, GG, Goggins, M, Goodman, PJ, Hartge, P, Hassan, M, Helzlsouer, K, Henderson, B, Holly, EA, Hoover, R, Jacobs, EJ, Kamineni, A, Klein, A, Klein, E, Kolonel, LN, Li, D, Malats, N, Mannisto, S, McCullough, ML, Olson, SH, Orlow, I, Peters, U, Petersen, GM, Porta, M, Severi, G, Shu, X-O, Visvanathan, K, White, E, Yu, H, Zeleniuch-Jacquotte, A, Zheng, W, Tobias, GS, Maeder, D, Brotzman, M, Risch, H, Sampson, JN, and Stolzenberg-Solomon, RZ

Abstract

Evidence on the association between vitamin D status and pancreatic cancer risk is inconsistent. This inconsistency may be partially attributable to variation in vitamin D regulating genes. We selected 11 vitamin D-related genes (GC, DHCR7, CYP2R1, VDR, CYP27B1, CYP24A1, CYP27A1, RXRA, CRP2, CASR and CUBN) totaling 213 single nucleotide polymorphisms (SNPs), and examined associations with pancreatic adenocarcinoma. Our study included 3,583 pancreatic cancer cases and 7,053 controls from the genome-wide association studies of pancreatic cancer PanScans-I-III. We used the Adaptive Joint Test and the Adaptive Rank Truncated Product statistic for pathway and gene analyses, and unconditional logistic regression for SNP analyses, adjusting for age, sex, study and population stratification. We examined effect modification by circulating vitamin D concentration (≤50, >50 nmol/L) for the most significant SNPs using a subset of cohort cases (n = 713) and controls (n = 878). The vitamin D metabolic pathway was not associated with pancreatic cancer risk (p = 0.830). Of the individual genes, none were associated with pancreatic cancer risk at a significance level of p<0.05. SNPs near the VDR (rs2239186), LRP2 (rs4668123), CYP24A1 (rs2762932), GC (rs2282679), and CUBN (rs1810205) genes were the top SNPs associated with pancreatic cancer (p-values 0.008-0.037), but none were statistically significant after adjusting for multiple comparisons. Associations between these SNPs and pancreatic cancer were not modified by circulating concentrations of vitamin D. These findings do not support an association between vitamin D-related genes and pancreatic cancer risk. Future research should explore other pathways through which vitamin D status might be associated with pancreatic cancer risk.

Published

2015

20. Vitamin D Metabolic Pathway Genes and Pancreatic Cancer Risk (vol 10, e0117574, 2015)

Author

Arem, H, Yu, K, Xiong, X, Moy, K, Freedman, ND, Mayne, ST, Albanes, D, Amundadottir, LT, Arslan, AA, Austin, M, Bamlet, WR, Beane-Freeman, L, Bracci, P, Canzian, F, Chanock, SJ, Cotterchio, M, Duell, EJ, Gallinger, S, Giles, GG, Goggins, M, Goodman, PJ, Hartge, P, Hassan, M, Helzlsouer, K, Henderson, B, Holly, EA, Hoover, R, Jacobs, EJ, Kamineni, A, Klein, A, Klein, E, Kolonel, LN, Li, D, Malats, N, Maennistoe, S, McCullough, ML, Olson, SH, Orlow, I, Peters, U, Petersen, GM, Porta, M, Severi, G, Shu, X-O, Van den Eeden, S, Visvanathan, K, White, E, Yu, H, Zeleniuch-Jacquotte, A, Zheng, W, Tobias, GS, Maeder, D, Brotzman, M, Risch, H, Sampson, JN, Stolzenberg-Solomon, RZ, Arem, H, Yu, K, Xiong, X, Moy, K, Freedman, ND, Mayne, ST, Albanes, D, Amundadottir, LT, Arslan, AA, Austin, M, Bamlet, WR, Beane-Freeman, L, Bracci, P, Canzian, F, Chanock, SJ, Cotterchio, M, Duell, EJ, Gallinger, S, Giles, GG, Goggins, M, Goodman, PJ, Hartge, P, Hassan, M, Helzlsouer, K, Henderson, B, Holly, EA, Hoover, R, Jacobs, EJ, Kamineni, A, Klein, A, Klein, E, Kolonel, LN, Li, D, Malats, N, Maennistoe, S, McCullough, ML, Olson, SH, Orlow, I, Peters, U, Petersen, GM, Porta, M, Severi, G, Shu, X-O, Van den Eeden, S, Visvanathan, K, White, E, Yu, H, Zeleniuch-Jacquotte, A, Zheng, W, Tobias, GS, Maeder, D, Brotzman, M, Risch, H, Sampson, JN, and Stolzenberg-Solomon, RZ

Published

2015

21. Genome-wide association study of colorectal cancer identifies six new susceptibility loci (vol 6, 7138, 2015)

Author

Schumacher, FR, Schmit, SL, Jiao, S, Edlund, CK, Wang, H, Zhang, B, Hsu, L, Huang, S-C, Fischer, CP, Harju, JF, Idos, GE, Lejbkowicz, F, Manion, FJ, McDonnell, K, McNeil, CE, Melas, M, Rennert, HS, Shi, W, Thomas, DC, Van den Berg, DJ, Hutter, CM, Aragaki, AK, Butterbach, K, Caan, BJ, Carlson, CS, Chanock, SJ, Curtis, KR, Fuchs, CS, Gala, M, Giovannucci, EL, Gogarten, SM, Hayes, RB, Henderson, B, Hunter, DJ, Jackson, RD, Kolonel, LN, Kooperberg, C, Kuery, S, LaCroix, A, Laurie, CC, Laurie, CA, Lemire, M, Levine, D, Ma, J, Makar, KW, Qu, C, Taverna, D, Ulrich, CM, Wu, K, Kono, S, West, DW, Berndt, SI, Bezieau, S, Brenner, H, Campbell, PT, Chan, AT, Chang-Claude, J, Coetzee, GA, Conti, DV, Duggan, D, Figueiredo, JC, Fortini, BK, Gallinger, SJ, Gauderman, WJ, Giles, G, Green, R, Haile, R, Harrison, TA, Hoffmeister, M, Hopper, JL, Hudson, TJ, Jacobs, E, Iwasaki, M, Jee, SH, Jenkins, M, Jia, W-H, Joshi, A, Li, L, Lindor, NM, Matsuo, K, Moreno, V, Mukherjee, B, Newcomb, PA, Potter, JD, Raskin, L, Rennert, G, Rosse, S, Severi, G, Schoen, RE, Seminara, D, Shu, X-O, Slattery, ML, Tsugane, S, White, E, Xiang, Y-B, Zanke, BW, Zheng, W, Le Marchand, L, Casey, G, Gruber, SB, Peters, U, Schumacher, FR, Schmit, SL, Jiao, S, Edlund, CK, Wang, H, Zhang, B, Hsu, L, Huang, S-C, Fischer, CP, Harju, JF, Idos, GE, Lejbkowicz, F, Manion, FJ, McDonnell, K, McNeil, CE, Melas, M, Rennert, HS, Shi, W, Thomas, DC, Van den Berg, DJ, Hutter, CM, Aragaki, AK, Butterbach, K, Caan, BJ, Carlson, CS, Chanock, SJ, Curtis, KR, Fuchs, CS, Gala, M, Giovannucci, EL, Gogarten, SM, Hayes, RB, Henderson, B, Hunter, DJ, Jackson, RD, Kolonel, LN, Kooperberg, C, Kuery, S, LaCroix, A, Laurie, CC, Laurie, CA, Lemire, M, Levine, D, Ma, J, Makar, KW, Qu, C, Taverna, D, Ulrich, CM, Wu, K, Kono, S, West, DW, Berndt, SI, Bezieau, S, Brenner, H, Campbell, PT, Chan, AT, Chang-Claude, J, Coetzee, GA, Conti, DV, Duggan, D, Figueiredo, JC, Fortini, BK, Gallinger, SJ, Gauderman, WJ, Giles, G, Green, R, Haile, R, Harrison, TA, Hoffmeister, M, Hopper, JL, Hudson, TJ, Jacobs, E, Iwasaki, M, Jee, SH, Jenkins, M, Jia, W-H, Joshi, A, Li, L, Lindor, NM, Matsuo, K, Moreno, V, Mukherjee, B, Newcomb, PA, Potter, JD, Raskin, L, Rennert, G, Rosse, S, Severi, G, Schoen, RE, Seminara, D, Shu, X-O, Slattery, ML, Tsugane, S, White, E, Xiang, Y-B, Zanke, BW, Zheng, W, Le Marchand, L, Casey, G, Gruber, SB, and Peters, U

Published

2015

22. Insulin-like growth factor pathway genes and blood concentrations, dietary protein, and risk of prostate cancer in the NCI breast and prostate cancer cohort consortium (BPC3)

Author

Tsilidis, KK, Travis, RC, Appleby, PN, Allen, NE, Lindström, S, Albanes, D, Ziegler, RG, McCullough, ML, Siddiq, A, Barricarte, A, Berndt, SI, Bueno-de-Mesquita, HB, Chanock, SJ, Crawford, ED, Diver, WR, Gapstur, SM, Giovannucci, E, Gu, F, Haiman, CA, Hayes, RB, Hunter, DJ, Johansson, M, Kaaks, R, Kolonel, LN, Kraft, P, Le Marchand, L, Overvad, K, Polidoro, S, Riboli, E, Schumacher, FR, Stevens, VL, Trichopoulos, D, Virtamo, J, Willett, WC, and Key, TJ

Subjects

Male, Genotype, Prostatic Neoplasms, Middle Aged, Models, Biological, Polymorphism, Single Nucleotide, Article, Body Mass Index, Diet, Cohort Studies, Insulin-Like Growth Factor Binding Protein 3, Risk Factors, Case-Control Studies, Odds Ratio, Humans, Regression Analysis, Insulin-Like Growth Factor I, Aged

Abstract

It has been hypothesized that a high intake of dairy protein may increase prostate cancer risk by increasing the production of insulin-like growth factor 1 (IGF-1). Several single nucleotide polymorphisms (SNPs) have been weakly associated with circulating concentrations of IGF-1 and IGF binding protein 3 (IGFBP-3), but none of these SNPs was associated with risk of prostate cancer. We examined whether an association between 16 SNPs associated with circulating IGF-1 or IGFBP-3 concentrations and prostate cancer exists within subgroups defined by dietary protein intake in 5,253 cases and 4,963 controls of European ancestry within the NCI Breast and Prostate Cancer Cohort Consortium (BPC3). The BPC3 includes nested case-control studies within large North-American and European cohorts. Per-allele odds ratios for prostate cancer for the SNPs were compared across tertiles of protein intake, which was expressed as the percentage of energy derived from total, animal, dairy or plant protein sources, using conditional logistic regression models. Total, animal, dairy and plant protein intakes were significantly positively associated with blood IGF-1 (p 0.10) or with risk of prostate cancer (p > 0.20). After adjusting for multiple testing, the SNP-prostate cancer associations did not differ by intakes of protein, although two interactions by intake of plant protein were of marginal statistical significance [SSTR5 (somatostatin receptor 5)-rs197056 (uncorrected p for interaction, 0.001); SSTR5-rs197057 (uncorrected p for interaction, 0.002)]. We found no strong evidence that the associations between 16 IGF pathway SNPs and prostate cancer differed by intakes of dietary protein.

Published

2013

23. Admixture mapping identifies a locus on 6q25 associated with breast cancer risk in US Latinas

Author

Fejerman L, Chen GK, Eng C, Huntsman S, Hu D, Williams A, Pasaniuc B, John EM, Via M, Gignoux C, Ingles S, Monroe KR, Kolonel LN, Torres-Mejía G, Pérez-Stable EJ, Burchard EG, Henderson BE, Haiman CA, and Ziv E

Abstract

Among US Latinas and Mexican women, those with higher European ancestry have increased risk of breast cancer. We combined an admixture mapping and genome-wide association mapping approach to search for genomic regions that may explain this observation. Latina women with breast cancer (n= 1497) and Latina controls (n= 1272) were genotyped using Affymetrix and Illumina arrays. We inferred locus-specific genetic ancestry and compared the ancestry between cases and controls. We also performed single nucleotide polymorphism (SNP) association analyses in regions of interest. Correction for multiple-hypothesis testing was conducted using permutations (P(corrected)). We identified one region where genetic ancestry was significantly associated with breast cancer risk: 6q25 [odds ratio (OR) per Indigenous American chromosome 0.75, 95% confidence interval (CI): 0.65-0.85, P= 1.1 × 10(-5), P(corrected)= 0.02]. A second region on 11p15 showed a trend towards association (OR per Indigenous American chromosome 0.77, 95% CI: 0.68-0.87, P= 4.3 × 10(-5), P(corrected)= 0.08). In both regions, breast cancer risk decreased with higher Indigenous American ancestry in concordance with observations made on global ancestry. The peak of the 6q25 signal includes the estrogen receptor 1 (ESR1) gene and 5' region, a locus previously implicated in breast cancer. Genome-wide association analysis found that a multi-SNP model explained the admixture signal in both regions. Our results confirm that the association between genetic ancestry and breast cancer risk in US Latinas is partly due to genetic differences between populations of European and Indigenous Americans origin. Fine-mapping within the 6q25 and possibly the 11p15 loci will lead to the discovery of the biologically functional variant/s behind this association.

Published

2012

24. A common variant at the TERT-CLPTM1L locus is associated with estrogen receptor-negative breast cancer

Author

Haiman, CA, Chen, GK, Vachon, CM, Canzian, F, Dunning, A, Millikan, RC, Wang, X, Ademuyiwa, F, Ahmed, S, Ambrosone, CB, Baglietto, L, Balleine, R, Bandera, EV, Beckmann, MW, Berg, CD, Bernstein, L, Blomqvist, C, Blot, WJ, Brauch, H, Buring, JE, Carey, LA, Carpenter, JE, Chang-Claude, J, Chanock, SJ, Chasman, DI, Clarke, CL, Cox, A, Cross, SS, Deming, SL, Diasio, RB, Dimopoulos, AM, Driver, WR, Duennebier, T, Durcan, L, Eccles, D, Edlund, CK, Ekici, AB, Fasching, PA, Feigelson, HS, Flesch-Janys, D, Fostira, F, Foersti, A, Fountzilas, G, Gerty, SM, Giles, GG, Godwin, AK, Goodfellow, P, Graham, N, Greco, D, Hamann, U, Hankinson, SE, Hartmann, A, Hein, R, Heinz, J, Holbrook, A, Hoover, RN, Hu, JJ, Hunter, DJ, Ingles, SA, Irwanto, A, Ivanovich, J, John, EM, Johnson, N, Jukkola-Vuorinen, A, Kaaks, R, Ko, Y-D, Kolonel, LN, Konstantopoulou, I, Kosma, V-M, Kulkarni, S, Lambrechts, D, Lee, AM, Le Marchand, L, Lesnick, T, Liu, J, Lindstrom, S, Mannermaa, A, Margolin, S, Martin, NG, Miron, P, Montgomery, GW, Nevanlinna, H, Nickels, S, Nyante, S, Olswold, C, Palmer, J, Pathak, H, Pectasides, D, Perou, CM, Peto, J, Pharoah, PDP, Pooler, LC, Press, MF, Pylkas, K, Rebbeck, TR, Rodriguez-Gil, JL, Rosenberg, L, Ross, E, Ruediger, T, Silva, IDS, Sawyer, E, Schmidt, MK, Schulz-Wendtland, R, Schumacher, F, Severi, G, Sheng, X, Signorello, LB, Sinn, H-P, Stevens, KN, Southey, MC, Tapper, WJ, Tomlinson, I, Hogervorst, FBL, Wauters, E, Weaver, J, Wildiers, H, Winqvist, R, Van Den Berg, D, Wan, P, Xia, LY, Yannoukakos, D, Zheng, W, Ziegler, RG, Siddiq, A, Slager, SL, Stram, DO, Easton, D, Kraft, P, Henderson, BE, Couch, FJ, and Gene, EIBC

Abstract

Estrogen receptor (ER)-negative breast cancer shows a higher incidence in women of African ancestry compared to women of European ancestry. In search of common risk alleles for ER-negative breast cancer, we combined genome-wide association study (GWAS) data from women of African ancestry (1,004 ER-negative cases and 2,745 controls) and European ancestry (1,718 ER-negative cases and 3,670 controls), with replication testing conducted in an additional 2,292 ER-negative cases and 16,901 controls of European ancestry. We identified a common risk variant for ER-negative breast cancer at the TERT-CLPTM1L locus on chromosome 5p15 (rs10069690: per-allele odds ratio (OR) = 1.18 per allele, P = 1.0 × 10−10). The variant was also significantly associated with triple-negative (ER-negative, progesterone receptor (PR)-negative and human epidermal growth factor-2 (HER2)-negative) breast cancer (OR = 1.25, P = 1.1 × 10−9), particularly in younger women (

Published

2011

25. The landscape of recombination in African Americans

Author

Hinch, AG, Tandon, A, Patterson, N, Song, Y, Rohland, N, Palmer, CD, Chen, GK, Wang, K, Buxbaum, SG, Akylbekova, EL, Aldrich, MC, Ambrosone, CB, Amos, C, Bandera, EV, Berndt, SI, Bernstein, L, Blot, WJ, Bock, CH, Boerwinkle, E, Cai, Q, Caporaso, N, Casey, G, Adrienne Cupples, L, Deming, SL, Ryan Diver, W, Divers, J, Fornage, M, Gillanders, EM, Glessner, J, Harris, CC, Hu, JJ, Ingles, SA, Isaacs, W, John, EM, Linda Kao, WH, Keating, B, Kittles, RA, Kolonel, LN, Larkin, E, Le Marchand, L, McNeill, LH, Millikan, RC, Musani, S, Neslund-Dudas, C, Nyante, S, Papanicolaou, GJ, Press, MF, Psaty, BM, Reiner, AP, Rich, SS, Rodriguez-Gil, JL, Rotter, JI, Rybicki, BA, Schwartz, AG, Signorello, LB, Spitz, M, Strom, SS, Thun, MJ, Tucker, MA, Wang, Z, Wiencke, JK, Witte, JS, Wrensch, M, Wu, X, Yamamura, Y, Zanetti, KA, Zheng, W, Ziegler, RG, Zhu, X, Redline, S, Hirschhorn, JN, Henderson, BE, Taylor Jr, HA, Price, AL, Hakonarson, H, Chanock, SJ, Haiman, CA, Wilson, JG, Reich, D, and Myers, SR

Published

2011

26. Genome-wide association study identifies multiple susceptibility loci for pancreatic cancer

Author

Wolpin, BM, Rizzato, C, Kraft, P, Kooperberg, C, Petersen, GM, Wang, Z, Arslan, AA, Beane-Freeman, L, Bracci, PM, Buring, J, Canzian, F, Duell, EJ, Gallinger, S, Giles, GG, Goodman, GE, Goodman, PJ, Jacobs, EJ, Kamineni, A, Klein, AP, Kolonel, LN, Kulke, MH, Li, D, Malats, N, Olson, SH, Risch, HA, Sesso, HD, Visvanathan, K, White, E, Zheng, W, Abnet, CC, Albanes, D, Andreotti, G, Austin, MA, Barfield, R, Basso, D, Berndt, SI, Boutron-Ruault, M-C, Brotzman, M, Buechler, MW, Bueno-de-Mesquita, HB, Bugert, P, Burdette, L, Campa, D, Caporaso, NE, Capurso, G, Chung, C, Cotterchio, M, Costello, E, Elena, J, Funel, N, Gaziano, JM, Giese, NA, Goggins, M, Gorman, MJ, Gross, M, Haiman, CA, Hassan, M, Helzlsouer, KJ, Henderson, BE, Holly, EA, Hu, N, Hunter, DJ, Innocenti, F, Jenab, M, Kaaks, R, Key, TJ, Khaw, K-T, Klein, EA, Kogevinas, M, Krogh, V, Kupcinskas, J, Kurtz, RC, LaCroix, A, Landi, MT, Landi, S, Le Marchand, L, Mambrini, A, Mannisto, S, Milne, RL, Nakamura, Y, Oberg, AL, Owzar, K, Patel, AV, Peeters, PHM, Peters, U, Pezzilli, R, Piepoli, A, Porta, M, Real, FX, Riboli, E, Rothman, N, Scarpa, A, Shu, X-O, Silverman, DT, Soucek, P, Sund, M, Talar-Wojnarowska, R, Taylor, PR, Theodoropoulos, GE, Thornquist, M, Tjonneland, A, Tobias, GS, Trichopoulos, D, Vodicka, P, Wactawski-Wende, J, Wentzensen, N, Wu, C, Yu, H, Yu, K, Zeleniuch-Jacquotte, A, Hoover, R, Hartge, P, Fuchs, C, Chanock, SJ, Stolzenberg-Solomon, RS, Amundadottir, LT, Wolpin, BM, Rizzato, C, Kraft, P, Kooperberg, C, Petersen, GM, Wang, Z, Arslan, AA, Beane-Freeman, L, Bracci, PM, Buring, J, Canzian, F, Duell, EJ, Gallinger, S, Giles, GG, Goodman, GE, Goodman, PJ, Jacobs, EJ, Kamineni, A, Klein, AP, Kolonel, LN, Kulke, MH, Li, D, Malats, N, Olson, SH, Risch, HA, Sesso, HD, Visvanathan, K, White, E, Zheng, W, Abnet, CC, Albanes, D, Andreotti, G, Austin, MA, Barfield, R, Basso, D, Berndt, SI, Boutron-Ruault, M-C, Brotzman, M, Buechler, MW, Bueno-de-Mesquita, HB, Bugert, P, Burdette, L, Campa, D, Caporaso, NE, Capurso, G, Chung, C, Cotterchio, M, Costello, E, Elena, J, Funel, N, Gaziano, JM, Giese, NA, Goggins, M, Gorman, MJ, Gross, M, Haiman, CA, Hassan, M, Helzlsouer, KJ, Henderson, BE, Holly, EA, Hu, N, Hunter, DJ, Innocenti, F, Jenab, M, Kaaks, R, Key, TJ, Khaw, K-T, Klein, EA, Kogevinas, M, Krogh, V, Kupcinskas, J, Kurtz, RC, LaCroix, A, Landi, MT, Landi, S, Le Marchand, L, Mambrini, A, Mannisto, S, Milne, RL, Nakamura, Y, Oberg, AL, Owzar, K, Patel, AV, Peeters, PHM, Peters, U, Pezzilli, R, Piepoli, A, Porta, M, Real, FX, Riboli, E, Rothman, N, Scarpa, A, Shu, X-O, Silverman, DT, Soucek, P, Sund, M, Talar-Wojnarowska, R, Taylor, PR, Theodoropoulos, GE, Thornquist, M, Tjonneland, A, Tobias, GS, Trichopoulos, D, Vodicka, P, Wactawski-Wende, J, Wentzensen, N, Wu, C, Yu, H, Yu, K, Zeleniuch-Jacquotte, A, Hoover, R, Hartge, P, Fuchs, C, Chanock, SJ, Stolzenberg-Solomon, RS, and Amundadottir, LT

Abstract

We performed a multistage genome-wide association study including 7,683 individuals with pancreatic cancer and 14,397 controls of European descent. Four new loci reached genome-wide significance: rs6971499 at 7q32.3 (LINC-PINT, per-allele odds ratio (OR) = 0.79, 95% confidence interval (CI) 0.74-0.84, P = 3.0 × 10(-12)), rs7190458 at 16q23.1 (BCAR1/CTRB1/CTRB2, OR = 1.46, 95% CI 1.30-1.65, P = 1.1 × 10(-10)), rs9581943 at 13q12.2 (PDX1, OR = 1.15, 95% CI 1.10-1.20, P = 2.4 × 10(-9)) and rs16986825 at 22q12.1 (ZNRF3, OR = 1.18, 95% CI 1.12-1.25, P = 1.2 × 10(-8)). We identified an independent signal in exon 2 of TERT at the established region 5p15.33 (rs2736098, OR = 0.80, 95% CI 0.76-0.85, P = 9.8 × 10(-14)). We also identified a locus at 8q24.21 (rs1561927, P = 1.3 × 10(-7)) that approached genome-wide significance located 455 kb telomeric of PVT1. Our study identified multiple new susceptibility alleles for pancreatic cancer that are worthy of follow-up studies.

Published

2014

27. A meta-analysis of 87,040 individuals identifies 23 new susceptibility loci for prostate cancer

Author

Al Olama, AA, Kote-Jarai, Z, Berndt, SI, Conti, DV, Schumacher, F, Han, Y, Benlloch, S, Hazelett, DJ, Wang, Z, Saunders, E, Leongamornlert, D, Lindstrom, S, Jugurnauth-Little, S, Dadaev, T, Tymrakiewicz, M, Stram, DO, Rand, K, Wan, P, Stram, A, Sheng, X, Pooler, LC, Park, K, Xia, L, Tyrer, J, Kolonel, LN, Le Marchand, L, Hoover, RN, Machiela, MJ, Yeager, M, Burdette, L, Chung, CC, Hutchinson, A, Yu, K, Goh, C, Ahmed, M, Govindasami, K, Guy, M, Tammela, TLJ, Auvinen, A, Wahlfors, T, Schleutker, J, Visakorpi, T, Leinonen, KA, Xu, J, Aly, M, Donovan, J, Travis, RC, Key, TJ, Siddiq, A, Canzian, F, Khaw, K-T, Takahashi, A, Kubo, M, Pharoah, P, Pashayan, N, Weischer, M, Nordestgaard, BG, Nielsen, SF, Klarskov, P, Roder, MA, Iversen, P, Thibodeau, SN, McDonnell, SK, Schaid, DJ, Stanford, JL, Kolb, S, Holt, S, Knudsen, B, Coll, AH, Gapstur, SM, Diver, WR, Stevens, VL, Maier, C, Luedeke, M, Herkommer, K, Rinckleb, AE, Strom, SS, Pettaway, C, Yeboah, ED, Tettey, Y, Biritwum, RB, Adjei, AA, Tay, E, Truelove, A, Niwa, S, Choklcalingam, AP, Cannon-Albright, L, Cybulski, C, Wokolorczyk, D, Kluzniak, W, Park, J, Sellers, T, Lin, H-Y, Isaacs, WB, Partin, AW, Brenner, H, Dieffenbach, AK, Stegmaier, C, Chen, C, Giovannucci, EL, Ma, J, Stampfer, M, Penney, KL, Mucci, L, John, EM, Ingles, SA, Kittles, RA, Murphy, AB, Pandha, H, Michael, A, Kierzek, AM, Blot, W, Signorello, LB, Zheng, W, Albanes, D, Virtamo, J, Weinstein, S, Nemesure, B, Carpten, J, Leske, C, Wu, S-Y, Hennis, A, Kibel, AS, Rybicki, BA, Neslund-Dudas, C, Hsing, AW, Chu, L, Goodman, PJ, Klein, EA, Zheng, SL, Batra, J, Clements, J, Spurdle, A, Teixeira, MR, Paulo, P, Maia, S, Slavov, C, Kaneva, R, Mitev, V, Witte, JS, Casey, G, Gillanders, EM, Seminara, D, Riboli, E, Hamdy, FC, Coetzee, GA, Li, Q, Freedman, ML, Hunter, DJ, Muir, K, Gronberg, H, Nea, DE, Southey, M, Giles, GG, Severi, G, Cook, MB, Nakagawa, H, Wiklund, F, Kraft, P, Chanock, SJ, Henderson, BE, Easton, DF, Eeles, RA, Haiman, CA, Al Olama, AA, Kote-Jarai, Z, Berndt, SI, Conti, DV, Schumacher, F, Han, Y, Benlloch, S, Hazelett, DJ, Wang, Z, Saunders, E, Leongamornlert, D, Lindstrom, S, Jugurnauth-Little, S, Dadaev, T, Tymrakiewicz, M, Stram, DO, Rand, K, Wan, P, Stram, A, Sheng, X, Pooler, LC, Park, K, Xia, L, Tyrer, J, Kolonel, LN, Le Marchand, L, Hoover, RN, Machiela, MJ, Yeager, M, Burdette, L, Chung, CC, Hutchinson, A, Yu, K, Goh, C, Ahmed, M, Govindasami, K, Guy, M, Tammela, TLJ, Auvinen, A, Wahlfors, T, Schleutker, J, Visakorpi, T, Leinonen, KA, Xu, J, Aly, M, Donovan, J, Travis, RC, Key, TJ, Siddiq, A, Canzian, F, Khaw, K-T, Takahashi, A, Kubo, M, Pharoah, P, Pashayan, N, Weischer, M, Nordestgaard, BG, Nielsen, SF, Klarskov, P, Roder, MA, Iversen, P, Thibodeau, SN, McDonnell, SK, Schaid, DJ, Stanford, JL, Kolb, S, Holt, S, Knudsen, B, Coll, AH, Gapstur, SM, Diver, WR, Stevens, VL, Maier, C, Luedeke, M, Herkommer, K, Rinckleb, AE, Strom, SS, Pettaway, C, Yeboah, ED, Tettey, Y, Biritwum, RB, Adjei, AA, Tay, E, Truelove, A, Niwa, S, Choklcalingam, AP, Cannon-Albright, L, Cybulski, C, Wokolorczyk, D, Kluzniak, W, Park, J, Sellers, T, Lin, H-Y, Isaacs, WB, Partin, AW, Brenner, H, Dieffenbach, AK, Stegmaier, C, Chen, C, Giovannucci, EL, Ma, J, Stampfer, M, Penney, KL, Mucci, L, John, EM, Ingles, SA, Kittles, RA, Murphy, AB, Pandha, H, Michael, A, Kierzek, AM, Blot, W, Signorello, LB, Zheng, W, Albanes, D, Virtamo, J, Weinstein, S, Nemesure, B, Carpten, J, Leske, C, Wu, S-Y, Hennis, A, Kibel, AS, Rybicki, BA, Neslund-Dudas, C, Hsing, AW, Chu, L, Goodman, PJ, Klein, EA, Zheng, SL, Batra, J, Clements, J, Spurdle, A, Teixeira, MR, Paulo, P, Maia, S, Slavov, C, Kaneva, R, Mitev, V, Witte, JS, Casey, G, Gillanders, EM, Seminara, D, Riboli, E, Hamdy, FC, Coetzee, GA, Li, Q, Freedman, ML, Hunter, DJ, Muir, K, Gronberg, H, Nea, DE, Southey, M, Giles, GG, Severi, G, Cook, MB, Nakagawa, H, Wiklund, F, Kraft, P, Chanock, SJ, Henderson, BE, Easton, DF, Eeles, RA, and Haiman, CA

Abstract

Genome-wide association studies (GWAS) have identified 76 variants associated with prostate cancer risk predominantly in populations of European ancestry. To identify additional susceptibility loci for this common cancer, we conducted a meta-analysis of > 10 million SNPs in 43,303 prostate cancer cases and 43,737 controls from studies in populations of European, African, Japanese and Latino ancestry. Twenty-three new susceptibility loci were identified at association P < 5 × 10(-8); 15 variants were identified among men of European ancestry, 7 were identified in multi-ancestry analyses and 1 was associated with early-onset prostate cancer. These 23 variants, in combination with known prostate cancer risk variants, explain 33% of the familial risk for this disease in European-ancestry populations. These findings provide new regions for investigation into the pathogenesis of prostate cancer and demonstrate the usefulness of combining ancestrally diverse populations to discover risk loci for disease.

Published

2014

28. Gene-Environment Interaction Involving Recently Identified Colorectal Cancer Susceptibility Loci

Author

Kantor, ED, Hutter, CM, Minnier, J, Berndt, SI, Brenner, H, Caan, BJ, Campbell, PT, Carlson, CS, Casey, G, Chan, AT, Chang-Claude, J, Chanock, SJ, Cotterchio, M, Du, M, Duggan, D, Fuchs, CS, Giovannucci, EL, Gong, J, Harrison, TA, Hayes, RB, Henderson, BE, Hoffmeister, M, Hopper, JL, Jenkins, MA, Jiao, S, Kolonel, LN, Le Marchand, L, Lemire, M, Ma, J, Newcomb, PA, Ochs-Balcom, HM, Pflugeisen, BM, Potter, JD, Rudolph, A, Schoen, RE, Seminara, D, Slattery, ML, Stelling, DL, Thomas, F, Thornquist, M, Ulrich, CM, Warnick, GS, Zanke, BW, Peters, U, Hsu, L, White, E, Kantor, ED, Hutter, CM, Minnier, J, Berndt, SI, Brenner, H, Caan, BJ, Campbell, PT, Carlson, CS, Casey, G, Chan, AT, Chang-Claude, J, Chanock, SJ, Cotterchio, M, Du, M, Duggan, D, Fuchs, CS, Giovannucci, EL, Gong, J, Harrison, TA, Hayes, RB, Henderson, BE, Hoffmeister, M, Hopper, JL, Jenkins, MA, Jiao, S, Kolonel, LN, Le Marchand, L, Lemire, M, Ma, J, Newcomb, PA, Ochs-Balcom, HM, Pflugeisen, BM, Potter, JD, Rudolph, A, Schoen, RE, Seminara, D, Slattery, ML, Stelling, DL, Thomas, F, Thornquist, M, Ulrich, CM, Warnick, GS, Zanke, BW, Peters, U, Hsu, L, and White, E

Abstract

BACKGROUND: Genome-wide association studies have identified several single nucleotide polymorphisms (SNPs) that are associated with risk of colorectal cancer. Prior research has evaluated the presence of gene-environment interaction involving the first 10 identified susceptibility loci, but little work has been conducted on interaction involving SNPs at recently identified susceptibility loci, including: rs10911251, rs6691170, rs6687758, rs11903757, rs10936599, rs647161, rs1321311, rs719725, rs1665650, rs3824999, rs7136702, rs11169552, rs59336, rs3217810, rs4925386, and rs2423279. METHODS: Data on 9,160 cases and 9,280 controls from the Genetics and Epidemiology of Colorectal Cancer Consortium (GECCO) and Colon Cancer Family Registry (CCFR) were used to evaluate the presence of interaction involving the above-listed SNPs and sex, body mass index (BMI), alcohol consumption, smoking, aspirin use, postmenopausal hormone (PMH) use, as well as intake of dietary calcium, dietary fiber, dietary folate, red meat, processed meat, fruit, and vegetables. Interaction was evaluated using a fixed effects meta-analysis of an efficient Empirical Bayes estimator, and permutation was used to account for multiple comparisons. RESULTS: None of the permutation-adjusted P values reached statistical significance. CONCLUSIONS: The associations between recently identified genetic susceptibility loci and colorectal cancer are not strongly modified by sex, BMI, alcohol, smoking, aspirin, PMH use, and various dietary factors. IMPACT: Results suggest no evidence of strong gene-environment interactions involving the recently identified 16 susceptibility loci for colorectal cancer taken one at a time.

Published

2014

29. Trans-ethnic genome-wide association study of colorectal cancer identifies a new susceptibility locus in VTI1A

Author

Wang, H, Burnett, T, Kono, S, Haiman, CA, Iwasaki, M, Wilkens, LR, Loo, LWM, Van den Berg, D, Kolonel, LN, Henderson, BE, Keku, TO, Sandler, RS, Signorello, LB, Blot, WJ, Newcomb, PA, Pande, M, Amos, CI, West, DW, Bezieau, S, Berndt, SI, Zanke, BW, Hsu, L, Lindor, NM, Haile, RW, Hopper, JL, Jenkins, MA, Gallinger, S, Casey, G, Stenzel, SL, Schumacher, FR, Peters, U, Gruber, SB, Tsugane, S, Stram, DO, Le Marchand, L, Wang, H, Burnett, T, Kono, S, Haiman, CA, Iwasaki, M, Wilkens, LR, Loo, LWM, Van den Berg, D, Kolonel, LN, Henderson, BE, Keku, TO, Sandler, RS, Signorello, LB, Blot, WJ, Newcomb, PA, Pande, M, Amos, CI, West, DW, Bezieau, S, Berndt, SI, Zanke, BW, Hsu, L, Lindor, NM, Haile, RW, Hopper, JL, Jenkins, MA, Gallinger, S, Casey, G, Stenzel, SL, Schumacher, FR, Peters, U, Gruber, SB, Tsugane, S, Stram, DO, and Le Marchand, L

Abstract

The genetic basis of sporadic colorectal cancer (CRC) is not well explained by known risk polymorphisms. Here we perform a meta-analysis of two genome-wide association studies in 2,627 cases and 3,797 controls of Japanese ancestry and 1,894 cases and 4,703 controls of African ancestry, to identify genetic variants that contribute to CRC susceptibility. We replicate genome-wide statistically significant associations (P<5 × 10(-8)) in 16,823 cases and 18,211 controls of European ancestry. This study reveals a new pan-ethnic CRC risk locus at 10q25 (rs12241008, intronic to VTI1A; P=1.4 × 10(-9)), providing additional insight into the aetiology of CRC and highlighting the value of association mapping in diverse populations.

Published

2014

30. Circulating Fatty Acids and Prostate Cancer Risk: Individual Participant Meta-Analysis of Prospective Studies

Author

Crowe, FL, Appleby, PN, Travis, RC, Barnett, M, Brasky, TM, Bueno-de-Mesquita, HB, Chajes, V, Chavarro, JE, Chirlaque, M-D, English, DR, Gibson, RA, Giles, GG, Goodman, GE, Henning, SM, Kaaks, R, King, IB, Kolonel, LN, Kristal, AR, Neuhouser, ML, Park, S-Y, Severi, G, Siddiq, A, Stampfer, MJ, Stattin, P, Tangen, CM, Tjonneland, A, Trichopoulos, D, Tumino, R, Wilkens, LR, Key, TJ, Allen, NE, Crowe, FL, Appleby, PN, Travis, RC, Barnett, M, Brasky, TM, Bueno-de-Mesquita, HB, Chajes, V, Chavarro, JE, Chirlaque, M-D, English, DR, Gibson, RA, Giles, GG, Goodman, GE, Henning, SM, Kaaks, R, King, IB, Kolonel, LN, Kristal, AR, Neuhouser, ML, Park, S-Y, Severi, G, Siddiq, A, Stampfer, MJ, Stattin, P, Tangen, CM, Tjonneland, A, Trichopoulos, D, Tumino, R, Wilkens, LR, Key, TJ, and Allen, NE

Abstract

BACKGROUND: Individual studies have suggested that some circulating fatty acids are associated with prostate cancer risk, but have not been large enough to provide precise estimates of associations, particularly by stage and grade of disease. METHODS: Principal investigators of prospective studies on circulating fatty acids and prostate cancer were invited to collaborate. Investigators provided individual participant data on circulating fatty acids (weight percent) and other characteristics of prostate cancer cases and controls. Prostate cancer risk by study-specific fifths of 14 fatty acids was estimated using multivariable-adjusted conditional logistic regression. All statistical tests were two-sided. RESULTS: Five thousand and ninety-eight case patients and 6649 control patients from seven studies with an average follow-up of 5.1 (SD = 3.3) years were included. Stearic acid (18:0) was inversely associated with total prostate cancer (odds ratio [OR] Q5 vs Q1 = 0.88, 95% confidence interval [CI] = 0.78 to 1.00, P trend = .043). Prostate cancer risk was, respectively, 14% and 16% greater in the highest fifth of eicosapentaenoic acid (20:5n-3) (OR = 1.14, 95% CI = 1.01 to 1.29, Ptrend = .001) and docosapentaenoic acid (22:5n-3) (OR = 1.16, 95% CI = 1.02 to 1.33, P trend = .003), but in each case there was heterogeneity between studies (P = .022 and P < .001, respectively). There was heterogeneity in the association between docosapentaenoic acid and prostate cancer by grade of disease (P = .006); the association was statistically significant for low-grade disease but not high-grade disease. The remaining 11 fatty acids were not statistically associated with total prostate cancer risk. CONCLUSION: There was no strong evidence that circulating fatty acids are important predictors of prostate cancer risk. It is not clear whether the modest associations of stearic, eicosapentaenoic, and docosapentaenoic acid are causal.

Published

2014

31. Genome-Wide Diet-Gene Interaction Analyses for Risk of Colorectal Cancer

Author

Amos, CI, Figueiredo, JC, Hsu, L, Hutter, CM, Lin, Y, Campbell, PT, Baron, JA, Berndt, SI, Jiao, S, Casey, G, Fortini, B, Chan, AT, Cotterchio, M, Lemire, M, Gallinger, S, Harrison, TA, Le Marchand, L, Newcomb, PA, Slattery, ML, Caan, BJ, Carlson, CS, Zanke, BW, Rosse, SA, Brenner, H, Giovannucci, EL, Wu, K, Chang-Claude, J, Chanock, SJ, Curtis, KR, Duggan, D, Gong, J, Haile, RW, Hayes, RB, Hoffmeister, M, Hopper, JL, Jenkins, MA, Kolonel, LN, Qu, C, Rudolph, A, Schoen, RE, Schumacher, FR, Seminara, D, Stelling, DL, Thibodeau, SN, Thornquist, M, Warnick, GS, Henderson, BE, Ulrich, C, Gauderman, WJ, Potter, JD, White, E, Peters, U, Amos, CI, Figueiredo, JC, Hsu, L, Hutter, CM, Lin, Y, Campbell, PT, Baron, JA, Berndt, SI, Jiao, S, Casey, G, Fortini, B, Chan, AT, Cotterchio, M, Lemire, M, Gallinger, S, Harrison, TA, Le Marchand, L, Newcomb, PA, Slattery, ML, Caan, BJ, Carlson, CS, Zanke, BW, Rosse, SA, Brenner, H, Giovannucci, EL, Wu, K, Chang-Claude, J, Chanock, SJ, Curtis, KR, Duggan, D, Gong, J, Haile, RW, Hayes, RB, Hoffmeister, M, Hopper, JL, Jenkins, MA, Kolonel, LN, Qu, C, Rudolph, A, Schoen, RE, Schumacher, FR, Seminara, D, Stelling, DL, Thibodeau, SN, Thornquist, M, Warnick, GS, Henderson, BE, Ulrich, C, Gauderman, WJ, Potter, JD, White, E, and Peters, U

Abstract

Dietary factors, including meat, fruits, vegetables and fiber, are associated with colorectal cancer; however, there is limited information as to whether these dietary factors interact with genetic variants to modify risk of colorectal cancer. We tested interactions between these dietary factors and approximately 2.7 million genetic variants for colorectal cancer risk among 9,287 cases and 9,117 controls from ten studies. We used logistic regression to investigate multiplicative gene-diet interactions, as well as our recently developed Cocktail method that involves a screening step based on marginal associations and gene-diet correlations and a testing step for multiplicative interactions, while correcting for multiple testing using weighted hypothesis testing. Per quartile increment in the intake of red and processed meat were associated with statistically significant increased risks of colorectal cancer and vegetable, fruit and fiber intake with lower risks. From the case-control analysis, we detected a significant interaction between rs4143094 (10p14/near GATA3) and processed meat consumption (OR = 1.17; p = 8.7E-09), which was consistently observed across studies (p heterogeneity = 0.78). The risk of colorectal cancer associated with processed meat was increased among individuals with the rs4143094-TG and -TT genotypes (OR = 1.20 and OR = 1.39, respectively) and null among those with the GG genotype (OR = 1.03). Our results identify a novel gene-diet interaction with processed meat for colorectal cancer, highlighting that diet may modify the effect of genetic variants on disease risk, which may have important implications for prevention.

Published

2014

32. Genome-Wide Diet-Gene Interaction Analyses for Risk of Colorectal Cancer

Author

Figueiredo, JC, Hsu, L, Hutter, CM, Lin, Y, Campbell, PT, Baron, JA, Berndt, SI, Jiao, S, Casey, G, Fortini, B, Chan, AT, Cotterchio, M, Lemire, M, Gallinger, S, Harrison, TA, Le Marchand, L, Newcomb, PA, Slattery, ML, Caan, BJ, Carlson, CS, Zanke, BW, Rosse, SA, Brenner, H, Giovannucci, EL, Wu, K, Chang-Claude, J, Chanock, SJ, Curtis, KR, Duggan, D, Gong, J, Haile, RW, Hayes, RB, Hoffmeister, M, Hopper, JL, Jenkins, MA, Kolonel, LN, Qu, C, Rudolph, A, Schoen, RE, Schumacher, FR, Seminara, D, Stelling, DL, Thibodeau, SN, Thornquist, M, Warnick, GS, Henderson, BE, Ulrich, CM, Gauderman, WJ, Potter, JD, White, E, Peters, U, Figueiredo, JC, Hsu, L, Hutter, CM, Lin, Y, Campbell, PT, Baron, JA, Berndt, SI, Jiao, S, Casey, G, Fortini, B, Chan, AT, Cotterchio, M, Lemire, M, Gallinger, S, Harrison, TA, Le Marchand, L, Newcomb, PA, Slattery, ML, Caan, BJ, Carlson, CS, Zanke, BW, Rosse, SA, Brenner, H, Giovannucci, EL, Wu, K, Chang-Claude, J, Chanock, SJ, Curtis, KR, Duggan, D, Gong, J, Haile, RW, Hayes, RB, Hoffmeister, M, Hopper, JL, Jenkins, MA, Kolonel, LN, Qu, C, Rudolph, A, Schoen, RE, Schumacher, FR, Seminara, D, Stelling, DL, Thibodeau, SN, Thornquist, M, Warnick, GS, Henderson, BE, Ulrich, CM, Gauderman, WJ, Potter, JD, White, E, and Peters, U

Abstract

Dietary factors, including meat, fruits, vegetables and fiber, are associated with colorectal cancer; however, there is limited information as to whether these dietary factors interact with genetic variants to modify risk of colorectal cancer. We tested interactions between these dietary factors and approximately 2.7 million genetic variants for colorectal cancer risk among 9,287 cases and 9,117 controls from ten studies. We used logistic regression to investigate multiplicative gene-diet interactions, as well as our recently developed Cocktail method that involves a screening step based on marginal associations and gene-diet correlations and a testing step for multiplicative interactions, while correcting for multiple testing using weighted hypothesis testing. Per quartile increment in the intake of red and processed meat were associated with statistically significant increased risks of colorectal cancer and vegetable, fruit and fiber intake with lower risks. From the case-control analysis, we detected a significant interaction between rs4143094 (10p14/near GATA3) and processed meat consumption (OR = 1.17; p = 8.7E-09), which was consistently observed across studies (p heterogeneity = 0.78). The risk of colorectal cancer associated with processed meat was increased among individuals with the rs4143094-TG and -TT genotypes (OR = 1.20 and OR = 1.39, respectively) and null among those with the GG genotype (OR = 1.03). Our results identify a novel gene-diet interaction with processed meat for colorectal cancer, highlighting that diet may modify the effect of genetic variants on disease risk, which may have important implications for prevention. © 2014.

Published

2014

33. Haplotype analysis of the HSD17B1 gene and risk of breast cancer: A comprehensive approach to multicenter analyses of prospective cohort studies

Author

Feigelson, HS Cox, DG Cann, HM Wacholder, S Kaaks, R and Henderson, BE Albanes, D Altshuler, D Berglund, G and Berrino, F Bingham, S Buring, JE Burtt, NP Calle, EE and Chanock, SJ Clavel-Chapelon, F Colditz, G Diver, WR and Freedman, ML Haiman, CA Hankinson, SE Hayes, RB and Hirschhorn, JN Hunter, D Kolonel, LN Kraft, P and LeMarchand, L Linseisen, J Modi, W Navarro, C Peeters, PH Pike, MC Riboli, E Setiawan, VW Stram, DO Thomas, G Thun, MJ Tjonneland, A Trichopoulos, D

Abstract

The 17 beta-hydroxysteroid dehydrogenase 1 gene (HSD17B1) encodes 17HSD1, which catalyzes the final step of estradiol biosynthesis. Despite the important role of HSD17B1 in hormone metabolism, few epidemiologic studies of HSD17B1 and breast cancer have been conducted. This study includes 5,370 breast cancer cases and 7,480 matched controls from five large cohorts in the Breast and Prostate Cancer Cohort Consortium. We characterized variation in HSD17B1 by resequencing and dense genotyping a multiethnic sample and identified haplotype-tagging single nucleotide polymorphisms (htSNP) that capture common variation within a 33.3-kb region around HSD17B1. Four htSNPs, including the previously studied SNP rs605059 (S312G), were genotyped to tag five common haplotypes in all cases and controls. Conditional logistic regression was used to estimate odds ratios (OR) for disease. We found no evidence of association between common HSD17B1 haplotypes or htSNPs and overall risk of breast cancer. The OR for each haplotype relative to the most common haplotype ranged from 0.98 to 1.07 (omnibus test for association: X-2 = 3.77, P = 0.58, 5 degrees of freedom). When cases were subdivided by estrogen receptor (ER) status, two common haplotypes were associated with ER-negative tumors (test for trend, Ps = 0.0009 and 0.0076; n = 353 cases). HSD17B1 variants that are common in Caucasians are not associated with overall risk of breast cancer; however, there was an association among the subset of ER-negative tumors. Although the probability that these ER-negative findings are false-positive results is high, these findings were consistent across each cohort examined and warrant further study.

Published

2006

34. Genetic variation in the HSD17B1 gene and risk of prostate cancer

Author

Kraft, P Pharoah, P Chanock, SJ Albanes, D Kolonel, LN and Hayes, RB Altshuler, D Andriole, G Berg, C Boeing, H and Burtt, NP Bueno-de-Mesquita, B Calle, EE Cann, H and Canzian, F Chen, YC Crawford, DE Dunning, AM Feigelson, HS Freedman, ML Gaziano, JM Giovannucci, E Gonzalez, CA and Haiman, CA Hallmans, G Henderson, BE Hirschhorn, JN and Hunter, DJ Kaaks, R Key, T Le Marchand, L Ma, J and Overvad, K Palli, D Pike, MC Riboli, E Rodriguez, C and Setiawan, WV Stampfer, MJ Stram, DO Thomas, G Thun, MJ and Travis, R Trichopoulou, A Virtamo, J Wacholder, S

Abstract

Steroid hormones are believed to play an important role in prostate carcinogenesis, but epidemiological evidence linking prostate cancer and steroid hormone genes has been inconclusive, in part due to small sample sizes or incomplete characterization of genetic variation at the locus of interest. Here we report on the results of a comprehensive study of the association between HSD17B1 and prostate cancer by the Breast and Prostate Cancer Cohort Consortium, a large collaborative study. HSD17B1 encodes 17p-hydroxysteroid clehydrogenase 1, an enzyme that converts clihydroepiandrosterone to the testosterone precursor Delta 5-androsterone-3 beta, 17 beta-diol and converts estrone to estradiol. The Breast and Prostate Cancer Cohort Consortium researchers systematically characterized variation in HSD17B1 by targeted resequencing and dense genotyping; selected haplotype-tagging single nucleotide polymorphisms (htSNPs) that efficiently predict common variants in U.S. and European whites, Latinos, Japanese Americans, and Native Hawaiians; and genotyped these htSNPs in 8,290 prostate cancer cases and 9,367 study-, age-, and ethnicity-matched controls. We found no evidence that HSD17B1 htSNPs (including the nonsynonymous coding SNP S312G) or htSNP haplotypes were associated with risk of prostate cancer or tumor stage in the pooled multiethnic sample or in U.S. and European whites. Analyses stratified by age, body mass index, and family history of disease found no subgroup-specific associations between these HSD17B1 htSNPs and prostate cancer. We found significant evidence of heterogeneity in associations between HSD17B1 haplotypes and prostate cancer across ethnicity: one haplotype had a significant (p < 0.002) inverse association with risk of prostate cancer in Latinos and Japanese Americans but showed no evidence of association in African Americans, Native Hawaiians, or whites. However, the smaller numbers of Latinos and Japanese Americans in this study makes these subgroup analyses less reliable. These results suggest that the germline variants in HSD17B1 characterized by these htSNPs do not substantially influence the risk of prostate cancer in U.S. and European whites.

Published

2005

35. Effects of smoking on the genetic risk of obesity: The population architecture using genomics and epidemiology study

Author

Fesinmeyer, MD, North, KE, Lim, U, Bůžková, P, Crawford, DC, Haessler, J, Gross, MD, Fowke, JH, Goodloe, R, Love, SA, Graff, M, Carlson, CS, Kuller, LH, Matise, TC, Hong, CP, Henderson, BE, Allen, M, Rohde, RR, Mayo, P, Schnetz-Boutaud, N, Monroe, KR, Ritchie, MD, Prentice, RL, Kolonel, LN, Manson, JAE, Pankow, J, Hindorff, LA, Franceschini, N, Wilkens, LR, Haiman, CA, Le Marchand, L, Peters, U, Fesinmeyer, MD, North, KE, Lim, U, Bůžková, P, Crawford, DC, Haessler, J, Gross, MD, Fowke, JH, Goodloe, R, Love, SA, Graff, M, Carlson, CS, Kuller, LH, Matise, TC, Hong, CP, Henderson, BE, Allen, M, Rohde, RR, Mayo, P, Schnetz-Boutaud, N, Monroe, KR, Ritchie, MD, Prentice, RL, Kolonel, LN, Manson, JAE, Pankow, J, Hindorff, LA, Franceschini, N, Wilkens, LR, Haiman, CA, Le Marchand, L, and Peters, U

Abstract

Background: Although smoking behavior is known to affect body mass index (BMI), the potential for smoking to influence genetic associations with BMI is largely unexplored.Methods: As part of the 'Population Architecture using Genomics and Epidemiology (PAGE)' Consortium, we investigated interaction between genetic risk factors associated with BMI and smoking for 10 single nucleotide polymorphisms (SNPs) previously identified in genome-wide association studies. We included 6 studies with a total of 56,466 subjects (16,750 African Americans (AA) and 39,716 European Americans (EA)). We assessed effect modification by testing an interaction term for each SNP and smoking (current vs. former/never) in the linear regression and by stratified analyses.Results: We did not observe strong evidence for interactions and only observed two interactions with p-values <0.1: for rs6548238/TMEM18, the risk allele (C) was associated with BMI only among AA females who were former/never smokers (β = 0.018, p = 0.002), vs. current smokers (β = 0.001, p = 0.95, pinteraction = 0.10). For rs9939609/FTO, the A allele was more strongly associated with BMI among current smoker EA females (β = 0.017, p = 3.5x10-5), vs. former/never smokers (β = 0.006, p = 0.05, pinteraction = 0.08).Conclusions: These analyses provide limited evidence that smoking status may modify genetic effects of previously identified genetic risk factors for BMI. Larger studies are needed to follow up our results.Clinical Trial Registration: NCT00000611. © 2013 Fesinmeyer et al.; licensee BioMed Central Ltd.

Published

2013

36. Common Breast Cancer Susceptibility Variants in LSP1 and RAD51L1 Are Associated with Mammographic Density Measures that Predict Breast Cancer Risk

Author

Vachon, CM, Scott, CG, Fasching, PA, Hall, P, Tamimi, RM, Li, J, Stone, J, Apicella, C, Odefrey, F, Gierach, GL, Jud, SM, Heusinger, K, Beckmann, MW, Pollan, M, Fernandez-Navarro, P, Gonzalez-Neira, A, Benitez, J, van Gils, CH, Lokate, M, Onland-Moret, NC, Peeters, PHM, Brown, J, Leyland, J, Varghese, JS, Easton, DF, Thompson, DJ, Luben, RN, Warren, RML, Wareham, NJ, Loos, RJF, Khaw, K-T, Ursin, G, Lee, E, Gayther, SA, Ramus, SJ, Eeles, RA, Leach, MO, Kwan-Lim, G, Couch, FJ, Giles, GG, Baglietto, L, Krishnan, K, Southey, MC, Le Marchand, L, Kolonel, LN, Woolcott, C, Maskarinec, G, Haiman, CA, Walker, K, Johnson, N, McCormack, VA, Biong, M, Alnaes, GIG, Gram, IT, Kristensen, VN, Borresen-Dale, A-L, Lindstroem, S, Hankinson, SE, Hunter, DJ, Andrulis, IL, Knight, JA, Boyd, NF, Figuero, JD, Lissowska, J, Wesolowska, E, Peplonska, B, Bukowska, A, Reszka, E, Liu, J, Eriksson, L, Czene, K, Audley, T, Wu, AH, Pankratz, VS, Hopper, JL, dos-Santos-Silva, I, Vachon, CM, Scott, CG, Fasching, PA, Hall, P, Tamimi, RM, Li, J, Stone, J, Apicella, C, Odefrey, F, Gierach, GL, Jud, SM, Heusinger, K, Beckmann, MW, Pollan, M, Fernandez-Navarro, P, Gonzalez-Neira, A, Benitez, J, van Gils, CH, Lokate, M, Onland-Moret, NC, Peeters, PHM, Brown, J, Leyland, J, Varghese, JS, Easton, DF, Thompson, DJ, Luben, RN, Warren, RML, Wareham, NJ, Loos, RJF, Khaw, K-T, Ursin, G, Lee, E, Gayther, SA, Ramus, SJ, Eeles, RA, Leach, MO, Kwan-Lim, G, Couch, FJ, Giles, GG, Baglietto, L, Krishnan, K, Southey, MC, Le Marchand, L, Kolonel, LN, Woolcott, C, Maskarinec, G, Haiman, CA, Walker, K, Johnson, N, McCormack, VA, Biong, M, Alnaes, GIG, Gram, IT, Kristensen, VN, Borresen-Dale, A-L, Lindstroem, S, Hankinson, SE, Hunter, DJ, Andrulis, IL, Knight, JA, Boyd, NF, Figuero, JD, Lissowska, J, Wesolowska, E, Peplonska, B, Bukowska, A, Reszka, E, Liu, J, Eriksson, L, Czene, K, Audley, T, Wu, AH, Pankratz, VS, Hopper, JL, and dos-Santos-Silva, I

Abstract

BACKGROUND: Mammographic density adjusted for age and body mass index (BMI) is a heritable marker of breast cancer susceptibility. Little is known about the biologic mechanisms underlying the association between mammographic density and breast cancer risk. We examined whether common low-penetrance breast cancer susceptibility variants contribute to interindividual differences in mammographic density measures. METHODS: We established an international consortium (DENSNP) of 19 studies from 10 countries, comprising 16,895 Caucasian women, to conduct a pooled cross-sectional analysis of common breast cancer susceptibility variants in 14 independent loci and mammographic density measures. Dense and nondense areas, and percent density, were measured using interactive-thresholding techniques. Mixed linear models were used to assess the association between genetic variants and the square roots of mammographic density measures adjusted for study, age, case status, BMI, and menopausal status. RESULTS: Consistent with their breast cancer associations, the C-allele of rs3817198 in LSP1 was positively associated with both adjusted dense area (P = 0.00005) and adjusted percent density (P = 0.001), whereas the A-allele of rs10483813 in RAD51L1 was inversely associated with adjusted percent density (P = 0.003), but not with adjusted dense area (P = 0.07). CONCLUSION: We identified two common breast cancer susceptibility variants associated with mammographic measures of radiodense tissue in the breast gland. IMPACT: We examined the association of 14 established breast cancer susceptibility loci with mammographic density phenotypes within a large genetic consortium and identified two breast cancer susceptibility variants, LSP1-rs3817198 and RAD51L1-rs10483813, associated with mammographic measures and in the same direction as the breast cancer association.

Published

2012

37. Genome-Wide Search for Gene-Gene Interactions in Colorectal Cancer

Author

Yu, Z, Jiao, S, Hsu, L, Berndt, S, Bezieau, S, Brenner, H, Buchanan, D, Caan, BJ, Campbell, PT, Carlson, CS, Casey, G, Chan, AT, Chang-Claude, J, Chanock, S, Conti, DV, Curtis, KR, Duggan, D, Gallinger, S, Gruber, SB, Harrison, TA, Hayes, RB, Henderson, BE, Hoffmeister, M, Hopper, JL, Hudson, TJ, Hutter, CM, Jackson, RD, Jenkins, MA, Kantor, ED, Kolonel, LN, Kuery, S, Le Marchand, L, Lemire, M, Newcomb, PA, Potter, JD, Qu, C, Rosse, SA, Schoen, RE, Schumacher, FR, Seminara, D, Slattery, ML, Ulrich, CM, Zanke, BW, Peters, U, Yu, Z, Jiao, S, Hsu, L, Berndt, S, Bezieau, S, Brenner, H, Buchanan, D, Caan, BJ, Campbell, PT, Carlson, CS, Casey, G, Chan, AT, Chang-Claude, J, Chanock, S, Conti, DV, Curtis, KR, Duggan, D, Gallinger, S, Gruber, SB, Harrison, TA, Hayes, RB, Henderson, BE, Hoffmeister, M, Hopper, JL, Hudson, TJ, Hutter, CM, Jackson, RD, Jenkins, MA, Kantor, ED, Kolonel, LN, Kuery, S, Le Marchand, L, Lemire, M, Newcomb, PA, Potter, JD, Qu, C, Rosse, SA, Schoen, RE, Schumacher, FR, Seminara, D, Slattery, ML, Ulrich, CM, Zanke, BW, and Peters, U

Abstract

Genome-wide association studies (GWAS) have successfully identified a number of single-nucleotide polymorphisms (SNPs) associated with colorectal cancer (CRC) risk. However, these susceptibility loci known today explain only a small fraction of the genetic risk. Gene-gene interaction (GxG) is considered to be one source of the missing heritability. To address this, we performed a genome-wide search for pair-wise GxG associated with CRC risk using 8,380 cases and 10,558 controls in the discovery phase and 2,527 cases and 2,658 controls in the replication phase. We developed a simple, but powerful method for testing interaction, which we term the Average Risk Due to Interaction (ARDI). With this method, we conducted a genome-wide search to identify SNPs showing evidence for GxG with previously identified CRC susceptibility loci from 14 independent regions. We also conducted a genome-wide search for GxG using the marginal association screening and examining interaction among SNPs that pass the screening threshold (p<10(-4)). For the known locus rs10795668 (10p14), we found an interacting SNP rs367615 (5q21) with replication p = 0.01 and combined p = 4.19×10(-8). Among the top marginal SNPs after LD pruning (n = 163), we identified an interaction between rs1571218 (20p12.3) and rs10879357 (12q21.1) (nominal combined p = 2.51×10(-6); Bonferroni adjusted p = 0.03). Our study represents the first comprehensive search for GxG in CRC, and our results may provide new insight into the genetic etiology of CRC.

Published

2012

38. Detectable clonal mosaicism and its relationship to aging and cancer

Author

Jacobs, KB, Yeager, M, Zhou, W, Wacholder, S, Wang, Z, Rodriguez-Santiago, B, Hutchinson, A, Deng, X, Liu, C, Horner, M-J, Cullen, M, Epstein, CG, Burdett, L, Dean, MC, Chatterjee, N, Sampson, J, Chung, CC, Kovaks, J, Gapstur, SM, Stevens, VL, Teras, LT, Gaudet, MM, Albanes, D, Weinstein, SJ, Virtamo, J, Taylor, PR, Freedman, ND, Abnet, CC, Goldstein, AM, Hu, N, Yu, K, Yuan, J-M, Liao, L, Ding, T, Qiao, Y-L, Gao, Y-T, Koh, W-P, Xiang, Y-B, Tang, Z-Z, Fan, J-H, Aldrich, MC, Amos, C, Blot, WJ, Bock, CH, Gillanders, EM, Harris, CC, Haiman, CA, Henderson, BE, Kolonel, LN, Le Marchand, L, McNeill, LH, Rybicki, BA, Schwartz, AG, Signorello, LB, Spitz, MR, Wiencke, JK, Wrensch, M, Wu, X, Zanetti, KA, Ziegler, RG, Figueroa, JD, Garcia-Closas, M, Malats, N, Marenne, G, Prokunina-Olsson, L, Baris, D, Schwenn, M, Johnson, A, Landi, MT, Goldin, L, Consonni, D, Bertazzi, PA, Rotunno, M, Rajaraman, P, Andersson, U, Freeman, LEB, Berg, CD, Buring, JE, Butler, MA, Carreon, T, Feychting, M, Ahlbom, A, Gaziano, JM, Giles, GG, Hallmans, G, Hankinson, SE, Hartge, P, Henriksson, R, Inskip, PD, Johansen, C, Landgren, A, McKean-Cowdin, R, Michaud, DS, Melin, BS, Peters, U, Ruder, AM, Sesso, HD, Severi, G, Shu, X-O, Visvanathan, K, White, E, Wolk, A, Zeleniuch-Jacquotte, A, Zheng, W, Silverman, DT, Kogevinas, M, Gonzalez, JR, Villa, O, Li, D, Duell, EJ, Risch, HA, Olson, SH, Kooperberg, C, Wolpin, BM, Jiao, L, Hassan, M, Wheeler, W, Arslan, AA, Bueno-de-Mesquita, HB, Fuchs, CS, Gallinger, S, Gross, MD, Holly, EA, Klein, AP, LaCroix, A, Mandelson, MT, Petersen, G, Boutron-Ruault, M-C, Bracci, PM, Canzian, F, Chang, K, Cotterchio, M, Giovannucci, EL, Goggins, M, Bolton, JAH, Jenab, M, Khaw, K-T, Krogh, V, Kurtz, RC, McWilliams, RR, Mendelsohn, JB, Rabe, KG, Riboli, E, Tjonneland, A, Tobias, GS, Trichopoulos, D, Elena, JW, Yu, H, Amundadottir, L, Stolzenberg-Solomon, RZ, Kraft, P, Schumacher, F, Stram, D, Savage, SA, Mirabello, L, Andrulis, IL, Wunder, JS, Patino Garcia, A, Sierrasesumaga, L, Barkauskas, DA, Gorlick, RG, Purdue, M, Chow, W-H, Moore, LE, Schwartz, KL, Davis, FG, Hsing, AW, Berndt, SI, Black, A, Wentzensen, N, Brinton, LA, Lissowska, J, Peplonska, B, McGlynn, KA, Cook, MB, Graubard, BI, Kratz, CP, Greene, MH, Erickson, RL, Hunter, DJ, Thomas, G, Hoover, RN, Real, FX, Fraumeni, JF, Caporaso, NE, Tucker, M, Rothman, N, Perez-Jurado, LA, Chanock, SJ, Jacobs, KB, Yeager, M, Zhou, W, Wacholder, S, Wang, Z, Rodriguez-Santiago, B, Hutchinson, A, Deng, X, Liu, C, Horner, M-J, Cullen, M, Epstein, CG, Burdett, L, Dean, MC, Chatterjee, N, Sampson, J, Chung, CC, Kovaks, J, Gapstur, SM, Stevens, VL, Teras, LT, Gaudet, MM, Albanes, D, Weinstein, SJ, Virtamo, J, Taylor, PR, Freedman, ND, Abnet, CC, Goldstein, AM, Hu, N, Yu, K, Yuan, J-M, Liao, L, Ding, T, Qiao, Y-L, Gao, Y-T, Koh, W-P, Xiang, Y-B, Tang, Z-Z, Fan, J-H, Aldrich, MC, Amos, C, Blot, WJ, Bock, CH, Gillanders, EM, Harris, CC, Haiman, CA, Henderson, BE, Kolonel, LN, Le Marchand, L, McNeill, LH, Rybicki, BA, Schwartz, AG, Signorello, LB, Spitz, MR, Wiencke, JK, Wrensch, M, Wu, X, Zanetti, KA, Ziegler, RG, Figueroa, JD, Garcia-Closas, M, Malats, N, Marenne, G, Prokunina-Olsson, L, Baris, D, Schwenn, M, Johnson, A, Landi, MT, Goldin, L, Consonni, D, Bertazzi, PA, Rotunno, M, Rajaraman, P, Andersson, U, Freeman, LEB, Berg, CD, Buring, JE, Butler, MA, Carreon, T, Feychting, M, Ahlbom, A, Gaziano, JM, Giles, GG, Hallmans, G, Hankinson, SE, Hartge, P, Henriksson, R, Inskip, PD, Johansen, C, Landgren, A, McKean-Cowdin, R, Michaud, DS, Melin, BS, Peters, U, Ruder, AM, Sesso, HD, Severi, G, Shu, X-O, Visvanathan, K, White, E, Wolk, A, Zeleniuch-Jacquotte, A, Zheng, W, Silverman, DT, Kogevinas, M, Gonzalez, JR, Villa, O, Li, D, Duell, EJ, Risch, HA, Olson, SH, Kooperberg, C, Wolpin, BM, Jiao, L, Hassan, M, Wheeler, W, Arslan, AA, Bueno-de-Mesquita, HB, Fuchs, CS, Gallinger, S, Gross, MD, Holly, EA, Klein, AP, LaCroix, A, Mandelson, MT, Petersen, G, Boutron-Ruault, M-C, Bracci, PM, Canzian, F, Chang, K, Cotterchio, M, Giovannucci, EL, Goggins, M, Bolton, JAH, Jenab, M, Khaw, K-T, Krogh, V, Kurtz, RC, McWilliams, RR, Mendelsohn, JB, Rabe, KG, Riboli, E, Tjonneland, A, Tobias, GS, Trichopoulos, D, Elena, JW, Yu, H, Amundadottir, L, Stolzenberg-Solomon, RZ, Kraft, P, Schumacher, F, Stram, D, Savage, SA, Mirabello, L, Andrulis, IL, Wunder, JS, Patino Garcia, A, Sierrasesumaga, L, Barkauskas, DA, Gorlick, RG, Purdue, M, Chow, W-H, Moore, LE, Schwartz, KL, Davis, FG, Hsing, AW, Berndt, SI, Black, A, Wentzensen, N, Brinton, LA, Lissowska, J, Peplonska, B, McGlynn, KA, Cook, MB, Graubard, BI, Kratz, CP, Greene, MH, Erickson, RL, Hunter, DJ, Thomas, G, Hoover, RN, Real, FX, Fraumeni, JF, Caporaso, NE, Tucker, M, Rothman, N, Perez-Jurado, LA, and Chanock, SJ

Abstract

In an analysis of 31,717 cancer cases and 26,136 cancer-free controls from 13 genome-wide association studies, we observed large chromosomal abnormalities in a subset of clones in DNA obtained from blood or buccal samples. We observed mosaic abnormalities, either aneuploidy or copy-neutral loss of heterozygosity, of >2 Mb in size in autosomes of 517 individuals (0.89%), with abnormal cell proportions of between 7% and 95%. In cancer-free individuals, frequency increased with age, from 0.23% under 50 years to 1.91% between 75 and 79 years (P = 4.8 × 10(-8)). Mosaic abnormalities were more frequent in individuals with solid tumors (0.97% versus 0.74% in cancer-free individuals; odds ratio (OR) = 1.25; P = 0.016), with stronger association with cases who had DNA collected before diagnosis or treatment (OR = 1.45; P = 0.0005). Detectable mosaicism was also more common in individuals for whom DNA was collected at least 1 year before diagnosis with leukemia compared to cancer-free individuals (OR = 35.4; P = 3.8 × 10(-11)). These findings underscore the time-dependent nature of somatic events in the etiology of cancer and potentially other late-onset diseases.

Published

2012

39. Comprehensive analysis of hormone and genetic variation in 36 genes related to steroid hormone metabolism in pre- and postmenopausal women from the breast and prostate cancer cohort consortium (BPC3)

Author

Beckmann, L, Hüsing, A, Setiawan, VW, Amiano, P, Clavel-Chapelon, F, Chanock, SJ, Cox, DG, Diver, R, Dossus, L, Feigelson, HS, Haiman, C, Hallmans, Göran, Hayes, RB, Henderson, BE, Hoover, RN, Hunter, DJ, Khaw, K, Kolonel, LN, Kraft, P, Lund, E, Le Marchand, L, Peeters, PHM, Riboli, E, Stram, D, Thomas, G, Thun, MJ, Tumino, R, Trichopoulos, D, Vogel, U, Willett, WC, Yeager, M, Ziegler, R, Hankinson, SE, Kaaks, R, Beckmann, L, Hüsing, A, Setiawan, VW, Amiano, P, Clavel-Chapelon, F, Chanock, SJ, Cox, DG, Diver, R, Dossus, L, Feigelson, HS, Haiman, C, Hallmans, Göran, Hayes, RB, Henderson, BE, Hoover, RN, Hunter, DJ, Khaw, K, Kolonel, LN, Kraft, P, Lund, E, Le Marchand, L, Peeters, PHM, Riboli, E, Stram, D, Thomas, G, Thun, MJ, Tumino, R, Trichopoulos, D, Vogel, U, Willett, WC, Yeager, M, Ziegler, R, Hankinson, SE, and Kaaks, R

Abstract

We confirmed associations between serum levels of SHBG and the SHBG gene and of E1 and E2 and the CYP19 and ESR1 genes. Novel associations were observed between FSHR and DHEAS, E1, and E2 and between AKR1C3 and DHEAS.

Published

2011

40. Characterizing Associations and SNP-Environment Interactions for GWAS-Identified Prostate Cancer Risk Markers-Results from BPC3

Author

Dubé, M-P, Lindstrom, S, Schumacher, F, Siddiq, A, Travis, RC, Campa, D, Berndt, SI, Diver, WR, Severi, G, Allen, N, Andriole, G, Bueno-de-Mesquita, B, Chanock, SJ, Crawford, D, Gaziano, JM, Giles, GG, Giovannucci, E, Guo, C, Haiman, CA, Hayes, RB, Halkjaer, J, Hunter, DJ, Johansson, M, Kaaks, R, Kolonel, LN, Navarro, C, Riboli, E, Sacerdote, C, Stampfer, M, Stram, DO, Thun, MJ, Trichopoulos, D, Virtamo, J, Weinstein, SJ, Yeager, M, Henderson, B, Ma, J, Le Marchand, L, Albanes, D, Kraft, P, Dubé, M-P, Lindstrom, S, Schumacher, F, Siddiq, A, Travis, RC, Campa, D, Berndt, SI, Diver, WR, Severi, G, Allen, N, Andriole, G, Bueno-de-Mesquita, B, Chanock, SJ, Crawford, D, Gaziano, JM, Giles, GG, Giovannucci, E, Guo, C, Haiman, CA, Hayes, RB, Halkjaer, J, Hunter, DJ, Johansson, M, Kaaks, R, Kolonel, LN, Navarro, C, Riboli, E, Sacerdote, C, Stampfer, M, Stram, DO, Thun, MJ, Trichopoulos, D, Virtamo, J, Weinstein, SJ, Yeager, M, Henderson, B, Ma, J, Le Marchand, L, Albanes, D, and Kraft, P

Abstract

Genome-wide association studies (GWAS) have identified multiple single nucleotide polymorphisms (SNPs) associated with prostate cancer risk. However, whether these associations can be consistently replicated, vary with disease aggressiveness (tumor stage and grade) and/or interact with non-genetic potential risk factors or other SNPs is unknown. We therefore genotyped 39 SNPs from regions identified by several prostate cancer GWAS in 10,501 prostate cancer cases and 10,831 controls from the NCI Breast and Prostate Cancer Cohort Consortium (BPC3). We replicated 36 out of 39 SNPs (P-values ranging from 0.01 to 10⁻²⁸). Two SNPs located near KLK3 associated with PSA levels showed differential association with Gleason grade (rs2735839, P = 0.0001 and rs266849, P = 0.0004; case-only test), where the alleles associated with decreasing PSA levels were inversely associated with low-grade (as defined by Gleason grade < 8) tumors but positively associated with high-grade tumors. No other SNP showed differential associations according to disease stage or grade. We observed no effect modification by SNP for association with age at diagnosis, family history of prostate cancer, diabetes, BMI, height, smoking or alcohol intake. Moreover, we found no evidence of pair-wise SNP-SNP interactions. While these SNPs represent new independent risk factors for prostate cancer, we saw little evidence for effect modification by other SNPs or by the environmental factors examined.

Published

2011

41. Identification, replication, and fine-mapping of loci associated with adult height in individuals of African ancestry

Author

N'Diaye, A, Chen, GK, Palmer, CD, Ge, B, Tayo, B, Mathias, RA, Ding, J, Nalls, MA, Adeyemo, A, Adoue, V, Ambrosone, CB, Atwood, L, Bandera, EV, Becker, LC, Berndt, SI, Bernstein, L, Blot, WJ, Boerwinkle, E, Britton, A, Casey, G, Chanock, SJ, Demerath, E, Deming, SL, Diver, WR, Fox, C, Harris, TB, Hernandez, DG, Hu, JJ, Ingles, SA, John, EM, Johnson, C, Keating, B, Kittles, RA, Kolonel, LN, Kritchevsky, SB, Marchand, L, Lohman, K, Liu, J, Millikan, RC, Murphy, A, Musani, S, Neslund-Dudas, C, North, KE, Nyante, S, Ogunniyi, A, Ostrander, EA, Papanicolaou, G, Patel, S, Pettaway, CA, Press, MF, Redline, S, Rodriguez-Gil, JL, Rotimi, C, Rybicki, BA, Salako, B, Schreiner, PJ, Signorello, LB, Singleton, AB, Stanford, JL, Stram, AH, Stram, DO, Strom, SS, Suktitipat, B, Thun, MJ, Witte, JS, Yanek, LR, Ziegler, RG, Zheng, W, Zhu, X, Zmuda, JM, Zonderman, AB, Evans, MK, Liu, Y, Becker, DM, Cooper, RS, Pastinen, T, Henderson, BE, Hirschhorn, JN, Lettre, G, Haiman, CA, N'Diaye, A, Chen, GK, Palmer, CD, Ge, B, Tayo, B, Mathias, RA, Ding, J, Nalls, MA, Adeyemo, A, Adoue, V, Ambrosone, CB, Atwood, L, Bandera, EV, Becker, LC, Berndt, SI, Bernstein, L, Blot, WJ, Boerwinkle, E, Britton, A, Casey, G, Chanock, SJ, Demerath, E, Deming, SL, Diver, WR, Fox, C, Harris, TB, Hernandez, DG, Hu, JJ, Ingles, SA, John, EM, Johnson, C, Keating, B, Kittles, RA, Kolonel, LN, Kritchevsky, SB, Marchand, L, Lohman, K, Liu, J, Millikan, RC, Murphy, A, Musani, S, Neslund-Dudas, C, North, KE, Nyante, S, Ogunniyi, A, Ostrander, EA, Papanicolaou, G, Patel, S, Pettaway, CA, Press, MF, Redline, S, Rodriguez-Gil, JL, Rotimi, C, Rybicki, BA, Salako, B, Schreiner, PJ, Signorello, LB, Singleton, AB, Stanford, JL, Stram, AH, Stram, DO, Strom, SS, Suktitipat, B, Thun, MJ, Witte, JS, Yanek, LR, Ziegler, RG, Zheng, W, Zhu, X, Zmuda, JM, Zonderman, AB, Evans, MK, Liu, Y, Becker, DM, Cooper, RS, Pastinen, T, Henderson, BE, Hirschhorn, JN, Lettre, G, and Haiman, CA

Abstract

Adult height is a classic polygenic trait of high heritability (h 2 ~0.8). More than 180 single nucleotide polymorphisms (SNPs), identified mostly in populations of European descent, are associated with height. These variants convey modest effects and explain ~10% of the variance in height. Discovery efforts in other populations, while limited, have revealed loci for height not previously implicated in individuals of European ancestry. Here, we performed a meta-analysis of genome-wide association (GWA) results for adult height in 20,427 individuals of African ancestry with replication in up to 16,436 African Americans. We found two novel height loci (Xp22-rs12393627, P = 3.4×10 -12 and 2p14-rs4315565, P = 1.2×10 -8). As a group, height associations discovered in European-ancestry samples replicate in individuals of African ancestry (P = 1.7×10 -4 for overall replication). Fine-mapping of the European height loci in African-ancestry individuals showed an enrichment of SNPs that are associated with expression of nearby genes when compared to the index European height SNPs (P<0.01). Our results highlight the utility of genetic studies in non-European populations to understand the etiology of complex human diseases and traits. © 2011 N'Diaye et al.

Published

2011

42. Heterogeneity of breast cancer associations with five susceptibility loci by clinical and pathological characteristics

Author

Leal, SM, Garcia-Closas, M, Hall, P, Nevanlinna, H, Pooley, K, Morrison, J, Richesson, DA, Bojesen, SE, Nordestgaard, BG, Axelsson, CK, Arias, JI, Milne, RL, Ribas, G, Gonzalez-Neira, A, Benitez, J, Zamora, P, Brauch, H, Justenhoven, C, Hamann, U, Ko, Y-D, Bruening, T, Haas, S, Doerk, T, Schuermann, P, Hillemanns, P, Bogdanova, N, Bremer, M, Karstens, JH, Fagerholm, R, Aaltonen, K, Aittomaki, K, Von Smitten, K, Blomqvist, C, Mannermaa, A, Uusitupa, M, Eskelinen, M, Tengstrom, M, Kosma, V-M, Kataja, V, Chenevix-Trench, G, Spurdle, AB, Beesley, J, Chen, X, Devilee, P, Van Asperen, CJ, Jacobi, CE, Tollenaar, RAEM, Huijts, PEA, Klijn, JGM, Chang-Claude, J, Kropp, S, Slanger, T, Flesch-Janys, D, Mutschelknauss, E, Salazar, R, Wang-Gohrke, S, Couch, F, Goode, EL, Olson, JE, Vachon, C, Fredericksen, ZS, Giles, GG, Baglietto, L, Severi, G, Hopper, JL, English, DR, Southey, MC, Haiman, CA, Henderson, BE, Kolonel, LN, Le Marchand, L, Stram, DO, Hunter, DJ, Hankinson, SE, Cox, DG, Tamimi, R, Kraft, P, Sherman, ME, Chanock, SJ, Lissowska, J, Brinton, LA, Peplonska, B, Hooning, MJ, Meijers-Heijboer, H, Collee, JM, Van den Ouweland, A, Uitterlinden, AG, Liu, J, Lin, LY, Yuqing, L, Humphreys, K, Czene, K, Cox, A, Balasubramanian, SP, Cross, SS, Reed, MWR, Blows, F, Driver, K, Dunning, A, Tyrer, J, Ponder, BAJ, Sangrajrang, S, Brennan, P, Mckay, J, Odefrey, F, Gabrieau, V, Sigurdson, A, Doody, M, Struewing, JP, Alexander, B, Easton, DF, Pharoah, PD, Leal, SM, Garcia-Closas, M, Hall, P, Nevanlinna, H, Pooley, K, Morrison, J, Richesson, DA, Bojesen, SE, Nordestgaard, BG, Axelsson, CK, Arias, JI, Milne, RL, Ribas, G, Gonzalez-Neira, A, Benitez, J, Zamora, P, Brauch, H, Justenhoven, C, Hamann, U, Ko, Y-D, Bruening, T, Haas, S, Doerk, T, Schuermann, P, Hillemanns, P, Bogdanova, N, Bremer, M, Karstens, JH, Fagerholm, R, Aaltonen, K, Aittomaki, K, Von Smitten, K, Blomqvist, C, Mannermaa, A, Uusitupa, M, Eskelinen, M, Tengstrom, M, Kosma, V-M, Kataja, V, Chenevix-Trench, G, Spurdle, AB, Beesley, J, Chen, X, Devilee, P, Van Asperen, CJ, Jacobi, CE, Tollenaar, RAEM, Huijts, PEA, Klijn, JGM, Chang-Claude, J, Kropp, S, Slanger, T, Flesch-Janys, D, Mutschelknauss, E, Salazar, R, Wang-Gohrke, S, Couch, F, Goode, EL, Olson, JE, Vachon, C, Fredericksen, ZS, Giles, GG, Baglietto, L, Severi, G, Hopper, JL, English, DR, Southey, MC, Haiman, CA, Henderson, BE, Kolonel, LN, Le Marchand, L, Stram, DO, Hunter, DJ, Hankinson, SE, Cox, DG, Tamimi, R, Kraft, P, Sherman, ME, Chanock, SJ, Lissowska, J, Brinton, LA, Peplonska, B, Hooning, MJ, Meijers-Heijboer, H, Collee, JM, Van den Ouweland, A, Uitterlinden, AG, Liu, J, Lin, LY, Yuqing, L, Humphreys, K, Czene, K, Cox, A, Balasubramanian, SP, Cross, SS, Reed, MWR, Blows, F, Driver, K, Dunning, A, Tyrer, J, Ponder, BAJ, Sangrajrang, S, Brennan, P, Mckay, J, Odefrey, F, Gabrieau, V, Sigurdson, A, Doody, M, Struewing, JP, Alexander, B, Easton, DF, and Pharoah, PD

Abstract

A three-stage genome-wide association study recently identified single nucleotide polymorphisms (SNPs) in five loci (fibroblast growth receptor 2 (FGFR2), trinucleotide repeat containing 9 (TNRC9), mitogen-activated protein kinase 3 K1 (MAP3K1), 8q24, and lymphocyte-specific protein 1 (LSP1)) associated with breast cancer risk. We investigated whether the associations between these SNPs and breast cancer risk varied by clinically important tumor characteristics in up to 23,039 invasive breast cancer cases and 26,273 controls from 20 studies. We also evaluated their influence on overall survival in 13,527 cases from 13 studies. All participants were of European or Asian origin. rs2981582 in FGFR2 was more strongly related to ER-positive (per-allele OR (95%CI) = 1.31 (1.27-1.36)) than ER-negative (1.08 (1.03-1.14)) disease (P for heterogeneity = 10(-13)). This SNP was also more strongly related to PR-positive, low grade and node positive tumors (P = 10(-5), 10(-8), 0.013, respectively). The association for rs13281615 in 8q24 was stronger for ER-positive, PR-positive, and low grade tumors (P = 0.001, 0.011 and 10(-4), respectively). The differences in the associations between SNPs in FGFR2 and 8q24 and risk by ER and grade remained significant after permutation adjustment for multiple comparisons and after adjustment for other tumor characteristics. Three SNPs (rs2981582, rs3803662, and rs889312) showed weak but significant associations with ER-negative disease, the strongest association being for rs3803662 in TNRC9 (1.14 (1.09-1.21)). rs13281615 in 8q24 was associated with an improvement in survival after diagnosis (per-allele HR = 0.90 (0.83-0.97). The association was attenuated and non-significant after adjusting for known prognostic factors. Our findings show that common genetic variants influence the pathological subtype of breast cancer and provide further support for the hypothesis that ER-positive and ER-negative disease are biologically distinct. Understanding

Published

2008

43. Heterogeneity of breast cancer associations with five susceptibility loci by clinical and pathological characteristics

Author

Garcia-Closas, M, Hall, P, Nevanlinna, H, Pooley, KA, Morrison, J, Richesson, DA, Bojesen, SE, Nordestgaard, BG, Axelsson, CK, Arias, JI, Milne, RL, Ribas, G, Gonzalez-Neira, A, Benitez, J, Zamora, P, Brauch, H, Justenhoven, C, Hamann, U, Ko, YD, Bruening, T, Haas, S, Dork, T, Schurmann, P, Hillemanns, P, Bogdanova, N, Bremer, M, Karstens, JH, Fagerholm, R, Aaltonen, K, Aittomaki, K, von Smitten, K, Blomqvist, C, Mannermaa, A, Uusitupa, M, Eskelinen, M, Tengstrom, M, Kosma, VM, Kataja, V, Chenevix-Trench, G, Spurdle, AB, Beeslev, J, Chen, X, Devilee, P, van Asperen, CJ, Jacobi, CE, Tollenaar, RA, Huijts, PE, Klijn, Jan, Chang-Claude, J, Kropp, S, Slanger, T, Flesch-Janys, D, Mutschelknauss, E, Salazar, R, Wang-Gohrke, S, Couch, F, Goode, EL, Olson, JE, Vachon, C, Fredericksen, ZS, Giles, GG, Baglietto, L, Severi, G, Hopper, JL, English, DR, Southey, M, Haiman, CA, Henderson, BE, Kolonel, LN, Le Marchand, L, Stram, DO, Hunter, DJ, Hankinson, SE, Cox, DG, Tamimi, R, van Kraft, PJA (Peter), Sherman, M, Chanock, S, Lissowska, J, Brinton, L, Peplonska, B, Hooning, Maartje, Meijers-Heijboer, EJ, Collee, Margriet, van den Ouweland, Ans, Uitterlinden, André, Liu, Jun, Lin, L, Yuqing, L, Humphreys, K, Czene, K, Cox, A, Balasubramanian, SP, Cross, SS, Reed, MWR, Blows, F, Driver, K, Dunning, AJ, Tyrer, J, Garcia-Closas, M, Hall, P, Nevanlinna, H, Pooley, KA, Morrison, J, Richesson, DA, Bojesen, SE, Nordestgaard, BG, Axelsson, CK, Arias, JI, Milne, RL, Ribas, G, Gonzalez-Neira, A, Benitez, J, Zamora, P, Brauch, H, Justenhoven, C, Hamann, U, Ko, YD, Bruening, T, Haas, S, Dork, T, Schurmann, P, Hillemanns, P, Bogdanova, N, Bremer, M, Karstens, JH, Fagerholm, R, Aaltonen, K, Aittomaki, K, von Smitten, K, Blomqvist, C, Mannermaa, A, Uusitupa, M, Eskelinen, M, Tengstrom, M, Kosma, VM, Kataja, V, Chenevix-Trench, G, Spurdle, AB, Beeslev, J, Chen, X, Devilee, P, van Asperen, CJ, Jacobi, CE, Tollenaar, RA, Huijts, PE, Klijn, Jan, Chang-Claude, J, Kropp, S, Slanger, T, Flesch-Janys, D, Mutschelknauss, E, Salazar, R, Wang-Gohrke, S, Couch, F, Goode, EL, Olson, JE, Vachon, C, Fredericksen, ZS, Giles, GG, Baglietto, L, Severi, G, Hopper, JL, English, DR, Southey, M, Haiman, CA, Henderson, BE, Kolonel, LN, Le Marchand, L, Stram, DO, Hunter, DJ, Hankinson, SE, Cox, DG, Tamimi, R, van Kraft, PJA (Peter), Sherman, M, Chanock, S, Lissowska, J, Brinton, L, Peplonska, B, Hooning, Maartje, Meijers-Heijboer, EJ, Collee, Margriet, van den Ouweland, Ans, Uitterlinden, André, Liu, Jun, Lin, L, Yuqing, L, Humphreys, K, Czene, K, Cox, A, Balasubramanian, SP, Cross, SS, Reed, MWR, Blows, F, Driver, K, Dunning, AJ, and Tyrer, J

Published

2008

44. Meat consumption and risk of type 2 diabetes: the Multiethnic Cohort

Author

Steinbrecher, A, primary, Erber, E, additional, Grandinetti, A, additional, Kolonel, LN, additional, and Maskarinec, G, additional

Published

2010

45. Menstrual and reproductive factors and risk of breast cancer in Asian-Americans

Author

Wu, AH, primary, Ziegler, RG, additional, Pike, MC, additional, Nomura, AMY, additional, West, DW, additional, Kolonel, LN, additional, Horn-Ross, PL, additional, Rosenthal, JF, additional, and Hoover, RN, additional

Published

1996

46. The association of body size, reproductive factors and thyroid cancer

Author

Goodman, MT, primary, Kolonel, LN, additional, and Wilkens, LR, additional

Published

1992

47. Erythrocyte membrane fatty acid composition, serum lipids, and non-Hodgkin's lymphoma risk in a nested case-control study: the multiethnic cohort.

Author

Morimoto Y, Conroy SM, Ollberding NJ, Henning SM, Franke AA, Wilkens LR, Goodman MT, Hernandez BY, Le Marchand L, Henderson BE, Kolonel LN, Maskarinec G, Morimoto, Yukiko, Conroy, Shannon M, Ollberding, Nicholas J, Henning, Susanne M, Franke, Adrian A, Wilkens, Lynne R, Goodman, Marc T, and Hernandez, Brenda Y

Abstract

Purpose: Composition of dietary fatty acid intake, which influences cytokine production, may contribute to the development of non-Hodgkin's lymphoma (NHL). Serum lipid levels may serve as biomarkers of inflammation associated with NHL risk.Methods: We conducted a case-control analysis (275 cases and 549 controls) nested within the Multiethnic Cohort Study (whites, Japanese Americans, Latinos, African Americans, and Native Hawaiians) to examine the association of prediagnostic, erythrocyte membrane phospholipid fatty acid composition, and serum cholesterol and triglyceride (TG) concentrations with the risk of NHL. Conditional logistic regression was used to calculate odds ratios (OR) and 95 % confidence intervals (CI) by tertiles of biomarker concentrations.Results: Higher total saturated fatty acids (SFA) were associated with an increase in NHL risk (OR(T3 vs. T1) = 1.57 [95 % CI: 1.03-2.39]; p(trend) = 0.01), whereas no associations were detected for total n-3 or n-6 polyunsaturated fatty acids. Inverse associations were observed for total cholesterol (TC; OR (T3 vs. T1) = 0.51 [95 % CI: 0.35-0.74]; p(trend) < 0.0001) and high-density lipoprotein cholesterol (HDL-C; OR (T3 vs. T1) = 0.47 [95 % CI: 0.31-0.71]; p(trend) = 0.0001) but not for low-density lipoprotein cholesterol or TG. Adjustment for the use of lipid-lowering medication did not modify the results substantially.Conclusions: This prospective biomarker investigation offers supportive evidence for an adverse effect of higher erythrocyte membrane SFA levels on NHL risk, but preclinical effects cannot be excluded. Inverse relations between prediagnostic, circulating TC and HDL-C and NHL risk may be due to reverse causation or a result of protective actions of these lipids and lipoproteins. [ABSTRACT FROM AUTHOR]

Published

2012

48. Consistent directions of effect for established type 2 diabetes risk variants across populations: the population architecture using Genomics and Epidemiology (PAGE) Consortium.

Author

Haiman CA, Fesinmeyer MD, Spencer KL, Buzková P, Voruganti VS, Wan P, Haessler J, Franceschini N, Monroe KR, Howard BV, Jackson RD, Florez JC, Kolonel LN, Buyske S, Goodloe RJ, Liu S, Manson JE, Meigs JB, Waters K, and Mukamal KJ

Abstract

Common genetic risk variants for type 2 diabetes (T2D) have primarily been identified in populations of European and Asian ancestry. We tested whether the direction of association with 20 T2D risk variants generalizes across six major racial/ethnic groups in the U.S. as part of the Population Architecture using Genomics and Epidemiology Consortium (16,235 diabetes case and 46,122 control subjects of European American, African American, Hispanic, East Asian, American Indian, and Native Hawaiian ancestry). The percentage of positive (odds ratio [OR] >1 for putative risk allele) associations ranged from 69% in American Indians to 100% in European Americans. Of the nine variants where we observed significant heterogeneity of effect by racial/ethnic group (P(heterogeneity) < 0.05), eight were positively associated with risk (OR >1) in at least five groups. The marked directional consistency of association observed for most genetic variants across populations implies a shared functional common variant in each region. Fine-mapping of all loci will be required to reveal markers of risk that are important within and across populations. [ABSTRACT FROM AUTHOR]

Published

2012

49. The association of cigarette smoking with gastric cancer: the multiethnic cohort study.

Author

Nomura AM, Wilkens LR, Henderson BE, Epplein M, Kolonel LN, Nomura, Abraham M Y, Wilkens, Lynne R, Henderson, Brian E, Epplein, Meira, and Kolonel, Laurence N

Abstract

Purpose: The purpose of this study is to investigate the association of cigarette smoking with gastric cancer.Methods: Over 215,000 men and women, representing five ethnic groups (African Americans, Japanese Americans, Latino Americans, Native Hawaiians, and Whites), completed a mailed questionnaire, 1993-1996. After an average follow-up of 7.3 years, 454 men and 242 women were diagnosed with gastric adenocarcinoma. Cox proportional hazard models were used to calculate multivariate-adjusted hazard ratios and 95% confidence intervals.Results: Current cigarette smokers had elevated hazard ratios compared with never smokers among men (HR = 1.98; 95% CI 1.46-2.70) and women (HR = 1.78; 95% CI 1.23-2.57). This positive association was consistent across all five ethnicities. Former smokers had an elevated risk among men, but not among women. There was a significant trend by intensity (cigarettes per day) and duration (years) of smoking among all current smokers. After separation by anatomic location of their tumor, ever smokers had a higher risk for gastric cardia cancer (HR = 2.86; 95% CI 1.66-4.93) than for distal gastric cancer (HR = 1.52; 95% CI 1.25-1.86) among men and women combined. Analysis by histologic tumor type showed a stronger association between current smoking and the intestinal type.Conclusions: Overall, this study shows an association of current cigarette smoking with gastric cancer in both sexes, consistency of this effect across five ethnic groups, evidence for a dose-response effect of smoking in both sexes, a stronger effect for cardia than for distal gastric cancer, and a stronger association for intestinal than for diffuse gastric cancer. [ABSTRACT FROM AUTHOR]

Published

2012

50. Circulating 25-hydroxyvitamin D and risk of esophageal and gastric cancer: Cohort Consortium Vitamin D Pooling Project of Rarer Cancers.

Author

Abnet CC, Chen Y, Chow W, Gao Y, Helzlsouer KJ, Le Marchand L, McCullough ML, Shikany JM, Virtamo J, Weinstein SJ, Xiang Y, Yu K, Zheng W, Albanes D, Arslan AA, Campbell DS, Campbell PT, Hayes RB, Horst RL, and Kolonel LN

Abstract

Upper gastrointestinal (GI) cancers of the stomach and esophagus have high incidence and mortality worldwide, but they are uncommon in Western countries. Little information exists on the association between vitamin D and risk of upper GI cancers. This study examined the association between circulating 25-hydroxyvitamin D (25(OH)D) and upper GI cancer risk in the Cohort Consortium Vitamin D Pooling Project of Rarer Cancers. Concentrations of 25(OH)D were measured from 1,065 upper GI cancer cases and 1,066 age-, sex-, race-, and season-of blood draw-matched controls from 8 prospective cohort studies. In multivariate-adjusted models, circulating 25(OH)D concentration was not significantly associated with upper GI cancer risk. Subgroup analysis by race showed that among Asians, but not Caucasians, lower concentrations of 25(OH)D (<25 nmol/L) were associated with a statistically significant decreased risk of upper GI cancer (reference: 50-<75 nmol/L) (odds ratio = 0.53, 95% confidence interval: 0.31, 0.91; P trend = 0.003). Never smokers with concentrations of <25 nmol/L showed a lower risk of upper GI cancers (odds ratio = 0.55, 95% confidence interval: 0.31, 0.96). Subgroup analyses by alcohol consumption produced opposing trends. Results do not support the hypothesis that interventions aimed at increasing vitamin D status would lead to a lower risk of these highly fatal cancers. [ABSTRACT FROM AUTHOR]

Published

2010