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Author: Baglietto, Laura × Author: Giles, Graham × End date: 2019 × Start date: 2010 × Type: Journal Article ×

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    Genome-Wide Measures of Peripheral Blood Dna Methylation and Prostate Cancer Risk in a Prospective Nested Case-Control Study
    FitzGerald, LM ; Naeem, H ; Makalic, E ; Schmidt, DF ; Dowty, JG ; Joo, JE ; Jung, C-H ; Bassett, JK ; Dugue, P-A ; Chung, J ; Lonie, A ; Milne, RL ; Wong, EM ; Hopper, JL ; English, DR ; Severi, G ; Baglietto, L ; Pedersen, J ; Giles, GG ; Southey, MC (WILEY, 2017-04-01)
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    Genome-wide association study of peripheral blood DNA methylation and conventional mammographic density measures
    Li, S ; Dugue, P-A ; Baglietto, L ; Severi, G ; Wong, EM ; Nguyen, TL ; Stone, J ; English, DR ; Southey, MC ; Giles, GG ; Hopper, JL ; Milne, RL (WILEY, 2019-10-01)
    Age- and body mass index (BMI)-adjusted mammographic density is one of the strongest breast cancer risk factors. DNA methylation is a molecular mechanism that could underlie inter-individual variation in mammographic density. We aimed to investigate the association between breast cancer risk-predicting mammographic density measures and blood DNA methylation. For 436 women from the Australian Mammographic Density Twins and Sisters Study and 591 women from the Melbourne Collaborative Cohort Study, mammographic density (dense area, nondense area and percentage dense area) defined by the conventional brightness threshold was measured using the CUMULUS software, and peripheral blood DNA methylation was measured using the HumanMethylation450 (HM450) BeadChip assay. Associations between DNA methylation at >400,000 sites and mammographic density measures adjusted for age and BMI were assessed within each cohort and pooled using fixed-effect meta-analysis. Associations with methylation at genetic loci known to be associated with mammographic density were also examined. We found no genome-wide significant (p < 10-7 ) association for any mammographic density measure from the meta-analysis, or from the cohort-specific analyses. None of the 299 methylation sites located at genetic loci associated with mammographic density was associated with any mammographic density measure after adjusting for multiple testing (all p > 0.05/299 = 1.7 × 10-4 ). In summary, our study did not find evidence for associations between blood DNA methylation, as measured by the HM450 assay, and conventional mammographic density measures that predict breast cancer risk.
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    A comprehensive gene-environment interaction analysis in Ovarian Cancer using genome-wide significant common variants
    Kim, S ; Wang, M ; Tyrer, JP ; Jensen, A ; Wiensch, A ; Liu, G ; Lee, AW ; Ness, RB ; Salvatore, M ; Tworoger, SS ; Whittemore, AS ; Anton-Culver, H ; Sieh, W ; Olson, SH ; Berchuck, A ; Goode, EL ; Goodman, MT ; Doherty, JA ; Chenevix-Trench, G ; Rossing, MA ; Webb, PM ; Giles, GG ; Terry, KL ; Ziogas, A ; Fortner, RT ; Menon, U ; Gayther, SA ; Wu, AH ; Song, H ; Brooks-Wilson, A ; Bandera, E ; Cook, LS ; Cramer, DW ; Milne, RL ; Winham, SJ ; Kjaer, SK ; Modugno, F ; Thompson, PJ ; Chang-Claude, J ; Harris, HR ; Schildkraut, JM ; Le, ND ; Wentzensen, N ; Trabert, B ; Hogdall, E ; Huntsman, D ; Pike, MC ; Pharoah, PDP ; Pearce, CL ; Mukherjee, B (WILEY, 2019-05-01)
    As a follow-up to genome-wide association analysis of common variants associated with ovarian carcinoma (cancer), our study considers seven well-known ovarian cancer risk factors and their interactions with 28 genome-wide significant common genetic variants. The interaction analyses were based on data from 9971 ovarian cancer cases and 15,566 controls from 17 case-control studies. Likelihood ratio and Wald tests for multiplicative interaction and for relative excess risk due to additive interaction were used. The top multiplicative interaction was noted between oral contraceptive pill (OCP) use (ever vs. never) and rs13255292 (p value = 3.48 × 10-4 ). Among women with the TT genotype for this variant, the odds ratio for OCP use was 0.53 (95% CI = 0.46-0.60) compared to 0.71 (95%CI = 0.66-0.77) for women with the CC genotype. When stratified by duration of OCP use, women with 1-5 years of OCP use exhibited differential protective benefit across genotypes. However, no interaction on either the multiplicative or additive scale was found to be statistically significant after multiple testing correction. The results suggest that OCP use may offer increased benefit for women who are carriers of the T allele in rs13255292. On the other hand, for women carrying the C allele in this variant, longer (5+ years) use of OCP may reduce the impact of carrying the risk allele of this SNP. Replication of this finding is needed. The study presents a comprehensive analytic framework for conducting gene-environment analysis in ovarian cancer.
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    Identification of six new susceptibility loci for invasive epithelial ovarian cancer
    Kuchenbaecker, KB ; Ramus, SJ ; Tyrer, J ; Lee, A ; Shen, HC ; Beesley, J ; Lawrenson, K ; McGuffog, L ; Healey, S ; Lee, JM ; Spindler, TJ ; Lin, YG ; Pejovic, T ; Bean, Y ; Li, Q ; Coetzee, S ; Hazelett, D ; Miron, A ; Southey, M ; Terry, MB ; Goldgar, DE ; Buys, SS ; Janavicius, R ; Dorfling, CM ; van Rensburg, EJ ; Neuhausen, SL ; Ding, YC ; Hansen, TVO ; Jonson, L ; Gerdes, A-M ; Ejlertsen, B ; Barrowdale, D ; Dennis, J ; Benitez, J ; Osorio, A ; Garcia, MJ ; Komenaka, I ; Weitzel, JN ; Ganschow, P ; Peterlongo, P ; Bernard, L ; Viel, A ; Bonanni, B ; Peissel, B ; Manoukian, S ; Radice, P ; Papi, L ; Ottini, L ; Fostira, F ; Konstantopoulou, I ; Garber, J ; Frost, D ; Perkins, J ; Platte, R ; Ellis, S ; Godwin, AK ; Schmutzler, RK ; Meindl, A ; Engel, C ; Sutter, C ; Sinilnikova, OM ; Damiola, F ; Mazoyer, S ; Stoppa-Lyonnet, D ; Claes, K ; De Leeneer, K ; Kirk, J ; Rodriguez, GC ; Piedmonte, M ; O'Malley, DM ; de la Hoya, M ; Caldes, T ; Aittomaeki, K ; Nevanlinna, H ; Collee, JM ; Rookus, MA ; Oosterwijk, JC ; Tihomirova, L ; Tung, N ; Hamann, U ; Isaccs, C ; Tischkowitz, M ; Imyanitov, EN ; Caligo, MA ; Campbell, IG ; Hogervorst, FBL ; Olah, E ; Diez, O ; Blanco, I ; Brunet, J ; Lazaroso, C ; Angel Pujana, M ; Jakubowska, A ; Gronwald, J ; Lubinski, J ; Sukiennicki, G ; Barkardottir, RB ; Plante, M ; Simard, J ; Soucy, P ; Montagna, M ; Tognazzo, S ; Teixeira, MR ; Pankratz, VS ; Wang, X ; Lindor, N ; Szabo, CI ; Kauff, N ; Vijai, J ; Aghajanian, CA ; Pfeiler, G ; Berger, A ; Singer, CF ; Tea, M-K ; Phelan, CM ; Greene, MH ; Mai, PL ; Rennert, G ; Mulligan, AM ; Tchatchou, S ; Andrulis, IL ; Glendon, G ; Toland, AE ; Jensen, UB ; Kruse, TA ; Thomassen, M ; Bojesen, A ; Zidan, J ; Friedman, E ; Laitman, Y ; Soller, M ; Liljegren, A ; Arver, B ; Einbeigi, Z ; Stenmark-Askmalm, M ; Olopade, OI ; Nussbaum, RL ; Rebbeck, TR ; Nathanson, KL ; Domchek, SM ; Lu, KH ; Karlan, BY ; Walsh, C ; Lester, J ; Hein, A ; Ekici, AB ; Beckmann, MW ; Fasching, PA ; Lambrechts, D ; Van Nieuwenhuysen, E ; Vergote, I ; Lambrechts, S ; Dicks, E ; Doherty, JA ; Wicklund, KG ; Rossing, MA ; Rudolph, A ; Chang-Claude, J ; Wang-Gohrke, S ; Eilber, U ; Moysich, KB ; Odunsi, K ; Sucheston, L ; Lele, S ; Wilkens, LR ; Goodman, MT ; Thompson, PJ ; Shvetsov, YB ; Runnebaum, IB ; Duerst, M ; Hillemanns, P ; Doerk, T ; Antonenkova, N ; Bogdanova, N ; Leminen, A ; Pelttari, LM ; Butzow, R ; Modugno, F ; Kelley, JL ; Edwards, RP ; Ness, RB ; du Bois, A ; Heitz, F ; Schwaab, I ; Harter, P ; Matsuo, K ; Hosono, S ; Orsulic, S ; Jensen, A ; Kjaer, SK ; Hogdall, E ; Hasmad, HN ; Azmi, MAN ; Teo, S-H ; Woo, Y-L ; Fridley, BL ; Goode, EL ; Cunningham, JM ; Vierkant, RA ; Bruinsma, F ; Giles, GG ; Liang, D ; Hildebrandt, MAT ; Wu, X ; Levine, DA ; Bisogna, M ; Berchuck, A ; Iversen, ES ; Schildkraut, JM ; Concannon, P ; Weber, RP ; Cramer, DW ; Terry, KL ; Poole, EM ; Tworoger, SS ; Bandera, EV ; Orlow, I ; Olson, SH ; Krakstad, C ; Salvesen, HB ; Tangen, IL ; Bjorge, L ; van Altena, AM ; Aben, KKH ; Kiemeney, LA ; Massuger, LFAG ; Kellar, M ; Brooks-Wilson, A ; Kelemen, LE ; Cook, LS ; Le, ND ; Cybulski, C ; Yang, H ; Lissowska, J ; Brinton, LA ; Wentzensen, N ; Hogdall, C ; Lundvall, L ; Nedergaard, L ; Baker, H ; Song, H ; Eccles, D ; McNeish, I ; Paul, J ; Carty, K ; Siddiqui, N ; Glasspool, R ; Whittemore, AS ; Rothstein, JH ; McGuire, V ; Sieh, W ; Ji, B-T ; Zheng, W ; Shu, X-O ; Gao, Y-T ; Rosen, B ; Risch, HA ; McLaughlin, JR ; Narod, SA ; Monteiro, AN ; Chen, A ; Lin, H-Y ; Permuth-Wey, J ; Sellers, TA ; Tsai, Y-Y ; Chen, Z ; Ziogas, A ; Anton-Culver, H ; Gentry-Maharaj, A ; Menon, U ; Harrington, P ; Lee, AW ; Wu, AH ; Pearce, CL ; Coetzee, G ; Pike, MC ; Dansonka-Mieszkowska, A ; Timorek, A ; Rzepecka, IK ; Kupryjanczyk, J ; Freedman, M ; Noushmehr, H ; Easton, DF ; Offit, K ; Couch, FJ ; Gayther, S ; Pharoah, PP ; Antoniou, AC ; Chenevix-Trench, G (NATURE PORTFOLIO, 2015-02)
    Genome-wide association studies (GWAS) have identified 12 epithelial ovarian cancer (EOC) susceptibility alleles. The pattern of association at these loci is consistent in BRCA1 and BRCA2 mutation carriers who are at high risk of EOC. After imputation to 1000 Genomes Project data, we assessed associations of 11 million genetic variants with EOC risk from 15,437 cases unselected for family history and 30,845 controls and from 15,252 BRCA1 mutation carriers and 8,211 BRCA2 mutation carriers (3,096 with ovarian cancer), and we combined the results in a meta-analysis. This new study design yielded increased statistical power, leading to the discovery of six new EOC susceptibility loci. Variants at 1p36 (nearest gene, WNT4), 4q26 (SYNPO2), 9q34.2 (ABO) and 17q11.2 (ATAD5) were associated with EOC risk, and at 1p34.3 (RSPO1) and 6p22.1 (GPX6) variants were specifically associated with the serous EOC subtype, all with P < 5 × 10(-8). Incorporating these variants into risk assessment tools will improve clinical risk predictions for BRCA1 and BRCA2 mutation carriers.
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    Genome-wide association study identifies multiple loci associated with both mammographic density and breast cancer risk
    Lindstroem, S ; Thompson, DJ ; Paterson, AD ; Li, J ; Gierach, GL ; Scott, C ; Stone, J ; Douglas, JA ; dos-Santos-Silva, I ; Fernandez-Navarro, P ; Verghase, J ; Smith, P ; Brown, J ; Luben, R ; Wareham, NJ ; Loos, RJF ; Heit, JA ; Pankratz, VS ; Norman, A ; Goode, EL ; Cunningham, JM ; Deandrade, M ; Vierkant, RA ; Czene, K ; Fasching, PA ; Baglietto, L ; Southey, MC ; Giles, GG ; Shah, KP ; Chan, H-P ; Helvie, MA ; Beck, AH ; Knoblauch, NW ; Hazra, A ; Hunter, DJ ; Kraft, P ; Pollan, M ; Figueroa, JD ; Couch, FJ ; Hopper, JL ; Hall, P ; Easton, DF ; Boyd, NF ; Vachon, CM ; Tamimi, RM (NATURE PORTFOLIO, 2014-10)
    Mammographic density reflects the amount of stromal and epithelial tissues in relation to adipose tissue in the breast and is a strong risk factor for breast cancer. Here we report the results from meta-analysis of genome-wide association studies (GWAS) of three mammographic density phenotypes: dense area, non-dense area and percent density in up to 7,916 women in stage 1 and an additional 10,379 women in stage 2. We identify genome-wide significant (P<5 × 10(-8)) loci for dense area (AREG, ESR1, ZNF365, LSP1/TNNT3, IGF1, TMEM184B and SGSM3/MKL1), non-dense area (8p11.23) and percent density (PRDM6, 8p11.23 and TMEM184B). Four of these regions are known breast cancer susceptibility loci, and four additional regions were found to be associated with breast cancer (P<0.05) in a large meta-analysis. These results provide further evidence of a shared genetic basis between mammographic density and breast cancer and illustrate the power of studying intermediate quantitative phenotypes to identify putative disease-susceptibility loci.
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    GWAS meta-analysis and replication identifies three new susceptibility loci for ovarian cancer
    Pharoah, PDP ; Tsai, Y-Y ; Ramus, SJ ; Phelan, CM ; Goode, EL ; Lawrenson, K ; Buckley, M ; Fridley, BL ; Tyrer, JP ; Shen, H ; Weber, R ; Karevan, R ; Larson, MC ; Song, H ; Tessier, DC ; Bacot, F ; Vincent, D ; Cunningham, JM ; Dennis, J ; Dicks, E ; Aben, KK ; Anton-Culver, H ; Antonenkova, N ; Armasu, SM ; Baglietto, L ; Bandera, EV ; Beckmann, MW ; Birrer, MJ ; Bloom, G ; Bogdanova, N ; Brenton, JD ; Brinton, LA ; Brooks-Wilson, A ; Brown, R ; Butzow, R ; Campbell, I ; Carney, ME ; Carvalho, RS ; Chang-Claude, J ; Chen, YA ; Chen, Z ; Chow, W-H ; Cicek, MS ; Coetzee, G ; Cook, LS ; Cramer, DW ; Cybulski, C ; Dansonka-Mieszkowska, A ; Despierre, E ; Doherty, JA ; Doerk, T ; du Bois, A ; Duerst, M ; Eccles, D ; Edwards, R ; Ekici, AB ; Fasching, PA ; Fenstermacher, D ; Flanagan, J ; Gao, Y-T ; Garcia-Closas, M ; Gentry-Maharaj, A ; Giles, G ; Gjyshi, A ; Gore, M ; Gronwald, J ; Guo, Q ; Halle, MK ; Harter, P ; Hein, A ; Heitz, F ; Hillemanns, P ; Hoatlin, M ; Hogdall, E ; Hogdall, CK ; Hosono, S ; Jakubowska, A ; Jensen, A ; Kalli, KR ; Karlan, BY ; Kelemen, LE ; Kiemeney, LA ; Kjaer, SK ; Konecny, GE ; Krakstad, C ; Kupryjanczyk, J ; Lambrechts, D ; Lambrechts, S ; Le, ND ; Lee, N ; Lee, J ; Leminen, A ; Lim, BK ; Lissowska, J ; Lubinski, J ; Lundvall, L ; Lurie, G ; Massuger, LFAG ; Matsuo, K ; McGuire, V ; McLaughlin, JR ; Menon, U ; Modugno, F ; Moysich, KB ; Nakanishi, T ; Narod, SA ; Ness, RB ; Nevanlinna, H ; Nickels, S ; Noushmehr, H ; Odunsi, K ; Olson, S ; Orlow, I ; Paul, J ; Pejovic, T ; Pelttari, LM ; Permuth-Wey, J ; Pike, MC ; Poole, EM ; Qu, X ; Risch, HA ; Rodriguez-Rodriguez, L ; Rossing, MA ; Rudolph, A ; Runnebaum, I ; Rzepecka, IK ; Salvesen, HB ; Schwaab, I ; Severi, G ; Shen, H ; Shridhar, V ; Shu, X-O ; Sieh, W ; Southey, MC ; Spellman, P ; Tajima, K ; Teo, S-H ; Terry, KL ; Thompson, PJ ; Timorek, A ; Tworoger, SS ; van Altena, AM ; van den Berg, D ; Vergote, I ; Vierkant, RA ; Vitonis, AF ; Wang-Gohrke, S ; Wentzensen, N ; Whittemore, AS ; Wik, E ; Winterhoff, B ; Woo, YL ; Wu, AH ; Yang, HP ; Zheng, W ; Ziogas, A ; Zulkifli, F ; Goodman, MT ; Hall, P ; Easton, DF ; Pearce, CL ; Berchuck, A ; Chenevix-Trench, G ; Iversen, E ; Monteiro, ANA ; Gayther, SA ; Schildkraut, JM ; Sellers, TA (NATURE PUBLISHING GROUP, 2013-04)
    Genome-wide association studies (GWAS) have identified four susceptibility loci for epithelial ovarian cancer (EOC), with another two suggestive loci reaching near genome-wide significance. We pooled data from a GWAS conducted in North America with another GWAS from the UK. We selected the top 24,551 SNPs for inclusion on the iCOGS custom genotyping array. We performed follow-up genotyping in 18,174 individuals with EOC (cases) and 26,134 controls from 43 studies from the Ovarian Cancer Association Consortium. We validated the two loci at 3q25 and 17q21 that were previously found to have associations close to genome-wide significance and identified three loci newly associated with risk: two loci associated with all EOC subtypes at 8q21 (rs11782652, P = 5.5 × 10(-9)) and 10p12 (rs1243180, P = 1.8 × 10(-8)) and another locus specific to the serous subtype at 17q12 (rs757210, P = 8.1 × 10(-10)). An integrated molecular analysis of genes and regulatory regions at these loci provided evidence for functional mechanisms underlying susceptibility and implicated CHMP4C in the pathogenesis of ovarian cancer.
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    Identification and molecular characterization of a new ovarian cancer susceptibility locus at 17q21.31
    Permuth-Wey, J ; Lawrenson, K ; Shen, HC ; Velkova, A ; Tyrer, JP ; Chen, Z ; Lin, H-Y ; Chen, YA ; Tsai, Y-Y ; Qu, X ; Ramus, SJ ; Karevan, R ; Lee, J ; Lee, N ; Larson, MC ; Aben, KK ; Anton-Culver, H ; Antonenkova, N ; Antoniou, AC ; Armasu, SM ; Bacot, F ; Baglietto, L ; Bandera, EV ; Barnholtz-Sloan, J ; Beckmann, MW ; Birrer, MJ ; Bloom, G ; Bogdanova, N ; Brinton, LA ; Brooks-Wilson, A ; Brown, R ; Butzow, R ; Cai, Q ; Campbell, I ; Chang-Claude, J ; Chanock, S ; Chenevix-Trench, G ; Cheng, JQ ; Cicek, MS ; Coetzee, GA ; Cook, LS ; Couch, FJ ; Cramer, DW ; Cunningham, JM ; Dansonka-Mieszkowska, A ; Despierre, E ; Doherty, JA ; Doerk, T ; du Bois, A ; Duerst, M ; Easton, DF ; Eccles, D ; Edwards, R ; Ekici, AB ; Fasching, PA ; Fenstermacher, DA ; Flanagan, JM ; Garcia-Closas, M ; Gentry-Maharaj, A ; Giles, GG ; Glasspool, RM ; Gonzalez-Bosquet, J ; Goodman, MT ; Gore, M ; Gorski, B ; Gronwald, J ; Hall, P ; Halle, MK ; Harter, P ; Heitz, F ; Hillemanns, P ; Hoatlin, M ; Hogdall, CK ; Hogdall, E ; Hosono, S ; Jakubowska, A ; Jensen, A ; Jim, H ; Kalli, KR ; Karlan, BY ; Kaye, SB ; Kelemen, LE ; Kiemeney, LA ; Kikkawa, F ; Konecny, GE ; Krakstad, C ; Kjaer, SK ; Kupryjanczyk, J ; Lambrechts, D ; Lambrechts, S ; Lancaster, JM ; Le, ND ; Leminen, A ; Levine, DA ; Liang, D ; Lim, BK ; Lin, J ; Lissowska, J ; Lu, KH ; Lubinski, J ; Lurie, G ; Massuger, LFAG ; Matsuo, K ; McGuire, V ; McLaughlin, JR ; Menon, U ; Modugno, F ; Moysich, KB ; Nakanishi, T ; Narod, SA ; Nedergaard, L ; Ness, RB ; Nevanlinna, H ; Nickels, S ; Noushmehr, H ; Odunsi, K ; Olson, SH ; Orlow, I ; Paul, J ; Pearce, CL ; Pejovic, T ; Pelttari, LM ; Pike, MC ; Poole, EM ; Raska, P ; Renner, SP ; Risch, HA ; Rodriguez-Rodriguez, L ; Rossing, MA ; Rudolph, A ; Runnebaum, IB ; Rzepecka, IK ; Salvesen, HB ; Schwaab, I ; Severi, G ; Shridhar, V ; Shu, X-O ; Shvetsov, YB ; Sieh, W ; Song, H ; Southey, MC ; Spiewankiewicz, B ; Stram, D ; Sutphen, R ; Teo, S-H ; Terry, KL ; Tessier, DC ; Thompson, PJ ; Tworoger, SS ; van Altena, AM ; Vergote, I ; Vierkant, RA ; Vincent, D ; Vitonis, AF ; Wang-Gohrke, S ; Weber, RP ; Wentzensen, N ; Whittemore, AS ; Wik, E ; Wilkens, LR ; Winterhoff, B ; Woo, YL ; Wu, AH ; Xiang, Y-B ; Yang, HP ; Zheng, W ; Ziogas, A ; Zulkifli, F ; Phelan, CM ; Iversen, E ; Schildkraut, JM ; Berchuck, A ; Fridley, BL ; Goode, EL ; Pharoah, PDP ; Monteiro, ANA ; Sellers, TA ; Gayther, SA (NATURE RESEARCH, 2013-03)
    Epithelial ovarian cancer (EOC) has a heritable component that remains to be fully characterized. Most identified common susceptibility variants lie in non-protein-coding sequences. We hypothesized that variants in the 3' untranslated region at putative microRNA (miRNA)-binding sites represent functional targets that influence EOC susceptibility. Here, we evaluate the association between 767 miRNA-related single-nucleotide polymorphisms (miRSNPs) and EOC risk in 18,174 EOC cases and 26,134 controls from 43 studies genotyped through the Collaborative Oncological Gene-environment Study. We identify several miRSNPs associated with invasive serous EOC risk (odds ratio=1.12, P=10(-8)) mapping to an inversion polymorphism at 17q21.31. Additional genotyping of non-miRSNPs at 17q21.31 reveals stronger signals outside the inversion (P=10(-10)). Variation at 17q21.31 is associated with neurological diseases, and our collaboration is the first to report an association with EOC susceptibility. An integrated molecular analysis in this region provides evidence for ARHGAP27 and PLEKHM1 as candidate EOC susceptibility genes.
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    Genome-wide association analysis identifies three new breast cancer susceptibility loci
    Ghoussaini, M ; Fletcher, O ; Michailidou, K ; Turnbull, C ; Schmidt, MK ; Dicks, E ; Dennis, J ; Wang, Q ; Humphreys, MK ; Luccarini, C ; Baynes, C ; Conroy, D ; Maranian, M ; Ahmed, S ; Driver, K ; Johnson, N ; Orr, N ; Silva, IDS ; Waisfisz, Q ; Meijers-Heijboer, H ; Uitterlinden, AG ; Rivadeneira, F ; Hall, P ; Czene, K ; Irwanto, A ; Liu, J ; Nevanlinna, H ; Aittomaki, K ; Blomqvist, C ; Meindl, A ; Schmutzler, RK ; Mueller-Myhsok, B ; Lichtner, P ; Chang-Claude, J ; Hein, R ; Nickels, S ; Flesch-Janys, D ; Tsimiklis, H ; Makalic, E ; Schmidt, D ; Bui, M ; Hopper, JL ; Apicella, C ; Park, DJ ; Southey, M ; Hunter, DJ ; Chanock, SJ ; Broeks, A ; Verhoef, S ; Hogervorst, FBL ; Fasching, PA ; Lux, MP ; Beckmann, MW ; Ekici, AB ; Sawyer, E ; Tomlinson, I ; Kerin, M ; Marme, F ; Schneeweiss, A ; Sohn, C ; Burwinkel, B ; Guenel, P ; Truong, T ; Cordina-Duverger, E ; Menegaux, F ; Bojesen, SE ; Nordestgaard, BG ; Nielsen, SF ; Flyger, H ; Milne, RL ; Rosario Alonso, M ; Gonzalez-Neira, A ; Benitez, J ; Anton-Culver, H ; Ziogas, A ; Bernstein, L ; Dur, CC ; Brenner, H ; Mueller, H ; Arndt, V ; Stegmaier, C ; Justenhoven, C ; Brauch, H ; Bruening, T ; Wang-Gohrke, S ; Eilber, U ; Doerk, T ; Schuermann, P ; Bremer, M ; Hillemanns, P ; Bogdanova, NV ; Antonenkova, NN ; Rogov, YI ; Karstens, JH ; Bermisheva, M ; Prokofieva, D ; Khusnutdinova, E ; Lindblom, A ; Margolin, S ; Mannermaa, A ; Kataja, V ; Kosma, V-M ; Hartikainen, JM ; Lambrechts, D ; Yesilyurt, BT ; Floris, G ; Leunen, K ; Manoukian, S ; Bonanni, B ; Fortuzzi, S ; Peterlongo, P ; Couch, FJ ; Wang, X ; Stevens, K ; Lee, A ; Giles, GG ; Baglietto, L ; Severi, G ; McLean, C ; Alnaes, GG ; Kristensen, V ; Borrensen-Dale, A-L ; John, EM ; Miron, A ; Winqvist, R ; Pylkas, K ; Jukkola-Vuorinen, A ; Kauppila, S ; Andrulis, IL ; Glendon, G ; Mulligan, AM ; Devilee, P ; van Asperen, CJ ; Tollenaar, RAEM ; Seynaeve, C ; Figueroa, JD ; Garcia-Closas, M ; Brinton, L ; Lissowska, J ; Hooning, MJ ; Hollestelle, A ; Oldenburg, RA ; van den Ouweland, AMW ; Cox, A ; Reed, MWR ; Shah, M ; Jakubowska, A ; Lubinski, J ; Jaworska, K ; Durda, K ; Jones, M ; Schoemaker, M ; Ashworth, A ; Swerdlow, A ; Beesley, J ; Chen, X ; Muir, KR ; Lophatananon, A ; Rattanamongkongul, S ; Chaiwerawattana, A ; Kang, D ; Yoo, K-Y ; Noh, D-Y ; Shen, C-Y ; Yu, J-C ; Wu, P-E ; Hsiung, C-N ; Perkins, A ; Swann, R ; Velentzis, L ; Eccles, DM ; Tapper, WJ ; Gerty, SM ; Graham, NJ ; Ponder, BAJ ; Chenevix-Trench, G ; Pharoah, PDP ; Lathrop, M ; Dunning, AM ; Rahman, N ; Peto, J ; Easton, DF (NATURE PUBLISHING GROUP, 2012-03)
    Breast cancer is the most common cancer among women. To date, 22 common breast cancer susceptibility loci have been identified accounting for ∼8% of the heritability of the disease. We attempted to replicate 72 promising associations from two independent genome-wide association studies (GWAS) in ∼70,000 cases and ∼68,000 controls from 41 case-control studies and 9 breast cancer GWAS. We identified three new breast cancer risk loci at 12p11 (rs10771399; P = 2.7 × 10(-35)), 12q24 (rs1292011; P = 4.3 × 10(-19)) and 21q21 (rs2823093; P = 1.1 × 10(-12)). rs10771399 was associated with similar relative risks for both estrogen receptor (ER)-negative and ER-positive breast cancer, whereas the other two loci were associated only with ER-positive disease. Two of the loci lie in regions that contain strong plausible candidate genes: PTHLH (12p11) has a crucial role in mammary gland development and the establishment of bone metastasis in breast cancer, and NRIP1 (21q21) encodes an ER cofactor and has a role in the regulation of breast cancer cell growth.
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    Evaluation of variation in the phosphoinositide-3-kinase catalytic subunit alpha oncogene and breast cancer risk
    Stevens, KN ; Garcia-Closas, M ; Fredericksen, Z ; Kosel, M ; Pankratz, VS ; Hopper, JL ; Dite, GS ; Apicella, C ; Southey, MC ; Schmidt, MK ; Broeks, A ; Van 't Veer, LJ ; Tollenaar, RAEM ; Fasching, PA ; Beckmann, MW ; Hein, A ; Ekici, AB ; Johnson, N ; Peto, J ; Silva, IDS ; Gibson, L ; Sawyer, E ; Tomlinson, I ; Kerin, MJ ; Chanock, S ; Lissowska, J ; Hunter, DJ ; Hoover, RN ; Thomas, GD ; Milne, RL ; Perez, JIA ; Gonzalez-Neira, A ; Benitez, J ; Burwinkel, B ; Meindl, A ; Schmutzler, RK ; Bartrar, CR ; Hamann, U ; Ko, YD ; Bruening, T ; Chang-Claude, J ; Hein, R ; Wang-Gohrke, S ; Doerk, T ; Schuermann, P ; Bremer, M ; Hillemanns, P ; Bogdanova, N ; Zalutsky, JV ; Rogov, YI ; Antonenkova, N ; Lindblom, A ; Margolin, S ; Mannermaa, A ; Kataja, V ; Kosma, V-M ; Hartikainen, J ; Chenevix-Trench, G ; Chen, X ; Peterlongo, P ; Bonanni, B ; Bernard, L ; Manoukian, S ; Wang, X ; Cerhan, J ; Vachon, CM ; Olson, J ; Giles, GG ; Baglietto, L ; McLean, CA ; Severi, G ; John, EM ; Miron, A ; Winqvist, R ; Pylkaes, K ; Jukkola-Vuorinen, A ; Grip, M ; Andrulis, I ; Knight, JA ; Glendon, G ; Mulligan, AM ; Cox, A ; Brock, IW ; Elliott, G ; Cross, SS ; Pharoah, PP ; Dunning, AM ; Pooley, KA ; Humphreys, MK ; Wang, J ; Kang, D ; Yoo, K-Y ; Noh, D-Y ; Sangrajrang, S ; Gabrieau, V ; Brennan, P ; Mckay, J ; Anton-Culver, H ; Ziogas, A ; Couch, FJ ; Easton, DF (NATURE PUBLISHING GROUP, 2011-12-06)
    BACKGROUND: Somatic mutations in phosphoinositide-3-kinase catalytic subunit alpha (PIK3CA) are frequent in breast tumours and have been associated with oestrogen receptor (ER) expression, human epidermal growth factor receptor-2 overexpression, lymph node metastasis and poor survival. The goal of this study was to evaluate the association between inherited variation in this oncogene and risk of breast cancer. METHODS: A single-nucleotide polymorphism from the PIK3CA locus that was associated with breast cancer in a study of Caucasian breast cancer cases and controls from the Mayo Clinic (MCBCS) was genotyped in 5436 cases and 5280 controls from the Cancer Genetic Markers of Susceptibility (CGEMS) study and in 30 949 cases and 29 788 controls from the Breast Cancer Association Consortium (BCAC). RESULTS: Rs1607237 was significantly associated with a decreased risk of breast cancer in MCBCS, CGEMS and all studies of white Europeans combined (odds ratio (OR)=0.97, 95% confidence interval (CI) 0.95-0.99, P=4.6 × 10(-3)), but did not reach significance in the BCAC replication study alone (OR=0.98, 95% CI 0.96-1.01, P=0.139). CONCLUSION: Common germline variation in PIK3CA does not have a strong influence on the risk of breast cancer.
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    Dietary patterns and risk of breast cancer
    Baglietto, L ; Krishnan, K ; Severi, G ; Hodge, A ; Brinkman, M ; English, DR ; McLean, C ; Hopper, JL ; Giles, GG (SPRINGERNATURE, 2011-02-01)
    BACKGROUND: Evidence is emerging that prudent/healthy dietary patterns might be associated with a reduced risk of breast cancer. METHODS: Using data from the prospective Melbourne Collaborative Cohort Study, we applied principal factor analysis to 124 foods and beverages to identify dietary patterns and estimated their association with breast cancer risk overall and by tumour characteristics using Cox regression. RESULTS: During an average of 14.1 years of follow-up of 20 967 women participants, 815 invasive breast cancers were diagnosed. Among the four dietary factors that we identified, only that characterised by high consumption of fruit and salad was associated with a reduced risk, with stronger associations observed for tumours not expressing oestrogen (ER) and progesterone receptors (PR). Compared with women in the lowest quintile of the factor score, the hazard ratio for women in the highest quintile was 0.92 (95% confidence interval (CI)=0.70-1.21; test for trend, P=0.5) for ER-positive or PR-positive tumours and 0.48 (95% CI=0.26-0.86; test for trend, P=0.002) for ER-negative and PR-negative tumours (test for homogeneity, P=0.01). CONCLUSION: Our study provides additional support for the hypothesis that a dietary pattern rich in fruit and salad might protect against invasive breast cancer and that the effect might be stronger for ER- and PR-negative tumours.