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1.  MicroRNA Related Polymorphisms and Breast Cancer Risk 
Khan, Sofia | Greco, Dario | Michailidou, Kyriaki | Milne, Roger L. | Muranen, Taru A. | Heikkinen, Tuomas | Aaltonen, Kirsimari | Dennis, Joe | Bolla, Manjeet K. | Liu, Jianjun | Hall, Per | Irwanto, Astrid | Humphreys, Keith | Li, Jingmei | Czene, Kamila | Chang-Claude, Jenny | Hein, Rebecca | Rudolph, Anja | Seibold, Petra | Flesch-Janys, Dieter | Fletcher, Olivia | Peto, Julian | dos Santos Silva, Isabel | Johnson, Nichola | Gibson, Lorna | Aitken, Zoe | Hopper, John L. | Tsimiklis, Helen | Bui, Minh | Makalic, Enes | Schmidt, Daniel F. | Southey, Melissa C. | Apicella, Carmel | Stone, Jennifer | Waisfisz, Quinten | Meijers-Heijboer, Hanne | Adank, Muriel A. | van der Luijt, Rob B. | Meindl, Alfons | Schmutzler, Rita K. | Müller-Myhsok, Bertram | Lichtner, Peter | Turnbull, Clare | Rahman, Nazneen | Chanock, Stephen J. | Hunter, David J. | Cox, Angela | Cross, Simon S. | Reed, Malcolm W. R. | Schmidt, Marjanka K. | Broeks, Annegien | Veer, Laura J. V. a. n't. | Hogervorst, Frans B. | Fasching, Peter A. | Schrauder, Michael G. | Ekici, Arif B. | Beckmann, Matthias W. | Bojesen, Stig E. | Nordestgaard, Børge G. | Nielsen, Sune F. | Flyger, Henrik | Benitez, Javier | Zamora, Pilar M. | Perez, Jose I. A. | Haiman, Christopher A. | Henderson, Brian E. | Schumacher, Fredrick | Le Marchand, Loic | Pharoah, Paul D. P. | Dunning, Alison M. | Shah, Mitul | Luben, Robert | Brown, Judith | Couch, Fergus J. | Wang, Xianshu | Vachon, Celine | Olson, Janet E. | Lambrechts, Diether | Moisse, Matthieu | Paridaens, Robert | Christiaens, Marie-Rose | Guénel, Pascal | Truong, Thérèse | Laurent-Puig, Pierre | Mulot, Claire | Marme, Frederick | Burwinkel, Barbara | Schneeweiss, Andreas | Sohn, Christof | Sawyer, Elinor J. | Tomlinson, Ian | Kerin, Michael J. | Miller, Nicola | Andrulis, Irene L. | Knight, Julia A. | Tchatchou, Sandrine | Mulligan, Anna Marie | Dörk, Thilo | Bogdanova, Natalia V. | Antonenkova, Natalia N. | Anton-Culver, Hoda | Darabi, Hatef | Eriksson, Mikael | Garcia-Closas, Montserrat | Figueroa, Jonine | Lissowska, Jolanta | Brinton, Louise | Devilee, Peter | Tollenaar, Robert A. E. M. | Seynaeve, Caroline | van Asperen, Christi J. | Kristensen, Vessela N. | Slager, Susan | Toland, Amanda E. | Ambrosone, Christine B. | Yannoukakos, Drakoulis | Lindblom, Annika | Margolin, Sara | Radice, Paolo | Peterlongo, Paolo | Barile, Monica | Mariani, Paolo | Hooning, Maartje J. | Martens, John W. M. | Collée, J. Margriet | Jager, Agnes | Jakubowska, Anna | Lubinski, Jan | Jaworska-Bieniek, Katarzyna | Durda, Katarzyna | Giles, Graham G. | McLean, Catriona | Brauch, Hiltrud | Brüning, Thomas | Ko, Yon-Dschun | Brenner, Hermann | Dieffenbach, Aida Karina | Arndt, Volker | Stegmaier, Christa | Swerdlow, Anthony | Ashworth, Alan | Orr, Nick | Jones, Michael | Simard, Jacques | Goldberg, Mark S. | Labrèche, France | Dumont, Martine | Winqvist, Robert | Pylkäs, Katri | Jukkola-Vuorinen, Arja | Grip, Mervi | Kataja, Vesa | Kosma, Veli-Matti | Hartikainen, Jaana M. | Mannermaa, Arto | Hamann, Ute | Chenevix-Trench, Georgia | Blomqvist, Carl | Aittomäki, Kristiina | Easton, Douglas F. | Nevanlinna, Heli
PLoS ONE  2014;9(11):e109973.
Genetic variations, such as single nucleotide polymorphisms (SNPs) in microRNAs (miRNA) or in the miRNA binding sites may affect the miRNA dependent gene expression regulation, which has been implicated in various cancers, including breast cancer, and may alter individual susceptibility to cancer. We investigated associations between miRNA related SNPs and breast cancer risk. First we evaluated 2,196 SNPs in a case-control study combining nine genome wide association studies (GWAS). Second, we further investigated 42 SNPs with suggestive evidence for association using 41,785 cases and 41,880 controls from 41 studies included in the Breast Cancer Association Consortium (BCAC). Combining the GWAS and BCAC data within a meta-analysis, we estimated main effects on breast cancer risk as well as risks for estrogen receptor (ER) and age defined subgroups. Five miRNA binding site SNPs associated significantly with breast cancer risk: rs1045494 (odds ratio (OR) 0.92; 95% confidence interval (CI): 0.88–0.96), rs1052532 (OR 0.97; 95% CI: 0.95–0.99), rs10719 (OR 0.97; 95% CI: 0.94–0.99), rs4687554 (OR 0.97; 95% CI: 0.95–0.99, and rs3134615 (OR 1.03; 95% CI: 1.01–1.05) located in the 3′ UTR of CASP8, HDDC3, DROSHA, MUSTN1, and MYCL1, respectively. DROSHA belongs to miRNA machinery genes and has a central role in initial miRNA processing. The remaining genes are involved in different molecular functions, including apoptosis and gene expression regulation. Further studies are warranted to elucidate whether the miRNA binding site SNPs are the causative variants for the observed risk effects.
doi:10.1371/journal.pone.0109973
PMCID: PMC4229095  PMID: 25390939
2.  Mutations in the DNA methyltransferase gene, DNMT3A, cause an overgrowth syndrome with intellectual disability 
Nature genetics  2014;46(4):385-388.
Overgrowth disorders are a heterogeneous group of conditions characterised by increased growth parameters and variable other clinical features, such as intellectual disability and facial dysmorphism1. To identify novel causes of human overgrowth we performed exome sequencing in 10 proband-parent trios and detected two de novo DNMT3A mutations. We identified 11 additional de novo mutations through DNMT3A sequencing of a further 142 individuals with overgrowth. The mutations were all located in functional DNMT3A domains and protein modelling suggests they interfere with domain-domain interactions and histone binding. No similar mutations were present in 1000 UK population controls (13/152 vs 0/1000; P<0.0001). Mutation carriers had a distinctive facial appearance, intellectual disability and increased height. DNMT3A encodes a key methyltransferase essential for establishing the methylation imprint in embryogenesis and is commonly somatically mutated in acute myeloid leukaemia2-4. Thus DNMT3A joins an emerging group of epigenetic DNA and histone modifying genes associated with both developmental growth disorders and haematological malignancies5.
doi:10.1038/ng.2917
PMCID: PMC3981653  PMID: 24614070
3.  Confirmation of 5p12 as a susceptibility locus for progesterone-receptor-positive, lower grade breast cancer 
Milne, Roger L. | Goode, Ellen L. | García-Closas, Montserrat | Couch, Fergus J. | Severi, Gianluca | Hein, Rebecca | Fredericksen, Zachary | Malats, Núria | Zamora, M. Pilar | Pérez, Jose Ignacio Arias | Benítez, Javier | Dörk, Thilo | Schürmann, Peter | Karstens, Johann H. | Hillemanns, Peter | Cox, Angela | Brock, Ian W. | Elliot, Graeme | Cross, Simon S. | Seal, Sheila | Turnbull, Clare | Renwick, Anthony | Rahman, Nazneen | Shen, Chen-Yang | Yu, Jyh-Cherng | Huang, Chiun-Sheng | Hou, Ming-Feng | Nordestgaard, Børge G. | Bojesen, Stig E. | Lanng, Charlotte | Alnæs, Grethe Grenaker | Kristensen, Vessela | Børrensen-Dale, Anne-Lise | Hopper, John L. | Dite, Gillian S. | Apicella, Carmel | Southey, Melissa C. | Lambrechts, Diether | Yesilyurt, Betül T. | Floris, Giuseppe | Leunen, Karin | Sangrajrang, Suleeporn | Gaborieau, Valerie | Brennan, Paul | McKay, James | Chang-Claude, Jenny | Wang-Gohrke, Shan | Radice, Paolo | Peterlongo, Paolo | Manoukian, Siranoush | Barile, Monica | Giles, Graham G. | Baglietto, Laura | John, Esther M. | Miron, Alexander | Chanock, Stephen J. | Lissowska, Jolanta | Sherman, Mark E. | Figueroa, Jonine D. | Bogdanova, Natalia V. | Antonenkova, Natalia N. | Zalutsky, Iosif V. | Rogov, Yuri I. | Fasching, Peter A. | Bayer, Christian M. | Ekici, Arif B. | Beckmann, Matthias W. | Brenner, Hermann | Müller, Heiko | Arndt, Volker | Stegmaier, Christa | Andrulis, Irene L. | Knight, Julia A. | Glendon, Gord | Mulligan, Anna Marie | Mannermaa, Arto | Kataja, Vesa | Kosma, Veli-Matti | Hartikainen, Jaana M. | Meindl, Alfons | Heil, Joerg | Bartram, Claus R. | Schmutzler, Rita K. | Thomas, Gilles D. | Hoover, Robert N. | Fletcher, Olivia | Gibson, Lorna J. | Silva, Isabel dos Santos | Peto, Julian | Nickels, Stefan | Flesch-Janys, Dieter | Anton-Culver, Hoda | Ziogas, Argyrios | Sawyer, Elinor | Tomlinson, Ian | Kerin, Michael | Miller, Nicola | Schmidt, Marjanka K. | Broeks, Annegien | Van ‘t Veer, Laura J. | Tollenaar, Rob A.E.M. | Pharoah, Paul D.P. | Dunning, Alison M. | Pooley, Karen A. | Marme, Frederik | Schneeweiss, Andreas | Sohn, Christof | Burwinkel, Barbara | Jakubowska, Anna | Lubinski, Jan | Jaworska, Katarzyna | Durda, Katarzyna | Kang, Daehee | Yoo, Keun-Young | Noh, Dong-Young | Ahn, Sei-Hyun | Hunter, David J. | Hankinson, Susan E. | Kraft, Peter | Lindstrom, Sara | Chen, Xiaoqing | Beesley, Jonathan | Hamann, Ute | Harth, Volker | Justenhoven, Christina | Winqvist, Robert | Pylkäs, Katri | Jukkola-Vuorinen, Arja | Grip, Mervi | Hooning, Maartje | Hollestelle, Antoinette | Oldenburg, Rogier A. | Tilanus-Linthorst, Madeleine | Khusnutdinova, Elza | Bermisheva, Marina | Prokofieva, Darya | Farahtdinova, Albina | Olson, Janet E. | Wang, Xianshu | Humphreys, Manjeet K. | Wang, Qin | Chenevix-Trench, Georgia | Easton, Douglas F.
Background
The single nucleotide polymorphism 5p12-rs10941679has been found to be associated with risk of breast cancer, particularly estrogen receptor (ER)-positive disease. We aimed to further explore this association overall, and by tumor histopathology, in the Breast Cancer Association Consortium.
Methods
Data were combined from 37 studies, including 40,972 invasive cases, 1,398 cases of ductal carcinoma in situ (DCIS) and 46,334 controls, all of white European ancestry, as well as 3,007 invasive cases and 2,337 controls of Asian ancestry. Associations overall and by tumor invasiveness and histopathology were assessed using logistic regression.
Results
For white Europeans, the per-allele odds ratio (OR) associated with 5p12-rs10941679 was 1.11 (95% confidence interval [CI] =1.08–1.14, P=7×10−18) for invasive breast cancer and 1.10 (95%CI=1.01–1.21, P=0.03) for DCIS. For Asian women, the estimated OR for invasive disease was similar (OR=1.07, 95%CI=0.99–1.15, P=0.09). Further analyses suggested that the association in white Europeans was largely limited to progesterone receptor (PR)-positive disease (per-allele OR=1.16, 95%CI=1.12–1.20, P=1×10−18 versus OR=1.03, 95%CI=0.99–1.07, P=0.2 for PR-negative disease; P-heterogeneity=2×10−7); heterogeneity by estrogen receptor status was not observed (P=0.2) once PR status was accounted for. The association was also stronger for lower-grade tumors (per-allele OR [95%CI]=1.20 [1.14–1.25], 1.13 [1.09–1.16] and 1.04 [0.99–1.08] for grade 1, 2 and 3/4, respectively; P–trend=5×10−7).
Conclusion
5p12 is a breast cancer susceptibility locus for PR-positive, lower gradebreast cancer.
Impact
Multi-centre fine-mapping studies of this region are needed as a first step to identifying the causal variant or variants.
doi:10.1158/1055-9965.EPI-11-0569
PMCID: PMC4164116  PMID: 21795498
Breast cancer; SNP; susceptibility; disease subtypes
4.  Characterizing Genetic Variants for Clinical Action 
Genome-wide association studies, DNA sequencing studies, and other genomic studies are finding an increasing number of genetic variants associated with clinical phenotypes that may be useful in developing diagnostic, preventive, and treatment strategies for individual patients. However, few common variants have been integrated into routine clinical practice. The reasons for this are several, but two of the most significant are limited evidence about the clinical implications of the variants and a lack of a comprehensive knowledge base that captures genetic variants, their phenotypic associations, and other pertinent phenotypic information that is openly accessible to clinical groups attempting to interpret sequencing data. As the field of medicine begins to incorporate genome-scale analysis into clinical care, approaches need to be developed for collecting and characterizing data on the clinical implications of variants, developing consensus on their actionability, and making this information available for clinical use. The National Human Genome Research Institute (NHGRI) and the Wellcome Trust thus convened a workshop to consider the processes and resources needed to: 1) identify clinically valid genetic variants; 2) decide whether they are actionable and what the action should be; and 3) provide this information for clinical use. This commentary outlines the key discussion points and recommendations from the workshop.
doi:10.1002/ajmg.c.31386
PMCID: PMC4158437  PMID: 24634402
genomic medicine; clinical actionability; database; electronic health records (EHR); pharmacogenomics; DNA sequencing
5.  Recognition of and Response to Neonatal Intrapartum-related Complications in Home-birth Settings in Bangladesh 
ABSTRACT
Intrapartum-related complications (previously called ‘birth asphyxia’) are a significant contributor to deaths of newborns in Bangladesh. This study describes some of the perceived signs, causes, and treatments for this condition as described by new mothers, female relatives, traditional birth attendants, and village doctors in three sites in Bangladesh. Informants were asked to name characteristics of a healthy newborn and a newborn with difficulty in breathing at birth and about the perceived causes, consequences, and treatments for breathing difficulties. Across all three sites ‘no movement’ and ‘no cry’ were identified as signs of breathing difficulties while ‘prolonged labour’ was the most commonly-mentioned cause. Informants described a variety of treatments for difficulty in breathing at birth, including biomedical and, less often, spiritual and traditional practices. This study identified the areas that need to be addressed through behaviour change interventions to improve recognition of and response to intrapartum-related complications in Bangladesh.
PMCID: PMC4221456  PMID: 25395913
Home-birth; Intrapartum-related complications; Bangladesh
6.  Testicular germ cell tumor susceptibility associated with the UCK2 locus on chromosome 1q23 
Human Molecular Genetics  2013;22(13):2748-2753.
Genome-wide association studies (GWASs) have identified multiple common genetic variants associated with an increased risk of testicular germ cell tumors (TGCTs). A previous GWAS reported a possible TGCT susceptibility locus on chromosome 1q23 in the UCK2 gene, but failed to reach genome-wide significance following replication. We interrogated this region by conducting a meta-analysis of two independent GWASs including a total of 940 TGCT cases and 1559 controls for 122 single-nucleotide polymorphisms (SNPs) on chromosome 1q23 and followed up the most significant SNPs in an additional 2202 TGCT cases and 2386 controls from four case–control studies. We observed genome-wide significant associations for several UCK2 markers, the most significant of which was for rs3790665 (PCombined = 6.0 × 10−9). Additional support is provided from an independent familial study of TGCT where a significant over-transmission for rs3790665 with TGCT risk was observed (PFBAT = 2.3 × 10−3). Here, we provide substantial evidence for the association between UCK2 genetic variation and TGCT risk.
doi:10.1093/hmg/ddt109
PMCID: PMC3674801  PMID: 23462292
7.  Large-scale genotyping identifies 41 new loci associated with breast cancer risk 
Michailidou, Kyriaki | Hall, Per | Gonzalez-Neira, Anna | Ghoussaini, Maya | Dennis, Joe | Milne, Roger L | Schmidt, Marjanka K | Chang-Claude, Jenny | Bojesen, Stig E | Bolla, Manjeet K | Wang, Qin | Dicks, Ed | Lee, Andrew | Turnbull, Clare | Rahman, Nazneen | Fletcher, Olivia | Peto, Julian | Gibson, Lorna | Silva, Isabel dos Santos | Nevanlinna, Heli | Muranen, Taru A | Aittomäki, Kristiina | Blomqvist, Carl | Czene, Kamila | Irwanto, Astrid | Liu, Jianjun | Waisfisz, Quinten | Meijers-Heijboer, Hanne | Adank, Muriel | van der Luijt, Rob B | Hein, Rebecca | Dahmen, Norbert | Beckman, Lars | Meindl, Alfons | Schmutzler, Rita K | Müller-Myhsok, Bertram | Lichtner, Peter | Hopper, John L | Southey, Melissa C | Makalic, Enes | Schmidt, Daniel F | Uitterlinden, Andre G | Hofman, Albert | Hunter, David J | Chanock, Stephen J | Vincent, Daniel | Bacot, François | Tessier, Daniel C | Canisius, Sander | Wessels, Lodewyk F A | Haiman, Christopher A | Shah, Mitul | Luben, Robert | Brown, Judith | Luccarini, Craig | Schoof, Nils | Humphreys, Keith | Li, Jingmei | Nordestgaard, Børge G | Nielsen, Sune F | Flyger, Henrik | Couch, Fergus J | Wang, Xianshu | Vachon, Celine | Stevens, Kristen N | Lambrechts, Diether | Moisse, Matthieu | Paridaens, Robert | Christiaens, Marie-Rose | Rudolph, Anja | Nickels, Stefan | Flesch-Janys, Dieter | Johnson, Nichola | Aitken, Zoe | Aaltonen, Kirsimari | Heikkinen, Tuomas | Broeks, Annegien | Van’t Veer, Laura J | van der Schoot, C Ellen | Guénel, Pascal | Truong, Thérèse | Laurent-Puig, Pierre | Menegaux, Florence | Marme, Frederik | Schneeweiss, Andreas | Sohn, Christof | Burwinkel, Barbara | Zamora, M Pilar | Perez, Jose Ignacio Arias | Pita, Guillermo | Alonso, M Rosario | Cox, Angela | Brock, Ian W | Cross, Simon S | Reed, Malcolm W R | Sawyer, Elinor J | Tomlinson, Ian | Kerin, Michael J | Miller, Nicola | Henderson, Brian E | Schumacher, Fredrick | Le Marchand, Loic | Andrulis, Irene L | Knight, Julia A | Glendon, Gord | Mulligan, Anna Marie | Lindblom, Annika | Margolin, Sara | Hooning, Maartje J | Hollestelle, Antoinette | van den Ouweland, Ans M W | Jager, Agnes | Bui, Quang M | Stone, Jennifer | Dite, Gillian S | Apicella, Carmel | Tsimiklis, Helen | Giles, Graham G | Severi, Gianluca | Baglietto, Laura | Fasching, Peter A | Haeberle, Lothar | Ekici, Arif B | Beckmann, Matthias W | Brenner, Hermann | Müller, Heiko | Arndt, Volker | Stegmaier, Christa | Swerdlow, Anthony | Ashworth, Alan | Orr, Nick | Jones, Michael | Figueroa, Jonine | Lissowska, Jolanta | Brinton, Louise | Goldberg, Mark S | Labrèche, France | Dumont, Martine | Winqvist, Robert | Pylkäs, Katri | Jukkola-Vuorinen, Arja | Grip, Mervi | Brauch, Hiltrud | Hamann, Ute | Brüning, Thomas | Radice, Paolo | Peterlongo, Paolo | Manoukian, Siranoush | Bonanni, Bernardo | Devilee, Peter | Tollenaar, Rob A E M | Seynaeve, Caroline | van Asperen, Christi J | Jakubowska, Anna | Lubinski, Jan | Jaworska, Katarzyna | Durda, Katarzyna | Mannermaa, Arto | Kataja, Vesa | Kosma, Veli-Matti | Hartikainen, Jaana M | Bogdanova, Natalia V | Antonenkova, Natalia N | Dörk, Thilo | Kristensen, Vessela N | Anton-Culver, Hoda | Slager, Susan | Toland, Amanda E | Edge, Stephen | Fostira, Florentia | Kang, Daehee | Yoo, Keun-Young | Noh, Dong-Young | Matsuo, Keitaro | Ito, Hidemi | Iwata, Hiroji | Sueta, Aiko | Wu, Anna H | Tseng, Chiu-Chen | Van Den Berg, David | Stram, Daniel O | Shu, Xiao-Ou | Lu, Wei | Gao, Yu-Tang | Cai, Hui | Teo, Soo Hwang | Yip, Cheng Har | Phuah, Sze Yee | Cornes, Belinda K | Hartman, Mikael | Miao, Hui | Lim, Wei Yen | Sng, Jen-Hwei | Muir, Kenneth | Lophatananon, Artitaya | Stewart-Brown, Sarah | Siriwanarangsan, Pornthep | Shen, Chen-Yang | Hsiung, Chia-Ni | Wu, Pei-Ei | Ding, Shian-Ling | Sangrajrang, Suleeporn | Gaborieau, Valerie | Brennan, Paul | McKay, James | Blot, William J | Signorello, Lisa B | Cai, Qiuyin | Zheng, Wei | Deming-Halverson, Sandra | Shrubsole, Martha | Long, Jirong | Simard, Jacques | Garcia-Closas, Montse | Pharoah, Paul D P | Chenevix-Trench, Georgia | Dunning, Alison M | Benitez, Javier | Easton, Douglas F
Nature genetics  2013;45(4):353-361e2.
Breast cancer is the most common cancer among women. Common variants at 27 loci have been identified as associated with susceptibility to breast cancer, and these account for ~9% of the familial risk of the disease. We report here a meta-analysis of 9 genome-wide association studies, including 10,052 breast cancer cases and 12,575 controls of European ancestry, from which we selected 29,807 SNPs for further genotyping. These SNPs were genotyped in 45,290 cases and 41,880 controls of European ancestry from 41 studies in the Breast Cancer Association Consortium (BCAC). The SNPs were genotyped as part of a collaborative genotyping experiment involving four consortia (Collaborative Oncological Gene-environment Study, COGS) and used a custom Illumina iSelect genotyping array, iCOGS, comprising more than 200,000 SNPs. We identified SNPs at 41 new breast cancer susceptibility loci at genome-wide significance (P < 5 × 10−8). Further analyses suggest that more than 1,000 additional loci are involved in breast cancer susceptibility.
doi:10.1038/ng.2563
PMCID: PMC3771688  PMID: 23535729
8.  Genome-wide association studies identify four ER negative–specific breast cancer risk loci 
Garcia-Closas, Montserrat | Couch, Fergus J | Lindstrom, Sara | Michailidou, Kyriaki | Schmidt, Marjanka K | Brook, Mark N | orr, Nick | Rhie, Suhn Kyong | Riboli, Elio | Feigelson, Heather s | Le Marchand, Loic | Buring, Julie E | Eccles, Diana | Miron, Penelope | Fasching, Peter A | Brauch, Hiltrud | Chang-Claude, Jenny | Carpenter, Jane | Godwin, Andrew K | Nevanlinna, Heli | Giles, Graham G | Cox, Angela | Hopper, John L | Bolla, Manjeet K | Wang, Qin | Dennis, Joe | Dicks, Ed | Howat, Will J | Schoof, Nils | Bojesen, Stig E | Lambrechts, Diether | Broeks, Annegien | Andrulis, Irene L | Guénel, Pascal | Burwinkel, Barbara | Sawyer, Elinor J | Hollestelle, Antoinette | Fletcher, Olivia | Winqvist, Robert | Brenner, Hermann | Mannermaa, Arto | Hamann, Ute | Meindl, Alfons | Lindblom, Annika | Zheng, Wei | Devillee, Peter | Goldberg, Mark S | Lubinski, Jan | Kristensen, Vessela | Swerdlow, Anthony | Anton-Culver, Hoda | Dörk, Thilo | Muir, Kenneth | Matsuo, Keitaro | Wu, Anna H | Radice, Paolo | Teo, Soo Hwang | Shu, Xiao-Ou | Blot, William | Kang, Daehee | Hartman, Mikael | Sangrajrang, Suleeporn | Shen, Chen-Yang | Southey, Melissa C | Park, Daniel J | Hammet, Fleur | Stone, Jennifer | Veer, Laura J Van’t | Rutgers, Emiel J | Lophatananon, Artitaya | Stewart-Brown, Sarah | Siriwanarangsan, Pornthep | Peto, Julian | Schrauder, Michael G | Ekici, Arif B | Beckmann, Matthias W | Silva, Isabel dos Santos | Johnson, Nichola | Warren, Helen | Tomlinson, Ian | Kerin, Michael J | Miller, Nicola | Marme, Federick | Schneeweiss, Andreas | Sohn, Christof | Truong, Therese | Laurent-Puig, Pierre | Kerbrat, Pierre | Nordestgaard, Børge G | Nielsen, Sune F | Flyger, Henrik | Milne, Roger L | Perez, Jose Ignacio Arias | Menéndez, Primitiva | Müller, Heiko | Arndt, Volker | Stegmaier, Christa | Lichtner, Peter | Lochmann, Magdalena | Justenhoven, Christina | Ko, Yon-Dschun | Muranen, Taru A | Aittomäki, Kristiina | Blomqvist, Carl | Greco, Dario | Heikkinen, Tuomas | Ito, Hidemi | Iwata, Hiroji | Yatabe, Yasushi | Antonenkova, Natalia N | Margolin, Sara | Kataja, Vesa | Kosma, Veli-Matti | Hartikainen, Jaana M | Balleine, Rosemary | Tseng, Chiu-Chen | Van Den Berg, David | Stram, Daniel O | Neven, Patrick | Dieudonné, Anne-Sophie | Leunen, Karin | Rudolph, Anja | Nickels, Stefan | Flesch-Janys, Dieter | Peterlongo, Paolo | Peissel, Bernard | Bernard, Loris | Olson, Janet E | Wang, Xianshu | Stevens, Kristen | Severi, Gianluca | Baglietto, Laura | Mclean, Catriona | Coetzee, Gerhard A | Feng, Ye | Henderson, Brian E | Schumacher, Fredrick | Bogdanova, Natalia V | Labrèche, France | Dumont, Martine | Yip, Cheng Har | Taib, Nur Aishah Mohd | Cheng, Ching-Yu | Shrubsole, Martha | Long, Jirong | Pylkäs, Katri | Jukkola-Vuorinen, Arja | Kauppila, Saila | knight, Julia A | Glendon, Gord | Mulligan, Anna Marie | Tollenaar, Robertus A E M | Seynaeve, Caroline M | Kriege, Mieke | Hooning, Maartje J | Van den Ouweland, Ans M W | Van Deurzen, Carolien H M | Lu, Wei | Gao, Yu-Tang | Cai, Hui | Balasubramanian, Sabapathy P | Cross, Simon S | Reed, Malcolm W R | Signorello, Lisa | Cai, Qiuyin | Shah, Mitul | Miao, Hui | Chan, Ching Wan | Chia, Kee Seng | Jakubowska, Anna | Jaworska, Katarzyna | Durda, Katarzyna | Hsiung, Chia-Ni | Wu, Pei-Ei | Yu, Jyh-Cherng | Ashworth, Alan | Jones, Michael | Tessier, Daniel C | González-Neira, Anna | Pita, Guillermo | Alonso, M Rosario | Vincent, Daniel | Bacot, Francois | Ambrosone, Christine B | Bandera, Elisa V | John, Esther M | Chen, Gary K | Hu, Jennifer J | Rodriguez-gil, Jorge L | Bernstein, Leslie | Press, Michael F | Ziegler, Regina G | Millikan, Robert M | Deming-Halverson, Sandra L | Nyante, Sarah | Ingles, Sue A | Waisfisz, Quinten | Tsimiklis, Helen | Makalic, Enes | Schmidt, Daniel | Bui, Minh | Gibson, Lorna | Müller-Myhsok, Bertram | Schmutzler, Rita K | Hein, Rebecca | Dahmen, Norbert | Beckmann, Lars | Aaltonen, Kirsimari | Czene, Kamila | Irwanto, Astrid | Liu, Jianjun | Turnbull, Clare | Rahman, Nazneen | Meijers-Heijboer, Hanne | Uitterlinden, Andre G | Rivadeneira, Fernando | Olswold, Curtis | Slager, Susan | Pilarski, Robert | Ademuyiwa, Foluso | Konstantopoulou, Irene | Martin, Nicholas G | Montgomery, Grant W | Slamon, Dennis J | Rauh, Claudia | Lux, Michael P | Jud, Sebastian M | Bruning, Thomas | Weaver, Joellen | Sharma, Priyanka | Pathak, Harsh | Tapper, Will | Gerty, Sue | Durcan, Lorraine | Trichopoulos, Dimitrios | Tumino, Rosario | Peeters, Petra H | Kaaks, Rudolf | Campa, Daniele | Canzian, Federico | Weiderpass, Elisabete | Johansson, Mattias | Khaw, Kay-Tee | Travis, Ruth | Clavel-Chapelon, Françoise | Kolonel, Laurence N | Chen, Constance | Beck, Andy | Hankinson, Susan E | Berg, Christine D | Hoover, Robert N | Lissowska, Jolanta | Figueroa, Jonine D | Chasman, Daniel I | Gaudet, Mia M | Diver, W Ryan | Willett, Walter C | Hunter, David J | Simard, Jacques | Benitez, Javier | Dunning, Alison M | Sherman, Mark E | Chenevix-Trench, Georgia | Chanock, Stephen J | Hall, Per | Pharoah, Paul D P | Vachon, Celine | Easton, Douglas F | Haiman, Christopher A | Kraft, Peter
Nature genetics  2013;45(4):392-398e2.
Estrogen receptor (ER)-negative tumors represent 20–30% of all breast cancers, with a higher proportion occurring in younger women and women of African ancestry1. The etiology2 and clinical behavior3 of ER-negative tumors are different from those of tumors expressing ER (ER positive), including differences in genetic predisposition4. To identify susceptibility loci specific to ER-negative disease, we combined in a meta-analysis 3 genome-wide association studies of 4,193 ER-negative breast cancer cases and 35,194 controls with a series of 40 follow-up studies (6,514 cases and 41,455 controls), genotyped using a custom Illumina array, iCOGS, developed by the Collaborative Oncological Gene-environment Study (COGS). SNPs at four loci, 1q32.1 (MDM4, P = 2.1 × 10−12 and LGR6, P = 1.4 × 10−8), 2p24.1 (P = 4.6 × 10−8) and 16q12.2 (FTO, P = 4.0 × 10−8), were associated with ER-negative but not ER-positive breast cancer (P > 0.05). These findings provide further evidence for distinct etiological pathways associated with invasive ER-positive and ER-negative breast cancers.
doi:10.1038/ng.2561
PMCID: PMC3771695  PMID: 23535733
9.  A meta-analysis of genome-wide association studies of breast cancer identifies two novel susceptibility loci at 6q14 and 20q11 
Siddiq, Afshan | Couch, Fergus J. | Chen, Gary K. | Lindström, Sara | Eccles, Diana | Millikan, Robert C. | Michailidou, Kyriaki | Stram, Daniel O. | Beckmann, Lars | Rhie, Suhn Kyong | Ambrosone, Christine B. | Aittomäki, Kristiina | Amiano, Pilar | Apicella, Carmel | Baglietto, Laura | Bandera, Elisa V. | Beckmann, Matthias W. | Berg, Christine D. | Bernstein, Leslie | Blomqvist, Carl | Brauch, Hiltrud | Brinton, Louise | Bui, Quang M. | Buring, Julie E. | Buys, Saundra S. | Campa, Daniele | Carpenter, Jane E. | Chasman, Daniel I. | Chang-Claude, Jenny | Chen, Constance | Clavel-Chapelon, Françoise | Cox, Angela | Cross, Simon S. | Czene, Kamila | Deming, Sandra L. | Diasio, Robert B. | Diver, W. Ryan | Dunning, Alison M. | Durcan, Lorraine | Ekici, Arif B. | Fasching, Peter A. | Feigelson, Heather Spencer | Fejerman, Laura | Figueroa, Jonine D. | Fletcher, Olivia | Flesch-Janys, Dieter | Gaudet, Mia M. | Gerty, Susan M. | Rodriguez-Gil, Jorge L. | Giles, Graham G. | van Gils, Carla H. | Godwin, Andrew K. | Graham, Nikki | Greco, Dario | Hall, Per | Hankinson, Susan E. | Hartmann, Arndt | Hein, Rebecca | Heinz, Judith | Hoover, Robert N. | Hopper, John L. | Hu, Jennifer J. | Huntsman, Scott | Ingles, Sue A. | Irwanto, Astrid | Isaacs, Claudine | Jacobs, Kevin B. | John, Esther M. | Justenhoven, Christina | Kaaks, Rudolf | Kolonel, Laurence N. | Coetzee, Gerhard A. | Lathrop, Mark | Le Marchand, Loic | Lee, Adam M. | Lee, I-Min | Lesnick, Timothy | Lichtner, Peter | Liu, Jianjun | Lund, Eiliv | Makalic, Enes | Martin, Nicholas G. | McLean, Catriona A. | Meijers-Heijboer, Hanne | Meindl, Alfons | Miron, Penelope | Monroe, Kristine R. | Montgomery, Grant W. | Müller-Myhsok, Bertram | Nickels, Stefan | Nyante, Sarah J. | Olswold, Curtis | Overvad, Kim | Palli, Domenico | Park, Daniel J. | Palmer, Julie R. | Pathak, Harsh | Peto, Julian | Pharoah, Paul | Rahman, Nazneen | Rivadeneira, Fernando | Schmidt, Daniel F. | Schmutzler, Rita K. | Slager, Susan | Southey, Melissa C. | Stevens, Kristen N. | Sinn, Hans-Peter | Press, Michael F. | Ross, Eric | Riboli, Elio | Ridker, Paul M. | Schumacher, Fredrick R. | Severi, Gianluca | dos Santos Silva, Isabel | Stone, Jennifer | Sund, Malin | Tapper, William J. | Thun, Michael J. | Travis, Ruth C. | Turnbull, Clare | Uitterlinden, Andre G. | Waisfisz, Quinten | Wang, Xianshu | Wang, Zhaoming | Weaver, JoEllen | Schulz-Wendtland, Rüdiger | Wilkens, Lynne R. | Van Den Berg, David | Zheng, Wei | Ziegler, Regina G. | Ziv, Elad | Nevanlinna, Heli | Easton, Douglas F. | Hunter, David J. | Henderson, Brian E. | Chanock, Stephen J. | Garcia-Closas, Montserrat | Kraft, Peter | Haiman, Christopher A. | Vachon, Celine M.
Human Molecular Genetics  2012;21(24):5373-5384.
Genome-wide association studies (GWAS) of breast cancer defined by hormone receptor status have revealed loci contributing to susceptibility of estrogen receptor (ER)-negative subtypes. To identify additional genetic variants for ER-negative breast cancer, we conducted the largest meta-analysis of ER-negative disease to date, comprising 4754 ER-negative cases and 31 663 controls from three GWAS: NCI Breast and Prostate Cancer Cohort Consortium (BPC3) (2188 ER-negative cases; 25 519 controls of European ancestry), Triple Negative Breast Cancer Consortium (TNBCC) (1562 triple negative cases; 3399 controls of European ancestry) and African American Breast Cancer Consortium (AABC) (1004 ER-negative cases; 2745 controls). We performed in silico replication of 86 SNPs at P ≤ 1 × 10-5 in an additional 11 209 breast cancer cases (946 with ER-negative disease) and 16 057 controls of Japanese, Latino and European ancestry. We identified two novel loci for breast cancer at 20q11 and 6q14. SNP rs2284378 at 20q11 was associated with ER-negative breast cancer (combined two-stage OR = 1.16; P = 1.1 × 10−8) but showed a weaker association with overall breast cancer (OR = 1.08, P = 1.3 × 10–6) based on 17 869 cases and 43 745 controls and no association with ER-positive disease (OR = 1.01, P = 0.67) based on 9965 cases and 22 902 controls. Similarly, rs17530068 at 6q14 was associated with breast cancer (OR = 1.12; P = 1.1 × 10−9), and with both ER-positive (OR = 1.09; P = 1.5 × 10−5) and ER-negative (OR = 1.16, P = 2.5 × 10−7) disease. We also confirmed three known loci associated with ER-negative (19p13) and both ER-negative and ER-positive breast cancer (6q25 and 12p11). Our results highlight the value of large-scale collaborative studies to identify novel breast cancer risk loci.
doi:10.1093/hmg/dds381
PMCID: PMC3510753  PMID: 22976474
10.  Identification of nine new susceptibility loci for testicular cancer, including variants near DAZL and PRDM14 
Nature genetics  2013;45(6):10.1038/ng.2635.
Testicular germ cell tumor (TGCT) is the most common cancer in young men and is notable for its high familial risks1,2. To date, six loci associated with TGCT have been reported3-7. From GWAS analysis of 307,291 SNPs in 986 cases and 4,946 controls, we selected for follow-up 694 SNPs, which we genotyped in a further 1,064 TGCT cases and 10,082 controls from the UK. We identified SNPs at nine new loci showing association with TGCT (P<5×10−8), at 1q22, 1q24.1, 3p24.3, 4q24, 5q31.1, 8q13.3, 16q12.1, 17q22 and 21q22.3, which together account for an additional 4-6% of the familial risk of TGCT. The loci include genes plausibly related to TGCT development. PRDM14, at 8q13.3, is essential for early germ cell specification8 whilst DAZL, at 3p24.3, is required for regulation of germ cell development9. Furthermore, PITX1, at 5q31.1 regulates TERT expression, and is the third TGCT locus implicated in telomerase regulation10.
doi:10.1038/ng.2635
PMCID: PMC3680037  PMID: 23666240
11.  Meta-analysis identifies four new loci associated with testicular germ cell tumor 
Nature genetics  2013;45(6):10.1038/ng.2634.
We conducted a meta-analysis to identify new loci for testicular germ cell tumor (TGCT) susceptibility. In the discovery phase, 931 affected individuals and 1,975 controls from three genome wide association studies (GWAS) were analyzed. Replication was conducted in six independent sample sets totaling 3,211 affected individuals and 7,591 controls. In the combined analysis, TGCT risk was significantly associated with markers at four novel loci: 4q22.2 in HPGDS (per allele odds ratio (OR) 1.19, 95%CI 1.12–1.26, P = 1.11×10−8); 7p22.3 in MAD1L1 (OR 1.21, 95%CI 1.14–1.29, P = 5.59×10−9); 16q22.3 in RFWD3 (OR 1.26, 95%CI 1.18–1.34, P = 5.15×10−12); and 17q22 (rs9905704; OR 1.27, 95%CI 1.18–1.33; P = 4.32×10−13, and rs7221274; OR 1.20, 95%CI 1.12–1.28 P = 4.04×10−9), a locus which includes TEX14, RAD51C and PPM1E. The new TGCT susceptibility loci contain biologically plausible genes encoding proteins important for male germ cell development, chromosomal segregation and DNA damage response.
doi:10.1038/ng.2634
PMCID: PMC3723930  PMID: 23666239
12.  Bayesian refinement of association signals for 14 loci in 3 common diseases 
Nature genetics  2012;44(12):1294-1301.
To further investigate susceptibility loci identified by genome-wide association studies, we genotyped 5,500 SNPs across 14 associated regions in 8,000 samples from a control group and 3 diseases: type 2 diabetes (T2D), coronary artery disease (CAD) and Graves’ disease. We defined, using Bayes theorem, credible sets of SNPs that were 95% likely, based on posterior probability, to contain the causal disease-associated SNPs. In 3 of the 14 regions, TCF7L2 (T2D), CTLA4 (Graves’ disease) and CDKN2A-CDKN2B (T2D), much of the posterior probability rested on a single SNP, and, in 4 other regions (CDKN2A-CDKN2B (CAD) and CDKAL1, FTO and HHEX (T2D)), the 95% sets were small, thereby excluding most SNPs as potentially causal. Very few SNPs in our credible sets had annotated functions, illustrating the limitations in understanding the mechanisms underlying susceptibility to common diseases. Our results also show the value of more detailed mapping to target sequences for functional studies.
doi:10.1038/ng.2435
PMCID: PMC3791416  PMID: 23104008
13.  Predisposition gene identification in common cancers by exome sequencing: insights from familial breast cancer 
The genetic component of breast cancer predisposition remains largely unexplained. Candidate-gene case-control resequencing has identified predisposition genes characterised by rare, protein truncating mutations that confer moderate risks of disease. In theory, exome sequencing should yield additional genes of this class. Here, we explore the feasibility and design considerations of this approach.
We performed exome sequencing in 50 individuals with familial breast cancer, applying frequency and protein function filters to identify variants most likely to be pathogenic. We identified 867,378 variants that passed the call quality filters of which 1,296 variants passed the frequency and protein truncation filters. The median number of validated, rare, protein truncating variants (PTVs) was 10 in individuals with, and without, mutations in known genes. The functional candidacy of mutated genes was similar in both groups. Without prior knowledge, the known genes would not have been recognisable as breast cancer predisposition genes. Everyone carries multiple rare mutations that are plausibly related to disease. Exome sequencing in common conditions will therefore require intelligent sample and variant prioritisation strategies in large case-control studies to deliver robust genetic evidence of disease association.
doi:10.1007/s10549-012-2057-x
PMCID: PMC3781770  PMID: 22527104
breast cancer predisposition; exome sequencing; common disease genetics; missing heritability
14.  Variants near DMRT1, TERT and ATF7IP are associated with testicular germ cell cancer 
Nature genetics  2010;42(7):604-607.
We conducted a genome-wide association study for testicular germ cell tumor genotyping 298,782 SNPs in 979 cases and 4,947 controls from the UK and replicating associations in a further 664 cases and 3,456 controls. We identified three novel susceptibility loci, two of which include genes that are involved in telomere regulation. We identified two independent signals within the TERT-CLPTM1L locus on chromosome 5 which has been associated with multiple other cancers (rs4635969, OR=1.54 (95%CI 1.33-1.79), P=1.14×10−23 and rs2736100, OR 1.33 (1.18-1.50) P=7.55 ×10−15). We also identified a locus on chromosome 12 (rs2900333, OR=1.27 (95%CI 1.12-1.44), P=6.16×10−10) that contains ATF7IP, a regulator of TERT expression. Finally we identified a locus on chromosome 9 (rs755383, OR=1.37 (95%CI 1.21-1.55), P=1.12×10−23) containing the sex determination gene DMRT1, which has been linked with teratoma susceptibility in mice.
doi:10.1038/ng.607
PMCID: PMC3773909  PMID: 20543847
15.  Mosaic PPM1D mutations are associated with predisposition to breast and ovarian cancer 
Nature  2012;493(7432):406-410.
Improved sequencing technologies offer unprecedented opportunities for investigating the role of rare genetic variation in common disease. However, there are considerable challenges with respect to study design, data analysis and replication1. Here, using pooled next-generation sequencing of 507 genes implicated in the repair of DNA in 1,150 samples, an analytical strategy focussed on protein truncating variants (PTVs) and a large-scale sequencing case-control replication experiment in 13,642 individuals, we show that rare PTVs in the p53 inducible protein phosphatase PPM1D are associated with predisposition to breast cancer and to ovarian cancer. PPM1D PTV mutations were present in 25/7781 cases vs 1/5861 controls; P=1.12×10−5, which included 18 mutations in 6,912 individuals with breast cancer; P = 2.42×10−4 and 12 mutations in 1,121 individuals with ovarian cancer; P = 3.10×10−9. Notably, all the identified PPM1D PTVs were mosaic in lymphocyte DNA and clustered within a 370 bp region in the final exon of the gene, C-terminal to the phosphatase catalytic domain. Functional studies demonstrated that the mutations result in enhanced suppression of p53 in response to ionising radiation exposure, suggesting the mutant alleles encode hyperactive PPM1D isoforms. Thus, although the mutations cause premature protein truncation, they do not result in the simple loss-of-function typically associated with this class of variant, but instead likely have a gain-of-function effect. Our results have implications for the detection and management of breast and ovarian cancer risk. More generally, these data provide new insights into the role of rare and of mosaic genetic variants in common conditions, and the utility of sequencing in their identification.
doi:10.1038/nature11725
PMCID: PMC3759028  PMID: 23242139
16.  Genome-wide association analysis identifies three new breast cancer susceptibility loci 
Ghoussaini, Maya | Fletcher, Olivia | Michailidou, Kyriaki | Turnbull, Clare | Schmidt, Marjanka K | Dicks, Ed | Dennis, Joe | Wang, Qin | Humphreys, Manjeet K | Luccarini, Craig | Baynes, Caroline | Conroy, Don | Maranian, Melanie | Ahmed, Shahana | Driver, Kristy | Johnson, Nichola | Orr, Nicholas | Silva, Isabel dos Santos | Waisfisz, Quinten | Meijers-Heijboer, Hanne | Uitterlinden, Andre G. | Rivadeneira, Fernando | Hall, Per | Czene, Kamila | Irwanto, Astrid | Liu, Jianjun | Nevanlinna, Heli | Aittomäki, Kristiina | Blomqvist, Carl | Meindl, Alfons | Schmutzler, Rita K | Müller-Myhsok, Bertram | Lichtner, Peter | Chang-Claude, Jenny | Hein, Rebecca | Nickels, Stefan | Flesch-Janys, Dieter | Tsimiklis, Helen | Makalic, Enes | Schmidt, Daniel | Bui, Minh | Hopper, John L | Apicella, Carmel | Park, Daniel J | Southey, Melissa | Hunter, David J | Chanock, Stephen J | Broeks, Annegien | Verhoef, Senno | Hogervorst, Frans BL | Fasching, Peter A. | Lux, Michael P. | Beckmann, Matthias W. | Ekici, Arif B. | Sawyer, Elinor | Tomlinson, Ian | Kerin, Michael | Marme, Frederik | Schneeweiss, Andreas | Sohn, Christof | Burwinkel, Barbara | Guénel, Pascal | Truong, Thérèse | Cordina-Duverger, Emilie | Menegaux, Florence | Bojesen, Stig E | Nordestgaard, Børge G | Nielsen, Sune F | Flyger, Henrik | Milne, Roger L. | Alonso, M. Rosario | González-Neira, Anna | Benítez, Javier | Anton-Culver, Hoda | Ziogas, Argyrios | Bernstein, Leslie | Dur, Christina Clarke | Brenner, Hermann | Müller, Heiko | Arndt, Volker | Stegmaier, Christa | Justenhoven, Christina | Brauch, Hiltrud | Brüning, Thomas | Wang-Gohrke, Shan | Eilber, Ursula | Dörk, Thilo | Schürmann, Peter | Bremer, Michael | Hillemanns, Peter | Bogdanova, Natalia V. | Antonenkova, Natalia N. | Rogov, Yuri I. | Karstens, Johann H. | Bermisheva, Marina | Prokofieva, Darya | Khusnutdinova, Elza | Lindblom, Annika | Margolin, Sara | Mannermaa, Arto | Kataja, Vesa | Kosma, Veli-Matti | Hartikainen, Jaana M | Lambrechts, Diether | Yesilyurt, Betul T. | Floris, Giuseppe | Leunen, Karin | Manoukian, Siranoush | Bonanni, Bernardo | Fortuzzi, Stefano | Peterlongo, Paolo | Couch, Fergus J | Wang, Xianshu | Stevens, Kristen | Lee, Adam | Giles, Graham G. | Baglietto, Laura | Severi, Gianluca | McLean, Catriona | Alnæs, Grethe Grenaker | Kristensen, Vessela | Børrensen-Dale, Anne-Lise | John, Esther M. | Miron, Alexander | Winqvist, Robert | Pylkäs, Katri | Jukkola-Vuorinen, Arja | Kauppila, Saila | Andrulis, Irene L. | Glendon, Gord | Mulligan, Anna Marie | Devilee, Peter | van Asperen, Christie J. | Tollenaar, Rob A.E.M. | Seynaeve, Caroline | Figueroa, Jonine D | Garcia-Closas, Montserrat | Brinton, Louise | Lissowska, Jolanta | Hooning, Maartje J. | Hollestelle, Antoinette | Oldenburg, Rogier A. | van den Ouweland, Ans M.W. | Cox, Angela | Reed, Malcolm WR | Shah, Mitul | Jakubowska, Ania | Lubinski, Jan | Jaworska, Katarzyna | Durda, Katarzyna | Jones, Michael | Schoemaker, Minouk | Ashworth, Alan | Swerdlow, Anthony | Beesley, Jonathan | Chen, Xiaoqing | Muir, Kenneth R | Lophatananon, Artitaya | Rattanamongkongul, Suthee | Chaiwerawattana, Arkom | Kang, Daehee | Yoo, Keun-Young | Noh, Dong-Young | Shen, Chen-Yang | Yu, Jyh-Cherng | Wu, Pei-Ei | Hsiung, Chia-Ni | Perkins, Annie | Swann, Ruth | Velentzis, Louiza | Eccles, Diana M | Tapper, Will J | Gerty, Susan M | Graham, Nikki J | Ponder, Bruce A. J. | Chenevix-Trench, Georgia | Pharoah, Paul D.P. | Lathrop, Mark | Dunning, Alison M. | Rahman, Nazneen | Peto, Julian | Easton, Douglas F
Nature genetics  2012;44(3):312-318.
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 followed up 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 nine breast cancer GWAS. We identified three new breast cancer risk loci on 12p11 (rs10771399; P=2.7 × 10−35), 12q24 (rs1292011; P=4.3×10−19) and 21q21 (rs2823093; P=1.1×10−12). SNP 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) plays a crucial role in mammary gland development and the establishment of bone metastasis in breast cancer, while NRIP1 (21q21) encodes an ER co-factor and has a role in the regulation of breast cancer cell growth.
doi:10.1038/ng.1049
PMCID: PMC3653403  PMID: 22267197
17.  Mutation and association analysis of GEN1 in breast cancer susceptibility 
GEN1 was recently identified as a key Holliday junction resolvase involved in homologous recombination. Somatic truncating GEN1 mutations have been reported in two breast cancers. Together these data led to the proposition that GEN1 is a breast cancer predisposition gene. In this article we have formally investigated this hypothesis. We performed full-gene mutational analysis of GEN1 in 176 BRCA1/2-negative familial breast cancer samples and 159 controls. We genotyped six SNPs tagging the 30 common variants in the transcribed region of GEN1 in 3,750 breast cancer cases and 4,907 controls. Mutation analysis revealed one truncating variant, c.2515_2519del-AAGTT, which was present in 4% of cases and 4% of controls. We identified control individuals homozygous for the deletion, demonstrating that the last 69 amino acids of GEN1 are dispensable for its function. We identified 17 other variants, but their frequency did not significantly differ between cases and controls. Analysis of 3,750 breast cancer cases and 4,907 controls demonstrated no evidence of significant association with breast cancer for six SNPs tagging the 30 common GEN1 variants. These data indicate that although it also plays a key role in double-strand DNA break repair, GEN1 does not make an appreciable contribution to breast cancer susceptibility by acting as a high- or intermediate-penetrance breast cancer predisposition gene like BRCA1, BRCA2, CHEK2, ATM, BRIP1 and PALB2 and that common GEN1 variants do not act as low-penetrance susceptibility alleles analogous to SNPs in FGFR2. Furthermore, our analyses demonstrate the importance of undertaking appropriate genetic investigations, typically full gene screening in cases and controls together with large-scale case–control association analyses, to evaluate the contribution of genes to cancer susceptibility.
doi:10.1007/s10549-010-0949-1
PMCID: PMC3632835  PMID: 20512659
Breast cancer; Genetic susceptibility; DNA repair; Cancer genes
18.  Genome-wide association study identifies five new breast cancer susceptibility loci 
Nature genetics  2010;42(6):504-507.
Breast cancer is the most common cancer in women in developed countries. To identify common breast cancer susceptibility alleles, we conducted a genome-wide association study in which 582,886 SNPs were genotyped in 3,659 cases with a family history of the disease and 4,897 controls. Promising associations were evaluated in a second stage, comprising 12,576 cases and 12,223 controls. We identified five new susceptibility loci, on chromosomes 9, 10 and 11 (P = 4.6 × 10−7 to P = 3.2 × 10−15). We also identified SNPs in the 6q25.1 (rs3757318, P = 2.9 × 10−6), 8q24 (rs1562430, P = 5.8 × 10−7) and LSP1 (rs909116, P = 7.3 × 10−7) regions that showed more significant association with risk than those reported previously. Previously identified breast cancer susceptibility loci were also found to show larger effect sizes in this study of familial breast cancer cases than in previous population-based studies, consistent with polygenic susceptibility to the disease.
doi:10.1038/ng.586
PMCID: PMC3632836  PMID: 20453838
19.  Gene–gene interactions in breast cancer susceptibility 
Human Molecular Genetics  2011;21(4):958-962.
There have been few definitive examples of gene–gene interactions in humans. Through mutational analyses in 7325 individuals, we report four interactions (defined as departures from a multiplicative model) between mutations in the breast cancer susceptibility genes ATM and CHEK2 with BRCA1 and BRCA2 (case-only interaction between ATM and BRCA1/BRCA2 combined, P = 5.9 × 10–4; ATM and BRCA1, P= 0.01; ATM and BRCA2, P= 0.02; CHEK2 and BRCA1/BRCA2 combined, P = 2.1 × 10−4; CHEK2 and BRCA1, P= 0.01; CHEK2 and BRCA2, P= 0.01). The interactions are such that the resultant risk of breast cancer is lower than the multiplicative product of the constituent risks, and plausibly reflect the functional relationships of the encoded proteins in DNA repair. These findings have important implications for models of disease predisposition and clinical translation.
doi:10.1093/hmg/ddr525
PMCID: PMC4125627  PMID: 22072393
20.  A genome-wide association study identifies susceptibility loci for Wilms tumor 
Nature genetics  2012;44(6):681-684.
Wilms tumor is the most common renal malignancy of childhood. To identify common variants that confer susceptibility to Wilms tumor we conducted a genome-wide association study in 757 cases and 1,879 controls. We evaluated ten SNPs in regions significant at P<5×10−5 in two independent replication series from the UK (769 cases and 2,814 controls) and the US (719 cases and 1,037 controls). We identified clear significant associations at two loci, 2p24 (rs3755132, P=1.03×10−14 and rs807624, P=1.32×10−14) and 11q14 (rs790356, P=4.25 ×10−15). Both regions contain genes that are plausibly related to Wilms tumorigenesis. We also identified candidate signals at 5q14, 22q12 and Xp22.
doi:10.1038/ng.2251
PMCID: PMC3400150  PMID: 22544364
21.  Associations of common variants at 1p11.2 and 14q24.1 (RAD51L1) with breast cancer risk and heterogeneity by tumor subtype: findings from the Breast Cancer Association Consortium† 
Figueroa, Jonine D. | Garcia-Closas, Montserrat | Humphreys, Manjeet | Platte, Radka | Hopper, John L. | Southey, Melissa C. | Apicella, Carmel | Hammet, Fleur | Schmidt, Marjanka K. | Broeks, Annegien | Tollenaar, Rob A.E.M. | Van't Veer, Laura J. | Fasching, Peter A. | Beckmann, Matthias W. | Ekici, Arif B. | Strick, Reiner | Peto, Julian | dos Santos Silva, Isabel | Fletcher, Olivia | Johnson, Nichola | Sawyer, Elinor | Tomlinson, Ian | Kerin, Michael | Burwinkel, Barbara | Marme, Federik | Schneeweiss, Andreas | Sohn, Christof | Bojesen, Stig | Flyger, Henrik | Nordestgaard, Børge G. | Benítez, Javier | Milne, Roger L. | Ignacio Arias, Jose | Zamora, M. Pilar | Brenner, Hermann | Müller, Heiko | Arndt, Volker | Rahman, Nazneen | Turnbull, Clare | Seal, Sheila | Renwick, Anthony | Brauch, Hiltrud | Justenhoven, Christina | Brüning, Thomas | Chang-Claude, Jenny | Hein, Rebecca | Wang-Gohrke, Shan | Dörk, Thilo | Schürmann, Peter | Bremer, Michael | Hillemanns, Peter | Nevanlinna, Heli | Heikkinen, Tuomas | Aittomäki, Kristiina | Blomqvist, Carl | Bogdanova, Natalia | Antonenkova, Natalia | Rogov, Yuri I. | Karstens, Johann Hinrich | Bermisheva, Marina | Prokofieva, Darya | Hanafievich Gantcev, Shamil | Khusnutdinova, Elza | Lindblom, Annika | Margolin, Sara | Chenevix-Trench, Georgia | Beesley, Jonathan | Chen, Xiaoqing | Mannermaa, Arto | Kosma, Veli-Matti | Soini, Ylermi | Kataja, Vesa | Lambrechts, Diether | Yesilyurt, Betül T. | Chrisiaens, Marie-Rose | Peeters, Stephanie | Radice, Paolo | Peterlongo, Paolo | Manoukian, Siranoush | Barile, Monica | Couch, Fergus | Lee, Adam M. | Diasio, Robert | Wang, Xianshu | Giles, Graham G. | Severi, Gianluca | Baglietto, Laura | Maclean, Catriona | Offit, Ken | Robson, Mark | Joseph, Vijai | Gaudet, Mia | John, Esther M. | Winqvist, Robert | Pylkäs, Katri | Jukkola-Vuorinen, Arja | Grip, Mervi | Andrulis, Irene | Knight, Julia A. | Marie Mulligan, Anna | O'Malley, Frances P. | Brinton, Louise A. | Sherman, Mark E. | Lissowska, Jolanta | Chanock, Stephen J. | Hooning, Maartje | Martens, John W.M. | van den Ouweland, Ans M.W. | Collée, J. Margriet | Hall, Per | Czene, Kamila | Cox, Angela | Brock, Ian W. | Reed, Malcolm W.R. | Cross, Simon S. | Pharoah, Paul | Dunning, Alison M. | Kang, Daehee | Yoo, Keun-Young | Noh, Dong-Young | Ahn, Sei-Hyun | Jakubowska, Anna | Lubinski, Jan | Jaworska, Katarzyna | Durda, Katarzyna | Sangrajrang, Suleeporn | Gaborieau, Valerie | Brennan, Paul | McKay, James | Shen, Chen-Yang | Ding, Shian-ling | Hsu, Huan-Ming | Yu, Jyh-Cherng | Anton-Culver, Hoda | Ziogas, Argyrios | Ashworth, Alan | Swerdlow, Anthony | Jones, Michael | Orr, Nick | Trentham-Dietz, Amy | Egan, Kathleen | Newcomb, Polly | Titus-Ernstoff, Linda | Easton, Doug | Spurdle, Amanda B.
Human Molecular Genetics  2011;20(23):4693-4706.
A genome-wide association study (GWAS) identified single-nucleotide polymorphisms (SNPs) at 1p11.2 and 14q24.1 (RAD51L1) as breast cancer susceptibility loci. The initial GWAS suggested stronger effects for both loci for estrogen receptor (ER)-positive tumors. Using data from the Breast Cancer Association Consortium (BCAC), we sought to determine whether risks differ by ER, progesterone receptor (PR), human epidermal growth factor receptor 2 (HER2), grade, node status, tumor size, and ductal or lobular morphology. We genotyped rs11249433 at 1p.11.2, and two highly correlated SNPs rs999737 and rs10483813 (r2= 0.98) at 14q24.1 (RAD51L1), for up to 46 036 invasive breast cancer cases and 46 930 controls from 39 studies. Analyses by tumor characteristics focused on subjects reporting to be white women of European ancestry and were based on 25 458 cases, of which 87% had ER data. The SNP at 1p11.2 showed significantly stronger associations with ER-positive tumors [per-allele odds ratio (OR) for ER-positive tumors was 1.13, 95% CI = 1.10–1.16 and, for ER-negative tumors, OR was 1.03, 95% CI = 0.98–1.07, case-only P-heterogeneity = 7.6 × 10−5]. The association with ER-positive tumors was stronger for tumors of lower grade (case-only P= 6.7 × 10−3) and lobular histology (case-only P= 0.01). SNPs at 14q24.1 were associated with risk for most tumor subtypes evaluated, including triple-negative breast cancers, which has not been described previously. Our results underscore the need for large pooling efforts with tumor pathology data to help refine risk estimates for SNP associations with susceptibility to different subtypes of breast cancer.
doi:10.1093/hmg/ddr368
PMCID: PMC3209823  PMID: 21852249
22.  Mutations in CEP57 cause mosaic variegated aneuploidy syndrome 
Nature genetics  2011;43(6):527-529.
Using exome sequencing and a variant prioritisation strategy that focuses on loss-of-function variants, we identified biallelic, loss-of-function CEP57 mutations as a cause of constitutional mosaic aneuploidies. CEP57 is a centrosomal protein and is involved in nucleating and stabilizing microtubules. Our data indicate that these and/or additional functions of CEP57 are crucial in maintaining correct chromosomal number during cell division.
doi:10.1038/ng.822
PMCID: PMC3508359  PMID: 21552266
23.  Correction: Comparison of 6q25 Breast Cancer Hits from Asian and European Genome Wide Association Studies in the Breast Cancer Association Consortium (BCAC) 
Hein, Rebecca | Maranian, Melanie | Hopper, John L. | Kapuscinski, Miroslaw K. | Southey, Melissa C. | Park, Daniel J. | Schmidt, Marjanka K. | Broeks, Annegien | Hogervorst, Frans B. L. | Bueno-de-Mesquit, H. Bas | Muir, Kenneth R. | Lophatananon, Artitaya | Rattanamongkongul, Suthee | Puttawibul, Puttisak | Fasching, Peter A. | Hein, Alexander | Ekici, Arif B. | Beckmann, Matthias W. | Fletcher, Olivia | Johnson, Nichola | dos Santos Silva, Isabel | Peto, Julian | Sawyer, Elinor | Tomlinson, Ian | Kerin, Michael | Miller, Nicola | Marmee, Frederick | Schneeweiss, Andreas | Sohn, Christof | Burwinkel, Barbara | Guénel, Pascal | Cordina-Duverger, Emilie | Menegaux, Florence | Truong, Thérèse | Bojesen, Stig E. | Nordestgaard, Børge G. | Flyger, Henrik | Milne, Roger L. | Perez, Jose Ignacio Arias | Zamora, M. Pilar | Benítez, Javier | Anton-Culver, Hoda | Ziogas, Argyrios | Bernstein, Leslie | Clarke, Christina A. | Brenner, Hermann | Müller, Heiko | Arndt, Volker | Stegmaier, Christa | Rahman, Nazneen | Seal, Sheila | Turnbull, Clare | Renwick, Anthony | Meindl, Alfons | Schott, Sarah | Bartram, Claus R. | Schmutzler, Rita K. | Brauch, Hiltrud | Hamann, Ute | Ko, Yon-Dschun | Wang-Gohrke, Shan | Dörk, Thilo | Schürmann, Peter | Karstens, Johann H. | Hillemanns, Peter | Nevanlinna, Heli | Heikkinen, Tuomas | Aittomäki, Kristiina | Blomqvist, Carl | Bogdanova, Natalia V. | Zalutsky, Iosif V. | Antonenkova, Natalia N. | Bermisheva, Marina | Prokovieva, Darya | Farahtdinova, Albina | Khusnutdinova, Elza | Lindblom, Annika | Margolin, Sara | Mannermaa, Arto | Kataja, Vesa | Kosma, Veli-Matti | Hartikainen, Jaana | Chen, Xiaoqing | Beesley, Jonathan | Investigators, kConFab | Lambrechts, Diether | Zhao, Hui | Neven, Patrick | Wildiers, Hans | Nickels, Stefan | Flesch-Janys, Dieter | Radice, Paolo | Peterlongo, Paolo | Manoukian, Siranoush | Barile, Monica | Couch, Fergus J. | Olson, Janet E. | Wang, Xianshu | Fredericksen, Zachary | Giles, Graham G. | Baglietto, Laura | McLean, Catriona A. | Severi, Gianluca | Offit, Kenneth | Robson, Mark | Gaudet, Mia M. | Vijai, Joseph | Alnæs, Grethe Grenaker | Kristensen, Vessela | Børresen-Dale, Anne-Lise | John, Esther M. | Miron, Alexander | Winqvist, Robert | Pylkäs, Katri | Jukkola-Vuorinen, Arja | Grip, Mervi | Andrulis, Irene L. | Knight, Julia A. | Glendon, Gord | Mulligan, Anna Marie | Figueroa, Jonine D. | García-Closas, Montserrat | Lissowska, Jolanta | Sherman, Mark E. | Hooning, Maartje | Martens, John W. M. | Seynaeve, Caroline | Collée, Margriet | Hall, Per | Humpreys, Keith | Czene, Kamila | Liu, Jianjun | Cox, Angela | Brock, Ian W. | Cross, Simon S. | Reed, Malcolm W. R. | Ahmed, Shahana | Ghoussaini, Maya | Pharoah, Paul DP. | Kang, Daehee | Yoo, Keun-Young | Noh, Dong-Young | Jakubowska, Anna | Jaworska, Katarzyna | Durda, Katarzyna | Złowocka, Elżbieta | Sangrajrang, Suleeporn | Gaborieau, Valerie | Brennan, Paul | McKay, James | Shen, Chen-Yang | Yu, Jyh-Cherng | Hsu, Huan-Ming | Hou, Ming-Feng | Orr, Nick | Schoemaker, Minouk | Ashworth, Alan | Swerdlow, Anthony | Trentham-Dietz, Amy | Newcomb, Polly A. | Titus, Linda | Egan, Kathleen M. | Chenevix-Trench, Georgia | Antoniou, Antonis C. | Humphreys, Manjeet K. | Morrison, Jonathan | Chang-Claude, Jenny | Easton, Douglas F. | Dunning, Alison M.
PLoS ONE  2012;7(10):10.1371/annotation/e5de602c-0ffc-4e6f-a2ed-f79913c2e57c.
doi:10.1371/annotation/e5de602c-0ffc-4e6f-a2ed-f79913c2e57c
PMCID: PMC3525690
24.  Mammographic breast density and breast cancer: evidence of a shared genetic basis 
Cancer research  2012;72(6):1478-1484.
Percent mammographic breast density (PMD) is a strong heritable risk factor for breast cancer. However, the pathways through which this risk is mediated are still unclear. To explore whether PMD and breast cancer have a shared genetic basis, we identified genetic variants most strongly associated with PMD in a published meta-analysis of five genome-wide association studies (GWAS) and used these to construct risk scores for 3628 breast cancer cases and 5190 controls from the UK2 GWAS of breast cancer. The signed per-allele effect estimates of SNPs were multiplied with the respective allele counts in the individual and summed over all SNPs to derive the risk score for an individual. These scores were included as the exposure variable in a logistic regression model with breast cancer case-control status as the outcome. This analysis was repeated using ten different cut-offs for the most significant density SNPs (1-10% representing 5,222-50,899 SNPs). Permutation analysis was also performed across all 10 cut-offs. The association between risk score and breast cancer was significant for all cut-offs from 3-10% of top density SNPs, being most significant for the 6% (2-sided P=0.002) to 10% (P=0.001) cut-offs (overall permutation P=0.003). Women in the top 10% of the risk score distribution had a 31% increased risk of breast cancer [OR= 1.31 (95%CI 1.08-1.59)] compared to women in the bottom 10%. Together, our results demonstrate that PMD and breast cancer have a shared genetic basis that is mediated through a large number of common variants.
doi:10.1158/0008-5472.CAN-11-3295
PMCID: PMC3378688  PMID: 22266113
breast cancer; mammographic density; SNPs; polygenic; Mendelian Randomisation
25.  Comparison of 6q25 Breast Cancer Hits from Asian and European Genome Wide Association Studies in the Breast Cancer Association Consortium (BCAC) 
Hein, Rebecca | Maranian, Melanie | Hopper, John L. | Kapuscinski, Miroslaw K. | Southey, Melissa C. | Park, Daniel J. | Schmidt, Marjanka K. | Broeks, Annegien | Hogervorst, Frans B. L. | Bueno-de-Mesquit, H. Bas | Muir, Kenneth R. | Lophatananon, Artitaya | Rattanamongkongul, Suthee | Puttawibul, Puttisak | Fasching, Peter A. | Hein, Alexander | Ekici, Arif B. | Beckmann, Matthias W. | Fletcher, Olivia | Johnson, Nichola | dos Santos Silva, Isabel | Peto, Julian | Sawyer, Elinor | Tomlinson, Ian | Kerin, Michael | Miller, Nicola | Marmee, Frederick | Schneeweiss, Andreas | Sohn, Christof | Burwinkel, Barbara | Guénel, Pascal | Cordina-Duverger, Emilie | Menegaux, Florence | Truong, Thérèse | Bojesen, Stig E. | Nordestgaard, Børge G. | Flyger, Henrik | Milne, Roger L. | Perez, Jose Ignacio Arias | Zamora, M. Pilar | Benítez, Javier | Anton-Culver, Hoda | Ziogas, Argyrios | Bernstein, Leslie | Clarke, Christina A. | Brenner, Hermann | Müller, Heiko | Arndt, Volker | Stegmaier, Christa | Rahman, Nazneen | Seal, Sheila | Turnbull, Clare | Renwick, Anthony | Meindl, Alfons | Schott, Sarah | Bartram, Claus R. | Schmutzler, Rita K. | Brauch, Hiltrud | Hamann, Ute | Ko, Yon-Dschun | Wang-Gohrke, Shan | Dörk, Thilo | Schürmann, Peter | Karstens, Johann H. | Hillemanns, Peter | Nevanlinna, Heli | Heikkinen, Tuomas | Aittomäki, Kristiina | Blomqvist, Carl | Bogdanova, Natalia V. | Zalutsky, Iosif V. | Antonenkova, Natalia N. | Bermisheva, Marina | Prokovieva, Darya | Farahtdinova, Albina | Khusnutdinova, Elza | Lindblom, Annika | Margolin, Sara | Mannermaa, Arto | Kataja, Vesa | Kosma, Veli-Matti | Hartikainen, Jaana | Chen, Xiaoqing | Beesley, Jonathan | Investigators, kConFab | Lambrechts, Diether | Zhao, Hui | Neven, Patrick | Wildiers, Hans | Nickels, Stefan | Flesch-Janys, Dieter | Radice, Paolo | Peterlongo, Paolo | Manoukian, Siranoush | Barile, Monica | Couch, Fergus J. | Olson, Janet E. | Wang, Xianshu | Fredericksen, Zachary | Giles, Graham G. | Baglietto, Laura | McLean, Catriona A. | Severi, Gianluca | Offit, Kenneth | Robson, Mark | Gaudet, Mia M. | Vijai, Joseph | Alnæs, Grethe Grenaker | Kristensen, Vessela | Børresen-Dale, Anne-Lise | John, Esther M. | Miron, Alexander | Winqvist, Robert | Pylkäs, Katri | Jukkola-Vuorinen, Arja | Grip, Mervi | Andrulis, Irene L. | Knight, Julia A. | Glendon, Gord | Mulligan, Anna Marie | Figueroa, Jonine D. | García-Closas, Montserrat | Lissowska, Jolanta | Sherman, Mark E. | Hooning, Maartje | Martens, John W. M. | Seynaeve, Caroline | Collée, Margriet | Hall, Per | Humpreys, Keith | Czene, Kamila | Liu, Jianjun | Cox, Angela | Brock, Ian W. | Cross, Simon S. | Reed, Malcolm W. R. | Ahmed, Shahana | Ghoussaini, Maya | Pharoah, Paul DP. | Kang, Daehee | Yoo, Keun-Young | Noh, Dong-Young | Jakubowska, Anna | Jaworska, Katarzyna | Durda, Katarzyna | Złowocka, Elżbieta | Sangrajrang, Suleeporn | Gaborieau, Valerie | Brennan, Paul | McKay, James | Shen, Chen-Yang | Yu, Jyh-Cherng | Hsu, Huan-Ming | Hou, Ming-Feng | Orr, Nick | Schoemaker, Minouk | Ashworth, Alan | Swerdlow, Anthony | Trentham-Dietz, Amy | Newcomb, Polly A. | Titus, Linda | Egan, Kathleen M. | Chenevix-Trench, Georgia | Antoniou, Antonis C. | Humphreys, Manjeet K. | Morrison, Jonathan | Chang-Claude, Jenny | Easton, Douglas F. | Dunning, Alison M.
PLoS ONE  2012;7(8):e42380.
The 6q25.1 locus was first identified via a genome-wide association study (GWAS) in Chinese women and marked by single nucleotide polymorphism (SNP) rs2046210, approximately 180 Kb upstream of ESR1. There have been conflicting reports about the association of this locus with breast cancer in Europeans, and a GWAS in Europeans identified a different SNP, tagged here by rs12662670. We examined the associations of both SNPs in up to 61,689 cases and 58,822 controls from forty-four studies collaborating in the Breast Cancer Association Consortium, of which four studies were of Asian and 39 of European descent. Logistic regression was used to estimate odds ratios (OR) and 95% confidence intervals (CI). Case-only analyses were used to compare SNP effects in Estrogen Receptor positive (ER+) versus negative (ER−) tumours. Models including both SNPs were fitted to investigate whether the SNP effects were independent. Both SNPs are significantly associated with breast cancer risk in both ethnic groups. Per-allele ORs are higher in Asian than in European studies [rs2046210: OR (A/G) = 1.36 (95% CI 1.26–1.48), p = 7.6×10−14 in Asians and 1.09 (95% CI 1.07–1.11), p = 6.8×10−18 in Europeans. rs12662670: OR (G/T) = 1.29 (95% CI 1.19–1.41), p = 1.2×10−9 in Asians and 1.12 (95% CI 1.08–1.17), p = 3.8×10−9 in Europeans]. SNP rs2046210 is associated with a significantly greater risk of ER− than ER+ tumours in Europeans [OR (ER−) = 1.20 (95% CI 1.15–1.25), p = 1.8×10−17 versus OR (ER+) = 1.07 (95% CI 1.04–1.1), p = 1.3×10−7, pheterogeneity = 5.1×10−6]. In these Asian studies, by contrast, there is no clear evidence of a differential association by tumour receptor status. Each SNP is associated with risk after adjustment for the other SNP. These results suggest the presence of two variants at 6q25.1 each independently associated with breast cancer risk in Asians and in Europeans. Of these two, the one tagged by rs2046210 is associated with a greater risk of ER− tumours.
doi:10.1371/journal.pone.0042380
PMCID: PMC3413660  PMID: 22879957

Results 1-25 (45)