Your search keyword '"Odefrey F"' showing total 37 results

1. Expanded genetic analysis of a PALB2 c.3113G>A mutation carrying multiple-case breast cancer family via exome sequencing

Author

Teo ZL, Park DJ, Odefrey F, Hammet F, Nguyen-Dumont T, Tsimiklis H, Pope BJ, Lonie A, Winship I, Giles GG, Hopper JL, and Southey MC

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282, Genetics, QH426-470

Published

2012

2. Identification of new breast cancer predisposition genes via whole exome sequencing

Author

Southey MC, Park DJ, Lesueur F, Odefrey F, Nguyen-Dumont T, Hammet F, Neuhausen SL, John EM, Andrulis IL, Chenevix-Trench G, Baglietto L, Le Calvez-Kelm F, Pertesi M, Lonie A, Pope B, Sinilnikova O, Tsimiklis H, Giles GG, Hopper JL, Tavtigian SV, and Goldgar DE

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282, Genetics, QH426-470

Published

2012

3. Are PALB2 mutations associated with increased risk of male breast cancer?

Author

Sauty de Chalon, A., Teo, Z., Park, D. J., Odefrey, F. A., Hopper, J. L., Southey, M. C., and kConFab

Published

2010

4. Rare Mutations in XRCC2 Increase the Risk of Breast Cancer

Author

Park, D.J., Lesueur, F., Nguyen-Dumont, T., Pertesi, M., Odefrey, F., Hammet, F., Neuhausen, S.L., John, E.M., Andrulis, I.L., Terry, M.B., Daly, M., Buys, S., Calvez-Kelm, F. le, Lonie, A., Pope, B.J., Tsimiklis, H., Voegele, C., Hilbers, F.M., Hoogerbrugge, N., Barroso, A., Osorio, A., Giles, G.G., Devilee, P., Benitez, J., Hopper, J.L., Tavtigian, S.V., Goldgar, D.E., Southey, M.C., Breast Canc Family Registry, and Kathleen Cuningham Fdn Consortium

Subjects

Adult, Male, Risk, Hereditary cancer and cancer-related syndromes Genetics and epigenetic pathways of disease [ONCOL 1], Population, Breast Neoplasms, Biology, medicine.disease_cause, Germline mutation, Breast cancer, Report, Genetics, medicine, Humans, Missense mutation, Exome, Genetic Predisposition to Disease, Genetics(clinical), Homologous Recombination, education, Genetics (clinical), education.field_of_study, Mutation, Massive parallel sequencing, Hereditary cancer and cancer-related syndromes [ONCOL 1], Middle Aged, medicine.disease, Pedigree, DNA-Binding Proteins, Case-Control Studies, RAD51C, Female

Abstract

Item does not contain fulltext An exome-sequencing study of families with multiple breast-cancer-affected individuals identified two families with XRCC2 mutations, one with a protein-truncating mutation and one with a probably deleterious missense mutation. We performed a population-based case-control mutation-screening study that identified six probably pathogenic coding variants in 1,308 cases with early-onset breast cancer and no variants in 1,120 controls (the severity grading was p < 0.02). We also performed additional mutation screening in 689 multiple-case families. We identified ten breast-cancer-affected families with protein-truncating or probably deleterious rare missense variants in XRCC2. Our identification of XRCC2 as a breast cancer susceptibility gene thus increases the proportion of breast cancers that are associated with homologous recombination-DNA-repair dysfunction and Fanconi anemia and could therefore benefit from specific targeted treatments such as PARP (poly ADP ribose polymerase) inhibitors. This study demonstrates the power of massively parallel sequencing for discovering susceptibility genes for common, complex diseases.

Published

2012

5. PALB2, CHEK2 and ATM rare variants and cancer risk:data from COGS

Author

Southey, M. C. (Melissa C.), Goldgar, D. E. (David E.), Winqvist, R. (Robert), Pylkäs, K. (Katri), Couch, F. (Fergus), Tischkowitz, M. (Marc), Foulkes, W. D. (William D.), Dennis, J. (Joe), Michailidou, K. (Kyriaki), van Rensburg, E. J. (Elizabeth J.), Heikkinen, T. (Tuomas), Nevanlinna, H. (Heli), Hopper, J. L. (John L.), Doerk, T. (Thilo), Claes, K. B. (Kathleen B. M.), Reis-Filho, J. (Jorge), Teo, Z. L. (Zhi Ling), Radice, P. (Paolo), Catucci, I. (Irene), Peterlongo, P. (Paolo), Tsimiklis, H. (Helen), Odefrey, F. A. (Fabrice A.), Dowty, J. G. (James G.), Schmidt, M. K. (Marjanka K.), Broeks, A. (Annegien), Hogervorst, F. B. (Frans B.), Verhoef, S. (Senno), Carpenter, J. (Jane), Clarke, C. (Christine), Scott, R. J. (Rodney J.), Fasching, P. A. (Peter A.), Haeberle, L. (Lothar), Ekici, A. B. (Arif B.), Beckmann, M. W. (Matthias W.), Peto, J. (Julian), dos-Santos-Silva, I. (Isabel), Fletcher, O. (Olivia), Johnson, N. (Nichola), Bolla, M. K. (Manjeet K.), Sawyer, E. J. (Elinor J.), Tomlinson, I. (Ian), Kerin, M. J. (Michael J.), Miller, N. (Nicola), Marme, F. (Federik), Burwinkel, B. (Barbara), Yang, R. (Rongxi), Guenel, P. (Pascal), Menegaux, F. (Florence), Sanchez, M. (Marie), Bojesen, S. (Stig), Nielsen, S. F. (Sune F.), Flyger, H. (Henrik), Benitez, J. (Javier), Pilar Zamora, M. (M.), Arias Perez, J. I. (Jose Ignacio), Menendez, P. (Primitiva), Anton-Culver, H. (Hoda), Neuhausen, S. (Susan), Ziogas, A. (Argyrios), Clarke, C. A. (Christina A.), Brenner, H. (Hermann), Arndt, V. (Volker), Stegmaier, C. (Christa), Brauch, H. (Hiltrud), Bruening, T. (Thomas), Ko, Y.-D. (Yon-Dschun), Muranen, T. A. (Taru A.), Aittomaki, K. (Kristiina), Blomqvist, C. (Carl), Bogdanova, N. V. (Natalia V.), Antonenkova, N. N. (Natalia N.), Lindblom, A. (Annika), Margolin, S. (Sara), Mannermaa, A. (Arto), Kataja, V. (Vesa), Kosma, V.-M. (Veli-Matti), Hartikainen, J. M. (Jaana M.), Spurdle, A. B. (Amanda B.), Wauters, E. (Els), Smeets, D. (Dominiek), Beuselinck, B. (Benoit), Floris, G. (Giuseppe), Chang-Claude, J. (Jenny), Rudolph, A. (Anja), Seibold, P. (Petra), Flesch-Janys, D. (Dieter), Olson, J. E. (Janet E.), Vachon, C. (Celine), Pankratz, V. S. (Vernon S.), McLean, C. (Catriona), Haiman, C. A. (Christopher A.), Henderson, B. E. (Brian E.), Schumacher, F. (Fredrick), Le Marchand, L. (Loic), Kristensen, V. (Vessela), Alnaes, G. G. (Grethe Grenaker), Zheng, W. (Wei), Hunter, D. J. (David J.), Lindstrom, S. (Sara), Hankinson, S. E. (Susan E.), Kraft, P. (Peter), Andrulis, I. (Irene), Knight, J. A. (Julia A.), Glendon, G. (Gord), Mulligan, A. M. (Anna Marie), Jukkola-Vuorinen, A. (Arja), Grip, M. (Mervi), Kauppila, S. (Saila), Devilee, P. (Peter), Tollenaar, R. A. (Robert A. E. M.), Seynaeve, C. (Caroline), Hollestelle, A. (Antoinette), Garcia-Closas, M. (Montserrat), Figueroa, J. (Jonine), Chanock, S. J. (Stephen J.), Lissowska, J. (Jolanta), Czene, K. (Kamila), Darabi, H. (Hatef), Eriksson, M. (Mikael), Eccles, D. M. (Diana M.), Rafiq, S. (Sajjad), Tapper, W. J. (William J.), Gerty, S. M. (Sue M.), Hooning, M. J. (Maartje J.), Martens, J. W. (John W. M.), Collee, J. M. (J. Margriet), Tilanus-Linthorst, M. (Madeleine), Hall, P. (Per), Li, J. (Jingmei), Brand, J. S. (Judith S.), Humphreys, K. (Keith), Cox, A. (Angela), Reed, M. W. (Malcolm W. R.), Luccarini, C. (Craig), Baynes, C. (Caroline), Dunning, A. M. (Alison M.), Hamann, U. (Ute), Torres, D. (Diana), Ulmer, H. U. (Hans Ulrich), Ruediger, T. (Thomas), Jakubowska, A. (Anna), Lubinski, J. (Jan), Jaworska, K. (Katarzyna), Durda, K. (Katarzyna), Slager, S. (Susan), Toland, A. E. (Amanda E.), Ambrosone, C. B. (Christine B.), Yannoukakos, D. (Drakoulis), Swerdlow, A. (Anthony), Ashworth, A. (Alan), Orr, N. (Nick), Jones, M. (Michael), Gonzalez-Neira, A. (Anna), Pita, G. (Guillermo), Rosario Alonso, M. (M.), Alvarez, N. (Nuria), Herrero, D. (Daniel), Tessier, D. C. (Daniel C.), Vincent, D. (Daniel), Bacot, F. (Francois), Simard, J. (Jacques), Dumont, M. (Martine), Soucy, P. (Penny), Eeles, R. (Rosalind), Muir, K. (Kenneth), Wiklund, F. (Fredrik), Gronberg, H. (Henrik), Schleutker, J. (Johanna), Nordestgaard, B. G. (Borge G.), Weischer, M. (Maren), Travis, R. C. (Ruth C.), Neal, D. (David), Donovan, J. L. (Jenny L.), Hamdy, F. C. (Freddie C.), Khaw, K.-T. (Kay-Tee), Stanford, J. L. (Janet L.), Blot, W. J. (William J.), Thibodeau, S. (Stephen), Schaid, D. J. (Daniel J.), Kelley, J. L. (Joseph L.), Maier, C. (Christiane), Kibel, A. S. (Adam S.), Cybulski, C. (Cezary), Cannon-Albright, L. (Lisa), Butterbach, K. (Katja), Park, J. (Jong), Kaneva, R. (Radka), Batra, J. (Jyotsna), Teixeira, M. R. (Manuel R.), Kote-Jarai, Z. (Zsofia), Al Olama, A. A. (Ali Amin), Benlloch, S. (Sara), Renner, S. P. (Stefan P.), Hartmann, A. (Arndt), Hein, A. (Alexander), Ruebner, M. (Matthias), Lambrechts, D. (Diether), Van Nieuwenhuysen, E. (Els), Vergote, I. (Ignace), Lambretchs, S. (Sandrina), Doherty, J. A. (Jennifer A.), Rossing, M. A. (Mary Anne), Nickels, S. (Stefan), Eilber, U. (Ursula), Wang-Gohrke, S. (Shan), Odunsi, K. (Kunle), Sucheston-Campbell, L. E. (Lara E.), Friel, G. (Grace), Lurie, G. (Galina), Killeen, J. L. (Jeffrey L.), Wilkens, L. R. (Lynne R.), Goodman, M. T. (Marc T.), Runnebaum, I. (Ingo), Hillemanns, P. A. (Peter A.), Pelttari, L. M. (Liisa M.), Butzow, R. (Ralf), Modugno, F. (Francesmary), Edwards, R. P. (Robert P.), Ness, R. B. (Roberta B.), Moysich, K. B. (Kirsten B.), du Bois, A. (Andreas), Heitz, F. (Florian), Harter, P. (Philipp), Kommoss, S. (Stefan), Karlan, B. Y. (Beth Y.), Walsh, C. (Christine), Lester, J. (Jenny), Jensen, A. (Allan), Kjaer, S. K. (Susanne Kruger), Hogdall, E. (Estrid), Peissel, B. (Bernard), Bonanni, B. (Bernardo), Bernard, L. (Loris), Goode, E. L. (Ellen L.), Fridley, B. L. (Brooke L.), Vierkant, R. A. (Robert A.), Cunningham, J. M. (Julie M.), Larson, M. C. (Melissa C.), Fogarty, Z. C. (Zachary C.), Kalli, K. R. (Kimberly R.), Liang, D. (Dong), Lu, K. H. (Karen H.), Hildebrandt, M. A. (Michelle A. T.), Wu, X. (Xifeng), Levine, D. A. (Douglas A.), Dao, F. (Fanny), Bisogna, M. (Maria), Berchuck, A. (Andrew), Iversen, E. S. (Edwin S.), Marks, J. R. (Jeffrey R.), Akushevich, L. (Lucy), Cramer, D. W. (Daniel W.), Schildkraut, J. (Joellen), Terry, K. L. (Kathryn L.), Poole, E. M. (Elizabeth M.), Stampfer, M. (Meir), Tworoger, S. S. (Shelley S.), Bandera, E. V. (Elisa V.), Orlow, I. (Irene), Olson, S. H. (Sara H.), Bjorge, L. (Line), Salvesen, H. B. (Helga B.), van Altena, A. M. (Anne M.), Aben, K. K. (Katja K. H.), Kiemeney, L. A. (Lambertus A.), Massuger, L. F. (Leon F. A. G.), Pejovic, T. (Tanja), Bean, Y. (Yukie), Brooks-Wilson, A. (Angela), Kelemen, L. E. (Linda E.), Cook, L. S. (Linda S.), Le, N. D. (Nhu D.), Grski, B. (Bohdan), Gronwald, J. (Jacek), Menkiszak, J. (Janusz), Hogdall, C. K. (Claus K.), Lundvall, L. (Lene), Nedergaard, L. (Lotte), Engelholm, S. A. (Svend Aage), Dicks, E. (Ed), Tyrer, J. (Jonathan), Campbell, I. (Ian), McNeish, I. (Iain), Paul, J. (James), Siddiqui, N. (Nadeem), Glasspool, R. (Rosalind), Whittemore, A. S. (Alice S.), Rothstein, J. H. (Joseph H.), McGuire, V. (Valerie), Sieh, W. (Weiva), Cai, H. (Hui), Shu, X.-O. (Xiao-Ou), Teten, R. T. (Rachel T.), Sutphen, R. (Rebecca), McLaughlin, J. R. (John R.), Narod, S. A. (Steven A.), Phelan, C. M. (Catherine M.), Monteiro, A. N. (Alvaro N.), Fenstermacher, D. (David), Lin, H.-Y. (Hui-Yi), Permuth, J. B. (Jennifer B.), Sellers, T. A. (Thomas A.), Chen, Y. A. (Y. Ann), Tsai, Y.-Y. (Ya-Yu), Chen, Z. (Zhihua), Gentry-Maharaj, A. (Aleksandra), Gayther, S. A. (Simon A.), Ramus, S. J. (Susan J.), Menon, U. (Usha), Wu, A. H. (Anna H.), Pearce, C. L. (Celeste L.), Van den Berg, D. (David), Pike, M. C. (Malcolm C.), Dansonka-Mieszkowska, A. (Agnieszka), Plisiecka-Halasa, J. (Joanna), Moes-Sosnowska, J. (Joanna), Kupryjanczyk, J. (Jolanta), Pharoah, P. D. (Paul D. P.), Song, H. (Honglin), Winship, I. (Ingrid), Chenevix-Trench, G. (Georgia), Giles, G. G. (Graham G.), Tavtigian, S. V. (Sean V.), Easton, D. F. (Doug F.), and Milne, R. L. (Roger L.)

Subjects

skin and connective tissue diseases

Abstract

Background: The rarity of mutations in PALB2, CHEK2 and ATM make it difficult to estimate precisely associated cancer risks. Population-based family studies have provided evidence that at least some of these mutations are associated with breast cancer risk as high as those associated with rare BRCA2 mutations. We aimed to estimate the relative risks associated with specific rare variants in PALB2, CHEK2 and ATM via a multicentre case-control study. Methods: We genotyped 10 rare mutations using the custom iCOGS array: PALB2 c.1592delT, c.2816T>G and c.3113G>A, CHEK2 c.349A>G, c.538C>T, c.715G>A, c.1036C>T, c.1312G>T, and c.1343T>G and ATM c.7271T>G. We assessed associations with breast cancer risk (42 671 cases and 42 164 controls), as well as prostate (22 301 cases and 22 320 controls) and ovarian (14 542 cases and 23 491 controls) cancer risk, for each variant. Results: For European women, strong evidence of association with breast cancer risk was observed for PALB2 c.1592delT OR 3.44 (95% CI 1.39 to 8.52, p = 7.1 × 10⁻⁵), PALB2 c.3113G>A OR 4.21 (95% CI 1.84 to 9.60, p = 6.9 × 10⁻⁸) and ATM c.7271T>G OR 11.0 (95% CI 1.42 to 85.7, p = 0.0012). We also found evidence of association with breast cancer risk for three variants in CHEK2, c.349A>G OR 2.26 (95% CI 1.29 to 3.95), c.1036C>T OR 5.06 (95% CI 1.09 to 23.5) and c.538C>T OR 1.33 (95% CI 1.05 to 1.67) (p ≤ 0.017). Evidence for prostate cancer risk was observed for CHEK2 c.1343T>G OR 3.03 (95% CI 1.53 to 6.03, p = 0.0006) for African men and CHEK2 c.1312G>T OR 2.21 (95% CI 1.06 to 4.63, p = 0.030) for European men. No evidence of association with ovarian cancer was found for any of these variants. Conclusions: This report adds to accumulating evidence that at least some variants in these genes are associated with an increased risk of breast cancer that is clinically important.

Published

2016

6. An early-onset breast and colorectal cancer-prone family: Does a specific hereditary breast and colorectal cancer syndrome exist?

Author

Thiffault, I., Pal, T., Hamel, N., Deschenes, J., Marcus, V., Odefrey, F., Watters, K., Graham, T., Meschino, W., Narod, S., Goldgar, D., Farber, D., MacNamara, E., Chong, G., and Foulkes, W.

Subjects

Human genetics -- Research, Genetic disorders -- Research, Colorectal cancer -- Genetic aspects, Breast cancer -- Genetic aspects, Biological sciences

Published

2001

7. Evaluation of breast cancer linkage to the putative BRCA3 locus on chromosome 13q21 in 128 multiple case families from the International BRCAX Linkage Consortium

Author

Szabo, C.I., Thompson, D., Mangion, J., Oldenberg, R., Odefrey, F., Seal, S., Barfoot, R., Teare, D., Weber, B., Devilee, P., Easton, D., Goldgar, D., and Stratton, M.

Subjects

Human genetics -- Research, Breast cancer -- Genetic aspects, Linkage (Genetics) -- Research, Chromosomes -- Research, Genetic disorders -- Research, Biological sciences

Published

2001

8. Are ATM mutations 7271T-->G and IVS10-6T-->G really high-risk breast cancer-susceptibility alleles?

Author

Szabo, CI, Schutte, Mieke, Broeks, A, Houwing-Duistermaat, JJ, Thorstenson, YR, Durocher, F, Oldenburg, Rogier, Wasielewski, M (Marijke), Odefrey, F, Thompson, D, Floore, AN, Kraan, J, Klijn, Jan, van den Ouweland, Ans, BRCA-X cons.coop.fam.reg.,, Int.disc.Health Res.int.breast,, Wagner, TMU, Devilee, P, Simard, J, van 't Veer, LJ (Laura), Goldgar, DE, Meijers-Heijboer, EJ, Medical Oncology, Epidemiology, Clinical Genetics, and Human Genetics

Subjects

Cancer Research, Mammary gland, Breast Neoplasms, Cell Cycle Proteins, Ataxia Telangiectasia Mutated Proteins, Protein Serine-Threonine Kinases, Biology, Breast cancer, SDG 3 - Good Health and Well-being, medicine, Humans, Point Mutation, Genetic Predisposition to Disease, Allele, Risk factor, skin and connective tissue diseases, Alleles, Genetics, Tumor Suppressor Proteins, Point mutation, Odds ratio, Middle Aged, medicine.disease, Confidence interval, Pedigree, DNA-Binding Proteins, medicine.anatomical_structure, Oncology, Mutation (genetic algorithm), Female

Abstract

Two mutations of the ATM gene were recently suggested to confer breast cancer risks similar to mutations of BRCA1 or BRCA2. Here, we set out to confirm these findings in 961 families with non-BRCA1/BRCA2 breast cancer from diverse geographical regions. We did not detect the ATM 7271T→G mutation in any family. The ATM IVS10–6T→G mutation was detected in eight families, which was similar to its frequency among population-matched control individuals (pooled Mantel-Haenszel odds ratio = 1.60; 95% confidence interval = 0.48 to 5.35; P = 0.44). Bayesian analysis of linkage in the ATM IVS10–6T→G-positive families showed an overall posterior probability of causality for this mutation of 0.008. We conclude that the ATM IVS10–6T→G mutation does not confer a significantly elevated breast cancer risk and that ATM 7271T→G is a rare event in familial breast cancer.

Published

2004

9. Whole Exome Sequencing Suggests Much of Non-BRCA1/BRCA2 Familial Breast Cancer Is Due to Moderate and Low Penetrance Susceptibility Alleles

Author

Toland, AE, Javier Gracia-Aznarez, F, Fernandez, V, Pita, G, Peterlongo, P, Dominguez, O, de la Hoya, M, Duran, M, Osorio, A, Moreno, L, Gonzalez-Neira, A, Manuel Rosa-Rosa, J, Sinilnikova, O, Mazoyer, S, Hopper, J, Lazaro, C, Southey, M, Odefrey, F, Manoukian, S, Catucci, I, Caldes, T, Lynch, HT, Hilbers, FSM, van Asperen, CJ, Vasen, HFA, Goldgar, D, Radice, P, Devilee, P, Benitez, J, Toland, AE, Javier Gracia-Aznarez, F, Fernandez, V, Pita, G, Peterlongo, P, Dominguez, O, de la Hoya, M, Duran, M, Osorio, A, Moreno, L, Gonzalez-Neira, A, Manuel Rosa-Rosa, J, Sinilnikova, O, Mazoyer, S, Hopper, J, Lazaro, C, Southey, M, Odefrey, F, Manoukian, S, Catucci, I, Caldes, T, Lynch, HT, Hilbers, FSM, van Asperen, CJ, Vasen, HFA, Goldgar, D, Radice, P, Devilee, P, and Benitez, J

Abstract

The identification of the two most prevalent susceptibility genes in breast cancer, BRCA1 and BRCA2, was the beginning of a sustained effort to uncover new genes explaining the missing heritability in this disease. Today, additional high, moderate and low penetrance genes have been identified in breast cancer, such as P53, PTEN, STK11, PALB2 or ATM, globally accounting for around 35 percent of the familial cases. In the present study we used massively parallel sequencing to analyze 7 BRCA1/BRCA2 negative families, each having at least 6 affected women with breast cancer (between 6 and 10) diagnosed under the age of 60 across generations. After extensive filtering, Sanger sequencing validation and co-segregation studies, variants were prioritized through either control-population studies, including up to 750 healthy individuals, or case-control assays comprising approximately 5300 samples. As a result, a known moderate susceptibility indel variant (CHEK2 1100delC) and a catalogue of 11 rare variants presenting signs of association with breast cancer were identified. All the affected genes are involved in important cellular mechanisms like DNA repair, cell proliferation and survival or cell cycle regulation. This study highlights the need to investigate the role of rare variants in familial cancer development by means of novel high throughput analysis strategies optimized for genetically heterogeneous scenarios. Even considering the intrinsic limitations of exome resequencing studies, our findings support the hypothesis that the majority of non-BRCA1/BRCA2 breast cancer families might be explained by the action of moderate and/or low penetrance susceptibility alleles.

Published

2013

10. FAVR (Filtering and Annotation of Variants that are Rare): methods to facilitate the analysis of rare germline genetic variants from massively parallel sequencing datasets

Author

Pope, BJ, Tu, N-D, Odefrey, F, Hammet, F, Bell, R, Tao, K, Tavtigian, SV, Goldgar, DE, Lonie, A, Southey, MC, Park, DJ, Pope, BJ, Tu, N-D, Odefrey, F, Hammet, F, Bell, R, Tao, K, Tavtigian, SV, Goldgar, DE, Lonie, A, Southey, MC, and Park, DJ

Abstract

BACKGROUND: Characterising genetic diversity through the analysis of massively parallel sequencing (MPS) data offers enormous potential to significantly improve our understanding of the genetic basis for observed phenotypes, including predisposition to and progression of complex human disease. Great challenges remain in resolving genetic variants that are genuine from the millions of artefactual signals. RESULTS: FAVR is a suite of new methods designed to work with commonly used MPS analysis pipelines to assist in the resolution of some of the issues related to the analysis of the vast amount of resulting data, with a focus on relatively rare genetic variants. To the best of our knowledge, no equivalent method has previously been described. The most important and novel aspect of FAVR is the use of signatures in comparator sequence alignment files during variant filtering, and annotation of variants potentially shared between individuals. The FAVR methods use these signatures to facilitate filtering of (i) platform and/or mapping-specific artefacts, (ii) common genetic variants, and, where relevant, (iii) artefacts derived from imbalanced paired-end sequencing, as well as annotation of genetic variants based on evidence of co-occurrence in individuals. We applied conventional variant calling applied to whole-exome sequencing datasets, produced using both SOLiD and TruSeq chemistries, with or without downstream processing by FAVR methods. We demonstrate a 3-fold smaller rare single nucleotide variant shortlist with no detected reduction in sensitivity. This analysis included Sanger sequencing of rare variant signals not evident in dbSNP131, assessment of known variant signal preservation, and comparison of observed and expected rare variant numbers across a range of first cousin pairs. The principles described herein were applied in our recent publication identifying XRCC2 as a new breast cancer risk gene and have been made publically available as a suite of software

Published

2013

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

Author

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

Abstract

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

Published

2012

12. Identification of new breast cancer predisposition genes via whole exome sequencing

Author

Southey, MC, Park, DJ, Lesueur, F, Odefrey, F, Nguyen-Dumont, T, Hammet, F, Neuhausen, SL, John, EM, Andrulis, IL, Chenevix-Trench, G, Baglietto, L, Le Calvez-Kelm, F, Pertesi, M, Lonie, A, Pope, B, Sinilnikova, O, Tsimiklis, H, Giles, GG, Hopper, JL, Tavtigian, SV, Goldgar, DE, Southey, MC, Park, DJ, Lesueur, F, Odefrey, F, Nguyen-Dumont, T, Hammet, F, Neuhausen, SL, John, EM, Andrulis, IL, Chenevix-Trench, G, Baglietto, L, Le Calvez-Kelm, F, Pertesi, M, Lonie, A, Pope, B, Sinilnikova, O, Tsimiklis, H, Giles, GG, Hopper, JL, Tavtigian, SV, and Goldgar, DE

Published

2012

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

Author

García-Closas, M. (Montserrat), Hall, P. (Per), Nevanlinna, H. (Heli), Pooley, K.A. (Karen), Morrison, J. (Jonathan), Richesson, D.A. (Douglas), Bojesen, S.E. (Stig), Nordestgaard, B.G. (Børge), Axelsson, C.K. (Christen), Arias Pérez, J.I. (José Ignacio), Milne, R.L. (Roger), Ribas, G. (Gloria), González-Neira, A. (Anna), Benítez, J. (Javier), Zamora, P. (Pilar), Brauch, H. (Hiltrud), Justenhoven, C. (Christina), Hamann, U. (Ute), Ko, Y-D. (Yon-Dschun), Bruening, T. (Thomas), Haas, S. (Susanne), Dörk, T. (Thilo), Schürmann, P. (Peter), Hillemanns, P. (Peter), Bogdanova, N.V. (Natalia), Bremer, M. (Michael), Karstens, J.H. (Johann), Fagerholm, R. (Rainer), Aaltonen, K. (Kirsimari), Aittomäki, K. (Kristiina), Smitten, K. (Karl) von, Blomqvist, C. (Carl), Mannermaa, A. (Arto), Uusitupa, M. (Matti), Eskelinen, M. (Matti), Tengström, M. (Maria), Kosma, V-M. (Veli-Matti), Kataja, V. (Vesa), Chenevix-Trench, G. (Georgia), Spurdle, A.B. (Amanda), Beesley, J. (Jonathan), Chen, X. (Xiaoqing), Devilee, P. (Peter), Asperen, C.J. (Christi) van, Jacobi, C.E. (Catharina), Tollenaar, R.A.E.M. (Rob), Huijts, P. (Petra), Klijn, J.G.M. (Jan), Chang-Claude, J. (Jenny), Kropp, S. (Silke), Slanger, T. (Tracy), Flesch-Janys, D. (Dieter), Mutschelknauss, E. (Elke), Salazar, R. (Ramona), Wang-Gohrke, S. (Shan), Couch, F.J. (Fergus), Goode, E.L. (Ellen), Olson, J.E. (Janet), Vachon, C. (Celine), Fredericksen, Z. (Zachary), Giles, G.G. (Graham), Baglietto, L. (Laura), Severi, G. (Gianluca), Hopper, J.L. (John), English, D.R. (Dallas), Southey, M.C. (Melissa), Haiman, C.A. (Christopher), Henderson, B.E. (Brian), Kolonel, L.N. (Laurence), Le Marchand, L. (Loic), Stram, D.O. (Daniel), Hunter, D. (David), Hankinson, S.E. (Susan), Cox, A. (Angela), Tamimi, R. (Rulla), Kraft, P. (Peter), Sherman, M.E. (Mark), Chanock, S.J. (Stephen), Lissowska, J. (Jolanta), Brinton, L.A. (Louise), Peplonska, B. (Beata), Hooning, M.J. (Maartje), Meijers-Heijboer, E.J. (Hanne), Collée, J.M. (Margriet), Ouweland, A.M.W. (Ans) van den, Uitterlinden, A.G. (André), Liu, J. (Jianjun), Low, Y.L., Yuqing, L. (Li), Humphreys, M.K. (Manjeet), Czene, K. (Kamila), Balasubramanian, S. (Sabapathy), Cross, S.S. (Simon), Reed, M.W.R. (Malcolm), Blows, F. (Fiona), Driver, K. (Kristy), Dunning, A.M. (Alison), Tyrer, J.P. (Jonathan), Ponder, B.A.J. (Bruce), Sangrajrang, S. (Suleeporn), Brennan, P. (Paul), McKay, J.D. (James), Odefrey, F. (Fabrice), Gabrieau, V. (Valerie), Sigurdson, A.J. (Alice), Doody, M. (Michele), Struewing, J.P. (Jeffrey), Alexander, B.H. (Bruce), Easton, D.F. (Douglas), Pharoah, P.D.P. (Paul), García-Closas, M. (Montserrat), Hall, P. (Per), Nevanlinna, H. (Heli), Pooley, K.A. (Karen), Morrison, J. (Jonathan), Richesson, D.A. (Douglas), Bojesen, S.E. (Stig), Nordestgaard, B.G. (Børge), Axelsson, C.K. (Christen), Arias Pérez, J.I. (José Ignacio), Milne, R.L. (Roger), Ribas, G. (Gloria), González-Neira, A. (Anna), Benítez, J. (Javier), Zamora, P. (Pilar), Brauch, H. (Hiltrud), Justenhoven, C. (Christina), Hamann, U. (Ute), Ko, Y-D. (Yon-Dschun), Bruening, T. (Thomas), Haas, S. (Susanne), Dörk, T. (Thilo), Schürmann, P. (Peter), Hillemanns, P. (Peter), Bogdanova, N.V. (Natalia), Bremer, M. (Michael), Karstens, J.H. (Johann), Fagerholm, R. (Rainer), Aaltonen, K. (Kirsimari), Aittomäki, K. (Kristiina), Smitten, K. (Karl) von, Blomqvist, C. (Carl), Mannermaa, A. (Arto), Uusitupa, M. (Matti), Eskelinen, M. (Matti), Tengström, M. (Maria), Kosma, V-M. (Veli-Matti), Kataja, V. (Vesa), Chenevix-Trench, G. (Georgia), Spurdle, A.B. (Amanda), Beesley, J. (Jonathan), Chen, X. (Xiaoqing), Devilee, P. (Peter), Asperen, C.J. (Christi) van, Jacobi, C.E. (Catharina), Tollenaar, R.A.E.M. (Rob), Huijts, P. (Petra), Klijn, J.G.M. (Jan), Chang-Claude, J. (Jenny), Kropp, S. (Silke), Slanger, T. (Tracy), Flesch-Janys, D. (Dieter), Mutschelknauss, E. (Elke), Salazar, R. (Ramona), Wang-Gohrke, S. (Shan), Couch, F.J. (Fergus), Goode, E.L. (Ellen), Olson, J.E. (Janet), Vachon, C. (Celine), Fredericksen, Z. (Zachary), Giles, G.G. (Graham), Baglietto, L. (Laura), Severi, G. (Gianluca), Hopper, J.L. (John), English, D.R. (Dallas), Southey, M.C. (Melissa), Haiman, C.A. (Christopher), Henderson, B.E. (Brian), Kolonel, L.N. (Laurence), Le Marchand, L. (Loic), Stram, D.O. (Daniel), Hunter, D. (David), Hankinson, S.E. (Susan), Cox, A. (Angela), Tamimi, R. (Rulla), Kraft, P. (Peter), Sherman, M.E. (Mark), Chanock, S.J. (Stephen), Lissowska, J. (Jolanta), Brinton, L.A. (Louise), Peplonska, B. (Beata), Hooning, M.J. (Maartje), Meijers-Heijboer, E.J. (Hanne), Collée, J.M. (Margriet), Ouweland, A.M.W. (Ans) van den, Uitterlinden, A.G. (André), Liu, J. (Jianjun), Low, Y.L., Yuqing, L. (Li), Humphreys, M.K. (Manjeet), Czene, K. (Kamila), Balasubramanian, S. (Sabapathy), Cross, S.S. (Simon), Reed, M.W.R. (Malcolm), Blows, F. (Fiona), Driver, K. (Kristy), Dunning, A.M. (Alison), Tyrer, J.P. (Jonathan), Ponder, B.A.J. (Bruce), Sangrajrang, S. (Suleeporn), Brennan, P. (Paul), McKay, J.D. (James), Odefrey, F. (Fabrice), Gabrieau, V. (Valerie), Sigurdson, A.J. (Alice), Doody, M. (Michele), Struewing, J.P. (Jeffrey), Alexander, B.H. (Bruce), Easton, D.F. (Douglas), and Pharoah, P.D.P. (Paul)

Abstract

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

Published

2008

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

Author

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

Abstract

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

Published

2008

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

Author

Garcia-Closas, M., Hall, P., Nevanlinna, H., Pooley, K., Morrison, J., Richesson, D.A., Bojesen, S.E., Axelsson, C.K., Arias, J.I., Milne, R.L., Ribas, G., Gonzalez-Neira, A., Benitez, J., Zamora, P., Brauch, H., Justenhoven, C., Hamann, U., Ko, Y.D., Bruening, T., Haas, S., Dork, T., Schurmann, P., Hillemanns, P., Bogdanova, N., Bremer, M., Karstens, J.H., Fagerholm, R., Aaltonen, K., Aittomaki, K., Smitten, K. Von, Blomqvist, C., Mannermaa, A., Uusitupa, M., Eskelinen, M., Tengstrom, M., Kosma, V.M., Kataja, V., Chenevix-Trench, G., Spurdle, A.B., Beesley, J., Chen, X., Devilee, P., Asperen, C.J. Van, Jacobi, C.E., Tollenaar, R.A.E.M., Huijts, P.E.A., Klijn, J.G.M., Chang-Claude, J., Kropp, S., Slanger, T., Flesch-Janys, D., Mutschelknauss, E., Salazar, R., Wang-Gohrke, S., Couch, F., Goode, E.L., Olson, J.E., Vachon, C., Fredericksen, Z.S., Giles, G.G., Baglietto, L., Severi, G., Hopper, J.L., English, D.R., Southey, M.C., Haiman, C.A., Henderson, B.E., Kolonel, L.N., Marchand, L. Le, Stram, D.O., Hunter, D.J., Hankinson, S.E., Cox, D.G., Tamimi, R., Kraft, P., Sherman, M.E., Chanock, S.J., Lissowska, J., Brinton, L.A., Peplonska, B., Hooning, M.J., Meijers-Heijboer, H., Collee, J.M., Ouweland, A. Van den, Uitterlinden, A.G., Liu, J., Lin, L.Y., Yuqing, L., Humphreys, K., Czene, K., Cox, A., Balasubramanian, S.P., Cross, S.S., Reed, M.W.R., Blows, F., Driver, K., Dunning, A., Tyrer, J., Ponder, B.A.J., Sangrajrang, S., Brennan, P., Mckay, J., Odefrey, F., Gabrieau, V., Sigurdson, A., Doody, M., Struewing, J.P., Alexander, B., Easton, D.F., Pharoah, P.D., Nordestgaard, Børge, Garcia-Closas, M., Hall, P., Nevanlinna, H., Pooley, K., Morrison, J., Richesson, D.A., Bojesen, S.E., Axelsson, C.K., Arias, J.I., Milne, R.L., Ribas, G., Gonzalez-Neira, A., Benitez, J., Zamora, P., Brauch, H., Justenhoven, C., Hamann, U., Ko, Y.D., Bruening, T., Haas, S., Dork, T., Schurmann, P., Hillemanns, P., Bogdanova, N., Bremer, M., Karstens, J.H., Fagerholm, R., Aaltonen, K., Aittomaki, K., Smitten, K. Von, Blomqvist, C., Mannermaa, A., Uusitupa, M., Eskelinen, M., Tengstrom, M., Kosma, V.M., Kataja, V., Chenevix-Trench, G., Spurdle, A.B., Beesley, J., Chen, X., Devilee, P., Asperen, C.J. Van, Jacobi, C.E., Tollenaar, R.A.E.M., Huijts, P.E.A., Klijn, J.G.M., Chang-Claude, J., Kropp, S., Slanger, T., Flesch-Janys, D., Mutschelknauss, E., Salazar, R., Wang-Gohrke, S., Couch, F., Goode, E.L., Olson, J.E., Vachon, C., Fredericksen, Z.S., Giles, G.G., Baglietto, L., Severi, G., Hopper, J.L., English, D.R., Southey, M.C., Haiman, C.A., Henderson, B.E., Kolonel, L.N., Marchand, L. Le, Stram, D.O., Hunter, D.J., Hankinson, S.E., Cox, D.G., Tamimi, R., Kraft, P., Sherman, M.E., Chanock, S.J., Lissowska, J., Brinton, L.A., Peplonska, B., Hooning, M.J., Meijers-Heijboer, H., Collee, J.M., Ouweland, A. Van den, Uitterlinden, A.G., Liu, J., Lin, L.Y., Yuqing, L., Humphreys, K., Czene, K., Cox, A., Balasubramanian, S.P., Cross, S.S., Reed, M.W.R., Blows, F., Driver, K., Dunning, A., Tyrer, J., Ponder, B.A.J., Sangrajrang, S., Brennan, P., Mckay, J., Odefrey, F., Gabrieau, V., Sigurdson, A., Doody, M., Struewing, J.P., Alexander, B., Easton, D.F., Pharoah, P.D., and Nordestgaard, Børge

Abstract

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

Published

2008

16. Genome-wide association study identifies novel breast cancer susceptibility loci.

Author

Cox A., Farshid G., Fawcett S., Field M., Firgaira F., Fleming J., Forbes J., Friedlander M., Gaff C., Gardner M., Gattas M., George P., Gill G., Goldblatt J., Greening S., Haan E., Hart S., Humphrey E., Jenkins M., Kefford R., Kirk J., Kollias J., Kovalenko S., Lakhani S., Leary J., Lim J., Lindeman G., Lipton L., Lobb L., Maclurcan M., Marsh D., McKay M., Anne McLachlan S., Mitchell G., Newman B., O'Loughlin I., Osborne R., Peters L., Price M., Reeve J., Reeve T., Richards R., Rinehart G., Robinson B., Rudzki B., Salisbury E., Saunders C., Scott E., Seshadri R., Shelling A., Suthers G., Taylor D., Tennant C., Townshend S., Tyler J., Venter D., Visvader J., Walpole I., Ward R., Warner B., Warren G., Watson E., Williams R., Winship I., Bowtell D., Green A., DeFazio A., Gertig D., Webb P., Milne R., Young M.A., Harris M., Wilson J., Easton D.F., Pooley K.A., Dunning A.M., Pharoah P.D.P., Thompson D., Ballinger D.G., Struewing J.P., Morrison J., Field H., Luben R., Wareham N., Ahmed S., Healey C.S., Bowman R., Meyer K.B., Haiman C.A., Kolonel L.K., Henderson B.E., Le Marchand L., Brennan P., Sangrajrang S., Gaborieau V., Odefrey F., Shen C.-Y., Wu P.-E., Wang H.-C., Eccles D., Evans D.G., Peto J., Fletcher O., Johnson N., Seal S., Stratton M.R., Rahman N., Chenevix-Trench G., Bojesen S.E., Nordestgaard B.G., Axelsson C.K., Garcia-Closas M., Brinton L., Chanock S., Lissowska J., Peplonska B., Nevanlinna H., Fagerholm R., Eerola H., Kang D., Yoo K.-Y., Noh D.-Y., Ahn S.-H., Hunter D.J., Hankinson S.E., Cox D.G., Hall P., Wedren S., Liu J., Low Y.-L., Bogdanova N., Schurmann P., Dork T., Tollenaar R.A.E.M., Jacobi C.E., Devilee P., Klijn J.G.M., Sigurdson A.J., Doody M.M., Alexander B.H., Zhang J., Brock I.W., MacPherson G., Reed M.W.R., Couch F.J., Goode E.L., Olson J.E., Meijers-Heijboer H., Van Den Ouweland A., Uitterlinden A., Rivadeneira F., Milne R.L., Ribas G., Gonzalez-Neira A., Benitez J., Hopper J., McCredie M., Southey M., Giles G., Schroen C., Justenhoven C., Brauch H., Hamann U., Ko Y.-D., Spurdle A.B., Beesley J., Chen X., Mannermaa A., Kosma V.-M., Kataja V., Hartikainen J., Day N.E., Cox D.R., Ponder B.A.J., Luccarini C., Conroy D., Shah M., Munday H., Jordan C., Perkins B., West J., Redman K., Driver K., Aghmesheh M., Amor D., Andrews L., Antill Y., Armes J., Armitage S., Arnold L., Balleine R., Begley G., Beilby J., Bennett I., Bennett B., Berry G., Blackburn A., Brennan M., Brown M., Buckley M., Burke J., Butow P., Byron K., Callen D., Campbell I., Clarke C., Colley A., Cotton D., Cui J., Culling B., Cummings M., Dawson S.-J., Dixon J., Dobrovic A., Dudding T., Edkins T., Eisenbruch M., Cox A., Farshid G., Fawcett S., Field M., Firgaira F., Fleming J., Forbes J., Friedlander M., Gaff C., Gardner M., Gattas M., George P., Gill G., Goldblatt J., Greening S., Haan E., Hart S., Humphrey E., Jenkins M., Kefford R., Kirk J., Kollias J., Kovalenko S., Lakhani S., Leary J., Lim J., Lindeman G., Lipton L., Lobb L., Maclurcan M., Marsh D., McKay M., Anne McLachlan S., Mitchell G., Newman B., O'Loughlin I., Osborne R., Peters L., Price M., Reeve J., Reeve T., Richards R., Rinehart G., Robinson B., Rudzki B., Salisbury E., Saunders C., Scott E., Seshadri R., Shelling A., Suthers G., Taylor D., Tennant C., Townshend S., Tyler J., Venter D., Visvader J., Walpole I., Ward R., Warner B., Warren G., Watson E., Williams R., Winship I., Bowtell D., Green A., DeFazio A., Gertig D., Webb P., Milne R., Young M.A., Harris M., Wilson J., Easton D.F., Pooley K.A., Dunning A.M., Pharoah P.D.P., Thompson D., Ballinger D.G., Struewing J.P., Morrison J., Field H., Luben R., Wareham N., Ahmed S., Healey C.S., Bowman R., Meyer K.B., Haiman C.A., Kolonel L.K., Henderson B.E., Le Marchand L., Brennan P., Sangrajrang S., Gaborieau V., Odefrey F., Shen C.-Y., Wu P.-E., Wang H.-C., Eccles D., Evans D.G., Peto J., Fletcher O., Johnson N., Seal S., Stratton M.R., Rahman N., Chenevix-Trench G., Bojesen S.E., Nordestgaard B.G., Axelsson C.K., Garcia-Closas M., Brinton L., Chanock S., Lissowska J., Peplonska B., Nevanlinna H., Fagerholm R., Eerola H., Kang D., Yoo K.-Y., Noh D.-Y., Ahn S.-H., Hunter D.J., Hankinson S.E., Cox D.G., Hall P., Wedren S., Liu J., Low Y.-L., Bogdanova N., Schurmann P., Dork T., Tollenaar R.A.E.M., Jacobi C.E., Devilee P., Klijn J.G.M., Sigurdson A.J., Doody M.M., Alexander B.H., Zhang J., Brock I.W., MacPherson G., Reed M.W.R., Couch F.J., Goode E.L., Olson J.E., Meijers-Heijboer H., Van Den Ouweland A., Uitterlinden A., Rivadeneira F., Milne R.L., Ribas G., Gonzalez-Neira A., Benitez J., Hopper J., McCredie M., Southey M., Giles G., Schroen C., Justenhoven C., Brauch H., Hamann U., Ko Y.-D., Spurdle A.B., Beesley J., Chen X., Mannermaa A., Kosma V.-M., Kataja V., Hartikainen J., Day N.E., Cox D.R., Ponder B.A.J., Luccarini C., Conroy D., Shah M., Munday H., Jordan C., Perkins B., West J., Redman K., Driver K., Aghmesheh M., Amor D., Andrews L., Antill Y., Armes J., Armitage S., Arnold L., Balleine R., Begley G., Beilby J., Bennett I., Bennett B., Berry G., Blackburn A., Brennan M., Brown M., Buckley M., Burke J., Butow P., Byron K., Callen D., Campbell I., Clarke C., Colley A., Cotton D., Cui J., Culling B., Cummings M., Dawson S.-J., Dixon J., Dobrovic A., Dudding T., Edkins T., and Eisenbruch M.

Abstract

Breast cancer exhibits familial aggregation, consistent with variation in genetic susceptibility to the disease. Known susceptibility genes account for less than 25% of the familial risk of breast cancer, and the residual genetic variance is likely to be due to variants conferring more moderate risks. To identify further susceptibility alleles, we conducted a two-stage genome-wide association study in 4,398 breast cancer cases and 4,316 controls, followed by a third stage in which 30 single nucleotide polymorphisms (SNPs) were tested for confirmation in 21,860 cases and 22,578 controls from 22 studies. We used 227,876 SNPs that were estimated to correlate with 77% of known common SNPs in Europeans at r2> 0.5. SNPs in five novel independent loci exhibited strong and consistent evidence of association with breast cancer (P < 10-7). Four of these contain plausible causative genes (FGFR2, TNRC9, MAP3K1 and LSP1). At the second stage, 1,792 SNPs were significant at the P < 0.05 level compared with an estimated 1,343 that would be expected by chance, indicating that many additional common susceptibility alleles may be identifiable by this approach. ©2007 Nature Publishing Group.

Published

2007

17. Germline truncating mutations in both MSH2 and BRCA2 in a single kindred.

Author

Thiffault, I, Hamel, N, Pal, T, McVety, S, Marcus, VA, Farber, D, Cowie, S, Deschênes, J, Meschino, W, Odefrey, F, Goldgar, D, Graham, T, Narod, S, Watters, AK, MacNamara, E, Du Sart, D, Chong, G, Foulkes, WD, Thiffault, I, Hamel, N, Pal, T, McVety, S, Marcus, VA, Farber, D, Cowie, S, Deschênes, J, Meschino, W, Odefrey, F, Goldgar, D, Graham, T, Narod, S, Watters, AK, MacNamara, E, Du Sart, D, Chong, G, and Foulkes, WD

Abstract

There has been interest in the literature in the possible existence of a gene that predisposes to both breast cancer (BC) and colorectal cancer (CRC). We describe the detailed characterisation of one kindred, MON1080, with 10 cases of BC or CRC invasive cancer among 26 first-, second- or third-degree relatives. Linkage analysis suggested that a mutation was present in BRCA2. DNA sequencing from III: 22 (diagnosed with lobular BC) identified a BRCA2 exon 3 542G>T (L105X) mutation. Her sister (III: 25) had BC and endometrial cancer and carries the same mutation. Following immunohistochemical and microsatellite instability studies, mutation analysis by protein truncation test, cDNA sequencing and quantitative real-time PCR revealed a deletion of MSH2 exon 8 in III: 25, confirming her as a double heterozygote for truncating mutations in both BRCA2 and MSH2. The exon 8 deletion was identified as a 14.9 kb deletion occurring between two Alu sequences. The breakpoint lies within a sequence of 45 bp that is identical in both Alu sequences. In this large BC/CRC kindred, MON1080, disease-causing truncating mutations are present in both MSH2 and BRCA2. There appeared to be no increased susceptibility to the development of colorectal tumours in BRCA2 mutation carriers or to the development of breast tumours in MSH2 mutation carriers. Additionally, two double heterozygotes did not appear to have a different phenotype than would be expected from the presence of a mutation in each gene alone.

Published

2004

18. The rs12975333 variant in the miR-125a and breast cancer risk in Germany, Italy, Australia and Spain

Author

Peterlongo, P., primary, Caleca, L., additional, Cattaneo, E., additional, Ravagnani, F., additional, Bianchi, T., additional, Galastri, L., additional, Bernard, L., additional, Ficarazzi, F., additional, Dall'olio, V., additional, Marme, F., additional, Langheinz, A., additional, Sohn, C., additional, Burwinkel, B., additional, Giles, G. G., additional, Baglietto, L., additional, Severi, G., additional, Odefrey, F. A., additional, Southey, M. C., additional, Osorio, A., additional, Fernandez, F., additional, Alonso, M. R., additional, Benitez, J., additional, Barile, M., additional, Peissel, B., additional, Manoukian, S., additional, and Radice, P., additional

Published

2011

19. Germline truncating mutations in both MSH2 and BRCA2 in a single kindred

Author

Thiffault, I, primary, Hamel, N, additional, Pal, T, additional, McVety, S, additional, Marcus, V A, additional, Farber, D, additional, Cowie, S, additional, Deschênes, J, additional, Meschino, W, additional, Odefrey, F, additional, Goldgar, D, additional, Graham, T, additional, Narod, S, additional, Watters, A K, additional, MacNamara, E, additional, Sart, D Du, additional, Chong, G, additional, and Foulkes, W D, additional

Published

2004

20. Tumour morphology predicts PALB2 germline mutation status.

Author

Teo, Z L, Provenzano, E, Dite, G S, Park, D J, Apicella, C, Sawyer, S D, James, P A, Mitchell, G, Trainer, A H, Lindeman, G J, Shackleton, K, Cicciarelli, L, Buys, S S, Andrulis, I L, Mulligan, A M, Glendon, G, John, E M, Terry, M B, Daly, M, and Odefrey, F A

Subjects

BREAST cancer diagnosis, GERM cells, BREAST tumors, MORPHOLOGY, GENETIC mutation, CONFIDENCE intervals

Abstract

Background:Population-based studies of breast cancer have estimated that at least some PALB2 mutations are associated with high breast cancer risk. For women carrying PALB2 mutations, knowing their carrier status could be useful in directing them towards effective cancer risk management and therapeutic strategies. We sought to determine whether morphological features of breast tumours can predict PALB2 germline mutation status.Methods:Systematic pathology review was conducted on breast tumours from 28 female carriers of PALB2 mutations (non-carriers of other known high-risk mutations, recruited through various resources with varying ascertainment) and on breast tumours from a population-based sample of 828 Australian women diagnosed before the age of 60 years (which included 40 BRCA1 and 18 BRCA2 mutation carriers). Tumour morphological features of the 28 PALB2 mutation carriers were compared with those of 770 women without high-risk mutations.Results:Tumours arising in PALB2 mutation carriers were associated with minimal sclerosis (odds ratio (OR)=19.7; 95% confidence interval (CI)=6.0-64.6; P=5 × 10−7). Minimal sclerosis was also a feature that distinguished PALB2 mutation carriers from BRCA1 (P=0.05) and BRCA2 (P=0.04) mutation carriers.Conclusion:This study identified minimal sclerosis to be a predictor of germline PALB2 mutation status. Morphological review can therefore facilitate the identification of women most likely to carry mutations in PALB2. [ABSTRACT FROM AUTHOR]

Published

2013

21. Early exploration of two candidate breast cancer susceptibility genes identified by whole-exome sequencing

Author

Blanc R, Jammot A, Nguyen-Dumont T, Teo ZL, Odefrey FA, Hammet F, Goldgar DE, Park DJ, and Southey MC

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282, Genetics, QH426-470

Published

2012

22. Uncommon CHEK2 mis-sense variant and reduced risk of tobacco-related cancers: Case - Control study

Author

Lee E. Moore, Peter Rudnai, Lenka Foretova, Paul Brennan, Eleonora Fabianova, Melissa C. Southey, Rayjean J. Hung, Dana Mates, Neonilia Szeszenia-Dabrowska, Valerie Gaborieau, Paolo Boffetta, James McKay, Fabrice Odefrey, Vladimir Janout, Amelie Chabrier, Jolanta Lissowska, Richard Peto, Wong Ho Chow, Anush Mukeria, Julian Peto, Vladimir Bencko, Janet Hall, David Zaridze, Nathanial Rothman, Mia Hashibe, Brennan, P., McKay, J., Moore, L., Zaridze, D., Mukeria, A., Szeszenia-Dabrowska, N., Lissowska, J., Rudnai, P., Fabianova, E., Mates, D., Bencko, V., Foretova, L., Janout, V., Chow, W.-H., Rothman, N., Chabrier, A., Gaborieau, V., Odefrey, F., Southey, M., Hashibe, M., Hall, J., Boffetta, P., Peto, J., Peto, R., and Hung, R.J.

Subjects

Oncology, Adult, Male, medicine.medical_specialty, Lung Neoplasms, Mutation, Missense, Apoptosis, Biology, Protein Serine-Threonine Kinases, Polymorphism, Single Nucleotide, Tobacco smoke, Breast cancer, Risk Factors, Internal medicine, Genotype, Genetics, medicine, Carcinoma, Humans, Lung cancer, Molecular Biology, CHEK2, Genetics (clinical), Aged, Stem Cells, Smoking, Cancer, General Medicine, Middle Aged, medicine.disease, Kidney Neoplasms, Checkpoint Kinase 2, Uncommon CHEK2 mis-sense variant reduced risk tobacco-related cancers: case control study, Case-Control Studies, Carcinoma, Squamous Cell, Female, Kidney cancer

Abstract

CHEK2 is a key cell cycle control gene encoding a pluripotent kinase that can cause arrest or apoptosis in response to unrepaired DNA damage. We report a large case-control study of a non-functional variant that had previously been expected to increase cancer rates. Four thousand and fifteen cancer patients (2250 lung, 811 squamous upper aero-digestive and 954 kidney) and 3052 controls in central Europe were genotyped for the mis-sense variant rs17879961 (replacement of T by C), which changes an amino acid (I157T) in an active site of the gene product. The heterozygous (T/C) genotype was associated with a highly significantly lower incidence of lung cancer than the common T/T genotype [relative risk (RR), T/C versus T/T, 0.44, with 95% confidence interval (CI) 0.31-0.63, P < 0.00001] and with a significantly lower incidence of upper aero-digestive cancer (RR 0.44, CI 0.26-0.73, (P = 0.001; P = 0.000001 for lung or upper aero-digestive cancer). Protection was significantly greater for squamous than adenomatous lung cancer (P = 0.001). There was an increase of borderline significance in kidney cancer (RR 1.44, CI 0.99-2.00, P = 0.06). This unexpected halving of tobacco-related cancer (since replicated independently) implies much greater absolute risk reduction in smokers than in non-smokers. The mechanism is unknown: perhaps squamous stem cell apoptosis following smoke exposure causes net harm (e.g. by forcing nearby stem cells to divide before they have repaired their own DNA damage from tobacco smoke). If so, reducing the rate of apoptosis by reducing CHEK2 activity could be protective - although not smoking would be far more so. © The Author 2007. Published by Oxford University Press. All rights reserved.

Published

2007

23. Rare mutations in RINT1 predispose carriers to breast and Lynch syndrome-spectrum cancers.

Author

Park DJ, Tao K, Le Calvez-Kelm F, Nguyen-Dumont T, Robinot N, Hammet F, Odefrey F, Tsimiklis H, Teo ZL, Thingholm LB, Young EL, Voegele C, Lonie A, Pope BJ, Roane TC, Bell R, Hu H, Shankaracharya, Huff CD, Ellis J, Li J, Makunin IV, John EM, Andrulis IL, Terry MB, Daly M, Buys SS, Snyder C, Lynch HT, Devilee P, Giles GG, Hopper JL, Feng BJ, Lesueur F, Tavtigian SV, Southey MC, and Goldgar DE

Subjects

Case-Control Studies, Exome, Female, Genetic Predisposition to Disease, Genetic Variation, High-Throughput Nucleotide Sequencing, Humans, Male, Mutation, Pedigree, Sequence Analysis, DNA, Breast Neoplasms genetics, Cell Cycle Proteins genetics, Colorectal Neoplasms, Hereditary Nonpolyposis genetics

Abstract

Unlabelled: Approximately half of the familial aggregation of breast cancer remains unexplained. A multiple-case breast cancer family exome-sequencing study identified three likely pathogenic mutations in RINT1 (NM&#95;021930.4) not present in public sequencing databases: RINT1 c.343C>T (p.Q115X), c.1132&#95;1134del (p.M378del), and c.1207G>T (p.D403Y). On the basis of this finding, a population-based case-control mutation-screening study was conducted that identified 29 carriers of rare (minor allele frequency < 0.5%), likely pathogenic variants: 23 in 1,313 early-onset breast cancer cases and six in 1,123 frequency-matched controls [OR, 3.24; 95% confidence interval (CI), 1.29-8.17; P = 0.013]. RINT1 mutation screening of probands from 798 multiple-case breast cancer families identified four additional carriers of rare genetic variants. Analysis of the incidence of first primary cancers in families of women carrying RINT1 mutations estimated that carriers were at increased risk of Lynch syndrome-spectrum cancers [standardized incidence ratio (SIR), 3.35; 95% CI, 1.7-6.0; P = 0.005], particularly for relatives diagnosed with cancer under the age of 60 years (SIR, 10.9; 95% CI, 4.7-21; P = 0.0003)., Significance: The work described in this study adds RINT1 to the growing list of genes in which rare sequence variants are associated with intermediate levels of breast cancer risk. Given that RINT1 is also associated with a spectrum of cancers with mismatch repair defects, these findings have clinical applications and raise interesting biological questions., (©2014 American Association for Cancer Research.)

Published

2014

24. Explaining variance in the cumulus mammographic measures that predict breast cancer risk: a twins and sisters study.

Author

Nguyen TL, Schmidt DF, Makalic E, Dite GS, Stone J, Apicella C, Bui M, Macinnis RJ, Odefrey F, Cawson JN, Treloar SA, Southey MC, Giles GG, and Hopper JL

Subjects

Age Factors, Australia epidemiology, Body Mass Index, Breast pathology, Breast Neoplasms genetics, Breast Neoplasms pathology, Case-Control Studies, Cohort Studies, Female, Genetic Predisposition to Disease, Humans, Mammography instrumentation, Middle Aged, Predictive Value of Tests, Breast Neoplasms diagnostic imaging, Breast Neoplasms epidemiology, Mammography methods, Siblings, Twins, Dizygotic, Twins, Monozygotic

Abstract

Background: Mammographic density, the area of the mammographic image that appears white or bright, predicts breast cancer risk. We estimated the proportions of variance explained by questionnaire-measured breast cancer risk factors and by unmeasured residual familial factors., Methods: For 544 MZ and 339 DZ twin pairs and 1,558 non-twin sisters from 1,564 families, mammographic density was measured using the computer-assisted method Cumulus. We estimated associations using multilevel mixed-effects linear regression and studied familial aspects using a multivariate normal model., Results: The proportions of variance explained by age, body mass index (BMI), and other risk factors, respectively, were 4%, 1%, and 4% for dense area; 7%, 14%, and 4% for percent dense area; and 7%, 40%, and 1% for nondense area. Associations with dense area and percent dense area were in opposite directions than for nondense area. After adjusting for measured factors, the correlations of dense area with percent dense area and nondense area were 0.84 and -0.46, respectively. The MZ, DZ, and sister pair correlations were 0.59, 0.28, and 0.29 for dense area; 0.57, 0.30, and 0.28 for percent dense area; and 0.56, 0.27, and 0.28 for nondense area (SE = 0.02, 0.04, and 0.03, respectively)., Conclusions: Under the classic twin model, 50% to 60% (SE = 5%) of the variance of mammographic density measures that predict breast cancer risk are due to undiscovered genetic factors, and the remainder to as yet unknown individual-specific, nongenetic factors., Impact: Much remains to be learnt about the genetic and environmental determinants of mammographic density., (©2013 AACR.)

Published

2013

25. FAVR (Filtering and Annotation of Variants that are Rare): methods to facilitate the analysis of rare germline genetic variants from massively parallel sequencing datasets.

Author

Pope BJ, Nguyen-Dumont T, Odefrey F, Hammet F, Bell R, Tao K, Tavtigian SV, Goldgar DE, Lonie A, Southey MC, and Park DJ

Subjects

Breast Neoplasms genetics, Exome, Female, Humans, Molecular Sequence Annotation, Phenotype, Sequence Alignment, Genetic Variation, High-Throughput Nucleotide Sequencing, Sequence Analysis, DNA, Software

Abstract

Background: Characterising genetic diversity through the analysis of massively parallel sequencing (MPS) data offers enormous potential to significantly improve our understanding of the genetic basis for observed phenotypes, including predisposition to and progression of complex human disease. Great challenges remain in resolving genetic variants that are genuine from the millions of artefactual signals., Results: FAVR is a suite of new methods designed to work with commonly used MPS analysis pipelines to assist in the resolution of some of the issues related to the analysis of the vast amount of resulting data, with a focus on relatively rare genetic variants. To the best of our knowledge, no equivalent method has previously been described. The most important and novel aspect of FAVR is the use of signatures in comparator sequence alignment files during variant filtering, and annotation of variants potentially shared between individuals. The FAVR methods use these signatures to facilitate filtering of (i) platform and/or mapping-specific artefacts, (ii) common genetic variants, and, where relevant, (iii) artefacts derived from imbalanced paired-end sequencing, as well as annotation of genetic variants based on evidence of co-occurrence in individuals. We applied conventional variant calling applied to whole-exome sequencing datasets, produced using both SOLiD and TruSeq chemistries, with or without downstream processing by FAVR methods. We demonstrate a 3-fold smaller rare single nucleotide variant shortlist with no detected reduction in sensitivity. This analysis included Sanger sequencing of rare variant signals not evident in dbSNP131, assessment of known variant signal preservation, and comparison of observed and expected rare variant numbers across a range of first cousin pairs. The principles described herein were applied in our recent publication identifying XRCC2 as a new breast cancer risk gene and have been made publically available as a suite of software tools., Conclusions: FAVR is a platform-agnostic suite of methods that significantly enhances the analysis of large volumes of sequencing data for the study of rare genetic variants and their influence on phenotypes.

Published

2013

26. Whole exome sequencing suggests much of non-BRCA1/BRCA2 familial breast cancer is due to moderate and low penetrance susceptibility alleles.

Author

Gracia-Aznarez FJ, Fernandez V, Pita G, Peterlongo P, Dominguez O, de la Hoya M, Duran M, Osorio A, Moreno L, Gonzalez-Neira A, Rosa-Rosa JM, Sinilnikova O, Mazoyer S, Hopper J, Lazaro C, Southey M, Odefrey F, Manoukian S, Catucci I, Caldes T, Lynch HT, Hilbers FS, van Asperen CJ, Vasen HF, Goldgar D, Radice P, Devilee P, and Benitez J

Subjects

Female, Humans, Alleles, Breast Neoplasms genetics, Exome, Genes, BRCA1, Genes, BRCA2

Abstract

The identification of the two most prevalent susceptibility genes in breast cancer, BRCA1 and BRCA2, was the beginning of a sustained effort to uncover new genes explaining the missing heritability in this disease. Today, additional high, moderate and low penetrance genes have been identified in breast cancer, such as P53, PTEN, STK11, PALB2 or ATM, globally accounting for around 35 percent of the familial cases. In the present study we used massively parallel sequencing to analyze 7 BRCA1/BRCA2 negative families, each having at least 6 affected women with breast cancer (between 6 and 10) diagnosed under the age of 60 across generations. After extensive filtering, Sanger sequencing validation and co-segregation studies, variants were prioritized through either control-population studies, including up to 750 healthy individuals, or case-control assays comprising approximately 5300 samples. As a result, a known moderate susceptibility indel variant (CHEK2 1100delC) and a catalogue of 11 rare variants presenting signs of association with breast cancer were identified. All the affected genes are involved in important cellular mechanisms like DNA repair, cell proliferation and survival or cell cycle regulation. This study highlights the need to investigate the role of rare variants in familial cancer development by means of novel high throughput analysis strategies optimized for genetically heterogeneous scenarios. Even considering the intrinsic limitations of exome resequencing studies, our findings support the hypothesis that the majority of non-BRCA1/BRCA2 breast cancer families might be explained by the action of moderate and/or low penetrance susceptibility alleles.

Published

2013

27. Common breast cancer susceptibility variants in LSP1 and RAD51L1 are associated with mammographic density measures that predict breast cancer risk.

Author

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

Subjects

Adult, Aged, Case-Control Studies, Cross-Sectional Studies, Female, Humans, Mammography, Middle Aged, Prognosis, Risk Factors, Breast pathology, Breast Neoplasms diagnosis, Breast Neoplasms genetics, DNA-Binding Proteins genetics, Genetic Predisposition to Disease, Microfilament Proteins genetics, Polymorphism, Single Nucleotide

Abstract

Background: Mammographic density adjusted for age and body mass index (BMI) is a heritable marker of breast cancer susceptibility. Little is known about the biologic mechanisms underlying the association between mammographic density and breast cancer risk. We examined whether common low-penetrance breast cancer susceptibility variants contribute to interindividual differences in mammographic density measures., Methods: We established an international consortium (DENSNP) of 19 studies from 10 countries, comprising 16,895 Caucasian women, to conduct a pooled cross-sectional analysis of common breast cancer susceptibility variants in 14 independent loci and mammographic density measures. Dense and nondense areas, and percent density, were measured using interactive-thresholding techniques. Mixed linear models were used to assess the association between genetic variants and the square roots of mammographic density measures adjusted for study, age, case status, BMI, and menopausal status., Results: Consistent with their breast cancer associations, the C-allele of rs3817198 in LSP1 was positively associated with both adjusted dense area (P = 0.00005) and adjusted percent density (P = 0.001), whereas the A-allele of rs10483813 in RAD51L1 was inversely associated with adjusted percent density (P = 0.003), but not with adjusted dense area (P = 0.07)., Conclusion: We identified two common breast cancer susceptibility variants associated with mammographic measures of radiodense tissue in the breast gland., Impact: We examined the association of 14 established breast cancer susceptibility loci with mammographic density phenotypes within a large genetic consortium and identified two breast cancer susceptibility variants, LSP1-rs3817198 and RAD51L1-rs10483813, associated with mammographic measures and in the same direction as the breast cancer association., (©2012 AACR)

Published

2012

28. Associations of breast cancer risk factors with tumor subtypes: a pooled analysis from the Breast Cancer Association Consortium studies.

Author

Yang XR, Chang-Claude J, Goode EL, Couch FJ, Nevanlinna H, Milne RL, Gaudet M, Schmidt MK, Broeks A, Cox A, Fasching PA, Hein R, Spurdle AB, Blows F, Driver K, Flesch-Janys D, Heinz J, Sinn P, Vrieling A, Heikkinen T, Aittomäki K, Heikkilä P, Blomqvist C, Lissowska J, Peplonska B, Chanock S, Figueroa J, Brinton L, Hall P, Czene K, Humphreys K, Darabi H, Liu J, Van 't Veer LJ, van Leeuwen FE, Andrulis IL, Glendon G, Knight JA, Mulligan AM, O'Malley FP, Weerasooriya N, John EM, Beckmann MW, Hartmann A, Weihbrecht SB, Wachter DL, Jud SM, Loehberg CR, Baglietto L, English DR, Giles GG, McLean CA, Severi G, Lambrechts D, Vandorpe T, Weltens C, Paridaens R, Smeets A, Neven P, Wildiers H, Wang X, Olson JE, Cafourek V, Fredericksen Z, Kosel M, Vachon C, Cramp HE, Connley D, Cross SS, Balasubramanian SP, Reed MW, Dörk T, Bremer M, Meyer A, Karstens JH, Ay A, Park-Simon TW, Hillemanns P, Arias Pérez JI, Menéndez Rodríguez P, Zamora P, Benítez J, Ko YD, Fischer HP, Hamann U, Pesch B, Brüning T, Justenhoven C, Brauch H, Eccles DM, Tapper WJ, Gerty SM, Sawyer EJ, Tomlinson IP, Jones A, Kerin M, Miller N, McInerney N, Anton-Culver H, Ziogas A, Shen CY, Hsiung CN, Wu PE, Yang SL, Yu JC, Chen ST, Hsu GC, Haiman CA, Henderson BE, Le Marchand L, Kolonel LN, Lindblom A, Margolin S, Jakubowska A, Lubiński J, Huzarski T, Byrski T, Górski B, Gronwald J, Hooning MJ, Hollestelle A, van den Ouweland AM, Jager A, Kriege M, Tilanus-Linthorst MM, Collée M, Wang-Gohrke S, Pylkäs K, Jukkola-Vuorinen A, Mononen K, Grip M, Hirvikoski P, Winqvist R, Mannermaa A, Kosma VM, Kauppinen J, Kataja V, Auvinen P, Soini Y, Sironen R, Bojesen SE, Ørsted DD, Kaur-Knudsen D, Flyger H, Nordestgaard BG, Holland H, Chenevix-Trench G, Manoukian S, Barile M, Radice P, Hankinson SE, Hunter DJ, Tamimi R, Sangrajrang S, Brennan P, McKay J, Odefrey F, Gaborieau V, Devilee P, Huijts PE, Tollenaar RA, Seynaeve C, Dite GS, Apicella C, Hopper JL, Hammet F, Tsimiklis H, Smith LD, Southey MC, Humphreys MK, Easton D, Pharoah P, Sherman ME, and Garcia-Closas M

Subjects

Age Factors, Body Mass Index, Breast Neoplasms etiology, Case-Control Studies, ErbB Receptors metabolism, Female, Humans, Keratin-5 metabolism, Logistic Models, Odds Ratio, Receptor, ErbB-2 metabolism, Receptors, Estrogen metabolism, Receptors, Progesterone metabolism, Risk Factors, Biomarkers, Tumor metabolism, Breast Neoplasms metabolism, Breast Neoplasms pathology, Menarche, Obesity complications, Parity, Parturition

Abstract

Background: Previous studies have suggested that breast cancer risk factors are associated with estrogen receptor (ER) and progesterone receptor (PR) expression status of the tumors., Methods: We pooled tumor marker and epidemiological risk factor data from 35,568 invasive breast cancer case patients from 34 studies participating in the Breast Cancer Association Consortium. Logistic regression models were used in case-case analyses to estimate associations between epidemiological risk factors and tumor subtypes, and case-control analyses to estimate associations between epidemiological risk factors and the risk of developing specific tumor subtypes in 12 population-based studies. All statistical tests were two-sided., Results: In case-case analyses, of the epidemiological risk factors examined, early age at menarche (≤12 years) was less frequent in case patients with PR(-) than PR(+) tumors (P = .001). Nulliparity (P = 3 × 10(-6)) and increasing age at first birth (P = 2 × 10(-9)) were less frequent in ER(-) than in ER(+) tumors. Obesity (body mass index [BMI] ≥ 30 kg/m(2)) in younger women (≤50 years) was more frequent in ER(-)/PR(-) than in ER(+)/PR(+) tumors (P = 1 × 10(-7)), whereas obesity in older women (>50 years) was less frequent in PR(-) than in PR(+) tumors (P = 6 × 10(-4)). The triple-negative (ER(-)/PR(-)/HER2(-)) or core basal phenotype (CBP; triple-negative and cytokeratins [CK]5/6(+) and/or epidermal growth factor receptor [EGFR](+)) accounted for much of the heterogeneity in parity-related variables and BMI in younger women. Case-control analyses showed that nulliparity, increasing age at first birth, and obesity in younger women showed the expected associations with the risk of ER(+) or PR(+) tumors but not triple-negative (nulliparity vs parity, odds ratio [OR] = 0.94, 95% confidence interval [CI] = 0.75 to 1.19, P = .61; 5-year increase in age at first full-term birth, OR = 0.95, 95% CI = 0.86 to 1.05, P = .34; obesity in younger women, OR = 1.36, 95% CI = 0.95 to 1.94, P = .09) or CBP tumors., Conclusions: This study shows that reproductive factors and BMI are most clearly associated with hormone receptor-positive tumors and suggest that triple-negative or CBP tumors may have distinct etiology.

Published

2011

29. Common genetic variants associated with breast cancer and mammographic density measures that predict disease.

Author

Odefrey F, Stone J, Gurrin LC, Byrnes GB, Apicella C, Dite GS, Cawson JN, Giles GG, Treloar SA, English DR, Hopper JL, and Southey MC

Subjects

Adult, Age Factors, Aged, Breast Neoplasms pathology, Cell Count, Cross-Sectional Studies, Disease Susceptibility pathology, Female, Gene Frequency, Humans, Mammary Glands, Human anatomy & histology, Mammary Glands, Human pathology, Mammography, Middle Aged, Prognosis, Risk Factors, Siblings, Twins, Breast Neoplasms diagnosis, Breast Neoplasms genetics, Disease Susceptibility diagnosis, Mammary Glands, Human cytology, Polymorphism, Single Nucleotide

Abstract

Mammographic density for age and body mass index (BMI) is a heritable risk factor for breast cancer. We aimed to determine if recently identified common variants associated with small gradients in breast cancer risk are associated with mammographic density. We genotyped 497 monozygotic and 330 dizygotic twin pairs and 634 of their sisters from 903 families for 12 independent variants. Mammographic dense area, percent dense area, and nondense area were measured by three observers using a computer-thresholding technique. Associations with mammographic density measures adjusted for age, BMI, and other determinants were estimated (a) cross-sectionally using a multivariate normal model for pedigree analysis (P(x)), (b) between sibships, and (c) within sibships using orthogonal transformations of outcomes and exposures. A combined test of association (P(c)) was derived using the independent estimates from b and c. We tested if the distributions of P values across variants differed from the uniform distribution (P(u)). For dense area and percent dense area, the distributions of P(c) values were not uniform (both P(u) <0.007). Consistent with their breast cancer associations, rs3817198 (LSP1) and rs13281615 (8q) were associated with dense area and percent dense area (all P(x) and P(c) <0.05), and rs889312 (MAP3K1), rs2107425 (H19), and rs17468277 (CASP8) were marginally associated with dense area (some P(x) or P(c) <0.05). All associations were independent of menopausal status. At least two common breast cancer susceptibility variants are associated with mammographic density measures that predict breast cancer. These findings could help elucidate how those variants and mammographic density measures are associated with breast cancer susceptibility.

Published

2010

30. FGFR2 variants and breast cancer risk: fine-scale mapping using African American studies and analysis of chromatin conformation.

Author

Udler MS, Meyer KB, Pooley KA, Karlins E, Struewing JP, Zhang J, Doody DR, MacArthur S, Tyrer J, Pharoah PD, Luben R, Bernstein L, Kolonel LN, Henderson BE, Le Marchand L, Ursin G, Press MF, Brennan P, Sangrajrang S, Gaborieau V, Odefrey F, Shen CY, Wu PE, Wang HC, Kang D, Yoo KY, Noh DY, Ahn SH, Ponder BA, Haiman CA, Malone KE, Dunning AM, Ostrander EA, and Easton DF

Subjects

Adult, Aged, Aged, 80 and over, Breast Neoplasms ethnology, Case-Control Studies, Cell Line, Tumor, Female, Genetic Predisposition to Disease, Humans, Middle Aged, Young Adult, Black or African American genetics, Breast Neoplasms genetics, Chromatin genetics, Polymorphism, Single Nucleotide, Receptor, Fibroblast Growth Factor, Type 2 genetics

Abstract

Genome-wide association studies have identified FGFR2 as a breast cancer (BC) susceptibility gene in populations of European and Asian descent, but a causative variant has not yet been conclusively identified. We hypothesized that the weaker linkage disequilibrium across this associated region in populations of African ancestry might help refine the set of candidate-causal single nucleotide polymorphisms (SNPs) previously identified by our group. Eight candidate-causal SNPs were evaluated in 1253 African American invasive BC cases and 1245 controls. A significant association with BC risk was found with SNP rs2981578 (unadjusted per-allele odds ratio = 1.20, 95% confidence interval 1.03-1.41, P(trend) = 0.02), with the odds ratio estimate similar to that reported in European and Asian subjects. To extend the fine-mapping, genotype data from the African American studies were analyzed jointly with data from European (n = 7196 cases, 7275 controls) and Asian (n = 3901 cases, 3205 controls) studies. In the combined analysis, SNP rs2981578 was the most strongly associated. Five other SNPs were too strongly correlated to be excluded at a likelihood ratio of < 1/100 relative to rs2981578. Analysis of DNase I hypersensitive sites indicated that only two of these map to highly accessible chromatin, one of which, SNP rs2981578, has previously been implicated in up-regulating FGFR2 expression. Our results demonstrate that the association of SNPs in FGFR2 with BC risk extends to women of African American ethnicity, and illustrate the utility of combining association analysis in datasets of diverse ethnic groups with functional experiments to identify disease susceptibility variants.

Published

2009

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

Author

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

Subjects

Apoptosis Regulatory Proteins, Case-Control Studies, Chromosomes, Human, Pair 8 genetics, Female, High Mobility Group Proteins, Humans, Linkage Disequilibrium, MAP Kinase Kinase Kinase 1 genetics, Microfilament Proteins genetics, Middle Aged, Odds Ratio, Receptor, Fibroblast Growth Factor, Type 2 genetics, Receptors, Progesterone genetics, Trans-Activators, Trinucleotide Repeats, Breast Neoplasms genetics, Breast Neoplasms pathology, Genetic Predisposition to Disease, Polymorphism, Single Nucleotide

Abstract

A three-stage genome-wide association study recently identified single nucleotide polymorphisms (SNPs) in five loci (fibroblast growth receptor 2 (FGFR2), trinucleotide repeat containing 9 (TNRC9), mitogen-activated protein kinase 3 K1 (MAP3K1), 8q24, and lymphocyte-specific protein 1 (LSP1)) associated with breast cancer risk. We investigated whether the associations between these SNPs and breast cancer risk varied by clinically important tumor characteristics in up to 23,039 invasive breast cancer cases and 26,273 controls from 20 studies. We also evaluated their influence on overall survival in 13,527 cases from 13 studies. All participants were of European or Asian origin. rs2981582 in FGFR2 was more strongly related to ER-positive (per-allele OR (95%CI) = 1.31 (1.27-1.36)) than ER-negative (1.08 (1.03-1.14)) disease (P for heterogeneity = 10(-13)). This SNP was also more strongly related to PR-positive, low grade and node positive tumors (P = 10(-5), 10(-8), 0.013, respectively). The association for rs13281615 in 8q24 was stronger for ER-positive, PR-positive, and low grade tumors (P = 0.001, 0.011 and 10(-4), respectively). The differences in the associations between SNPs in FGFR2 and 8q24 and risk by ER and grade remained significant after permutation adjustment for multiple comparisons and after adjustment for other tumor characteristics. Three SNPs (rs2981582, rs3803662, and rs889312) showed weak but significant associations with ER-negative disease, the strongest association being for rs3803662 in TNRC9 (1.14 (1.09-1.21)). rs13281615 in 8q24 was associated with an improvement in survival after diagnosis (per-allele HR = 0.90 (0.83-0.97). The association was attenuated and non-significant after adjusting for known prognostic factors. Our findings show that common genetic variants influence the pathological subtype of breast cancer and provide further support for the hypothesis that ER-positive and ER-negative disease are biologically distinct. Understanding the etiologic heterogeneity of breast cancer may ultimately result in improvements in prevention, early detection, and treatment., Competing Interests: The authors have declared that no competing interests exist.

Published

2008

32. Uncommon CHEK2 mis-sense variant and reduced risk of tobacco-related cancers: case control study.

Author

Brennan P, McKay J, Moore L, Zaridze D, Mukeria A, Szeszenia-Dabrowska N, Lissowska J, Rudnai P, Fabianova E, Mates D, Bencko V, Foretova L, Janout V, Chow WH, Rothman N, Chabrier A, Gaborieau V, Odefrey F, Southey M, Hashibe M, Hall J, Boffetta P, Peto J, Peto R, and Hung RJ

Subjects

Adult, Aged, Apoptosis, Case-Control Studies, Checkpoint Kinase 2, Female, Humans, Male, Middle Aged, Protein Serine-Threonine Kinases metabolism, Risk Factors, Stem Cells metabolism, Carcinoma, Squamous Cell genetics, Kidney Neoplasms genetics, Lung Neoplasms genetics, Mutation, Missense, Polymorphism, Single Nucleotide, Protein Serine-Threonine Kinases genetics, Smoking adverse effects

Abstract

CHEK2 is a key cell cycle control gene encoding a pluripotent kinase that can cause arrest or apoptosis in response to unrepaired DNA damage. We report a large case-control study of a non-functional variant that had previously been expected to increase cancer rates. Four thousand and fifteen cancer patients (2250 lung, 811 squamous upper aero-digestive and 954 kidney) and 3052 controls in central Europe were genotyped for the mis-sense variant rs17879961 (replacement of T by C), which changes an amino acid (I157T) in an active site of the gene product. The heterozygous (T/C) genotype was associated with a highly significantly lower incidence of lung cancer than the common T/T genotype [relative risk (RR), T/C versus T/T, 0.44, with 95% confidence interval (CI) 0.31-0.63, P < 0.00001] and with a significantly lower incidence of upper aero-digestive cancer (RR 0.44, CI 0.26-0.73, P = 0.001; P = 0.000001 for lung or upper aero-digestive cancer). Protection was significantly greater for squamous than adenomatous lung cancer (P = 0.001). There was an increase of borderline significance in kidney cancer (RR 1.44, CI 0.99-2.00, P = 0.06). This unexpected halving of tobacco-related cancer (since replicated independently) implies much greater absolute risk reduction in smokers than in non-smokers. The mechanism is unknown: perhaps squamous stem cell apoptosis following smoke exposure causes net harm (e.g. by forcing nearby stem cells to divide before they have repaired their own DNA damage from tobacco smoke). If so, reducing the rate of apoptosis by reducing CHEK2 activity could be protective-although not smoking would be far more so.

Published

2007

33. Genome-wide association study identifies novel breast cancer susceptibility loci.

Author

Easton DF, Pooley KA, Dunning AM, Pharoah PD, Thompson D, Ballinger DG, Struewing JP, Morrison J, Field H, Luben R, Wareham N, Ahmed S, Healey CS, Bowman R, Meyer KB, Haiman CA, Kolonel LK, Henderson BE, Le Marchand L, Brennan P, Sangrajrang S, Gaborieau V, Odefrey F, Shen CY, Wu PE, Wang HC, Eccles D, Evans DG, Peto J, Fletcher O, Johnson N, Seal S, Stratton MR, Rahman N, Chenevix-Trench G, Bojesen SE, Nordestgaard BG, Axelsson CK, Garcia-Closas M, Brinton L, Chanock S, Lissowska J, Peplonska B, Nevanlinna H, Fagerholm R, Eerola H, Kang D, Yoo KY, Noh DY, Ahn SH, Hunter DJ, Hankinson SE, Cox DG, Hall P, Wedren S, Liu J, Low YL, Bogdanova N, Schürmann P, Dörk T, Tollenaar RA, Jacobi CE, Devilee P, Klijn JG, Sigurdson AJ, Doody MM, Alexander BH, Zhang J, Cox A, Brock IW, MacPherson G, Reed MW, Couch FJ, Goode EL, Olson JE, Meijers-Heijboer H, van den Ouweland A, Uitterlinden A, Rivadeneira F, Milne RL, Ribas G, Gonzalez-Neira A, Benitez J, Hopper JL, McCredie M, Southey M, Giles GG, Schroen C, Justenhoven C, Brauch H, Hamann U, Ko YD, Spurdle AB, Beesley J, Chen X, Mannermaa A, Kosma VM, Kataja V, Hartikainen J, Day NE, Cox DR, and Ponder BA

Subjects

Alleles, Apoptosis Regulatory Proteins, Asia, Southeastern, Australia, Case-Control Studies, Europe ethnology, Female, Genotype, High Mobility Group Proteins, Humans, MAP Kinase Kinase Kinase 1 genetics, Microfilament Proteins genetics, North America, Odds Ratio, Polymorphism, Single Nucleotide genetics, Receptor, Fibroblast Growth Factor, Type 2 genetics, Receptors, Progesterone genetics, Trans-Activators, Breast Neoplasms genetics, Genetic Predisposition to Disease genetics, Genome, Human genetics

Abstract

Breast cancer exhibits familial aggregation, consistent with variation in genetic susceptibility to the disease. Known susceptibility genes account for less than 25% of the familial risk of breast cancer, and the residual genetic variance is likely to be due to variants conferring more moderate risks. To identify further susceptibility alleles, we conducted a two-stage genome-wide association study in 4,398 breast cancer cases and 4,316 controls, followed by a third stage in which 30 single nucleotide polymorphisms (SNPs) were tested for confirmation in 21,860 cases and 22,578 controls from 22 studies. We used 227,876 SNPs that were estimated to correlate with 77% of known common SNPs in Europeans at r2 > 0.5. SNPs in five novel independent loci exhibited strong and consistent evidence of association with breast cancer (P < 10(-7)). Four of these contain plausible causative genes (FGFR2, TNRC9, MAP3K1 and LSP1). At the second stage, 1,792 SNPs were significant at the P < 0.05 level compared with an estimated 1,343 that would be expected by chance, indicating that many additional common susceptibility alleles may be identifiable by this approach.

Published

2007

34. A common coding variant in CASP8 is associated with breast cancer risk.

Author

Cox A, Dunning AM, Garcia-Closas M, Balasubramanian S, Reed MW, Pooley KA, Scollen S, Baynes C, Ponder BA, Chanock S, Lissowska J, Brinton L, Peplonska B, Southey MC, Hopper JL, McCredie MR, Giles GG, Fletcher O, Johnson N, dos Santos Silva I, Gibson L, Bojesen SE, Nordestgaard BG, Axelsson CK, Torres D, Hamann U, Justenhoven C, Brauch H, Chang-Claude J, Kropp S, Risch A, Wang-Gohrke S, Schürmann P, Bogdanova N, Dörk T, Fagerholm R, Aaltonen K, Blomqvist C, Nevanlinna H, Seal S, Renwick A, Stratton MR, Rahman N, Sangrajrang S, Hughes D, Odefrey F, Brennan P, Spurdle AB, Chenevix-Trench G, Beesley J, Mannermaa A, Hartikainen J, Kataja V, Kosma VM, Couch FJ, Olson JE, Goode EL, Broeks A, Schmidt MK, Hogervorst FB, Van't Veer LJ, Kang D, Yoo KY, Noh DY, Ahn SH, Wedrén S, Hall P, Low YL, Liu J, Milne RL, Ribas G, Gonzalez-Neira A, Benitez J, Sigurdson AJ, Stredrick DL, Alexander BH, Struewing JP, Pharoah PD, and Easton DF

Subjects

Adult, Aged, Case-Control Studies, Cohort Studies, Female, Genetic Variation, Genotype, Humans, Middle Aged, Polymorphism, Single Nucleotide, Risk Factors, Breast Neoplasms genetics, Caspase 8 genetics, Genetic Predisposition to Disease

Abstract

The Breast Cancer Association Consortium (BCAC) has been established to conduct combined case-control analyses with augmented statistical power to try to confirm putative genetic associations with breast cancer. We genotyped nine SNPs for which there was some prior evidence of an association with breast cancer: CASP8 D302H (rs1045485), IGFBP3 -202 C --> A (rs2854744), SOD2 V16A (rs1799725), TGFB1 L10P (rs1982073), ATM S49C (rs1800054), ADH1B 3' UTR A --> G (rs1042026), CDKN1A S31R (rs1801270), ICAM5 V301I (rs1056538) and NUMA1 A794G (rs3750913). We included data from 9-15 studies, comprising 11,391-18,290 cases and 14,753-22,670 controls. We found evidence of an association with breast cancer for CASP8 D302H (with odds ratios (OR) of 0.89 (95% confidence interval (c.i.): 0.85-0.94) and 0.74 (95% c.i.: 0.62-0.87) for heterozygotes and rare homozygotes, respectively, compared with common homozygotes; P(trend) = 1.1 x 10(-7)) and weaker evidence for TGFB1 L10P (OR = 1.07 (95% c.i.: 1.02-1.13) and 1.16 (95% c.i.: 1.08-1.25), respectively; P(trend) = 2.8 x 10(-5)). These results demonstrate that common breast cancer susceptibility alleles with small effects on risk can be identified, given sufficiently powerful studies.

Published

2007

35. A genome wide linkage search for breast cancer susceptibility genes.

Author

Smith P, McGuffog L, Easton DF, Mann GJ, Pupo GM, Newman B, Chenevix-Trench G, Szabo C, Southey M, Renard H, Odefrey F, Lynch H, Stoppa-Lyonnet D, Couch F, Hopper JL, Giles GG, McCredie MR, Buys S, Andrulis I, Senie R, Goldgar DE, Oldenburg R, Kroeze-Jansema K, Kraan J, Meijers-Heijboer H, Klijn JG, van Asperen C, van Leeuwen I, Vasen HF, Cornelisse CJ, Devilee P, Baskcomb L, Seal S, Barfoot R, Mangion J, Hall A, Edkins S, Rapley E, Wooster R, Chang-Claude J, Eccles D, Evans DG, Futreal P, Nathanson KL, Weber BL, Rahman N, and Stratton MR

Subjects

Female, Genes, BRCA1, Genes, BRCA2, Genetic Testing, Humans, Lod Score, Male, Models, Statistical, Breast Neoplasms genetics, Genetic Linkage, Genetic Predisposition to Disease, Genome, Human

Abstract

Mutations in known breast cancer susceptibility genes account for a minority of the familial aggregation of the disease. To search for further breast cancer susceptibility genes, we performed a combined analysis of four genome-wide linkage screens, which included a total of 149 multiple case breast cancer families. All families included at least three cases of breast cancer diagnosed below age 60 years, at least one of whom had been tested and found not to carry a BRCA1 or BRCA2 mutation. Evidence for linkage was assessed using parametric linkage analysis, assuming both a dominant and a recessive mode of inheritance, and using nonparametric methods. The highest LOD score obtained in any analysis of the combined data was 1.80 under the dominant model, in a region on chromosome 4 close to marker D4S392. Three further LOD scores over 1 were identified in the parametric analyses and two in the nonparametric analyses. A maximum LOD score of 2.40 was found on chromosome arm 2p in families with four or more cases of breast cancer diagnosed below age 50 years. The number of linkage peaks did not differ from the number expected by chance. These results suggest regions that may harbor novel breast cancer susceptibility genes. They also indicate that no single gene is likely to account for a large fraction of the familial aggregation of breast cancer that is not due to mutations in BRCA1 or BRCA2., ((c) 2006 Wiley-Liss, Inc.)

Published

2006

36. Haplotype analysis of the BRCA2 9254delATCAT recurrent mutation in breast/ovarian cancer families from Spain.

Author

Campos B, Díez O, Odefrey F, Domènech M, Moncoutier V, Martínez-Ferrandis JI, Osorio A, Balmaña J, Barroso A, Armengod ME, Benítez J, Alonso C, Stoppa-Lyonnet D, Goldgar D, and Baiget M

Subjects

Adult, Aged, Aged, 80 and over, BRCA2 Protein genetics, Breast Neoplasms diagnosis, Breast Neoplasms epidemiology, Breast Neoplasms, Male epidemiology, Female, Founder Effect, Genotype, Humans, Male, Middle Aged, Ovarian Neoplasms diagnosis, Ovarian Neoplasms epidemiology, Phenotype, Recurrence, Spain epidemiology, Breast Neoplasms genetics, Breast Neoplasms, Male genetics, Genes, BRCA2, Haplotypes genetics, Mutation, Ovarian Neoplasms genetics

Abstract

A frame-shift 9254del5 mutation was independently identified in 12 families, eleven of them with Spanish ancestors, in a BRCA2 screening performed in 841 breast and/or ovarian cancer families and in 339 women with breast cancer diagnosed before the age of 40 at different centers in France and Spain. We sought to analyze in detail the haplotype and founder effects of the 9254del5 and to estimate the time of origin of the mutation. Eight polymorphic microsatellite markers and two BRCA2 polymorphisms were used for the haplotype analyses. The markers were located flanking the BRCA2 gene spanning a region of 6.1 cM. Our results suggest that these families shared a common ancestry with BRCA2 9254del5, which is a founder mutation originating in the Northeast Spanish, with an estimated age of 92 (95% CI 56-141) generations., (Copyright 2003 Wiley-Liss, Inc.)

Published

2003

37. Evaluation of linkage of breast cancer to the putative BRCA3 locus on chromosome 13q21 in 128 multiple case families from the Breast Cancer Linkage Consortium.

Author

Thompson D, Szabo CI, Mangion J, Oldenburg RA, Odefrey F, Seal S, Barfoot R, Kroeze-Jansema K, Teare D, Rahman N, Renard H, Mann G, Hopper JL, Buys SS, Andrulis IL, Senie R, Daly MB, West D, Ostrander EA, Offit K, Peretz T, Osorio A, Benitez J, Nathanson KL, Sinilnikova OM, Olàh E, Bignon YJ, Ruiz P, Badzioch MD, Vasen HF, Futreal AP, Phelan CM, Narod SA, Lynch HT, Ponder BA, Eeles RA, Meijers-Heijboer H, Stoppa-Lyonnet D, Couch FJ, Eccles DM, Evans DG, Chang-Claude J, Lenoir G, Weber BL, Devilee P, Easton DF, Goldgar DE, and Stratton MR

Subjects

Australia, Europe, Female, Humans, Lod Score, North America, Breast Neoplasms genetics, Chromosomes, Human, Pair 13 genetics, Genes, Tumor Suppressor, Genetic Linkage

Abstract

The known susceptibility genes for breast cancer, including BRCA1 and BRCA2, only account for a minority of the familial aggregation of the disease. A recent study of 77 multiple case breast cancer families from Scandinavia found evidence of linkage between the disease and polymorphic markers on chromosome 13q21. We have evaluated the contribution of this candidate "BRCA3" locus to breast cancer susceptibility in 128 high-risk breast cancer families of Western European ancestry with no identified BRCA1 or BRCA2 mutations. No evidence of linkage was found. The estimated proportion (alpha) of families linked to a susceptibility locus at D13S1308, the location estimated by Kainu et al. [(2000) Proc. Natl. Acad. Sci. USA 97, 9603-9608], was 0 (upper 95% confidence limit 0.13). Adjustment for possible bias due to selection of families on the basis of linkage evidence at BRCA2 did not materially alter this result (alpha = 0, upper 95% confidence limit 0.18). The proportion of linked families reported by Kainu et al. (0.65) is excluded with a high degree of confidence in our dataset [heterogeneity logarithm of odds (HLOD) at alpha = 0.65 was -11.0]. We conclude that, if a susceptibility gene does exist at this locus, it can only account for a small proportion of non-BRCA1/2 families with multiple cases of early-onset breast cancer.

Published

2002