Medicine (RMH) - Research Publications

Permanent URI for this collection

http://hdl.handle.net/11343/193

Filters

2011 - 2019 24 2020 - 2023 6
30
Reset filters

Settings
Statistics
Citations
Author: Winship, Ingrid × Author: Giles, Graham × Author: Jenkins, Mark ×

Search Results

Now showing 1 - 10 of 30
  • Item
    No Preview Available
    Elucidating the Risk of Colorectal Cancer for Variants in Hereditary Colorectal Cancer Genes
    Mahmood, K ; Thomas, M ; Qu, C ; Hsu, L ; Buchanan, DD ; Peters, U (W B SAUNDERS CO-ELSEVIER INC, 2023-10)
  • Item
    Thumbnail Image
    Identifying colorectal cancer caused by biallelic MUTYH pathogenic variants using tumor mutational signatures
    Georgeson, P ; Harrison, TA ; Pope, BJ ; Zaidi, SH ; Qu, C ; Steinfelder, RS ; Lin, Y ; Joo, JE ; Mahmood, K ; Clendenning, M ; Walker, R ; Amitay, EL ; Berndt, S ; Brenner, H ; Campbell, PT ; Cao, Y ; Chan, AT ; Chang-Claude, J ; Doheny, KF ; Drew, DA ; Figueiredo, JC ; French, AJ ; Gallinger, S ; Giannakis, M ; Giles, GG ; Gsur, A ; Gunter, MJ ; Hoffmeister, M ; Hsu, L ; Huang, W-Y ; Limburg, P ; Manson, JE ; Moreno, V ; Nassir, R ; Nowak, JA ; Obon-Santacana, M ; Ogino, S ; Phipps, A ; Potter, JD ; Schoen, RE ; Sun, W ; Toland, AE ; Trinh, QM ; Ugai, T ; Macrae, FA ; Rosty, C ; Hudson, TJ ; Jenkins, MA ; Thibodeau, SN ; Winship, IM ; Peters, U ; Buchanan, DD (NATURE PORTFOLIO, 2022-06-06)
    Carriers of germline biallelic pathogenic variants in the MUTYH gene have a high risk of colorectal cancer. We test 5649 colorectal cancers to evaluate the discriminatory potential of a tumor mutational signature specific to MUTYH for identifying biallelic carriers and classifying variants of uncertain clinical significance (VUS). Using a tumor and matched germline targeted multi-gene panel approach, our classifier identifies all biallelic MUTYH carriers and all known non-carriers in an independent test set of 3019 colorectal cancers (accuracy = 100% (95% confidence interval 99.87-100%)). All monoallelic MUTYH carriers are classified with the non-MUTYH carriers. The classifier provides evidence for a pathogenic classification for two VUS and a benign classification for five VUS. Somatic hotspot mutations KRAS p.G12C and PIK3CA p.Q546K are associated with colorectal cancers from biallelic MUTYH carriers compared with non-carriers (p = 2 × 10-23 and p = 6 × 10-11, respectively). Here, we demonstrate the potential application of mutational signatures to tumor sequencing workflows to improve the identification of biallelic MUTYH carriers.
  • Item
    Thumbnail Image
    Mendelian randomisation study of smoking exposure in relation to breast cancer risk
    Park, HA ; Neumeyer, S ; Michailidou, K ; Bolla, MK ; Wang, Q ; Dennis, J ; Ahearn, TU ; Andrulis, IL ; Anton-Culver, H ; Antonenkova, NN ; Arndt, V ; Aronson, KJ ; Augustinsson, A ; Baten, A ; Freeman, LEB ; Becher, H ; Beckmann, MW ; Behrens, S ; Benitez, J ; Bermisheva, M ; Bogdanova, N ; Bojesen, SE ; Brauch, H ; Brenner, H ; Brucker, SY ; Burwinkel, B ; Campa, D ; Canzian, F ; Castelao, JE ; Chanock, SJ ; Chenevix-Trench, G ; Clarke, CL ; Conroy, DM ; Couch, FJ ; Cox, A ; Cross, SS ; Czene, K ; Daly, MB ; Devilee, P ; Dork, T ; Dos-Santos-Silva, I ; Dwek, M ; Eccles, DM ; Eliassen, AH ; Engel, C ; Eriksson, M ; Evans, DG ; Fasching, PA ; Flyger, H ; Fritschi, L ; Garcia-Closas, M ; Garcia-Saenz, JA ; Gaudet, MM ; Giles, GG ; Glendon, G ; Goldberg, MS ; Goldgar, DE ; Gonzalez-Neira, A ; Grip, M ; Guenel, P ; Hahnen, E ; Haiman, CA ; Hakansson, N ; Hall, P ; Hamann, U ; Han, S ; Harkness, EF ; Hart, SN ; He, W ; Heemskerk-Gerritsen, BAM ; Hopper, JL ; Hunter, DJ ; Jager, A ; Jakubowska, A ; John, EM ; Jung, A ; Kaaks, R ; Kapoor, PM ; Keeman, R ; Khusnutdinova, E ; Kitahara, CM ; Koppert, LB ; Koutros, S ; Kristensen, VN ; Kurian, AW ; Lacey, J ; Lambrechts, D ; LeMarchand, L ; Lo, W-Y ; Mannermaa, A ; Manoochehri, M ; Margolin, S ; ElenaMartinez, M ; Mavroudis, D ; Meindl, A ; Menon, U ; Milne, RL ; Muranen, TA ; Nevanlinna, H ; Newman, WG ; Nordestgaard, BG ; Offit, K ; Olshan, AF ; Olsson, H ; Park-Simon, T-W ; Peterlongo, P ; Peto, J ; Plaseska-Karanfilska, D ; Presneau, N ; Radice, P ; Rennert, G ; Rennert, HS ; Romero, A ; Saloustros, E ; Sawyer, EJ ; Schmidt, MK ; Schmutzler, RK ; Schoemaker, MJ ; Schwentner, L ; Scott, C ; Shah, M ; Shu, X-O ; Simard, J ; Smeets, A ; Southey, MC ; Spinelli, JJ ; Stevens, V ; Swerdlow, AJ ; Tamimi, RM ; Tapper, WJ ; Taylor, JA ; Terry, MB ; Tomlinson, I ; Troester, MA ; Truong, T ; Vachon, CM ; van Veen, EM ; Vijai, J ; Wang, S ; Wendt, C ; Winqvist, R ; Wolk, A ; Ziogas, A ; Dunning, AM ; Pharoah, PDP ; Easton, DF ; Zheng, W ; Kraft, P ; Chang-Claude, J (SPRINGERNATURE, 2021-10-12)
    BACKGROUND: Despite a modest association between tobacco smoking and breast cancer risk reported by recent epidemiological studies, it is still equivocal whether smoking is causally related to breast cancer risk. METHODS: We applied Mendelian randomisation (MR) to evaluate a potential causal effect of cigarette smoking on breast cancer risk. Both individual-level data as well as summary statistics for 164 single-nucleotide polymorphisms (SNPs) reported in genome-wide association studies of lifetime smoking index (LSI) or cigarette per day (CPD) were used to obtain MR effect estimates. Data from 108,420 invasive breast cancer cases and 87,681 controls were used for the LSI analysis and for the CPD analysis conducted among ever-smokers from 26,147 cancer cases and 26,072 controls. Sensitivity analyses were conducted to address pleiotropy. RESULTS: Genetically predicted LSI was associated with increased breast cancer risk (OR 1.18 per SD, 95% CI: 1.07-1.30, P = 0.11 × 10-2), but there was no evidence of association for genetically predicted CPD (OR 1.02, 95% CI: 0.78-1.19, P = 0.85). The sensitivity analyses yielded similar results and showed no strong evidence of pleiotropic effect. CONCLUSION: Our MR study provides supportive evidence for a potential causal association with breast cancer risk for lifetime smoking exposure but not cigarettes per day among smokers.
  • Item
    Thumbnail Image
    DNA Methylation Signatures and the Contribution of Age-Associated Methylomic Drift to Carcinogenesis in Early-Onset Colorectal Cancer
    Joo, JE ; Clendenning, M ; Wong, EM ; Rosty, C ; Mahmood, K ; Georgeson, P ; Winship, IM ; Preston, SG ; Win, AK ; Dugue, P-A ; Jayasekara, H ; English, D ; Macrae, FA ; Hopper, JL ; Jenkins, MA ; Milne, RL ; Giles, GG ; Southey, MC ; Buchanan, DD (MDPI, 2021-06)
    We investigated aberrant DNA methylation (DNAm) changes and the contribution of ageing-associated methylomic drift and age acceleration to early-onset colorectal cancer (EOCRC) carcinogenesis. Genome-wide DNAm profiling using the Infinium HM450K on 97 EOCRC tumour and 54 normal colonic mucosa samples was compared with: (1) intermediate-onset CRC (IOCRC; diagnosed between 50-70 years; 343 tumour and 35 normal); and (2) late-onset CRC (LOCRC; >70 years; 318 tumour and 40 normal). CpGs associated with age-related methylation drift were identified using a public dataset of 231 normal mucosa samples from people without CRC. DNAm-age was estimated using epiTOC2. Common to all three age-of-onset groups, 88,385 (20% of all CpGs) CpGs were differentially methylated between tumour and normal mucosa. We identified 234 differentially methylated genes that were unique to the EOCRC group; 13 of these DMRs/genes were replicated in EOCRC compared with LOCRCs from TCGA. In normal mucosa from people without CRC, we identified 28,154 CpGs that undergo ageing-related DNAm drift, and of those, 65% were aberrantly methylated in EOCRC tumours. Based on the mitotic-based DNAm clock epiTOC2, we identified age acceleration in normal mucosa of people with EOCRC compared with normal mucosa from the IOCRC, LOCRC groups (p = 3.7 × 10-16) and young people without CRC (p = 5.8 × 10-6). EOCRC acquires unique DNAm alterations at 234 loci. CpGs associated with ageing-associated drift were widely affected in EOCRC without needing the decades-long accrual of DNAm drift as commonly seen in intermediate- and late-onset CRCs. Accelerated ageing in normal mucosa from people with EOCRC potentially underlies the earlier age of diagnosis in CRC carcinogenesis.
  • Item
    Thumbnail Image
    CYP3A7*1C allele: linking premenopausal oestrone and progesterone levels with risk of hormone receptor-positive breast cancers
    Johnson, N ; Maguire, S ; Morra, A ; Kapoor, PM ; Tomczyk, K ; Jones, ME ; Schoemaker, MJ ; Gilham, C ; Bolla, MK ; Wang, Q ; Dennis, J ; Ahearn, TU ; Andrulis, IL ; Anton-Culver, H ; Antonenkova, NN ; Arndt, V ; Aronson, KJ ; Augustinsson, A ; Baynes, C ; Freeman, LEB ; Beckmann, MW ; Benitez, J ; Bermisheva, M ; Blomqvist, C ; Boeckx, B ; Bogdanova, NV ; Bojesen, SE ; Brauch, H ; Brenner, H ; Burwinkel, B ; Campa, D ; Canzian, F ; Castelao, JE ; Chanock, SJ ; Chenevix-Trench, G ; Clarke, CL ; Conroy, DM ; Couch, FJ ; Cox, A ; Cross, SS ; Czene, K ; Doerk, T ; Eliassen, AH ; Engel, C ; Evans, DG ; Fasching, PA ; Figueroa, J ; Floris, G ; Flyger, H ; Gago-Dominguez, M ; Gapstur, SM ; Garcia-Closas, M ; Gaudet, MM ; Giles, GG ; Goldberg, MS ; Gonzalez-Neira, A ; Guenel, P ; Hahnen, E ; Haiman, CA ; Hakansson, N ; Hall, P ; Hamann, U ; Harrington, PA ; Hart, SN ; Hooning, MJ ; Hopper, JL ; Howell, A ; Hunter, DJ ; Jager, A ; Jakubowska, A ; John, EM ; Kaaks, R ; Keeman, R ; Khusnutdinova, E ; Kitahara, CM ; Kosma, V-M ; Koutros, S ; Kraft, P ; Kristensen, VN ; Kurian, AW ; Lambrechts, D ; Le Marchand, L ; Linet, M ; Lubinski, J ; Mannermaa, A ; Manoukian, S ; Margolin, S ; Martens, JWM ; Mavroudis, D ; Mayes, R ; Meindl, A ; Milne, RL ; Neuhausen, SL ; Nevanlinna, H ; Newman, WG ; Nielsen, SF ; Nordestgaard, BG ; Obi, N ; Olshan, AF ; Olson, JE ; Olsson, H ; Orban, E ; Park-Simon, T-W ; Peterlongo, P ; Plaseska-Karanfilska, D ; Pylkas, K ; Rennert, G ; Rennert, HS ; Ruddy, KJ ; Saloustros, E ; Sandler, DP ; Sawyer, EJ ; Schmutzler, RK ; Scott, C ; Shu, X-O ; Simard, J ; Smichkoska, S ; Sohn, C ; Southey, MC ; Spinelli, JJ ; Stone, J ; Tamimi, RM ; Taylor, JA ; Tollenaar, RAEM ; Tomlinson, I ; Troester, MA ; Truong, T ; Vachon, CM ; van Veen, EM ; Wang, SS ; Weinberg, CR ; Wendt, C ; Wildiers, H ; Winqvist, R ; Wolk, A ; Zheng, W ; Ziogas, A ; Dunning, AM ; Pharoah, PDP ; Easton, DF ; Howie, AF ; Peto, J ; dos-Santos-Silva, I ; Swerdlow, AJ ; Chang-Claude, J ; Schmidt, MK ; Orr, N ; Fletcher, O (SPRINGERNATURE, 2021-02-16)
    BACKGROUND: Epidemiological studies provide strong evidence for a role of endogenous sex hormones in the aetiology of breast cancer. The aim of this analysis was to identify genetic variants that are associated with urinary sex-hormone levels and breast cancer risk. METHODS: We carried out a genome-wide association study of urinary oestrone-3-glucuronide and pregnanediol-3-glucuronide levels in 560 premenopausal women, with additional analysis of progesterone levels in 298 premenopausal women. To test for the association with breast cancer risk, we carried out follow-up genotyping in 90,916 cases and 89,893 controls from the Breast Cancer Association Consortium. All women were of European ancestry. RESULTS: For pregnanediol-3-glucuronide, there were no genome-wide significant associations; for oestrone-3-glucuronide, we identified a single peak mapping to the CYP3A locus, annotated by rs45446698. The minor rs45446698-C allele was associated with lower oestrone-3-glucuronide (-49.2%, 95% CI -56.1% to -41.1%, P = 3.1 × 10-18); in follow-up analyses, rs45446698-C was also associated with lower progesterone (-26.7%, 95% CI -39.4% to -11.6%, P = 0.001) and reduced risk of oestrogen and progesterone receptor-positive breast cancer (OR = 0.86, 95% CI 0.82-0.91, P = 6.9 × 10-8). CONCLUSIONS: The CYP3A7*1C allele is associated with reduced risk of hormone receptor-positive breast cancer possibly mediated via an effect on the metabolism of endogenous sex hormones in premenopausal women.
  • Item
    Thumbnail Image
    Morphological predictors of BRCA1 germline mutations in young women with breast cancer
    Southey, MC ; Ramus, SJ ; Dowty, JG ; Smith, LD ; Tesoriero, AA ; Wong, EEM ; Dite, GS ; Jenkins, MA ; Byrnes, GB ; Winship, I ; Phillips, K-A ; Giles, GG ; Hopper, JL (NATURE PUBLISHING GROUP, 2011-03-15)
    BACKGROUND: Knowing a young woman with newly diagnosed breast cancer has a germline BRCA1 mutation informs her clinical management and that of her relatives. We sought an optimal strategy for identifying carriers using family history, breast cancer morphology and hormone receptor status data. METHODS: We studied a population-based sample of 452 Australian women with invasive breast cancer diagnosed before age 40 years for whom we conducted extensive germline mutation testing (29 carried a BRCA1 mutation) and a systematic pathology review, and collected three-generational family history and tumour ER and PR status. Predictors of mutation status were identified using multiple logistic regression. Areas under receiver operator characteristic (ROC) curves were estimated using five-fold stratified cross-validation. RESULTS: The probability of being a BRCA1 mutation carrier increased with number of selected histology features even after adjusting for family history and ER and PR status (P<0.0001). From the most parsimonious multivariate model, the odds ratio for being a carrier were: 9.7 (95% confidence interval: 2.6-47.0) for trabecular growth pattern (P=0.001); 7.8 (2.7-25.7) for mitotic index over 50 mitoses per 10 high-powered field (P=0.0003); and 2.7 (1.3-5.9) for each first-degree relative with breast cancer diagnosed before age 60 years (P=0.01).The area under the ROC curve was 0.87 (0.83-0.90). CONCLUSION: Pathology review, with attention to a few specific morphological features of invasive breast cancers, can identify almost all BRCA1 germline mutation carriers among women with early-onset breast cancer without taking into account family history.
  • Item
    No Preview Available
    Fine-mapping of 150 breast cancer risk regions identifies 191 likely target genes
    Fachal, L ; Aschard, H ; Beesley, J ; Barnes, DR ; Allen, J ; Kar, S ; Pooley, KA ; Dennis, J ; Michailidou, K ; Turman, C ; Soucy, P ; Lemacon, A ; Lush, M ; Tyrer, JP ; Ghoussaini, M ; Marjaneh, MM ; Jiang, X ; Agata, S ; Aittomaki, K ; Rosario Alonso, M ; Andrulis, IL ; Anton-Culver, H ; Antonenkova, NN ; Arason, A ; Arndt, V ; Aronson, KJ ; Arun, BK ; Auber, B ; Auer, PL ; Azzollini, J ; Balmana, J ; Barkardottir, RB ; Barrowdale, D ; Beeghly-Fadiel, A ; Benitez, J ; Bermisheva, M ; Bialkowska, K ; Blanco, AM ; Blomqvist, C ; Blot, W ; Bogdanova, N ; Bojesen, SE ; Bolla, MK ; Bonanni, B ; Borg, A ; Bosse, K ; Brauch, H ; Brenner, H ; Briceno, I ; Brock, IW ; Brooks-Wilson, A ; Bruening, T ; Burwinkel, B ; Buys, SS ; Cai, Q ; Caldes, T ; Caligo, MA ; Camp, NJ ; Campbell, I ; Canzian, F ; Carroll, JS ; Carter, BD ; Castelao, JE ; Chiquette, J ; Christiansen, H ; Chung, WK ; Claes, KBM ; Clarke, CL ; Collee, JM ; Cornelissen, S ; Couch, FJ ; Cox, A ; Cross, SS ; Cybulski, C ; Czene, K ; Daly, MB ; de la Hoya, M ; Devilee, P ; Diez, O ; Ding, YC ; Dite, GS ; Domchek, SM ; Doerk, T ; dos-Santos-Silva, I ; Droit, A ; Dubois, S ; Dumont, M ; Duran, M ; Durcan, L ; Dwek, M ; Eccles, DM ; Engel, C ; Eriksson, M ; Evans, DG ; Fasching, PA ; Fletcher, O ; Floris, G ; Flyger, H ; Foretova, L ; Foulkes, WD ; Friedman, E ; Fritschi, L ; Frost, D ; Gabrielson, M ; Gago-Dominguez, M ; Gambino, G ; Ganz, PA ; Gapstur, SM ; Garber, J ; Garcia-Saenz, JA ; Gaudet, MM ; Georgoulias, V ; Giles, GG ; Glendon, G ; Godwin, AK ; Goldberg, MS ; Goldgar, DE ; Gonzalez-Neira, A ; Tibiletti, MG ; Greene, MH ; Grip, M ; Gronwald, J ; Grundy, A ; Guenel, P ; Hahnen, E ; Haiman, CA ; Hakansson, N ; Hall, P ; Hamann, U ; Harrington, PA ; Hartikainen, JM ; Hartman, M ; He, W ; Healey, CS ; Heemskerk-Gerritsen, BAM ; Heyworth, J ; Hillemanns, P ; Hogervorst, FBL ; Hollestelle, A ; Hooning, MJ ; Hopper, JL ; Howell, A ; Huang, G ; Hulick, PJ ; Imyanitov, EN ; Isaacs, C ; Iwasaki, M ; Jager, A ; Jakimovska, M ; Jakubowska, A ; James, PA ; Janavicius, R ; Jankowitz, RC ; John, EM ; Johnson, N ; Jones, ME ; Jukkola-Vuorinen, A ; Jung, A ; Kaaks, R ; Kang, D ; Kapoor, PM ; Karlan, BY ; Keeman, R ; Kerin, MJ ; Khusnutdinova, E ; Kiiski, J ; Kirk, J ; Kitahara, CM ; Ko, Y-D ; Konstantopoulou, I ; Kosma, V-M ; Koutros, S ; Kubelka-Sabit, K ; Kwong, A ; Kyriacou, K ; Laitman, Y ; Lambrechts, D ; Lee, E ; Leslie, G ; Lester, J ; Lesueur, F ; Lindblom, A ; Lo, W-Y ; Long, J ; Lophatananon, A ; Loud, JT ; Lubinski, J ; MacInnis, RJ ; Maishman, T ; Makalic, E ; Mannermaa, A ; Manoochehri, M ; Manoukian, S ; Margolin, S ; Martinez, ME ; Matsuo, K ; Maurer, T ; Mavroudis, D ; Mayes, R ; McGuffog, L ; McLean, C ; Mebirouk, N ; Meindl, A ; Miller, A ; Miller, N ; Montagna, M ; Moreno, F ; Muir, K ; Mulligan, AM ; Munoz-Garzon, VM ; Muranen, TA ; Narod, SA ; Nassir, R ; Nathanson, KL ; Neuhausen, SL ; Nevanlinna, H ; Neven, P ; Nielsen, FC ; Nikitina-Zake, L ; Norman, A ; Offit, K ; Olah, E ; Olopade, O ; Olsson, H ; Orr, N ; Osorio, A ; Pankratz, VS ; Papp, J ; Park, SK ; Park-Simon, T-W ; Parsons, MT ; Paul, J ; Pedersen, IS ; Peissel, B ; Peshkin, B ; Peterlongo, P ; Peto, J ; Plaseska-Karanfilska, D ; Prajzendanc, K ; Prentice, R ; Presneau, N ; Prokofyeva, D ; Angel Pujana, M ; Pylkas, K ; Radice, P ; Ramus, SJ ; Rantala, J ; Rau-Murthy, R ; Rennert, G ; Risch, HA ; Robson, M ; Romero, A ; Rossing, M ; Saloustros, E ; Sanchez-Herrero, E ; Sandler, DP ; Santamarina, M ; Saunders, C ; Sawyer, EJ ; Scheuner, MT ; Schmidt, DF ; Schmutzler, RK ; Schneeweiss, A ; Schoemaker, MJ ; Schoettker, B ; Schuermann, P ; Scott, C ; Scott, RJ ; Senter, L ; Seynaeve, CM ; Shah, M ; Sharma, P ; Shen, C-Y ; Shu, X-O ; Singer, CF ; Slavin, TP ; Smichkoska, S ; Southey, MC ; Spinelli, JJ ; Spurdle, AB ; Stone, J ; Stoppa-Lyonnet, D ; Sutter, C ; Swerdlow, AJ ; Tamimi, RM ; Tan, YY ; Tapper, WJ ; Taylor, JA ; Teixeira, MR ; Tengstroem, M ; Teo, SH ; Terry, MB ; Teul, A ; Thomassen, M ; Thull, DL ; Tischkowitz, M ; Toland, AE ; Tollenaar, RAEM ; Tomlinson, I ; Torres, D ; Torres-Mejia, G ; Troester, MA ; Truong, T ; Tung, N ; Tzardi, M ; Ulmer, H-U ; Vachon, CM ; van Asperen, CJ ; van der Kolk, LE ; van Rensburg, EJ ; Vega, A ; Viel, A ; Vijai, J ; Vogel, MJ ; Wang, Q ; Wappenschmidt, B ; Weinberg, CR ; Weitzel, JN ; Wendt, C ; Wildiers, H ; Winqvist, R ; Wolk, A ; Wu, AH ; Yannoukakos, D ; Zhang, Y ; Zheng, W ; Hunter, D ; Pharoah, PDP ; Chang-Claude, J ; Garcia-Closas, M ; Schmidt, MK ; Milne, RL ; Kristensen, VN ; French, JD ; Edwards, SL ; Antoniou, AC ; Chenevix-Trench, G ; Simard, J ; Easton, DF ; Kraft, P ; Dunning, AM ; Mari, V ; Berthet, P ; Castera, L ; Vaur, D ; Lallaoui, H ; Bignon, Y-J ; Uhrhammer, N ; Bonadona, V ; Lasset, C ; Revillion, F ; Vennin, P ; Muller, D ; Gomes, DM ; Ingster, O ; Coupier, I ; Pujol, P ; Collonge-Rame, M-A ; Mortemousque, I ; Bera, O ; Rose, M ; Baurand, A ; Bertolone, G ; Faivre, L ; Dreyfus, H ; Leroux, D ; Venat-Bouvet, L ; Bezieau, S ; Delnatte, C ; Chiesa, J ; Gilbert-Dussardier, B ; Gesta, P ; Prieur, FP ; Bronner, M ; Sokolowska, J ; Coulet, F ; Boutry-Kryza, N ; Calender, A ; Giraud, S ; Leone, M ; Fert-Ferrer, S ; Jiao, Y ; Lesueur, FL ; Barouk-Simonet, E ; Bubien, V ; Longy, M ; Sevenet, N ; Gladieff, L ; Toulas, C ; Reimineras, A ; Sobol, H ; Bressac-de Paillerets, B ; Cabaret, O ; Caron, O ; Guillaud-Bataille, M ; Rouleau, E ; Belotti, M ; Buecher, B ; Caputo, S ; Colas, C ; De Pauw, A ; Fourme, E ; Gauthier-Villars, M ; Golmard, L ; Moncoutier, V ; Saule, C ; Donaldson, A ; Murray, A ; Brady, A ; Brewer, C ; Pottinger, C ; Miller, C ; Gallagher, D ; Gregory, H ; Cook, J ; Eason, J ; Adlard, J ; Barwell, J ; Ong, K-R ; Snape, K ; Walker, L ; Izatt, L ; Side, L ; Rogers, MT ; Porteous, ME ; Ahmed, M ; Morrison, PJ ; Brennan, P ; Eeles, R ; Davidson, R ; Sexton, A ; Christian, A ; Trainer, A ; Spigelman, A ; Fellows, A ; Shelling, A ; De Fazio, A ; Blackburn, A ; Crook, A ; Meiser, B ; Patterson, B ; Clarke, C ; Hunt, C ; Scott, C ; Amor, D ; Marsh, D ; Edkins, E ; Salisbury, E ; Haan, E ; Neidermayr, E ; Macrea, F ; Farshid, G ; Lindeman, G ; Trench, G ; Mann, G ; Giles, G ; Gill, G ; Thorne, H ; Hickie, I ; Winship, I ; Flanagan, J ; Kollias, J ; Visvader, J ; Taylor, J ; Burke, J ; Saunus, J ; Forbes, J ; Hopper, J ; French, J ; Tucker, K ; Wu, K ; Phillips, K ; Lipton, L ; Andrews, L ; Lobb, L ; Walker, L ; Kentwell, M ; Spurdle, M ; Cummings, M ; Gleeson, M ; Harris, M ; Jenkins, M ; Young, MA ; Delatycki, M ; Wallis, M ; Burgess, M ; Price, M ; Brown, M ; Southey, M ; Bogwitz, M ; Field, M ; Friedlander, M ; Gattas, M ; Saleh, M ; Hayward, N ; Pachter, N ; Cohen, P ; Duijf, P ; James, P ; Simpson, P ; Fong, P ; Butow, P ; Williams, R ; Kefford, R ; Scott, R ; Milne, R ; Balleine, R ; Dawson, S ; Lok, S ; O'Connell, S ; Greening, S ; Nightingale, S ; Edwards, S ; Fox, S ; Mclachlan, S-A ; Lakhani, S ; Antill, Y ; Aalfs, C ; Meijers-Heijboer, H ; van Engelen, K ; Gille, H ; Boere, I ; Collee, M ; van Deurzen, C ; Hooning, M ; Obdeijn, I-M ; van den Ouweland, A ; Seynaeve, C ; Siesling, S ; Verloop, J ; van Asperen, C ; van Cronenburg, T ; Blok, R ; de Boer, M ; Garcia, EG ; Adank, M ; Hogervorst, F ; Jenner, D ; van Leeuwen, F ; Rookus, M ; Russell, N ; Schmidt, M ; van den Belt-Dusebout, S ; Kets, C ; Mensenkamp, A ; de Bock, T ; van Der Hout, A ; Mourits, M ; Oosterwijk, J ; Ausems, M ; Koudijs, M ; Marsh, D ; Baxter, R ; Yip, D ; Carpenter, J ; Davis, A ; Pathmanathan, N ; Simpson, P ; Graham, D ; Sachchithananthan, M (NATURE RESEARCH, 2020-01-07)
    Genome-wide association studies have identified breast cancer risk variants in over 150 genomic regions, but the mechanisms underlying risk remain largely unknown. These regions were explored by combining association analysis with in silico genomic feature annotations. We defined 205 independent risk-associated signals with the set of credible causal variants in each one. In parallel, we used a Bayesian approach (PAINTOR) that combines genetic association, linkage disequilibrium and enriched genomic features to determine variants with high posterior probabilities of being causal. Potentially causal variants were significantly over-represented in active gene regulatory regions and transcription factor binding sites. We applied our INQUSIT pipeline for prioritizing genes as targets of those potentially causal variants, using gene expression (expression quantitative trait loci), chromatin interaction and functional annotations. Known cancer drivers, transcription factors and genes in the developmental, apoptosis, immune system and DNA integrity checkpoint gene ontology pathways were over-represented among the highest-confidence target genes.
  • Item
    Thumbnail Image
    Polygenic Risk Scores for Prediction of Breast Cancer and Breast Cancer Subtypes
    Mavaddat, N ; Michailidou, K ; Dennis, J ; Lush, M ; Fachal, L ; Lee, A ; Tyrer, JP ; Chen, T-H ; Wang, Q ; Bolla, MK ; Yang, X ; Adank, MA ; Ahearn, T ; Aittomaki, K ; Allen, J ; Andrulis, IL ; Anton-Culver, H ; Antonenkova, NN ; Arndt, V ; Aronson, KJ ; Auer, PL ; Auvinen, P ; Barrdahl, M ; Freeman, LEB ; Beckmann, MW ; Behrens, S ; Benitez, J ; Bermisheva, M ; Bernstein, L ; Blomqvist, C ; Bogdanova, N ; Bojesen, SE ; Bonanni, B ; Borresen-Dale, A-L ; Brauch, H ; Bremer, M ; Brenner, H ; Brentnall, A ; Brock, IW ; Brooks-Wilson, A ; Brucker, SY ; Bruening, T ; Burwinkel, B ; Campa, D ; Carter, BD ; Castelao, JE ; Chanock, SJ ; Chlebowski, R ; Christiansen, H ; Clarke, CL ; Collee, JM ; Cordina-Duverger, E ; Cornelissen, S ; Couch, FJ ; Cox, A ; Cross, SS ; Czene, K ; Daly, MB ; Devilee, P ; Doerk, T ; dos-Santos-Silva, I ; Dumont, M ; Durcan, L ; Dwek, M ; Eccles, DM ; Ekici, AB ; Eliassen, AH ; Ellberg, C ; Engel, C ; Eriksson, M ; Evans, DG ; Fasching, PA ; Figueroa, J ; Fletcher, O ; Flyger, H ; Foersti, A ; Fritschi, L ; Gabrielson, M ; Gago-Dominguez, M ; Gapstur, SM ; Garcia-Saenz, JA ; Gaudet, MM ; Georgoulias, V ; Giles, GG ; Gilyazova, IR ; Glendon, G ; Goldberg, MS ; Goldgar, DE ; Gonzalez-Neira, A ; Alnaes, GIG ; Grip, M ; Gronwald, J ; Grundy, A ; Guenel, P ; Haeberle, L ; Hahnen, E ; Haiman, CA ; Hakansson, N ; Hamann, U ; Hankinson, SE ; Harkness, EF ; Hart, SN ; He, W ; Hein, A ; Heyworth, J ; Hillemanns, P ; Hollestelle, A ; Hooning, MJ ; Hoover, RN ; Hopper, JL ; Howell, A ; Huang, G ; Humphreys, K ; Hunter, DJ ; Jakimovska, M ; Jakubowska, A ; Janni, W ; John, EM ; Johnson, N ; Jones, ME ; Jukkola-Vuorinen, A ; Jung, A ; Kaaks, R ; Kaczmarek, K ; Kataja, V ; Keeman, R ; Kerin, MJ ; Khusnutdinova, E ; Kiiski, J ; Knight, JA ; Ko, Y-D ; Kosma, V-M ; Koutros, S ; Kristensen, VN ; Kruger, U ; Kuehl, T ; Lambrechts, D ; Le Marchand, L ; Lee, E ; Lejbkowicz, F ; Lilyquist, J ; Lindblom, A ; Lindstrom, S ; Lissowska, J ; Lo, W-Y ; Loibl, S ; Long, J ; Lubinski, J ; Lux, MP ; MacInnis, RJ ; Maishman, T ; Makalic, E ; Kostovska, IM ; Mannermaa, A ; Manoukian, S ; Margolin, S ; Martens, JWM ; Martinez, ME ; Mavroudis, D ; McLean, C ; Meindl, A ; Menon, U ; Middha, P ; Miller, N ; Moreno, F ; Mulligan, AM ; Mulot, C ; Munoz-Garzon, VM ; Neuhausen, SL ; Nevanlinna, H ; Neven, P ; Newman, WG ; Nielsen, SF ; Nordestgaard, BG ; Norman, A ; Offit, K ; Olson, JE ; Olsson, H ; Orr, N ; Pankratz, VS ; Park-Simon, T-W ; Perez, JIA ; Perez-Barrios, C ; Peterlongo, P ; Peto, J ; Pinchev, M ; Plaseska-Karanfilska, D ; Polley, EC ; Prentice, R ; Presneau, N ; Prokofyeva, D ; Purrington, K ; Pylkas, K ; Rack, B ; Radice, P ; Rau-Murthy, R ; Rennert, G ; Rennert, HS ; Rhenius, V ; Robson, M ; Romero, A ; Ruddy, KJ ; Ruebner, M ; Saloustros, E ; Sandler, DP ; Sawyer, EJ ; Schmidt, DF ; Schmutzler, RK ; Schneeweiss, A ; Schoemaker, MJ ; Schumacher, F ; Schuermann, P ; Schwentner, L ; Scott, C ; Scott, RJ ; Seynaeve, C ; Shah, M ; Sherman, ME ; Shrubsole, MJ ; Shu, X-O ; Slager, S ; Smeets, A ; Sohn, C ; Soucy, P ; Southey, MC ; Spinelli, JJ ; Stegmaier, C ; Stone, J ; Swerdlow, AJ ; Tamimi, RM ; Tapper, WJ ; Taylor, JA ; Terry, MB ; Thoene, K ; Tollenaar, RAEM ; Tomlinson, I ; Truong, T ; Tzardi, M ; Ulmer, H-U ; Untch, M ; Vachon, CM ; van Veen, EM ; Vijai, J ; Weinberg, CR ; Wendt, C ; Whittemore, AS ; Wildiers, H ; Willett, W ; Winqvist, R ; Wolk, A ; Yang, XR ; Yannoukakos, D ; Zhang, Y ; Zheng, W ; Ziogas, A ; Clarke, C ; Balleine, R ; Baxter, R ; Braye, S ; Carpenter, J ; Dahlstrom, J ; Forbes, J ; Lee, CS ; Marsh, D ; Morey, A ; Pathmanathan, N ; Scott, R ; Simpson, P ; Spigelman, A ; Wilcken, N ; Yip, D ; Zeps, N ; Sexton, A ; Dobrovic, A ; Christian, A ; Trainer, A ; Fellows, A ; Shelling, A ; De Fazio, A ; Blackburn, A ; Crook, A ; Meiser, B ; Patterson, B ; Clarke, C ; Saunders, C ; Hunt, C ; Scott, C ; Amor, D ; Ortega, DG ; Marsh, D ; Edkins, E ; Salisbury, E ; Haan, E ; Macrea, F ; Farshid, G ; Lindeman, G ; Trench, G ; Mann, G ; Giles, G ; Gill, G ; Thorne, H ; Campbell, I ; Hickie, I ; Caldon, L ; Winship, I ; Cui, J ; Flanagan, J ; Kollias, J ; Visvader, J ; Taylor, J ; Burke, J ; Saunus, J ; Forbs, J ; Hopper, J ; Beesley, J ; Kirk, J ; French, J ; Tucker, K ; Wu, K ; Phillips, K ; Forrest, L ; Lipton, L ; Andrews, L ; Lobb, L ; Walker, L ; Kentwell, M ; Spurdle, M ; Cummings, M ; Gleeson, M ; Harris, M ; Jenkins, M ; Young, MA ; Delatycki, M ; Wallis, M ; Burgess, M ; Brown, M ; Southey, M ; Bogwitz, M ; Field, M ; Friedlander, M ; Gattas, M ; Saleh, M ; Aghmesheh, M ; Hayward, N ; Pachter, N ; Cohen, P ; Duijf, P ; James, P ; Simpson, P ; Fong, P ; Butow, P ; Williams, R ; Kefford, R ; Simard, J ; Balleine, R-M ; Dawson, S-J ; Lok, S ; O'connell, S ; Greening, S ; Nightingale, S ; Edwards, S ; Fox, S ; McLachlan, S-A ; Lakhani, S ; Dudding, T ; Antill, Y ; Sahlberg, KK ; Ottestad, L ; Karesen, R ; Schlichting, E ; Holmen, MM ; Sauer, T ; Haakensen, V ; Engebraten, O ; Naume, B ; Fossa, A ; Kiserud, CE ; Reinertsen, K ; Helland, A ; Riis, M ; Geisler, J ; Dunning, AM ; Thompson, DJ ; Chenevix-Trench, G ; Chang-Claude, J ; Schmidt, MK ; Hall, P ; Milne, RL ; Pharoah, PDP ; Antoniou, AC ; Chatterjee, N ; Kraft, P ; Garcia-Closas, M ; Easton, DF (CELL PRESS, 2019-01-03)
    Stratification of women according to their risk of breast cancer based on polygenic risk scores (PRSs) could improve screening and prevention strategies. Our aim was to develop PRSs, optimized for prediction of estrogen receptor (ER)-specific disease, from the largest available genome-wide association dataset and to empirically validate the PRSs in prospective studies. The development dataset comprised 94,075 case subjects and 75,017 control subjects of European ancestry from 69 studies, divided into training and validation sets. Samples were genotyped using genome-wide arrays, and single-nucleotide polymorphisms (SNPs) were selected by stepwise regression or lasso penalized regression. The best performing PRSs were validated in an independent test set comprising 11,428 case subjects and 18,323 control subjects from 10 prospective studies and 190,040 women from UK Biobank (3,215 incident breast cancers). For the best PRSs (313 SNPs), the odds ratio for overall disease per 1 standard deviation in ten prospective studies was 1.61 (95%CI: 1.57-1.65) with area under receiver-operator curve (AUC) = 0.630 (95%CI: 0.628-0.651). The lifetime risk of overall breast cancer in the top centile of the PRSs was 32.6%. Compared with women in the middle quintile, those in the highest 1% of risk had 4.37- and 2.78-fold risks, and those in the lowest 1% of risk had 0.16- and 0.27-fold risks, of developing ER-positive and ER-negative disease, respectively. Goodness-of-fit tests indicated that this PRS was well calibrated and predicts disease risk accurately in the tails of the distribution. This PRS is a powerful and reliable predictor of breast cancer risk that may improve breast cancer prevention programs.
  • Item
    Thumbnail Image
    Homologous recombination DNA repair defects in PALB2-associated breast cancers
    Li, A ; Geyer, FC ; Blecua, P ; Lee, JY ; Selenica, P ; Brown, DN ; Pareja, F ; Lee, SSK ; Kumar, R ; Rivera, B ; Bi, R ; Piscuoglio, S ; Wen, HY ; Lozada, JR ; Gularte-Merida, R ; Cavallone, L ; Rezoug, Z ; Nguyen-Dumont, T ; Peterlongo, P ; Tondini, C ; Terkelsen, T ; Ronlund, K ; Boonen, SE ; Mannerma, A ; Winqvist, R ; Janatova, M ; Rajadurai, P ; Xia, B ; Norton, L ; Robson, ME ; Ng, P-S ; Looi, L-M ; Southey, MC ; Weigelt, B ; Soo-Hwang, T ; Tischkowitz, M ; Foulkes, WD ; Reis-Filho, JS ; Aghmesheh, M ; Amor, D ; Andrews, L ; Antill, Y ; Balleine, R ; Beesley, J ; Blackburn, A ; Bogwitz, M ; Brown, M ; Burgess, M ; Burke, J ; Butow, P ; Caldon, L ; Campbell, I ; Christian, A ; Clarke, C ; Cohen, P ; Crook, A ; Cui, J ; Cummings, M ; Dawson, S-J ; De Fazio, A ; Delatycki, M ; Dobrovic, A ; Dudding, T ; Duijf, P ; Edkins, E ; Edwards, S ; Farshid, G ; Fellows, A ; Field, M ; Flanagan, J ; Fong, P ; Forbes, J ; Forrest, L ; Fox, S ; French, J ; Friedlander, M ; Ortega, DG ; Gattas, M ; Giles, G ; Gill, G ; Gleeson, M ; Greening, S ; Haan, E ; Harris, M ; Hayward, N ; Hickie, I ; Hopper, J ; Hunt, C ; James, P ; Jenkins, M ; Kefford, R ; Kentwell, M ; Kirk, J ; Kollias, J ; Lakhani, S ; Lindeman, G ; Lipton, L ; Lobb, L ; Lok, S ; Macrea, F ; Mane, G ; Marsh, D ; Mclachlan, S-A ; Meiser, B ; Milne, R ; Nightingale, S ; O'Connell, S ; Pachter, N ; Patterson, B ; Phillips, K ; Saleh, M ; Salisbury, E ; Saunders, C ; Saunus, J ; Scott, C ; Scott, R ; Sexton, A ; Shelling, A ; Simpson, P ; Spigelman, A ; Spurdle, M ; Stone, J ; Taylor, J ; Thorne, H ; Trainer, A ; Trench, G ; Tucker, K ; Visvader, J ; Walker, L ; Wallis, M ; Williams, R ; Winship, I ; Wu, K ; Young, MA (NATURE PUBLISHING GROUP, 2019-08-08)
    Mono-allelic germline pathogenic variants in the Partner And Localizer of BRCA2 (PALB2) gene predispose to a high-risk of breast cancer development, consistent with the role of PALB2 in homologous recombination (HR) DNA repair. Here, we sought to define the repertoire of somatic genetic alterations in PALB2-associated breast cancers (BCs), and whether PALB2-associated BCs display bi-allelic inactivation of PALB2 and/or genomic features of HR-deficiency (HRD). Twenty-four breast cancer patients with pathogenic PALB2 germline mutations were analyzed by whole-exome sequencing (WES, n = 16) or targeted capture massively parallel sequencing (410 cancer genes, n = 8). Somatic genetic alterations, loss of heterozygosity (LOH) of the PALB2 wild-type allele, large-scale state transitions (LSTs) and mutational signatures were defined. PALB2-associated BCs were found to be heterogeneous at the genetic level, with PIK3CA (29%), PALB2 (21%), TP53 (21%), and NOTCH3 (17%) being the genes most frequently affected by somatic mutations. Bi-allelic PALB2 inactivation was found in 16 of the 24 cases (67%), either through LOH (n = 11) or second somatic mutations (n = 5) of the wild-type allele. High LST scores were found in all 12 PALB2-associated BCs with bi-allelic PALB2 inactivation sequenced by WES, of which eight displayed the HRD-related mutational signature 3. In addition, bi-allelic inactivation of PALB2 was significantly associated with high LST scores. Our findings suggest that the identification of bi-allelic PALB2 inactivation in PALB2-associated BCs is required for the personalization of HR-directed therapies, such as platinum salts and/or PARP inhibitors, as the vast majority of PALB2-associated BCs without PALB2 bi-allelic inactivation lack genomic features of HRD.
  • Item
    Thumbnail Image
    Development and validation of a targeted gene sequencing panel for application to disparate cancers
    McCabe, MJ ; Gauthier, M-EA ; Chan, C-L ; Thompson, TJ ; De Sousa, SMC ; Puttick, C ; Grady, JP ; Gayevskiy, V ; Tao, J ; Ying, K ; Cipponi, A ; Deng, N ; Swarbrick, A ; Thomas, ML ; kConFab, ; Lord, RV ; Johns, AL ; Kohonen-Corish, M ; O'Toole, SA ; Clark, J ; Mueller, SA ; Gupta, R ; McCormack, AI ; Dinger, ME ; Cowley, MJ (Nature Publishing Group, 2019-11-19)
    Next generation sequencing has revolutionised genomic studies of cancer, having facilitated the development of precision oncology treatments based on a tumour's molecular profile. We aimed to develop a targeted gene sequencing panel for application to disparate cancer types with particular focus on tumours of the head and neck, plus test for utility in liquid biopsy. The final panel designed through Roche/Nimblegen combined 451 cancer-associated genes (2.01 Mb target region). 136 patient DNA samples were collected for performance and application testing. Panel sensitivity and precision were measured using well-characterised DNA controls (n = 47), and specificity by Sanger sequencing of the Aryl Hydrocarbon Receptor Interacting Protein (AIP) gene in 89 patients. Assessment of liquid biopsy application employed a pool of synthetic circulating tumour DNA (ctDNA). Library preparation and sequencing were conducted on Illumina-based platforms prior to analysis with our accredited (ISO15189) bioinformatics pipeline. We achieved a mean coverage of 395x, with sensitivity and specificity of >99% and precision of >97%. Liquid biopsy revealed detection to 1.25% variant allele frequency. Application to head and neck tumours/cancers resulted in detection of mutations aligned to published databases. In conclusion, we have developed an analytically-validated panel for application to cancers of disparate types with utility in liquid biopsy.