Your search keyword '"Nowinski, S"' showing total 21 results

1. Genetic Predisposition to In Situ and Invasive Lobular Carcinoma of the Breast

Author

Ashworth, Alan, Sawyer, E, Roylance, R, Petridis, C, Brook, MN, Nowinski, S, Papouli, E, Fletcher, O, Pinder, S, Hanby, A, and Kohut, K

Abstract

Invasive lobular breast cancer (ILC) accounts for 10-15% of all invasive breast carcinomas. It is generally ER positive (ER+) and often associated with lobular carcinoma in situ (LCIS). Genome-wide association studies have identified more than 70 common po

Published

2014

2. P698 Mapping field cancerisation and clonal evolution in IBD colons with dysplasia and colorectal cancer

Author

Yalchin, M, primary, Curtius, K, additional, Nowinski, S, additional, Moorghen, M, additional, Kimberley, C, additional, Smith, K, additional, Baker, A M, additional, Al-Bakir, I, additional, Mossner, M, additional, Nadhamuni, V, additional, Hart, A, additional, and Graham, T, additional

Published

2022

3. Mitochondrial respiratory uncoupling promotes keratinocyte differentiation and blocks skin carcinogenesis

Author

Lago, C U, Nowinski, S M, Rundhaug, J E, Pfeiffer, M E, Kiguchi, K, Hirasaka, K, Yang, X, Abramson, E M, Bratton, S B, Rho, O, Colavitti, R, Kenaston, M A, Nikawa, T, Trempus, C, DiGiovanni, J, Fischer, S M, and Mills, E M

Published

2012

4. Assessment of structural chromosomal instability phenotypes as biomarkers of carboplatin response in triple negative breast cancer: the TNT trial

Author

Sipos, O., primary, Tovey, H., additional, Quist, J., additional, Haider, S., additional, Nowinski, S., additional, Gazinska, P., additional, Kernaghan, S., additional, Toms, C., additional, Maguire, S., additional, Orr, N., additional, Linn, S.C., additional, Owen, J., additional, Gillett, C., additional, Pinder, S.E., additional, Bliss, J.M., additional, Tutt, A., additional, Cheang, M.C.U., additional, and Grigoriadis, A., additional

Published

2021

5. PO-228 Comprehensive molecular characterisation of TNBCs expressing HORMAD1, a driver of homologous recombination deficiency

Author

Quist, J., primary, Mirza, H., additional, Weekes, D., additional, Nowinski, S., additional, Cheang, M.C.U., additional, Lord, C.J., additional, Tutt, A.N.J., additional, and Grigoriadis, A., additional

Published

2018

6. PO-308 Identification of genomic patterns predictive of upgrading in low-grade prostate cancer

Author

Nowinski, S., primary, Quist, J., additional, Baker, A.M., additional, Graham, T.A., additional, Lombardelli, C., additional, Gillett, C., additional, Loda, M., additional, Chandra, A., additional, Hemelrijck, M. Van, additional, and Grigoriadis, A., additional

Published

2018

7. Genetic Predisposition to In Situ and Invasive Lobular\ud Carcinoma of the Breast

Author

Sawyer, E., Roylance, R., Petridis, C., Brook, M.N., Nowinski, S., Papouli, E., Fletcher, O., Pinder, S., Hanby, A., Kohut, K., Gorman, P., Caneppele, M., Peto, J., Silva, I.D.S., Johnson, N., Swann, R., Dwek, M., Perkins, K-A., Gillett, C., Houlston, R., Ross, G., De Ieso, P., Southey, M.C., Hopper, J.L., Provenzano, E., Apicella, C., Wesseling, J., Cornelissen, S., Keeman, R., Fasching, P.A., Jud, S.M., Ekici, A.B., Beckmann, M.W., Kerin, M.J., Marme, F., Schneeweiss, A., Sohn, C., Burwinkel, B., Guenel, P., Truong, T., Laurent-Puig, P., Kerbrat, P., Bojesen, S.E., Nordestgaard, B.G., Nielsen, S.F., Flyger, H., Milne, R.L., Perez, J.I.A., Menendez, P., Benitez, J., Brenner, H., Dieffenbach, A.K., Arndt, V., Stegmaier, C., Meindl, A., Lichtner, P., Schmutzler, R.K., Lochmann, M., Brauch, H., Fischer, H-P., Ko, Y-D., Nevanlinna, H., Muranen, T.A., Aittomaki, K., Blomqvist, C., Bogdanova, N.V., Dork, T., Lindblom, A., Margolin, S., Mannermaa, A., Kataja, V., Kosma, V-M., Hartikainen, J.M., Chenevix-Trench, G., Lambrechts, D., Weltens, C., Van Limbergen, E., Hatse, S., Chang-Claude, J., Rudolph, A., Seibold, P., Flesch-Janys, D., Radice, P., Peterlongo, P., Bonanni, B., Volorio, S., Giles, G.G., Severi, G., Baglietto, L., Mclean, C.A., Haiman, C.A., Henderson, B.E., Schumacher, F., Le Marchand, L., Simard, J., Goldberg, M.S., Labreche, F., Dumont, M., Kristensen, V., Winqvist, R., Pylkas, K., Jukkola-Vuorinen, A., Kauppila, S., Andrulis, I.L., Knight, J.A., Glendon, G., Mulligan, A.M., Devillee, P., Tollenaar, R.A.E.M., Seynaeve, C.M., Kriege, M., Figueroa, J., Chanock, S.J., Sherman, M.E., Hooning, M.J., Hollestelle, A., van den Ouweland, A.M.W., van Deurzen, C.H.M., Li, J., Czene, K., Humphreys, K., Cox, A., Cross, S.S., Reed, M.W.R., Shah, M., Jakubowska, A., Lubinski, J., Jaworska-Bieniek, K., Durda, K., Swerdlow, A., Ashworth, A., Orr, N., Schoemaker, M., Couch, F.J., Hallberg, E., Gonzalez-Neira, A., Pita, G., Alonso, M.R., Tessier, D.C., Vincent, D., Bacot, F., Bolla, M.K., Wang, Q., Dennis, J., Michailidou, K., Dunning, A.M., Hall, P., Easton, D., Pharoah, P., Schmidt, M.K., Tomlinson, I., Garcia-Closas, M., Network, GENICA, and Investigators, K

Subjects

body regions, skin and connective tissue diseases

Abstract

Invasive lobular breast cancer (ILC) accounts for 10–15% of all invasive breast carcinomas. It is generally ER positive (ER+) and\ud often associated with lobular carcinoma in situ (LCIS). Genome-wide association studies have identified more than 70 common\ud polymorphisms that predispose to breast cancer, but these studies included predominantly ductal (IDC) carcinomas. To\ud identify novel common polymorphisms that predispose to ILC and LCIS, we pooled data from 6,023 cases (5,622 ILC, 401 pure\ud LCIS) and 34,271 controls from 36 studies genotyped using the iCOGS chip. Six novel SNPs most strongly associated with ILC/\ud LCIS in the pooled analysis were genotyped in a further 516 lobular cases (482 ILC, 36 LCIS) and 1,467 controls. These analyses\ud identified a lobular-specific SNP at 7q34 (rs11977670, OR (95%CI) for ILC = 1.13 (1.09–1.18), P = 6.0610210; P-het for ILC vs IDC\ud ER+ tumors = 1.861024\ud ). Of the 75 known breast cancer polymorphisms that were genotyped, 56 were associated with ILC and\ud 15 with LCIS at P,0.05. Two SNPs showed significantly stronger associations for ILC than LCIS (rs2981579/10q26/FGFR2, Phet\ud = 0.04 and rs889312/5q11/MAP3K1, P-het = 0.03); and two showed stronger associations for LCIS than ILC (rs6678914/1q32/\ud LGR6, P-het = 0.001 and rs1752911/6q14, P-het = 0.04). In addition, seven of the 75 known loci showed significant differences\ud between ER+ tumors with IDC and ILC histology, three of these showing stronger associations for ILC (rs11249433/1p11,\ud rs2981579/10q26/FGFR2 and rs10995190/10q21/ZNF365) and four associated only with IDC (5p12/rs10941679; rs2588809/\ud 14q24/RAD51L1, rs6472903/8q21 and rs1550623/2q31/CDCA7). In conclusion, we have identified one novel lobular breast\ud cancer specific predisposition polymorphism at 7q34, and shown for the first time that common breast cancer polymorphisms\ud predispose to LCIS. We have shown that many of the ER+ breast cancer predisposition loci also predispose to ILC, although\ud there is some heterogeneity between ER+ lobular and ER+ IDC tumors. These data provide evidence for overlapping, but\ud distinct etiological pathways within ER+ breast cancer between morphological subtypes.

Published

2014

8. Genetic Predisposition to In Situ and Invasive Lobular Carcinoma of the Breast

Author

Sawyer, E.J. (Elinor), Roylance, R. (Rebecca), Petridis, C. (Christos), Brook, R.H., Nowinski, S. (Salpie), Papouli, E. (Efterpi), Fletcher, O. (Olivia), Pinder, S. (Sarah), Hanby, A. (Andrew), Kohut, K. (Kelly), Gorman, P. (Patricia), Caneppele, M. (Michele), Peto, J. (Julian), Santos Silva, I. (Isabel) dos, Johnson, N. (Nichola), Swann, R. (Ruth), Dwek, M. (Miriam), Perkins, K.-A. (Katherine-Anne), Gillett, C. (Cheryl), Houlston, R. (Richard), Ross, G. (Gillian), Ieso, P. (Paolo) de, Southey, M.C. (Melissa), Hopper, J.L. (John), Provenzano, E. (Elena), Apicella, C. (Carmel), Wesseling, J. (Jelle), Cornelissen, S. (Sten), Keeman, J.N., Fasching, P.A. (Peter), Jud, S.M. (Sebastian), Ekici, A.B. (Arif), Beckmann, M.W. (Matthias), Kerin, M. (Michael), Marme, F. (Federick), Schneeweiss, A. (Andreas), Sohn, C. (Christof), Burwinkel, B. (Barbara), Guénel, P. (Pascal), Truong, T. (Thérèse), Laurent-Puig, P. (Pierre), Kerbrat, P. (Pierre), Bojesen, S.E. (Stig), Nordestgaard, B.G. (Børge), Nielsen, S.F. (Sune), Flyger, H. (Henrik), Milne, R.L. (Roger), Perez, J.I.A. (Jose Ignacio Arias), Menéndez, P. (Primitiva), Benítez, J. (Javier), Brenner, H. (Hermann), Dieffenbach, A.K. (Aida Karina), Arndt, V. (Volker), Stegmaier, C. (Christa), Meindl, A. (Alfons), Lichtner, P. (Peter), Schmutzler, R.K. (Rita), Lochmann, M. (Magdalena), Brauch, H. (Hiltrud), Fischer, H.-P., Ko, Y-D. (Yon-Dschun), Nevanlinna, H. (Heli), Muranen, T.A. (Taru), Aittomäki, K. (Kristiina), Blomqvist, C. (Carl), Bogdanova, N.V. (Natalia), Dörk, T. (Thilo), Lindblom, A. (Annika), Margolin, S. (Sara), Mannermaa, A. (Arto), Kataja, V. (Vesa), Kosma, V-M. (Veli-Matti), Hartikainen, J. (Jaana), Chenevix-Trench, G. (Georgia), Lambrechts, D. (Diether), Weltens, C. (Caroline), Limbergen, E. (Erik) van, Hatse, S. (Sigrid), Chang-Claude, J. (Jenny), Rudolph, A. (Anja), Seibold, P. (Petra), Flesch-Janys, D. (Dieter), Radice, P. (Paolo), Peterlongo, P. (Paolo), Bonnani, B. (Bernardo), Volorio, S. (Sara), Giles, G.G. (Graham), Severi, G. (Gianluca), Baglietto, L. (Laura), McLean, C.A. (Catriona Ann), Haiman, C.A. (Christopher), Henderson, B.E. (Brian), Schumacher, F.R. (Fredrick), Le Marchand, L. (Loic), Simard, J. (Jacques), Goldberg, M.S. (Mark), Labrèche, F. (France), Dumont, M. (Martine), Kristensen, V. (Vessela), Winqvist, R. (Robert), Pykäs, K. (Katri), Jukkola-Vuorinen, A. (Arja), Kauppila, S. (Saila), Andrulis, I.L. (Irene), Knight, J.A. (Julia), Glendon, G. (Gord), Mulligan, A.M. (Anna Marie), Devillee, P. (Peter), Tollenaar, R.A.E.M. (Rob), Seynaeve, C.M. (Caroline), Kriege, M. (Mieke), Figueroa, J.D. (Jonine), Chanock, S.J. (Stephen), Sherman, M.E. (Mark), Hooning, M.J. (Maartje), Hollestelle, A. (Antoinette), Ouweland, A.M.W. (Ans) van den, Deurzen, C.H.M. (Carolien) van, Li, J. (Jingmei), Czene, K. (Kamila), Humphreys, M.K. (Manjeet), Cox, A. (Angela), Cross, S.S. (Simon), Reed, M.W.R. (Malcolm), Shah, M. (Mitul), Jakubowska, A. (Anna), Lubinski, J. (Jan), Jaworska-Bieniek, K. (Katarzyna), Durda, K. (Katarzyna), Swerdlow, A.J. (Anthony ), Ashworth, A. (Alan), Orr, N. (Nick), Schoemaker, M. (Minouk), Couch, F.J. (Fergus), Hallberg, B. (Boubou), González-Neira, A. (Anna), Pita, G. (Guillermo), Alonso, M.R. (Rosario), Tessier, Y. (Yann), Vincent, D. (Daniel), Bacot, F. (Francois), Bolla, M.K. (Manjeet), Wang, Q. (Qing), Dennis, J. (Joe), Michailidou, K. (Kyriaki), Dunning, A.M. (Alison), Hall, P. (Per), Easton, D.F. (Douglas), Pharoah, P.D.P. (Paul), Schmidt, M.K. (Marjanka), Tomlinson, I.P. (Ian), García-Closas, M. (Montserrat), Sawyer, E.J. (Elinor), Roylance, R. (Rebecca), Petridis, C. (Christos), Brook, R.H., Nowinski, S. (Salpie), Papouli, E. (Efterpi), Fletcher, O. (Olivia), Pinder, S. (Sarah), Hanby, A. (Andrew), Kohut, K. (Kelly), Gorman, P. (Patricia), Caneppele, M. (Michele), Peto, J. (Julian), Santos Silva, I. (Isabel) dos, Johnson, N. (Nichola), Swann, R. (Ruth), Dwek, M. (Miriam), Perkins, K.-A. (Katherine-Anne), Gillett, C. (Cheryl), Houlston, R. (Richard), Ross, G. (Gillian), Ieso, P. (Paolo) de, Southey, M.C. (Melissa), Hopper, J.L. (John), Provenzano, E. (Elena), Apicella, C. (Carmel), Wesseling, J. (Jelle), Cornelissen, S. (Sten), Keeman, J.N., Fasching, P.A. (Peter), Jud, S.M. (Sebastian), Ekici, A.B. (Arif), Beckmann, M.W. (Matthias), Kerin, M. (Michael), Marme, F. (Federick), Schneeweiss, A. (Andreas), Sohn, C. (Christof), Burwinkel, B. (Barbara), Guénel, P. (Pascal), Truong, T. (Thérèse), Laurent-Puig, P. (Pierre), Kerbrat, P. (Pierre), Bojesen, S.E. (Stig), Nordestgaard, B.G. (Børge), Nielsen, S.F. (Sune), Flyger, H. (Henrik), Milne, R.L. (Roger), Perez, J.I.A. (Jose Ignacio Arias), Menéndez, P. (Primitiva), Benítez, J. (Javier), Brenner, H. (Hermann), Dieffenbach, A.K. (Aida Karina), Arndt, V. (Volker), Stegmaier, C. (Christa), Meindl, A. (Alfons), Lichtner, P. (Peter), Schmutzler, R.K. (Rita), Lochmann, M. (Magdalena), Brauch, H. (Hiltrud), Fischer, H.-P., Ko, Y-D. (Yon-Dschun), Nevanlinna, H. (Heli), Muranen, T.A. (Taru), Aittomäki, K. (Kristiina), Blomqvist, C. (Carl), Bogdanova, N.V. (Natalia), Dörk, T. (Thilo), Lindblom, A. (Annika), Margolin, S. (Sara), Mannermaa, A. (Arto), Kataja, V. (Vesa), Kosma, V-M. (Veli-Matti), Hartikainen, J. (Jaana), Chenevix-Trench, G. (Georgia), Lambrechts, D. (Diether), Weltens, C. (Caroline), Limbergen, E. (Erik) van, Hatse, S. (Sigrid), Chang-Claude, J. (Jenny), Rudolph, A. (Anja), Seibold, P. (Petra), Flesch-Janys, D. (Dieter), Radice, P. (Paolo), Peterlongo, P. (Paolo), Bonnani, B. (Bernardo), Volorio, S. (Sara), Giles, G.G. (Graham), Severi, G. (Gianluca), Baglietto, L. (Laura), McLean, C.A. (Catriona Ann), Haiman, C.A. (Christopher), Henderson, B.E. (Brian), Schumacher, F.R. (Fredrick), Le Marchand, L. (Loic), Simard, J. (Jacques), Goldberg, M.S. (Mark), Labrèche, F. (France), Dumont, M. (Martine), Kristensen, V. (Vessela), Winqvist, R. (Robert), Pykäs, K. (Katri), Jukkola-Vuorinen, A. (Arja), Kauppila, S. (Saila), Andrulis, I.L. (Irene), Knight, J.A. (Julia), Glendon, G. (Gord), Mulligan, A.M. (Anna Marie), Devillee, P. (Peter), Tollenaar, R.A.E.M. (Rob), Seynaeve, C.M. (Caroline), Kriege, M. (Mieke), Figueroa, J.D. (Jonine), Chanock, S.J. (Stephen), Sherman, M.E. (Mark), Hooning, M.J. (Maartje), Hollestelle, A. (Antoinette), Ouweland, A.M.W. (Ans) van den, Deurzen, C.H.M. (Carolien) van, Li, J. (Jingmei), Czene, K. (Kamila), Humphreys, M.K. (Manjeet), Cox, A. (Angela), Cross, S.S. (Simon), Reed, M.W.R. (Malcolm), Shah, M. (Mitul), Jakubowska, A. (Anna), Lubinski, J. (Jan), Jaworska-Bieniek, K. (Katarzyna), Durda, K. (Katarzyna), Swerdlow, A.J. (Anthony ), Ashworth, A. (Alan), Orr, N. (Nick), Schoemaker, M. (Minouk), Couch, F.J. (Fergus), Hallberg, B. (Boubou), González-Neira, A. (Anna), Pita, G. (Guillermo), Alonso, M.R. (Rosario), Tessier, Y. (Yann), Vincent, D. (Daniel), Bacot, F. (Francois), Bolla, M.K. (Manjeet), Wang, Q. (Qing), Dennis, J. (Joe), Michailidou, K. (Kyriaki), Dunning, A.M. (Alison), Hall, P. (Per), Easton, D.F. (Douglas), Pharoah, P.D.P. (Paul), Schmidt, M.K. (Marjanka), Tomlinson, I.P. (Ian), and García-Closas, M. (Montserrat)

Abstract

Invasive lobular breast cancer (ILC) accounts for 10-15% of all invasive breast carcinomas. It is generally ER positive (ER+) and often associated with lobular carcinoma in situ (LCIS). Genome-wide association studies have identified more than 70 common polymorphisms that predispose to breast cancer, but these studies included predominantly ductal (IDC) carcinomas. To identify novel common polymorphisms that predispose to ILC and LCIS, we po

Published

2014

9. Genetic Predisposition to In Situ and Invasive Lobular Carcinoma of the Breast

Author

Gibson, G, Sawyer, E, Roylance, R, Petridis, C, Brook, MN, Nowinski, S, Papouli, E, Fletcher, O, Pinder, S, Hanby, A, Kohut, K, Gorman, P, Caneppele, M, Peto, J, Silva, IDS, Johnson, N, Swann, R, Dwek, M, Perkins, K-A, Gillett, C, Houlston, R, Ross, G, De Ieso, P, Southey, MC, Hopper, JL, Provenzano, E, Apicella, C, Wesseling, J, Cornelissen, S, Keeman, R, Fasching, PA, Jud, SM, Ekici, AB, Beckmann, MW, Kerin, MJ, Marme, F, Schneeweiss, A, Sohn, C, Burwinkel, B, Guenel, P, Truong, T, Laurent-Puig, P, Kerbrat, P, Bojesen, SE, Nordestgaard, BG, Nielsen, SF, Flyger, H, Milne, RL, Perez, JIA, Menendez, P, Benitez, J, Brenner, H, Dieffenbach, AK, Arndt, V, Stegmaier, C, Meindl, A, Lichtner, P, Schmutzler, RK, Lochmann, M, Brauch, H, Fischer, H-P, Ko, Y-D, Nevanlinna, H, Muranen, TA, Aittomaki, K, Blomqvist, C, Bogdanova, NV, Dork, T, Lindblom, A, Margolin, S, Mannermaa, A, Kataja, V, Kosma, V-M, Hartikainen, JM, Chenevix-Trench, G, Lambrechts, D, Weltens, C, Van Limbergen, E, Hatse, S, Chang-Claude, J, Rudolph, A, Seibold, P, Flesch-Janys, D, Radice, P, Peterlongo, P, Bonanni, B, Volorio, S, Giles, GG, Severi, G, Baglietto, L, Mclean, CA, Haiman, CA, Henderson, BE, Schumacher, F, Le Marchand, L, Simard, J, Goldberg, MS, Labreche, F, Dumont, M, Kristensen, V, Winqvist, R, Pylkas, K, Jukkola-Vuorinen, A, Kauppila, S, Andrulis, IL, Knight, JA, Glendon, G, Mulligan, AM, Devillee, P, Tollenaar, RAEM, Seynaeve, CM, Kriege, M, Figueroa, J, Chanock, SJ, Sherman, ME, Hooning, MJ, Hollestelle, A, van den Ouweland, AMW, van Deurzen, CHM, Li, J, Czene, K, Humphreys, K, Cox, A, Cross, SS, Reed, MWR, Shah, M, Jakubowska, A, Lubinski, J, Jaworska-Bieniek, K, Durda, K, Swerdlow, A, Ashworth, A, Orr, N, Schoemaker, M, Couch, FJ, Hallberg, E, Gonzalez-Neira, A, Pita, G, Alonso, MR, Tessier, DC, Vincent, D, Bacot, F, Bolla, MK, Wang, Q, Dennis, J, Michailidou, K, Dunning, AM, Hall, P, Easton, D, Pharoah, P, Schmidt, MK, Tomlinson, I, Garcia-Closas, M, Gibson, G, Sawyer, E, Roylance, R, Petridis, C, Brook, MN, Nowinski, S, Papouli, E, Fletcher, O, Pinder, S, Hanby, A, Kohut, K, Gorman, P, Caneppele, M, Peto, J, Silva, IDS, Johnson, N, Swann, R, Dwek, M, Perkins, K-A, Gillett, C, Houlston, R, Ross, G, De Ieso, P, Southey, MC, Hopper, JL, Provenzano, E, Apicella, C, Wesseling, J, Cornelissen, S, Keeman, R, Fasching, PA, Jud, SM, Ekici, AB, Beckmann, MW, Kerin, MJ, Marme, F, Schneeweiss, A, Sohn, C, Burwinkel, B, Guenel, P, Truong, T, Laurent-Puig, P, Kerbrat, P, Bojesen, SE, Nordestgaard, BG, Nielsen, SF, Flyger, H, Milne, RL, Perez, JIA, Menendez, P, Benitez, J, Brenner, H, Dieffenbach, AK, Arndt, V, Stegmaier, C, Meindl, A, Lichtner, P, Schmutzler, RK, Lochmann, M, Brauch, H, Fischer, H-P, Ko, Y-D, Nevanlinna, H, Muranen, TA, Aittomaki, K, Blomqvist, C, Bogdanova, NV, Dork, T, Lindblom, A, Margolin, S, Mannermaa, A, Kataja, V, Kosma, V-M, Hartikainen, JM, Chenevix-Trench, G, Lambrechts, D, Weltens, C, Van Limbergen, E, Hatse, S, Chang-Claude, J, Rudolph, A, Seibold, P, Flesch-Janys, D, Radice, P, Peterlongo, P, Bonanni, B, Volorio, S, Giles, GG, Severi, G, Baglietto, L, Mclean, CA, Haiman, CA, Henderson, BE, Schumacher, F, Le Marchand, L, Simard, J, Goldberg, MS, Labreche, F, Dumont, M, Kristensen, V, Winqvist, R, Pylkas, K, Jukkola-Vuorinen, A, Kauppila, S, Andrulis, IL, Knight, JA, Glendon, G, Mulligan, AM, Devillee, P, Tollenaar, RAEM, Seynaeve, CM, Kriege, M, Figueroa, J, Chanock, SJ, Sherman, ME, Hooning, MJ, Hollestelle, A, van den Ouweland, AMW, van Deurzen, CHM, Li, J, Czene, K, Humphreys, K, Cox, A, Cross, SS, Reed, MWR, Shah, M, Jakubowska, A, Lubinski, J, Jaworska-Bieniek, K, Durda, K, Swerdlow, A, Ashworth, A, Orr, N, Schoemaker, M, Couch, FJ, Hallberg, E, Gonzalez-Neira, A, Pita, G, Alonso, MR, Tessier, DC, Vincent, D, Bacot, F, Bolla, MK, Wang, Q, Dennis, J, Michailidou, K, Dunning, AM, Hall, P, Easton, D, Pharoah, P, Schmidt, MK, Tomlinson, I, and Garcia-Closas, M

Abstract

Invasive lobular breast cancer (ILC) accounts for 10-15% of all invasive breast carcinomas. It is generally ER positive (ER+) and often associated with lobular carcinoma in situ (LCIS). Genome-wide association studies have identified more than 70 common polymorphisms that predispose to breast cancer, but these studies included predominantly ductal (IDC) carcinomas. To identify novel common polymorphisms that predispose to ILC and LCIS, we pooled data from 6,023 cases (5,622 ILC, 401 pure LCIS) and 34,271 controls from 36 studies genotyped using the iCOGS chip. Six novel SNPs most strongly associated with ILC/LCIS in the pooled analysis were genotyped in a further 516 lobular cases (482 ILC, 36 LCIS) and 1,467 controls. These analyses identified a lobular-specific SNP at 7q34 (rs11977670, OR (95%CI) for ILC = 1.13 (1.09-1.18), P = 6.0 × 10(-10); P-het for ILC vs IDC ER+ tumors = 1.8 × 10(-4)). Of the 75 known breast cancer polymorphisms that were genotyped, 56 were associated with ILC and 15 with LCIS at P<0.05. Two SNPs showed significantly stronger associations for ILC than LCIS (rs2981579/10q26/FGFR2, P-het = 0.04 and rs889312/5q11/MAP3K1, P-het = 0.03); and two showed stronger associations for LCIS than ILC (rs6678914/1q32/LGR6, P-het = 0.001 and rs1752911/6q14, P-het = 0.04). In addition, seven of the 75 known loci showed significant differences between ER+ tumors with IDC and ILC histology, three of these showing stronger associations for ILC (rs11249433/1p11, rs2981579/10q26/FGFR2 and rs10995190/10q21/ZNF365) and four associated only with IDC (5p12/rs10941679; rs2588809/14q24/RAD51L1, rs6472903/8q21 and rs1550623/2q31/CDCA7). In conclusion, we have identified one novel lobular breast cancer specific predisposition polymorphism at 7q34, and shown for the first time that common breast cancer polymorphisms predispose to LCIS. We have shown that many of the ER+ breast cancer predisposition loci also predispose to ILC, although there is some heterogeneity between E

Published

2014

10. Provoking symptoms to relieve symptoms : A randomized controlled dismantling study of exposure therapy in irritable bowel syndrome

Author

Ljótsson, B., Hesser, Hugo, Andersson, E., Lackner, J. M., El Alaoui, S., Falk, L., Aspvall, K., Fransson, J., Hammarlund, K., Löfström, A., Nowinski, S., Lindfors, P., Hedman, E., Ljótsson, B., Hesser, Hugo, Andersson, E., Lackner, J. M., El Alaoui, S., Falk, L., Aspvall, K., Fransson, J., Hammarlund, K., Löfström, A., Nowinski, S., Lindfors, P., and Hedman, E.

Abstract

An internet-delivered cognitive behavioral treatment (ICBT) based on systematic exposure exercises has previously shown beneficial effects for patients with irritable bowel syndrome (IBS). Exposure exercises may be perceived as difficult for patients to perform because of the elicited short-term distress and clinicians may be reluctant to use these interventions. The aim of this study was to compare ICBT with the same protocol without systematic exposure (ICBT-WE) to assess if exposure had any incremental value. This randomized controlled dismantling study included 309 participants diagnosed with IBS. The treatment interventions lasted for 10 weeks and included online therapist contact. ICBT-WE comprised mindfulness, work with life values, acceptance, and encouraged reduced avoidance behaviors, while ICBT also included systematic exposure to IBS symptoms and related situations. Severity of IBS symptoms was measured with the Gastrointestinal Symptom Rating Scale-IBS version (GSRS-IBS). The between-group Cohen's don GSRS-IBS was 0.47(95% CI: 0.23-0.70) at post-treatment and 0.48 (95% CI: 0.20-0.76) at 6-month follow-up, favoring ICBT. We conclude that the systematic exposure included in the ICBT protocol has incremental effects over the other components in the protocol. This study provides evidence for the utility of exposure exercises in psychological treatments for IBS.

Published

2014

11. French Catholic activism in Algeria between colonization and development, 1930-65

Author

Nowinski, S., primary

Published

2013

12. Mapping field cancerisation and clonal evolution in IBD colons with dysplasia and colorectal cancer

Author

Yalchin, M., Curtius, K., Nowinski, S., Moorghen, M., Kimberley, C., Smith, K., Baker, A. M., Ibrahim Al Bakir, Mossner, M., Nadhamuni, V., Hart, A., and Graham, T.

13. Low-coverage whole genome sequencing of low-grade dysplasia strongly predicts advanced neoplasia risk in ulcerative colitis.

Author

Al Bakir I, Curtius K, Cresswell GD, Grant HE, Nasreddin N, Smith K, Nowinski S, Guo Q, Belnoue-Davis HL, Fisher J, Clarke T, Kimberley C, Mossner M, Dunne PD, Loughrey MB, Speight A, East JE, Wright NA, Rodriguez-Justo M, Jansen M, Moorghen M, Baker AM, Leedham SJ, Hart AL, and Graham TA

Abstract

Background: The risk of developing advanced neoplasia (AN; colorectal cancer and/or high-grade dysplasia) in ulcerative colitis (UC) patients with a low-grade dysplasia (LGD) lesion is variable and difficult to predict. This is a major challenge for effective clinical management., Objective: We aimed to provide accurate AN risk stratification in UC patients with LGD. We hypothesised that the pattern and burden of somatic genomic copy number alterations (CNAs) in LGD lesions could predict future AN risk., Design: We performed a retrospective multicentre validated case-control study using n=270 LGD samples from n=122 patients with UC. Patients were designated progressors (n=40) if they had a diagnosis of AN in the ~5 years following LGD diagnosis or non-progressors (n=82) if they remained AN-free during follow-up. DNA was extracted from the baseline LGD lesion, low-coverage whole genome sequencing performed and data processed to detect CNAs. Survival analysis was used to evaluate CNAs as predictors of future AN risk., Results: CNA burden was significantly higher in progressors than non-progressors (p=2×10 -6 in discovery cohort) and was a very significant predictor of AN risk in univariate analysis (OR=36; p=9×10 -7 ), outperforming existing clinical risk factors such as lesion size, shape and focality. Optimal risk prediction was achieved with a multivariate model combining CNA burden with the known clinical risk factor of incomplete LGD resection. Within-LGD lesion genetic heterogeneity did not confound risk prediction., Conclusion: Measurement of CNAs in LGD is an accurate predictor of AN risk in inflammatory bowel disease and is likely to support clinical management., Competing Interests: Competing interests: The authors are in discussions about potential commercialisation and clinical translation of the findings described here. AH has served as consultant, advisory board member or speaker for AbbVie, Arena, Atlantic, Bristol-Myers Squibb, Celgene, Celltrion, Falk, Galapogos, Lilly, Janssen, MSD, Napp Pharmaceuticals, Pfizer, Pharmacosmos, Roche, Shire and Takeda. KC has an investigator-led research grant from Phathom Pharmaceuticals. TAG and A-MB are named as coinventors on a patent application that describe a method for TCR sequencing (GB2305655.9), and TAG is named on a method to measure evolutionary dynamics in cancers using DNA methylation (GB2317139.0). TAG has received honorarium from Genentech and DAiNA therapeutics., (© Author(s) (or their employer(s)) 2025. Re-use permitted under CC BY-NC. No commercial re-use. See rights and permissions. Published by BMJ Group.)

Published

2025

14. Low coverage whole genome sequencing of low-grade dysplasia strongly predicts colorectal cancer risk in ulcerative colitis.

Author

Al Bakir I, Curtius K, Cresswell GD, Grant HE, Nasreddin N, Smith K, Nowinski S, Guo Q, Belnoue-Davis HL, Fisher J, Clarke T, Kimberley C, Mossner M, Dunne PD, Loughrey MB, Speight A, East JE, Wright NA, Rodriguez-Justo M, Jansen M, Moorghen M, Baker AM, Leedham SJ, Hart AL, and Graham TA

Abstract

Patients with inflammatory bowel disease (IBD) are at increased risk of colorectal cancer (CRC), and this risk increases dramatically in those who develop low-grade dysplasia (LGD). However, there is currently no accurate way to risk-stratify patients with LGD, leading to both over- and under-treatment of cancer risk. Here we show that the burden of somatic copy number alterations (CNAs) within resected LGD lesions strongly predicts future cancer development. We performed a retrospective multi-centre validated case-control study of n=122 patients (40 progressors, 82 non-progressors, 270 LGD regions). Low coverage whole genome sequencing revealed CNA burden was significantly higher in progressors than non-progressors (p=2×10 -6 in discovery cohort) and was a very significant predictor of CRC risk in univariate analysis (odds ratio = 36; p=9×10 -7 ), outperforming existing clinical risk factors such as lesion size, shape and focality. Optimal risk prediction was achieved with a multivariate model combining CNA burden with the known clinical risk factor of incomplete LGD resection. The measurement of CNAs in LGD lesions is a robust, low-cost and rapidly translatable predictor of CRC risk in IBD that can be used to direct management and so prevent CRC in high-risk individuals whilst sparing those at low-risk from unnecessary intervention., Competing Interests: Competing Interests The authors are in discussions about potential commercialisation and clinical translation of the findings described here. Professor Hart has served as consultant, advisory board member or speaker for AbbVie, Arena, Atlantic, Bristol-Myers Squibb, Celgene, Celltrion, Falk, Galapogos, Lilly, Janssen, MSD, Napp Pharmaceuticals, Pfizer, Pharmacosmos, Roche, Shire and Takeda. K Curtius has an investigator-led research grant from Phathom Pharmaceuticals.

Published

2024

15. Evolutionary and immune microenvironment dynamics during neoadjuvant treatment of oesophagael adenocarcinoma.

Author

Barroux M, Househam J, Lakatos E, Ronel T, Baker AM, Salié H, Mossner M, Smith K, Kimberley C, Nowinski S, Berner A, Gunasri V, Jansen M, Caravagna G, Steiger K, Slotta-Huspenina J, Weichert W, Alberstmeier M, Chain B, Friess H, Bengsch B, Schmid R, Siveke J, Quante M, and Graham T

Abstract

Locally advanced oesophageal adenocarcinoma (EAC) remains difficult to treat because of common resistance to neoadjuvant therapy and high recurrence rates. The ecological and evolutionary dynamics responsible for treatment failure are incompletely understood. Here, we performed a comprehensive multi-omic analysis of samples collected from EAC patients in the MEMORI clinical trial, revealing major changes in gene expression profiles and immune microenvironment composition that did not appear to be driven by changes in clonal composition. Multi-region multi-timepoint whole exome (300x depth) and paired transcriptome sequencing was performed on 27 patients pre-, during and after neoadjuvant treatment. EAC showed major transcriptomic changes during treatment with upregulation of immune and stromal pathways and oncogenic pathways such as KRAS, Hedgehog and WNT. However, genetic data revealed that clonal sweeps were rare, suggesting that gene expression changes were not clonally driven. Additional longitudinal image mass cytometry was performed in a subset of 15 patients and T-cell receptor sequencing in 10 patients, revealing remodelling of the T-cell compartment during treatment and other shifts in microenvironment composition. The presence of immune escape mechanisms and a lack of clonal T-cell expansions were linked to poor clinical treatment response. This study identifies profound transcriptional changes during treatment with limited evidence that clonal replacement is the cause, suggesting phenotypic plasticity and immune dynamics as mechanisms for therapy resistance with pharmacological relevance.

Published

2023

16. Genomic analysis defines clonal relationships of ductal carcinoma in situ and recurrent invasive breast cancer.

Author

Lips EH, Kumar T, Megalios A, Visser LL, Sheinman M, Fortunato A, Shah V, Hoogstraat M, Sei E, Mallo D, Roman-Escorza M, Ahmed AA, Xu M, van den Belt-Dusebout AW, Brugman W, Casasent AK, Clements K, Davies HR, Fu L, Grigoriadis A, Hardman TM, King LM, Krete M, Kristel P, de Maaker M, Maley CC, Marks JR, Menegaz BA, Mulder L, Nieboer F, Nowinski S, Pinder S, Quist J, Salinas-Souza C, Schaapveld M, Schmidt MK, Shaaban AM, Shami R, Sridharan M, Zhang J, Stobart H, Collyar D, Nik-Zainal S, Wessels LFA, Hwang ES, Navin NE, Futreal PA, Thompson AM, Wesseling J, and Sawyer EJ

Subjects

Biomarkers, Tumor analysis, Biomarkers, Tumor genetics, Female, Genomics, Humans, Neoplasm Recurrence, Local genetics, Breast Neoplasms genetics, Breast Neoplasms pathology, Carcinoma, Ductal, Breast genetics, Carcinoma, Intraductal, Noninfiltrating genetics, Carcinoma, Intraductal, Noninfiltrating pathology

Abstract

Ductal carcinoma in situ (DCIS) is the most common form of preinvasive breast cancer and, despite treatment, a small fraction (5-10%) of DCIS patients develop subsequent invasive disease. A fundamental biologic question is whether the invasive disease arises from tumor cells in the initial DCIS or represents new unrelated disease. To address this question, we performed genomic analyses on the initial DCIS lesion and paired invasive recurrent tumors in 95 patients together with single-cell DNA sequencing in a subset of cases. Our data show that in 75% of cases the invasive recurrence was clonally related to the initial DCIS, suggesting that tumor cells were not eliminated during the initial treatment. Surprisingly, however, 18% were clonally unrelated to the DCIS, representing new independent lineages and 7% of cases were ambiguous. This knowledge is essential for accurate risk evaluation of DCIS, treatment de-escalation strategies and the identification of predictive biomarkers., (© 2022. The Author(s).)

Published

2022

17. Lipogenic signalling modulates prostate cancer cell adhesion and migration via modification of Rho GTPases.

Author

De Piano M, Manuelli V, Zadra G, Otte J, Edqvist PD, Pontén F, Nowinski S, Niaouris A, Grigoriadis A, Loda M, Van Hemelrijck M, and Wells CM

Subjects

Cell Adhesion genetics, Cell Line, Tumor, Cell Movement genetics, Cell Proliferation genetics, Gene Expression Regulation, Neoplastic genetics, Humans, Male, Phosphorylation genetics, Prostate metabolism, Prostate pathology, Prostatic Neoplasms metabolism, Prostatic Neoplasms pathology, Signal Transduction genetics, Fatty Acid Synthase, Type I genetics, Lipogenesis genetics, Prostatic Neoplasms genetics, cdc42 GTP-Binding Protein genetics, rho GTP-Binding Proteins genetics

Abstract

Fatty acid synthase (FASN) is commonly overexpressed in prostate cancer and associated with tumour progression. FASN is responsible for de novo synthesis of the fatty acid palmitate; the building block for protein palmitoylation. Recent work has suggested that alongside its established role in promoting cell proliferation FASN may also promote invasion. We now find depletion of FASN expression increases prostate cancer cell adhesiveness, impairs HGF-mediated cell migration and reduces 3D invasion. These changes in motility suggest that FASN can mediate actin cytoskeletal remodelling; a process known to be downstream of Rho family GTPases. Here, we demonstrate that modulation of FASN expression specifically impacts on the palmitoylation of the atypical GTPase RhoU. Impaired RhoU activity in FASN depleted cells leads to reduced adhesion turnover downstream of paxillin serine phosphorylation, which is rescued by addition of exogenous palmitate. Moreover, canonical Cdc42 expression is dependent on the palmitoylation status of RhoU. Thus we uncover a novel relationship between FASN, RhoU and Cdc42 that directly influences cell migration potential. These results provide compelling evidence that FASN activity directly promotes cell migration and supports FASN as a potential therapeutic target in metastatic prostate cancer.

Published

2020

18. Systematic identification of functionally relevant risk alleles to stratify aggressive versus indolent prostate cancer.

Author

Nowinski S, Santaolalla A, O'Leary B, Loda M, Mirchandani A, Emberton M, Van Hemelrijck M, and Grigoriadis A

Abstract

Novel approaches for classification, including molecular features, are needed to direct therapy for men with low-grade prostate cancer (PCa), especially men on active surveillance. Risk alleles identified from genome-wide association studies (GWAS) could improve prognostication. Those risk alleles that coincided with genes and somatic copy number aberrations associated with progression of PCa were selected as the most relevant for prognostication. In a systematic literature review, a total of 698 studies were collated. Fifty-three unique SNPs residing in 29 genomic regions, including 8q24, 10q11 and 19q13, were associated with PCa progression. Functional studies implicated 21 of these single nucleotide polymorphisms (SNPs) as modulating the expression of genes in the androgen receptor pathway and several other oncogenes. In particular, 8q24, encompassing MYC , harbours a high density of SNPs conferring unfavourable pathological characteristics in low-grade PCa, while a copy number gain of MYC in low-grade PCa was associated with prostate-specific antigen recurrence after radical prostatectomy. By combining GWAS data with gene expression and structural rearrangements, risk alleles were identified that could provide a new basis for developing a prognostication tool to guide therapy for men with early prostate cancer., Competing Interests: CONFLICTS OF INTEREST The authors declare no conflicts of interest.

Published

2018

19. PIK3CA mutations are common in lobular carcinoma in situ, but are not a biomarker of progression.

Author

Shah V, Nowinski S, Levi D, Shinomiya I, Kebaier Ep Chaabouni N, Gillett C, Grigoriadis A, Graham TA, Roylance R, Simpson MA, Pinder SE, and Sawyer EJ

Subjects

Alleles, Biomarkers, Chromosome Mapping, Class I Phosphatidylinositol 3-Kinases, DNA Copy Number Variations, DNA Mutational Analysis, Disease Progression, Exome, Female, Gene Frequency, Genetic Heterogeneity, Genotype, High-Throughput Nucleotide Sequencing, Humans, Immunohistochemistry, In Situ Hybridization, Fluorescence, Microsatellite Repeats, Phosphatidylinositol 3-Kinases metabolism, Polymorphism, Single Nucleotide, Breast Carcinoma In Situ genetics, Breast Carcinoma In Situ pathology, Breast Neoplasms genetics, Breast Neoplasms pathology, Carcinoma, Lobular genetics, Carcinoma, Lobular pathology, Mutation, Phosphatidylinositol 3-Kinases genetics

Abstract

Background: Lobular carcinoma in situ (LCIS) is a non-invasive breast lesion that is typically found incidentally on biopsy and is often associated with invasive lobular carcinoma (ILC). LCIS is considered by some to be a risk factor for future breast cancer rather than a true precursor lesion. The aim of this study was to identify genetic changes that could be used as biomarkers of progression of LCIS to invasive disease using cases of pure LCIS and comparing their genetic profiles to LCIS which presented contemporaneously with associated ILC, on the hypothesis that the latter represents LCIS that has already progressed., Methods: Somatic copy number aberrations (SCNAs) were assessed by SNP array in three subgroups: pure LCIS, LCIS associated with ILC and the paired ILC. In addition exome sequencing was performed on seven fresh frozen samples of LCIS associated with ILC, to identify recurrent somatic mutations., Results: The copy number profiles of pure LCIS and LCIS associated with ILC were almost identical. However, four SCNAs were more frequent in ILC than LCIS associated with ILC, including gain/amplification of CCND1. CCND1 protein over-expression assessed by immunohistochemical analysis in a second set of samples from 32 patients with pure LCIS and long-term follow up, was associated with invasive recurrence (P = 0.02, Fisher's exact test). Exome sequencing revealed that PIK3CA mutations were as frequent as CDH1 mutations in LCIS, but were not a useful biomarker of LCIS progression as they were as frequent in pure LCIS as in LCIS associated with ILC. We also observed heterogeneity of PIK3CA mutations and evidence of sub-clonal populations in LCIS irrespective of whether they were associated with ILC., Conclusions: Our data shows that pure LCIS and LCIS co-existing with ILC have very similar SCNA profiles, supporting the hypothesis that LCIS is a true precursor lesion. We have provided evidence that over-expression of CCND1 may identify a subgroup of patients with pure LCIS who are more likely to develop invasive disease, in contrast to PIK3CA mutations, which occur too early in lobular tumorigenesis to be informative.

Published

2017

20. Genetic predisposition to in situ and invasive lobular carcinoma of the breast.

Author

Sawyer E, Roylance R, Petridis C, Brook MN, Nowinski S, Papouli E, Fletcher O, Pinder S, Hanby A, Kohut K, Gorman P, Caneppele M, Peto J, Dos Santos Silva I, Johnson N, Swann R, Dwek M, Perkins KA, Gillett C, Houlston R, Ross G, De Ieso P, Southey MC, Hopper JL, Provenzano E, Apicella C, Wesseling J, Cornelissen S, Keeman R, Fasching PA, Jud SM, Ekici AB, Beckmann MW, Kerin MJ, Marme F, Schneeweiss A, Sohn C, Burwinkel B, Guénel P, Truong T, Laurent-Puig P, Kerbrat P, Bojesen SE, Nordestgaard BG, Nielsen SF, Flyger H, Milne RL, Perez JI, Menéndez P, Benitez J, Brenner H, Dieffenbach AK, Arndt V, Stegmaier C, Meindl A, Lichtner P, Schmutzler RK, Lochmann M, Brauch H, Fischer HP, Ko YD, Nevanlinna H, Muranen TA, Aittomäki K, Blomqvist C, Bogdanova NV, Dörk T, Lindblom A, Margolin S, Mannermaa A, Kataja V, Kosma VM, Hartikainen JM, Chenevix-Trench G, Lambrechts D, Weltens C, Van Limbergen E, Hatse S, Chang-Claude J, Rudolph A, Seibold P, Flesch-Janys D, Radice P, Peterlongo P, Bonanni B, Volorio S, Giles GG, Severi G, Baglietto L, McLean CA, Haiman CA, Henderson BE, Schumacher F, Le Marchand L, Simard J, Goldberg MS, Labrèche F, Dumont M, Kristensen V, Winqvist R, Pylkäs K, Jukkola-Vuorinen A, Kauppila S, Andrulis IL, Knight JA, Glendon G, Mulligan AM, Devillee P, Tollenaar RA, Seynaeve CM, Kriege M, Figueroa J, Chanock SJ, Sherman ME, Hooning MJ, Hollestelle A, van den Ouweland AM, van Deurzen CH, Li J, Czene K, Humphreys K, Cox A, Cross SS, Reed MW, Shah M, Jakubowska A, Lubinski J, Jaworska-Bieniek K, Durda K, Swerdlow A, Ashworth A, Orr N, Schoemaker M, Couch FJ, Hallberg E, González-Neira A, Pita G, Alonso MR, Tessier DC, Vincent D, Bacot F, Bolla MK, Wang Q, Dennis J, Michailidou K, Dunning AM, Hall P, Easton D, Pharoah P, Schmidt MK, Tomlinson I, and Garcia-Closas M

Subjects

Case-Control Studies, Female, Genome-Wide Association Study, Genotype, Humans, Middle Aged, Polymorphism, Single Nucleotide genetics, Breast Neoplasms genetics, Carcinoma in Situ genetics, Carcinoma, Lobular genetics, Genetic Predisposition to Disease genetics

Abstract

Invasive lobular breast cancer (ILC) accounts for 10-15% of all invasive breast carcinomas. It is generally ER positive (ER+) and often associated with lobular carcinoma in situ (LCIS). Genome-wide association studies have identified more than 70 common polymorphisms that predispose to breast cancer, but these studies included predominantly ductal (IDC) carcinomas. To identify novel common polymorphisms that predispose to ILC and LCIS, we pooled data from 6,023 cases (5,622 ILC, 401 pure LCIS) and 34,271 controls from 36 studies genotyped using the iCOGS chip. Six novel SNPs most strongly associated with ILC/LCIS in the pooled analysis were genotyped in a further 516 lobular cases (482 ILC, 36 LCIS) and 1,467 controls. These analyses identified a lobular-specific SNP at 7q34 (rs11977670, OR (95%CI) for ILC = 1.13 (1.09-1.18), P = 6.0 × 10(-10); P-het for ILC vs IDC ER+ tumors = 1.8 × 10(-4)). Of the 75 known breast cancer polymorphisms that were genotyped, 56 were associated with ILC and 15 with LCIS at P<0.05. Two SNPs showed significantly stronger associations for ILC than LCIS (rs2981579/10q26/FGFR2, P-het = 0.04 and rs889312/5q11/MAP3K1, P-het = 0.03); and two showed stronger associations for LCIS than ILC (rs6678914/1q32/LGR6, P-het = 0.001 and rs1752911/6q14, P-het = 0.04). In addition, seven of the 75 known loci showed significant differences between ER+ tumors with IDC and ILC histology, three of these showing stronger associations for ILC (rs11249433/1p11, rs2981579/10q26/FGFR2 and rs10995190/10q21/ZNF365) and four associated only with IDC (5p12/rs10941679; rs2588809/14q24/RAD51L1, rs6472903/8q21 and rs1550623/2q31/CDCA7). In conclusion, we have identified one novel lobular breast cancer specific predisposition polymorphism at 7q34, and shown for the first time that common breast cancer polymorphisms predispose to LCIS. We have shown that many of the ER+ breast cancer predisposition loci also predispose to ILC, although there is some heterogeneity between ER+ lobular and ER+ IDC tumors. These data provide evidence for overlapping, but distinct etiological pathways within ER+ breast cancer between morphological subtypes.

Published

2014

21. Provoking symptoms to relieve symptoms: a randomized controlled dismantling study of exposure therapy in irritable bowel syndrome.

Author

Ljótsson B, Hesser H, Andersson E, Lackner JM, El Alaoui S, Falk L, Aspvall K, Fransson J, Hammarlund K, Löfström A, Nowinski S, Lindfors P, and Hedman E

Subjects

Adult, Combined Modality Therapy, Female, Humans, Internet, Male, Therapy, Computer-Assisted, Treatment Outcome, Young Adult, Cognitive Behavioral Therapy, Implosive Therapy, Irritable Bowel Syndrome psychology, Irritable Bowel Syndrome therapy

Abstract

An internet-delivered cognitive behavioral treatment (ICBT) based on systematic exposure exercises has previously shown beneficial effects for patients with irritable bowel syndrome (IBS). Exposure exercises may be perceived as difficult for patients to perform because of the elicited short-term distress and clinicians may be reluctant to use these interventions. The aim of this study was to compare ICBT with the same protocol without systematic exposure (ICBT-WE) to assess if exposure had any incremental value. This randomized controlled dismantling study included 309 participants diagnosed with IBS. The treatment interventions lasted for 10 weeks and included online therapist contact. ICBT-WE comprised mindfulness, work with life values, acceptance, and encouraged reduced avoidance behaviors, while ICBT also included systematic exposure to IBS symptoms and related situations. Severity of IBS symptoms was measured with the Gastrointestinal Symptom Rating Scale - IBS version (GSRS-IBS). The between-group Cohen's d on GSRS-IBS was 0.47 (95% CI: 0.23-0.70) at post-treatment and 0.48 (95% CI: 0.20-0.76) at 6-month follow-up, favoring ICBT. We conclude that the systematic exposure included in the ICBT protocol has incremental effects over the other components in the protocol. This study provides evidence for the utility of exposure exercises in psychological treatments for IBS., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014