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2. Variation in the risk of colorectal cancer in families with Lynch syndrome: a retrospective cohort study

Author

Win, Aung Ko, Dowty, James G., Reece, Jeanette C., Lee, Grant, Templeton, Allyson S., Plazzer, John-Paul, Buchanan, Daniel D., Akagi, Kiwamu, Aksoy, Seçil, Alonso, Angel, Alvarez, Karin, Amor, David J., Ankathil, Ravindran, Aretz, Stefan, Arnold, Julie L., Aronson, Melyssa, Austin, Rachel, Backman, Ann-Sofie, Bajwa-ten Broeke, Sanne W., Barca-Tierno, Verónica, Barwell, Julian, Bernstein, Inge, Berthet, Pascaline, Betz, Beate, Bignon, Yves-Jean, Boisjoli, Talya, Bonadona, Valérie, Briollais, Laurent, Brunet, Joan, Bucksch, Karolin, Buecher, Bruno, Buettner, Reinhard, Burn, John, Caldés, Trinidad, Capella, Gabriel, Caron, Olivier, Casey, Graham, Chew, Min H., Choi, Yun-hee, Church, James, Clendenning, Mark, Colas, Chrystelle, Cops, Elisa J., Coupier, Isabelle, Cruz-Correa, Marcia, de la Chapelle, Albert, de Wind, Niels, Dębniak, Tadeusz, Della Valle, Adriana, Delnatte, Capuccine, Dhooge, Marion, Dominguez-Valentin, Mev, Drouet, Youenn, Duijkers, Floor A., Engel, Christoph, Esperon, Patricia, Evans, D. Gareth, Falcón de Vargas, Aída, Figueiredo, Jane C, Foulkes, William, Fourme, Emmanuelle, Frebourg, Thierry, Gallinger, Steven, Garre, Pilar, Genuardi, Maurizio, Gerdes, Anne-Marie, Gima, Lauren M., Giraud, Sophie, Goodwin, Annabel, Görgens, Heike, Green, Kate, Guillem, Jose, Guillén-Ponce, Carmen, Guimbaud, Roselyne, Guindalini, Rodrigo S.C., Half, Elizabeth E., Hall, Michael J, Hampel, Heather, Hansen, Thomas V.O., Heinimann, Karl, Hes, Frederik J., Hill, James, Ho, Judy W.C., Holinski-Feder, Elke, Hoogerbrugge, Nicoline, Hüneburg, Robert, Huntley, Vanessa, James, Paul A., Jensen, Uffe B, John, Thomas, Juhari, Wan K.W., Kalady, Matthew, Kastrinos, Fay, Kloor, Matthias, Kohonen-Corish, Maija RJ, Krogh, Lotte N., Kupfer, Sonia S., Ladabaum, Uri, Lagerstedt-Robinson, Kristina, Lalloo, Fiona, Lasset, Christine, Latchford, Andrew, Laurent-Puig, Pierre, Lautrup, Charlotte K., Leggett, Barbara A., Lejeune, Sophie, LeMarchand, Loic, Ligtenberg, Marjolijn, Lindor, Noralane, Loeffler, Markus, Longy, Michel, Lopez, Francisco, Lowery, Jan, Lubiński, Jan, Lucassen, Anneke M, Lynch, Patrick M., Malińska, Karolina, Matsubara, Nagahide, Mecklin, Jukka-Pekka, Møller, Pål, Monahan, Kevin, Morrison, Patrick J., Nattermann, Jacob, Navarro, Matilde, Neffa, Florencia, Neklason, Deborah, Newcomb, Polly A., Ngeow, Joanne, Nichols, Cassandra, Nielsen, Maartje, Nixon, Dawn M., Nogues, Catherine, Okkels, Henrik, Olschwang, Sylviane, Pachter, Nicholas, Pai, Rish K., Palmero, Edenir I., Pande, Mala, Parry, Susan, Patel, Swati G., Pearlman, Rachel, Perne, Claudia, Pineda, Marta, Poplawski, Nicola K, Pylvänäinen, Kirsi, Qiu, Jay, Rahner, Nils, Ramesar, Raj, Rasmussen, Lene J., Redler, Silke, Reis, Rui M., Ricciardiello, Luigi, Rogoża-Janiszewska, Emilia, Rosty, Christophe, Samadder, N. Jewel, Sampson, Julian R., Schackert, Hans K., Schmiegel, Wolff, Schulmann, Karsten, Schuster, Helène, Scott, Rodney, Senter, Leigha, Seppälä, Toni T, Shtoyerman, Rakefet, Sijmons, Rolf H., Snyder, Carrie, Solomon, Ilana B., Soto, Jose Luis, Southey, Melissa C., Spigelman, Allan, Spirandelli, Florencia, Spurdle, Amanda B., Steinke-Lange, Verena, Stoffel, Elena M., Strassburg, Christian P., Sunde, Lone, Susman, Rachel, Syngal, Sapna, Tanakaya, Kohji, Tezcan, Gülçin, Therkildsen, Christina, Thibodeau, Steve, Tomita, Naohiro, Tucker, Katherine M., Tunca, Berrin, Turchetti, Daniela, Uhrhammer, Nancy, Utsunomiya, Joji, Vaccaro, Carlos, van Duijnhoven, Fränzel J.B., van Wanzeele, Meghan J., Vangala, Deepak B., Vasen, Hans F.A., von Knebel Doeberitz, Magnus, von Salomé, Jenny, Wadt, Karin A.W., Ward, Robyn L., Weitz, Jürgen, Weitzel, Jeffrey N., Williams, Heinric, Winship, Ingrid, Wise, Paul E., Wods, Julie, Woods, Michael O., Yamaguchi, Tatsuro, Zachariae, Silke, Zahary, Mohd N., Hopper, John L., Haile, Robert W., Macrae, Finlay A., Möslein, Gabriela, and Jenkins, Mark A.

Published
2021
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8. Variation in the Risk of Colorectal Cancer for Lynch Syndrome: A retrospective family cohort study

Author

Win, Aung Ko, Dowty, James G., Reece, Jeanette C., Lee, Grant, Templeton, Allyson S., Plazzer, John-Paul, Buchanan, Daniel D., Akagi, Kiwamu, Aksoy, Seçil, Alonso, Angel, Alvarez, Karin, Amor, David J., Ankathil, Ravindran, Aretz, Stefan, Arnold, Julie L., Aronson, Melyssa, Austin, Rachel, Backman, Ann-Sofie, Bajwa–ten Broeke, Sanne W., Barca-Tierno, Verónica, Barwell, Julian, Bernstein, Inge, Berthet, Pascaline, Betz, Beate, Bignon, Yves-Jean, Boisjoli, Talya, Bonadona, Valérie, Briollais, Laurent, Brunet, Joan, Bucksch, Karolin, Buecher, Bruno, Buettner, Reinhard, Burn, John, Caldés, Trinidad, Capella, Gabriel, Caron, Olivier, Casey, Graham, Chew, Min H., Choi, Yun-hee, Church, James, Clendenning, Mark, Colas, Chrystelle, Cops, Elisa J., Coupier, Isabelle, Cruz-Correa, Marcia, de la Chapelle, Albert, de Wind, Niels, Dębniak, Tadeusz, Della Valle, Adriana, Delnatte, Capuccine, Dhooge, Marion, Dominguez-Valentin, Mev, Drouet, Youenn, Duijkers, Floor A., Engel, Christoph, Esperon, Patricia, Evans, D. Gareth, de Vargas, Aída Falcón, Figueiredo, Jane C, Foulkes, William, Fourme, Emmanuelle, Frebourg, Thierry, Gallinger, Steven, Garre, Pilar, Genuardi, Maurizio, Gerdes, Anne-Marie, Gima, Lauren M., Giraud, Sophie, Goodwin, Annabel, Görgens, Heike, Green, Kate, Guillem, Jose, Guillén-Ponce, Carmen, Guimbaud, Roselyne, Guindalini, Rodrigo S. C., Half, Elizabeth E., Hall, Michael J, Hampel, Heather, Hansen, Thomas V. O., Heinimann, Karl, Hes, Frederik J., Hill, James, Ho, Judy W.C., Holinski-Feder, Elke, Hoogerbrugge, Nicoline, Hüneburg, Robert, Huntley, Vanessa, James, Paul A., Jensen, Uffe B, John, Thomas, Juhari, Wan K.W., Kalady, Matthew, Kastrinos, Fay, Kloor, Matthias, Kohonen-Corish, Maija RJ, Krogh, Lotte N., Kupfer, Sonia S., Ladabaum, Uri, Lagerstedt-Robinson, Kristina, Lalloo, Fiona, Lasset, Christine, Latchford, Andrew, Laurent-Puig, Pierre, Lautrup, Charlotte K., Leggett, Barbara A., Lejeune, Sophie, LeMarchand, Loic, Ligtenberg, Marjolijn, Lindor, Noralane, Loeffler, Markus, Longy, Michel, Lopez, Francisco, Lowery, Jan, Lubiński, Jan, Lucassen, Anneke M, Lynch, Patrick M., Malińska, Karolina, Matsubara, Nagahide, Mecklin, Jukka-Pekka, Møller, Pål, Monahan, Kevin, Morrison, Patrick J., Nattermann, Jacob, Navarro, Matilde, Neffa, Florencia, Neklason, Deborah, Newcomb, Polly A., Ngeow, Joanne, Nichols, Cassandra, Nielsen, Maartje, Nixon, Dawn M., Nogues, Catherine, Okkels, Henrik, Olschwang, Sylviane, Pachter, Nicholas, Pai, Rish K., Palmero, Edenir I., Pande, Mala, Parry, Susan, Patel, Swati G., Pearlman, Rachel, Perne, Claudia, Pineda, Marta, Poplawski, Nicola K, Pylvänäinen, Kirsi, Qiu, Jay, Rahner, Nils, Ramesar, Raj, Rasmussen, Lene J., Redler, Silke, Reis, Rui M., Ricciardiello, Luigi, Rogoża-Janiszewska, Emilia, Rosty, Christophe, Samadder, N. Jewel, Sampson, Julian R., Schackert, Hans K., Schmiegel, Wolff, Schulmann, Karsten, Schuster, Helène, Scott, Rodney, Senter, Leigha, Seppälä, Toni T, Shtoyerman, Rakefet, Sijmons, Rolf H., Snyder, Carrie, Solomon, Ilana B., Soto, Jose Luis, Southey, Melissa C., Spigelman, Allan, Spirandelli, Florencia, Spurdle, Amanda B., Steinke-Lange, Verena, Stoffel, Elena M., Strassburg, Christian P., Sunde, Lone, Susman, Rachel, Syngal, Sapna, Tanakaya, Kohji, Tezcan, Gülçin, Therkildsen, Christina, Thibodeau, Steve, Tomita, Naohiro, Tucker, Katherine M., Tunca, Berrin, Turchetti, Daniela, Uhrhammer, Nancy, Utsunomiya, Joji, Vaccaro, Carlos, van Duijnhoven, Fränzel J.B., van Wanzeele, Meghan J., Vangala, Deepak B., Vasen, Hans F.A., von Knebel Doeberitz, Magnus, von Salomé, Jenny, Wadt, Karin A. W., Ward, Robyn L., Weitz, Jürgen, Weitzel, Jeffrey N., Williams, Heinric, Winship, Ingrid, Wise, Paul E., Wods, Julie, Woods, Michael O., Yamaguchi, Tatsuro, Zachariae, Silke, Zahary, Mohd N., Hopper, John L., Haile, Robert W., Macrae, Finlay A., Möslein, Gabriela, and Jenkins, Mark A.

Subjects
Article
Abstract

BACKGROUND: Current clinical practice guidelines for carriers of pathogenic variants of DNA mismatch repair genes (Lynch syndrome) are based on the average age-specific cumulative risk (penetrance) of colorectal cancer for all carriers of pathogenic variants in the same gene. We aimed to estimate how much penetrance varies between carriers of pathogenic variants in the same gene by sex and continent of residence of the carrier. METHODS: We studied 79,809 relatives from 5,255 families, of at least three relatives, in which at least one was a confirmed carrier of a pathogenic or likely pathogenic variant in a mismatch repair gene (1,829 MLH1, 2,179 MSH2, 798 MSH6, 449 PMS2), recruited in 15 countries from North America, Europe and Australasia by the collaborative centres of the International Mismatch Repair Consortium. We used modified segregation analysis conditioned on ascertainment to estimate the average penetrance and modelled unmeasured polygenic factors to estimate the variation in penetrance of colorectal cancer. The existence of familial risk factors modifying colorectal cancer risk for Lynch syndrome carriers was tested using a Wald p-value for the null hypothesis that the polygenic standard deviation is zero. FINDINGS: There was strong evidence of the existence of familial risk factors modifying colorectal cancer risk for Lynch syndrome carriers (pT variant. The variation was more prominent for MLH1 and MSH2 variant carriers; depending on gene, sex, and continent, with 7–56% of carriers having a risk of colorectal cancer to age 80 of less than 20%, and 9–44% having a risk of more than 80%, while only 10–19% had a risk of 40–60%. INTERPRETATION: Our study findings highlight the important role of risk modifiers, which could lead to personalised risk assessment for precision prevention and early detection of colorectal cancer for Lynch syndrome.

Published
2021

9. The Apparent Genetic Anticipation in PMS2-Associated Lynch Syndrome Families Is Explained by Birth-cohort Effect

Author

ten Broeke, Sanne W., primary, Rodríguez-Girondo, Mar, additional, Suerink, Manon, additional, Aretz, Stefan, additional, Bernstein, Inge, additional, Capellá, Gabriel, additional, Engel, Christoph, additional, Gomez-Garcia, Encarna B., additional, van Hest, Liselot P., additional, von Knebel Doeberitz, Magnus, additional, Lagerstedt-Robinson, Kristina, additional, Letteboer, Tom G.W., additional, Moller, Pal, additional, van Os, Theo A., additional, Pineda, Marta, additional, Rahner, Nils, additional, Olderode-Berends, Maran J.W., additional, von Salomé, Jenny, additional, Schackert, Hans K., additional, Spruijt, Liesbeth, additional, Steinke-Lange, Verena, additional, Wagner, Anja, additional, Tops, Carli M.J., additional, and Nielsen, Maartje, additional

Published
2019
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10. Sequence features of HLA-DRB1 locus define putative basis for gene conversion and point mutations

Author

von Salomé Jenny and Kukkonen Jyrki P

Subjects
Biotechnology, TP248.13-248.65, Genetics, QH426-470
Abstract

Abstract Background HLA/MHC class II molecules show high degree of polymorphism in the human population. The individual polymorphic motifs have been suggested to be propagated and mixed by transfer of genetic material (recombination, gene conversion) between alleles, but no clear molecular basis for this has been identified as yet. A large number of MHC class II allele sequences is publicly available and could be used to analyze the sequence features behind the recombination, revealing possible basis for such recombination processes both in HLA class II genes and other genes, which recombination acts upon. Results In this study we analyzed the vast dataset of human allelic variants (49 full coding sequences, 374 full exon 2 sequences) of the most polymorphic MHC class II locus, HLA-DRB1, and identified many previously unknown sequence features possibly contributing to the recombination. The CpG-dinucleotide content of exon 2 (containing the antigen-binding sites and subsequently a high degree of polymorphism) was much elevated as compared to the other exons despite similar overall G+C content. Furthermore, the CpG pattern was highly conserved. We also identified more complex, highly conserved sequence motifs in exon 2. Some of these can be identified as putative recombination motifs previously found in other genes, but most are previously unidentified. Conclusion The identified sequence features could putatively act in recombination allowing either less (CpG dinucleotides) or more specific DNA cleavage (complex sequences) or homologous recombination (complex sequences).

Published
2008
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12. Genetic anticipation in Swedish Lynch syndrome families

Author

von Salomé, Jenny, Boonstra, Philip S., Karimi, Masoud, Silander, Gustav, Stenmark-Askmalm, Marie, Gebre-Medhin, Samuel, Aravidis, Christos, Nilbert, Mef, Lindblom, Annika, Lagerstedt-Robinson, Kristina, von Salomé, Jenny, Boonstra, Philip S., Karimi, Masoud, Silander, Gustav, Stenmark-Askmalm, Marie, Gebre-Medhin, Samuel, Aravidis, Christos, Nilbert, Mef, Lindblom, Annika, and Lagerstedt-Robinson, Kristina

Abstract

Among hereditary colorectal cancer predisposing syndromes, Lynch syndrome (LS) caused by mutations in DNA mismatch repair genes MLH1, MSH2, MSH6 or PMS2 is the most common. Patients with LS have an increased risk of early onset colon and endometrial cancer, but also other tumors that generally have an earlier onset compared to the general population. However, age at first primary cancer varies within families and genetic anticipation, i.e. decreasing age at onset in successive generations, has been suggested in LS. Anticipation is a well-known phenomenon in e.g neurodegenerative diseases and several reports have studied anticipation in heritable cancer. The purpose of this study is to determine whether anticipation can be shown in a large cohort of Swedish LS families referred to the regional departments of clinical genetics in Lund, Stockholm, Linkoping, Uppsala and Umea between the years 1990-2013. We analyzed a homogenous group of mutation carriers, utilizing information from both affected and non-affected family members. In total, 239 families with a mismatch repair gene mutation (96 MLH1 families, 90 MSH2 families including one family with an EPCAM-MSH2 deletion, 39 MSH6 families, 12 PMS2 families, and 2 MLH1+PMS2 families) comprising 1028 at-risk carriers were identified among the Swedish LS families, of which 1003 mutation carriers had available follow-up information and could be included in the study. Using a normal random effects model (NREM) we estimate a 2.1 year decrease in age of diagnosis per generation. An alternative analysis using a mixed-effects Cox proportional hazards model (COX-R) estimates a hazard ratio of exp(0.171), or about 1.19, for age of diagnosis between consecutive generations. LS-associated gene-specific anticipation effects are evident for MSH2 (2.6 years/generation for NREM and hazard ratio of 1.33 for COX-R) and PMS2 (7.3 years/generation and hazard ratio of 1.86). The estimated anticipation effects for MLH1 and MSH6 are smaller.

Published
2017
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13. Genetic anticipation in Swedish Lynch syndrome families

Author

von Salomé, Jenny, primary, Boonstra, Philip S., additional, Karimi, Masoud, additional, Silander, Gustav, additional, Stenmark-Askmalm, Marie, additional, Gebre-Medhin, Samuel, additional, Aravidis, Christos, additional, Nilbert, Mef, additional, Lindblom, Annika, additional, and Lagerstedt-Robinson, Kristina, additional

Published
2017
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14. Sequence features of HLA-DRB1 locus define putative basis for gene conversion and point mutations

Author

von Salomé, Jenny, Kukkonen, Jyrki, von Salomé, Jenny, and Kukkonen, Jyrki

Abstract

BACKGROUND: HLA/MHC class II molecules show high degree of polymorphism in the human population. The individual polymorphic motifs have been suggested to be propagated and mixed by transfer of genetic material (recombination, gene conversion) between alleles, but no clear molecular basis for this has been identified as yet. A large number of MHC class II allele sequences is publicly available and could be used to analyze the sequence features behind the recombination, revealing possible basis for such recombination processes both in HLA class II genes and other genes, which recombination acts upon. RESULTS: In this study we analyzed the vast dataset of human allelic variants (49 full coding sequences, 374 full exon 2 sequences) of the most polymorphic MHC class II locus, HLA-DRB1, and identified many previously unknown sequence features possibly contributing to the recombination. The CpG-dinucleotide content of exon 2 (containing the antigen-binding sites and subsequently a high degree of polymorphism) was much elevated as compared to the other exons despite similar overall G+C content. Furthermore, the CpG pattern was highly conserved. We also identified more complex, highly conserved sequence motifs in exon 2. Some of these can be identified as putative recombination motifs previously found in other genes, but most are previously unidentified. CONCLUSION: The identified sequence features could putatively act in recombination allowing either less (CpG dinucleotides) or more specific DNA cleavage (complex sequences) or homologous recombination (complex sequences).

Published
2008
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15. Full-length sequence analysis of the HLA-DRB1 locus suggests a recent origin of alleles

Author

von Salomé, Jenny, Gyllensten, Ulf, Bergström, Tomas F., von Salomé, Jenny, Gyllensten, Ulf, and Bergström, Tomas F.

Abstract

The HLA region harbors some of the most polymorphic loci in the human genome. Among them is the class II locus HLA-DRB1, with more than 400 known alleles. The age of the polymorphism and the rate at which new alleles are generated at HLA loci has caused much controversy over the years. Previous studies have mostly been restricted to the 270 base pairs that constitute the second exon and represent the most variable part of the gene. Here, we investigate the evolutionary history of the HLA-DRB1 locus on the basis of an analysis of 15 genomic full-length alleles (10–15 kb). In addition, the variation in 49 complete coding sequences and 322 exon 2 sequences were analyzed. When excluding exon 2 from the analysis, the diversity at the synonymous sites was found to be similar to the intron diversity. The overall diversity in noncoding region was also similar to the genome average. The DRB1*03 lineage has been found in human, chimpanzee, bonobo, gorilla, and orangutan. An ancestral “proto HLA-DRB1*03 lineage” appeared to have diverged in the last 5 million years into the human-specific lineages *08, *11, *13, and *14. With exception to exon 2, both the coding- and the noncoding diversity suggests a recent origin (<1 million years ago) for most of the alleles at the HLA-DRB1 locus. Sites encoding for amino acids involved in antigen binding [antigen recognizing sites (ARS)] appear to have a more ancient origin. Taken together, the recent origin of most alleles, the high diversity between allelic lineages, and the ancient origin of sequence motifs in exon 2, is consistent with a relatively rapid generation of novel alleles by gene conversion like events., Published on-line (doi:10.1007/s00251-007-0196-8) on Friday, February 16, 2007.

Published
2007
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16. Genome-wide prediction of human VNTRs

Author

Näslund, Kalle, Saetre, Peter, von Salomé, Jenny, Bergström, Tomas, Jareborg, Niclas, Jazin, Elena, Näslund, Kalle, Saetre, Peter, von Salomé, Jenny, Bergström, Tomas, Jareborg, Niclas, and Jazin, Elena

Abstract

Polymorphic minisatellites, also known as variable number of tandem repeats (VNTRs), are tandem repeat regions that show variation in the number of repeat units among chromosomes in a population. Currently, there are no general methods for predicting which minisatellites have a high probability of being polymorphic, given their sequence characteristics. An earlier approach has focused on potentially highly polymorphic and hypervariable minisatellites, which make up only a small fraction of all minisatellites in the human genome. We have developed a model, based on available minisatellite and VNTR sequence data, that predicts the probability that a minisatellite (unit size > or = 6 bp) identified by the computer program Tandem Repeats Finder is polymorphic (VNTR). According to the model, minisatellites with high copy number and high degree of sequence similarity are most likely to be VNTRs. This approach was used to scan the draft sequence of the human genome for VNTRs. A total of 157,549 minisatellite repeats were found, of which 29,224 are predicted to be VNTRs. Contrary to previous results, VNTRs appear to be widespread and abundant throughout the human genome, with an estimated density of 9.1 VNTRs/Mb.

Published
2005
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18. Genome-wide prediction of human VNTRs

Author

Näslund, Karl, primary, Saetre, Peter, additional, von Salomé, Jenny, additional, Bergström, Tomas F., additional, Jareborg, Niclas, additional, and Jazin, Elena, additional

Published
2005
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