Your search keyword '"López-Bigas, Núria"' showing total 6 results

1. Analyses of non-coding somatic drivers in 2,658 cancer whole genomes.

Author

Rheinbay, Esther, Nielsen, Morten Muhlig, Abascal, Federico, Wala, Jeremiah A, Shapira, Ofer, Tiao, Grace, Hornshøj, Henrik, Hess, Julian M, Juul, Randi Istrup, Lin, Ziao, Feuerbach, Lars, Sabarinathan, Radhakrishnan, Madsen, Tobias, Kim, Jaegil, Mularoni, Loris, Shuai, Shimin, Lanzós, Andrés, Herrmann, Carl, Maruvka, Yosef E, Shen, Ciyue, Amin, Samirkumar B, Bandopadhayay, Pratiti, Bertl, Johanna, Boroevich, Keith A, Busanovich, John, Carlevaro-Fita, Joana, Chakravarty, Dimple, Chan, Calvin Wing Yiu, Craft, David, Dhingra, Priyanka, Diamanti, Klev, Fonseca, Nuno A, Gonzalez-Perez, Abel, Guo, Qianyun, Hamilton, Mark P, Haradhvala, Nicholas J, Hong, Chen, Isaev, Keren, Johnson, Todd A, Juul, Malene, Kahles, Andre, Kahraman, Abdullah, Kim, Youngwook, Komorowski, Jan, Kumar, Kiran, Kumar, Sushant, Lee, Donghoon, Lehmann, Kjong-Van, Li, Yilong, Liu, Eric Minwei, Lochovsky, Lucas, Park, Keunchil, Pich, Oriol, Roberts, Nicola D, Saksena, Gordon, Schumacher, Steven E, Sidiropoulos, Nikos, Sieverling, Lina, Sinnott-Armstrong, Nasa, Stewart, Chip, Tamborero, David, Tubio, Jose MC, Umer, Husen M, Uusküla-Reimand, Liis, Wadelius, Claes, Wadi, Lina, Yao, Xiaotong, Zhang, Cheng-Zhong, Zhang, Jing, Haber, James E, Hobolth, Asger, Imielinski, Marcin, Kellis, Manolis, Lawrence, Michael S, von Mering, Christian, Nakagawa, Hidewaki, Raphael, Benjamin J, Rubin, Mark A, Sander, Chris, Stein, Lincoln D, Stuart, Joshua M, Tsunoda, Tatsuhiko, Wheeler, David A, Johnson, Rory, Reimand, Jüri, Gerstein, Mark, Khurana, Ekta, Campbell, Peter J, López-Bigas, Núria, PCAWG Drivers and Functional Interpretation Working Group, PCAWG Structural Variation Working Group, Weischenfeldt, Joachim, Beroukhim, Rameen, Martincorena, Iñigo, Pedersen, Jakob Skou, Getz, Gad, and PCAWG Consortium

Subjects

PCAWG Drivers and Functional Interpretation Working Group, PCAWG Structural Variation Working Group, PCAWG Consortium, Humans, Neoplasms, Gene Expression Regulation, Neoplastic, Mutation, Genome, Human, Databases, Genetic, DNA Breaks, INDEL Mutation, Genome-Wide Association Study, Gene Expression Regulation, Neoplastic, Genome, Human, Databases, Genetic, General Science & Technology

Abstract

The discovery of drivers of cancer has traditionally focused on protein-coding genes1-4. Here we present analyses of driver point mutations and structural variants in non-coding regions across 2,658 genomes from the Pan-Cancer Analysis of Whole Genomes (PCAWG) Consortium5 of the International Cancer Genome Consortium (ICGC) and The Cancer Genome Atlas (TCGA). For point mutations, we developed a statistically rigorous strategy for combining significance levels from multiple methods of driver discovery that overcomes the limitations of individual methods. For structural variants, we present two methods of driver discovery, and identify regions that are significantly affected by recurrent breakpoints and recurrent somatic juxtapositions. Our analyses confirm previously reported drivers6,7, raise doubts about others and identify novel candidates, including point mutations in the 5' region of TP53, in the 3' untranslated regions of NFKBIZ and TOB1, focal deletions in BRD4 and rearrangements in the loci of AKR1C genes. We show that although point mutations and structural variants that drive cancer are less frequent in non-coding genes and regulatory sequences than in protein-coding genes, additional examples of these drivers will be found as more cancer genomes become available.

Published

2020

2. Strand-resolved mutagenicity of DNA damage and repair

Author

Anderson, Craig J., Talmane, Lana, Luft, Juliet, Connelly, John, Nicholson, Michael D., Verburg, Jan C., Pich, Oriol, Campbell, Susan, Giaisi, Marco, Wei, Pei-Chi, Sundaram, Vasavi, Connor, Frances, Ginno, Paul A., Sasaki, Takayo, Gilbert, David M., López-Bigas, Núria, Semple, Colin A., Odom, Duncan T., Aitken, Sarah J., and Taylor, Martin S.

Abstract

DNA base damage is a major source of oncogenic mutations1. Such damage can produce strand-phased mutation patterns and multiallelic variation through the process of lesion segregation2. Here we exploited these properties to reveal how strand-asymmetric processes, such as replication and transcription, shape DNA damage and repair. Despite distinct mechanisms of leading and lagging strand replication3,4, we observe identical fidelity and damage tolerance for both strands. For small alkylation adducts of DNA, our results support a model in which the same translesion polymerase is recruited on-the-fly to both replication strands, starkly contrasting the strand asymmetric tolerance of bulky UV-induced adducts5. The accumulation of multiple distinct mutations at the site of persistent lesions provides the means to quantify the relative efficiency of repair processes genome wide and at single-base resolution. At multiple scales, we show DNA damage-induced mutations are largely shaped by the influence of DNA accessibility on repair efficiency, rather than gradients of DNA damage. Finally, we reveal specific genomic conditions that can actively drive oncogenic mutagenesis by corrupting the fidelity of nucleotide excision repair. These results provide insight into how strand-asymmetric mechanisms underlie the formation, tolerance and repair of DNA damage, thereby shaping cancer genome evolution.

Published

2024

3. Nucleotide excision repair is impaired by binding of transcription factors to DNA

Author

Sabarinathan, Radhakrishnan, Mularoni, Loris, Deu-Pons, Jordi, Gonzalez-Perez, Abel, and López-Bigas, Núria

Published

2016

4. Whole-genome landscapes of major melanoma subtypes

Author

Hayward, Nicholas K., primary, Wilmott, James S., additional, Waddell, Nicola, additional, Johansson, Peter A., additional, Field, Matthew A., additional, Nones, Katia, additional, Patch, Ann-Marie, additional, Kakavand, Hojabr, additional, Alexandrov, Ludmil B., additional, Burke, Hazel, additional, Jakrot, Valerie, additional, Kazakoff, Stephen, additional, Holmes, Oliver, additional, Leonard, Conrad, additional, Sabarinathan, Radhakrishnan, additional, Mularoni, Loris, additional, Wood, Scott, additional, Xu, Qinying, additional, Waddell, Nick, additional, Tembe, Varsha, additional, Pupo, Gulietta M., additional, De Paoli-Iseppi, Ricardo, additional, Vilain, Ricardo E., additional, Shang, Ping, additional, Lau, Loretta M. S., additional, Dagg, Rebecca A., additional, Schramm, Sarah-Jane, additional, Pritchard, Antonia, additional, Dutton-Regester, Ken, additional, Newell, Felicity, additional, Fitzgerald, Anna, additional, Shang, Catherine A., additional, Grimmond, Sean M., additional, Pickett, Hilda A., additional, Yang, Jean Y., additional, Stretch, Jonathan R., additional, Behren, Andreas, additional, Kefford, Richard F., additional, Hersey, Peter, additional, Long, Georgina V., additional, Cebon, Jonathan, additional, Shackleton, Mark, additional, Spillane, Andrew J., additional, Saw, Robyn P. M., additional, López-Bigas, Núria, additional, Pearson, John V., additional, Thompson, John F., additional, Scolyer, Richard A., additional, and Mann, Graham J., additional

Published

2017

5. Pervasive lesion segregation shapes cancer genome evolution

Author

Aitken, Sarah J., Anderson, Craig J., Connor, Frances, Pich, Oriol, Sundaram, Vasavi, Feig, Christine, Rayner, Tim F., Lukk, Margus, Aitken, Stuart, Luft, Juliet, Kentepozidou, Elissavet, Arnedo-Pac, Claudia, Beentjes, Sjoerd V., Davies, Susan E., Drews, Ruben M., Ewing, Ailith, Kaiser, Vera B., Khamseh, Ava, López-Arribillaga, Erika, Redmond, Aisling M., Santoyo-Lopez, Javier, Sentís, Inés, Talmane, Lana, Yates, Andrew D., Semple, Colin A., López-Bigas, Núria, Flicek, Paul, Odom, Duncan T., and Taylor, Martin S.

Abstract

Cancers arise through the acquisition of oncogenic mutations and grow by clonal expansion1,2. Here we reveal that most mutagenic DNA lesions are not resolved into a mutated DNA base pair within a single cell cycle. Instead, DNA lesions segregate, unrepaired, into daughter cells for multiple cell generations, resulting in the chromosome-scale phasing of subsequent mutations. We characterize this process in mutagen-induced mouse liver tumours and show that DNA replication across persisting lesions can produce multiple alternative alleles in successive cell divisions, thereby generating both multiallelic and combinatorial genetic diversity. The phasing of lesions enables accurate measurement of strand-biased repair processes, quantification of oncogenic selection and fine mapping of sister-chromatid-exchange events. Finally, we demonstrate that lesion segregation is a unifying property of exogenous mutagens, including UV light and chemotherapy agents in human cells and tumours, which has profound implications for the evolution and adaptation of cancer genomes.

Published

2020

6. Author Correction: Analyses of non-coding somatic drivers in 2,658 cancer whole genomes

Author

Rheinbay, Esther, Nielsen, Morten Muhlig, Abascal, Federico, Wala, Jeremiah A., Shapira, Ofer, Tiao, Grace, Hornshøj, Henrik, Hess, Julian M., Juul, Randi Istrup, Lin, Ziao, Feuerbach, Lars, Sabarinathan, Radhakrishnan, Madsen, Tobias, Kim, Jaegil, Mularoni, Loris, Shuai, Shimin, Lanzós, Andrés, Herrmann, Carl, Maruvka, Yosef E., Shen, Ciyue, Amin, Samirkumar B., Bandopadhayay, Pratiti, Bertl, Johanna, Boroevich, Keith A., Busanovich, John, Carlevaro-Fita, Joana, Chakravarty, Dimple, Chan, Calvin Wing Yiu, Craft, David, Dhingra, Priyanka, Diamanti, Klev, Fonseca, Nuno A., Gonzalez-Perez, Abel, Guo, Qianyun, Hamilton, Mark P., Haradhvala, Nicholas J., Hong, Chen, Isaev, Keren, Johnson, Todd A., Juul, Malene, Kahles, Andre, Kahraman, Abdullah, Kim, Youngwook, Komorowski, Jan, Kumar, Kiran, Kumar, Sushant, Lee, Donghoon, Lehmann, Kjong-Van, Li, Yilong, Liu, Eric Minwei, Lochovsky, Lucas, Park, Keunchil, Pich, Oriol, Roberts, Nicola D., Saksena, Gordon, Schumacher, Steven E., Sidiropoulos, Nikos, Sieverling, Lina, Sinnott-Armstrong, Nasa, Stewart, Chip, Tamborero, David, Tubio, Jose M. C., Umer, Husen M., Uusküla-Reimand, Liis, Wadelius, Claes, Wadi, Lina, Yao, Xiaotong, Zhang, Cheng-Zhong, Zhang, Jing, Haber, James E., Hobolth, Asger, Imielinski, Marcin, Kellis, Manolis, Lawrence, Michael S., von Mering, Christian, Nakagawa, Hidewaki, Raphael, Benjamin J., Rubin, Mark A., Sander, Chris, Stein, Lincoln D., Stuart, Joshua M., Tsunoda, Tatsuhiko, Wheeler, David A., Johnson, Rory, Reimand, Jüri, Gerstein, Mark, Khurana, Ekta, Campbell, Peter J., López-Bigas, Núria, Weischenfeldt, Joachim, Beroukhim, Rameen, Martincorena, Iñigo, Pedersen, Jakob Skou, and Getz, Gad

Published

2023