Your search keyword '"Alexandrov LB"' showing total 8 results

1. Mechanisms of APOBEC3 mutagenesis in human cancer cells.

Author

Petljak M, Dananberg A, Chu K, Bergstrom EN, Striepen J, von Morgen P, Chen Y, Shah H, Sale JE, Alexandrov LB, Stratton MR, and Maciejowski J

Subjects

Cell Line, Tumor, DNA-Directed DNA Polymerase metabolism, Gene Deletion, Genome, Human, Humans, Uracil-DNA Glycosidase metabolism, APOBEC Deaminases deficiency, APOBEC Deaminases genetics, APOBEC Deaminases metabolism, Mutagenesis genetics, Neoplasms enzymology, Neoplasms genetics, Neoplasms pathology

Abstract

The APOBEC3 family of cytosine deaminases has been implicated in some of the most prevalent mutational signatures in cancer 1-3 . However, a causal link between endogenous APOBEC3 enzymes and mutational signatures in human cancer genomes has not been established, leaving the mechanisms of APOBEC3 mutagenesis poorly understood. Here, to investigate the mechanisms of APOBEC3 mutagenesis, we deleted implicated genes from human cancer cell lines that naturally generate APOBEC3-associated mutational signatures over time 4 . Analysis of non-clustered and clustered signatures across whole-genome sequences from 251 breast, bladder and lymphoma cancer cell line clones revealed that APOBEC3A deletion diminished APOBEC3-associated mutational signatures. Deletion of both APOBEC3A and APOBEC3B further decreased APOBEC3 mutation burdens, without eliminating them. Deletion of APOBEC3B increased APOBEC3A protein levels, activity and APOBEC3A-mediated mutagenesis in some cell lines. The uracil glycosylase UNG was required for APOBEC3-mediated transversions, whereas the loss of the translesion polymerase REV1 decreased overall mutation burdens. Together, these data represent direct evidence that endogenous APOBEC3 deaminases generate prevalent mutational signatures in human cancer cells. Our results identify APOBEC3A as the main driver of these mutations, indicate that APOBEC3B can restrain APOBEC3A-dependent mutagenesis while contributing its own smaller mutation burdens and dissect mechanisms that translate APOBEC3 activities into distinct mutational signatures., (© 2022. The Author(s).)

Published

2022

2. Whole-exome sequencing reveals the impact of UVA light mutagenesis in xeroderma pigmentosum variant human cells.

Author

Moreno NC, de Souza TA, Garcia CCM, Ruiz NQ, Corradi C, Castro LP, Munford V, Ienne S, Alexandrov LB, and Menck CFM

Subjects

Cell Line, DNA Damage radiation effects, DNA Repair radiation effects, DNA Replication radiation effects, Humans, Mutagenesis radiation effects, Mutation genetics, Mutation radiation effects, Oxidative Stress radiation effects, Pyrimidine Dimers radiation effects, Ultraviolet Rays, Exome Sequencing, Xeroderma Pigmentosum etiology, Mutagenesis genetics, Oxidative Stress genetics, Pyrimidine Dimers genetics, Xeroderma Pigmentosum genetics

Abstract

UVA-induced mutagenesis was investigated in human pol eta-deficient (XP-V) cells through whole-exome sequencing. In UVA-irradiated cells, the increase in the mutation frequency in deficient cells included a remarkable contribution of C>T transitions, mainly at potential pyrimidine dimer sites. A strong contribution of C>A transversions, potentially due to oxidized bases, was also observed in non-irradiated XP-V cells, indicating that basal mutagenesis caused by oxidative stress may be related to internal tumours in XP-V patients. The low levels of mutations involving T induced by UVA indicate that pol eta is not responsible for correctly replicating T-containing pyrimidine dimers, a phenomenon known as the 'A-rule'. Moreover, the mutation signature profile of UVA-irradiated XP-V cells is highly similar to the human skin cancer profile, revealing how studies involving cells deficient in DNA damage processing may be useful to understand the mechanisms of environmentally induced carcinogenesis., (© The Author(s) 2019. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2020

3. Therapy-induced mutations drive the genomic landscape of relapsed acute lymphoblastic leukemia.

Author

Li B, Brady SW, Ma X, Shen S, Zhang Y, Li Y, Szlachta K, Dong L, Liu Y, Yang F, Wang N, Flasch DA, Myers MA, Mulder HL, Ding L, Liu Y, Tian L, Hagiwara K, Xu K, Zhou X, Sioson E, Wang T, Yang L, Zhao J, Zhang H, Shao Y, Sun H, Sun L, Cai J, Sun HY, Lin TN, Du L, Li H, Rusch M, Edmonson MN, Easton J, Zhu X, Zhang J, Cheng C, Raphael BJ, Tang J, Downing JR, Alexandrov LB, Zhou BS, Pui CH, Yang JJ, and Zhang J

Subjects

5'-Nucleotidase genetics, Antimetabolites, Antineoplastic therapeutic use, Child, DNA Mutational Analysis, Female, Follow-Up Studies, Genomics, High-Throughput Nucleotide Sequencing, Humans, Male, Precursor Cell Lymphoblastic Leukemia-Lymphoma drug therapy, Prognosis, Receptors, Glucocorticoid genetics, Survival Rate, Tumor Suppressor Protein p53 genetics, Biomarkers, Tumor genetics, Methotrexate therapeutic use, Mutagenesis drug effects, Mutation, Precursor Cell Lymphoblastic Leukemia-Lymphoma genetics, Precursor Cell Lymphoblastic Leukemia-Lymphoma pathology

Abstract

To study the mechanisms of relapse in acute lymphoblastic leukemia (ALL), we performed whole-genome sequencing of 103 diagnosis-relapse-germline trios and ultra-deep sequencing of 208 serial samples in 16 patients. Relapse-specific somatic alterations were enriched in 12 genes (NR3C1, NR3C2, TP53, NT5C2, FPGS, CREBBP, MSH2, MSH6, PMS2, WHSC1, PRPS1, and PRPS2) involved in drug response. Their prevalence was 17% in very early relapse (<9 months from diagnosis), 65% in early relapse (9-36 months), and 32% in late relapse (>36 months) groups. Convergent evolution, in which multiple subclones harbor mutations in the same drug resistance gene, was observed in 6 relapses and confirmed by single-cell sequencing in 1 case. Mathematical modeling and mutational signature analysis indicated that early relapse resistance acquisition was frequently a 2-step process in which a persistent clone survived initial therapy and later acquired bona fide resistance mutations during therapy. In contrast, very early relapses arose from preexisting resistant clone(s). Two novel relapse-specific mutational signatures, one of which was caused by thiopurine treatment based on in vitro drug exposure experiments, were identified in early and late relapses but were absent from 2540 pan-cancer diagnosis samples and 129 non-ALL relapses. The novel signatures were detected in 27% of relapsed ALLs and were responsible for 46% of acquired resistance mutations in NT5C2, PRPS1, NR3C1, and TP53. These results suggest that chemotherapy-induced drug resistance mutations facilitate a subset of pediatric ALL relapses., (© 2020 by The American Society of Hematology.)

Published

2020

4. A renewed model of pancreatic cancer evolution based on genomic rearrangement patterns.

Author

Notta F, Chan-Seng-Yue M, Lemire M, Li Y, Wilson GW, Connor AA, Denroche RE, Liang SB, Brown AM, Kim JC, Wang T, Simpson JT, Beck T, Borgida A, Buchner N, Chadwick D, Hafezi-Bakhtiari S, Dick JE, Heisler L, Hollingsworth MA, Ibrahimov E, Jang GH, Johns J, Jorgensen LG, Law C, Ludkovski O, Lungu I, Ng K, Pasternack D, Petersen GM, Shlush LI, Timms L, Tsao MS, Wilson JM, Yung CK, Zogopoulos G, Bartlett JM, Alexandrov LB, Real FX, Cleary SP, Roehrl MH, McPherson JD, Stein LD, Hudson TJ, Campbell PJ, and Gallinger S

Subjects

Carcinoma in Situ genetics, Chromothripsis, DNA Copy Number Variations genetics, Disease Progression, Evolution, Molecular, Female, Genes, Neoplasm genetics, Humans, Male, Mitosis genetics, Mutation genetics, Neoplasm Invasiveness genetics, Neoplasm Invasiveness pathology, Neoplasm Metastasis genetics, Neoplasm Metastasis pathology, Polyploidy, Precancerous Conditions genetics, Carcinogenesis genetics, Carcinogenesis pathology, Gene Rearrangement genetics, Genome, Human genetics, Models, Biological, Mutagenesis genetics, Pancreatic Neoplasms genetics, Pancreatic Neoplasms pathology

Abstract

Pancreatic cancer, a highly aggressive tumour type with uniformly poor prognosis, exemplifies the classically held view of stepwise cancer development. The current model of tumorigenesis, based on analyses of precursor lesions, termed pancreatic intraepithelial neoplasm (PanINs) lesions, makes two predictions: first, that pancreatic cancer develops through a particular sequence of genetic alterations (KRAS, followed by CDKN2A, then TP53 and SMAD4); and second, that the evolutionary trajectory of pancreatic cancer progression is gradual because each alteration is acquired independently. A shortcoming of this model is that clonally expanded precursor lesions do not always belong to the tumour lineage, indicating that the evolutionary trajectory of the tumour lineage and precursor lesions can be divergent. This prevailing model of tumorigenesis has contributed to the clinical notion that pancreatic cancer evolves slowly and presents at a late stage. However, the propensity for this disease to rapidly metastasize and the inability to improve patient outcomes, despite efforts aimed at early detection, suggest that pancreatic cancer progression is not gradual. Here, using newly developed informatics tools, we tracked changes in DNA copy number and their associated rearrangements in tumour-enriched genomes and found that pancreatic cancer tumorigenesis is neither gradual nor follows the accepted mutation order. Two-thirds of tumours harbour complex rearrangement patterns associated with mitotic errors, consistent with punctuated equilibrium as the principal evolutionary trajectory. In a subset of cases, the consequence of such errors is the simultaneous, rather than sequential, knockout of canonical preneoplastic genetic drivers that are likely to set-off invasive cancer growth. These findings challenge the current progression model of pancreatic cancer and provide insights into the mutational processes that give rise to these aggressive tumours.

Published

2016

5. Understanding mutagenesis through delineation of mutational signatures in human cancer.

Author

Petljak M and Alexandrov LB

Subjects

Genome, Human, Humans, Mutagenesis, Mutation, Neoplasms genetics

Abstract

Each individual cell within a human body acquires a certain number of somatic mutations during a course of its lifetime. These mutations originate from a wide spectra of both endogenous and exogenous mutational processes that leave distinct patterns of mutations, termed mutational signatures, embedded within the genomes of all cells. In recent years, the vast amount of data produced by sequencing of cancer genomes was coupled with novel mathematical models and computational tools to generate the first comprehensive map of mutational signatures in human cancer. Up to date, >30 distinct mutational signatures have been identified, and etiologies have been proposed for many of them. This review provides a brief historical background on examination of mutational patterns in human cancer, summarizes the knowledge accumulated since introducing the concept of mutational signatures and discusses their future potential applications and perspectives within the field., (Published by Oxford University Press 2016.)

Published

2016

6. Understanding the origins of human cancer.

Author

Alexandrov LB

Subjects

DNA Mutational Analysis, Humans, Mutation, Neoplasms classification, Neoplasms pathology, Computer Simulation, Genomics methods, Models, Genetic, Mutagenesis, Neoplasms genetics

Published

2015

7. Genome sequencing of normal cells reveals developmental lineages and mutational processes.

Author

Behjati S, Huch M, van Boxtel R, Karthaus W, Wedge DC, Tamuri AU, Martincorena I, Petljak M, Alexandrov LB, Gundem G, Tarpey PS, Roerink S, Blokker J, Maddison M, Mudie L, Robinson B, Nik-Zainal S, Campbell P, Goldman N, van de Wetering M, Cuppen E, Clevers H, and Stratton MR

Subjects

Animals, Biological Clocks genetics, Cell Division, Cells, Cultured, Embryo, Mammalian cytology, Humans, Male, Mice, Mice, Inbred C57BL, Mutation Rate, Organoids cytology, Organoids metabolism, Phylogeny, Sequence Analysis, DNA, Tail cytology, Cell Lineage genetics, Clone Cells cytology, Clone Cells metabolism, Genome genetics, Mutagenesis genetics, Mutation genetics

Abstract

The somatic mutations present in the genome of a cell accumulate over the lifetime of a multicellular organism. These mutations can provide insights into the developmental lineage tree, the number of divisions that each cell has undergone and the mutational processes that have been operative. Here we describe whole genomes of clonal lines derived from multiple tissues of healthy mice. Using somatic base substitutions, we reconstructed the early cell divisions of each animal, demonstrating the contributions of embryonic cells to adult tissues. Differences were observed between tissues in the numbers and types of mutations accumulated by each cell, which likely reflect differences in the number of cell divisions they have undergone and varying contributions of different mutational processes. If somatic mutation rates are similar to those in mice, the results indicate that precise insights into development and mutagenesis of normal human cells will be possible.

Published

2014

8. Signatures of mutational processes in human cancer.

Author

Alexandrov LB, Nik-Zainal S, Wedge DC, Aparicio SA, Behjati S, Biankin AV, Bignell GR, Bolli N, Borg A, Børresen-Dale AL, Boyault S, Burkhardt B, Butler AP, Caldas C, Davies HR, Desmedt C, Eils R, Eyfjörd JE, Foekens JA, Greaves M, Hosoda F, Hutter B, Ilicic T, Imbeaud S, Imielinski M, Jäger N, Jones DT, Jones D, Knappskog S, Kool M, Lakhani SR, López-Otín C, Martin S, Munshi NC, Nakamura H, Northcott PA, Pajic M, Papaemmanuil E, Paradiso A, Pearson JV, Puente XS, Raine K, Ramakrishna M, Richardson AL, Richter J, Rosenstiel P, Schlesner M, Schumacher TN, Span PN, Teague JW, Totoki Y, Tutt AN, Valdés-Mas R, van Buuren MM, van 't Veer L, Vincent-Salomon A, Waddell N, Yates LR, Zucman-Rossi J, Futreal PA, McDermott U, Lichter P, Meyerson M, Grimmond SM, Siebert R, Campo E, Shibata T, Pfister SM, Campbell PJ, and Stratton MR

Subjects

Aging genetics, Algorithms, Cell Transformation, Neoplastic pathology, Cytidine Deaminase genetics, DNA genetics, DNA metabolism, DNA Mutational Analysis, Humans, Models, Genetic, Mutagenesis, Insertional genetics, Mutagens pharmacology, Neoplasms enzymology, Neoplasms pathology, Organ Specificity, Reproducibility of Results, Sequence Deletion genetics, Transcription, Genetic genetics, Cell Transformation, Neoplastic genetics, Mutagenesis genetics, Mutation genetics, Neoplasms genetics

Abstract

All cancers are caused by somatic mutations; however, understanding of the biological processes generating these mutations is limited. The catalogue of somatic mutations from a cancer genome bears the signatures of the mutational processes that have been operative. Here we analysed 4,938,362 mutations from 7,042 cancers and extracted more than 20 distinct mutational signatures. Some are present in many cancer types, notably a signature attributed to the APOBEC family of cytidine deaminases, whereas others are confined to a single cancer class. Certain signatures are associated with age of the patient at cancer diagnosis, known mutagenic exposures or defects in DNA maintenance, but many are of cryptic origin. In addition to these genome-wide mutational signatures, hypermutation localized to small genomic regions, 'kataegis', is found in many cancer types. The results reveal the diversity of mutational processes underlying the development of cancer, with potential implications for understanding of cancer aetiology, prevention and therapy.

Published

2013