Your search keyword '"Nakagawa, Hidewaki"' showing total 20 results

1. Deep whole-genome analysis of 494 hepatocellular carcinomas.

Author

Chen L, Zhang C, Xue R, Liu M, Bai J, Bao J, Wang Y, Jiang N, Li Z, Wang W, Wang R, Zheng B, Yang A, Hu J, Liu K, Shen S, Zhang Y, Bai M, Wang Y, Zhu Y, Yang S, Gao Q, Gu J, Gao D, Wang XW, Nakagawa H, Zhang N, Wu L, Rozen SG, Bai F, and Wang H

Subjects

Humans, Aristolochic Acids metabolism, Carcinogenesis, China, Chromothripsis, Disease Progression, DNA, Circular genetics, East Asian People genetics, Evolution, Molecular, Hepatitis B virus genetics, INDEL Mutation genetics, Liver metabolism, Neoplasm Metastasis genetics, Open Reading Frames genetics, Reproducibility of Results, Carcinoma, Hepatocellular genetics, Carcinoma, Hepatocellular virology, Genome, Human genetics, High-Throughput Nucleotide Sequencing, Liver Neoplasms genetics, Liver Neoplasms virology, Mutation genetics, Whole Genome Sequencing

Abstract

Over half of hepatocellular carcinoma (HCC) cases diagnosed worldwide are in China 1-3 . However, whole-genome analysis of hepatitis B virus (HBV)-associated HCC in Chinese individuals is limited 4-8 , with current analyses of HCC mainly from non-HBV-enriched populations 9,10 . Here we initiated the Chinese Liver Cancer Atlas (CLCA) project and performed deep whole-genome sequencing (average depth, 120×) of 494 HCC tumours. We identified 6 coding and 28 non-coding previously undescribed driver candidates. Five previously undescribed mutational signatures were found, including aristolochic-acid-associated indel and doublet base signatures, and a single-base-substitution signature that we termed SBS_H8. Pentanucleotide context analysis and experimental validation confirmed that SBS_H8 was distinct to the aristolochic-acid-associated SBS22. Notably, HBV integrations could take the form of extrachromosomal circular DNA, resulting in elevated copy numbers and gene expression. Our high-depth data also enabled us to characterize subclonal clustered alterations, including chromothripsis, chromoplexy and kataegis, suggesting that these catastrophic events could also occur in late stages of hepatocarcinogenesis. Pathway analysis of all classes of alterations further linked non-coding mutations to dysregulation of liver metabolism. Finally, we performed in vitro and in vivo assays to show that fibrinogen alpha chain (FGA), determined as both a candidate coding and non-coding driver, regulates HCC progression and metastasis. Our CLCA study depicts a detailed genomic landscape and evolutionary history of HCC in Chinese individuals, providing important clinical implications., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

2. Aberrant integration of Hepatitis B virus DNA promotes major restructuring of human hepatocellular carcinoma genome architecture.

Author

Álvarez EG, Demeulemeester J, Otero P, Jolly C, García-Souto D, Pequeño-Valtierra A, Zamora J, Tojo M, Temes J, Baez-Ortega A, Rodriguez-Martin B, Oitaben A, Bruzos AL, Martínez-Fernández M, Haase K, Zumalave S, Abal R, Rodríguez-Castro J, Rodriguez-Casanova A, Diaz-Lagares A, Li Y, Raine KM, Butler AP, Otero I, Ono A, Aikata H, Chayama K, Ueno M, Hayami S, Yamaue H, Maejima K, Blanco MG, Forns X, Rivas C, Ruiz-Bañobre J, Pérez-Del-Pulgar S, Torres-Ruiz R, Rodriguez-Perales S, Garaigorta U, Campbell PJ, Nakagawa H, Van Loo P, and Tubio JMC

Subjects

Carcinoma, Hepatocellular virology, Gene Expression Regulation, Neoplastic, Humans, Virus Integration, Whole Genome Sequencing, Carcinoma, Hepatocellular genetics, DNA, Viral, Genome, Human, Hepatitis B virus genetics, Liver Neoplasms genetics

Abstract

Most cancers are characterized by the somatic acquisition of genomic rearrangements during tumour evolution that eventually drive the oncogenesis. Here, using multiplatform sequencing technologies, we identify and characterize a remarkable mutational mechanism in human hepatocellular carcinoma caused by Hepatitis B virus, by which DNA molecules from the virus are inserted into the tumour genome causing dramatic changes in its configuration, including non-homologous chromosomal fusions, dicentric chromosomes and megabase-size telomeric deletions. This aberrant mutational mechanism, present in at least 8% of all HCC tumours, can provide the driver rearrangements that a cancer clone requires to survive and grow, including loss of relevant tumour suppressor genes. Most of these events are clonal and occur early during liver cancer evolution. Real-time timing estimation reveals some HBV-mediated rearrangements occur as early as two decades before cancer diagnosis. Overall, these data underscore the importance of characterising liver cancer genomes for patterns of HBV integration., (© 2021. The Author(s).)

Published

2021

3. Characterization of intermediate-sized insertions using whole-genome sequencing data and analysis of their functional impact on gene expression.

Author

Ashouri S, Wong JH, Nakagawa H, Shimada M, Tokunaga K, and Fujimoto A

Subjects

ATP-Binding Cassette Transporters genetics, ATP-Binding Cassette Transporters metabolism, BRCA1 Protein genetics, BRCA1 Protein metabolism, Base Sequence, Binding Sites, CCCTC-Binding Factor genetics, CCCTC-Binding Factor metabolism, Chromosome Mapping, Databases, Genetic, Enhancer Elements, Genetic, Gene Expression Profiling, Humans, Japan, Molecular Sequence Annotation, Neoplasm Proteins metabolism, Neoplasms metabolism, Neoplasms pathology, Osteoarthritis metabolism, Osteoarthritis pathology, Promoter Regions, Genetic, Quantitative Trait Loci, Repressor Proteins genetics, Repressor Proteins metabolism, Software, Whole Genome Sequencing, Gene Expression Regulation, Genome, Human, Mutagenesis, Insertional, Neoplasm Proteins genetics, Neoplasms genetics, Osteoarthritis genetics

Abstract

Intermediate-sized insertions are one of the structural variants contributing to genome diversity. However, due to technical difficulties in identifying them, their importance in disease pathogenicity and gene expression regulation remains unclear. We used whole-genome sequencing data of 174 Japanese samples to characterize intermediate-sized insertions using a highly-accurate insertion calling method (IMSindel software and joint-call recovery) and obtained a catalogue of 4254 insertions. We constructed an imputation panel comprising of insertions and SNVs from all samples, and conducted imputation of intermediate-sized insertions for 82 publicly-available Japanese samples. Positive Predictive Value of imputation, evaluated using Nanopore long-read sequencing data, was 97%. Subsequent eQTL analysis predicted 128 (~ 3.0%) insertions as causative for gene expression level changes. Enrichment analysis of causal insertions for genome regulatory elements showed significant associations with CTCF-binding sites, super-enhancers, and promoters. Among 17 causal insertions found in the same causal set with GWAS hits, there were insertions associated with changes in expression of cancer-related genes such as BRCA1, ZNF222, and ABCB10. Analysis of insertions sequences revealed that 461 insertions were short tandem duplications frequently found in early-replicating regions of genome. Furthermore, comparison of functional importance of intermediate-sized insertions with that of intermediate-sized deletions detected in the same sample set in our previous study showed that insertions were more frequent in genic regions, and proportion of functional candidates was smaller in insertions. Here, we characterize a high-confidence set of intermediate-sized insertions and indicate their importance in gene expression regulation. Our results emphasize the importance of considering intermediate-sized insertions in trait association studies.

Published

2021

4. Whole-genome sequencing with long reads reveals complex structure and origin of structural variation in human genetic variations and somatic mutations in cancer.

Author

Fujimoto A, Wong JH, Yoshii Y, Akiyama S, Tanaka A, Yagi H, Shigemizu D, Nakagawa H, Mizokami M, and Shimada M

Subjects

Base Sequence, DNA Methylation genetics, Germ-Line Mutation genetics, Humans, INDEL Mutation genetics, Promoter Regions, Genetic genetics, Telomerase genetics, Viruses metabolism, Genome, Human, Genomic Structural Variation, Mutation genetics, Neoplasms genetics, Whole Genome Sequencing

Abstract

Background: Identification of germline variation and somatic mutations is a major issue in human genetics. However, due to the limitations of DNA sequencing technologies and computational algorithms, our understanding of genetic variation and somatic mutations is far from complete., Methods: In the present study, we performed whole-genome sequencing using long-read sequencing technology (Oxford Nanopore) for 11 Japanese liver cancers and matched normal samples which were previously sequenced for the International Cancer Genome Consortium (ICGC). We constructed an analysis pipeline for the long-read data and identified germline and somatic structural variations (SVs)., Results: In polymorphic germline SVs, our analysis identified 8004 insertions, 6389 deletions, 27 inversions, and 32 intra-chromosomal translocations. By comparing to the chimpanzee genome, we correctly inferred events that caused insertions and deletions and found that most insertions were caused by transposons and Alu is the most predominant source, while other types of insertions, such as tandem duplications and processed pseudogenes, are rare. We inferred mechanisms of deletion generations and found that most non-allelic homolog recombination (NAHR) events were caused by recombination errors in SINEs. Analysis of somatic mutations in liver cancers showed that long reads could detect larger numbers of SVs than a previous short-read study and that mechanisms of cancer SV generation were different from that of germline deletions., Conclusions: Our analysis provides a comprehensive catalog of polymorphic and somatic SVs, as well as their possible causes. Our software are available at https://github.com/afujimoto/CAMPHOR and https://github.com/afujimoto/CAMPHORsomatic .

Published

2021

5. Endogenization and excision of human herpesvirus 6 in human genomes.

Author

Liu X, Kosugi S, Koide R, Kawamura Y, Ito J, Miura H, Matoba N, Matsuzaki M, Fujita M, Kamada AJ, Nakagawa H, Tamiya G, Matsuda K, Murakami Y, Kubo M, Aswad A, Sato K, Momozawa Y, Ohashi J, Terao C, Yoshikawa T, Parrish NF, and Kamatani Y

Subjects

Asian People genetics, Chromosomes, Human, Pair 22 genetics, Evolution, Molecular, Germ-Line Mutation, Humans, Polymorphism, Single Nucleotide, RNA, Small Interfering genetics, Genome, Human, Herpesvirus 6, Human genetics, Virus Integration

Abstract

Sequences homologous to human herpesvirus 6 (HHV-6) are integrated within the nuclear genome of about 1% of humans, but it is not clear how this came about. It is also uncertain whether integrated HHV-6 can reactivate into an infectious virus. HHV-6 integrates into telomeres, and this has recently been associated with polymorphisms affecting MOV10L1. MOV10L1 is located on the subtelomere of chromosome 22q (chr22q) and is required to make PIWI-interacting RNAs (piRNAs). As piRNAs block germline integration of transposons, piRNA-mediated repression of HHV-6 integration has been proposed to explain this association. In vitro, recombination of the HHV-6 genome along its terminal direct repeats (DRs) leads to excision from the telomere and viral reactivation, but the expected "solo-DR scar" has not been described in vivo. Here we screened for integrated HHV-6 in 7,485 Japanese subjects using whole-genome sequencing (WGS). Integrated HHV-6 was associated with polymorphisms on chr22q. However, in contrast to prior work, we find that the reported MOV10L1 polymorphism is physically linked to an ancient endogenous HHV-6A variant integrated into the telomere of chr22q in East Asians. Unexpectedly, an HHV-6B variant has also endogenized in chr22q; two endogenous HHV-6 variants at this locus thus account for 72% of all integrated HHV-6 in Japan. We also report human genomes carrying only one portion of the HHV-6B genome, a solo-DR, supporting in vivo excision and possible viral reactivation. Together these results explain the recently-reported association between integrated HHV-6 and MOV10L1/piRNAs, suggest potential exaptation of HHV-6 in its coevolution with human chr22q, and clarify the evolution and risk of reactivation of the only intact (non-retro)viral genome known to be present in human germlines., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

6. Comprehensive molecular characterization of mitochondrial genomes in human cancers.

Author

Yuan Y, Ju YS, Kim Y, Li J, Wang Y, Yoon CJ, Yang Y, Martincorena I, Creighton CJ, Weinstein JN, Xu Y, Han L, Kim HL, Nakagawa H, Park K, Campbell PJ, and Liang H

Subjects

Cell Cycle genetics, DNA Repair genetics, DNA, Mitochondrial genetics, Humans, Mutation, Oxidative Phosphorylation, Sequence Analysis, RNA, DNA Copy Number Variations, Genome, Human genetics, Genome, Mitochondrial genetics, Neoplasms genetics, Whole Genome Sequencing

Abstract

Mitochondria are essential cellular organelles that play critical roles in cancer. Here, as part of the International Cancer Genome Consortium/The Cancer Genome Atlas Pan-Cancer Analysis of Whole Genomes Consortium, which aggregated whole-genome sequencing data from 2,658 cancers across 38 tumor types, we performed a multidimensional, integrated characterization of mitochondrial genomes and related RNA sequencing data. Our analysis presents the most definitive mutational landscape of mitochondrial genomes and identifies several hypermutated cases. Truncating mutations are markedly enriched in kidney, colorectal and thyroid cancers, suggesting oncogenic effects with the activation of signaling pathways. We find frequent somatic nuclear transfers of mitochondrial DNA, some of which disrupt therapeutic target genes. Mitochondrial copy number varies greatly within and across cancers and correlates with clinical variables. Co-expression analysis highlights the function of mitochondrial genes in oxidative phosphorylation, DNA repair and the cell cycle, and shows their connections with clinically actionable genes. Our study lays a foundation for translating mitochondrial biology into clinical applications.

Published

2020

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

Author

Rheinbay E, Nielsen MM, Abascal F, Wala JA, Shapira O, Tiao G, Hornshøj H, Hess JM, Juul RI, Lin Z, Feuerbach L, Sabarinathan R, Madsen T, Kim J, Mularoni L, Shuai S, Lanzós A, Herrmann C, Maruvka YE, Shen C, Amin SB, Bandopadhayay P, Bertl J, Boroevich KA, Busanovich J, Carlevaro-Fita J, Chakravarty D, Chan CWY, Craft D, Dhingra P, Diamanti K, Fonseca NA, Gonzalez-Perez A, Guo Q, Hamilton MP, Haradhvala NJ, Hong C, Isaev K, Johnson TA, Juul M, Kahles A, Kahraman A, Kim Y, Komorowski J, Kumar K, Kumar S, Lee D, Lehmann KV, Li Y, Liu EM, Lochovsky L, Park K, Pich O, Roberts ND, Saksena G, Schumacher SE, Sidiropoulos N, Sieverling L, Sinnott-Armstrong N, Stewart C, Tamborero D, Tubio JMC, Umer HM, Uusküla-Reimand L, Wadelius C, Wadi L, Yao X, Zhang CZ, Zhang J, Haber JE, Hobolth A, Imielinski M, Kellis M, Lawrence MS, von Mering C, Nakagawa H, Raphael BJ, Rubin MA, Sander C, Stein LD, Stuart JM, Tsunoda T, Wheeler DA, Johnson R, Reimand J, Gerstein M, Khurana E, Campbell PJ, López-Bigas N, Weischenfeldt J, Beroukhim R, Martincorena I, Pedersen JS, and Getz G

Subjects

DNA Breaks, Databases, Genetic, Gene Expression Regulation, Neoplastic, Genome-Wide Association Study, Humans, INDEL Mutation, Genome, Human genetics, Mutation genetics, Neoplasms genetics

Abstract

The discovery of drivers of cancer has traditionally focused on protein-coding genes 1-4 . 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) Consortium 5 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 drivers 6,7 , 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

8. ALPHLARD: a Bayesian method for analyzing HLA genes from whole genome sequence data.

Author

Hayashi S, Yamaguchi R, Mizuno S, Komura M, Miyano S, Nakagawa H, and Imoto S

Subjects

Algorithms, Alleles, Databases, Genetic, Genotype, Humans, Mutation, Exome Sequencing, Bayes Theorem, Computational Biology methods, Genome, Human, Genomics methods, HLA Antigens genetics, Whole Genome Sequencing

Abstract

Background: Although human leukocyte antigen (HLA) genotyping based on amplicon, whole exome sequence (WES), and RNA sequence data has been achieved in recent years, accurate genotyping from whole genome sequence (WGS) data remains a challenge due to the low depth. Furthermore, there is no method to identify the sequences of unknown HLA types not registered in HLA databases., Results: We developed a Bayesian model, called ALPHLARD, that collects reads potentially generated from HLA genes and accurately determines a pair of HLA types for each of HLA-A, -B, -C, -DPA1, -DPB1, -DQA1, -DQB1, and -DRB1 genes at 3rd field resolution. Furthermore, ALPHLARD can detect rare germline variants not stored in HLA databases and call somatic mutations from paired normal and tumor sequence data. We illustrate the capability of ALPHLARD using 253 WES data and 25 WGS data from Illumina platforms. By comparing the results of HLA genotyping from SBT and amplicon sequencing methods, ALPHLARD achieved 98.8% for WES data and 98.5% for WGS data at 2nd field resolution. We also detected three somatic point mutations and one case of loss of heterozygosity in the HLA genes from the WGS data., Conclusions: ALPHLARD showed good performance for HLA genotyping even from low-coverage data. It also has a potential to detect rare germline variants and somatic mutations in HLA genes. It would help to fill in the current gaps in HLA reference databases and unveil the immunological significance of somatic mutations identified in HLA genes.

Published

2018

9. Whole-genome mutational landscape and characterization of noncoding and structural mutations in liver cancer.

Author

Fujimoto A, Furuta M, Totoki Y, Tsunoda T, Kato M, Shiraishi Y, Tanaka H, Taniguchi H, Kawakami Y, Ueno M, Gotoh K, Ariizumi S, Wardell CP, Hayami S, Nakamura T, Aikata H, Arihiro K, Boroevich KA, Abe T, Nakano K, Maejima K, Sasaki-Oku A, Ohsawa A, Shibuya T, Nakamura H, Hama N, Hosoda F, Arai Y, Ohashi S, Urushidate T, Nagae G, Yamamoto S, Ueda H, Tatsuno K, Ojima H, Hiraoka N, Okusaka T, Kubo M, Marubashi S, Yamada T, Hirano S, Yamamoto M, Ohdan H, Shimada K, Ishikawa O, Yamaue H, Chayama K, Miyano S, Aburatani H, Shibata T, and Nakagawa H

Subjects

DNA Mutational Analysis, DNA, Neoplasm, Genetic Structures, Humans, Neoplasm Proteins genetics, Prognosis, Regulatory Sequences, Nucleic Acid, Sequence Analysis, DNA, Virus Integration, Genome, Human, Liver Neoplasms genetics, Mutation

Abstract

Liver cancer, which is most often associated with virus infection, is prevalent worldwide, and its underlying etiology and genomic structure are heterogeneous. Here we provide a whole-genome landscape of somatic alterations in 300 liver cancers from Japanese individuals. Our comprehensive analysis identified point mutations, structural variations (STVs), and virus integrations, in noncoding and coding regions. We discovered mutational signatures related to liver carcinogenesis and recurrently mutated coding and noncoding regions, such as long intergenic noncoding RNA genes (NEAT1 and MALAT1), promoters, CTCF-binding sites, and regulatory regions. STV analysis found a significant association with replication timing and identified known (CDKN2A, CCND1, APC, and TERT) and new (ASH1L, NCOR1, and MACROD2) cancer-related genes that were recurrently affected by STVs, leading to altered expression. These results emphasize the value of whole-genome sequencing analysis in discovering cancer driver mutations and understanding comprehensive molecular profiles of liver cancer, especially with regard to STVs and noncoding mutations.

Published

2016

10. Integrated analysis of whole genome and transcriptome sequencing reveals diverse transcriptomic aberrations driven by somatic genomic changes in liver cancers.

Author

Shiraishi Y, Fujimoto A, Furuta M, Tanaka H, Chiba K, Boroevich KA, Abe T, Kawakami Y, Ueno M, Gotoh K, Ariizumi S, Shibuya T, Nakano K, Sasaki A, Maejima K, Kitada R, Hayami S, Shigekawa Y, Marubashi S, Yamada T, Kubo M, Ishikawa O, Aikata H, Arihiro K, Ohdan H, Yamamoto M, Yamaue H, Chayama K, Tsunoda T, Miyano S, and Nakagawa H

Subjects

Carcinoma, Hepatocellular metabolism, Case-Control Studies, Gene Expression Regulation, Neoplastic, Humans, Liver Neoplasms metabolism, Oncogenes genetics, Carcinoma, Hepatocellular genetics, Clonal Evolution, Genome, Human, Liver Neoplasms genetics, Mutation, Transcriptome

Abstract

Recent studies applying high-throughput sequencing technologies have identified several recurrently mutated genes and pathways in multiple cancer genomes. However, transcriptional consequences from these genomic alterations in cancer genome remain unclear. In this study, we performed integrated and comparative analyses of whole genomes and transcriptomes of 22 hepatitis B virus (HBV)-related hepatocellular carcinomas (HCCs) and their matched controls. Comparison of whole genome sequence (WGS) and RNA-Seq revealed much evidence that various types of genomic mutations triggered diverse transcriptional changes. Not only splice-site mutations, but also silent mutations in coding regions, deep intronic mutations and structural changes caused splicing aberrations. HBV integrations generated diverse patterns of virus-human fusion transcripts depending on affected gene, such as TERT, CDK15, FN1 and MLL4. Structural variations could drive over-expression of genes such as WNT ligands, with/without creating gene fusions. Furthermore, by taking account of genomic mutations causing transcriptional aberrations, we could improve the sensitivity of deleterious mutation detection in known cancer driver genes (TP53, AXIN1, ARID2, RPS6KA3), and identified recurrent disruptions in putative cancer driver genes such as HNF4A, CPS1, TSC1 and THRAP3 in HCCs. These findings indicate genomic alterations in cancer genome have diverse transcriptomic effects, and integrated analysis of WGS and RNA-Seq can facilitate the interpretation of a large number of genomic alterations detected in cancer genome.

Published

2014

11. Comprehensive genome sequencing of the liver cancer genome.

Author

Nakagawa H and Shibata T

Subjects

Animals, Carcinoma, Hepatocellular diagnosis, Carcinoma, Hepatocellular therapy, Carcinoma, Hepatocellular virology, Chromatin Assembly and Disassembly genetics, Computational Biology, DNA Mutational Analysis, Gene Expression Regulation, Neoplastic, Genetic Predisposition to Disease, Hepatitis B virus genetics, Humans, Liver Neoplasms diagnosis, Liver Neoplasms therapy, Liver Neoplasms virology, Mutation, Phenotype, Precision Medicine, Predictive Value of Tests, Prognosis, Biomarkers, Tumor genetics, Carcinoma, Hepatocellular genetics, Genetic Testing, Genome, Human, Genomics methods, High-Throughput Nucleotide Sequencing, Liver Neoplasms genetics, Sequence Analysis, DNA

Abstract

Hepatocellular carcinoma (HCC) is the third leading cause of cancer-related death worldwide. Recently, comprehensive whole genome and exome sequencing analyses for HCC revealed new cancer-associated genes and a variety of genomic alterations. In particular, frequent genetic alterations of the chromatin remodeling genes were observed, suggesting a new potential therapeutic target for HCC. Sequencing analysis has further identified the molecular complexities of multicentric lesions and intratumoral heterogeneity. Detailed analyses of the somatic substitution pattern of the cancer genome and the HBV virus genome integration sites by using whole-genome sequencing will elucidate the molecular basis and diverse etiological factors involved in liver cancer development., (Copyright © 2012 Elsevier Ireland Ltd. All rights reserved.)

Published

2013

12. A practical method to detect SNVs and indels from whole genome and exome sequencing data.

Author

Shigemizu D, Fujimoto A, Akiyama S, Abe T, Nakano K, Boroevich KA, Yamamoto Y, Furuta M, Kubo M, Nakagawa H, and Tsunoda T

Subjects

Humans, Exome, Genome, Human, Polymorphism, Single Nucleotide

Abstract

The recent development of massively parallel sequencing technology has allowed the creation of comprehensive catalogs of genetic variation. However, due to the relatively high sequencing error rate for short read sequence data, sophisticated analysis methods are required to obtain high-quality variant calls. Here, we developed a probabilistic multinomial method for the detection of single nucleotide variants (SNVs) as well as short insertions and deletions (indels) in whole genome sequencing (WGS) and whole exome sequencing (WES) data for single sample calling. Evaluation with DNA genotyping arrays revealed a concordance rate of 99.98% for WGS calls and 99.99% for WES calls. Sanger sequencing of the discordant calls determined the false positive and false negative rates for the WGS (0.0068% and 0.17%) and WES (0.0036% and 0.0084%) datasets. Furthermore, short indels were identified with high accuracy (WGS: 94.7%, WES: 97.3%). We believe our method can contribute to the greater understanding of human diseases.

Published

2013

13. Whole-genome sequencing and comprehensive variant analysis of a Japanese individual using massively parallel sequencing.

Author

Fujimoto A, Nakagawa H, Hosono N, Nakano K, Abe T, Boroevich KA, Nagasaki M, Yamaguchi R, Shibuya T, Kubo M, Miyano S, Nakamura Y, and Tsunoda T

Subjects

Asian People genetics, Base Sequence, Chromosome Mapping, Genetic Diseases, Inborn genetics, Genetic Variation, Genome-Wide Association Study, Humans, Male, Polymorphism, Single Nucleotide, Translocation, Genetic, Genome, Human

Abstract

We report the analysis of a Japanese male using high-throughput sequencing to × 40 coverage. More than 99% of the sequence reads were mapped to the reference human genome. Using a Bayesian decision method, we identified 3,132,608 single nucleotide variations (SNVs). Comparison with six previously reported genomes revealed an excess of singleton nonsense and nonsynonymous SNVs, as well as singleton SNVs in conserved non-coding regions. We also identified 5,319 deletions smaller than 10 kb with high accuracy, in addition to copy number variations and rearrangements. De novo assembly of the unmapped sequence reads generated around 3 Mb of novel sequence, which showed high similarity to non-reference human genomes and the human herpesvirus 4 genome. Our analysis suggests that considerable variation remains undiscovered in the human genome and that whole-genome sequencing is an invaluable tool for obtaining a complete understanding of human genetic variation.

Published

2010

14. International network of cancer genome projects.

Author

Hudson TJ, Anderson W, Artez A, Barker AD, Bell C, Bernabé RR, Bhan MK, Calvo F, Eerola I, Gerhard DS, Guttmacher A, Guyer M, Hemsley FM, Jennings JL, Kerr D, Klatt P, Kolar P, Kusada J, Lane DP, Laplace F, Youyong L, Nettekoven G, Ozenberger B, Peterson J, Rao TS, Remacle J, Schafer AJ, Shibata T, Stratton MR, Vockley JG, Watanabe K, Yang H, Yuen MM, Knoppers BM, Bobrow M, Cambon-Thomsen A, Dressler LG, Dyke SO, Joly Y, Kato K, Kennedy KL, Nicolás P, Parker MJ, Rial-Sebbag E, Romeo-Casabona CM, Shaw KM, Wallace S, Wiesner GL, Zeps N, Lichter P, Biankin AV, Chabannon C, Chin L, Clément B, de Alava E, Degos F, Ferguson ML, Geary P, Hayes DN, Hudson TJ, Johns AL, Kasprzyk A, Nakagawa H, Penny R, Piris MA, Sarin R, Scarpa A, Shibata T, van de Vijver M, Futreal PA, Aburatani H, Bayés M, Botwell DD, Campbell PJ, Estivill X, Gerhard DS, Grimmond SM, Gut I, Hirst M, López-Otín C, Majumder P, Marra M, McPherson JD, Nakagawa H, Ning Z, Puente XS, Ruan Y, Shibata T, Stratton MR, Stunnenberg HG, Swerdlow H, Velculescu VE, Wilson RK, Xue HH, Yang L, Spellman PT, Bader GD, Boutros PC, Campbell PJ, Flicek P, Getz G, Guigó R, Guo G, Haussler D, Heath S, Hubbard TJ, Jiang T, Jones SM, Li Q, López-Bigas N, Luo R, Muthuswamy L, Ouellette BF, Pearson JV, Puente XS, Quesada V, Raphael BJ, Sander C, Shibata T, Speed TP, Stein LD, Stuart JM, Teague JW, Totoki Y, Tsunoda T, Valencia A, Wheeler DA, Wu H, Zhao S, Zhou G, Stein LD, Guigó R, Hubbard TJ, Joly Y, Jones SM, Kasprzyk A, Lathrop M, López-Bigas N, Ouellette BF, Spellman PT, Teague JW, Thomas G, Valencia A, Yoshida T, Kennedy KL, Axton M, Dyke SO, Futreal PA, Gerhard DS, Gunter C, Guyer M, Hudson TJ, McPherson JD, Miller LJ, Ozenberger B, Shaw KM, Kasprzyk A, Stein LD, Zhang J, Haider SA, Wang J, Yung CK, Cros A, Liang Y, Gnaneshan S, Guberman J, Hsu J, Bobrow M, Chalmers DR, Hasel KW, Joly Y, Kaan TS, Kennedy KL, Knoppers BM, Lowrance WW, Masui T, Nicolás P, Rial-Sebbag E, Rodriguez LL, Vergely C, Yoshida T, Grimmond SM, Biankin AV, Bowtell DD, Cloonan N, deFazio A, Eshleman JR, Etemadmoghadam D, Gardiner BB, Kench JG, Scarpa A, Sutherland RL, Tempero MA, Waddell NJ, Wilson PJ, McPherson JD, Gallinger S, Tsao MS, Shaw PA, Petersen GM, Mukhopadhyay D, Chin L, DePinho RA, Thayer S, Muthuswamy L, Shazand K, Beck T, Sam M, Timms L, Ballin V, Lu Y, Ji J, Zhang X, Chen F, Hu X, Zhou G, Yang Q, Tian G, Zhang L, Xing X, Li X, Zhu Z, Yu Y, Yu J, Yang H, Lathrop M, Tost J, Brennan P, Holcatova I, Zaridze D, Brazma A, Egevard L, Prokhortchouk E, Banks RE, Uhlén M, Cambon-Thomsen A, Viksna J, Ponten F, Skryabin K, Stratton MR, Futreal PA, Birney E, Borg A, Børresen-Dale AL, Caldas C, Foekens JA, Martin S, Reis-Filho JS, Richardson AL, Sotiriou C, Stunnenberg HG, Thoms G, van de Vijver M, van't Veer L, Calvo F, Birnbaum D, Blanche H, Boucher P, Boyault S, Chabannon C, Gut I, Masson-Jacquemier JD, Lathrop M, Pauporté I, Pivot X, Vincent-Salomon A, Tabone E, Theillet C, Thomas G, Tost J, Treilleux I, Calvo F, Bioulac-Sage P, Clément B, Decaens T, Degos F, Franco D, Gut I, Gut M, Heath S, Lathrop M, Samuel D, Thomas G, Zucman-Rossi J, Lichter P, Eils R, Brors B, Korbel JO, Korshunov A, Landgraf P, Lehrach H, Pfister S, Radlwimmer B, Reifenberger G, Taylor MD, von Kalle C, Majumder PP, Sarin R, Rao TS, Bhan MK, Scarpa A, Pederzoli P, Lawlor RA, Delledonne M, Bardelli A, Biankin AV, Grimmond SM, Gress T, Klimstra D, Zamboni G, Shibata T, Nakamura Y, Nakagawa H, Kusada J, Tsunoda T, Miyano S, Aburatani H, Kato K, Fujimoto A, Yoshida T, Campo E, López-Otín C, Estivill X, Guigó R, de Sanjosé S, Piris MA, Montserrat E, González-Díaz M, Puente XS, Jares P, Valencia A, Himmelbauer H, Quesada V, Bea S, Stratton MR, Futreal PA, Campbell PJ, Vincent-Salomon A, Richardson AL, Reis-Filho JS, van de Vijver M, Thomas G, Masson-Jacquemier JD, Aparicio S, Borg A, Børresen-Dale AL, Caldas C, Foekens JA, Stunnenberg HG, van't Veer L, Easton DF, Spellman PT, Martin S, Barker AD, Chin L, Collins FS, Compton CC, Ferguson ML, Gerhard DS, Getz G, Gunter C, Guttmacher A, Guyer M, Hayes DN, Lander ES, Ozenberger B, Penny R, Peterson J, Sander C, Shaw KM, Speed TP, Spellman PT, Vockley JG, Wheeler DA, Wilson RK, Hudson TJ, Chin L, Knoppers BM, Lander ES, Lichter P, Stein LD, Stratton MR, Anderson W, Barker AD, Bell C, Bobrow M, Burke W, Collins FS, Compton CC, DePinho RA, Easton DF, Futreal PA, Gerhard DS, Green AR, Guyer M, Hamilton SR, Hubbard TJ, Kallioniemi OP, Kennedy KL, Ley TJ, Liu ET, Lu Y, Majumder P, Marra M, Ozenberger B, Peterson J, Schafer AJ, Spellman PT, Stunnenberg HG, Wainwright BJ, Wilson RK, and Yang H

Subjects

DNA Methylation, DNA Mutational Analysis trends, Databases, Genetic, Genes, Neoplasm genetics, Genetics, Medical trends, Genomics trends, Humans, Intellectual Property, Mutation, Neoplasms classification, Neoplasms pathology, Neoplasms therapy, Genetics, Medical organization & administration, Genome, Human genetics, Genomics organization & administration, International Cooperation, Neoplasms genetics

Abstract

The International Cancer Genome Consortium (ICGC) was launched to coordinate large-scale cancer genome studies in tumours from 50 different cancer types and/or subtypes that are of clinical and societal importance across the globe. Systematic studies of more than 25,000 cancer genomes at the genomic, epigenomic and transcriptomic levels will reveal the repertoire of oncogenic mutations, uncover traces of the mutagenic influences, define clinically relevant subtypes for prognosis and therapeutic management, and enable the development of new cancer therapies.

Published

2010

15. Comprehensive molecular characterization of mitochondrial genomes in human cancers

Author

Yuan, Yuan, Ju, Young Seok, Kim, Youngwook, Li, Jun, Wang, Yumeng, Yoon, Christopher J, Yang, Yang, Martincorena, Inigo, Creighton, Chad J, Weinstein, John N, Xu, Yanxun, Han, Leng, Kim, Hyung-Lae, Nakagawa, Hidewaki, Park, Keunchil, Campbell, Peter J, Liang, Han, PCAWG Consortium, Yuan, Yuan [0000-0003-4706-7897], Ju, Young Seok [0000-0002-5514-4189], Kim, Youngwook [0000-0002-1106-3037], Li, Jun [0000-0002-1171-7141], Creighton, Chad J [0000-0002-6090-703X], Weinstein, John N [0000-0001-9401-6908], Han, Leng [0000-0002-7380-2640], Park, Keunchil [0000-0002-4846-7449], Campbell, Peter J [0000-0002-3921-0510], Liang, Han [0000-0001-7633-286X], and Apollo - University of Cambridge Repository

Subjects

DNA Copy Number Variations, DNA Repair, Whole Genome Sequencing, Genome, Human, Sequence Analysis, RNA, Neoplasms, Cell Cycle, Genome, Mitochondrial, Mutation, Humans, DNA, Mitochondrial, Oxidative Phosphorylation

Abstract

Mitochondria are essential cellular organelles that play critical roles in cancer. Here, as part of the International Cancer Genome Consortium/The Cancer Genome Atlas Pan-Cancer Analysis of Whole Genomes Consortium, which aggregated whole-genome sequencing data from 2,658 cancers across 38 tumor types, we performed a multidimensional, integrated characterization of mitochondrial genomes and related RNA sequencing data. Our analysis presents the most definitive mutational landscape of mitochondrial genomes and identifies several hypermutated cases. Truncating mutations are markedly enriched in kidney, colorectal and thyroid cancers, suggesting oncogenic effects with the activation of signaling pathways. We find frequent somatic nuclear transfers of mitochondrial DNA, some of which disrupt therapeutic target genes. Mitochondrial copy number varies greatly within and across cancers and correlates with clinical variables. Co-expression analysis highlights the function of mitochondrial genes in oxidative phosphorylation, DNA repair and the cell cycle, and shows their connections with clinically actionable genes. Our study lays a foundation for translating mitochondrial biology into clinical applications.

Published

2020

16. 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, PCAWG Consortium, and Apollo - University of Cambridge Repository

Subjects

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

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

17. Butler enables rapid cloud-based analysis of thousands of human genomes

Author

Yakneen, Sergei, Waszak, Sebastian M, Gertz, Michael, Korbel, Jan O, Aminou, Brice, Bartolome, Javier, Boroevich, Keith A, Boyce, Rich, Brooks, Angela N, Buchanan, Alex, Buchhalter, Ivo, Butler, Adam P, Byrne, Niall J, Cafferkey, Andy, Campbell, Peter J, Chen, Zhaohong, Cho, Sunghoon, Choi, Wan, Clapham, Peter, Davis-Dusenbery, Brandi N, De La Vega, Francisco M, Demeulemeester, Jonas, Dow, Michelle T, Dursi, Lewis Jonathan, Eils, Juergen, Eils, Roland, Ellrott, Kyle, Farcas, Claudiu, Favero, Francesco, Fayzullaev, Nodirjon, Ferretti, Vincent, Flicek, Paul, Fonseca, Nuno A, Gelpi, Josep Ll, Getz, Gad, Gibson, Bob, Grossman, Robert L, Harismendy, Olivier, Heath, Allison P, Heinold, Michael C, Hess, Julian M, Hofmann, Oliver, Hong, Jongwhi H, Hudson, Thomas J, Hutter, Barbara, Hutter, Carolyn M, Huebschmann, Daniel, Imoto, Seiya, Ivkovic, Sinisa, Jeon, Seung-Hyup, Jiao, Wei, Jung, Jongsun, Kabbe, Rolf, Kahles, Andre, Kerssemakers, Jules NA, Kim, Hyung-Lae, Kim, Hyunghwan, Kim, Jihoon, Kim, Youngwook, Kleinheinz, Kortine, Koscher, Michael, Koures, Antonios, Kovacevic, Milena, Lawerenz, Chris, Leshchiner, Ignaty, Liu, Jia, Livitz, Dimitri, Mihaiescu, George L, Mijalkovic, Sanja, Lazic, Ana Mijalkovic, Miyano, Satoru, Miyoshi, Naoki, Nahal-Bose, Hardeep K, Nakagawa, Hidewaki, Nastic, Mia, Newhouse, Steven J, Nicholson, Jonathan, O'Connor, Brian D, Ocana, David, Ohi, Kazuhiro, Ohno-Machado, Lucila, Omberg, Larsson, Ouellette, BF Francis, Paramasivam, Nagarajan, Perry, Marc D, Pihl, Todd D, Prinz, Manuel, Puiggros, Montserrat, Radovic, Petar, Raine, Keiran M, Rheinbay, Esther, Rosenberg, Mara, Royo, Romina, Raetsch, Gunnar, Saksena, Gordon, Schlesner, Matthias, Shorser, Solomon, Short, Charles, Sofia, Heidi J, Spring, Jonathan, Stein, Lincoln D, Struck, Adam J, Tiao, Grace, Tijanic, Nebojsa, Torrents, David, Van Loo, Peter, Vazquez, Miguel, Vicente, David, Wala, Jeremiah A, Wang, Zhining, Weischenfeldt, Joachim, Werner, Johannes, Williams, Ashley, Woo, Youngchoon, Wright, Adam J, Xiang, Qian, Yang, Liming, Yuen, Denis, Yung, Christina K, Zhang, Junjun, Graduate School, Laboratory Genetic Metabolic Diseases, AGEM - Endocrinology, metabolism and nutrition, and AGEM - Inborn errors of metabolism

Subjects

Computer science, Biomedical Engineering, Bioengineering, Cloud computing, computer.software_genre, Brief Communication, Genome informatics, Genoma humà, Applied Microbiology and Biotechnology, Genome, Biologia computacional, Computational biology, 03 medical and health sciences, 0302 clinical medicine, Software, Computational platforms and environments, Cancer genome, Neoplasms, Humans, Hardware and infrastructure, ddc:610, 030304 developmental biology, VARIANT DISCOVERY, 0303 health sciences, Data processing, Science & Technology, Women's cancers Radboud Institute for Molecular Life Sciences [Radboudumc 17], Human genome, business.industry, Genome, Human, Computational Biology, Cloud Computing, Women's cancers Radboud Institute for Health Sciences [Radboudumc 17], Biotechnology & Applied Microbiology, Molecular Medicine, Anomaly detection, Data mining, business, computer, Life Sciences & Biomedicine, 030217 neurology & neurosurgery, Biotechnology

Abstract

Cloud computing offers easy and economical access to computational capacity at a scale that had previously been available to only the largest research institutions. To take advantage, large biological datasets are increasingly analyzed on various cloud computing platforms, using public, private and hybrid clouds1 with the aid of workflow systems. When employed in global projects, such systems must be flexible in their ability to operate in different environments, including academic clouds, to allow researchers to bring their computational pipelines to the data, especially in cases where the raw data themselves cannot be moved. The recently developed cloud-based scientific workflow frameworks Nextflow2, Toil3 and GenomeVIP4 focus their support largely on individual commercial cloud computing environments—mostly Amazon Web Services—and lack complete functionality for other major providers. This limits their use in studies that require multi-cloud operation due to practical and regulatory requirements5,6. Butler, in contrast, provides full support for operation on OpenStack-based commercial and academic clouds, Amazon Web Services, Microsoft Azure and Google Compute Platform, and can thus enable international collaborations involving the analysis of hundreds of thousands of samples where distributed cloud-based computation is pursued in different jurisdictions5,6,7., Nature Biotechnology, 38 (3), ISSN:1546-1696, ISSN:1087-0156

Published

2020

18. Author Correction: Comprehensive molecular characterization of mitochondrial genomes in human cancers

Author

Yuan, Yuan, Ju, Young Seok, Kim, Youngwook, Li, Jun, Wang, Yumeng, Yoon, Christopher J., Yang, Yang, Martincorena, Inigo, Creighton, Chad J., Weinstein, John N., Xu, Yanxun, Han, Leng, Kim, Hyung-Lae, Nakagawa, Hidewaki, Park, Keunchil, Campbell, Peter J., and Liang, Han

Subjects

DNA Copy Number Variations, DNA Repair, Whole Genome Sequencing, Genome, Human, Sequence Analysis, RNA, Cell Cycle, DNA, Mitochondrial, Oxidative Phosphorylation, Neoplasms, Genome, Mitochondrial, Mutation, Genetics, Humans, Author Correction

Abstract

Mitochondria are essential cellular organelles that play critical roles in cancer. Here, as part of the International Cancer Genome Consortium/The Cancer Genome Atlas Pan-Cancer Analysis of Whole Genomes Consortium, which aggregated whole-genome sequencing data from 2,658 cancers across 38 tumor types, we performed a multidimensional, integrated characterization of mitochondrial genomes and related RNA sequencing data. Our analysis presents the most definitive mutational landscape of mitochondrial genomes and identifies several hypermutated cases. Truncating mutations are markedly enriched in kidney, colorectal and thyroid cancers, suggesting oncogenic effects with the activation of signaling pathways. We find frequent somatic nuclear transfers of mitochondrial DNA, some of which disrupt therapeutic target genes. Mitochondrial copy number varies greatly within and across cancers and correlates with clinical variables. Co-expression analysis highlights the function of mitochondrial genes in oxidative phosphorylation, DNA repair and the cell cycle, and shows their connections with clinically actionable genes. Our study lays a foundation for translating mitochondrial biology into clinical applications.

Published

2020

19. Comprehensive molecular characterization of mitochondrial genomes in human cancers

Author

Yuan, Yuan, Ju, Young Seok, Kim, Youngwook, Li, Jun, Wang, Yumeng, Yoon, Christopher J, Yang, Yang, Martincorena, Inigo, Creighton, Chad J, Weinstein, John N, Xu, Yanxun, Han, Leng, Kim, Hyung-Lae, Nakagawa, Hidewaki, Park, Keunchil, Campbell, Peter J, Liang, Han, and PCAWG Consortium

Subjects

DNA Copy Number Variations, DNA Repair, Whole Genome Sequencing, Genome, Human, Sequence Analysis, RNA, Neoplasms, Cell Cycle, Genome, Mitochondrial, Mutation, Humans, DNA, Mitochondrial, Oxidative Phosphorylation, 3. Good health

Abstract

Mitochondria are essential cellular organelles that play critical roles in cancer. Here, as part of the International Cancer Genome Consortium/The Cancer Genome Atlas Pan-Cancer Analysis of Whole Genomes Consortium, which aggregated whole-genome sequencing data from 2,658 cancers across 38 tumor types, we performed a multidimensional, integrated characterization of mitochondrial genomes and related RNA sequencing data. Our analysis presents the most definitive mutational landscape of mitochondrial genomes and identifies several hypermutated cases. Truncating mutations are markedly enriched in kidney, colorectal and thyroid cancers, suggesting oncogenic effects with the activation of signaling pathways. We find frequent somatic nuclear transfers of mitochondrial DNA, some of which disrupt therapeutic target genes. Mitochondrial copy number varies greatly within and across cancers and correlates with clinical variables. Co-expression analysis highlights the function of mitochondrial genes in oxidative phosphorylation, DNA repair and the cell cycle, and shows their connections with clinically actionable genes. Our study lays a foundation for translating mitochondrial biology into clinical applications.

20. 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

Gene Expression Regulation, Neoplastic, INDEL Mutation, Genome, Human, Neoplasms, DNA Breaks, Databases, Genetic, Mutation, Humans, 3. Good health, Genome-Wide Association Study

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.