Your search keyword '"Morris, Quaid"' showing total 17 results

1. Characterizing genetic intra-tumor heterogeneity across 2,658 human cancer genomes

Author

Dentro, Stefan C, Leshchiner, Ignaty, Haase, Kerstin, Tarabichi, Maxime, Wintersinger, Jeff, Deshwar, Amit G, Yu, Kaixian, Rubanova, Yulia, Macintyre, Geoff, Demeulemeester, Jonas, Vázquez-García, Ignacio, Kleinheinz, Kortine, Livitz, Dimitri G, Malikic, Salem, Donmez, Nilgun, Sengupta, Subhajit, Anur, Pavana, Jolly, Clemency, Cmero, Marek, Rosebrock, Daniel, Schumacher, Steven E, Fan, Yu, Fittall, Matthew, Drews, Ruben M, Yao, Xiaotong, Watkins, Thomas BK, Lee, Juhee, Schlesner, Matthias, Zhu, Hongtu, Adams, David J, McGranahan, Nicholas, Swanton, Charles, Getz, Gad, Boutros, Paul C, Imielinski, Marcin, Beroukhim, Rameen, Sahinalp, S Cenk, Ji, Yuan, Peifer, Martin, Martincorena, Inigo, Markowetz, Florian, Mustonen, Ville, Yuan, Ke, Gerstung, Moritz, Spellman, Paul T, Wang, Wenyi, Morris, Quaid D, Wedge, David C, Van Loo, Peter, Consortium, on behalf of the PCAWG Evolution and Heterogeneity Working Group and the PCAWG, Gonzalez, Santiago, Bowtell, David D, Campbell, Peter J, Cao, Shaolong, Christie, Elizabeth L, Cun, Yupeng, Dawson, Kevin J, Eils, Roland, Garsed, Dale W, Ha, Gavin, Jerman, Lara, Lee-Six, Henry, Mitchell, Thomas J, Oesper, Layla, Peto, Myron, and Raphael, Benjamin J

Subjects

Biological Sciences, Biomedical and Clinical Sciences, Bioinformatics and Computational Biology, Genetics, Oncology and Carcinogenesis, Human Genome, Biotechnology, Women's Health, Precision Medicine, Cancer Genomics, Cancer, Digestive Diseases, Good Health and Well Being, DNA Copy Number Variations, DNA, Neoplasm, Databases, Genetic, Drug Resistance, Neoplasm, Genetic Heterogeneity, Humans, Neoplasms, Polymorphism, Single Nucleotide, Whole Genome Sequencing, PCAWG Evolution and Heterogeneity Working Group and the PCAWG Consortium, branching evolution, cancer driver genes, cancer evolution, intra-tumor heterogeneity, pan-cancer genomics, subclonal reconstruction, tumor phylogeny, whole-genome sequencing, Medical and Health Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences

Abstract

Intra-tumor heterogeneity (ITH) is a mechanism of therapeutic resistance and therefore an important clinical challenge. However, the extent, origin, and drivers of ITH across cancer types are poorly understood. To address this, we extensively characterize ITH across whole-genome sequences of 2,658 cancer samples spanning 38 cancer types. Nearly all informative samples (95.1%) contain evidence of distinct subclonal expansions with frequent branching relationships between subclones. We observe positive selection of subclonal driver mutations across most cancer types and identify cancer type-specific subclonal patterns of driver gene mutations, fusions, structural variants, and copy number alterations as well as dynamic changes in mutational processes between subclonal expansions. Our results underline the importance of ITH and its drivers in tumor evolution and provide a pan-cancer resource of comprehensively annotated subclonal events from whole-genome sequencing data.

Published

2021

2. A practical guide to cancer subclonal reconstruction from DNA sequencing.

Author

Tarabichi, Maxime, Salcedo, Adriana, Deshwar, Amit G, Ni Leathlobhair, Máire, Wintersinger, Jeff, Wedge, David C, Van Loo, Peter, Morris, Quaid D, and Boutros, Paul C

Subjects

Humans, Neoplasms, DNA, Neoplasm, Sequence Analysis, DNA, Polymorphism, Single Nucleotide, Algorithms, Human Genome, Genetics, Cancer, Developmental Biology, Biological Sciences, Technology, Medical and Health Sciences

Abstract

Subclonal reconstruction from bulk tumor DNA sequencing has become a pillar of cancer evolution studies, providing insight into the clonality and relative ordering of mutations and mutational processes. We provide an outline of the complex computational approaches used for subclonal reconstruction from single and multiple tumor samples. We identify the underlying assumptions and uncertainties in each step and suggest best practices for analysis and quality assessment. This guide provides a pragmatic resource for the growing user community of subclonal reconstruction methods.

Published

2021

3. Quantifying the influence of mutation detection on tumour subclonal reconstruction.

Author

Liu, Lydia Y, Bhandari, Vinayak, Salcedo, Adriana, Espiritu, Shadrielle MG, Morris, Quaid D, Kislinger, Thomas, and Boutros, Paul C

Subjects

Clone Cells, Humans, Prostatic Neoplasms, Computational Biology, Genetic Heterogeneity, Mutation, Polymorphism, Single Nucleotide, Algorithms, Models, Genetic, Male, DNA Copy Number Variations, Clonal Evolution, Biomarkers, Tumor, Whole Genome Sequencing, Human Genome, Cancer, Genetics

Abstract

Whole-genome sequencing can be used to estimate subclonal populations in tumours and this intra-tumoural heterogeneity is linked to clinical outcomes. Many algorithms have been developed for subclonal reconstruction, but their variabilities and consistencies are largely unknown. We evaluate sixteen pipelines for reconstructing the evolutionary histories of 293 localized prostate cancers from single samples, and eighteen pipelines for the reconstruction of 10 tumours with multi-region sampling. We show that predictions of subclonal architecture and timing of somatic mutations vary extensively across pipelines. Pipelines show consistent types of biases, with those incorporating SomaticSniper and Battenberg preferentially predicting homogenous cancer cell populations and those using MuTect tending to predict multiple populations of cancer cells. Subclonal reconstructions using multi-region sampling confirm that single-sample reconstructions systematically underestimate intra-tumoural heterogeneity, predicting on average fewer than half of the cancer cell populations identified by multi-region sequencing. Overall, these biases suggest caution in interpreting specific architectures and subclonal variants.

Published

2020

4. The evolutionary history of 2,658 cancers

Author

Gerstung, Moritz, Jolly, Clemency, Leshchiner, Ignaty, Dentro, Stefan C, Gonzalez, Santiago, Rosebrock, Daniel, Mitchell, Thomas J, Rubanova, Yulia, Anur, Pavana, Yu, Kaixian, Tarabichi, Maxime, Deshwar, Amit, Wintersinger, Jeff, Kleinheinz, Kortine, Vázquez-García, Ignacio, Haase, Kerstin, Jerman, Lara, Sengupta, Subhajit, Macintyre, Geoff, Malikic, Salem, Donmez, Nilgun, Livitz, Dimitri G, Cmero, Marek, Demeulemeester, Jonas, Schumacher, Steven, Fan, Yu, Yao, Xiaotong, Lee, Juhee, Schlesner, Matthias, Boutros, Paul C, Bowtell, David D, Zhu, Hongtu, Getz, Gad, Imielinski, Marcin, Beroukhim, Rameen, Sahinalp, S Cenk, Ji, Yuan, Peifer, Martin, Markowetz, Florian, Mustonen, Ville, Yuan, Ke, Wang, Wenyi, Morris, Quaid D, Spellman, Paul T, Wedge, David C, and Van Loo, Peter

Subjects

Biological Sciences, Biomedical and Clinical Sciences, Bioinformatics and Computational Biology, Genetics, Oncology and Carcinogenesis, Rare Diseases, Brain Cancer, Brain Disorders, Human Genome, Cancer, 2.1 Biological and endogenous factors, Aetiology, DNA Repair, Evolution, Molecular, Gene Dosage, Genes, Tumor Suppressor, Genetic Variation, Genome, Human, Humans, Mutagenesis, Insertional, Neoplasms, PCAWG Evolution & Heterogeneity Working Group, PCAWG Consortium, General Science & Technology

Abstract

Cancer develops through a process of somatic evolution1,2. Sequencing data from a single biopsy represent a snapshot of this process that can reveal the timing of specific genomic aberrations and the changing influence of mutational processes3. Here, by whole-genome sequencing analysis of 2,658 cancers as part of the Pan-Cancer Analysis of Whole Genomes (PCAWG) Consortium of the International Cancer Genome Consortium (ICGC) and The Cancer Genome Atlas (TCGA)4, we reconstruct the life history and evolution of mutational processes and driver mutation sequences of 38 types of cancer. Early oncogenesis is characterized by mutations in a constrained set of driver genes, and specific copy number gains, such as trisomy 7 in glioblastoma and isochromosome 17q in medulloblastoma. The mutational spectrum changes significantly throughout tumour evolution in 40% of samples. A nearly fourfold diversification of driver genes and increased genomic instability are features of later stages. Copy number alterations often occur in mitotic crises, and lead to simultaneous gains of chromosomal segments. Timing analyses suggest that driver mutations often precede diagnosis by many years, if not decades. Together, these results determine the evolutionary trajectories of cancer, and highlight opportunities for early cancer detection.

Published

2020

5. Reconstructing evolutionary trajectories of mutation signature activities in cancer using TrackSig

Author

Rubanova, Yulia, Shi, Ruian, Harrigan, Caitlin F, Li, Roujia, Wintersinger, Jeff, Sahin, Nil, Deshwar, Amit G, and Morris, Quaid D

Subjects

Cancer, Genetics, Rare Diseases, Human Genome, 2.1 Biological and endogenous factors, Aetiology, Computational Biology, Computer Simulation, Evolution, Molecular, Gene Frequency, Genome, Human, Humans, Mutation, Neoplasms, Polymorphism, Single Nucleotide, Whole Genome Sequencing, PCAWG Evolution and Heterogeneity Working Group, PCAWG Consortium

Abstract

The type and genomic context of cancer mutations depend on their causes. These causes have been characterized using signatures that represent mutation types that co-occur in the same tumours. However, it remains unclear how mutation processes change during cancer evolution due to the lack of reliable methods to reconstruct evolutionary trajectories of mutational signature activity. Here, as part of the ICGC/TCGA Pan-Cancer Analysis of Whole Genomes (PCAWG) Consortium, which aggregated whole-genome sequencing data from 2658 cancers across 38 tumour types, we present TrackSig, a new method that reconstructs these trajectories using optimal, joint segmentation and deconvolution of mutation type and allele frequencies from a single tumour sample. In simulations, we find TrackSig has a 3-5% activity reconstruction error, and 12% false detection rate. It outperforms an aggressive baseline in situations with branching evolution, CNA gain, and neutral mutations. Applied to data from 2658 tumours and 38 cancer types, TrackSig permits pan-cancer insight into evolutionary changes in mutational processes.

Published

2020

6. A deep learning system accurately classifies primary and metastatic cancers using passenger mutation patterns

Author

Jiao, Wei, Atwal, Gurnit, Polak, Paz, Karlic, Rosa, Cuppen, Edwin, Danyi, Alexandra, de Ridder, Jeroen, van Herpen, Carla, Lolkema, Martijn P, Steeghs, Neeltje, Getz, Gad, Morris, Quaid D, and Stein, Lincoln D

Subjects

Cancer, Genetics, Rare Diseases, Human Genome, 2.1 Biological and endogenous factors, Aetiology, Good Health and Well Being, Computational Biology, Deep Learning, Female, Genome, Human, Humans, Male, Mutation, Neoplasm Metastasis, Neoplasms, Reproducibility of Results, Whole Genome Sequencing, PCAWG Tumor Subtypes and Clinical Translation Working Group, PCAWG Consortium

Abstract

In cancer, the primary tumour's organ of origin and histopathology are the strongest determinants of its clinical behaviour, but in 3% of cases a patient presents with a metastatic tumour and no obvious primary. Here, as part of the ICGC/TCGA Pan-Cancer Analysis of Whole Genomes (PCAWG) Consortium, we train a deep learning classifier to predict cancer type based on patterns of somatic passenger mutations detected in whole genome sequencing (WGS) of 2606 tumours representing 24 common cancer types produced by the PCAWG Consortium. Our classifier achieves an accuracy of 91% on held-out tumor samples and 88% and 83% respectively on independent primary and metastatic samples, roughly double the accuracy of trained pathologists when presented with a metastatic tumour without knowledge of the primary. Surprisingly, adding information on driver mutations reduced accuracy. Our results have clinical applicability, underscore how patterns of somatic passenger mutations encode the state of the cell of origin, and can inform future strategies to detect the source of circulating tumour DNA.

Published

2020

7. A community effort to create standards for evaluating tumor subclonal reconstruction.

Author

Salcedo, Adriana, Tarabichi, Maxime, Espiritu, Shadrielle Melijah G, Deshwar, Amit G, David, Matei, Wilson, Nathan M, Dentro, Stefan, Wintersinger, Jeff A, Liu, Lydia Y, Ko, Minjeong, Sivanandan, Srinivasan, Zhang, Hongjiu, Zhu, Kaiyi, Ou Yang, Tai-Hsien, Chilton, John M, Buchanan, Alex, Lalansingh, Christopher M, P'ng, Christine, Anghel, Catalina V, Umar, Imaad, Lo, Bryan, Zou, William, DREAM SMC-Het Participants, Simpson, Jared T, Stuart, Joshua M, Anastassiou, Dimitris, Guan, Yuanfang, Ewing, Adam D, Ellrott, Kyle, Wedge, David C, Morris, Quaid, Van Loo, Peter, and Boutros, Paul C

Subjects

DREAM SMC-Het Participants, Clone Cells, Humans, Neoplasms, Gene Dosage, Mutation, Polymorphism, Single Nucleotide, Genome, Algorithms, Reference Standards, Computer Simulation, DNA Copy Number Variations, Human Genome, Cancer, Genetics

Abstract

Tumor DNA sequencing data can be interpreted by computational methods that analyze genomic heterogeneity to infer evolutionary dynamics. A growing number of studies have used these approaches to link cancer evolution with clinical progression and response to therapy. Although the inference of tumor phylogenies is rapidly becoming standard practice in cancer genome analyses, standards for evaluating them are lacking. To address this need, we systematically assess methods for reconstructing tumor subclonality. First, we elucidate the main algorithmic problems in subclonal reconstruction and develop quantitative metrics for evaluating them. Then we simulate realistic tumor genomes that harbor all known clonal and subclonal mutation types and processes. Finally, we benchmark 580 tumor reconstructions, varying tumor read depth, tumor type and somatic variant detection. Our analysis provides a baseline for the establishment of gold-standard methods to analyze tumor heterogeneity.

Published

2020

8. A Chemical Biology Approach to Model Pontocerebellar Hypoplasia Type 1B (PCH1B)

Author

François-Moutal, Liberty, Jahanbakhsh, Shahriyar, Nelson, Andrew DL, Ray, Debashish, Scott, David D, Hennefarth, Matthew R, Moutal, Aubin, Perez-Miller, Samantha, Ambrose, Andrew J, Al-Shamari, Ahmed, Coursodon, Philippe, Meechoovet, Bessie, Reiman, Rebecca, Lyons, Eric, Beilstein, Mark, Chapman, Eli, Morris, Quaid D, Van Keuren-Jensen, Kendall, Hughes, Timothy R, Khanna, Rajesh, Koehler, Carla, Jen, Joanna, Gokhale, Vijay, and Khanna, May

Subjects

Neurosciences, Genetics, 2.1 Biological and endogenous factors, Aetiology, Animals, Atrophy, Cerebellum, Disease Models, Animal, Down-Regulation, Exosome Multienzyme Ribonuclease Complex, Gene Knockdown Techniques, Humans, Isoquinolines, Molecular Docking Simulation, Mutation, Olivopontocerebellar Atrophies, Phenotype, Protein Binding, Protein Domains, RNA, RNA-Binding Proteins, Spinal Curvatures, Transcriptome, Up-Regulation, Zebrafish, Chemical Sciences, Biological Sciences, Organic Chemistry

Abstract

Mutations of EXOSC3 have been linked to the rare neurological disorder known as Pontocerebellar Hypoplasia type 1B (PCH1B). EXOSC3 is one of three putative RNA-binding structural cap proteins that guide RNA into the RNA exosome, the cellular machinery that degrades RNA. Using RNAcompete, we identified a G-rich RNA motif binding to EXOSC3. Surface plasmon resonance (SPR) and microscale thermophoresis (MST) indicated an affinity in the low micromolar range of EXOSC3 for long and short G-rich RNA sequences. Although several PCH1B-causing mutations in EXOSC3 did not engage a specific RNA motif as shown by RNAcompete, they exhibited lower binding affinity to G-rich RNA as demonstrated by MST. To test the hypothesis that modification of the RNA-protein interface in EXOSC3 mutants may be phenocopied by small molecules, we performed an in-silico screen of 50 000 small molecules and used enzyme-linked immunosorbant assays (ELISAs) and MST to assess the ability of the molecules to inhibit RNA-binding by EXOSC3. We identified a small molecule, EXOSC3-RNA disrupting (ERD) compound 3 (ERD03), which ( i) bound specifically to EXOSC3 in saturation transfer difference nuclear magnetic resonance (STD-NMR), ( ii) disrupted the EXOSC3-RNA interaction in a concentration-dependent manner, and ( iii) produced a PCH1B-like phenotype with a 50% reduction in the cerebellum and an abnormally curved spine in zebrafish embryos. This compound also induced modification of zebrafish RNA expression levels similar to that observed with a morpholino against EXOSC3. To our knowledge, this is the first example of a small molecule obtained by rational design that models the abnormal developmental effects of a neurodegenerative disease in a whole organism.

Published

2018

9. Gene Expression Deconvolution for Uncovering Molecular Signatures in Response to Therapy in Juvenile Idiopathic Arthritis

Author

Cui, Ang, Quon, Gerald, Rosenberg, Alan M, Yeung, Rae SM, and Morris, Quaid

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Rare Diseases, Pediatric, Autoimmune Disease, Genetics, Arthritis, 4.1 Discovery and preclinical testing of markers and technologies, Detection, screening and diagnosis, Inflammatory and immune system, Adolescent, Algorithms, Antirheumatic Agents, Arthritis, Juvenile, Biomarkers, Blood Platelets, Child, Gene Expression, Gene Expression Profiling, Humans, Lymphocyte Count, Models, Theoretical, Monocytes, Neutrophils, Pilot Projects, T-Lymphocytes, Treatment Outcome, alpha-Defensins, BBOP Study Consortium, General Science & Technology

Abstract

Gene expression-based signatures help identify pathways relevant to diseases and treatments, but are challenging to construct when there is a diversity of disease mechanisms and treatments in patients with complex diseases. To overcome this challenge, we present a new application of an in silico gene expression deconvolution method, ISOpure-S1, and apply it to identify a common gene expression signature corresponding to response to treatment in 33 juvenile idiopathic arthritis (JIA) patients. Using pre- and post-treatment gene expression profiles only, we found a gene expression signature that significantly correlated with a reduction in the number of joints with active arthritis, a measure of clinical outcome (Spearman rho = 0.44, p = 0.040, Bonferroni correction). This signature may be associated with a decrease in T-cells, monocytes, neutrophils and platelets. The products of most differentially expressed genes include known biomarkers for JIA such as major histocompatibility complexes and interleukins, as well as novel biomarkers including α-defensins. This method is readily applicable to expression datasets of other complex diseases to uncover shared mechanistic patterns in heterogeneous samples.

Published

2016

10. ISOpureR: an R implementation of a computational purification algorithm of mixed tumour profiles.

Author

Anghel, Catalina V, Quon, Gerald, Haider, Syed, Nguyen, Francis, Deshwar, Amit G, Morris, Quaid D, and Boutros, Paul C

Subjects

Humans, Prostatic Neoplasms, Prognosis, Gene Expression Profiling, Computational Biology, Algorithms, Models, Theoretical, Software, Male, Tumour heterogeneity, mRNA abundance profile, Deconvolution, Models, Theoretical, Mathematical Sciences, Biological Sciences, Information and Computing Sciences, Bioinformatics

Abstract

BackgroundTumour samples containing distinct sub-populations of cancer and normal cells present challenges in the development of reproducible biomarkers, as these biomarkers are based on bulk signals from mixed tumour profiles. ISOpure is the only mRNA computational purification method to date that does not require a paired tumour-normal sample, provides a personalized cancer profile for each patient, and has been tested on clinical data. Replacing mixed tumour profiles with ISOpure-preprocessed cancer profiles led to better prognostic gene signatures for lung and prostate cancer.ResultsTo simplify the integration of ISOpure into standard R-based bioinformatics analysis pipelines, the algorithm has been implemented as an R package. The ISOpureR package performs analogously to the original code in estimating the fraction of cancer cells and the patient cancer mRNA abundance profile from tumour samples in four cancer datasets.ConclusionsThe ISOpureR package estimates the fraction of cancer cells and personalized patient cancer mRNA abundance profile from a mixed tumour profile. This open-source R implementation enables integration into existing computational pipelines, as well as easy testing, modification and extension of the model.

Published

2015

11. Binding specificities of human RNA-binding proteins toward structured and linear RNA sequences

Author

Jolma, Arttu, Zhang, Jilin, Hughes, Timothy R., Maher, Louis James, Taipale, Jussi, Mondragón, Estefania, Morgunova, Ekaterina, Kivioja, Teemu, Laverty, Kaitlin U., Yin, Yimeng, Zhu, Fangjie, Bourenkov, Gleb, Morris, Quaid, Research Programs Unit, University of Helsinki, ATG - Applied Tumor Genomics, Doctoral Programme in Integrative Life Science, Department of Pathology, University Management, and Jussi Taipale / Principal Investigator

Subjects

11832 Microbiology and virology, 318 Medical biotechnology, IDENTIFICATION, Base Sequence, Genome, Human, Research, SELEX Aptamer Technique, RECOGNITION, 1184 Genetics, developmental biology, physiology, SITE, RNA-Binding Proteins, Ribonucleases, DOMAIN, Protein Domains, AU-RICH ELEMENT, ddc:540, 1182 Biochemistry, cell and molecular biology, Humans, Nucleic Acid Conformation, RNA, Nucleotide Motifs, Protein Multimerization, MESSENGER-RNA, DECAY, Protein Binding

Abstract

RNA-binding proteins (RBPs) regulate RNA metabolism at multiple levels by affecting splicing of nascent transcripts, RNA folding, base modification, transport, localization, translation, and stability. Despite their central role in RNA function, the RNA-binding specificities of most RBPs remain unknown or incompletely defined. To address this, we have assembled a genome-scale collection of RBPs and their RNA-binding domains (RBDs) and assessed their specificities using high-through-put RNA-SELEX (HTR-SELEX). Approximately 70% of RBPs for which we obtained a motif bound to short linear sequenc-es, whereas similar to 30% preferred structured motifs folding into stem-loops. We also found that many RBPs can bind to multiple distinctly different motifs. Analysis of the matches of the motifs in human genomic sequences suggested novel roles for many RBPs. We found that three cytoplasmic proteins-ZC3H12A, ZC3H12B, and ZC3H12C-bound to motifs resembling the splice donor sequence, suggesting that these proteins are involved in degradation of cytoplasmic viral and/or unspliced transcripts. Structural analysis revealed that the RNA motif was not bound by the conventional C3H1 RNA-binding domain of ZC3H12B. Instead, the RNA motif was bound by the ZC3H12B's PilT N terminus (PIN) RNase domain, revealing a po-tential mechanism by which unconventional RBDs containing active sites or molecule-binding pockets could interact with short, structured RNA molecules. Our collection containing 145 high-resolution binding specificity models for 86 RBPs is the largest systematic resource for the analysis of human RBPs and will greatly facilitate future analysis of the various bi-ological roles of this important class of proteins.

Published

2020

12. Inferring structural variant cancer cell fraction

Author

Cmero, Marek, Yuan, Ke, Ong, Cheng Soon, Schröder, Jan, Corcoran, Niall M., Papenfuss, Tony, Hovens, Christopher M., Markowetz, Florian, Macintyre, Geoff, Adams, David J., Anur, Pavana, Beroukhim, Rameen, Boutros, Paul C., Bowtell, David D. L., Campbell, Peter J., Cao, Shaolong, Christie, Elizabeth L., Cun, Yupeng, Dawson, Kevin J., Demeulemeester, Jonas, Dentro, Stefan C., Deshwar, Amit G., Donmez, Nilgun, Drews, Ruben M., Eils, Roland, Fan, Yu, Fittall, Matthew W., Garsed, Dale W., Gerstung, Moritz, Getz, Gad, Gonzalez, Santiago, Ha, Gavin, Haase, Kerstin, Imielinski, Marcin, Jerman, Lara, Ji, Yuan, Jolly, Clemency, Kleinheinz, Kortine, Lee, Juhee, Lee-Six, Henry, Leshchiner, Ignaty, Livitz, Dimitri, Malikic, Salem, Martincorena, Iñigo, Mitchell, Thomas J., Morris, Quaid D., Mustonen, Ville, Oesper, Layla, Peifer, Martin, Peto, Myron, Raphael, Benjamin J., Rosebrock, Daniel, Rubanova, Yulia, Sahinalp, S. Cenk, Salcedo, Adriana, Schlesner, Matthias, Schumacher, Steven E., Sengupta, Subhajit, Shi, Ruian, Shin, Seung Jun, Spellman, Paul T., Spiro, Oliver, Stein, Lincoln D., Tarabichi, Maxime, Van Loo, Peter, Vembu, Shankar, Vázquez-García, Ignacio, Wang, Wenyi, Wedge, David C., Wheeler, David A., Wintersinger, Jeffrey A., Yang, Tsun-Po, Yao, Xiaotong, Yu, Kaixian, Zhu, Hongtu, Cmero, Marek [0000-0001-7783-5530], Yuan, Ke [0000-0002-2318-1460], Ong, Cheng Soon [0000-0002-2302-9733], Papenfuss, Tony [0000-0002-1102-8506], Markowetz, Florian [0000-0002-2784-5308], Macintyre, Geoff [0000-0003-3906-467X], Apollo - University of Cambridge Repository, Dentro, SC, Wedge, DC, Yang, T-P, Organismal and Evolutionary Biology Research Programme, Institute of Biotechnology, Bioinformatics, and Department of Computer Science

Subjects

Male, 0301 basic medicine, Medizin, General Physics and Astronomy, Somatic evolution in cancer, Genome, 0302 clinical medicine, Gene Frequency, Neoplasms, 129, lcsh:Science, Cancer, Ovarian Neoplasms, Women's cancers Radboud Institute for Molecular Life Sciences [Radboudumc 17], Multidisciplinary, Manchester Cancer Research Centre, Prostatic Neoplasms/genetics, Liver Neoplasms, 1184 Genetics, developmental biology, physiology, Neoplasms/genetics, Women's cancers Radboud Institute for Health Sciences [Radboudumc 17], Ovarian Cancer, 3. Good health, 030220 oncology & carcinogenesis, 1181 Ecology, evolutionary biology, 139, Female, Algorithms, Human, 631/67, DNA Copy Number Variations, Science, In silico, Computational biology, Biology, Sensitivity and Specificity, Article, General Biochemistry, Genetics and Molecular Biology, Ovarian Neoplasms/genetics, 03 medical and health sciences, Rare Diseases, Machine learning, Genetics, PCAWG Evolution and Heterogeneity Working Group, medicine, Humans, Computer Simulation, ddc:610, Liver Neoplasms/genetics, Allele frequency, Whole genome sequencing, 45, Whole Genome Sequencing, Genome, Human, ResearchInstitutes_Networks_Beacons/mcrc, Human Genome, Breakpoint, Computational Biology, Prostatic Neoplasms, PCAWG Consortium, General Chemistry, Computational Biology/methods, 631/114/1305, 113 Computer and information sciences, Pancreatic Neoplasms/genetics, medicine.disease, Computational biology and bioinformatics, Pancreatic Neoplasms, 030104 developmental biology, lcsh:Q, Human genome, 631/114, 119, Digestive Diseases

Abstract

We present SVclone, a computational method for inferring the cancer cell fraction of structural variant (SV) breakpoints from whole-genome sequencing data. SVclone accurately determines the variant allele frequencies of both SV breakends, then simultaneously estimates the cancer cell fraction and SV copy number. We assess performance using in silico mixtures of real samples, at known proportions, created from two clonal metastases from the same patient. We find that SVclone’s performance is comparable to single-nucleotide variant-based methods, despite having an order of magnitude fewer data points. As part of the Pan-Cancer Analysis of Whole Genomes (PCAWG) consortium, which aggregated whole-genome sequencing data from 2658 cancers across 38 tumour types, we use SVclone to reveal a subset of liver, ovarian and pancreatic cancers with subclonally enriched copy-number neutral rearrangements that show decreased overall survival. SVclone enables improved characterisation of SV intra-tumour heterogeneity., The authors present SVclone, a computational method for inferring the cancer cell fraction of structural variants from whole-genome sequencing data.

Published

2020

13. Detecting microRNAs of high influence on protein functional interaction networks: a prostate cancer case study

Author

Alshalalfa, Mohammed, Bader, Gary D, Goldenberg, Anna, Morris, Quaid, and Alhajj, Reda

Subjects

Male, Applied Mathematics, Methodology Article, Computational Biology, Prostatic Neoplasms, Protein interactions, Prognosis, Gene Expression Regulation, Neoplastic, MicroRNAs, lcsh:Biology (General), Structural Biology, Recurrence, High-influence miRNA, Modelling and Simulation, Protein Interaction Mapping, Biomarkers, Tumor, Humans, Protein Interaction Maps, MiRNA, Systems biology, Molecular Biology, lcsh:QH301-705.5

Abstract

Background The use of biological molecular network information for diagnostic and prognostic purposes and elucidation of molecular disease mechanism is a key objective in systems biomedicine. The network of regulatory miRNA-target and functional protein interactions is a rich source of information to elucidate the function and the prognostic value of miRNAs in cancer. The objective of this study is to identify miRNAs that have high influence on target protein complexes in prostate cancer as a case study. This could provide biomarkers or therapeutic targets relevant for prostate cancer treatment. Results Our findings demonstrate that a miRNA’s functional role can be explained by its target protein connectivity within a physical and functional interaction network. To detect miRNAs with high influence on target protein modules, we integrated miRNA and mRNA expression profiles with a sequence based miRNA-target network and human functional and physical protein interactions (FPI). miRNAs with high influence on target protein complexes play a role in prostate cancer progression and are promising diagnostic or prognostic biomarkers. We uncovered several miRNA-regulated protein modules which were enriched in focal adhesion and prostate cancer genes. Several miRNAs such as miR-96, miR-182, and miR-143 demonstrated high influence on their target protein complexes and could explain most of the gene expression changes in our analyzed prostate cancer data set. Conclusions We describe a novel method to identify active miRNA-target modules relevant to prostate cancer progression and outcome. miRNAs with high influence on protein networks are valuable biomarkers that can be used in clinical investigations for prostate cancer treatment.

Published

2012

14. The evolutionary history of 2,658 cancers

Author

Gerstung, Moritz, Jolly, Clemency, Leshchiner, Ignaty, Dentro, Stefan C, Gonzalez, Santiago, Rosebrock, Daniel, Mitchell, Thomas J, Rubanova, Yulia, Anur, Pavana, Yu, Kaixian, Tarabichi, Maxime, Deshwar, Amit, Wintersinger, Jeff, Kleinheinz, Kortine, Vázquez-García, Ignacio, Haase, Kerstin, Jerman, Lara, Sengupta, Subhajit, Macintyre, Geoff, Malikic, Salem, Donmez, Nilgun, Livitz, Dimitri G, Cmero, Marek, Demeulemeester, Jonas, Schumacher, Steven, Fan, Yu, Yao, Xiaotong, Lee, Juhee, Schlesner, Matthias, Boutros, Paul C, Bowtell, David D, Zhu, Hongtu, Getz, Gad, Imielinski, Marcin, Beroukhim, Rameen, Sahinalp, S Cenk, Ji, Yuan, Peifer, Martin, Markowetz, Florian, Mustonen, Ville, Yuan, Ke, Wang, Wenyi, Morris, Quaid D, PCAWG Evolution & Heterogeneity Working Group, Spellman, Paul T, Wedge, David C, Van Loo, Peter, and PCAWG Consortium

Subjects

Evolution, Molecular, Mutagenesis, Insertional, DNA Repair, Genome, Human, Neoplasms, Gene Dosage, Genetic Variation, Humans, Genes, Tumor Suppressor, 3. Good health

Abstract

Cancer develops through a process of somatic evolution1,2. Sequencing data from a single biopsy represent a snapshot of this process that can reveal the timing of specific genomic aberrations and the changing influence of mutational processes3. Here, by whole-genome sequencing analysis of 2,658 cancers as part of the Pan-Cancer Analysis of Whole Genomes (PCAWG) Consortium of the International Cancer Genome Consortium (ICGC) and The Cancer Genome Atlas (TCGA)4, we reconstruct the life history and evolution of mutational processes and driver mutation sequences of 38 types of cancer. Early oncogenesis is characterized by mutations in a constrained set of driver genes, and specific copy number gains, such as trisomy 7 in glioblastoma and isochromosome 17q in medulloblastoma. The mutational spectrum changes significantly throughout tumour evolution in 40% of samples. A nearly fourfold diversification of driver genes and increased genomic instability are features of later stages. Copy number alterations often occur in mitotic crises, and lead to simultaneous gains of chromosomal segments. Timing analyses suggest that driver mutations often precede diagnosis by many years, if not decades. Together, these results determine the evolutionary trajectories of cancer, and highlight opportunities for early cancer detection.

15. A deep learning system accurately classifies primary and metastatic cancers using passenger mutation patterns

Author

Jiao, Wei, Atwal, Gurnit, Polak, Paz, Karlic, Rosa, Cuppen, Edwin, PCAWG Tumor Subtypes And Clinical Translation Working Group, Danyi, Alexandra, De Ridder, Jeroen, Van Herpen, Carla, Lolkema, Martijn P, Steeghs, Neeltje, Getz, Gad, Morris, Quaid D, Stein, Lincoln D, and PCAWG Consortium

Subjects

Male, Deep Learning, Whole Genome Sequencing, Genome, Human, Neoplasms, Mutation, Computational Biology, Humans, Reproducibility of Results, Female, Neoplasm Metastasis, 3. Good health

Abstract

In cancer, the primary tumour's organ of origin and histopathology are the strongest determinants of its clinical behaviour, but in 3% of cases a patient presents with a metastatic tumour and no obvious primary. Here, as part of the ICGC/TCGA Pan-Cancer Analysis of Whole Genomes (PCAWG) Consortium, we train a deep learning classifier to predict cancer type based on patterns of somatic passenger mutations detected in whole genome sequencing (WGS) of 2606 tumours representing 24 common cancer types produced by the PCAWG Consortium. Our classifier achieves an accuracy of 91% on held-out tumor samples and 88% and 83% respectively on independent primary and metastatic samples, roughly double the accuracy of trained pathologists when presented with a metastatic tumour without knowledge of the primary. Surprisingly, adding information on driver mutations reduced accuracy. Our results have clinical applicability, underscore how patterns of somatic passenger mutations encode the state of the cell of origin, and can inform future strategies to detect the source of circulating tumour DNA.

16. A deep learning system accurately classifies primary and metastatic cancers using passenger mutation patterns

Author

Alexandra Danyi, Justin Whalley, Sean Grimmond, David Chang, Edwin Cuppen, Choon Kiat Ong, Peter Bailey, Samuel Aparicio, Jiayin Wang, Kirsten Kübler, Quaid Morris, Raquel Rabionet, Elizabeth Christie, Markus Ringnér, Rosa Karlić, Shuto Hayashi, Sergei Yakneen, Lynn Fink, Martijn Lolkema, Derek Wright, Gurnit Atwal, Nigel Jamieson, Benedikt Brors, LUCA MALCOVATI, Atwal, Gurnit [0000-0003-2817-3117], Polak, Paz [0000-0002-2153-4488], Karlic, Rosa [0000-0002-1291-2897], de Ridder, Jeroen [0000-0002-0828-3477], Lolkema, Martijn P [0000-0003-0466-2928], Getz, Gad [0000-0002-0936-0753], Morris, Quaid D [0000-0002-2760-6999], Apollo - University of Cambridge Repository, and Medical Oncology

Subjects

0301 basic medicine, Oncology, Male, Cancer genomics, Cancer of unknown primary, Chemistry(all), Cell of origin, Medizin, General Physics and Astronomy, Genome, Biochemistry, 0302 clinical medicine, Neoplasms, 2.1 Biological and endogenous factors, Aetiology, Neoplasm Metastasis, Càncer, lcsh:Science, health care economics and organizations, Cancer, Women's cancers Radboud Institute for Molecular Life Sciences [Radboudumc 17], Multidisciplinary, Women's cancers Radboud Institute for Health Sciences [Radboudumc 17], 3. Good health, 030220 oncology & carcinogenesis, Female, Human, Rare cancers Radboud Institute for Health Sciences [Radboudumc 9], medicine.medical_specialty, Science, education, 610 Medicine & health, Biology, Physics and Astronomy(all), ENCODE, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Rare Diseases, All institutes and research themes of the Radboud University Medical Center, Text mining, Deep Learning, Metàstasi, SDG 3 - Good Health and Well-being, Internal medicine, Genetics, medicine, Humans, PCAWG Tumor Subtypes and Clinical Translation Working Group, Genomes, Whole genome sequencing, Whole Genome Sequencing, business.industry, Genome, Human, Biochemistry, Genetics and Molecular Biology(all), Deep learning, Human Genome, PCAWG Consortium, Computational Biology, Reproducibility of Results, General Chemistry, Good Health and Well Being, 030104 developmental biology, Mutation, lcsh:Q, Histopathology, Human genome, Artificial intelligence, business, Genetics and Molecular Biology(all)

Abstract

In cancer, the primary tumour’s organ of origin and histopathology are the strongest determinants of its clinical behaviour, but in 3% of cases a patient presents with a metastatic tumour and no obvious primary. Here, as part of the ICGC/TCGA Pan-Cancer Analysis of Whole Genomes (PCAWG) Consortium, we train a deep learning classifier to predict cancer type based on patterns of somatic passenger mutations detected in whole genome sequencing (WGS) of 2606 tumours representing 24 common cancer types produced by the PCAWG Consortium. Our classifier achieves an accuracy of 91% on held-out tumor samples and 88% and 83% respectively on independent primary and metastatic samples, roughly double the accuracy of trained pathologists when presented with a metastatic tumour without knowledge of the primary. Surprisingly, adding information on driver mutations reduced accuracy. Our results have clinical applicability, underscore how patterns of somatic passenger mutations encode the state of the cell of origin, and can inform future strategies to detect the source of circulating tumour DNA., Some cancer patients first present with metastases where the location of the primary is unidentified; these are difficult to treat. In this study, using machine learning, the authors develop a method to determine the tissue of origin of a cancer based on whole sequencing data.

Published

2020

17. Reconstructing evolutionary trajectories of mutation signature activities in cancer using TrackSig

Author

Rubanova, Y., Shi, R., Harrigan, C.F., Li, R., Wintersinger, J., Sahin, N., Deshwar, A.G., Dentro, S.C., Leshchiner, I., Gerstung, M., Jolly, C., Haase, K., Tarabichi, M., Yu, K., Gonzalez, S., Macintyre, G., Adams, D.J., Anur, P., Beroukhim, R., Boutros, P.C., Bowtell, D.D., Campbell, P.J., Cao, S., Christie, E.L., Cmero, M., Cun, Y., Dawson, K.J., Demeulemeester, J., Donmez, N., Drews, R.M., Eils, R., Fan, Y., Fittall, M., Garsed, D.W., Getz, G., Ha, G., Imielinski, M., Jerman, L., Ji, Y., Kleinheinz, K., Lee, J., Lee-Six, H., Livitz, D.G., Malikic, S., Markowetz, F., Martincorena, I., Mitchell, T.J., Mustonen, V., Oesper, L., Peifer, M., Peto, M., Raphael, B.J., Rosebrock, D., Sahinalp, S.C., Salcedo, A., Schlesner, M., Schumacher, S., Sengupta, Subhajit, Shin, S.J., Spiro, O., Stein, L.D., Vázquez-García, I., Vembu, S., Wheeler, D.A., Yang, T.-P., Yao, X., Yuan, K., Zhu, H., Wang, W., Morris, Q., Spellman, P.T., Wedge, D.C., Van Loo, P., Harrigan, Caitlin F [0000-0002-9243-9648], Morris, Quaid D [0000-0002-2760-6999], Apollo - University of Cambridge Repository, Organismal and Evolutionary Biology Research Programme, Helsinki Institute for Information Technology, Institute of Biotechnology, Bioinformatics, Department of Computer Science, Wedge, DC, and Dentro, SC

Subjects

0301 basic medicine, Medizin, General Physics and Astronomy, Genome, 0302 clinical medicine, Gene Frequency, Ecology,Evolution & Ethology, Neoplasms, 2.1 Biological and endogenous factors, Computational models, Aetiology, lcsh:Science, Cancer genetics, Cancer, Human Biology & Physiology, Women's cancers Radboud Institute for Molecular Life Sciences [Radboudumc 17], Multidisciplinary, Manchester Cancer Research Centre, 1184 Genetics, developmental biology, physiology, Single Nucleotide, Neoplasms/genetics, Women's cancers Radboud Institute for Health Sciences [Radboudumc 17], 3. Good health, 030220 oncology & carcinogenesis, Mutation (genetic algorithm), 1181 Ecology, evolutionary biology, Genetics & Genomics, Human, Neutral mutation, Evolution, Science, Context (language use), Computational biology, Biology, Polymorphism, Single Nucleotide, General Biochemistry, Genetics and Molecular Biology, Article, Evolution, Molecular, 03 medical and health sciences, Rare Diseases, Genetics, medicine, PCAWG Evolution and Heterogeneity Working Group, Humans, Computer Simulation, ddc:610, Polymorphism, Allele frequency, Computational & Systems Biology, Whole genome sequencing, Whole Genome Sequencing, Genome, Human, ResearchInstitutes_Networks_Beacons/mcrc, Human Genome, Molecular, Computational Biology, PCAWG Consortium, General Chemistry, Computational Biology/methods, Tumour Biology, medicine.disease, 113 Computer and information sciences, 030104 developmental biology, Mutation, Human genome, lcsh:Q

Abstract

The type and genomic context of cancer mutations depend on their causes. These causes have been characterized using signatures that represent mutation types that co-occur in the same tumours. However, it remains unclear how mutation processes change during cancer evolution due to the lack of reliable methods to reconstruct evolutionary trajectories of mutational signature activity. Here, as part of the ICGC/TCGA Pan-Cancer Analysis of Whole Genomes (PCAWG) Consortium, which aggregated whole-genome sequencing data from 2658 cancers across 38 tumour types, we present TrackSig, a new method that reconstructs these trajectories using optimal, joint segmentation and deconvolution of mutation type and allele frequencies from a single tumour sample. In simulations, we find TrackSig has a 3–5% activity reconstruction error, and 12% false detection rate. It outperforms an aggressive baseline in situations with branching evolution, CNA gain, and neutral mutations. Applied to data from 2658 tumours and 38 cancer types, TrackSig permits pan-cancer insight into evolutionary changes in mutational processes., Cancers evolve as they progress under differing selective pressures. Here, as part of the ICGC/TCGA Pan-Cancer Analysis of Whole Genomes (PCAWG) Consortium, the authors present the method TrackSig the estimates evolutionary trajectories of somatic mutational processes from single bulk tumour data.

Published

2020