Your search keyword '"cancer driver genes"' showing total 182 results

1. SSCI: Self-Supervised Deep Learning Improves Network Structure for Cancer Driver Gene Identification.

Author

Xu, Jialuo, Hao, Jun, Liao, Xingyu, Shang, Xuequn, and Li, Xingyi

Subjects

*CANCER genes, *RECEIVER operating characteristic curves, *EARLY detection of cancer, *DEEP learning, *CARCINOGENESIS, *BIOLOGICAL networks

Abstract

The pathogenesis of cancer is complex, involving abnormalities in some genes in organisms. Accurately identifying cancer genes is crucial for the early detection of cancer and personalized treatment, among other applications. Recent studies have used graph deep learning methods to identify cancer driver genes based on biological networks. However, incompleteness and the noise of the networks will weaken the performance of models. To address this, we propose a cancer driver gene identification method based on self-supervision for graph convolutional networks, which can efficiently enhance the structure of the network and further improve predictive accuracy. The reliability of SSCI is verified by the area under the receiver operating characteristic curves (AUROC), the area under the precision-recall curves (AUPRC), and the F1 score, with respective values of 0.966, 0.964, and 0.913. The results show that our method can identify cancer driver genes with strong discriminative power and biological interpretability. [ABSTRACT FROM AUTHOR]

Published

2024

2. The Many Roads from Alternative Splicing to Cancer: Molecular Mechanisms Involving Driver Genes.

Author

Gimeno-Valiente, Francisco, López-Rodas, Gerardo, Castillo, Josefa, and Franco, Luis

Subjects

*EPIGENOMICS, *SEX chromatin, *RNA, *TUMOR suppressor genes, *ONCOGENES, *TUMORS, *GENETIC mutation

Abstract

Simple Summary: Alternative splicing is a mechanism that allows, through the combination of different exons, for the yielding of several protein variants from a single gene. These variants may display different and often opposed functions. Mutations occurring in driver genes result in oncogenesis, but alternative splicing may also result in obtaining oncogenic variants in the absence of driver mutations. This review describes how the oncogenic potential of driver genes is activated through aberrant alternative splicing. Firstly, there are driver genes directly acting on alternative splicing and their dysregulation affects the splicing of other genes involved in malignant transformation. A second possibility is that aberrant alternative splicing of a proto-oncogene or tumour suppressor gene results in the appearance of an oncogenic variant. The oncogenic potential of a total of 199 driver genes may result from aberrant alternative splicing, and the molecular mechanisms involved are detailed for more than 40 genes. Cancer driver genes are either oncogenes or tumour suppressor genes that are classically activated or inactivated, respectively, by driver mutations. Alternative splicing—which produces various mature mRNAs and, eventually, protein variants from a single gene—may also result in driving neoplastic transformation because of the different and often opposed functions of the variants of driver genes. The present review analyses the different alternative splicing events that result in driving neoplastic transformation, with an emphasis on their molecular mechanisms. To do this, we collected a list of 568 gene drivers of cancer and revised the literature to select those involved in the alternative splicing of other genes as well as those in which its pre-mRNA is subject to alternative splicing, with the result, in both cases, of producing an oncogenic isoform. Thirty-one genes fall into the first category, which includes splicing factors and components of the spliceosome and splicing regulators. In the second category, namely that comprising driver genes in which alternative splicing produces the oncogenic isoform, 168 genes were found. Then, we grouped them according to the molecular mechanisms responsible for alternative splicing yielding oncogenic isoforms, namely, mutations in cis splicing-determining elements, other causes involving non-mutated cis elements, changes in splicing factors, and epigenetic and chromatin-related changes. The data given in the present review substantiate the idea that aberrant splicing may regulate the activation of proto-oncogenes or inactivation of tumour suppressor genes and details on the mechanisms involved are given for more than 40 driver genes. [ABSTRACT FROM AUTHOR]

Published

2024

3. A feature extraction framework for discovering pan‐cancer driver genes based on multi‐omics data.

Author

Xue, Xiaomeng, Li, Feng, Shang, Junliang, Dai, Lingyun, Ge, Daohui, and Ren, Qianqian

Subjects

*CANCER diagnosis, *DNA methylation, *GENE expression, *PROTEIN-protein interactions, *CANCER genes

Abstract

The identification of tumor driver genes facilitates accurate cancer diagnosis and treatment, playing a key role in precision oncology, along with gene signaling, regulation, and their interaction with protein complexes. To tackle the challenge of distinguishing driver genes from a large number of genomic data, we construct a feature extraction framework for discovering pan‐cancer driver genes based on multi‐omics data (mutations, gene expression, copy number variants, and DNA methylation) combined with protein–protein interaction (PPI) networks. Using a network propagation algorithm, we mine functional information among nodes in the PPI network, focusing on genes with weak node information to represent specific cancer information. From these functional features, we extract distribution features of pan‐cancer data, pan‐cancer TOPSIS features of functional features using the ideal solution method, and SetExpan features of pan‐cancer data from the gene functional features, a method to rank pan‐cancer data based on the average inverse rank. These features represent the common message of pan‐cancer. Finally, we use the lightGBM classification algorithm for gene prediction. Experimental results show that our method outperforms existing methods in terms of the area under the check precision‐recall curve (AUPRC) and demonstrates better performance across different PPI networks. This indicates our framework's effectiveness in predicting potential cancer genes, offering valuable insights for the diagnosis and treatment of tumors. [ABSTRACT FROM AUTHOR]

Published

2024

4. DGCL: A Contrastive Learning Method for Predicting Cancer Driver Genes Based on Graph Diffusion

Author

Peng, Wei, Zhou, Zhengnan, Dai, Wei, Xu, Xinping, Fu, Xiaodong, Liu, Li, Liu, Lijun, Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Peng, Wei, editor, Cai, Zhipeng, editor, and Skums, Pavel, editor

Published

2024

5. Construction and clinical significance of prognostic risk markers based on cancer driver genes in lung adenocarcinoma

Author

Su, Yazhou, Huo, Tingting, Wang, Yanan, and Li, Jingyan

Published

2024

6. DriverDetector: An R package providing multiple statistical methods for cancer driver genes detection and tools for downstream analysis

Author

Zeyuan Wang, Hong Gu, Pan Qin, and Jia Wang

Subjects

Cancer driver genes, Genome analysis software, Background mutation rate, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

Identifying driver genes in cancer is a difficult task because of the heterogeneity of cancer as well as the complex interactions among genes. As sequencing data become more readily available, there is a growing need for detecting cancer driver genes based on statistical and mathematical modeling methods. Currently, plenty of driver gene identification algorithms have been published, but they fail to achieve consistent results. In order to obtain gene sets with high confidence, we present DriverDetector, an R package providing a convenient workflow for cancer driver genes detection and downstream analysis. We develop the background mutation rate calculating module based on the distance between genes in covariate space and binomial test, followed by the driver gene selection module which integrates 11 methods, including two already recognized approaches, a de novo method, and five variants of Fisher's method which are applied to driver gene identification for the first time. Through verification on 12 TCGA datasets, each method is able to identify a set of confirmed driver genes while the number of resulting genes vary significantly across different methods. For robust driver genes detection, a voting strategy based on 10 of the statistical methods is further applied. Results show that the collective prediction based on the voting strategy demonstrates superiority in achieving the consistency of prediction while ensuring a reasonable number of predicted genes and confirmed drivers. By comparing the results of each cancer dataset, we also find that sample size has a huge impact on the number of predicted genes. For downstream analysis, DriverDetector automatically generates plenty of plots and tables to elaborate the results. We propose DriverDetector as a user-friendly tool promoting early diagnosis of cancer and the development of targeted drugs.

Published

2024

7. SSCI: Self-Supervised Deep Learning Improves Network Structure for Cancer Driver Gene Identification

Author

Jialuo Xu, Jun Hao, Xingyu Liao, Xuequn Shang, and Xingyi Li

Subjects

cancer driver genes, self-supervised deep learning, graph learning, network structure enhancement, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

The pathogenesis of cancer is complex, involving abnormalities in some genes in organisms. Accurately identifying cancer genes is crucial for the early detection of cancer and personalized treatment, among other applications. Recent studies have used graph deep learning methods to identify cancer driver genes based on biological networks. However, incompleteness and the noise of the networks will weaken the performance of models. To address this, we propose a cancer driver gene identification method based on self-supervision for graph convolutional networks, which can efficiently enhance the structure of the network and further improve predictive accuracy. The reliability of SSCI is verified by the area under the receiver operating characteristic curves (AUROC), the area under the precision-recall curves (AUPRC), and the F1 score, with respective values of 0.966, 0.964, and 0.913. The results show that our method can identify cancer driver genes with strong discriminative power and biological interpretability.

Published

2024

8. Prediction of Cancer Driver Genes Based on Pyramidal Dynamic Mapping Algorithm

Author

Wei, Pi-Jing, Zhou, Shu-Li, Cao, Rui-Fen, Su, Yansen, Zheng, Chun-Hou, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Huang, De-Shuang, editor, Premaratne, Prashan, editor, Jin, Baohua, editor, Qu, Boyang, editor, Jo, Kang-Hyun, editor, and Hussain, Abir, editor

Published

2023

9. Introduction to Cancer

Author

Carlberg, Carsten, Velleuer, Eunike, Molnár, Ferdinand, Carlberg, Carsten, Velleuer, Eunike, and Molnár, Ferdinand

Published

2023

10. Mechanistic insights into the interactions between cancer drivers and the tumour immune microenvironment

Author

Hrvoje Misetic, Mohamed Reda Keddar, Jean-Pierre Jeannon, and Francesca D. Ciccarelli

Subjects

Cancer driver genes, Cancer immunology, Computational biology, Head and neck cancer, Functional networks, Medicine, Genetics, QH426-470

Abstract

Abstract Background The crosstalk between cancer and the tumour immune microenvironment (TIME) has attracted significant interest in the latest years because of its impact on cancer evolution and response to treatment. Despite this, cancer-specific tumour-TIME interactions and their mechanistic insights are still poorly understood. Methods Here, we compute the significant interactions occurring between cancer-specific genetic drivers and five anti- and pro-tumour TIME features in 32 cancer types using Lasso regularised ordinal regression. Focusing on head and neck squamous cancer (HNSC), we rebuild the functional networks linking specific TIME driver alterations to the TIME state they associate with. Results The 477 TIME drivers that we identify are multifunctional genes whose alterations are selected early in cancer evolution and recur across and within cancer types. Tumour suppressors and oncogenes have an opposite effect on the TIME and the overall anti-tumour TIME driver burden is predictive of response to immunotherapy. TIME driver alterations predict the immune profiles of HNSC molecular subtypes, and perturbations in keratinization, apoptosis and interferon signalling underpin specific driver-TIME interactions. Conclusions Overall, our study delivers a comprehensive resource of TIME drivers, gives mechanistic insights into their immune-regulatory role, and provides an additional framework for patient prioritisation to immunotherapy. The full list of TIME drivers and associated properties are available at http://www.network-cancer-genes.org .

Published

2023

11. 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, and PCAWG Evolution and Heterogeneity Working Group and the PCAWG Consortium

Subjects

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, Genetics, Cancer, Human Genome, 2.1 Biological and endogenous factors, Developmental Biology, Biological Sciences, Medical and Health 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

12. The adaptive evolution of cancer driver genes

Author

Langyu Gu, Canwei Xia, Shiyu Yang, and Guofen Yang

Subjects

Cancer driver genes, Positive selection, Primates, Modern human populations, Thyroid cancer, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background Cancer is a life-threatening disease in humans; yet, cancer genes are frequently reported to be under positive selection. This suggests an evolutionary-genetic paradox in which cancer evolves as a secondary product of selection in human beings. However, systematic investigation of the evolution of cancer driver genes is sparse. Results Using comparative genomics analysis, population genetics analysis and computational molecular evolutionary analysis, the evolution of 568 cancer driver genes of 66 cancer types were evaluated at two levels, selection on the early evolution of humans (long timescale selection in the human lineage during primate evolution, i.e., millions of years), and recent selection in modern human populations (~ 100,000 years). Results showed that eight cancer genes covering 11 cancer types were under positive selection in the human lineage (long timescale selection). And 35 cancer genes covering 47 cancer types were under positive selection in modern human populations (recent selection). Moreover, SNPs associated with thyroid cancer in three thyroid cancer driver genes (CUX1, HERC2 and RGPD3) were under positive selection in East Asian and European populations, consistent with the high incidence of thyroid cancer in these populations. Conclusions These findings suggest that cancer can be evolved, in part, as a by-product of adaptive changes in humans. Different SNPs at the same locus can be under different selection pressures in different populations, and thus should be under consideration during precision medicine, especially for targeted medicine in specific populations.

Published

2023

13. MiRNA–gene network embedding for predicting cancer driver genes.

Author

Peng, Wei, Wu, Rong, Dai, Wei, Ning, Yu, Fu, Xiaodong, Liu, Li, and Liu, Lijun

Subjects

*CANCER genes, *RECEIVER operating characteristic curves, *REGULATOR genes, *VOXEL-based morphometry, *CONVOLUTIONAL neural networks, *GENE regulatory networks

Abstract

The development and progression of cancer arise due to the accumulation of mutations in driver genes. Correctly identifying the driver genes that lead to cancer development can significantly assist the drug design, cancer diagnosis and treatment. Most computer methods detect cancer drivers based on gene–gene networks by assuming that driver genes tend to work together, form protein complexes and enrich pathways. However, they ignore that microribonucleic acid (RNAs; miRNAs) regulate the expressions of their targeted genes and are related to human diseases. In this work, we propose a graph convolution network (GCN) approach called GM-GCN to identify the cancer driver genes based on a gene–miRNA network. First, we constructed a gene–miRNA network, where the nodes are miRNAs and their targeted genes. The edges connecting miRNA and genes indicate the regulatory relationship between miRNAs and genes. We prepared initial attributes for miRNA and genes according to their biological properties and used a GCN model to learn the gene feature representations in the network by aggregating the features of their neighboring miRNA nodes. And then, the learned features were passed through a 1D convolution module for feature dimensionality change. We employed the learned and original gene features to optimize model parameters. Finally, the gene features learned from the network and the initial input gene features were fed into a logistic regression model to predict whether a gene is a driver gene. We applied our model and state-of-the-art methods to predict cancer drivers for pan-cancer and individual cancer types. Experimental results show that our model performs well in terms of the area under the receiver operating characteristic curve and the area under the precision-recall curve compared to state-of-the-art methods that work on gene networks. The GM-GCN is freely available via https://github.com/weiba/GM-GCN. [ABSTRACT FROM AUTHOR]

Published

2023

14. Mechanistic insights into the interactions between cancer drivers and the tumour immune microenvironment.

Author

Misetic, Hrvoje, Keddar, Mohamed Reda, Jeannon, Jean-Pierre, and Ciccarelli, Francesca D.

Subjects

*TUMOR microenvironment, *HEAD & neck cancer, *PROGRAMMED cell death 1 receptors

Abstract

Background: The crosstalk between cancer and the tumour immune microenvironment (TIME) has attracted significant interest in the latest years because of its impact on cancer evolution and response to treatment. Despite this, cancer-specific tumour-TIME interactions and their mechanistic insights are still poorly understood. Methods: Here, we compute the significant interactions occurring between cancer-specific genetic drivers and five anti- and pro-tumour TIME features in 32 cancer types using Lasso regularised ordinal regression. Focusing on head and neck squamous cancer (HNSC), we rebuild the functional networks linking specific TIME driver alterations to the TIME state they associate with. Results: The 477 TIME drivers that we identify are multifunctional genes whose alterations are selected early in cancer evolution and recur across and within cancer types. Tumour suppressors and oncogenes have an opposite effect on the TIME and the overall anti-tumour TIME driver burden is predictive of response to immunotherapy. TIME driver alterations predict the immune profiles of HNSC molecular subtypes, and perturbations in keratinization, apoptosis and interferon signalling underpin specific driver-TIME interactions. Conclusions: Overall, our study delivers a comprehensive resource of TIME drivers, gives mechanistic insights into their immune-regulatory role, and provides an additional framework for patient prioritisation to immunotherapy. The full list of TIME drivers and associated properties are available at http://www.network-cancer-genes.org. [ABSTRACT FROM AUTHOR]

Published

2023

15. Identifying cancer driver genes based on multi-view heterogeneous graph convolutional network and self-attention mechanism

Author

Wei Peng, Rong Wu, Wei Dai, and Ning Yu

Subjects

Cancer driver genes, Multi-view heterogeneous network embedding, Heterogeneous graph convolutional neural networks, Feature fusion, Network integration, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background Correctly identifying the driver genes that promote cell growth can significantly assist drug design, cancer diagnosis and treatment. The recent large-scale cancer genomics projects have revealed multi-omics data from thousands of cancer patients, which requires to design effective models to unlock the hidden knowledge within the valuable data and discover cancer drivers contributing to tumorigenesis. Results In this work, we propose a graph convolution network-based method called MRNGCN that integrates multiple gene relationship networks to identify cancer driver genes. First, we constructed three gene relationship networks, including the gene–gene, gene–outlying gene and gene–miRNA networks. Then, genes learnt feature presentations from the three networks through three sharing-parameter heterogeneous graph convolution network (HGCN) models with the self-attention mechanism. After that, these gene features pass a convolution layer to generate fused features. Finally, we utilized the fused features and the original feature to optimize the model by minimizing the node and link prediction losses. Meanwhile, we combined the fused features, the original features and the three features learned from every network through a logistic regression model to predict cancer driver genes. Conclusions We applied the MRNGCN to predict pan-cancer and cancer type-specific driver genes. Experimental results show that our model performs well in terms of the area under the ROC curve (AUC) and the area under the precision–recall curve (AUPRC) compared to state-of-the-art methods. Ablation experimental results show that our model successfully improved the cancer driver identification by integrating multiple gene relationship networks.

Published

2023

16. A novel heterophilic graph diffusion convolutional network for identifying cancer driver genes.

Author

Zhang, Tong, Zhang, Shao-Wu, Xie, Ming-Yu, and Li, Yan

Subjects

*CANCER genes, *GENE regulatory networks, *MACHINE learning, *BOOSTING algorithms, *GENES

Abstract

Identifying cancer driver genes plays a curial role in the development of precision oncology and cancer therapeutics. Although a plethora of methods have been developed to tackle this problem, the complex cancer mechanisms and intricate interactions between genes still make the identification of cancer driver genes challenging. In this work, we propose a novel machine learning method of heterophilic graph diffusion convolutional networks (called HGDCs) to boost cancer-driver gene identification. Specifically, HGDC first introduces graph diffusion to generate an auxiliary network for capturing the structurally similar nodes in a biomolecular network. Then, HGDC designs an improved message aggregation and propagation scheme to adapt to the heterophilic setting of biomolecular networks, alleviating the problem of driver gene features being smoothed by its neighboring dissimilar genes. Finally, HGDC uses a layer-wise attention classifier to predict the probability of one gene being a cancer driver gene. In the comparison experiments with other existing state-of-the-art methods, our HGDC achieves outstanding performance in identifying cancer driver genes. The experimental results demonstrate that HGDC not only effectively identifies well-known driver genes on different networks but also novel candidate cancer genes. Moreover, HGDC can effectively prioritize cancer driver genes for individual patients. Particularly, HGDC can identify patient-specific additional driver genes, which work together with the well-known driver genes to cooperatively promote tumorigenesis. [ABSTRACT FROM AUTHOR]

Published

2023

17. DriverRWH: discovering cancer driver genes by random walk on a gene mutation hypergraph

Author

Chenye Wang, Junhan Shi, Jiansheng Cai, Yusen Zhang, Xiaoqi Zheng, and Naiqian Zhang

Subjects

Cancer driver genes, Somatic mutation, Gene network, Hypergraph model, Random walk, Candidate gene prioritization, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background Recent advances in next-generation sequencing technologies have helped investigators generate massive amounts of cancer genomic data. A critical challenge in cancer genomics is identification of a few cancer driver genes whose mutations cause tumor growth. However, the majority of existing computational approaches underuse the co-occurrence mutation information of the individuals, which are deemed to be important in tumorigenesis and tumor progression, resulting in high rate of false positive. Results To make full use of co-mutation information, we present a random walk algorithm referred to as DriverRWH on a weighted gene mutation hypergraph model, using somatic mutation data and molecular interaction network data to prioritize candidate driver genes. Applied to tumor samples of different cancer types from The Cancer Genome Atlas, DriverRWH shows significantly better performance than state-of-art prioritization methods in terms of the area under the curve scores and the cumulative number of known driver genes recovered in top-ranked candidate genes. Besides, DriverRWH discovers several potential drivers, which are enriched in cancer-related pathways. DriverRWH recovers approximately 50% known driver genes in the top 30 ranked candidate genes for more than half of the cancer types. In addition, DriverRWH is also highly robust to perturbations in the mutation data and gene functional network data. Conclusion DriverRWH is effective among various cancer types in prioritizes cancer driver genes and provides considerable improvement over other tools with a better balance of precision and sensitivity. It can be a useful tool for detecting potential driver genes and facilitate targeted cancer therapies.

Published

2022

18. Identifying cancer driver genes based on multi-view heterogeneous graph convolutional network and self-attention mechanism.

Author

Peng, Wei, Wu, Rong, Dai, Wei, and Yu, Ning

Subjects

*CANCER genes, *GENE regulatory networks, *GENOMICS, *DRUG design, *RECEIVER operating characteristic curves, *LOGISTIC regression analysis

Abstract

Background: Correctly identifying the driver genes that promote cell growth can significantly assist drug design, cancer diagnosis and treatment. The recent large-scale cancer genomics projects have revealed multi-omics data from thousands of cancer patients, which requires to design effective models to unlock the hidden knowledge within the valuable data and discover cancer drivers contributing to tumorigenesis. Results: In this work, we propose a graph convolution network-based method called MRNGCN that integrates multiple gene relationship networks to identify cancer driver genes. First, we constructed three gene relationship networks, including the gene–gene, gene–outlying gene and gene–miRNA networks. Then, genes learnt feature presentations from the three networks through three sharing-parameter heterogeneous graph convolution network (HGCN) models with the self-attention mechanism. After that, these gene features pass a convolution layer to generate fused features. Finally, we utilized the fused features and the original feature to optimize the model by minimizing the node and link prediction losses. Meanwhile, we combined the fused features, the original features and the three features learned from every network through a logistic regression model to predict cancer driver genes. Conclusions: We applied the MRNGCN to predict pan-cancer and cancer type-specific driver genes. Experimental results show that our model performs well in terms of the area under the ROC curve (AUC) and the area under the precision–recall curve (AUPRC) compared to state-of-the-art methods. Ablation experimental results show that our model successfully improved the cancer driver identification by integrating multiple gene relationship networks. [ABSTRACT FROM AUTHOR]

Published

2023

19. Introduction to Cancer

Author

Carlberg, Carsten, Velleuer, Eunike, Carlberg, Carsten, and Velleuer, Eunike

Published

2021

20. gcMECM: graph clustering of mutual exclusivity of cancer mutations

Author

Ying Hu, Chunhua Yan, Qingrong Chen, and Daoud Meerzaman

Subjects

Cancer driver genes, Mutually exclusive mutations, Network analysis, R package, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background Next-generation sequencing platforms allow us to sequence millions of small fragments of DNA simultaneously, revolutionizing cancer research. Sequence analysis has revealed that cancer driver genes operate across multiple intricate pathways and networks with mutations often occurring in a mutually exclusive pattern. Currently, low-frequency mutations are understudied as cancer-relevant genes, especially in the context of networks. Results Here we describe a tool, gcMECM, that enables us to visualize the functionality of mutually exclusive genes in the subnetworks derived from mutation associations, gene–gene interactions, and graph clustering. These subnetworks have revealed crucial biological components in the canonical pathway, especially those mutated at low frequency. Examining the subnetwork, and not just the impact of a single gene, significantly increases the statistical power of clinical analysis and enables us to build models to better predict how and why cancer develops. Conclusions gcMECM uses a computationally efficient and scalable algorithm to identify subnetworks in a canonical pathway with mutually exclusive mutation patterns and distinct biological functions.

Published

2021

21. 结直肠癌的关键癌症驱动基因筛选及其生物学功能分析.

Author

王锦淼, 王颖, 周博昊, 王雷, and 穆伟斌

Abstract

Objective To explore the key cancer driver genes (CDGs) of colorectal carcinoma (CRC) and to investi‐ gate their biological functions. Methods CRC genomic data were obtained from the Cancer Genome Atlas database, and CRC gene expression data were obtained from the International Tumor Genome Collaboration database. The CRC gene mutation matrix was constructed by using the CRC mutant gene data, and the CRC mutant gene expression matrix was con‐ structed by using the mutant gene expression data. The protein-protein interaction (PPI) network of CRC gene was ob‐ tained from the STRING database, and the CRC gene mutation matrix, CRC mutant gene expression matrix and PPI data were integrated by python software to construct a weighted network of CRC high-dimensional mutant genes. The maxi‐ mum mutation impact score of the gene was measured, the CRC driver gene was obtained, and the key CDGs of CRC were screened by CGC database. The STRING online analysis tool was used to perform gene ontology analysis and Kyoto gene and genome database signal path enrichment analysis on key CDGs of CRC. Results Twenty-two key CDGs of CRC were screened out, namely ATM, TTN, PCDHGB3, LRP1B, PCDHA6, PIK3CA, SYNE1, PCDHGB2, KMT2C, BRAF, BM‐ PR1A, PCDHGA8, PCDHGA5, FAT4, PCDHA8, APC, PCDHGA7, PCDHA10, PCDHA9, and lar functions of key CDGs of CRC mainly focused on calcium ion binding, cation binding, metal ion binding, etc. Biologi‐ cal processes mainly focused on homologous cell adhesion through plasma membrane adhesion molecules, cell-cell adhe‐ sion through plasma membrane adhesion molecules, and cell adhesion, etc. Cell composition was mainly concentrated in the plasma membrane, the components of the plasma membrane, membranes, etc. The signaling pathways of key CDGs of CRC were mainly concentrated in colorectal cancer, FoxO signaling pathway, and signaling pathways that regulated stem cell pluripotency. Conclusions The key CDGs of CRC mainly include ATM, TTN, PCDHGB3, etc. Their biological functions mainly focus on calcium ion binding, homologous cell adhesion of plasma membrane adhesion molecules, and plasma membrane. They mainly play a role through colorectal cancer, FoxO signaling pathway, regulation of stem cell plu‐ ripotency, and other signaling pathways. [ABSTRACT FROM AUTHOR]

Published

2022

22. RNA splicing junction landscape reveals abundant tumor-specific transcripts in human cancer.

Author

Li Q, Li Z, Chen B, Zhao J, Yu H, Hu J, Lai H, Zhang H, Li Y, Meng Z, Hu Z, and Huang S

Abstract

RNA splicing is a critical process governing gene expression and transcriptomic diversity. Despite its importance, a detailed examination of transcript variation at the splicing junction level remains scarce. Here, we perform a thorough analysis of RNA splicing junctions in 34,775 samples across multiple sample types. We identified 29,051 tumor-specific transcripts (TSTs) in pan-cancer, with a majority of these TSTs being unannotated. Our findings show that TSTs are positively correlated with tumor stemness and linked to unfavorable outcomes in cancer patients. Additionally, TSTs display mutual exclusivity with somatic mutations and are overrepresented in transposable-element-derived transcripts possessing oncogenic functions. Importantly, TSTs can generate putative neoantigens for immunotherapy. Moreover, TSTs can be detected in blood extracellular vesicles from cancer patients. Our results shed light on the intricacies of RNA splicing and offer promising avenues for cancer diagnosis and therapy., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2024

23. A heterogeneous graph transformer framework for accurate cancer driver gene prediction and downstream analysis.

Author

Xiong S, Zhang J, Luo H, Zhang Y, and Xiao Q

Abstract

Accurately predicting cancer driver genes remains a formidable challenge amidst the burgeoning volume and intricacy of cancer genomic data. In this investigation, we propose HGTDG, an innovative heterogeneous graph transformer framework tailored for precisely predicting cancer driver genes and exploring downstream tasks. A heterogeneous graph construction module is central to the framework, which assembles a gene-protein heterogeneous network leveraging the Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways and protein-protein interactions sourced from the STRING (search tool for recurring instances of neighboring genes) database. Moreover, our framework introduces a pioneering heterogeneous graph transformer module, harnessing multi-head attention mechanisms for nuanced node embedding. This transformative module proficiently captures distinct representations for both nodes and edges, thereby enriching the model's predictive capacity. Subsequently, the generated node embeddings are seamlessly integrated into a classification module, facilitating the discrimination between driver and non-driver genes. Our experimental findings evince the superiority of HGTDG over existing methodologies, as evidenced by the enhanced performance metrics, including the area under the receiver operating characteristic curves (AUROC) and the area under the precision-recall curves (AUPRC). Furthermore, the downstream analysis utilizing the newly identified cancer driver genes underscores the efficacy and versatility of our proposed framework., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

24. Methylation-directed regulatory networks determine enhancing and silencing of mutation disease driver genes and explain inter-patient expression variation

Author

Edrei, Yifat, Levy, Revital, Kaye, Daniel, Marom, Anat, Radlwimmer, Bernhard, and Hellman, Asaf

Published

2023

25. The adaptive evolution of cancer driver genes

Author

Gu, Langyu, Xia, Canwei, Yang, Shiyu, and Yang, Guofen

Published

2023

26. Comprehensive analysis of the cancer driver genes in breast cancer demonstrates their roles in cancer prognosis and tumor microenvironment

Author

Xiao-wei Du, Gao Li, Juan Liu, Chun-yan Zhang, Qiong Liu, Hao Wang, and Ting-song Chen

Subjects

Cancer driver genes, Prognostic signature, Breast cancer, Tumor microenvironment, TCGA, Surgery, RD1-811, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Background Breast cancer is the most common malignancy in women. Cancer driver gene-mediated alterations in the tumor microenvironment are critical factors affecting the biological behavior of breast cancer. The purpose of this study was to identify the expression characteristics and prognostic value of cancer driver genes in breast cancer. Methods The Cancer Genome Atlas (TCGA) and Gene Expression Omnibus (GEO) datasets are used as the training and test sets. Classified according to cancer and paracancerous tissues, we identified differentially expressed cancer driver genes. We further screened prognosis-associated genes, and candidate genes were submitted for the construction of a risk signature. Functional enrichment analysis and transcriptional regulatory networks were performed to search for possible mechanisms by which cancer driver genes affect breast cancer prognosis. Results We identified more than 200 differentially expressed driver genes and 27 prognosis-related genes. High-risk group patients had a lower survival rate compared to the low-risk group (P

Published

2021

27. DriverRWH: discovering cancer driver genes by random walk on a gene mutation hypergraph.

Author

Wang, Chenye, Shi, Junhan, Cai, Jiansheng, Zhang, Yusen, Zheng, Xiaoqi, and Zhang, Naiqian

Subjects

*CANCER genes, *RANDOM walks, *GENETIC mutation, *GENE regulatory networks, *SOMATIC mutation, *NUCLEOTIDE sequencing, *GENOMICS, *FALSE positive error

Abstract

Background: Recent advances in next-generation sequencing technologies have helped investigators generate massive amounts of cancer genomic data. A critical challenge in cancer genomics is identification of a few cancer driver genes whose mutations cause tumor growth. However, the majority of existing computational approaches underuse the co-occurrence mutation information of the individuals, which are deemed to be important in tumorigenesis and tumor progression, resulting in high rate of false positive. Results: To make full use of co-mutation information, we present a random walk algorithm referred to as DriverRWH on a weighted gene mutation hypergraph model, using somatic mutation data and molecular interaction network data to prioritize candidate driver genes. Applied to tumor samples of different cancer types from The Cancer Genome Atlas, DriverRWH shows significantly better performance than state-of-art prioritization methods in terms of the area under the curve scores and the cumulative number of known driver genes recovered in top-ranked candidate genes. Besides, DriverRWH discovers several potential drivers, which are enriched in cancer-related pathways. DriverRWH recovers approximately 50% known driver genes in the top 30 ranked candidate genes for more than half of the cancer types. In addition, DriverRWH is also highly robust to perturbations in the mutation data and gene functional network data. Conclusion: DriverRWH is effective among various cancer types in prioritizes cancer driver genes and provides considerable improvement over other tools with a better balance of precision and sensitivity. It can be a useful tool for detecting potential driver genes and facilitate targeted cancer therapies. [ABSTRACT FROM AUTHOR]

Published

2022

28. Machine learning methods for prediction of cancer driver genes: a survey paper.

Author

Andrades, Renan and Recamonde-Mendoza, Mariana

Subjects

*CANCER genes, *SOMATIC mutation, *DEEP learning, *GENETIC mutation, *MACHINE learning, *THERAPEUTICS, *DIAGNOSIS, *SCIENTIFIC community

Abstract

Identifying the genes and mutations that drive the emergence of tumors is a critical step to improving our understanding of cancer and identifying new directions for disease diagnosis and treatment. Despite the large volume of genomics data, the precise detection of driver mutations and their carrying genes, known as cancer driver genes, from the millions of possible somatic mutations remains a challenge. Computational methods play an increasingly important role in discovering genomic patterns associated with cancer drivers and developing predictive models to identify these elements. Machine learning (ML), including deep learning, has been the engine behind many of these efforts and provides excellent opportunities for tackling remaining gaps in the field. Thus, this survey aims to perform a comprehensive analysis of ML-based computational approaches to identify cancer driver mutations and genes, providing an integrated, panoramic view of the broad data and algorithmic landscape within this scientific problem. We discuss how the interactions among data types and ML algorithms have been explored in previous solutions and outline current analytical limitations that deserve further attention from the scientific community. We hope that by helping readers become more familiar with significant developments in the field brought by ML, we may inspire new researchers to address open problems and advance our knowledge towards cancer driver discovery. [ABSTRACT FROM AUTHOR]

Published

2022

29. Integrated In Silico Analyses Identify PUF60 and SF3A3 as New Spliceosome-Related Breast Cancer RNA-Binding Proteins.

Author

García-Cárdenas, Jennyfer M., Armendáriz-Castillo, Isaac, Pérez-Villa, Andy, Indacochea, Alberto, Jácome-Alvarado, Andrea, López-Cortés, Andrés, and Guerrero, Santiago

Subjects

*RNA-binding proteins, *BREAST cancer, *CANCER genes, *CANCER patients, *BREAST, *CELL physiology

Abstract

Simple Summary: Globally, breast cancer (BC) is the most common cancer in women. Although numerous studies have attempted to address this worldwide health problem, it has not yet been possible to understand cancer in its entirety, mainly because most of the investigations have been focused on traditional molecular traits of DNA. Thus, new characteristics of breast tumorigenesis must be tackled, such as RNA-binding proteins (RBPs), which are crucial regulators of important cellular processes. To identify novel breast cancer RNA-binding proteins, we integrated several bioinformatic resources derived from experimentation on BC patient samples and cell lines. Consequently, we identified five putative breast cancer RNA-binding proteins (PUF60, TFRC, KPNB1, NSF, and SF3A3) showing strong tumorigenic characteristics. Supplementary investigation of the molecular and cellular functions of these proteins identified PUF60 and SF3A3 as new spliceosome-related breast cancer RNA-binding proteins. Further experimentation should center on these five RBPs to identify their role in breast tumorigenesis and potentially discover new druggable targets. More women are diagnosed with breast cancer (BC) than any other type of cancer. Although large-scale efforts have completely redefined cancer, a cure remains unattainable. In that respect, new molecular functions of the cell should be investigated, such as post-transcriptional regulation. RNA-binding proteins (RBPs) are emerging as critical post-transcriptional modulators of tumorigenesis, but only a few have clear roles in BC. To recognize new putative breast cancer RNA-binding proteins, we performed integrated in silico analyses of all human RBPs (n = 1392) in three major cancer databases and identified five putative BC RBPs (PUF60, TFRC, KPNB1, NSF, and SF3A3), which showed robust oncogenic features related to their genomic alterations, immunohistochemical changes, high interconnectivity with cancer driver genes (CDGs), and tumor vulnerabilities. Interestingly, some of these RBPs have never been studied in BC, but their oncogenic functions have been described in other cancer types. Subsequent analyses revealed PUF60 and SF3A3 as central elements of a spliceosome-related cluster involving RBPs and CDGs. Further research should focus on the mechanisms by which these proteins could promote breast tumorigenesis, with the potential to reveal new therapeutic pathways along with novel drug-development strategies. [ABSTRACT FROM AUTHOR]

Published

2022

30. Using Drosophila Models and Tools to Understand the Mechanisms of Novel Human Cancer Driver Gene Function

Author

Villegas, Santiago Nahuel, Ferres-Marco, Dolors, Domínguez, María, Crusio, Wim E., Series Editor, Dong, Haidong, Series Editor, Lambris, John D., Series Editor, Radeke, Heinfried H., Series Editor, Rezaei, Nima, Series Editor, Xiao, Junjie, Series Editor, and Deng, Wu-Min, editor

Published

2019

31. Pan-cancer detection of driver genes at the single-patient resolution

Author

Joel Nulsen, Hrvoje Misetic, Christopher Yau, and Francesca D. Ciccarelli

Subjects

Cancer genomics, Cancer driver genes, Systems-level properties, Patient-level driver detection, Medicine, Genetics, QH426-470

Abstract

Abstract Background Identifying the complete repertoire of genes that drive cancer in individual patients is crucial for precision oncology. Most established methods identify driver genes that are recurrently altered across patient cohorts. However, mapping these genes back to patients leaves a sizeable fraction with few or no drivers, hindering our understanding of cancer mechanisms and limiting the choice of therapeutic interventions. Results We present sysSVM2, a machine learning software that integrates cancer genetic alterations with gene systems-level properties to predict drivers in individual patients. Using simulated pan-cancer data, we optimise sysSVM2 for application to any cancer type. We benchmark its performance on real cancer data and validate its applicability to a rare cancer type with few known driver genes. We show that drivers predicted by sysSVM2 have a low false-positive rate, are stable and disrupt well-known cancer-related pathways. Conclusions sysSVM2 can be used to identify driver alterations in patients lacking sufficient canonical drivers or belonging to rare cancer types for which assembling a large enough cohort is challenging, furthering the goals of precision oncology. As resources for the community, we provide the code to implement sysSVM2 and the pre-trained models in all TCGA cancer types ( https://github.com/ciccalab/sysSVM2 ).

Published

2021

32. Improving cancer driver gene identification using multi-task learning on graph convolutional network.

Author

Peng, Wei, Tang, Qi, Dai, Wei, and Chen, Tielin

Subjects

*CANCER genes, *RECEIVER operating characteristic curves, *VIRTUAL networks, *PROTEIN-protein interactions, *GENETIC mutation

Abstract

Cancer is thought to be caused by the accumulation of driver genetic mutations. Therefore, identifying cancer driver genes plays a crucial role in understanding the molecular mechanism of cancer and developing precision therapies and biomarkers. In this work, we propose a Multi-Task learning method, called MTGCN, based on the Graph Convolutional Network to identify cancer driver genes. First, we augment gene features by introducing their features on the protein-protein interaction (PPI) network. After that, the multi-task learning framework propagates and aggregates nodes and graph features from input to next layer to learn node embedding features, simultaneously optimizing the node prediction task and the link prediction task. Finally, we use a Bayesian task weight learner to balance the two tasks automatically. The outputs of MTGCN assign each gene a probability of being a cancer driver gene. Our method and the other four existing methods are applied to predict cancer drivers for pan-cancer and some single cancer types. The experimental results show that our model shows outstanding performance compared with the state-of-the-art methods in terms of the area under the Receiver Operating Characteristic (ROC) curves and the area under the precision-recall curves. The MTGCN is freely available via https://github.com/weiba/MTGCN. [ABSTRACT FROM AUTHOR]

Published

2022

33. gcMECM: graph clustering of mutual exclusivity of cancer mutations.

Author

Hu, Ying, Yan, Chunhua, Chen, Qingrong, and Meerzaman, Daoud

Subjects

*GENETIC mutation, *STATISTICAL power analysis, *CANCER genes, *SEQUENCE analysis

Abstract

Background: Next-generation sequencing platforms allow us to sequence millions of small fragments of DNA simultaneously, revolutionizing cancer research. Sequence analysis has revealed that cancer driver genes operate across multiple intricate pathways and networks with mutations often occurring in a mutually exclusive pattern. Currently, low-frequency mutations are understudied as cancer-relevant genes, especially in the context of networks. Results: Here we describe a tool, gcMECM, that enables us to visualize the functionality of mutually exclusive genes in the subnetworks derived from mutation associations, gene–gene interactions, and graph clustering. These subnetworks have revealed crucial biological components in the canonical pathway, especially those mutated at low frequency. Examining the subnetwork, and not just the impact of a single gene, significantly increases the statistical power of clinical analysis and enables us to build models to better predict how and why cancer develops. Conclusions: gcMECM uses a computationally efficient and scalable algorithm to identify subnetworks in a canonical pathway with mutually exclusive mutation patterns and distinct biological functions. [ABSTRACT FROM AUTHOR]

Published

2021

34. Comprehensive analysis of the cancer driver genes in breast cancer demonstrates their roles in cancer prognosis and tumor microenvironment.

Author

Du, Xiao-wei, Li, Gao, Liu, Juan, Zhang, Chun-yan, Liu, Qiong, Wang, Hao, and Chen, Ting-song

Subjects

*BRCA genes, *TUMOR microenvironment, *PROGNOSIS, *CANCER prognosis, *CANCER genes

Abstract

Background: Breast cancer is the most common malignancy in women. Cancer driver gene-mediated alterations in the tumor microenvironment are critical factors affecting the biological behavior of breast cancer. The purpose of this study was to identify the expression characteristics and prognostic value of cancer driver genes in breast cancer. Methods: The Cancer Genome Atlas (TCGA) and Gene Expression Omnibus (GEO) datasets are used as the training and test sets. Classified according to cancer and paracancerous tissues, we identified differentially expressed cancer driver genes. We further screened prognosis-associated genes, and candidate genes were submitted for the construction of a risk signature. Functional enrichment analysis and transcriptional regulatory networks were performed to search for possible mechanisms by which cancer driver genes affect breast cancer prognosis. Results: We identified more than 200 differentially expressed driver genes and 27 prognosis-related genes. High-risk group patients had a lower survival rate compared to the low-risk group (P<0.05), and risk signature showed high specificity and sensitivity in predicting the patient prognosis (AUC 0.790). Multivariate regression analysis suggested that risk scores can independently predict patient prognosis. Further, we found differences in PD-1 expression, immune score, and stromal score among different risk groups. Conclusion: Our study confirms the critical prognosis role of cancer driver genes in breast cancer. The cancer driver gene risk signature may provide a novel biomarker for clinical treatment strategy and survival prediction of breast cancer. [ABSTRACT FROM AUTHOR]

Published

2021

35. A systematic view of computational methods for identifying driver genes based on somatic mutation data.

Author

Kan, Yingxin, Jiang, Limin, Tang, Jijun, Guo, Yan, and Guo, Fei

Subjects

*GENETIC mutation, *SOMATIC mutation, *CANCER genes, *GENES, *MEDICAL research, *GENOMES

Abstract

Abnormal changes of driver genes are serious for human health and biomedical research. Identifying driver genes, exactly from enormous genes with mutations, promotes accurate diagnosis and treatment of cancer. A lot of works about uncovering driver genes have been developed over the past decades. By analyzing previous works, we find that computational methods are more efficient than traditional biological experiments when distinguishing driver genes from massive data. In this study, we summarize eight common computational algorithms only using somatic mutation data. We first group these methods into three categories according to mutation features they apply. Then, we conclude a general process of nominating candidate cancer driver genes. Finally, we evaluate three representative methods on 10 kinds of cancer derived from The Cancer Genome Atlas Program and five Chinese projects from the International Cancer Genome Consortium. In addition, we compare results of methods with various parameters. Evaluation is performed from four perspectives, including CGC, OG/TSG, Q-value and QQQuantile–Quantileplot. To sum up, we present algorithms using somatic mutation data in order to offer a systematic view of various mutation features and lay the foundation of methods based on integration of mutation information and other types of data. [ABSTRACT FROM AUTHOR]

Published

2021

36. Large-Scale Transcriptome Analysis Identified a Novel Cancer Driver Genes Signature for Predicting the Prognostic of Patients With Hepatocellular Carcinoma

Author

Gao Li, Xiaowei Du, Xiaoxiong Wu, Shen Wu, Yufei Zhang, Jing Xu, Hao Wang, and Tingsong Chen

Subjects

cancer driver genes, prognostic signature, hepatocellular carcinoma, TCGA, ICGC, Therapeutics. Pharmacology, RM1-950

Abstract

Background: Hepatocellular carcinoma (HCC) is a common malignant tumor with high mortality and heterogeneity. Genetic mutations caused by driver genes are important contributors to the formation of the tumor microenvironment. The purpose of this study is to discuss the expression of cancer driver genes in tumor tissues and their clinical value in predicting the prognosis of HCC.Methods: All data were sourced from The Cancer Genome Atlas (TCGA), International Cancer Genome Consortium (ICGC), and Gene Expression Omnibus (GEO) public databases. Differentially expressed and prognostic genes were screened by the expression distribution of the cancer driver genes and their relationship with survival. Candidate genes were subjected to functional enrichment and transcription factor regulatory network. We further constructed a prognostic signature and analyzed the survival outcomes and immune status between different risk groups.Results: Most cancer driver genes are specifically expressed in cancer tissues. Driver genes may influence HCC progression through processes such as transcription, cell cycle, and T-cell receptor-related pathways. Patients in different risk groups had significant survival differences (p < 0.05), and risk scores showed high predictive efficacy (AUC>0.69). Besides, risk subgroups were also associated with multiple immune functions and immune cell content.Conclusion: We confirmed the critical role of cancer driver genes in mediating HCC progression and the immune microenvironment. Risk subgroups contribute to the assessment of prognostic value in different patients and explain the heterogeneity of HCC.

Published

2021

37. Identification of novel autoantibody signatures and evaluation of a panel of autoantibodies in breast cancer.

Author

Qiu, Cuipeng, Wang, Bofei, Wang, Peng, Wang, Xiao, Ma, Yan, Dai, Liping, Shi, Jianxiang, Wang, Keyan, Sun, Guiying, Ye, Hua, and Zhang, Jianying

Abstract

Tumor‐associated autoantibodies (TAAb) could be serological tumor markers. This study aims to discover novel TAAb signatures for breast cancer (BC) detection. The protein microarray was used to identify candidate TAAb, which were further validated in 1197 sera from BC, benign breast diseases (BD), and healthy controls (HC) by enzyme‐linked immunosorbent assay. In addition, 319 preoperative and postoperative sera were evaluated. A panel was determined using four different classifiers. Twelve TAAb were identified with frequencies of 15.8%‐59.2%; their levels were significantly decreased in postoperative sera compared to those in preoperative sera (P <.05). A panel with six TAAb was developed and evaluated. The area under the curve (AUC) was 0.879 (74.3% sensitivity, 91.9% specificity) and 0.865 (69.7% sensitivity, 91.7% specificity) for distinguishing BC from HC in the training set and test set, respectively. The panel had an AUC of.884 (71.2% sensitivity, 90.5% specificity) for discriminating BC from BD. For identifying BC from all controls (HC+BD), the AUC was.916 (78.9% sensitivity, 90.2% specificity). The AUC of the panel was.920 and.934 for distinguishing stage I‐II and age < 50 BC from HC, respectively. These identified TAAb have the potential to provide a non–invasive approach to detect BC. [ABSTRACT FROM AUTHOR]

Published

2021

38. Large-Scale Transcriptome Analysis Identified a Novel Cancer Driver Genes Signature for Predicting the Prognostic of Patients With Hepatocellular Carcinoma.

Author

Li, Gao, Du, Xiaowei, Wu, Xiaoxiong, Wu, Shen, Zhang, Yufei, Xu, Jing, Wang, Hao, and Chen, Tingsong

Subjects

CANCER genes, HEPATOCELLULAR carcinoma, GENETIC mutation, PROGNOSIS, SURVIVAL rate

Abstract

Background: Hepatocellular carcinoma (HCC) is a common malignant tumor with high mortality and heterogeneity. Genetic mutations caused by driver genes are important contributors to the formation of the tumor microenvironment. The purpose of this study is to discuss the expression of cancer driver genes in tumor tissues and their clinical value in predicting the prognosis of HCC. Methods: All data were sourced from The Cancer Genome Atlas (TCGA), International Cancer Genome Consortium (ICGC), and Gene Expression Omnibus (GEO) public databases. Differentially expressed and prognostic genes were screened by the expression distribution of the cancer driver genes and their relationship with survival. Candidate genes were subjected to functional enrichment and transcription factor regulatory network. We further constructed a prognostic signature and analyzed the survival outcomes and immune status between different risk groups. Results: Most cancer driver genes are specifically expressed in cancer tissues. Driver genes may influence HCC progression through processes such as transcription, cell cycle, and T-cell receptor-related pathways. Patients in different risk groups had significant survival differences (p < 0.05), and risk scores showed high predictive efficacy (AUC>0.69). Besides, risk subgroups were also associated with multiple immune functions and immune cell content. Conclusion: We confirmed the critical role of cancer driver genes in mediating HCC progression and the immune microenvironment. Risk subgroups contribute to the assessment of prognostic value in different patients and explain the heterogeneity of HCC. [ABSTRACT FROM AUTHOR]

Published

2021

39. Germline and somatic mutation profile in Cancer patients revealed by a medium-sized pan-Cancer panel.

Author

Li, Zhaopei, Wang, Hailong, Zhang, Zhen, Meng, Xiangwen, Liu, Dujuan, and Tang, Yuanhua

Subjects

*GENETIC mutation, *SOMATIC mutation, *GERM cells, *DISEASE risk factors, *CANCER patients, *CANCER genes

Abstract

Gene mutation detection and the resulted precision-medicine therapy is transforming clinical practice. Here, we report the use of a custom-developed, medium-sized, pan-cancer probe panel for the detection of somatic and germline mutations. We used a hybridization capture-based NGS assay for targeted deep sequencing of all exons and selected introns of 181 key cancer driver genes, covering both inherited risks and somatic mutations. We performed paired-variant calling on tumor samples and their matched normal samples. We processed clinical patient samples of formalin-fixed, paraffin embedded tumors (FFPE samples) and cell-free peripheral blood (cfDNA samples). We found germline mutations of inherited cancer risk at 9%; and discovered a novel germline mutation in BRCA1. Somatic mutation rate in driver genes is at 73.1%, much higher than previously reported. On recommending precision-medicine therapeutics, we achieved 91.6% for patients with FFPE samples. • Clinical study of patients' cancer mutations. Driver gene mutations with potential precision medicine therapies. • A pan-cancer NGS panel applied to study both germline and somatic mutations. • A specific germline mutation in BRCA1 gene of Chinese origin, c.2907delT, leading to p.N969fs. • Somatic mutation rates in key driver-genes are much higher than reported in Cosmic and TCGA. • Precision-medicine recommendations for 91.6% patients with FFPE samples. [ABSTRACT FROM AUTHOR]

Published

2021

40. Identification of cancer driver genes using Sleeping Beauty transposon mutagenesis.

Author

Takeda, Haruna, Jenkins, Nancy A., and Copeland, Neal G.

Abstract

Cancer genome sequencing studies have identified driver genes for a variety of different cancers and helped to understand the genetic landscape of human cancer. It is still challenging, however, to identify cancer driver genes with confidence simply from genetic data alone. In vivo forward genetic screens using Sleeping Beauty (SB) transposon mutagenesis provides another powerful genetic tool for identifying candidate cancer driver genes in wild‐type and sensitized mouse tumors. By comparing cancer driver genes identified in human and mouse tumors, cancer driver genes can be identified with additional confidence based upon comparative oncogenomics. This review describes how SB mutagenesis works in mice and focuses on studies that have identified cancer driver genes in the mouse gastrointestinal tract. [ABSTRACT FROM AUTHOR]

Published

2021

41. TOPDRIVER: the novel identifier of cancer driver genes in Gastric cancer and Melanoma

Author

Seyed Mohammad Razavi, Farzaneh Rami, Seyede Houri Razavi, and Changiz Eslahchi

Subjects

Network-based methods, Cancer driver genes, Gastric cancer, Melanoma, Applied mathematics. Quantitative methods, T57-57.97

Abstract

Abstract Nowadays, research has found a strong relationship between genomic status and occurrence of disease. Cancer is one of the most common diseases that leads to a high annual mortality rate worldwide, and the disease’s genetic content remains challenging. Detecting driver genes of different cancers could help in early diagnosis and treatment. In this paper, we proposed TOPDRIVER, a network-based algorithm, to detect cancer driver genes in cancers. An initial network was constructed by integrating four different omic datasets: HPRD, NCBI, KEGG, and GTEx. This integration created a gene similarity profile that provided a comprehensive perspective of gene interaction in each subtype of cancer and allocated weights to the edges of the network. The vertex scores were calculated using a gene-disease association dataset (DisGeNet) and a molecular functional disease similarity. In this step, the genes network was jagged and faced with a zero-one gap problem. A diffusion kernel was implemented to smooth the vertex scores to overcome this problem. Finally, potential driver genes were extracted according to the topology of the network, genes overall biological functions, and their involvement in cancer pathways. TOPDRIVER has been applied to two subtypes of gastric cancer and one subtype of melanoma. The method could nominate a considerable number of well-known driver genes of these cancers and also introduce novel driver genes. NKX3-1, KIDINS220, and RIPK4 have introduced for gastrointestinal cancer, UBA3, UBE2M, and RRAGA for hereditary gastric cancer and CIT for invasive melanoma. Biological evidences represents TOPDRIVER’s efficiency in a subtype-specific manner.

Published

2019

42. Genomics-Guided Drawing of Molecular and Pathophysiological Components of Malignant Regulatory Signatures Reveals a Pivotal Role in Human Diseases of Stem Cell-Associated Retroviral Sequences and Functionally-Active hESC Enhancers

Author

Gennadi V. Glinsky

Subjects

malignant regulatory signatures, stem cell-associated retroviral sequences, retrotransposition, human embryogenesis, cancer survival genes, cancer driver genes, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Repetitive DNA sequences (repeats) colonized two-third of human genome and a majority of repeats comprised of transposable genetic elements (TE). Evolutionary distinct categories of TE represent nucleic acid sequences that are repeatedly copied from and pasted into chromosomes at multiple genomic locations and acquired a multitude of regulatory functions. Here, genomics-guided maps of stemness regulatory signatures were drawn to dissect the contribution of TE to clinical manifestations of malignant phenotypes of human cancers. From patients’ and physicians’ perspectives, the clinical definition of a tumor’s malignant phenotype could be restricted to the early diagnosis of sub-types of malignancies with the increased risk of existing therapy failure and high likelihood of death from cancer. It is the viewpoint from which the understanding of stemness and malignant regulatory signatures is considered in this contribution. Genomics-guided analyses of experimental and clinical observations revealed the pivotal role of human stem cell-associated retroviral sequences (SCARS) in the origin and pathophysiology of clinically-lethal malignancies. SCARS were defined as the evolutionary- and biologically-related family of genomic regulatory sequences, the principal physiological function of which is to create and maintain the stemness phenotype during human preimplantation embryogenesis. For cell differentiation to occur, SCARS expression must be silenced and SCARS activity remains repressed in most terminally-differentiated human cells which are destined to perform specialized functions in the human body. Epigenetic reprogramming, de-repression, and sustained activity of SCARS results in various differentiation-defective phenotypes. One of the most prominent tissue- and organ-specific clinical manifestations of sustained SCARS activities is diagnosed as a pathological condition defined by a consensus of morphological, molecular, and genetic examinations as the malignant growth. Here, contemporary evidence are acquired, analyzed, and reported defining both novel diagnostic tools and druggable molecular targets readily amenable for diagnosis and efficient therapeutic management of clinically-lethal malignancies. These diagnostic and therapeutic approaches are based on monitoring of high-fidelity molecular signals of continuing SCARS activities in conjunction with genomic regulatory networks of thousands’ functionally-active embryonic enhancers affecting down-stream phenotype-altering genetic loci. Collectively, reported herein observations support a model of SCARS-activation triggered singular source code facilitating the intracellular propagation and intercellular (systemic) dissemination of disease states in the human body.

Published

2021

43. Genomics-Guided Drawing of Molecular and Pathophysiological Components of Malignant Regulatory Signatures Reveals a Pivotal Role in Human Diseases of Stem Cell-Associated Retroviral Sequences and Functionally-Active hESC Enhancers.

Author

Glinsky, Gennadi V.

Subjects

TRANSPOSONS, PHYSICIANS' attitudes, PERIPROSTHETIC fractures, HUMAN phenotype, HUMAN genome, DRUG target

Abstract

Repetitive DNA sequences (repeats) colonized two-third of human genome and a majority of repeats comprised of transposable genetic elements (TE). Evolutionary distinct categories of TE represent nucleic acid sequences that are repeatedly copied from and pasted into chromosomes at multiple genomic locations and acquired a multitude of regulatory functions. Here, genomics-guided maps of stemness regulatory signatures were drawn to dissect the contribution of TE to clinical manifestations of malignant phenotypes of human cancers. From patients' and physicians' perspectives, the clinical definition of a tumor's malignant phenotype could be restricted to the early diagnosis of sub-types of malignancies with the increased risk of existing therapy failure and high likelihood of death from cancer. It is the viewpoint from which the understanding of stemness and malignant regulatory signatures is considered in this contribution. Genomics-guided analyses of experimental and clinical observations revealed the pivotal role of human stem cell-associated retroviral sequences (SCARS) in the origin and pathophysiology of clinically-lethal malignancies. SCARS were defined as the evolutionary- and biologically-related family of genomic regulatory sequences, the principal physiological function of which is to create and maintain the stemness phenotype during human preimplantation embryogenesis. For cell differentiation to occur, SCARS expression must be silenced and SCARS activity remains repressed in most terminally-differentiated human cells which are destined to perform specialized functions in the human body. Epigenetic reprogramming, de-repression, and sustained activity of SCARS results in various differentiation-defective phenotypes. One of the most prominent tissue- and organ-specific clinical manifestations of sustained SCARS activities is diagnosed as a pathological condition defined by a consensus of morphological, molecular, and genetic examinations as the malignant growth. Here, contemporary evidence are acquired, analyzed, and reported defining both novel diagnostic tools and druggable molecular targets readily amenable for diagnosis and efficient therapeutic management of clinically-lethal malignancies. These diagnostic and therapeutic approaches are based on monitoring of high-fidelity molecular signals of continuing SCARS activities in conjunction with genomic regulatory networks of thousands' functionally-active embryonic enhancers affecting down-stream phenotype-altering genetic loci. Collectively, reported herein observations support a model of SCARS-activation triggered singular source code facilitating the intracellular propagation and intercellular (systemic) dissemination of disease states in the human body. [ABSTRACT FROM AUTHOR]

Published

2021

44. Integrated In Silico Analyses Identify PUF60 and SF3A3 as New Spliceosome-Related Breast Cancer RNA-Binding Proteins

Author

Jennyfer M. García-Cárdenas, Isaac Armendáriz-Castillo, Andy Pérez-Villa, Alberto Indacochea, Andrea Jácome-Alvarado, Andrés López-Cortés, and Santiago Guerrero

Subjects

RBPs, breast cancer, cancer driver genes, in silico analysis, Biology (General), QH301-705.5

Abstract

More women are diagnosed with breast cancer (BC) than any other type of cancer. Although large-scale efforts have completely redefined cancer, a cure remains unattainable. In that respect, new molecular functions of the cell should be investigated, such as post-transcriptional regulation. RNA-binding proteins (RBPs) are emerging as critical post-transcriptional modulators of tumorigenesis, but only a few have clear roles in BC. To recognize new putative breast cancer RNA-binding proteins, we performed integrated in silico analyses of all human RBPs (n = 1392) in three major cancer databases and identified five putative BC RBPs (PUF60, TFRC, KPNB1, NSF, and SF3A3), which showed robust oncogenic features related to their genomic alterations, immunohistochemical changes, high interconnectivity with cancer driver genes (CDGs), and tumor vulnerabilities. Interestingly, some of these RBPs have never been studied in BC, but their oncogenic functions have been described in other cancer types. Subsequent analyses revealed PUF60 and SF3A3 as central elements of a spliceosome-related cluster involving RBPs and CDGs. Further research should focus on the mechanisms by which these proteins could promote breast tumorigenesis, with the potential to reveal new therapeutic pathways along with novel drug-development strategies.

Published

2022

45. Pan-cancer detection of driver genes at the single-patient resolution.

Author

Nulsen, Joel, Misetic, Hrvoje, Yau, Christopher, and Ciccarelli, Francesca D.

Subjects

*GENES, *GENE mapping, *CANCER genes, *MACHINE learning, *T cell receptors, *CANCER patients

Abstract

Background: Identifying the complete repertoire of genes that drive cancer in individual patients is crucial for precision oncology. Most established methods identify driver genes that are recurrently altered across patient cohorts. However, mapping these genes back to patients leaves a sizeable fraction with few or no drivers, hindering our understanding of cancer mechanisms and limiting the choice of therapeutic interventions. Results: We present sysSVM2, a machine learning software that integrates cancer genetic alterations with gene systems-level properties to predict drivers in individual patients. Using simulated pan-cancer data, we optimise sysSVM2 for application to any cancer type. We benchmark its performance on real cancer data and validate its applicability to a rare cancer type with few known driver genes. We show that drivers predicted by sysSVM2 have a low false-positive rate, are stable and disrupt well-known cancer-related pathways. Conclusions: sysSVM2 can be used to identify driver alterations in patients lacking sufficient canonical drivers or belonging to rare cancer types for which assembling a large enough cohort is challenging, furthering the goals of precision oncology. As resources for the community, we provide the code to implement sysSVM2 and the pre-trained models in all TCGA cancer types (https://github.com/ciccalab/sysSVM2). [ABSTRACT FROM AUTHOR]

Published

2021

46. Genomic analysis of low‐grade serous ovarian carcinoma to identify key drivers and therapeutic vulnerabilities.

Author

Cheasley, Dane, Nigam, Abhimanyu, Zethoven, Magnus, Hunter, Sally, Etemadmoghadam, Dariush, Semple, Timothy, Allan, Prue, Carey, Mark S, Fernandez, Marta L, Dawson, Amy, Köbel, Martin, Huntsman, David G, Le Page, Cécile, Mes‐Masson, Anne‐Marie, Provencher, Diane, Hacker, Neville, Gao, Yunkai, Bowtell, David, deFazio, Anna, and Gorringe, Kylie L

Subjects

GENOMICS, PROGESTERONE receptors, CARCINOMA, IMMUNOHISTOCHEMISTRY, CHROMOSOMES

Abstract

Low‐grade serous ovarian carcinoma (LGSOC) is associated with a poor response to existing chemotherapy, highlighting the need to perform comprehensive genomic analysis and identify new therapeutic vulnerabilities. The data presented here represent the largest genetic study of LGSOCs to date (n = 71), analysing 127 candidate genes derived from whole exome sequencing cohorts to generate mutation and copy‐number variation data. Additionally, immunohistochemistry was performed on our LGSOC cohort assessing oestrogen receptor, progesterone receptor, TP53, and CDKN2A status. Targeted sequencing identified 47% of cases with mutations in key RAS/RAF pathway genes (KRAS, BRAF, and NRAS), as well as mutations in putative novel driver genes including USP9X (27%), MACF1 (11%), ARID1A (9%), NF2 (4%), DOT1L (6%), and ASH1L (4%). Immunohistochemistry evaluation revealed frequent oestrogen/progesterone receptor positivity (85%), along with CDKN2A protein loss (10%) and CDKN2A protein overexpression (6%), which were linked to shorter disease outcomes. Indeed, 90% of LGSOC samples harboured at least one potentially actionable alteration, which in 19/71 (27%) cases were predictive of clinical benefit from a standard treatment, either in another cancer's indication or in LGSOC specifically. In addition, we validated ubiquitin‐specific protease 9X (USP9X), which is a chromosome X‐linked substrate‐specific deubiquitinase and tumour suppressor, as a relevant therapeutic target for LGSOC. Our comprehensive genomic study highlighted that there is an addiction to a limited number of unique 'driver' aberrations that could be translated into improved therapeutic paths. © 2020 The Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2021

47. Tumor Mutation Burden Computation in Two Pan-Cancer Precision Medicine Next-Generation Sequencing Panels.

Author

Shu, Yongqian, Wu, Xiaohong, Shen, Jia, Luo, Dongdong, Li, Xiang, Wang, Hailong, and Tang, Yuanhua Tom

Subjects

*NUCLEOTIDE sequencing, *INDIVIDUALIZED medicine, *CANCER genes, *TUMORS, *LIFE sciences

Abstract

FD-180 and FD-600 are two next-generation sequencing panels developed by First Dimension Biosciences Co. for detecting mutations in cancer tissues and providing therapeutics guidance in precision medicine applications. FD-180 includes the coding exons of about 180 genes, including all the known drug target genes and some important driver genes; whereas FD-600 includes the coding exons of 578 cancer driver genes in the COSMIC database as of year 2016 when the panels are developed. Additional noncoding regions in the selected genes are included if they are reported as clinically meaningful in ClinVar. Tumor mutation burden (TMB) is a statistical index calculated from genomic sequencing for immunotherapeutic treatments, especially for PD1/PD-L1 antibodies. We used our computational algorithm on 81 patients and provided their classifications. TMB can be estimated quite accurately for the FD-180 and FD-600 panels, both for The Cancer Genome Atlas data and in clinical practice. [ABSTRACT FROM AUTHOR]

Published

2020

48. Not all cancers are created equal: Tissue specificity in cancer genes and pathways.

Author

Bianchi, Joy J., Zhao, Xin, Mays, Joseph C., and Davoli, Teresa

Subjects

*CANCER genes, *PROGRAMMED cell death 1 receptors, *GENETIC mutation, *CANCER, *TISSUES, *GENE therapy

Abstract

Tumors arise through waves of genetic alterations and clonal expansion that allow tumor cells to acquire cancer hallmarks, such as genome instability and immune evasion. Recent genomic analyses showed that the vast majority of cancer driver genes are mutated in a tissue-dependent manner, that is, are altered in some cancers but not others. Often the tumor type also affects the likelihood of therapy response. What is the origin of tissue specificity in cancer? Recent studies suggest that both cell-intrinsic and cell-extrinsic factors play a role. On one hand, cell type–specific wiring of the cell signaling network determines the outcome of cancer driver gene mutations. On the other hand, the tumor cells' exposure to tissue-specific microenvironments (e.g. immune cells) also contributes to shape the tissue specificity of driver genes and of therapy response. In the future, a more complete understanding of tissue specificity in cancer may inform methods to better predict and improve therapeutic outcomes. Cell intrinsic and extrinsic factors determine tissue specificity of cancer drivers and pathways. Different cell types in the body have different cell-intrinsic signaling networks (circuitry). In addition different tissues have different microenvionments (such as different composition of immune cells) and exposure to viruses and other environmental agents such as UV light and smoke (cell-intrinsic factors). Both cell-intrinsic and cell-extrinsic factors contribute to determine the tissue specificity in cancer driver genes and pathways. Image 1 • The vast majority of cancer driver genes are mutated in certain tumor types but not others. • Cell-intrinsic factors such as cell type-specific signaling networks define the output of cancer driver genes. • Cell-extrinsic factors such as exposure to environmental factors and immune microenvironment contribute to tissue specificity of cancer genes. • Response to cancer therapies (including immunotherapy) is often tissue specific. [ABSTRACT FROM AUTHOR]

Published

2020

49. Tumor radiogenomics in gliomas with Bayesian layered variable selection.

Author

Mohammed, Shariq, Kurtek, Sebastian, Bharath, Karthik, Rao, Arvind, and Baladandayuthapani, Veerabhadran

Subjects

*GLIOMAS, *PROBABILITY density function, *CANCER genes, *MAGNETIC resonance imaging, *VECTOR data

Abstract

We propose a statistical framework to analyze radiological magnetic resonance imaging (MRI) and genomic data to identify the underlying radiogenomic associations in lower grade gliomas (LGG). We devise a novel imaging phenotype by dividing the tumor region into concentric spherical layers that mimics the tumor evolution process. MRI data within each layer is represented by voxel–intensity-based probability density functions which capture the complete information about tumor heterogeneity. Under a Riemannian-geometric framework these densities are mapped to a vector of principal component scores which act as imaging phenotypes. Subsequently, we build Bayesian variable selection models for each layer with the imaging phenotypes as the response and the genomic markers as predictors. Our novel hierarchical prior formulation incorporates the interior-to-exterior structure of the layers, and the correlation between the genomic markers. We employ a computationally-efficient Expectation–Maximization-based strategy for estimation. Simulation studies demonstrate the superior performance of our approach compared to other approaches. With a focus on the cancer driver genes in LGG, we discuss some biologically relevant findings. Genes implicated with survival and oncogenesis are identified as being associated with the spherical layers, which could potentially serve as early-stage diagnostic markers for disease monitoring, prior to routine invasive approaches. We provide a R package that can be used to deploy our framework to identify radiogenomic associations. • We provide a novel Bayesian framework for imaging-genomic associations in gliomas. • We create novel tumor heterogeneity phenotypes from concentric spherical tumor layers. • Our prior integrates inner-to-outer tumor layer structure and genomic marker correlation. • We use an efficient Expectation-Maximization-based estimation and offer an R package. • Genes tied to survival and oncogenesis are linked to tumor layers, offering potential diagnostic markers. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

50. Differential analysis between somatic mutation and germline variation profiles reveals cancer-related genes

Author

Pawel F. Przytycki and Mona Singh

Subjects

Cancer, Whole-exome sequencing, Somatic mutations, Germline variation, Cancer driver genes, Medicine, Genetics, QH426-470

Abstract

Abstract A major aim of cancer genomics is to pinpoint which somatically mutated genes are involved in tumor initiation and progression. We introduce a new framework for uncovering cancer genes, differential mutation analysis, which compares the mutational profiles of genes across cancer genomes with their natural germline variation across healthy individuals. We present DiffMut, a fast and simple approach for differential mutational analysis, and demonstrate that it is more effective in discovering cancer genes than considerably more sophisticated approaches. We conclude that germline variation across healthy human genomes provides a powerful means for characterizing somatic mutation frequency and identifying cancer driver genes. DiffMut is available at https://github.com/Singh-Lab/Differential-Mutation-Analysis.

Published

2017