Interpreting pathways to discover cancer driver genes with Moonlight

Colaprico, Antonio; Olsen, Catharina; Bailey, Matthew H.; Odom, Gabriel J.; Terkelsen, Thilde; Silva, Tiago C.; Olsen, André Vidas; Cantini, Laura; Zinovyev, Andreï; Barillot, Emmanuel; Noushmehr, Houtan; Bertoli, Gloria; Castiglioni, Isabella; Cava, Claudia; Bontempi, Gianluca; Chen, Xi Steven; Papaleo, Elena

doi:10.1038/s41467-019-13803-0

Cited by 73 publications

(75 citation statements)

References 101 publications

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“…This can only be explained as a result of other less common driver genes complementing the pathway disruption of the unique combination of driver genes that are disrupted in each tumor, and we speculate that many of these are relatively tissue-specific in terms of their sensitivity to mutation. Consistent with our observations, Colaprico et al (2020) showed how tissue-and cancer-specific driver genes and druggable targets of pathway moduli can be discovered by machine learning on integrated multi-omics datasets. Marrying these approaches in future work will greatly enhance our understanding of tumor biology.…”

Section: Tissue Specific Manifestation Of Pathway-centric Disruptionssupporting

confidence: 89%

“…One of the challenges in the field remains that beyond a couple hundred common driver genes and mutations, there may be thousands of moderate effect genes that occur at such low frequency-given tissue diversity-and low sample numbers that they are impossible to detect using positive selection theory. Some groups have attempted to address this challenge by applying machine learning to cancer data sets to discover groups of functionally related genes as they interact with larger pathways and networks (Kim and Kim 2018;Mourikis et al 2019;Colaprico et al 2020). These studies have proven very effective at highlighting fundamental disease phenotypes at the pathway level across cancers with different origins at the cellular and tissue level.…”

Section: Introductionmentioning

confidence: 99%

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A molecular taxonomy of tumors independent of tissue-of-origin

Nguyen

Coetzee

Lakeland

et al. 2020

Preprint

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Cancer is a complex disease involving disrupted cellular metabolism, basic biochemical processes, and the microenvironment. However, despite some generally agreed upon unifying principles (Hanahan and Weinberg 2000, 2011), molecular signatures remain largely indistinguishable from tissue-of-origin, presenting a major barrier for precision health and individualized medicine. To address this challenge, we reduce mutation data to disruptions in a select set of pathways relevant to basic cell biology, from DNA replication to cellular communication. Using dimensionality reduction techniques, we assign tumor samples into ten clusters distinct from tissue-of-origin and largely free of bias from mutational burden or clinical stage. We show that the clusters vary in prognosis by modeling relative risk of death by cancer type and cluster. We identify cluster-specific mutations in different tissues, demonstrating that tissue-specific signatures contribute to common cellular phenotypes. Moreover, germline risk genes involved in replication fidelity and genome stability are equally distributed among clusters, contrary to the expectation that such genes are avatars of molecular subtype. We investigate metastatic and non-metastatic pathways, and show that most differences are cluster-specific. Some metastatic pathways from one cluster are cluster-specific pathways from non-metastatic tumors of another cluster, suggesting phenotypic convergence. Taken as a whole, our observations suggest that common driver genes combine with tissue-specific disruptions in tumor-promoting pathways to produce a limited number of distinct molecular phenotypes. Thus, we present a coherent view of global tumor biology, and explain how common cellular dysfunction might arise from tissue-specific mutations.

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Section: Tissue Specific Manifestation Of Pathway-centric Disruptionssupporting

confidence: 89%

Section: Introductionmentioning

confidence: 99%

A molecular taxonomy of tumors independent of tissue-of-origin

Nguyen

Coetzee

Lakeland

et al. 2020

Preprint

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“…The opposing effects exhibited by Ankrd2 in OS cells and in HNSCC [ 27 ] hint at a role of Ankrd2 as a “double-faced” cancer gene, a well-documented peculiarity of certain genes exhibiting oncogenic or tumor-suppressor behavior depending on the biological context [ 28 , 29 ]. Interestingly, a homolog of Ankrd2, Ankrd23 [ 1 ] was recently identified as a potential dual-role cancer driver gene acting as an oncogene in renal clear-cell carcinoma, and a tumor suppressor in bladder urothelial carcinoma [ 30 ].…”

Section: Discussionmentioning

confidence: 99%

Ectopic Expression of Ankrd2 Affects Proliferation, Motility and Clonogenic Potential of Human Osteosarcoma Cells

Piazzi

Kojić

Capanni

et al. 2021

Cancers

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Ankrd2 is a protein known for being mainly expressed in muscle fibers, where it participates in the mechanical stress response. Since both myocytes and osteoblasts are mesenchymal-derived cells, we were interested in examining the role of Ankrd2 in the progression of osteosarcoma which features a mechano-stress component. Although having been identified in many tumor-derived cell lines and -tissues, no study has yet described nor hypothesized any involvement for this protein in osteosarcoma tumorigenesis. In this paper, we report that Ankrd2 is expressed in cell lines obtained from human osteosarcoma and demonstrate a contribution by this protein in the pathogenesis of this insidious disease. Ankrd2 involvement in osteosarcoma development was evaluated in clones of Saos2, U2OS, HOS and MG63 cells stably expressing Ankrd2, through the investigation of hallmark processes of cancer cells. Interestingly, we found that exogenous expression of Ankrd2 influenced cellular growth, migration and clonogenicity in a cell line-dependent manner, whereas it was able to improve the formation of 3D spheroids in three out of four cellular models and enhanced matrix metalloproteinase (MMP) activity in all tested cell lines. Conversely, downregulation of Ankrd2 expression remarkably reduced proliferation and clonogenic potential of parental cells. As a whole, our data present Ankrd2 as a novel player in osteosarcoma development, opening up new therapeutic perspectives.

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“…Proper reproducible protocols and solid tools accessible to the community are needed in the PSN field to reach the standards of recent open-access and collaborative initiatives for reproducibility and transparency in molecular modeling and simulations (PLUMED Consortium, 2019;Smith et al, 2020;Senapathi et al, 2020). These initiatives are also common in other areas of bioinformatics, such as cancer genomics (Siu et al, 2016;Colaprico et al, 2020Colaprico et al, , 2015Mounir et al, 2019;Terkelsen et al, 2020). In 2014, we developed PyInteraph (Tiberti et al, 2014)for the study of protein structure networks (PSNs) from structural ensembles, especially suited to work on trajectories from atomistic simulations such as Molecular Dynamics (MD).…”

Section: Introductionmentioning

confidence: 99%

PyInteraph2 and PyInKnife2 to analyze networks in protein structural ensembles

Sora

Tiberti

Robbani

et al. 2020

Preprint

Self Cite

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MotivationProtein dynamic is essential for cellular functions. Due to the complex nature of non-covalent interactions and their long-range effects, the analysis of protein conformations using network theory can be enlightening. Protein Structure Networks (PSNs) rely on different philosophies, and the currently available tools suffer from limitations in terms of input formats, supported network models, and version control. Another issue is the precise definition of cutoffs for the network calculations and the assessment of the stability of the parameters, which ultimately affect the outcome of the analyses.ResultsWe provide two open-source software packages, i.e., PyInteraph2 and PyInKnife2, to implement and analyze PSNs in a harmonized, reproducible, and documented manner. PyInteraph2 interfaces with multiple formats for protein ensembles and calculates a diverse range of network models with the possibility to integrate them into a macro-network and perform further downstream graph analyses. PyInKnife2 is a standalone package that supports the network models implemented in PyInteraph2. It employs a jackknife resampling approach to estimate the convergence of network properties and streamline the selection of distance cutoffs. Several functionalities are based on MDAnalysis and NetworkX, including parallelization, and are available for Python 3.7. PyInteraph2 underwent a massive restructuring in terms of setup, installation, and test support compared to the original PyInteraph software.ConclusionsWe foresee that the modular structure of the code and the version control system of GitHub will promote the transition to a community-driven effort, boost reproducibility, and establish harmonized protocols in the PSN field. As developers, we will guarantee the introduction of new functionalities, assistance, training of new contributors, and maintenance of the package.AvailabilityThe packages are available at https://github.com/ELELAB/pyinteraph2 and https://github.com/ELELAB/PyInKnife2 with guides provided within the packages.

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Interpreting pathways to discover cancer driver genes with Moonlight

Cited by 73 publications

References 101 publications

A molecular taxonomy of tumors independent of tissue-of-origin

A molecular taxonomy of tumors independent of tissue-of-origin

Ectopic Expression of Ankrd2 Affects Proliferation, Motility and Clonogenic Potential of Human Osteosarcoma Cells

PyInteraph2 and PyInKnife2 to analyze networks in protein structural ensembles

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