A global genetic interaction network maps a wiring diagram of cellular function
Autor: | Yizhao Tan, Natasha Pascoe, Elena Kuzmin, Carles Pons, Scott W. Simpkins, Maximilian Billmann, Matej Usaj, Jolanda van Leeuwen, Olga G. Troyanskaya, Zhen Yuan Lin, Erin B. Styles, Sara Sharifpoor, Bryan Joseph San Luis, Noël Malod-Dognin, Julia Hanchard, Claire Moore, Brenda J. Andrews, Igor Stagljar, Vuk Janjić, Anastasia Baryshnikova, Michael Costanzo, Susan D. Lee, Anne-Claude Gingras, Yiqun Chen, Chad L. Myers, Charles Boone, Sondra Bahr, Harsha Garadi Suresh, Benjamin VanderSluis, Jeff S. Piotrowski, Guihong Tan, Natasa Przulj, Jamie Snider, Emira Shuteriqi, Michael Boutros, Raamesh Deshpande, Adam P. Rosebrock, Christoph F. Kurat, Lars M. Steinmetz, Tharan Srikumar, Brian Raught, Wen Wang, Hiroki Okada, Justin Nelson, Sheena C. Li, Hongwei Zhu, Yoshikazu Ohya, Tian Xia, Zhijian Li, Nydia Van Dyk, Elizabeth N. Koch, Vicent Pelechano, Amy A. Caudy, Mojca Mattiazzi Usaj |
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Rok vydání: | 2016 |
Předmět: |
2. Zero hunger
0301 basic medicine Genetics Genes Essential Saccharomyces cerevisiae Proteins Multidisciplinary biology Genes Fungal Saccharomyces cerevisiae Gene regulatory network Epistasis and functional genomics Epistasis Genetic Genetic Pleiotropy Computational biology biology.organism_classification Phenotype Genome Article 03 medical and health sciences 030104 developmental biology Genetic variation Genetic redundancy Gene Regulatory Networks Gene |
Zdroj: | Scopus-Elsevier |
ISSN: | 1095-9203 0036-8075 |
Popis: | INTRODUCTION Genetic interactions occur when mutations in two or more genes combine to generate an unexpected phenotype. An extreme negative or synthetic lethal genetic interaction occurs when two mutations, neither lethal individually, combine to cause cell death. Conversely, positive genetic interactions occur when two mutations produce a phenotype that is less severe than expected. Genetic interactions identify functional relationships between genes and can be harnessed for biological discovery and therapeutic target identification. They may also explain a considerable component of the undiscovered genetics associated with human diseases. Here, we describe construction and analysis of a comprehensive genetic interaction network for a eukaryotic cell. RATIONALE Genome sequencing projects are providing an unprecedented view of genetic variation. However, our ability to interpret genetic information to predict inherited phenotypes remains limited, in large part due to the extensive buffering of genomes, making most individual eukaryotic genes dispensable for life. To explore the extent to which genetic interactions reveal cellular function and contribute to complex phenotypes, and to discover the general principles of genetic networks, we used automated yeast genetics to construct a global genetic interaction network. RESULTS We tested most of the ~6000 genes in the yeast Saccharomyces cerevisiae for all possible pairwise genetic interactions, identifying nearly 1 million interactions, including ~550,000 negative and ~350,000 positive interactions, spanning ~90% of all yeast genes. Essential genes were network hubs, displaying five times as many interactions as nonessential genes. The set of genetic interactions or the genetic interaction profile for a gene provides a quantitative measure of function, and a global network based on genetic interaction profile similarity revealed a hierarchy of modules reflecting the functional architecture of a cell. Negative interactions connected functionally related genes, mapped core bioprocesses, and identified pleiotropic genes, whereas positive interactions often mapped general regulatory connections associated with defects in cell cycle progression or cellular proteostasis. Importantly, the global network illustrates how coherent sets of negative or positive genetic interactions connect protein complex and pathways to map a functional wiring diagram of the cell. CONCLUSION A global genetic interaction network highlights the functional organization of a cell and provides a resource for predicting gene and pathway function. This network emphasizes the prevalence of genetic interactions and their potential to compound phenotypes associated with single mutations. Negative genetic interactions tend to connect functionally related genes and thus may be predicted using alternative functional information. Although less functionally informative, positive interactions may provide insights into general mechanisms of genetic suppression or resiliency. We anticipate that the ordered topology of the global genetic network, in which genetic interactions connect coherently within and between protein complexes and pathways, may be exploited to decipher genotype-to-phenotype relationships. |
Databáze: | OpenAIRE |
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