1. Master regulators of genetic interaction networks mediating statin drug response in Saccharomyces cerevisiae vary with genetic background
- Author
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Coorey, Namal, Busby, Bede, Niktab, Eliatan, Roberts, Christina, Sheridan, Jeffrey, Senanayake, Dinindu, Munkacsi, Andrew, and Atkinson, Paul
- Subjects
Whole genome sequencing ,biology ,Saccharomyces cerevisiae ,Unfolded protein response ,Protein folding ,Computational biology ,biology.organism_classification ,Gene ,Function (biology) ,Secretory pathway ,GINS - Abstract
Determination of genetic interaction networks (GINs) surrounding drug targets identifies buffering genes and provides molecular insight into drug response in individuals. Here we used backcross methodology to createSaccharomyces cerevisiaedeletion libraries in three genetic backgrounds resistant to statins, which are additional to the statin-sensitive S288C deletion library that has provided much of what is known about GINs in eukaryotes. Whole genome sequencing and linkage group analysis confirmed the genomic authenticity of the new deletion libraries. Statin response was probed by drug-gene interactions with atorvastatin and cerivastatin treatments, as well as gene-gene interactions with the statin targetHMG1andHMG2genes or the sterol homeostaticARV1gene. The 20 GINs generated from these interactions were not conserved by function or topology across the four genetic backgrounds. Centrality measures and hierarchical agglomerative clustering identified master regulators that if removed collapsed the networks. Community structure distinguished a characteristic early secretory pathway pattern of gene usage in each genetic background. ER stress in statin-resistant backgrounds was buffered by protein folding genes, which was confirmed by reduced activation of the unfolded protein response in statin-resistant backgrounds relative to the statin-sensitive S288C background. These network analyses of new gene deletion libraries provide insight into the complexity of GINs underlying individual drug response.
- Published
- 2018