Development of genome-wide reagents has allowed systematic analysis of gene function. The experimental accessibility of budding yeast makes it a test-bed for technology development and application of new functional genomic tools and resources that pave the way for comparable efforts in higher eukaryotes. In this Thesis, I describe a two-color GFP-RFP reporter system I developed to assess the consequences of genetic perturbations on a promoter of interest. The dual-reporter system is compatible with the synthetic genetic array methodology, an approach that enables marked genetic elements to be introduced into arrays of yeast mutants via an automated procedure. I use this approach to probe cell cycle-regulation of histone gene transcription by introducing an HTA1 promoter-GFP reporter gene construct into an ordered array of ~4500 yeast deletion mutants. I scored defects in reporter gene expression for each mutant, generating a quantitative analysis of histone promoter activity. The results of my screen motivated a number of follow-up experiments, including chromatin immunoprecipitation, transcript profiling and genome-wide analysis of nucleosome positions, which revealed a previously unappreciated pathway that specifies regions of repressed chromatin in a cell cycle-sensitive manner. A novel aspect of this pathway is that it involves histone chaperones and a chromatin boundary element. Specifically, we discovered that the histone chaperone Rtt106 works with two other chaperones, Asf1 and the HIR complex, to create a repressive chromatin structure at histone promoters which is bound by the protein Yta7. It was clear from previous work that Asf1 and HIR repress transcription at HTA1 and that HIR localizes to and functions through a specific element in histone promoters. However, there was no previous data demonstrating a role for Rtt106 in cell cycle-dependent gene transcription. In sum, I describe a new genomic screen that I used to discover a novel pathway regulating cell cycle-dependent transcription. While I examined histone gene expression as proof-of-principle, my screening system could be applied to virtually any pathway for which a suitable reporter can be devised. I anticipate this methodology will enable yeast researchers to collect quantitative data on hundreds of gene expression pathways.
Identifer | oai:union.ndltd.org:TORONTO/oai:tspace.library.utoronto.ca:1807/19044 |
Date | 18 February 2010 |
Creators | Kainth, Parminder |
Contributors | Andrews, Brenda |
Source Sets | University of Toronto |
Language | en_ca |
Detected Language | English |
Type | Thesis |
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