Academic literature on the topic 'Saccharomyces cerevisiae; RNA, Messenger; Academic Dissertations'

mRNA decay is an important cellular process that regulates gene expression and is tightly linked to the process of translation. Many studies have illustrated the link between mRNA turnover and translation, indicating that mRNA decay is a cytoplasmic event. In order to investigate further the link between translation and turnover, seven mutants in translation initiation factors were analyzed for their effect on mRNA decay, including: i) three mutant alleles of the PRT1 gene (prt1-1, prt1-26 and prt1-63), which encodes a subunit of elF3; ii) sui1-1, which encodes the smallest subunit of elF3; iii) sui2-1, which encodes elF2; iv) GCN2c, which encodes the elF2 kinase, and v) cdc33-42, a mutant in the cap binding protein elF4E. The results demonstrate that the prt1-1 mutation results in stabilization of nonsense containing mRNAs without affecting the half-lives of most other mRNAs, a phenotype similar to a upf1Δ strain. To identify substrates for the nonsense-mediated mRNA decay pathway, mRNA differential display analysis was performed using RNA prepared from prt1-1, PRT1, upf1Δ and UPF1 strains. Although the abundance of the HHF2 mRNA is increased in the mutant strains the half-life is unaffected. However, the mRNA half-life of the transcriptional regulator SPT10 was increased in the mutant strains indicating the SPT10 transcript is a substrate for the nonsense-mediated mRNA decay pathway. Further characterization of the SPT10 transcript showed that it is a substrate for this pathway because the initiator AUG is present in a poor translation initiation context which results in aberrant translation initiation. Finally, several other mRNAs, predicted to be substrates for the pathway based on the leaky scanning model, were subsequently shown to decay through this pathway. These transcripts included the REV7, STE50, and UBP7 mRNAs. The results from these experiments lay the groundwork for addressing the potential regulatory role of the nonsense-mediated mRNA decay pathway.

Thesis (Ph. D.)--University of California, San Diego, 2009.
Title from first page of PDF file (viewed Jan. 19. 2010). Available via ProQuest Digital Dissertations. Vita. Includes bibliographical references (p. 48-53).

Nonsense-mediated mRNA decay (NMD) specifically targets mRNAs with premature translation termination codons for rapid degradation. NMD is a highly conserved translation-dependent mRNA decay pathway, and its core Upf factors are thought to be recruited to prematurely terminating mRNP complexes, possibly through the release factors that orchestrate translation termination. Upf1 is the central regulator of NMD and recent studies have challenged the notion that this protein is specifically targeted to aberrant, nonsense-containing mRNAs. Rather, it has been proposed that Upf1 binds to most mRNAs in a translation-independent manner. In this thesis, I investigated the nature of Upf1 association with its substrates in the yeast Saccharomyces cerevisiae. Using biochemical and genetic approaches, the basis for Upf1 interaction with ribosomes was evaluated to determine the specificity of Upf1 association with ribosomes, and the extent to which such binding is dependent on prior association of Upf1’s interacting partners. I discovered that Upf1 is specifically associated with Rps26 of the 40S ribosomal subunit, and that this association requires the N-terminal Upf1 CH domain. In addition, using selective ribosome profiling, I investigated when during translation Upf1 associates with ribosomes and showed that Upf1 binding was not limited to polyribosomes that were engaged in translating NMD substrate mRNAs. Rather, Upf1 associated with translating ribosomes on most mRNAs, binding preferentially as ribosomes approached the 3’ ends of open reading frames. Collectively, these studies provide new mechanistic insights into NMD and the dynamics of Upf1 during translation.

Nonsense-mediated mRNA decay (NMD) specifically targets mRNAs with premature translation termination codons for rapid degradation. NMD is a highly conserved translation-dependent mRNA decay pathway, and its core Upf factors are thought to be recruited to prematurely terminating mRNP complexes, possibly through the release factors that orchestrate translation termination. Upf1 is the central regulator of NMD and recent studies have challenged the notion that this protein is specifically targeted to aberrant, nonsense-containing mRNAs. Rather, it has been proposed that Upf1 binds to most mRNAs in a translation-independent manner. In this thesis, I investigated the nature of Upf1 association with its substrates in the yeast Saccharomyces cerevisiae. Using biochemical and genetic approaches, the basis for Upf1 interaction with ribosomes was evaluated to determine the specificity of Upf1 association with ribosomes, and the extent to which such binding is dependent on prior association of Upf1’s interacting partners. I discovered that Upf1 is specifically associated with Rps26 of the 40S ribosomal subunit, and that this association requires the N-terminal Upf1 CH domain. In addition, using selective ribosome profiling, I investigated when during translation Upf1 associates with ribosomes and showed that Upf1 binding was not limited to polyribosomes that were engaged in translating NMD substrate mRNAs. Rather, Upf1 associated with translating ribosomes on most mRNAs, binding preferentially as ribosomes approached the 3’ ends of open reading frames. Collectively, these studies provide new mechanistic insights into NMD and the dynamics of Upf1 during translation.

Eukaryotic genomes can produce two types of transcripts: protein-coding and non-coding RNAs (ncRNAs). Cryptic ncRNA transcripts are bona fide RNA Pol II products that originate from bidirectional promoters, yet they are degraded by the RNA exosome. Such pervasive transcription is prevalent across eukaryotes, yet its regulation and function is poorly understood. We hypothesized that chromatin architecture at cryptic promoters may regulate ncRNA transcription. Nucleosomes that flank promoters are highly enriched in two histone marks: H3-K56Ac and the variant H2A.Z, which make nucleosomes highly dynamic. These histone modifications are present at a majority of promoters and their stereotypic pattern is conserved from yeast to mammals, suggesting their evolutionary importance. Although required for inducing a handful of genes, their contribution to steady-state transcription has remained elusive. In this work, we set out to understand if dynamic nucleosomes regulate cryptic transcription and how this is coordinated with the RNA exosome. Remarkably, we find that H3-K56Ac promotes RNA polymerase II occupancy at a large number of protein coding and noncoding loci, yet neither histone mark has a significant impact on steady state mRNA levels in budding yeast. Instead, broad effects of H3-K56Ac or H2A.Z on levels of both coding and ncRNAs are only revealed in the absence of the nuclear RNA exosome. We show that H2A.Z functions with H3-K56Ac in chromosome folding, facilitating formation of Chromosomal Interaction Domains (CIDs). Our study suggests that H2A.Z and H3-K56Ac work in concert with the RNA exosome to control mRNA and ncRNA levels, perhaps in part by regulating higher order chromatin structures. Together, these chromatin factors achieve a balance of RNA exosome activity (yin; negative) and Pol II (yang; positive) to maintain transcriptional homeostasis.