Browsing by Author "McCracken, Neil Andrew"

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    Characterizing the Unfolded Protein Response by Changes in Protein Thermal Stability
    (2023-09) McCracken, Neil Andrew; Mosley, Amber; Wek, Ron; Evans-Molina, Carmella; Georgiadis, Millie; Quinney, Sara
    The Unfolded Protein Response (UPR) protects eukaryotic cells from the threat of excessive protein flux into the Endoplasmic Reticulum (ER). UPR sentries PERK, Ire1 and ATF6 detect unfolded protein in the ER and alert the cell of the condition. Downstream pathways increase translation of select responders while simultaneously decreasing the global protein load in order that toxic protein aggregates do not form in the cell. While this warning system has been characterized over several decades through extensive reporting of UPR impact on transcript and protein abundance, little is known about the biophysical changes that occur to proteins as part of the UPR in the context of the cellular environment. An understanding of how the UPR affects the folding, stability and protein oligomerization is vital for describing subtle but important changes that occur and contribute to maladaptive physiology in diseases including diabetes, cancer, and neurodegeneration. I propose that deficiencies in characterizing the UPR can be overcome by using thermal shifts assays (TSA) that quantify changes in protein stability post stimuli. Findings described herein show the utility of the biophysical thermal shift assay in characterizing the UPR. Thermal shift assays (TSA) measure susceptibility of proteins to denature upon heat treatment and consequently detect changes in protein structure, modification, and interactions in the cellular environment. Previously unobserved protein relationships related to the UPR were detected using TSA. These workflows were improved through more strategic upstream sampling and downstream data analysis through creation of the publicly available InflectSSP program. Observed UPR phenomena during N-linked glycosylation inhibition and UPR induction include protein degradation, changes in stability of N-linked glycosylation enzymes, and transcriptional targets canonical to the UPR. Stability changes in proteins downstream of PERK were also observed in experiments where PERK genetic ablation was combined with UPR induction. Finally, the thermal shift assay was used to develop a “signature” for the UPR that holistically describes the ER stress response. Results described in this dissertation provide an improved perspective of the UPR along with an approach that can be used to identify novel targets for therapeutic intervention of the UPR.
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    The impact of the termination override mutation on the activity of SSU72
    (2016-12-19) McCracken, Neil Andrew; Mosley, Amber; Wek, Ronald; Goebl, Mark
    Ssu72, an RNA Pol II CTD phosphatase that is conserved across eukaryotes, has been reported to have a wide array of genetic and physical associations with transcription factors and complexes in RNA transcription. Catalytic mutants of Ssu72 are lethal across many eukaryotes, and mutations to non-catalytic sites in SSU72 phosphatase have been shown to lower function. One spontaneous mutation of the SSU72 gene in Saccharomyces cerevisiae (A to C nucleotide mutation resulting in an L84F mutation in the coded protein) was shown to have transcription termination deficiency (termination override or TOV). This SSU72 mutation was suggested by Loya et al. to cause a lowering of the phosphatase activity of the protein and consequently affect proper termination. In research reported herein, an investigation was completed through in-vitro and ex-vivo approaches with the goal of understanding the impact of the SSU72 TOV mutation on the observed phenotype in S. cerevisiae. It can be concluded from work presented in this report that the SSU72 TOV mutation does not cause a decrease in in-vitro phosphatase activity as compared to wild type. Evidence presented even suggests an increase in phosphatase activity as compared to wild type Ssu72. One model for the observed responses in transcription termination is that the phenylalanine substitution in Ssu72 leads to cooperative interactions with proline residues in the CTD. It is proposed that the corresponding increase in Ssu72 phosphatase activity limits RNA Pol II CTD association with termination factors, such as Nrd1, thus causing deficient transcription termination.