Browsing by Subject "Protein aggregation"
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Item Evaluation of protein aggregation and organismal fitness(2011-05) Stovall, Gwendolyn Motz; Ellington, Andrew D.; Marcotte, Edward; Whiteley, Marvin; Wilke, Claus O.; Willets, KatherineIn quiescent yeast, the widespread reorganization of cytosolic proteins into punctate has been observed (Narayanaswamy et al. 2009). We seek to better understand and describe this reorganization, which we hypothesize to be a protein aggregation phenomenon. To test this hypothesis, we examined mutant proteins (Ade4p protein variants) in yeast with predicted non-native aggregation propensities and measured their punctate formation kinetics. Monitoring punctate formation kinetics involved the validation of an automated quantification technique using an Amnis ImageStream imaging flow cytometer. The automated punctate counts were strongly correlated with the manual punctate counts, with usual R² values of 0.99 or better, but evaluated 50-fold more cells per run. Fitness evaluations of the mutant yeast in the form of growth curves and batch competition experiments revealed the slowed growth of the Ade4-1286 strain and the functional inequality to the wild type strain of the Ade4-mtoin2034, Ade4-mtoin2105, and Ade4-2800 strains in competition experiments, especially when the mutants were forced to generate their own adenine. Subsequent structural analysis of the mutant proteins revealed destabilizing mutations for 4 of the 6 mutant proteins with 2 of the mutations classified as significantly destabilizing ([delta][delta]G >2 kcal/mol). We concluded that the reduction in protein fitness was likely due to the destabilizing effects of the mutations. Evaluation of the punctate formation kinetics revealed little difference between strains in the rate of punctate formation. Further examination revealed the wild type Ade4p and all of the mutants (with the exception of the Ade4-1286 mutant) were predicted to have similar aggregation propensities according to a secondary aggregation predicting algorithm (Zyggregator, Pawar et al. 2005). Additionally, solvent accessibility calculations estimate ~3-19% of the side chain surface area to be solvent accessible, which indicates proximity of mutations to the protein surface. However, mutating buried amino acids likely would have generated a greater disturbance (Matthews 1993, Tokuriki et al. 2007). We concluded that the mutations, although destabilizing, altered the aggregation propensity very little. Deletion of chaperone proteins (Hsp82p, Hsc82p, and Ssa1p) revealed no difference in the Ade4-GFP punctate formation kinetics, although a slight kinetic difference was detected in the chaperone (Hsp82p) knockout, Gln1-GFP strain and the wild type strain. While further workup is necessary in the chaperone knockout, Gln1-GFP work, the initial results are promising and suggest the involvement of protein folding machinery in punctate formation.Item On generic protein aggregation and its aging and evolutionary implications(2011-05) Tsechansky, Mark; Marcotte, Edward M.; Ellington, Andrew; Georgiou, George; Iyer, Vishwanath; Wilke, ClausMany neuro-degenerative and metabolic diseases like Parkinson’s and Alzheimer’s are attributed to the effect of mis-folded and aggregated state of proteins in cells. This suggests that the phenomenon of in vivo protein aggregation may be relatively common, perhaps more than currently appreciated. In this study, we aimed to decipher the cause behind an intriguing and potentially related phenomenon observed in yeast cells - a widespread reorganization of hundreds of cytosolic proteins into punctate foci under starvation conditions. The key question that emerges is whether this phenomenon represents organization of proteins into functional assemblies or catastrophic aggregation. This thesis supports the aggregation hypothesis and provides evidence of its role in shaping the dynamics of cellular proteomes. We have been able to demonstrate that the proteins forming foci share a high propensity to aggregate and that these foci may represent sites of homogenous protein aggregation, structures which are typically associated with chaperones. A link between the formation of foci to the yeast aging process has also been established. With evidence correlating protein aggregation propensities to the cellular energy state, we have extended the current "living on the edge" hypothesis (which demonstrates an inverse correlation between protein expression levels and their aggregation propensities). For a specific case of the "purinosome", which is inferred to be a functional enzyme complex responsible for purine biosynthesis, we have shown that the observations may be explained alternatively as a generic protein aggregation phenomenon. This study highlights a systems approach to studying cellular proteins, which can corroborate or provide an alternative explanation to inferences drawn from traditional reductionistic analysis.Item Systemic protein aggregation in stress and aging restructures cytoplasmic architecture(2012-12) O'Connell, Jeremy Daniel 1982-; Marcotte, Edward M.A common maxim of protein biochemistry states, “structure is function.” This is generally just as true for an individual polypeptide chains as for multi-protein complexes. The advent of yeast tagged-protein libraries has allowed systematic screening of a protein’s local interaction partners as well as a roughly mapping its cellular location. Recently our group and others discovered hundreds proteins forming new structures in stationary phase yeast cells using the yeast GFP-tag library. That equates to well over a quarter of normally diffuse cytoplasmic proteins assembled into discrete structures that appear as foci or fibers, all of unknown function. This study provides evidence that many of these foci are formed by protein aggregation- that contrary the maxim, structure can be dysfunction. Furthermore, this study uses yeast to demonstrate the generality of cytoplasmic protein aggregation in response to a variety of stresses, provides evidence that increasing aggregation of particular cytoplasmic proteins correlates with aging even across organisms, and proposes a theoretical framework for how cellular energy levels affect protein aggregation propensity.