Global ETD Search

171	SIRT1 Regulation of the Heat Shock Response in an HSF1-Dependent Manner and the Impact of Caloric Restriction Raynes, Rachel Rene 01 January 2013 (has links) The heat shock response (HSR) is the cell's molecular reaction to protein damaging stress and is critical in the management of denatured proteins. Activation of HSF1, the master transcriptional regulator of the HSR, results in the induction of molecular chaperones called heat shock proteins (HSPs). Transcription of hsp genes is promoted by the hyperphosphorylation of HSF1, while the attenuation of the HSR is regulated by a dual mechanism involving negative feedback inhibition from HSPs and acetylation at a critical lysine residue within the DNA binding domain of HSF1, which results in a loss of affinity for DNA. SIRT1 is a NAD+-dependent histone deacetylase that has been reported to deacetylate HSF1, thus promoting stress-induced HSF1 DNA binding ability and increasing HSP expression (Westerheide, Anckar et al. 2009). While an abundance of research is aimed to investigate SIRT1 substrate regulation, the mechanism in which SIRT1 itself is regulated is less understood (Haigis and Sinclair 2010). Positive and negative modulators of SIRT1 include AROS and DBC1, respectively, and have yet to be investigated in relation to SIRT1-dependent regulation of the HSR. In addition, metabolic stress such as caloric restriction has been shown to modulate SIRT1 activity in yeast (Rahat, Maoz et al. 2011), but the effect of caloric restriction on the HSR is unknown. Using cell-based assays, we have investigated how the HSR may be controlled by factors influencing SIRT1 activity. We found that heat shock results in an increase in the cellular NAD+/NADH ratio and an increase in recruitment of SIRT1 to the hsp70 promoter. Furthermore, we found that the SIRT1 modulators, AROS and DBC1, impact hsp70 transcription, HSF1 acetylation status, and HSF1 recruitment to the hsp70 promoter. The nematode Caenorhabditis elegans is a useful model organism for testing the relationship between the HSR and metabolism, as these animals can easily be calorically-restricted via bacterial limitation and possess the mammalian SIRT1 homolog, Sir2.1. Using C. elegans, we demonstrate that caloric restriction and heat shock have a synergistic effect on the HSR in a sir2.1-dependent manner. We show that caloric restriction increases the ability of heat shock to promote thermotolerance and fitness in wild-type animals and to preserve movement in a polyglutamine toxicity neurodegenerative disease model and that this effect is dependent on sir2.1. These studies provide insight into SIRT1-dependent regulation of the HSR and the impact of metabolism on this response. We highlight the SIRT1 modulators AROS and DBC1 as two new targets available for therapeutic regulation of the HSR and add caloric restriction as another HSR activator that can synergize with heat shock. Caloric Restriction C. elegans Cytoprotection DBC1 Heat Shock Proteins Hormesis Cell Biology Genetics Molecular Biology
172	Heat shock cognate 70(HSC70)and gata transcription factor as the regulators of vitellogenesis in the shrimp Metapenaeus ensis Chung, Pui-kei., 鍾沛基. January 2005 (has links) published_or_final_version / abstract / Zoology / Master / Master of Philosophy Heat shock proteins. Transcription factors. Genetic regulation. Gene expression. Oogenesis. Shrimps - Genetics.
173	Functional interaction between PROX1, ERR[alpha] and PGC-1[alpha] in the control of energy metabolism Charest-Marcotte, Alexis, 1984- January 2009 (has links) Nuclear receptors play crucial roles in the transcriptional regulation of many biological processes such as development and cellular differentiation. ERRalpha is known, along with coactivator PGC-1alpha, to playa central role in the control of energy metabolism in cardiac and skeletal muscle. They activate the expression of many genes involved in mitochondrial oxidative metabolism. Here we identified PROX1, a factor that was previously shown to broadly influence metabolism, as a regulator of this pathway. Indeed, PROX1 interacts in vitro and in vivo with both ERRalpha and PGC-1alpha. To provide more insight on the hepatic functions of ERRalpha and PROX1, we performed ChIP-on-chip using mouse liver, identifying a large number of ERRalpha and PROX1 genomic targets and reinforcing their role in energy metabolism. Over 40% of the target genes were found to be common to both factors and we observed that PROX1 could be recruited to ERRalpha binding sites and act as a negative regulator o fthe ERRalpha/POC-1alpha pathway. Liver -- metabolism. Homeodomain Proteins -- metabolism. Receptors, Estrogen -- metabolism. Heat-Shock Proteins -- metabolism.
174	Investigating the Role of Hsp27 in Drosophila : Genetic and Phospho - mutant Analysis Furbee, Emily Christine 01 August 2014 (has links) HSP27, the Drosophila homolog of mammalian HspB1, is a nuclear sHsp that is both stress induced and developmentally regulated with a conserved cyto-protective function. It is multiply phosphorylated in vivo through an unconfirmed mechanism at unidentified residues. The effect of phosphorylation on its localization, oligomerization, and function is also not well understood. Here we report a genetic investigation into the role of Hsp27 in Drosophila development, and a preliminary investigation into the effect of phosphorylation on HSP27 localization and function in Drosophila S2 cells. Through a proteomic screen, a pro-apoptotic role for Hsp27 in embryonic developmentally regulated programmed cell death was suggested and supported by RNAi experiments, but not replicated using Hsp27null mutant stocks. These stocks were complicated by the intriguing appearance of multiple background mutations. Specific developmental defects in transgenic lines overexpressing phospho-mutant isoforms were then investigated. These too were subject to multiple independent incidences of background genetic mutation, which we believe may be related to Hsp27 mis-expression. We also studied the endogenous expression and localization pattern of HSP27 in stressed and unstressed Drosophila S2 cells. We found evidence that wild-type protein localization is influenced by stress. Finally, we took a first step toward understanding how phosphorylation might regulate HSP27 localization by examining the effect of targeted mutations of serine residues (S58, S71, and S75) on the localization pattern of exogenous HSP27. By characterizing the expression of endogenous and overexpressed HSP27 in Drosophila cells, we provide a foundation for future investigation into the regulated localization and function of HSP27 that can be extended to address the regulatory mechanisms that govern the protective capacities and oligomeric properties of phosphorylated HSP27 in Drosophila. small heat shock proteins drosophilia programmed cell death hsp27 phosphorylation of hsp27
175	EVALUATION OF HEAT SHOCK PROTEIN 70A (HSP70A) IN <i>CHLAMYDOMONAS REINHARDTII</i> Short, Sarah Nicole 01 January 2012 (has links) Algae are being considered as a possible tool for carbon dioxide mitigation because they uptake carbon dioxide during photosynthesis. Using flue gas from a coal-fired power plant as a carbon source would allow the algae to remove CO2 from the flue gas before it is emitted into the atmosphere. Because algae do not grow well at the high temperature, low pH conditions presented by flue gas, the traditional approach has been to alter the flue gas to suit the needs of the algae; however, this work aimed to genetically modify the algae Chlamydomonas reinhardtii to grow better at less than optimal conditions. Heat shock proteins are important in the stress responses of many organisms; therefore, this work modified C. reinhardtii to overexpress HSP70A in order to increase the tolerance of C. reinhardtii to higher temperature and lower pH. Experiments yielded mixed results, but there were several instances in which the modified algae appeared to have gained an increased tolerance to decreased pH based on the chlorophyll concentration of the algae. Chlamydomonas reinhardtii heat shock proteins carbon dioxide mitigation temperature pH Agriculture Plant Biology Plant Sciences
176	Evolution of Reproduction and Stress Tolerance in Brachionid Rotifers Smith, Hilary April 08 1900 (has links) Stress can be a driving force for new evolutionary changes leading to local adaptation, or may be responded to with pre-existing, ancestral tolerance mechanisms. Using brachionid rotifers (microzooplankton) as a study system, I demonstrate roles of both conserved physiological mechanisms (heat shock protein induction) and rapid evolution of traits in response to ecologically relevant stressors such as temperature and hydroperiod. Rapid evolution of higher levels of sex and dormancy in cultures mimicking temporary waters represents an eco-evolutionary dynamic, with trait evolution feeding back into effects on ecology (i.e., reduced population growth). I also reveal that prolonged culture in a benign laboratory environment leads to evolution of increased lifespan and fecundity, perhaps due to reduction of extrinsic mortality factors. Potential mechanisms (e.g., hormonal signals) are suggested that may control evolvability of facets of the stress response. Due to prior studies suggesting a role of progesterone signaling in rotifer sex and dormancy, the membrane associated progesterone receptor is assayed as a candidate gene that could show positive selection indicating rapid divergence. Despite some sequence variation that may contribute to functional differences among species, results indicate this hormone receptor is under purifying selection. Detailed analyses of multiple stress responses and their evolution as performed here will be imperative to understanding current patterns of local adaptation and trait-environment correlations. Such research also is key to predicting persistence of species upon introduction to novel habitats and exposure to new stressors (e.g., warming due to climate change). Perhaps one of the most intriguing results of this dissertation is the rapid, adaptive change in levels of sex and dormancy in a metazoan through new mutations or re-arrangements of the genetic material. This suggests species may be able to rapidly evolve tolerance of new stressors, even if standing genetic variation does not currently encompass the suite of alleles necessary for survival. Cyclical parthenogenesis Ephemeral Diapause Senescence Cost of sex Sex frequency Heat shock proteins (HSP)
177	Examination of Cadmium-Induced Heat Shock Protein Gene Expression in Xenopus laevis A6 Kidney Epithelial Cells Woolfson, Jessica Pearl January 2008 (has links) Cadmium is a highly toxic chemical and has been classified by the International Agency for Research on Cancer as a human carcinogen. Cadmium is abundant in the environment, at specific work places, and in food and water. Toxicological responses to cadmium exposure include respiratory diseases, neurological disorders and kidney damage. The present study examined the effects of cadmium on heat shock protein (HSP) accumulation in Xenopus laevis A6 kidney epithelial cells. HSPs are molecular chaperones involved in protein folding and translocation. In response to environmental stress these proteins bind to unfolded protein and inhibit their aggregation. Stress-inducible hsp gene transcription is mediated by the heat shock promoter element (HSE), which interacts with heat shock transcription factor (HSF). In the present study, hsp30 and hsp70 mRNA and protein were induced by heat shock, as determined by northern and western blot analysis. Exposure of A6 cells to cadmium chloride also induced the expression of hsp genes. For example, northern and western blot analysis revealed that exposure of A6 cells to cadmium chloride induced the accumulation of hsp30 and hsp70 mRNA and their respective proteins. Western blot analysis also revealed that A6 cells recovering from a cadmium chloride treatment retained relatively high levels of HSP30 and HSP70 protein accumulation over 24 h after the removal of the stress. Treatments combining a mild heat shock and cadmium chloride resulted in a synergistic increase in hsp30 and hsp70 gene expression at mRNA and protein levels. Further experiments in which two stressors were combined revealed that synergistic effects occurred with varying cadmium concentrations and different temperatures. Immunocytochemistry and confocal microscopy were used to confirm the results attained from western blot analysis. Further, this technique allowed the determination of intracellular localization of HSP30 in A6 cells and the examination of cellular morphology and cytoskeletal structure during cadmium chloride treatments. A 2 h heat shock at 33??C resulted in the accumulation of HSP30 in the cytoplasm, whereas a 2 h heat shock at 35??C resulted in some HSP30 accumulation in the peripheral region of the nucleus. This is in contrast to cells treated with cadmium chloride, where HSP30 accumulation was restricted to the cytoplasm. A 14 h 50 ??M cadmium chloride treatment resulted in the accumulation of HSP30 in approximately 10% of cells. The proportion of cells displaying HSP30 accumulation increased to 80% and 95% in cells treated with 100 ??M and 200 ??M, respectively. HSP30 accumulation frequently occurred in large granular structures. High concentrations of cadmium chloride resulted in cell membrane ruffling at areas of cell-cell contact, as well as actin disorganization. This study characterized the pattern of hsp gene expression, accumulation and localization under various cadmium chloride conditions. These results suggest that hsp30 and hsp70 gene expression can be used as potential biomolecular markers for cadmium exposure. molecular biology Xenopus laevis cadmium kidney heat shock proteins gene expression
178	Analysis of heat shock protein 30 gene expression and function in Xenopus laevis A6 kidney epithelial cells Khan, Saad 28 August 2014 (has links) Heat shock proteins (HSPs) are molecular chaperones that assist in protein synthesis, folding and degradation and prevent stress-induced protein aggregation. The present study examined the pattern of accumulation of HSP30 and HSP70 in cells recovering from heat shock as well as the effect of proteasome inhibition on cytoplasmic/nuclear and endoplasmic reticulum (ER) molecular chaperone accumulation, large multimeric HSP30 complexes, stress granule and aggresome formation in Xenopus laevis A6 kidney epithelial cells. Initial immunoblot analysis revealed the presence of elevated levels of HSP30 after 72 h of recovery. However, the relative levels of HSP70 declined to near control levels after 24 h. The relative levels of both hsp30 and hsp70 mRNA were reduced to low levels after 24 h of recovery from heat shock. Pretreatment of cells with cycloheximide, a translational inhibitor, produced a rapid decline in HSP70 but not HSP30. The cycloheximide-associated decline of HSP70 was blocked by the proteasomal inhibitor, MG132, but had little effect on the relative level of HSP30. Also, treatment of cells with the phosphorylation inhibitor, SB203580, in addition to cycloheximide treatment enhanced the stability of HSP30 compared to cycloheximide alone. Immunocytochemical studies detected the presence of HSP30 accumulation in a granular pattern in the cytoplasm of recovering cells and its association with aggresome-like structures, which was enhanced in the presence of SB203580. To verify if proteasome inhibition in A6 cells induced the formation of similar HSP30 granules, immunoblot and immunocytochemical analyses were performed. MG132, celastrol and withaferin A enhanced ubiquitinated proteins, inhibited chymotrypsin-like activity of the proteasome and induced the accumulation of cytoplasmic/nuclear HSPs, HSP30 and HSP70 as well as ER chaperones, BiP and GRP94 and heme oxygenase-1. Northern blot experiments determined that proteasome inhibitors induced an accumulation in hsp30, hsp70 and bip mRNA but not eIF1α. The final part of this study demonstrated that treatment of A6 cells with proteasome inhibitors or sodium arsenite or cadmium chloride induced HSP30 multimeric complex formation primarily in the cytoplasm. Moreover, these stressors also induced the formation of RNA stress granules, pre-stalled translational complexes, which were detected via TIA1 and polyA binding protein (PABP), which are known stress granule markers. These stress granules, however, did not co-localize with large HSP30 multimeric complexes. In comparison, proteasome inhibition or treatment with sodium arsenite or cadmium chloride also induced the formation of aggresome-like structures, which are proteinaceous inclusion bodies formed as a result of an abundance of aggregated protein. Aggresome formation was identified by monitoring the presence of vimentin and γ-tubulin, both of which are cytoskeletal proteins and serve as markers of aggresome detection. Aggresome formation, which was also verified using the ProteoStat assay, co-localized with large HSP30 multimeric complexes. Co-immunoprecipitation experiments revealed that HSP30 associated with γ-tubulin and β-actin in cells treated with proteasome inhibitors or sodium arsenite or cadmium chloride suggesting a possible role in aggresome formation. In conclusion, this study has shown that the relative levels of heat shock-induced HSP30 persist during recovery in contrast to HSP70. While HSP70 is degraded by the ubiquitin-proteasome system, it is likely that the presence of HSP30 multimeric complexes that are known to associate with unfolded protein as well as its association with aggresome-like structures may delay its degradation. Finally, proteasome inhibition, sodium arsenite and cadmium chloride treatment of A6 cells induced cytoplasmic/nuclear and ER chaperones as well as resulting in the formation stress granules and aggresome-like structures which associated with large HSP30 multimeric complexes. heat shock proteins aggresomes stress granules Xenopus laevis HSP30 molecular chaperones proteasome inhibition
179	Molecular cloning and characterization of nucleoside diphosphate kinase in cultured sugarcane cells Dharmasiri, Sunethra January 1995 (has links) Thesis (Ph. D.)--University of Hawaii at Manoa, 1995. / Includes bibliographical references (leaves 104-124). / Microfiche. / xii, 124 leaves, bound photos. 29 cm Sugarcane -- Physiology Heat shock proteins Phosphorylation Amino acid sequence Plant genetic engineering
180	Intensive Care Unit Muscle Wasting : Skeletal Muscle Phenotype and Underlying Molecular Mechanisms Aare, Sudhakar Reddy January 2012 (has links) Acute quadriplegic myopathy (AQM), or critical illness myopathy, is a common debilitating acquired disorder in critically ill intensive care unit (ICU) patients characterized by generalized muscle wasting and weakness of limb and trunk muscles. A preferential loss of the thick filament protein myosin is considered pathognomonic of this disorder, but the myosin loss is observed relatively late during the disease progression. In attempt to explore the potential role of factors considered triggering AQM in sedated mechanically ventilated (MV) ICU patients, we have studied the early effects, prior to the myosin loss, of neuromuscular blockade (NMB), corticosteroids (CS) and sepsis separate or in combination in a porcine experimental ICU model. Specific interest has been focused on skeletal muscle gene/protein expression and regulation of muscle contraction at the muscle fiber level. This project aims at improving our understanding of the molecular mechanisms underlying muscle specific differences in response to the ICU intervention and the role played by the different triggering factors. The sparing of masticatory muscle fiber function was coupled to an up-regulation of heat shock protein genes and down-regulation of myostatin are suggested to be key factors in the relative sparing of masticatory muscles. Up-regulation of chemokine activity genes and down-regulation of heat shock protein genes play a significant role in the limb muscle dysfunction associated with sepsis. The effects of corticosteroids in the development of limb muscle weakness reveals up-regulation of kinase activity and transcriptional regulation genes and the down-regulation of heat shock protein, sarcomeric, cytoskeletal and oxidative stress responsive genes. In contrast to limb and craniofacial muscles, the respiratory diaphragm muscle responded differently to the different triggering factors. MV itself appears to play a major role for the diaphragm muscle dysfunction. By targeting these genes, future experiments can give an insight into the development of innovative treatments expected at protecting muscle mass and function in critically ill ICU patients. acute quadriplegic myopathy gene expression myosin heat shock proteins mechanical ventilation myostatin sepsis corticosteroids diaphragm

Search results