Global ETD Search

151	Detection of Endoplasmic Reticulum Stress and Progression of Steatohepatitis in Mink (Neovison vison) with Fatty Liver Pal, Catherine 04 August 2011 (has links) This study used the non-alcoholic steatohepatitis activity index (NAI), presence of fibrosis and Mallory-Denk bodies (MDBs), and quantification of glucose regulated protein 78 (GRP78) messenger ribonucleic acid (mRNA) as indicators of steatohepatitis development and recovery in the American mink (Neovison vison). Mink were fasted for 0, 1, 3, 5, or 7 days, and one group re-fed 28 days post 7-day fast. Liver NAI indicated that moderate fatty liver developed after 5 days of fasting. Liver recovery was achieved after the re-feeding period. There was no evidence of fibrosis or MDB formation. Upregulation of GRP78 was observed by day 7 of fasting indicating endoplasmic reticulum stress. This effect was greater in females. Results suggest that liver steatosis did not advance to steatohepatitis within a 7-day fast. However, should the length of fast be increased the mink may be at risk. Results also show that liver recovery from simple fatty liver is possible.
152	The Herp and HRD1-dependent degradation of TRPP2 Lara, Carlos J. Unknown Date No description available. TRPP2 HRD1 Herp polycystic kidney disease endoplasmic reticulum stress calcium signaling
153	Post-transcriptional Regulation of Membrane-associated RNAs Jagannathan, Sujatha January 2013 (has links) <p>RNA localization provides the blueprint for compartmentalized protein synthesis in eukaryotic cells. Current paradigms indicate that RNAs encoding secretory and membrane proteins are recruited to the endoplasmic reticulum (ER), via positive selection of a `signal peptide' tag encoded in the protein. Thus RNA sorting to the ER follows protein sorting and the RNA is considered a passive player. However, RNAs have been shown to access the ER independent of the signal peptide and display a wide range of affinities to the ER that does not correlate with signal peptide strength. How and why mRNAs localize to the ER to varying extents and whether such localization serves a purpose besides protein sorting is poorly understood. To establish the cause and consequence of RNA binding to the ER membrane, I pose three primary questions: 1. How are mRNAs targeted to the ER? 2. Once targeted, how are mRNAs anchored to the ER membrane? 3. Are ER localized mRNAs subject to transcript-specific regulation? </p><p>I address cytosolic mRNA targeting to the ER by comparing the partitioning profiles of cytosolic/nuclear protein-encoding mRNA population (mRNACyto) to that of mRNAs encoding a signal peptide (mRNAER). I show that, at a population level, mRNACyto display a mean ER enrichment that is proportional to the amount of ER-bound ribosomes. Thus, I propose that targeting of mRNACyto to the ER is stochastic and over time, the specific interactions engaged by an individual mRNACyto with the ER determines its steady state partitioning profile between the cytoplasm and the ER. </p><p>To address the modes of direct binding of mRNA to the ER, I examined the association of various RNA populations with the ER after disrupting membrane-bound ribosome's interaction with its ER receptor. mRNACyto and most of mRNAs encoding secretory proteins (mRNACargo) are released upon disruption of ribosome-receptor interactions, indicating no direct mRNA-ER interactions. However, the population of mRNAs that encode resident proteins of the endomembrane organelles such as the ER, lysosome, endosome and the Golgi apparatus (mRNARes) maintain their association with the ER despite the disruption of ribosome-receptor interactions. These results indicate direct binding of mRNARes to the ER, further suggesting that the function of the encoded proteins dictates the mode of association of corresponding mRNA with the ER. </p><p>To uncover the mode of mRNARes binding directly to ER, I performed differential proteomic analysis of cytosolic and membrane bound RNA-protein complexes, which revealed a network of RNA binding proteins that interact uniquely with the ER-anchored mRNAs. The anchoring of endomembrane resident protein-encoding RNAs to the ER through these RNA binding proteins may reflect an imprinting of the ER with the information necessary for the continued biogenesis of the endomembrane organelle system even in situations where translation-dependent ER targeting of an mRNA is compromised. </p><p>Finally, I address whether ER-bound mRNAs can be regulated differentially by comparing the fates of two signal peptide-encoding RNAs, B2M and GRP94, during the unfolded protein response (UPR). I show that in response to ER stress, GRP94 mRNA, but not B2M, relocates to stress-induced RNA granules, thus escaping an RNA decay program that operates at the ER membrane during the UPR. Hence, I propose that the mode of RNA association to the ER is subject to regulation and influences the fate of RNAs during cellular stress. Thus, by demonstrating diverse modes of mRNA localization to the ER and differential regulation of ER bound mRNAs during cellular stress, my work has helped establish an emerging role for the ER as a post-transcriptional gene regulatory platform.</p> / Dissertation Cellular biology Endoplasmic reticulum Membrane domain Protein synthesis RNA binding protein RNA localization Unfolded protein response
154	Endoplasmic reticulum associated degradation (ERAD) overflow pathways. Lamberti, Kelvin Robert. January 2008 (has links) Accumulation of misfolded proteins in the endoplasmic reticulum (ER) causes numerous human pathologies. Biochemical evidence suggests that soluble misfolded proteins are retrotranslocated out of the ER, via the endoplasmic reticulum associated degradation (ERAD) pathway, for proteosome-mediated cytoplasmic degradation. Excess, misfolded- or insoluble proteins, are suggested to cause induction of “overflow” degradation pathways. For soluble proteins, overflow to vacuole-mediated destruction is suggested to occur via two Golgi-to-vacuole (Gvt) routes, the alkaline phosphatase (ALP), direct route, or, a carboxypeptidase Y- (CPY-), prevacuolar compartmentvacuole, indirect route, though only the CPY route is thought to degrade soluble proteins. Insoluble aggregate-containing structures are suggested to be degraded by engulfment by membranes of unknown origin and trafficking to the vacuole for destruction, via an autophagic pathway. To confirm biochemical evidence, wild-type (BY4742), autophagosome- (W303/ATG14), CPY- and autophagy pathway- (W303/VPS30), and proteosome (WCG/2) mutants of S. cerevisiae yeasts were transformed with a high expression pYES plasmid and mutant (Z) human alpha-1- proteinase inhibitor (A1PiZ), giving rise to the derivatives cells BY4742/Z, W303/ATG14/Z, W303/VPS30/Z and WCG/2/Z, respectively. Electron microscopy using gold labeling for A1PiZ, markers for the ER, the ERAD ER channel protein, Sec61, or the chaperone, binding protein (BiP), ALP for the ALP pathway, and CPY for the CPY pathway, was used. Overexpression of A1PiZ seems to result in targeting to the vacuole via a prevacuolar, CPY-like compartment (PVC, 200-500 nm), though CPY and A1PiZ appears not to colocalise, unconvincingly confirming collaborative biochemical data. Large amounts of A1PiZ localise in the cytosol, possibly indicating a largely proteasome-mediated degradation. ER-resident A1PiZ targeting to the vacuole seems also to occur by the budding of the ER and peripheral plasma membrane or ER membrane only. This occurs in all cells, but especially in ATG14 gene (ΔATG14) mutants, possibly indicating autophagosome-mediated degradation independence, in the latter mutants. The ATG14 mutation gave rise to crescent-shaped, initiating membranelike (IM-like) structures of approximately Cvt vesicle-diameter, possibly indicating that ΔATG14 blocks autophagosome- (500-1000 nm) and Cvt vesicle (100-200 nm) enclosure, after core IM formation. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2008. Endoplasmic reticulum. Protein folding. Proteins--Biodegradation. Autophagic vacuoles. Saccharomyces cerevisiae. Diseases. Theses--Biochemistry.
155	Disulfide Bond Formation: Identifying Roles of PDI Family Thiol Oxidoreductases and ER Oxidant Pathways Rutkevich, Lori Ann 19 December 2012 (has links) Protein disulfide isomerases (PDIs) catalyze the oxidation and isomerization of disulfide bonds in proteins passing through the endoplasmic reticulum (ER). Although as many as 20 enzymes are classified as PDI family members, their relative contributions to protein folding have remained an open question. Additionally, Ero1 has been characterized as the ER oxidase that transfers oxidizing equivalents from oxygen to PDI enzymes. However, knockout mice lacking the mammalian Ero1 isoforms, Ero1Lα and Ero1Lβ, are viable, and the role of other potential ER oxidases in maintaining an oxidative ER environment is now an important issue. By systematic depletion of ER PDI family members and potential ER oxidases and assessment of disulfide bond formation of secreted endogenous substrates, I have outlined the functional relationships among some of these enzymes. PDI family member depletion revealed that PDI, although not essential for complete disulfide bond formation in client proteins, is the most significant catalyst of oxidative folding. In comparison, ERp57 acts preferentially on glycosylated substrates, ERp72 functions in a more supplementary capacity, and P5 has no detectable role in formation of disulfide bonds for the substrates assayed. Initially, no impact of depletion of Ero1 was observed under steady state conditions, suggesting that other oxidase systems are working in parallel to support normal disulfide bond formation. Subsequent experiments incorporating a reductive challenge revealed that Ero1 depletion produces the strongest delay in re-oxidation of the ER and oxidation of substrate. Depletion of two other potential ER oxidases, peroxiredoxin 4 (PRDX4) and Vitamin K epoxide reductase (VKOR), showed more modest effects. Upon co-depletion of Ero1 and other oxidases, additive effects were observed, culminating in cell death following combined removal of Ero1, PRDX4, and VKOR activities. These studies affirm the predominant roles of Ero1 in ER oxidation processes and, for the first time, establish VKOR as a significant contributor to disulfide bond formation. Protein Disulfide Isomerase Endoplasmic reticulum biogenesis & biodegradation protein folding chaperone disulfide bonds 0487
156	The role of endoplasmic reticulum stress in beta-cell lipoapoptosis Preston, Amanda Miriam, Clinical School - St Vincent's Hospital, Faculty of Medicine, UNSW January 2008 (has links) Beta-cell failure is a key step in the progression from metabolic disorder to overt type 2 diabetes (T2D). This failure is characterised by both secretory defects and loss of beta-cell mass, the latter most likely through increases in the rate of apoptosis. Although the mechanisms underlying these beta-cell defects are unclear, evidence suggests that chronic exposure of beta-cells to elevated fatty acid (FA) plays a role in disease development in genetically susceptible individuals. Furthermore, it has been postulated that endoplasmic reticulum (ER) stress signalling pathways (the unfolded protein response; UPR) play a role in FA-induced beta-cell dysfunction. The broad aim of this thesis was to explore the nature of these relationships. Experiments detailed in this thesis demonstrate that MIN6 beta-cells mount a comprehensive ER stress response with exposure to elevated saturated fatty acid palmitate, but not the unsaturated fatty acid, oleate, within the low elevated physiological range. This response was time-dependent and involved both transcriptional and translational changes in UPR transducers and targets. The differential activation of ER stress in MIN6 beta-cells by saturated, but not unsaturated FA species may represent a mechanism of differential beta-cell death described in many studies with these FA. Furthermore, these experiments describe defects in ER to Golgi trafficking with chronic palmitate treatment, but not oleate or thapsigagin treatment, identifying this as a potential mechanism by which palmitate treatment induces ER stress. Moreover, these studies have shown the relevance to ER stress to a whole body model of T2D by demonstrating UPR activation in the islets of the db/db mouse. In conclusion, studies detailed in this thesis have demonstrated that ER stress occurs in in vitro and in vivo models of beta-cell lipotoxicity and apoptosis. In addition, these studies have identified defects in ER to Golgi trafficking as a mechanism by which palmitate treatment induces ER stress. These studies highlight the importance of ER stress in the development of T2D. Fatty acid Endoplasmic reticulum stress Type 2 diabetes Pancreatic beta-cell Apoptosis
157	Membrane chaperones : protein folding in the ER membrane / Kota, Jhansi, January 2007 (has links) Diss. (sammanfattning) Stockholm : Karolinska institutet, 2007. / Härtill 3 uppsatser.
158	Structural insights into glycoprotein transport and viral escape / Velloso, Lucas Malard, January 2004 (has links) Diss. (sammanfattning) Stockholm : Karol inst., 2004. / Härtill 4 uppsatser.
159	Nephrin: cellular trafficking and intracellular interactions / Liu, Xiao Li, January 2004 (has links) Diss. (sammanfattning) Stockholm : Karol. inst., 2004. / Härtill 4 uppsatser.
160	Protein disulfide isomerase : function and mechanism in oxidative protein folding / Xiao, Ruoyu, January 2005 (has links) Diss. (sammanfattning) Stockholm : Karol. inst., 2005. / Härtill 4 uppsatser.

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