Global ETD Search

381	Investigating the Roles of NEDD4.2s and Nef in the Release and Replication of HIV-1: A Dissertation Weiss, Eric R. 13 September 2012 (has links) Replication of HIV-1 requires the assembly and release of mature and infectious viral particles. In order to accomplish this goal, HIV-1 has evolved multiple methods to interact with the host cell. HIV-1 recruits the host cell ESCRT machinery to facilitate the release of nascent viral particles from the host cell membrane. Recruitment of these cellular factors is dependent on the presence of short motifs in Gag referred to as Late-domains. Deletion or mutation of these domains results in substantial decrease in the release of infectious virions. However, previously published work has indicated that over-expression of the E3 ubiquitin ligase, NEDD4.2s is able to robustly rescue release of otherwise budding-defective HIV-1 particles. This rescue is specific to the NEDD4.2s isoform as related E3 ubiquitin ligases display no ability to rescue particle release. In addition, rescue of particle release is dependent on the presence of the partial C2 domain and a catalytically active HECT domain of NEDD4.2s. Here I provide evidence supporting the hypothesis that a partial C2 domain of NEDD4.2s constitutes a Gag interacting module capable of targeting the HECT domains of other E3 ubiquitin ligases to HIV-1 Gag. Also, by generating chimeras between HECT domains shown to form poly-ubiquitin chains linked through either K48 or K63 of ubiquitin, I demonstrate that the ability of NEDD4.2s to catalyze the formation of K63-polyubiquitin chains is required for its stimulation of HIV-1 L-domain mutant particle release. In addition, I present findings from on-going research into the role of the HIV-1 accessory protein Nef during viral replication using the culture T-cell line, MOLT3. My current findings indicate that downregulation of CD4 from the host cell membrane does not solely account for the dramatic dependence of HIV-1 replication on Nef expression in this system. In addition, I present evidence indicating that Nef proteins from diverse HIV-1 Groups and strains are capable of enhancing HIV-1 replication in this system. Analysis of a range of mutations in Nef known to impact interaction with cellular proteins suggest that the observed replication enhancement requires Nef targeting to the host cell membrane and may also require the ability to interact with select Src-kinases. Lastly, we find that the ability of Nef to enhance replication in this system is separate from any increase in viral particle infectivity, in agreement with current literature. Virus Replication Virus Release HIV-1 Ubiquitin-Protein Ligases nef Gene Products Human Immunodeficiency Virus Amino Acids, Peptides, and Proteins Cells Enzymes and Coenzymes Genetic Phenomena Immunology and Infectious Disease Microbiology Virology Viruses
382	Pharmacological Chaperoning in Fabry Disease Rogich, Jerome 01 January 2011 (has links) (PDF) Fabry Disease is an X-‐linked lysosomal storage disorder characterized by a variety of symptoms including hypohydrosis, seizures, cardiac abnormalities, skin lesions, and chronic pain. These symptoms stem from a lack of functional endogenous α-‐ Galactosidase A (α-GAL), which leads to an accrual of its natural substrate. The severity of the disease symptoms can be directly correlated with the amount of residual enzyme activity. It has been shown that an imino sugar, 1-deoxygalactonojirimycin (DGJ), can increase enzymatic activity and clear excess substrate. This pH-‐dependent chaperoning phenomenon is believed to arise from the presence of aspartic acid 170 in the active site. This key residue may become protonated at lower pH, preventing a buried salt bridge from being formed. We mutated this residue to an alanine, abolishing activity, and making traditional assays impractical. We have measured the KD of chaperone for this modified active site through crystallography. Previous crystallographic studies on this enzyme have also shown a preliminary second binding site on the surface of α-Galactosidase that prefers the β-Galactose anomer. When β-Galactose binds it buries a greater surface area than when α‐Galactose binds to the active site. Binding of this site by a small molecule should stabilize the native state of the enzyme, but would be sterically occluded from inhibiting active site. We have probed this second site by soaking crystals of α‐Galactosidase with a small library of compounds. Amino Acids, Peptides, and Proteins Biochemistry Biophysics Enzymes and Coenzymes Medicinal-Pharmaceutical Chemistry Molecular Biology Other Chemicals and Drugs Pharmaceutical Preparations Structural Biology
383	TOWARD AN ENZYME-COUPLED, BIOORTHOGONAL PLATFORM FOR METHYLTRANSFERASES: PROBING THE SPECIFICITY OF METHIONINE ADENOSYLTRANSFERASES Huber, Tyler D. 01 January 2019 (has links) Methyl group transfer from S-adenosyl-l-methionine (AdoMet) to various substrates including DNA, proteins, and natural products (NPs), is accomplished by methyltransferases (MTs). Analogs of AdoMet, bearing an alternative S-alkyl group can be exploited, in the context of an array of wild-type MT-catalyzed reactions, to differentially alkylate DNA, proteins, and NPs. This technology provides a means to elucidate MT targets by the MT-mediated installation of chemoselective handles from AdoMet analogs to biologically relevant molecules and affords researchers a fresh route to diversify NP scaffolds by permitting the differential alkylation of chemical sites vulnerable to NP MTs that are unreactive to traditional, synthetic organic chemistry alkylation protocols. The full potential of this technology is stifled by several impediments largely deriving from the AdoMet-based reagents, including the instability, membrane impermeability, poor synthetic yield and resulting diastereomeric mixtures. To circumvent these main liabilities, novel chemoenzymatic strategies that employ methionine adenosyltransferases (MATs) and methionine (Met) analogs to synthesize AdoMet analogs in vitro were advanced. Unstable AdoMet analogs are simultaneously utilized in a one-pot reaction by MTs for the alkylrandomization of NP scaffolds. As cell membranes are permeable to Met analogs, this also sets the stage for cell-based and, potentially, in vivo applications. In order to further address the instability of AdoMet and analogs thereof, MAT-catalyzed reactions utilizing Met and ATP isosteres generated highly stable AdoMet isosteres that were capable of downstream utilization by MTs. Finally, the development, use, and results of a high-throughput screen identified mutant-MAT/Met-analog pairs suitable for postliminary bioorthogonal applications. Methionine Adenosyltransferase Methyltransferase S-Adenosyl-L-methionine Natural Product Diversification Bioorthogonal Labelling Platforms Amino Acids, Peptides, and Proteins Biochemistry Biotechnology Chemical and Pharmacologic Phenomena Enzymes and Coenzymes Medicinal and Pharmaceutical Chemistry Medicinal Chemistry and Pharmaceutics Medicinal-Pharmaceutical Chemistry Molecular Biology Organic Chemistry Structural Biology
384	Effective Statistical Energy Function Based Protein Un/Structure Prediction Mishra, Avdesh 05 August 2019 (has links) Proteins are an important component of living organisms, composed of one or more polypeptide chains, each containing hundreds or even thousands of amino acids of 20 standard types. The structure of a protein from the sequence determines crucial functions of proteins such as initiating metabolic reactions, DNA replication, cell signaling, and transporting molecules. In the past, proteins were considered to always have a well-defined stable shape (structured proteins), however, it has recently been shown that there exist intrinsically disordered proteins (IDPs), which lack a fixed or ordered 3D structure, have dynamic characteristics and therefore, exist in multiple states. Based on this, we extend the mapping of protein sequence not only to a fixed stable structure but also to an ensemble of protein conformations, which help us explain the complex interaction within a cell that was otherwise obscured. The objective of this dissertation is to develop effective ab initio methods and tools for protein un/structure prediction by developing effective statistical energy function, conformational search method, and disulfide connectivity patterns predictor. The key outcomes of this dissertation research are: i) a sequence and structure-based energy function for structured proteins that includes energetic terms extracted from hydrophobic-hydrophilic properties, accessible surface area, torsion angles, and ubiquitously computed dihedral angles uPhi and uPsi, ii) an ab initio protein structure predictor that combines optimal energy function derived from sequence and structure-based properties of proteins and an effective conformational search method which includes angular rotation and segment translation strategies, iii) an SVM with RBF kernel-based framework to predict disulfide connectivity pattern, iv) a hydrophobic-hydrophilic property based energy function for unstructured proteins, and v) an ab initio conformational ensemble generator that combines energy function and conformational search method for unstructured proteins which can help understand the biological systems involving IDPs and assist in rational drugs design to cure critical diseases such as cancer or cardiovascular diseases caused by challenging states of IDPs. Energy Function Ab Initio Protein Structure Prediction Disulfide Bonds Prediction Intrinsically Disordered Proteins Flexible Energy Function Conformational Ensemble Generator Algebraic Geometry Amino Acids, Peptides, and Proteins Bioinformatics Biological and Chemical Physics Computational Biology Other Computer Sciences Statistical Models Structural Biology
385	A Proposal to Test the Effects of Factor ECAT1 on Pluripotency, from Reprogramming to Differentiation of Human Somatic Cells Goel, Vritti R. 01 January 2012 (has links) The field of stem cell research has been growing more because of the interest in using stem cells to cure diseases and heal injuries. Human embryonic stem cells, because of the controversy surrounding them—and subsequently the difficulties in acquiring samples of the existing aging cell lines—can only be used in limited capacities. While the development of induced pluripotent stem cells in the last decade has allowed the field to progress closer to medical treatments, the low efficiency of reprogramming a somatic cell to a pluripotent state, and the vast molecular and genomic differences between human embryonic stem cells and human induced pluripotent stem cells is still an issue. Therefore, the goal is to discover methods, chemicals, and factors that can reduce these differences and increase the efficiency of inducing pluripotency. This proposal aims to look at the effects of the protein ECAT1 in inducing pluripotency in human somatic cells. Little is known about ECAT1, otherwise known as Embryonic Stem Cell-Associated Transcript 1, beyond its presence in human embryonic stem cells and oocytes and its absence in differentiated cells. While originally considered by scientists during the development of the reprogramming technique, ECAT1's effects have not been tested in humans. Therefore, a series of experiments will be performed in which ECAT1 will be used in conjunction with OSKM to induce pluripotency in adult human dermal fibroblasts, which will then be differentiated into spinal motor neurons. The three stages of this proposal--inducing pluripotency, comparing pluripotencies in the reprogrammed cells and embryonic stem cells, and differentiating the stem cells--should answer questions about ECAT1 and the reprogramming process. It is predicted that ECAT1 should reduce the genomic and molecular differences between embryonic stem cells and induced pluripotent stem cells. ECAT1's presence should also increase the efficiency of reprogramming as well as successful differentiation to other cell types. stem cells OSKM induced pluripotency reprogramming differentiation ECAT1 Amino Acids, Peptides, and Proteins Bioethics and Medical Ethics Bioinformatics Biological Factors Biology Cell Biology Cellular and Molecular Physiology Developmental Biology Enzymes and Coenzymes Genetic Structures Medical Molecular Biology Molecular and Cellular Neuroscience Molecular Biology
386	CD40-CD154 Blockade Facilitates Induction of Allogeneic Hematopoietic Chimerism and Transplantation Tolerance: A Dissertation Seung, Edward 14 May 2003 (has links) Allogeneic hematopoietic chimerism leading to central tolerance has significant therapeutic potential. Establishment of hematopoietic chimerism created by stem cell transplantation has been shown to prevent and cure a number of autoimmune diseases and induce the most robust and long-lasting form of transplantation tolerance known. However, the realization of the vast clinical potential of hematopoietic chimerism for induction of transplantation tolerance has been impeded by the toxicity of the host conditioning regimen and the development of graft-versus-host disease (GVHD). This thesis describes the development of stem cell transplantation protocols that 1) reduce the host conditioning regimen; and 2) abrogate the development of GVHD. When applied to the treatment of autoimmune diabetic NOD mice, a model of type 1 diabetes, stem cell transplantation was able to 3) prevent autoimmune recurrence; and 4) permit curative pancreatic islet transplantation. I first describe a tolerance-based stem cell transplantation protocol that combines sub-lethal irradiation with transient blockade of the CD40-CD154 costimulatory pathway using an anti-CD154 antibody. With this protocol, I established hematopoietic chimerism in BALB/c mice transplanted with fully allogeneic C57BL/6 bone marrow. All chimeric mice treated with anti-CD154 antibody remained free of graft vs.host disease (GVHD) and accepted donor-origin but not third party skin allografts. It was similarly possible to create allogeneic hematopoietic chimerism in NOD/Lt mice with spontaneous autoimmune diabetes. Pancreatic islet allografts transplanted into chimeric NOD/Lt mice were resistant not only to allorejection but also to recurrence of autoimmunity. I conclude that it is possible to establish robust allogeneic hematopoietic chimerism in sub-lethally irradiated mice without subsequent GVHD by blocking the CD40-CD154 costimulatory pathway using as few as two injections of anti-CD154 antibody. I also conclude that chimerism created in this way generates donor-specific allograft tolerance and reverses the predisposition to recurrent autoimmune diabetes in NOD/Lt mice, enabling them to accept curative islet allografts. In order to further reduce the impediments associated with the implementation of allogeneic hematopoietic chimerism as a therapeutic modality, I adapted a costimulation blockade-based protocol developed for solid organ transplantation for use in stem cell transplantation. The protocol combines a donor-specific transfusion (DST) with anti-CD154 antibody to induce peripheral transplantation tolerance. When applied to stem cell transplantation, administration of DST, anti-CD154 antibody, and allogeneic bone marrow led to hematopoietic chimerism and central tolerance with no myeloablation (i.e. no radiation) and no GVHD in 3 different strains of mice. The development of donor-specific tolerance in this system was shown to involve deletion of both peripheral host alloreactive CD8+ T cells and nascent intrathymic alloreactive CD8+ T cells. In the absence of large numbers of host alloreactive CD8+ T cells, the cell transfusion that precedes transplantation need not be of donor-origin, suggesting that both allo-specific and non-allo-specific mechanisms regulate engraftment. Agents that interfere with peripheral transplantation tolerance partially impair establishment of chimerism. I conclude that robust allogeneic hematopoietic chimerism and central tolerance can be established in the absence of host myeloablative conditioning using a peripheral transplantation tolerance protocol. Hematopoietic Stem Cell Transplantation Transplantation Immunology Transplantation Homologous Transplantation Tolerance Transplantation Chimera Radiation Chimera Transplantation Conditioning Graft vs Host Disease Amino Acids, Peptides, and Proteins Animal Experimentation and Research Endocrine System Diseases Immune System Diseases Immunology and Infectious Disease Nutritional and Metabolic Diseases Surgical Procedures, Operative Therapeutics
387	Intranuclear Trafficking of RUNX/AML/CBFA/PEBP2 Transcription Factors in Living Cells: A Dissertation Harrington, Kimberly Stacy 28 March 2003 (has links) The family of runt related transcription factors (RUNX/Cbfa/AML/PEBP2) are essential for cellular differentiation and fetal development. RUNX factors are distributed throughout the nucleus in punctate foci that are associated with the nuclear matrix/scaffold and generally correspond with sites of active transcription. Truncations of RUNX proteins that eliminate the C-terminus including a 31-amino acid segment designated the nuclear matrix targeting signal (NMTS) lose nuclear matrix association and result in lethal hematopoietic (RUNX1) and skeletal (RUNX2) phenotypes in mice. These findings suggest that the targeting of RUNX factors to subnuclear foci may mediate the formation of multimeric regulatory complexes and contribute to transcriptional control. In this study, we hypothesized that RUNX transcription factors may dynamically move through the nucleus and associate with subnuclear domains in a C-terminal dependent mechanism to regulate transcription. Therefore, we investigated the subnuclear distribution and mobility of RUNX transcription factors in living cells using enhanced green fluorescent protein (EGFP) fused to RUNX proteins. The RUNX C-terminus was demonstrated to be necessary for the dynamic association of RUNX with stable subnuclear domains. Time-lapse fluorescence microscopy showed that RUNX1 and RUNX2 localize to punctate foci that remain stationary in the nuclear space in living cells. By measuring fluorescence recovery after photobleaching, both RUNX1 and RUNX2 were found to dynamically and rapidly associate with these subnuclear foci with a half-time of recovery in the ten-second time scale. A large immobile fraction of RUNX1 and RUNX2 proteins was observed in the photobleaching experiments, which suggests that this fraction of RUNX1 and RUNX2 proteins are immobilized through the C-terminal domain by interacting with the nuclear architecture. Truncation of the C-terminus of RUNX2, which removes the NMTS as well as several co-regulatory protein interaction domains, increases the mobility of RUNX2 by at least an order of magnitude, resulting in a half-time of recovery equivalent to that of EGFP alone. Contributions of the NMTS sequence to the subnuclear distribution and mobility of RUNX2 were further assessed by creating point mutations in the NMTS of RUNX2 fused to EGFP. The results show that these point mutations decrease, but do not abolish, association with the nuclear matrix compared to wild-type EGFP-RUNX2. Three patterns of subnuclear distribution were similarly observed in living cells for both NMTS mutants and wild-type RUNX2. Furthermore, the NMTS mutations showed no measurable effect on the mobility of RUNX2. However, the mobility of RUNX proteins in each of the different subnuclear distributions observed in living cells were significantly different from each other. The punctate distribution appears to correlate with higher fluorescence intensity, suggesting that the protein concentration in the cell may have an effect on the formation or size of the foci. These findings suggest that the entire NMTS and/or the co-regulatory protein interaction domains may be necessary to immobilize RUNX2 proteins. Because RUNX factors contain a conserved intranuclear targeting signal, we examined whether RUNX1 and RUNX2 are targeted to common subnuclear domains. The results show that RUNX1 and RUNX2 colocalized in common subnuclear foci. Furthermore, RUNX subnuclear foci contain the co-regulatory protein CBFβ, which heterodimerizes with RUNX factors, and nascent transcripts as shown by BrUTP incorporation. These results suggest that RUNX subnuclear foci may represent sites of transcription containing multi-subunit transcription factor complexes. RUNX2 transcription factors induce expression of the osteocalcin promoter during osteoblast differentiation and to study both RUNX2 and osteocalcin function, it would be helpful to have transgenic mice in which OC expression could be easily evaluated. Therefore, to assess the in vivo regulation of osteocalcin by RUNX protein, we generated transgenic mice expressing EGFP controlled by the osteocalcin promoter. Our results show that EGFP is expressed from the OC promoter in a cultured osteosarcoma cell line, but not in a kidney cell line, and is induced by vitamin D3. Furthermore, the OC-EGFP transgenic mice specifically express EGFP in osteoblasts and osteocytes in bone tissues. Moreover, EGFP is expressed in mineralized bone nodules of differentiated bone marrow derived from transgenic mice. Thus, these mice produce a good model for studying the in vivo effects of RUNX-mediated osteocalcin regulation and for developing potential drug therapies for bone diseases. Taken together, our results in living cells support the conclusion that RUNX transcription factors dynamically associate with stationary subnuclear foci in a C-terminal dependent mechanism to regulate gene expression. Moreover, RUNX subnuclear foci represent transcription sites containing nascent transcripts and co-regulatory interacting proteins. These conclusions provide a mechanism for how RUNX transcription factors may associate with subnuclear foci to regulate gene expression. Furthermore, the OC-EGFP transgenic mice now provide a useful tool for studying the in vivo function and regulation of osteocalcin by RUNX proteins during osteoblast differentiation and possibly for developing therapeutic drugs for treatment of bone diseases in the future. Transcription Genetic Transcription Factors DNA-Binding Proteins Focal Adhesions Cell Nucleus Nuclear Localization Signals Osteocalcin Osteocytes Osteoblasts Bone Diseases Models Animal Microscopy Fluorescence Amino Acids, Peptides, and Proteins Animal Experimentation and Research Cell and Developmental Biology Cells Genetic Phenomena Investigative Techniques Musculoskeletal Diseases Tissues
388	Egr-2 and PD-1 Are Required for Induction and Maintenance of T Cell Anergy: A Dissertation Bishop, Kenneth D. 13 July 2005 (has links) The prevalence of diabetes is approaching epidemic proportions worldwide. There is currently no cure for type 1 diabetes, and successful treatment requires constant monitoring of blood sugars and use of exogenous insulin to prevent hyperglycemia. Diabetes will be curable when pancreatic β-islet cells can be transplanted into diabetes patients without requiring long-term immunosuppression. This will require learning more about the induction of functional tolerance, a state that maintains the competence of the immune system to most antigens but protects graft-specific antigens from immune rejection, permitting transplantation. One known mechanism of peripheral tolerance is T cell anergy, a phenotype of hypo-reponsiveness in CD4+ T cells. The focus of this thesis is a description of factors shown to be specific to the induction and maintenance of T cell anergy, whose loss reverses the anergic phenotype, restoring the ability of the cells to proliferate in response to antigen. The first of these is Egr-2, a zinc-finger transcription factor, whose presence is required for the induction of anergy induced in T cell clones by TCR stimulation in the absence of costimulation. Egr-2 is shown to be important to anergy induction but not anergy maintenance. In contrast, a negative costimulation receptor, PD-1, is shown to be necessary for the maintenance of anergy. It is possible that learning more about the genetic factors that orchestrate T cell anergy will prove useful in the development of tolerance-based protocols for organ and tissue transplantation without the use of long-term immunosuppression. Clonal Anergy DNA-Binding Proteins Transcription Factors Zinc Fingers Antigens Surface CD4-Positive T-Lymphocytes Diabetes Mellitus Type 1 Islets of Langerhans Transplantation Immune Tolerance Immunosuppression Amino Acids, Peptides, and Proteins Biological Factors Cells Endocrine System Diseases Genetic Phenomena Hemic and Immune Systems Immune System Diseases Nutritional and Metabolic Diseases Surgical Procedures, Operative Therapeutics
389	Transcript-Specific Cytoplasmic Degradation of YRA1 Pre-mRNA Mediated by the Yeast EDC3 Protein: A Dissertation Dong, Shuyun 17 December 2007 (has links) mRNA degradation is a fundamental process that controls both the level and the fidelity of gene expression. Using a combination of bioinformatic, genomic, genetic, and molecular biology approaches, we have shown that Edc3p, a yeast mRNA decay factor, controls the stability of the intron-containing YRA1 pre-mRNA. We found that Edc3p-mediated degradation of YRA1 pre-mRNA: 1) is a component of a negative feedback loop involved in the autoregulation of YRA1, 2) takes place in the cytoplasm, 3) is independent of translation, 4) occurs through a deadenylation-independent decapping and 5΄ to 3΄ exonucleotic decay mechanism, and 5) is controlled by specific cis-acting elements and trans-regulatory factors. Cis-regulation of YRA1 pre-mRNA degradation is complicated and precise. Sequences in exon1 inhibit YRA1 pre-mRNA splicing and/or promote pre-mRNA export in a size-dependent but sequence-independent manner. Sequences in the intron dictate the substrate specificity for Edc3p-mediated decay. Five structurally different but functionally interdependent modules were identified in the YRA1 intron. Two modules, designated Edc3p-responsive elements (EREs), are required for triggering an Edc3p-response. Three other modules, designated translational repression elements (TREs), are required for repressing translation of YRA1 pre-mRNA. TREs enhance the efficiency of the response of the EREs to Edc3p by inhibiting translation-dependent nonsense-mediated mRNA decay (NMD). Trans-regulation of YRA1 pre-mRNA is governed by Yra1p, which inhibits YRA1 pre-mRNA splicing and commits the pre-mRNA to nuclear export, and the RNP export factors, Mex67p and Crm1p, which jointly promote YRA1 pre-mRNA export. Mex67p also appears to interact with sequences in the YRA1 intron to promote translational repression and to enhance the Edc3p response of YRA1 pre-mRNA. These results illustrate how common steps in the nuclear processing, export, and degradation of a transcript can be uniquely combined to control the expression of a specific gene and suggest that Edc3p-mediated decay may have additional regulatory functions in eukaryotic cells. Gene Expression Cell Nucleus Feedback Biochemical Nuclear Proteins RNA Stability RNA Precursors RNA-Binding Proteins Saccharomyces cerevisiae Amino Acids, Peptides, and Proteins Biochemistry Bioinformatics Cells Computational Biology Fungi Genetic Phenomena Genetics Genetics and Genomics Genomics Molecular Biology Molecular Genetics
390	Role of WFS1 in Regulating Endoplasmic Reticulum Stress Signaling: A Dissertation Fonseca, Sonya G. 24 February 2009 (has links) The endoplasmic reticulum (ER) is a multi-functional cellular compartment that functions in protein folding, lipid biosynthesis, and calcium homeostasis. Perturbations to ER function lead to the dysregulation of ER homeostasis, causing the accumulation of unfolded and misfolded proteins in the cell. This is a state of ER stress. ER stress elicits a cytoprotective, adaptive signaling cascade to mitigate stress, the Unfolded Protein Response (UPR). As long as the UPR can moderate stress, cells can produce the proper amount of proteins and maintain a state of homeostasis. If the UPR, however, is dysfunctional and fails to achieve this, cells will undergo apoptosis. Diabetes mellitus is a group of metabolic disorders characterized by persistent high blood glucose levels. The pathogenesis of this disease involves pancreatic β-cell dysfunction: an abnormality in the primary function of the β-cell, insulin production and secretion. Activation of the UPR is critical to pancreatic β-cell survival, where a disruption in ER stress signaling can lead to cell death and consequently diabetes. There are several models of ER stress leading to diabetes. Wolcott-Rallison syndrome, for example, occurs when there is a mutation in the gene encoding one of the master regulators of the UPR, PKR-like ER kinase (PERK). In this dissertation, we show that Wolfram Syndrome 1 (WFS1), an ER transmembrane protein, is a component of the UPR and is a downstream target of two of the master regulators of the UPR, Inositol Requiring 1 (IRE1) and PERK. WFS1 mutations lead to Wolfram syndrome, a non-autoimmune form of type 1 diabetes accompanied by optical atrophy and other neurological disorders. It has been shown that patients develop diabetes due to the selective loss of their pancreatic β-cells. Here we define the underlying molecular mechanism of β-cell loss in Wolfram syndrome, and link this cell loss to ER stress and a dysfunction in a component of the UPR, WFS1. We show that WFS1 expression is localized to the β-cell of the pancreas, it is upregulated during insulin secretion and ER stress, and its inactivation leads to chronic ER stress and apoptosis. This dissertation also reveals the previously unknown function of WFS1 in the UPR. Positive regulation of the UPR has been extensively studied, however, the precise mechanisms of negative regulation of this signaling pathway have not. Here we report that WFS1 regulates a key transcription factor of the UPR, activating transcription factor 6 (ATF6), through the ubiquitin-proteasome pathway. WFS1 expression decreases expression levels of ATF6 target genes and represses ATF6-mediated activation of the ER stress response (ERSE) promoter. WFS1 recruits and stabilizes an E3 ubiquitin ligase, HMG-CoA reductase degradation protein 1 (HRD1), on the ER membrane. The WFS1-HRD1 complex recruits ATF6 to the proteasome and enhances its ubiquitination and proteasome-mediated degradation, leading to suppression of the UPR under non-stress conditions. In response to ER stress, ATF6 is released from WFS1 and activates the UPR to mitigate ER stress. This body of work reveals a novel role for WFS1 in the UPR, and a novel mechanism for regulating ER stress signaling. These findings also indicate that hyperactivation of the UPR can lead to cellular dysfunction and death. This supports the notion that tight regulation of ER stress signaling is crucial to cell survival. This unanticipated role of WFS1 for a feedback loop of the UPR is relevant to diseases caused by chronic hyperactivation of ER stress signaling network such as pancreatic β-cell death in diabetes and neurodegeneration. Wolfram Syndrome Endoplasmic Reticulum Insulin-Secreting Cells Membrane Proteins Pancreas Signal Transduction Stress Physiological Amino Acids, Peptides, and Proteins Cells Digestive System Endocrine System Diseases Eye Diseases Male Urogenital Diseases Nervous System Diseases Nutritional and Metabolic Diseases Otorhinolaryngologic Diseases

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