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Browsing by Author "Elmendorf, Jeffrey"
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Item Cellular & Molecular Mechanisms That Contribute to the Early Development of Skeletal Muscle & Systemic Insulin Resistance(2019-10) Grice, Brian A.; Elmendorf, Jeffrey; Considine, Robert; Herring, Paul; Mather, Kieren; Mirmira, RaghuInsulin resistance starts years before type 2 diabetes (T2D) diagnosis, even before recognition of prediabetes. Mice on a high fat diet have a similar early onset of insulin resistance, yet the mechanism remains unknown. Several studies have demonstrated that skeletal muscle insulin resistance resulting from obesity or high fat feeding does not stem from defects in proximal insulin signaling. Our lab discovered that excess plasma membrane cholesterol impairs insulin action. Excess cholesterol in the plasma membrane causes a loss of cortical actin filaments that are essential for glucose transporter GLUT4 regulation by insulin. Our cell studies further revealed that increased hexosamine biosynthesis pathway (HBP) activity increases O-linked N-acetylglucosamine modification of the transcription factor Sp1, leading to transcription of HMG-CoA reductase (HMGR), the rate-limiting enzyme in cholesterol biosynthesis. Our central hypothesis is that cholesterol accumulation mediated by HBP activity is an early reversible mechanism of high-fat diet-induced insulin resistance. We performed a series of studies and found that early high-fat feeding-induced insulin resistance is associated with a buildup of cholesterol in skeletal muscle membranes (SMM). Akin to the antidiabetic effect of caloric restriction, we found that high-fat diet removal fully mitigated SMM cholesterol accumulation and insulin resistance. Furthermore, using the cholesterol-binding agent methyl-β-cyclodextrin (MβCD), studies established causality between excess SMM cholesterol and insulin resistance. To begin to assess the role of the HBP/Sp1 in contributing to de novo cholesterol biosynthesis, SMM accumulation, and insulin resistance we treated high-fat fed mice with an Sp1 inhibitor, mithramycin. We found that mithramycin prevented SMM cholesterol accumulation and insulin resistance. This series of studies provide evidence that HBP/Sp1-mediated cholesterol accumulation in SMM is a causal, early and reversible mechanism of whole body insulin resistance.Item Generation and Exploration of a Novel Low Oxygen Landscape for Hematopoietic Stem and Progenitor Cells(2022-10) Dausinas, Paige Burke; Elmendorf, Jeffrey; O'Leary, Heather; Bidwell, Joseph; Wan, Jun; Zhang, JiHematopoietic stem (HSC) and progenitor (HSPC) cells reside in low oxygen (~1- 4%, low O2) bone marrow niches which provide critical signals for maintenance, selfrenewal, and differentiation. Exposure of HSC/HSPCs to air (~21%) for less than 10 minutes irreversibly diminishes numbers of phenotypic and functional stem cells, a phenomenon termed extra physiologic oxygen stress/shock. Yet, most studies harvest and analyze HSC/HSPCs in air and often in fixed cells, leaving endogenous signaling mechanisms unidentified. To better understand the endogenous mechanisms regulating HSCs and HSPCs, we generated the first low O2 landscape of phenotypic/functional/signaling alterations in live, low O2 harvested/sorted HSC/HSPCs utilizing novel technology. HSC (LSKCD150+) and HSC/HSPC (LSK) expression, frequency, and stem cell maintenance retention were enhanced in low O2 relative to historic data and our air data. Transcriptomics uncovered low O2 differential pathway regulation of HSC/HSPCs and HSCs with analysis identifying low O2 enrichment of genes/pathways including Ca2+ ion binding, altered sodium hydrogen (Na+/H+) activity, viral entry, and transmembrane receptor activity in both HSCs and HSPCs. In exploring the low O2 landscape, we investigated differential low O2 regulation of Ca2+ and SARS-CoV-2 related pathways/mechanisms in HSCs and HSPCs. Differential Ca2+ regulation was observed in our transcriptional/proteomic analysis corroborated by phenotypic/functional data demonstrating increases in low O2 of cytosolic and mitochondrial Ca2+ flux, ABC Transporter (ABCG2) and Na+/H+ (NHE1) expression, discovery of a novel low O2 Ca2+ high HSPC population that enhances HSC maintenance compared to Ca2+ low populations and blunting of this population and subsequent enhanced stem cell maintenance upon NHE1 inhibition (Cariporide). Multi-omics analyses also identified enhancements in COVID19-related pathways in low O2 that corresponded with enhanced expression of SARS-CoV-2 receptors/co-receptors, SARS-CoV-2 spike protein (SP) binding, and expansion of SP-bound HSC/HSPCs in low O2 compared to air, as well as enhanced stem cell maintenance of SP-bound, versus unbound, cells in low O2. Together, these data presented show low O2 harvest/retention of HSC/HSPCs enhances stem cell maintenance, which could be utilized to improve HSC expansion, and leads to differential pathway/signaling regulation of various biological pathways in HSC/HSPCs including Ca2+ and SARS-CoV-2/viral infection that results in phenotypic and functional consequences.Item Pancreatic Beta Cell Identity Regulated by the Endoplasmic Reticulum Calcium Sensor Stromal Interaction Molecule 1(2021-12) Sohn, Paul; Evans-Molina, Carmella; Elmendorf, Jeffrey; Linnemann, Amelia; Sankar, UmaType 2 diabetes mellitus is a chronic disorder characterized by hyperglycemia, insulin resistance, and insufficient insulin secretion from the pancreatic β cells. To maintain adequate levels of insulin secretion, β cells rely on highly coordinated control of luminal ER Ca2+. Stromal Interaction Molecule 1 (STIM1) is an ER Ca2+ sensor that serves to replenish ER Ca2+ stores in response to depletion by gating plasmalemmal Orai1 channels in a process known as store-operated calcium entry (SOCE). We developed a method for the direct measurement of SOCE in pancreatic β cells and found that deletion of STIM1 in INS-1 cells (STIM1KO) is sufficient to block Ca2+ influx in response to store-depletion. To determine the physiological importance of β cell STIM1, we created mice with pancreatic β cell specific deletion of STIM1 (STIM1Δβ) and placed them on a high fat diet (HFD) with 60% of kilocalories derived from fat. After 8 weeks of HFD, female, but not male, STIM1Δβ mice exhibited increased body weight and fat mass as well as significant glucose intolerance and impaired insulin secretion without observable differences in insulin tolerance. Immunohistochemical analysis revealed a reduction of β cell mass and an increase of α cell mass; ELISA of islet lysates revealed a similar significant reduction in insulin content and increased glucagon content. RNA-sequencing performed on STIM1Δβ islets revealed differentially expressed genes for functions related to apoptosis, lipid metabolism, and epithelial cell differentiation, as well as loss of β cell identity. Proteomics analysis of STIM1KO cells phenocopied the metabolic findings, revealing significantly increased glucagon expression. Analysis of islet RNA-sequencing results showed modulation of pathways related to 17-β estradiol (E2) signaling, with notable downregulation of G-protein coupled estrogen receptor 1 (GPER1) expression. Consistently, treatment of female wild-type islets with pharmacological SOCE inhibitors led to reduced expression GPER1, while STIM1KO cells showed lower mobilization of intracellular cAMP levels in response to GPER agonist treatment. Taken together, these findings identify a novel interaction between SOCE and E2 signaling in the female islet and suggest that loss of STIM1 and impairments in SOCE may contribute to diabetes pathophysiology through loss of β cell identity.Item Stress-activated MIG6 compromises hepatic metabolism during diet-induced obesity(2016-07-25) Lutkewitte, Andrew John; Fueger, Patrick T.; Considine, Robert; Evans-Molina, Carmella; Tune, Johnathan; Elmendorf, JeffreyObesity-induced hepatic fat accumulation or nonalcoholic fatty liver disease (NAFLD) is the leading cause of liver disease in the United States. Unfortunately, NALFD patients are at higher risk of cardiovascular disease and mortality. The development of hepatic steatosis is multi-factorial and leads to a variety of pathologies. Yet, the molecular mechanisms behind liver disease during hepatic fat accumulation remain unclear. Here, we describe novel mechanisms of impaired liver function in the context of obesity-induced hepatic stress. Using chemical- and fatty acid-induced endoplasmic reticulum (ER) stress, we discovered ER stress decreases the activation of the pro-growth, pro survival, receptor tyrosine kinase, epidermal growth factor receptor (EGFR) in vitro. Importantly, EGFR was inhibited during these stress conditions by the induction and stabilization of mitogen inducible gene 6 (Mig6). Furthermore, Mig6 knockdown in vitro enhanced EGFR signaling and promoted survival. We demonstrated that mice fed a high fat diet have decreased EGFR activation and increased Mig6 protein expression, likely due to obesity-induced ER stress. To determine the functional consequences of increased Mig6 expression, we generated Mig6 liver-specific knockout mice (Mig6 LKO) and subjected them to high fat feeding. During diet-induced obesity, Mig6 LKO mice had improved hepatic glucose tolerance despite no improvements in whole-body insulin sensitivity or insulin secretion. Hepatic insulin signaling, measured by AKT activation, was similar between Mig6 LKO and littermate controls. However, several insulin-sensitive genes involved in gluconeogenesis were altered in Mig6 LKO mice compared to controls. In addition, Mig6 LKO mice had higher plasma high density lipoproteins and triglycerides despite similar liver lipid content. Using RNA sequencing we discovered Mig6 regulates several metabolic pathways in liver. These findings indicated Mig6 not only controls hepatic growth and survival but also regulates metabolism. This work will help us to better understand how augmented growth factor signaling impacts metabolic regulation during pathological obesity.Item Structural basis for regulated inhibition and substrate selection in yeast glycogen synthase(2017-02) Mahalingan, Krishna Kishore; Hurley, Thomas D.; Elmendorf, Jeffrey; Georgiadis, Millie M.; Roach, Peter J.Glycogen synthase (GS) is the rate limiting enzyme in the synthesis of glycogen. Eukaryotic GS catalyzes the transfer of glucose from UDP-glucose to the non-reducing ends of glycogen and its activity is negatively regulated by phosphorylation and allosterically activated by glucose-6-phosphate (G6P). A highly conserved cluster of six arginine residues on the C-terminal domain controls the responses toward these opposing signals. Previous studies had shown that tetrameric enzyme exists in three conformational states which are linked to specific structural changes in the regulatory helices that carry the cluster of arginines. These helices are found opposite and anti-parallel to one another at one of the subunit interfaces. The binding of G6P beneath the regulatory helices induces large scale conformational changes which open up the catalytic cleft for better substrate access. We solved the crystal structure of the enzyme in its inhibited state and found that the tetrameric and regulatory interfaces are more compacted compared to other states. The structural consequence of the tighter interfaces within the inhibited state of the tetramer is to lower the ability of glycogen chains to access to the catalytic cleft. Based on these observations, we developed a novel regulatory feature in yeast GS by substituting two of its conserved arginine residues on the regulatory helix with cysteines that permits its activity to be controlled by reversible oxidation/reduction of the cysteine residues which mimics the effects of reversible phosphorylation. In addition to defining the structural changes that give rise to the inhibited states, we also used X-ray crystallography to define the mechanism by which the enzyme discriminates between different UDP-sugar donors to be used as substrates in the catalytic mechanism of yeast GS. We found that only donor substrates can adopt the catalytically favorable bent conformation for donor transfer to a growing glycogen chain.