Browsing by Author "Roach, Peter J."
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Item Accurate and sensitive quantitation of glucose and glucose phosphates derived from storage carbohydrates by mass spectrometry(Elsevier, 2020-02-15) Young, Lyndsay E.A.; Brizzee, Corey O.; Macedo, Jessica K. A.; Murphy, Robert D.; Contreras, Christopher J.; DePaoli-Roach, Anna A.; Roach, Peter J.; Gentry, Matthew S.; Sun, Ramon C.; Biochemistry and Molecular Biology, School of MedicineThe addition of phosphate groups into glycogen modulates its branching pattern and solubility which all impact its accessibility to glycogen interacting enzymes. As glycogen architecture modulates its metabolism, it is essential to accurately evaluate and quantify its phosphate content. Simultaneous direct quantitation of glucose and its phosphate esters requires an assay with high sensitivity and a robust dynamic range. Herein, we describe a highly-sensitive method for the accurate detection of both glycogen-derived glucose and glucose-phosphate esters utilizing gas-chromatography coupled mass spectrometry. Using this method, we observed higher glycogen levels in the liver compared to skeletal muscle, but skeletal muscle contained many more phosphate esters. Importantly, this method can detect femtomole levels of glucose and glucose phosphate esters within an extremely robust dynamic range with excellent accuracy and reproducibility. The method can also be easily adapted for the quantification of plant starch, amylopectin or other biopolymers.Item Are there errors in glycogen biosynthesis and is laforin a repair enzyme?(Elsevier, 2011-10-20) Roach, Peter J.; Department of Biochemistry & Molecular Biology, IU School of MedicineGlycogen, a branched polymer of glucose, is well known as a cellular reserve of metabolic energy and/or biosynthetic precursors. Besides glucose, however, glycogen contains small amounts of covalent phosphate, present as C2 and C3 phosphomonoesters. Current evidence suggests that the phosphate is introduced by the biosynthetic enzyme glycogen synthase as a rare alternative to its normal catalytic addition of glucose units. The phosphate can be removed by the laforin phosphatase, whose mutation causes a fatal myoclonus epilepsy called Lafora disease. The hypothesis is that glycogen phosphorylation can be considered a catalytic error and laforin a repair enzyme.Item Brain glycogen serves as a critical glucosamine cache required for protein glycosylation(Elsevier, 2021) Sun, Ramon C.; Young, Lyndsay E.A.; Bruntz, Ronald C.; Markussen, Kia H.; Zhou, Zhengqiu; Conroy, Lindsey R.; Hawkinson, Tara R.; Clarke, Harrison A.; Stanback, Alexandra E.; Macedo, Jessica K.A.; Emanuelle, Shane; Brewer, M. Kathryn; Rondon, Alberto L.; Mestas, Annette; Sanders, William C.; Mahalingan, Krishna K.; Tang, Buyun; Chikwana, Vimbai M.; Segvich, Dyann M.; Contreras, Christopher J.; Allenger, Elizabeth J.; Brainson, Christine F.; Johnson, Lance A.; Taylor, Richard E.; Armstrong, Dustin D.; Shaffer, Robert; Waechter, Charles J.; Vander Kooi, Craig W.; DePaoli-Roach, Anna A.; Roach, Peter J.; Hurley, Thomas D.; Drake, Richard R.; Gentry, Matthew S.; Biochemistry and Molecular Biology, School of MedicineGlycosylation defects are a hallmark of many nervous system diseases. However, the molecular and metabolic basis for this pathology is not fully understood. In this study, we found that N-linked protein glycosylation in the brain is metabolically channeled to glucosamine metabolism through glycogenolysis. We discovered that glucosamine is an abundant constituent of brain glycogen, which functions as a glucosamine reservoir for multiple glycoconjugates. We demonstrated the enzymatic incorporation of glucosamine into glycogen by glycogen synthase, and the release by glycogen phosphorylase by biochemical and structural methodologies, in primary astrocytes, and in vivo by isotopic tracing and mass spectrometry. Using two mouse models of glycogen storage diseases, we showed that disruption of brain glycogen metabolism causes global decreases in free pools of UDP-N-acetylglucosamine and N-linked protein glycosylation. These findings revealed fundamental biological roles of brain glycogen in protein glycosylation with direct relevance to multiple human diseases of the central nervous system.Item COMPARATIVE ANALYSIS OF THE DISCORDANCE BETWEEN THE GLOBAL TRANSCRIPTIONAL AND PROTEOMIC RESPONSE OF THE YEAST SACCHAROMYCES CEREVISIAE TO DELETION OF THE F-BOX PROTEIN, GRR1(2010-05) Heyen, Joshua William; Goebl, Mark, 1958-; Roach, Peter J.; Clemmer, David E.; Wang, Mu; Chen, JakeThe Grr1 (Glucose Repression Resistant) protein in Saccharomyces cerevisiae is an F-box protein for the E3 ubiquitin ligase protein complex known as the SCFGrr1 (Skp, Cullin, F-box). F-box proteins serve as substrate receptors for this complex and in this capacity Grr1 serves to promote the ubiquitylation and subsequent proteasomal degradation of a number of intracellular protein substrates. Substrates of SCFGrr1 include the G1-S phase cyclins, Cln1 and Cln2, the Cdc42 effectors and cell polarity proteins, Gic1 and Gic2, the FCH-bar domain protein, Hof1, required for cytokinesis, the meiosis activating serine/threonine protein kinase, Ime2, the transcriptional regulators of glucose transporters, Mth1 and Std1, and the mitochondrial retrograde response inhibitor Mks1. Stabilization of these substrates lead to pleiotrophic phenotypic defects in grr1Δ strains including resistance to glucose repression, accumulation of grr1Δ cells in G2 and M phase of the cell cycle, sensitivity to osmotic stress, and resistance to divalent cations. However, many of these phenotypes are not reflected at the gene expression level. We conducted a quantitative genomic vii and proteomic comparison of 914 loci in a grr1Δ and wild-type strain grown to early log-phase in glucose media. These loci encompassed 16.7% of the Saccharomyces proteome of which 22.3% exhibited discordance between gene and protein expression. GO process enrichment analysis revealed that discordant loci were enriched in the processes of “trafficking”, “mitosis”, and “carbon/energy” metabolism. Here we show that these instances of discordance are biologically relevant and in fact reflect phenotypes of grr1Δ strains not evident at the transcriptional level. Additionally, through combined biochemical and network analysis of discordant loci among “carbon and energy metabolism” we were able to not only construct a model for central carbon metabolism in grr1Δ strains but also were able to elucidate a novel molecular event that may serve to regulate glucose repression of genes needed for respiration in response to changes in glucose concentration.Item Discovery and Development of Small-Molecule Inhibitors of Glycogen Synthase(ACS, 2020-03) Tang, Buyun; Frasinyuk, Mykhaylo S.; Chikwana, Vimbai M.; Mahalingan, Krishna K.; Morgan, Cynthia A.; Segvich, Dyann M.; Bondarenko, Svitlana P.; Mrug, Galyna P.; Wyrebek, Przemyslaw; Watt, David S.; DePaoli-Roach, Anna A.; Roach, Peter J.; Hurley, Thomas D.; Biochemistry and Molecular Biology, School of MedicineThe overaccumulation of glycogen appears as a hallmark in various glycogen storage diseases (GSDs), including Pompe, Cori, Andersen, and Lafora disease. Accumulating evidence suggests that suppression of glycogen accumulation represents a potential therapeutic approach for treating these GSDs. Using a fluorescence polarization assay designed to screen for inhibitors of the key glycogen synthetic enzyme, glycogen synthase (GS), we identified a substituted imidazole, (rac)-2-methoxy-4-(1-(2-(1-methylpyrrolidin-2-yl)ethyl)-4-phenyl-1H-imidazol-5-yl)phenol (H23), as a first-in-class inhibitor for yeast GS 2 (yGsy2p). Data from X-ray crystallography at 2.85 Å, as well as kinetic data, revealed that H23 bound within the uridine diphosphate glucose binding pocket of yGsy2p. The high conservation of residues between human and yeast GS in direct contact with H23 informed the development of around 500 H23 analogs. These analogs produced a structure–activity relationship profile that led to the identification of a substituted pyrazole, 4-(4-(4-hydroxyphenyl)-3-(trifluoromethyl)-1H-pyrazol-5-yl)pyrogallol, with a 300-fold improved potency against human GS. These substituted pyrazoles possess a promising scaffold for drug development efforts targeting GS activity in GSDs associated with excess glycogen accumulation.Item Discovery, Characterization, and Development of Small Molecule Inhibitors of Glycogen Synthase(2020-06) Tang, Buyun; Hurley, Thomas D.; Roach, Peter J.; Georgiadis, Millie M.; Johnson, Steven M.; Elmendorf, Jeffrey S.The over-accumulation of glycogen appears as a hallmark in various glycogen storage diseases (GSDs), including Pompe, Cori, Andersen, and Lafora disease. Glycogen synthase (GS) is the rate-limiting enzyme for glycogen synthesis. Recent evidence suggests that suppression of glycogen accumulation represents a potential therapeutic approach for treating these diseases. Herein, we describe the discovery, characterization, and development of small molecule inhibitors of GS through a multicomponent study including biochemical, biophysical, and cellular assays. Adopting an affinity-based fluorescence polarization assay, we identified a substituted imidazole molecule (H23), as a first-in-class inhibitor of yeast glycogen synthase 2 (yGsy2) from the 50,000 ChemBridge DIVERSet library. Structural data derived from X-ray crystallography at 2.85 Å, and enzyme kinetic data, revealed that H23 bound within the uridine diphosphate glucose binding pocket of yGsy2. Medicinal chemistry efforts examining over 500 H23 analogs produced structure-activity relationship (SAR) profiles that led to the identification of potent pyrazole and isoflavone compounds with low micromolar potency against human glycogen synthase 1 (hGYS1). Notably, several of the isoflavones demonstrated cellular efficacy toward suppressing glycogen accumulation. In an alternative effort to screen inhibitors directly against human GS, an activity-based assay was designed using a two-step colorimetric approach. This assay led to the identification of compounds with submicromolar potency to hGYS1 from a chemical library comprised of 10,000 compounds. One of the hit molecules, hexachlorophene, was crystallized bound to the active site of yGsy2. The structure was determined to 3.15 Å. Additional kinetic, mutagenic, and SAR studies validated the binding of hexachlorophene in the catalytic pocket and its non-competitive mode of inhibition. In summary, these two novel assays provided feasible biochemical platforms for large-scale screening of small molecule modulators of GS. The newly-developed, potent analogs possess diverse promising scaffolds for drug development efforts targeting GS activity in GSDs associated with excess glycogen accumulation.Item The effects of laforin, malin, Stbd1, and Ptg deficiencies on heart glycogen levels in Pompe disease mouse models(2015-08) Conway, Betsy Ann; Roach, Peter J.; DePaoli-Roach, Anna; Hurley, ThomasPompe disease (PD) is a rare metabolic myopathy characterized by loss of acid alpha-glucosidase (GAA), the enzyme responsible for breaking down glycogen to glucose within the lysosomes. PD cells accumulate massive quantities of glycogen within their lysosomes, and as such, PD is classified as a “lysosomal storage disease” (LSD). GAA-deficient cells also exhibit accumulation of autophagic debris. Symptoms of severe infantile PD include extreme muscle weakness, hypotonia, and hypertrophic cardiomyopathy, resulting in death before one year of age. Certain LSDs are currently being successfully treated with enzyme replacement therapy (ERT), which involves intravenous infusion of a recombinant enzyme to counteract the endogenous deficiency. ERT has been less successful in PD, however, due to ineffective delivery of the recombinant enzyme. Alternatively, specific genes deletion may reduce lysosomal glycogen load, and could thus be targeted in PD therapy development. Absence of malin (EPM2B) or laforin (EPM2A) has been proposed to impair autophagy, which could reduce lysosomal glycogen levels. Additionally, deficiency of Stbd1 has been postulated to disable lysosomal glycogen import. Furthermore, Ptg deficiency was previously reported to abrogate Lafora body formation and correct neurological abnormalities in Lafora disease mouse models and could have similar effects on PD pathologies. The goal of this study was to characterize the effects of homozygous disruption of Epm2a, Epm2b, Stbd1, and Ptg loci on total glycogen levels in PD mouse model heart tissue, as in severe infantile PD, it is accumulation of glycogen in the heart that results in fatal hypertrophic cardiomyopathy. Gaa-/- mice were intercrossed with Epm2a-/-, Epm2b-/-, Stbd1-/-, and Ptg-/- mice to generate wildtype (WT), single knockout, and double knockout mice. The results indicated that Gaa-/- hearts accumulated up to 100-fold more glycogen than the WT. These mice also displayed cardiac hypertrophy. However, deficiency of Epm2a, Epm2b, Stbd1, or PTG in the Gaa-/- background did not reveal changes of statistical significance in either heart glycogen or cardiac hypertrophy. Nevertheless, since total glycogen was measured, these deficiencies should not be discarded in future discussions of PD therapy, as increasing sample sizes and/or distinguishing cytosolic from lysosomal glycogen content may yet reveal differences of greater significance.Item Glycogen and its metabolism: some new developments and old themes(Portland Press Ltd., 2012-02-01) Roach, Peter J.; Depaoli-Roach, Anna A.; Hurley, Thomas D.; Tagliabracci, Vincent S.; Department of Biochemistry & Molecular Biology, IU School of MedicineGlycogen is a branched polymer of glucose that acts as a store of energy in times of nutritional sufficiency for utilization in times of need. Its metabolism has been the subject of extensive investigation and much is known about its regulation by hormones such as insulin, glucagon and adrenaline (epinephrine). There has been debate over the relative importance of allosteric compared with covalent control of the key biosynthetic enzyme, glycogen synthase, as well as the relative importance of glucose entry into cells compared with glycogen synthase regulation in determining glycogen accumulation. Significant new developments in eukaryotic glycogen metabolism over the last decade or so include: (i) three-dimensional structures of the biosynthetic enzymes glycogenin and glycogen synthase, with associated implications for mechanism and control; (ii) analyses of several genetically engineered mice with altered glycogen metabolism that shed light on the mechanism of control; (iii) greater appreciation of the spatial aspects of glycogen metabolism, including more focus on the lysosomal degradation of glycogen; and (iv) glycogen phosphorylation and advances in the study of Lafora disease, which is emerging as a glycogen storage disease.Item Glycogen Dynamics Drives Lipid Droplet Biogenesis during Brown Adipocyte Differentiation(Cell Press, 2019-11-05) Mayeuf-Louchart, Alicia; Lancel, Steve; Sebti, Yasmine; Pourcet, Benoit; Loyens, Anne; Delhaye, Stéphane; Duhem, Christian; Beauchamp, Justine; Ferri, Lise; Thorel, Quentin; Boulinguiez, Alexis; Zecchin, Mathilde; Dubois-Chevalier, Julie; Eeckhoute, Jérôme; Vaughn, Logan T.; Roach, Peter J.; Dani, Christian; Pederson, Bartholomew A.; Vincent, Stéphane D.; Staels, Bart; Duez, Hélène; Biochemistry and Molecular Biology, School of MedicineBrowning induction or transplantation of brown adipose tissue (BAT) or brown/beige adipocytes derived from progenitor or induced pluripotent stem cells (iPSCs) can represent a powerful strategy to treat metabolic diseases. However, our poor understanding of the mechanisms that govern the differentiation and activation of brown adipocytes limits the development of such therapy. Various genetic factors controlling the differentiation of brown adipocytes have been identified, although most studies have been performed using in vitro cultured pre-adipocytes. We investigate here the differentiation of brown adipocytes from adipose progenitors in the mouse embryo. We demonstrate that the formation of multiple lipid droplets (LDs) is initiated within clusters of glycogen, which is degraded through glycophagy to provide the metabolic substrates essential for de novo lipogenesis and LD formation. Therefore, this study uncovers the role of glycogen in the generation of LDs.Item Glycogen metabolism in Lafora disease(2018-02) Contreras, Christopher J.; Roach, Peter J.; DePaoli-Roach, Anna A.; Hurley, Thomas D.; Herring, B. PaulGlycogen, a branched polymer of glucose, serves as an osmotically neutral means of storing glucose. Covalent phosphate is a trace component of mammalian glycogen and has been a point of interest with respect to Lafora disease, a fatal form of juvenile myoclonus epilepsy. Mutations in either the EPM2A or EPM2B genes, which encode laforin and malin respectively, account for ~90% of disease cases. A characteristic of Lafora disease is the formation of Lafora bodies, which are mainly composed of an excess amount of abnormal glycogen that is poorly branched and insoluble. Laforin-/- and malin-/- knockout mice share several characteristics of the human disease, formation of Lafora bodies in various tissues, increased glycogen phosphorylation and development of neurological symptoms. The source of phosphate in glycogen has been an area of interest and here we provide evidence that glycogen synthase is capable of incorporating phosphate into glycogen. Mice lacking the glycogen targeting subunit PTG of the PP1 protein phosphatase have decreased glycogen stores in a number of tissues. When crossed with mice lacking either laforin or malin, the double knockout mice no longer over-accumulate glycogen, Lafora body formation is almost absent and the neurological disorders are normalized. Another question has been whether the abnormal glycogen in the Lafora disease mouse models can be metabolized. Using exercise to provoke glycogen degradation, we show that in laforin-/- and malin-/- mice the insoluble, abnormal glycogen appears to be metabolically inactive. These studies suggest that a therapeutic approach to Lafora disease may be to reduce the overall glycogen levels in cells so that insoluble, metabolically inert pools of the polysaccharide do not accumulate.