Browsing by Subject "Glycogen"

Now showing 1 - 10 of 24
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    The 5th International Lafora Epilepsy Workshop: Basic science elucidating therapeutic options and preparing for therapies in the clinic
    (Elsevier, 2020-02) Gentry, Matthew S.; Afawi, Zaid; Armstrong, Dustin D.; Delgado-Escueta, Antonio; Goldberg, Y. Paul; Grossman, Tamar R.; Guinovart, Joan J.; Harris, Frank; Hurley, Thomas D.; Michelucci, Roberto; Minassian, Berge A.; Sanz, Pascual; Worby, Carolyn A.; Serratosa, Jose M.; Biochemistry and Molecular Biology, School of Medicine
    Lafora disease (LD) is both a fatal childhood epilepsy and a glycogen storage disease caused by recessive mutations in either the Epilepsy progressive myoclonus 2A (EPM2A) or EPM2B genes. Hallmarks of LD are aberrant, cytoplasmic carbohydrate aggregates called Lafora bodies (LBs) that are a disease driver. The 5th International Lafora Epilepsy Workshop was recently held in Alcala de Henares, Spain. The workshop brought together nearly 100 clinicians, academic and industry scientists, trainees, National Institutes of Health (NIH) representation, and friends and family members of patients with LD. The workshop covered aspects of LD ranging from defining basic scientific mechanisms to elucidating a LD therapy or cure and a recently launched LD natural history study.
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    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 Medicine
    The 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.
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    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 Medicine
    Glycogen, 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.
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    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 Medicine
    Glycogen 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.
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    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 Medicine
    Browning 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.
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    Glycogen metabolism in Lafora disease
    (2018-02) Contreras, Christopher J.; Roach, Peter J.; DePaoli-Roach, Anna A.; Hurley, Thomas D.; Herring, B. Paul
    Glycogen, 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.
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    Glycogen phosphorylation and Lafora disease
    (Elsevier, 2015-12) Roach, Peter J.; Department of Biochemistry & Molecular Biology, IU School of Medicine
    Covalent phosphorylation of glycogen, first described 35 years ago, was put on firm ground through the work of the Whelan laboratory in the 1990s. But glycogen phosphorylation lay fallow until interest was rekindled in the mid 2000s by the finding that it could be removed by a glycogen-binding phosphatase, laforin, and that mutations in laforin cause a fatal teenage-onset epilepsy, called Lafora disease. Glycogen phosphorylation is due to phosphomonoesters at C2, C3 and C6 of glucose residues. Phosphate is rare, ranging from 1:500 to 1:5000 phosphates/glucose depending on the glycogen source. The mechanisms of glycogen phosphorylation remain under investigation but one hypothesis to explain C2 and perhaps C3 phosphate is that it results from a rare side reaction of the normal synthetic enzyme glycogen synthase. Lafora disease is likely caused by over-accumulation of abnormal glycogen in insoluble deposits termed Lafora bodies in neurons. The abnormality in the glycogen correlates with elevated phosphorylation (at C2, C3 and C6), reduced branching, insolubility and an enhanced tendency to aggregate and become insoluble. Hyperphosphorylation of glycogen is emerging as an important feature of this deadly childhood disease.
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    A highly prevalent equine glycogen storage disease is explained by constitutive activation of a mutant glycogen synthase
    (Elsevier, 2017-01) Maile, C.A.; Hingst, J. R.; Mahalingan, K. K.; O'Reilly, A. O.; Cleasby, M. E.; Mickelson, J. R.; McCue, M. E.; Anderson, S. M.; Hurley, T. D.; Wojtaszewski, J. F. P.; Piercy, R. J.; Biochemistry and Molecular Biology, School of Medicine
    BACKGROUND: Equine type 1 polysaccharide storage myopathy (PSSM1) is associated with a missense mutation (R309H) in the glycogen synthase (GYS1) gene, enhanced glycogen synthase (GS) activity and excessive glycogen and amylopectate inclusions in muscle. METHODS: Equine muscle biochemical and recombinant enzyme kinetic assays in vitro and homology modelling in silico, were used to investigate the hypothesis that higher GS activity in affected horse muscle is caused by higher GS expression, dysregulation, or constitutive activation via a conformational change. RESULTS: PSSM1-affected horse muscle had significantly higher glycogen content than control horse muscle despite no difference in GS expression. GS activity was significantly higher in muscle from homozygous mutants than from heterozygote and control horses, in the absence and presence of the allosteric regulator, glucose 6 phosphate (G6P). Muscle from homozygous mutant horses also had significantly increased GS phosphorylation at sites 2+2a and significantly higher AMPKα1 (an upstream kinase) expression than controls, likely reflecting a physiological attempt to reduce GS enzyme activity. Recombinant mutant GS was highly active with a considerably lower Km for UDP-glucose, in the presence and absence of G6P, when compared to wild type GS, and despite its phosphorylation. CONCLUSIONS: Elevated activity of the mutant enzyme is associated with ineffective regulation via phosphorylation rendering it constitutively active. Modelling suggested that the mutation disrupts a salt bridge that normally stabilises the basal state, shifting the equilibrium to the enzyme's active state. GENERAL SIGNIFICANCE: This study explains the gain of function pathogenesis in this highly prevalent polyglucosan myopathy.