Your search keyword '"Anna A. Depaoli‐Roach"' showing total 138 results

1. The structural mechanism of human glycogen synthesis by the GYS1-GYG1 complex

Author

Nathan M. Fastman, Yuxi Liu, Vyas Ramanan, Hanne Merritt, Eileen Ambing, Anna A. DePaoli-Roach, Peter J. Roach, Thomas D. Hurley, Kevin T. Mellem, Julie C. Ullman, Eric Green, David Morgans, Jr., and Christos Tzitzilonis

Subjects

CP: Molecular biology, Biology (General), QH301-705.5

Abstract

Summary: Glycogen is the primary energy reserve in mammals, and dysregulation of glycogen metabolism can result in glycogen storage diseases (GSDs). In muscle, glycogen synthesis is initiated by the enzymes glycogenin-1 (GYG1), which seeds the molecule by autoglucosylation, and glycogen synthase-1 (GYS1), which extends the glycogen chain. Although both enzymes are required for proper glycogen production, the nature of their interaction has been enigmatic. Here, we present the human GYS1:GYG1 complex in multiple conformations representing different functional states. We observe an asymmetric conformation of GYS1 that exposes an interface for close GYG1 association, and propose this state facilitates handoff of the GYG1-associated glycogen chain to a GYS1 subunit for elongation. Full activation of GYS1 widens the GYG1-binding groove, enabling GYG1 release concomitant with glycogen chain growth. This structural mechanism connecting chain nucleation and extension explains the apparent stepwise nature of glycogen synthesis and suggests distinct states to target for GSD-modifying therapeutics.

Published

2022

2. GYS1 or PPP1R3C deficiency rescues murine adult polyglucosan body disease

Author

Erin E. Chown, Peixiang Wang, Xiaochu Zhao, Justin J. Crowder, Jordan W. Strober, Mitchell A. Sullivan, Yunlin Xue, Cody S. Bennett, Ami M. Perri, Bret M. Evers, Peter J. Roach, Anna A. Depaoli‐Roach, H. Orhan Akman, Bartholomew A. Pederson, and Berge A. Minassian

Subjects

Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571, Neurology. Diseases of the nervous system, RC346-429

Abstract

Abstract Objective Adult polyglucosan body disease (APBD) is an adult‐onset neurological variant of glycogen storage disease type IV. APBD is caused by recessive mutations in the glycogen branching enzyme gene, and the consequent accumulation of poorly branched glycogen aggregates called polyglucosan bodies in the nervous system. There are presently no treatments for APBD. Here, we test whether downregulation of glycogen synthesis is therapeutic in a mouse model of the disease. Methods We characterized the effects of knocking out two pro‐glycogenic proteins in an APBD mouse model. APBD mice were crossed with mice deficient in glycogen synthase (GYS1), or mice deficient in protein phosphatase 1 regulatory subunit 3C (PPP1R3C), a protein involved in the activation of GYS1. Phenotypic and histological parameters were analyzed and glycogen was quantified. Results APBD mice deficient in GYS1 or PPP1R3C demonstrated improvements in life span, morphology, and behavioral assays of neuromuscular function. Histological analysis revealed a reduction in polyglucosan body accumulation and of astro‐ and micro‐gliosis in the brains of GYS1‐ and PPP1R3C‐deficient APBD mice. Brain glycogen quantification confirmed the reduction in abnormal glycogen accumulation. Analysis of skeletal muscle, heart, and liver found that GYS1 deficiency reduced polyglucosan body accumulation in all three tissues and PPP1R3C knockout reduced skeletal muscle polyglucosan bodies. Interpretation GYS1 and PPP1R3C are effective therapeutic targets in the APBD mouse model. These findings represent a critical step toward the development of a treatment for APBD and potentially other glycogen storage disease type IV patients.

Published

2020

3. Pathologic gene network rewiring implicates PPP1R3A as a central regulator in pressure overload heart failure

Author

Pablo Cordero, Victoria N. Parikh, Elizabeth T. Chin, Ayca Erbilgin, Michael J. Gloudemans, Ching Shang, Yong Huang, Alex C. Chang, Kevin S. Smith, Frederick Dewey, Kathia Zaleta, Michael Morley, Jeff Brandimarto, Nicole Glazer, Daryl Waggott, Aleksandra Pavlovic, Mingming Zhao, Christine S. Moravec, W. H. Wilson Tang, Jamie Skreen, Christine Malloy, Sridhar Hannenhalli, Hongzhe Li, Scott Ritter, Mingyao Li, Daniel Bernstein, Andrew Connolly, Hakon Hakonarson, Aldons J. Lusis, Kenneth B. Margulies, Anna A. Depaoli-Roach, Stephen B. Montgomery, Matthew T. Wheeler, Thomas Cappola, and Euan A. Ashley

Subjects

Science

Abstract

The genetic and pathogenetic basis of heart failure is incompletely understood. Here, the authors present a high-fidelity tissue collection from rapidly preserved failing and non-failing control hearts which are used for eQTL mapping and network analysis, resulting in the prioritization of PPP1R3A as a heart failure gene.

Published

2019

4. Neuron-astrocyte metabolic coupling facilitates spinal plasticity and maintenance of persistent pain

Author

Sebastián Marty-Lombardi, Shiying Lu, Wojciech Ambroziak, Hagen Wende, Katrin Schrenk-Siemens, Anna A. DePaoli-Roach, Anna M. Hagenston, Anke Tappe-Theodor, Manuela Simonetti, Rohini Kuner, Thomas Fleming, and Jan Siemens

Abstract

Long-lasting pain stimuli can trigger maladaptive changes in the spinal cord, reminiscent of plasticity associated with memory formation. Metabolic coupling between astrocytes and neurons has been implicated in neuronal plasticity and memory formation in the CNS, but neither its involvement in pathological pain nor in spinal plasticity has been tested. Here, we report a novel form of neuroglia signaling involving spinal astrocytic glycogen dynamics triggered by persistent noxious stimulation via upregulation of the metabolic signaling molecule PTG exclusively in spinal astrocytes. PTG drove glycogen build-up in astrocytes, and blunting glycogen accumulation and turnover byPtggene deletion reduced pain-related behaviors and promoted faster recovery by shortening pain maintenance. Furthermore, mechanistic analyses revealed that glycogen dynamics is a critically required process for maintenance of pain by facilitating neuronal plasticity in spinal lamina 1 neurons. Finally, metabolic analysis indicated that glycolysis and lactate transfer between astrocytes and neurons fuels spinal neuron hyperexcitability.Spinal glycogen-metabolic cascades therefore hold therapeutic potential to alleviate pathological pain.

Published

2022

5. GYS1 or PPP1R3C deficiency rescues murine adult polyglucosan body disease

Author

Justin J. Crowder, Erin E. Chown, Bret M. Evers, Mitchell A. Sullivan, Jordan W. Strober, Bartholomew A. Pederson, Peter J. Roach, Berge A. Minassian, Cody S. Bennett, Xiaochu Zhao, Anna A. DePaoli-Roach, H. Orhan Akman, Ami M. Perri, Yunlin Xue, and Peixiang Wang

Subjects

0301 basic medicine, medicine.medical_specialty, Neurosciences. Biological psychiatry. Neuropsychiatry, 03 medical and health sciences, chemistry.chemical_compound, Mice, 0302 clinical medicine, Downregulation and upregulation, Internal medicine, medicine, Glycogen branching enzyme, Animals, Glycogen storage disease type IV, Glycogen synthase, RC346-429, Research Articles, Mice, Knockout, biology, Glycogen, Behavior, Animal, business.industry, General Neuroscience, Intracellular Signaling Peptides and Proteins, Skeletal muscle, Protein phosphatase 1, Adult polyglucosan body disease, medicine.disease, Glycogen Storage Disease, Disease Models, Animal, 030104 developmental biology, Endocrinology, medicine.anatomical_structure, Glycogen Synthase, chemistry, biology.protein, Neurology (clinical), Neurology. Diseases of the nervous system, Nervous System Diseases, business, 030217 neurology & neurosurgery, Research Article, RC321-571

Abstract

Objective Adult polyglucosan body disease (APBD) is an adult‐onset neurological variant of glycogen storage disease type IV. APBD is caused by recessive mutations in the glycogen branching enzyme gene, and the consequent accumulation of poorly branched glycogen aggregates called polyglucosan bodies in the nervous system. There are presently no treatments for APBD. Here, we test whether downregulation of glycogen synthesis is therapeutic in a mouse model of the disease. Methods We characterized the effects of knocking out two pro‐glycogenic proteins in an APBD mouse model. APBD mice were crossed with mice deficient in glycogen synthase (GYS1), or mice deficient in protein phosphatase 1 regulatory subunit 3C (PPP1R3C), a protein involved in the activation of GYS1. Phenotypic and histological parameters were analyzed and glycogen was quantified. Results APBD mice deficient in GYS1 or PPP1R3C demonstrated improvements in life span, morphology, and behavioral assays of neuromuscular function. Histological analysis revealed a reduction in polyglucosan body accumulation and of astro‐ and micro‐gliosis in the brains of GYS1‐ and PPP1R3C‐deficient APBD mice. Brain glycogen quantification confirmed the reduction in abnormal glycogen accumulation. Analysis of skeletal muscle, heart, and liver found that GYS1 deficiency reduced polyglucosan body accumulation in all three tissues and PPP1R3C knockout reduced skeletal muscle polyglucosan bodies. Interpretation GYS1 and PPP1R3C are effective therapeutic targets in the APBD mouse model. These findings represent a critical step toward the development of a treatment for APBD and potentially other glycogen storage disease type IV patients.

Published

2020

6. Discovery and Development of Small-Molecule Inhibitors of Glycogen Synthase

Author

David S. Watt, Thomas D. Hurley, Mykhaylo S. Frasinyuk, Peter J. Roach, Dyann M. Segvich, Krishna K. Mahalingan, Vimbai M. Chikwana, Cynthia A. Morgan, S. P. Bondarenko, Przemyslaw Wyrebek, Galyna P. Mrug, Anna A. DePaoli-Roach, and Buyun Tang

Subjects

congenital, hereditary, and neonatal diseases and abnormalities, Saccharomyces cerevisiae, Crystallography, X-Ray, 01 natural sciences, Article, Lafora disease, Structure-Activity Relationship, 03 medical and health sciences, chemistry.chemical_compound, Drug Discovery, medicine, Animals, Humans, Enzyme Inhibitors, Caenorhabditis elegans, Glycogen synthase, 030304 developmental biology, 0303 health sciences, Molecular Structure, biology, Glycogen, Imidazoles, medicine.disease, Small molecule, 0104 chemical sciences, Kinetics, 010404 medicinal & biomolecular chemistry, Glycogen Synthase, HEK293 Cells, Biochemistry, chemistry, biology.protein, Pyrazoles, Molecular Medicine, Transferase inhibitor, Protein Binding

Abstract

The over-accumulation 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 glycogen synthase 2 (yGsy2p). Data from X-ray crystallography at 2.85 Å, as well as kinetic data, revealed that H23 bound within the UDP-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 (SAR) profile that led to the identification of a substituted pyrazole, 4-(4-(4-hydroxyphenyl)-3-(trifluoromethyl)-1H-pyrazol-5-yl)pyrogallol, with 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.

Published

2020

7. Brain glycogen serves as a critical glucosamine cache required for protein glycosylation

Author

Harrison A. Clarke, Craig W. Vander Kooi, Dustin D. Armstrong, Anna A. DePaoli-Roach, Richard R. Drake, Kia H. Markussen, Richard E. Taylor, Jessica K. A. Macedo, Lyndsay E.A. Young, Lindsey R. Conroy, Charles J. Waechter, Matthew S. Gentry, Ronald C. Bruntz, Ramon C. Sun, Christine Fillmore Brainson, Alexandra E. Stanback, Buyun Tang, William C. Sanders, Shane Emanuelle, Dyann M. Segvich, Elizabeth J. Allenger, M. Kathryn Brewer, Peter J. Roach, Krishna K. Mahalingan, Robert Shaffer, Annette Mestas, Vimbai M. Chikwana, Zhengqiu Zhou, Thomas D. Hurley, Tara R. Hawkinson, Alberto Rondon, Christopher J. Contreras, and Lance A. Johnson

Subjects

0301 basic medicine, Male, Glycosylation, Glycogenolysis, Physiology, Article, 03 medical and health sciences, chemistry.chemical_compound, Glycogen phosphorylase, Mice, 0302 clinical medicine, N-linked glycosylation, Glucosamine, medicine, Glycogen storage disease, Animals, Glycogen synthase, Molecular Biology, Cells, Cultured, Mice, Knockout, Glycogen, biology, Brain, Cell Biology, medicine.disease, carbohydrates (lipids), Mice, Inbred C57BL, Disease Models, Animal, 030104 developmental biology, Glycogen Synthase, chemistry, Biochemistry, Lafora Disease, biology.protein, Female, Protein Processing, Post-Translational, 030217 neurology & neurosurgery

Abstract

Summary Glycosylation 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.

Published

2020

8. Correction: A Prevalent Variant in Impairs Glycogen Synthesis and Reduces Muscle Glycogen Content in Humans and Mice.

Author

David B Savage, Lanmin Zhai, Balasubramanian Ravikumar, Cheol Soo Choi, Johanna E Snaar, Amanda C McGuire, Sung-Eun Wou, Gemma Medina-Gomez, Sheene Kim, Cheryl B Bock, Dyann M Segvich, Bhavana Solanky, Dinesh Deelchand, Antonio Vidal-Puig, Nicholas J Wareham, Gerald I Shulman, Fredrik Karpe, Roy Taylor, Bartholomew A Pederson, Peter J Roach, Stephen O'Rahilly, and Anna A DePaoli-Roach

Subjects

Medicine

Published

2008

9. A prevalent variant in PPP1R3A impairs glycogen synthesis and reduces muscle glycogen content in humans and mice.

Author

David B Savage, Lanmin Zhai, Balasubramanian Ravikumar, Cheol Soo Choi, Johanna E Snaar, Amanda C McGuire, Sung-Eun Wou, Gemma Medina-Gomez, Sheene Kim, Cheryl B Bock, Dyann M Segvich, Bhavana Solanky, Dinesh Deelchand, Antonio Vidal-Puig, Nicholas J Wareham, Gerald I Shulman, Fredrik Karpe, Roy Taylor, Bartholomew A Pederson, Peter J Roach, Stephen O'Rahilly, and Anna A DePaoli-Roach

Subjects

Medicine

Abstract

Stored glycogen is an important source of energy for skeletal muscle. Human genetic disorders primarily affecting skeletal muscle glycogen turnover are well-recognised, but rare. We previously reported that a frameshift/premature stop mutation in PPP1R3A, the gene encoding RGL, a key regulator of muscle glycogen metabolism, was present in 1.36% of participants from a population of white individuals in the UK. However, the functional implications of the mutation were not known. The objective of this study was to characterise the molecular and physiological consequences of this genetic variant.In this study we found a similar prevalence of the variant in an independent UK white population of 744 participants (1.46%) and, using in vivo (13)C magnetic resonance spectroscopy studies, demonstrate that human carriers (n = 6) of the variant have low basal (65% lower, p = 0.002) and postprandial muscle glycogen levels. Mice engineered to express the equivalent mutation had similarly decreased muscle glycogen levels (40% lower in heterozygous knock-in mice, p < 0.05). In muscle tissue from these mice, failure of the truncated mutant to bind glycogen and colocalize with glycogen synthase (GS) decreased GS and increased glycogen phosphorylase activity states, which account for the decreased glycogen content.Thus, PPP1R3A C1984DeltaAG (stop codon 668) is, to our knowledge, the first prevalent mutation described that directly impairs glycogen synthesis and decreases glycogen levels in human skeletal muscle. The fact that it is present in approximately 1 in 70 UK whites increases the potential biomedical relevance of these observations.

Published

2008

10. Targeting pathogenic Lafora bodies in Lafora disease using an antibody-enzyme fusion

Author

Grant L. Austin, John J. McCarthy, Annette Uittenbogaard, Jill Zeller, Tracy R. McKnight, Anna A. DePaoli-Roach, Dustin Armstrong, Dyann M. Segvich, M. Kathryn Brewer, James R. Pauly, Bradley L. Hodges, Matthew S. Gentry, and Peter J. Roach

Subjects

0303 health sciences, biology, Glycogen, Neurodegeneration, medicine.disease, Lafora disease, 3. Good health, Ubiquitin ligase, 03 medical and health sciences, Epilepsy, chemistry.chemical_compound, 0302 clinical medicine, chemistry, medicine, biology.protein, Cancer research, Antibody, Glycogen synthase, Laforin, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Lafora disease (LD) is a fatal childhood epilepsy and a non-classical glycogen storage disorder with no effective therapy or cure. LD is caused by recessive mutations in theEPM2AorEPM2Bgenes that encode the glycogen phosphatase laforin and an E3 ubiquitin ligase malin, respectively. A hallmark of LD is the intracellular accumulation of abnormal and insoluble α-linked polysaccharide deposits known as Lafora bodies (LBs) in several tissues, including most regions of the brain. In mouse models of LD, genetic reduction of glycogen synthesis eliminates LB formation and rescues the neurological phenotype. Since multiple groups have confirmed that neurodegeneration and epilepsy result from LB accumulation, a major focus in the field has shifted toward the development of therapies that reduce glycogen synthesis or target LBs for degradation with the goal of treating LD. Herein, we identify the optimal enzymes for degrading LBs, and we develop a novel therapeutic agent by fusing human pancreatic α-amylase to a cellpenetrating antibody fragment. This antibody-enzyme fusion (VAL-0417) degrades LBsin vitro, shows robust cellular uptake, and significantly reduces the LB loadin vivoinEpm2a-/- mice. VAL-0417 is a promising therapeutic for the treatment of LD and a putative precision therapy for an intractable epilepsy. Antibody-enzyme fusions represent a new class of antibody-based drugs that could be utilized to treat glycogen storage disorders and other diseases.One Sentence SummaryAn antibody-enzyme fusion delivering an amylase degrades the toxic polyglucosan bodies that cause Lafora disease, a fatal childhood epilepsy.

Published

2019

11. Pathologic gene network rewiring implicates PPP1R3A as a central regulator in pressure overload heart failure

Author

Alex C.Y. Chang, Ching Shang, Hongzhe Li, Christine S. Moravec, Christine Malloy, Thomas P. Cappola, Stephen B. Montgomery, Pablo Cordero, Daniel Bernstein, Anna A. DePaoli-Roach, Euan A. Ashley, Sridhar Hannenhalli, Andrew C. Connolly, Michael Morley, Kenneth B. Margulies, Yong Huang, Frederick Dewey, Kevin S. Smith, Hakon Hakonarson, Daryl Waggott, Aldons J. Lusis, Jamie Skreen, Kathia Zaleta, Aleksandra Pavlovic, Scott Ritter, Nicole L. Glazer, Jeff Brandimarto, Elizabeth T Chin, Mingming Zhao, Ayca Erbilgin, W.H. Wilson Tang, Victoria N. Parikh, Matthew T. Wheeler, Michael J. Gloudemans, and Mingyao Li

Subjects

0301 basic medicine, Male, Pyridines, Gene regulatory network, Regulator, Benzeneacetamides, General Physics and Astronomy, Datasets as Topic, Genome-wide association study, 02 engineering and technology, Cardiovascular, Rats, Sprague-Dawley, Mice, Phosphoprotein Phosphatases, 2.1 Biological and endogenous factors, Gene Regulatory Networks, Myocytes, Cardiac, Aetiology, lcsh:Science, Cells, Cultured, Regulator gene, Regulation of gene expression, Mice, Knockout, Cultured, Multidisciplinary, Middle Aged, 021001 nanoscience & nanotechnology, 3. Good health, Heart Disease, Gene Knockdown Techniques, Female, 0210 nano-technology, Cardiac, Sequence Analysis, Metabolic Networks and Pathways, Biotechnology, Cellular signalling networks, Science, Cells, Knockout, Primary Cell Culture, Quantitative Trait Loci, Heart failure, Computational biology, Biology, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, Gene interaction, Genetics, medicine, Animals, Humans, Heart Failure, Myocytes, Animal, Sequence Analysis, RNA, Gene Expression Profiling, Human Genome, General Chemistry, Cardiovascular genetics, medicine.disease, Rats, Disease Models, Animal, Good Health and Well Being, 030104 developmental biology, Gene Expression Regulation, Disease Models, Expression quantitative trait loci, RNA, lcsh:Q, Sprague-Dawley, Gene expression, Genome-Wide Association Study

Abstract

Heart failure is a leading cause of mortality, yet our understanding of the genetic interactions underlying this disease remains incomplete. Here, we harvest 1352 healthy and failing human hearts directly from transplant center operating rooms, and obtain genome-wide genotyping and gene expression measurements for a subset of 313. We build failing and non-failing cardiac regulatory gene networks, revealing important regulators and cardiac expression quantitative trait loci (eQTLs). PPP1R3A emerges as a regulator whose network connectivity changes significantly between health and disease. RNA sequencing after PPP1R3A knockdown validates network-based predictions, and highlights metabolic pathway regulation associated with increased cardiomyocyte size and perturbed respiratory metabolism. Mice lacking PPP1R3A are protected against pressure-overload heart failure. We present a global gene interaction map of the human heart failure transition, identify previously unreported cardiac eQTLs, and demonstrate the discovery potential of disease-specific networks through the description of PPP1R3A as a central regulator in heart failure., The genetic and pathogenetic basis of heart failure is incompletely understood. Here, the authors present a high-fidelity tissue collection from rapidly preserved failing and non-failing control hearts which are used for eQTL mapping and network analysis, resulting in the prioritization of PPP1R3A as a heart failure gene.

Published

2019

12. Redox Switch for the Inhibited State of Yeast Glycogen Synthase Mimics Regulation by Phosphorylation

Author

Sulochanadevi Baskaran, Anna A. DePaoli-Roach, Krishna K. Mahalingan, Peter J. Roach, and Thomas D. Hurley

Subjects

Models, Molecular, Uridine Diphosphate Glucose, 0301 basic medicine, Saccharomyces cerevisiae Proteins, Mutant, Glucose-6-Phosphate, Saccharomyces cerevisiae, Crystallography, X-Ray, Biochemistry, Protein Structure, Secondary, Article, 03 medical and health sciences, chemistry.chemical_compound, Protein Domains, Glycogen branching enzyme, Cysteine, Phosphorylation, Glycogen synthase, Cysteine metabolism, chemistry.chemical_classification, 030102 biochemistry & molecular biology, Glycogen, biology, Enzyme Activation, Kinetics, Glycogen Synthase, 030104 developmental biology, Enzyme, chemistry, Mutation, biology.protein, Protein Multimerization, Crystallization, Oxidation-Reduction

Abstract

Glycogen synthase (GS) is the rate limiting enzyme in the synthesis of glycogen. Eukaryotic GS is negatively regulated by covalent phosphorylation and allosterically activated by glucose-6-phosphate (G-6-P). To gain structural insights into the inhibited state of the enzyme, we solved the crystal structure of yGsy2-R589A/R592A to a resolution of 3.3 Å. The double mutant has an activity ratio similar to the phosphorylated enzyme and also retains the ability to be activated by G-6-P. When compared to the 2.88 Å structure of the wild-type G-6-P activated enzyme, the crystal structure of the low-activity mutant showed that the N-terminal domain of the inhibited state is tightly held against the dimer-related interface thereby hindering acceptor access to the catalytic cleft. On the basis of these two structural observations, we developed a reversible redox regulatory feature in yeast GS by substituting cysteine residues for two highly conserved arginine residues. When oxidized, the cysteine mutant enzyme exhibits activity levels similar to the phosphorylated enzyme but cannot be activated by G-6-P. Upon reduction, the cysteine mutant enzyme regains normal activity levels and regulatory response to G-6-P activation.

Published

2016

13. Protein targeting to glycogen is a master regulator of glycogen synthesis in astrocytes

Author

E. Ruchti, Anna A. DePaoli-Roach, Igor Allaman, Peter J. Roach, and Pierre J. Magistretti

Subjects

0301 basic medicine, medicine.medical_specialty, Cell type, medicine.medical_treatment, Carbohydrate metabolism, Article, lcsh:RC321-571, 03 medical and health sciences, chemistry.chemical_compound, Glycogen phosphorylase, 0302 clinical medicine, Downregulation and upregulation, Internal medicine, Glia, medicine, Insulin, Neurotransmitter, Glycogen synthase, Ins, Insulin, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Glucose metabolism, biology, Glycogen, NA, Noradrenaline, General Neuroscience, PTG, Protein targeting to glycogen, GS, Glycogen synthase, 030104 developmental biology, Endocrinology, chemistry, biology.protein, Noradrenaline, GP, Glycogen phosphorylase, 030217 neurology & neurosurgery

Abstract

The storage and use of glycogen, the main energy reserve in the brain, is a metabolic feature of astrocytes. Glycogen synthesis is regulated by Protein Targeting to Glycogen (PTG), a member of specific glycogen-binding subunits of protein phosphatase-1 (PPP1). It positively regulates glycogen synthesis through de-phosphorylation of both glycogen synthase (activation) and glycogen phosphorylase (inactivation). In cultured astrocytes, PTG mRNA levels were previously shown to be enhanced by the neurotransmitter noradrenaline. To achieve further insight into the role of PTG in the regulation of astrocytic glycogen, its levels of expression were manipulated in primary cultures of mouse cortical astrocytes using adenovirus-mediated overexpression of tagged-PTG or siRNA to downregulate its expression. Infection of astrocytes with adenovirus led to a strong increase in PTG expression and was associated with massive glycogen accumulation (>100 fold), demonstrating that increased PTG expression is sufficient to induce glycogen synthesis and accumulation. In contrast, siRNA-mediated downregulation of PTG resulted in a 2-fold decrease in glycogen levels. Interestingly, PTG downregulation strongly impaired long-term astrocytic glycogen synthesis induced by insulin or noradrenaline. Finally, these effects of PTG downregulation on glycogen metabolism could also be observed in cultured astrocytes isolated from PTG-KO mice. Collectively, these observations point to a major role of PTG in the regulation of glycogen synthesis in astrocytes and indicate that conditions leading to changes in PTG expression will directly impact glycogen levels in this cell type.

Published

2016

14. Incorporation of phosphate into glycogen by glycogen synthase

Author

Peter J. Roach, Christopher J. Contreras, Anna A. DePaoli-Roach, Thomas D. Hurley, Terence L. Kirley, Dyann M. Segvich, Krishna K. Mahalingan, and Vimbai M. Chikwana

Subjects

0301 basic medicine, Saccharomyces cerevisiae Proteins, Biophysics, Saccharomyces cerevisiae, Biochemistry, Article, Phosphates, Glycogen debranching enzyme, 03 medical and health sciences, chemistry.chemical_compound, Glycogen phosphorylase, 0302 clinical medicine, Glycogen branching enzyme, Humans, Glycogen synthase, Phosphorylase kinase, Molecular Biology, biology, Glycogen, Protein Tyrosine Phosphatases, Non-Receptor, Uridine Diphosphate Sugars, Glycogen Synthase, 030104 developmental biology, chemistry, Glycogenesis, biology.protein, Laforin, 030217 neurology & neurosurgery

Abstract

The storage polymer glycogen normally contains small amounts of covalently attached phosphate as phosphomonoesters at C2, C3 and C6 atoms of glucose residues. In the absence of the laforin phosphatase, as in the rare childhood epilepsy Lafora disease, the phosphorylation level is elevated and is associated with abnormal glycogen structure that contributes to the pathology. Laforin therefore likely functions in vivo as a glycogen phosphatase. The mechanism of glycogen phosphorylation is less well-understood. We have reported that glycogen synthase incorporates phosphate into glycogen via a rare side reaction in which glucose-phosphate rather than glucose is transferred to a growing polyglucose chain (Tagliabracci et al. (2011) Cell Metab 13 , 274–282). We proposed a mechanism to account for phosphorylation at C2 and possibly at C3. Our results have since been challenged (Nitschke et al. (2013) Cell Metab 17 , 756–767). Here we extend the evidence supporting our conclusion, validating the assay used for the detection of glycogen phosphorylation, measurement of the transfer of 32 P from [β- 32 P]UDP-glucose to glycogen by glycogen synthase. The 32 P associated with the glycogen fraction was stable to ethanol precipitation, SDS-PAGE and gel filtration on Sephadex G50. The 32 P-signal was not affected by inclusion of excess unlabeled UDP before analysis or by treatment with a UDPase, arguing against the signal being due to contaminating [β- 32 P]UDP generated in the reaction. Furthermore, [ 32 P]UDP did not bind non-covalently to glycogen. The 32 P associated with glycogen was released by laforin treatment, suggesting that it was present as a phosphomonoester. The conclusion is that glycogen synthase can mediate the introduction of phosphate into glycogen, thereby providing a possible mechanism for C2, and perhaps C3, phosphorylation.

Published

2016

15. Accurate and sensitive quantitation of glucose and glucose phosphates derived from storage carbohydrates by mass spectrometry

Author

Matthew S. Gentry, Ramon C. Sun, Anna A. DePaoli-Roach, Peter J. Roach, Christopher J. Contreras, Corey O. Brizzee, Robert D. Murphy, Jessica K. A. Macedo, and Lyndsay E.A. Young

Subjects

chemistry.chemical_classification, Chromatography, Polymers and Plastics, Glycogen, Starch, Organic Chemistry, food and beverages, 02 engineering and technology, Metabolism, 010402 general chemistry, 021001 nanoscience & nanotechnology, Phosphate, Glucose phosphate, Mass spectrometry, 01 natural sciences, Article, 0104 chemical sciences, chemistry.chemical_compound, Enzyme, chemistry, Amylopectin, Materials Chemistry, 0210 nano-technology

Abstract

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.

Published

2020

16. Muscle Glycogen Remodeling and Glycogen Phosphate Metabolism following Exhaustive Exercise of Wild Type and Laforin Knockout Mice

Author

Dyann M. Segvich, Jose M. Irimia, Vincent S. Tagliabracci, Anna A. DePaoli-Roach, Peter J. Roach, and Catalina M. Meyer

Subjects

congenital, hereditary, and neonatal diseases and abnormalities, medicine.medical_specialty, Biology, Biochemistry, Lafora disease, Glycogen debranching enzyme, Mice, chemistry.chemical_compound, Physical Conditioning, Animal, Internal medicine, Glycogen branching enzyme, medicine, Animals, Phosphorylation, Muscle, Skeletal, Glycogen synthase, Molecular Biology, Mice, Knockout, Glycogen, Cell Biology, Protein Tyrosine Phosphatases, Non-Receptor, medicine.disease, Metabolism, Endocrinology, Lafora Disease, chemistry, Glycogenesis, biology.protein, Dual-Specificity Phosphatases, Laforin

Abstract

Glycogen, the repository of glucose in many cell types, contains small amounts of covalent phosphate, of uncertain function and poorly understood metabolism. Loss-of-function mutations in the laforin gene cause the fatal neurodegenerative disorder, Lafora disease, characterized by increased glycogen phosphorylation and the formation of abnormal deposits of glycogen-like material called Lafora bodies. It is generally accepted that the phosphate is removed by the laforin phosphatase. To study the dynamics of skeletal muscle glycogen phosphorylation in vivo under physiological conditions, mice were subjected to glycogen-depleting exercise and then monitored while they resynthesized glycogen. Depletion of glycogen by exercise was associated with a substantial reduction in total glycogen phosphate and the newly resynthesized glycogen was less branched and less phosphorylated. Branching returned to normal on a time frame of days, whereas phosphorylation remained suppressed over a longer period of time. We observed no change in markers of autophagy. Exercise of 3-month-old laforin knock-out mice caused a similar depletion of glycogen but no loss of glycogen phosphate. Furthermore, remodeling of glycogen to restore the basal branching pattern was delayed in the knock-out animals. From these results, we infer that 1) laforin is responsible for glycogen dephosphorylation during exercise and acts during the cytosolic degradation of glycogen, 2) excess glycogen phosphorylation in the absence of laforin delays the normal remodeling of the branching structure, and 3) the accumulation of glycogen phosphate is a relatively slow process involving multiple cycles of glycogen synthesis-degradation, consistent with the slow onset of the symptoms of Lafora disease.

Published

2015

17. Glycogen Phosphomonoester Distribution in Mouse Models of the Progressive Myoclonic Epilepsy, Lafora Disease

Author

Anna A. DePaoli-Roach, Dyann M. Segvich, Mayumi Ishihara, Christian Heiss, Christopher J. Contreras, Parastoo Azadi, and Peter J. Roach

Subjects

congenital, hereditary, and neonatal diseases and abnormalities, medicine.medical_specialty, Ubiquitin-Protein Ligases, Glucose-6-Phosphate, Mice, Transgenic, Biochemistry, Lafora disease, Glycogen debranching enzyme, Mice, Glycogen phosphorylase, chemistry.chemical_compound, Internal medicine, Glycogen branching enzyme, medicine, Animals, Humans, Glycogen storage disease, Phosphorylation, Phosphorylase kinase, Glycogen synthase, Molecular Biology, biology, Glycogen, Cell Biology, Protein Tyrosine Phosphatases, Non-Receptor, medicine.disease, Disease Models, Animal, Metabolism, Endocrinology, Lafora Disease, chemistry, Mutation, biology.protein, Dual-Specificity Phosphatases, Rabbits

Abstract

Glycogen is a branched polymer of glucose that acts as an energy reserve in many cell types. Glycogen contains trace amounts of covalent phosphate, in the range of 1 phosphate per 500-2000 glucose residues depending on the source. The function, if any, is unknown, but in at least one genetic disease, the progressive myoclonic epilepsy Lafora disease, excessive phosphorylation of glycogen has been implicated in the pathology by disturbing glycogen structure. Some 90% of Lafora cases are attributed to mutations of the EPM2A or EPM2B genes, and mice with either gene disrupted accumulate hyperphosphorylated glycogen. It is, therefore, of importance to understand the chemistry of glycogen phosphorylation. Rabbit skeletal muscle glycogen contained covalent phosphate as monoesters of C2, C3, and C6 carbons of glucose residues based on analyses of phospho-oligosaccharides by NMR. Furthermore, using a sensitive assay for glucose 6-P in hydrolysates of glycogen coupled with measurement of total phosphate, we determined the proportion of C6 phosphorylation in rabbit muscle glycogen to be ∼20%. C6 phosphorylation also accounted for ∼20% of the covalent phosphate in wild type mouse muscle glycogen. Glycogen phosphorylation in Epm2a(-/-) and Epm2b(-/-) mice was increased 8- and 4-fold compared with wild type mice, but the proportion of C6 phosphorylation remained unchanged at ∼20%. Therefore, our results suggest that C2, C3, and/or C6 phosphate could all contribute to abnormal glycogen structure or to Lafora disease.

Published

2015

18. Lack of liver glycogen causes hepatic insulin resistance and steatosis in mice

Author

Sneha Surendran, Anna A. DePaoli-Roach, Peter J. Roach, Catalina M. Meyer, Dyann M. Segvich, Núria Morral, and Jose M. Irimia

Subjects

0301 basic medicine, medicine.medical_specialty, Active Transport, Cell Nucleus, Biology, Biochemistry, Glycogen debranching enzyme, 03 medical and health sciences, chemistry.chemical_compound, Glycogen Synthase Kinase 3, Mice, 0302 clinical medicine, Insulin resistance, Internal medicine, medicine, Glycogen storage disease, Animals, Phosphorylation, Glycogen synthase, Molecular Biology, Cell Nucleus, Mice, Knockout, Glycogen, Basic Helix-Loop-Helix Leucine Zipper Transcription Factors, Forkhead Box Protein O1, Nuclear Proteins, Cell Biology, medicine.disease, Fatty Liver, Insulin receptor, 030104 developmental biology, Endocrinology, Metabolism, chemistry, Glycogenesis, Lipogenesis, biology.protein, Hepatocytes, Insulin Receptor Substrate Proteins, Insulin Resistance, Sterol Regulatory Element Binding Protein 1, Proto-Oncogene Proteins c-akt, 030217 neurology & neurosurgery, Acetyl-CoA Carboxylase, Signal Transduction, Transcription Factors

Abstract

Disruption of the Gys2 gene encoding the liver isoform of glycogen synthase generates a mouse strain (LGSKO) that almost completely lacks hepatic glycogen, has impaired glucose disposal, and is pre-disposed to entering the fasted state. This study investigated how the lack of liver glycogen increases fat accumulation and the development of liver insulin resistance. Insulin signaling in LGSKO mice was reduced in liver, but not muscle, suggesting an organ-specific defect. Phosphorylation of components of the hepatic insulin-signaling pathway, namely IRS1, Akt, and GSK3, was decreased in LGSKO mice. Moreover, insulin stimulation of their phosphorylation was significantly suppressed, both temporally and in an insulin dose response. Phosphorylation of the insulin-regulated transcription factor FoxO1 was somewhat reduced and insulin treatment did not elicit normal translocation of FoxO1 out of the nucleus. Fat overaccumulated in LGSKO livers, showing an aberrant distribution in the acinus, an increase not explained by a reduction in hepatic triglyceride export. Rather, when administered orally to fasted mice, glucose was directed toward hepatic lipogenesis as judged by the activity, protein levels, and expression of several fatty acid synthesis genes, namely, acetyl-CoA carboxylase, fatty acid synthase, SREBP1c, chREBP, glucokinase, and pyruvate kinase. Furthermore, using cultured primary hepatocytes, we found that lipogenesis was increased by 40% in LGSKO cells compared with controls. Of note, the hepatic insulin resistance was not associated with increased levels of pro-inflammatory markers. Our results suggest that loss of liver glycogen synthesis diverts glucose toward fat synthesis, correlating with impaired hepatic insulin signaling and glucose disposal.

Published

2017

19. Sterol Regulatory Element-binding Protein-1 (SREBP-1) Is Required to Regulate Glycogen Synthesis and Gluconeogenic Gene Expression in Mouse Liver

Author

Aisha Gamble, Peter J. Roach, Charles L. Hoppel, Anna A. DePaoli-Roach, Rafaela Ruiz, Vincent S. Tagliabracci, Yongyong Hou, Janos Kerner, Michelle Puchowicz, Victoria Jideonwo, Sneha Surendran, Núria Morral, Miwon Ahn, and Jose Irimia-Dominguez

Subjects

Male, endocrine system, medicine.medical_specialty, Biology, Carbohydrate metabolism, digestive system, Biochemistry, Glycogen debranching enzyme, Mice, chemistry.chemical_compound, Internal medicine, polycyclic compounds, medicine, Animals, Gene Regulation, Obesity, Glycogen synthase, Molecular Biology, Glycogen, Glucokinase, Gluconeogenesis, food and beverages, Cell Biology, Sterol regulatory element-binding protein, Diabetes Mellitus, Type 1, Endocrinology, Diabetes Mellitus, Type 2, Gene Expression Regulation, Liver, chemistry, Gene Knockdown Techniques, Lipogenesis, biology.protein, Sterol Regulatory Element Binding Protein 1, lipids (amino acids, peptides, and proteins)

Abstract

Sterol regulatory element-binding protein-1 (SREBP-1) is a key transcription factor that regulates genes in the de novo lipogenesis and glycolysis pathways. The levels of SREBP-1 are significantly elevated in obese patients and in animal models of obesity and type 2 diabetes, and a vast number of studies have implicated this transcription factor as a contributor to hepatic lipid accumulation and insulin resistance. However, its role in regulating carbohydrate metabolism is poorly understood. Here we have addressed whether SREBP-1 is needed for regulating glucose homeostasis. Using RNAi and a new generation of adenoviral vector, we have silenced hepatic SREBP-1 in normal and obese mice. In normal animals, SREBP-1 deficiency increased Pck1 and reduced glycogen deposition during fed conditions, providing evidence that SREBP-1 is necessary to regulate carbohydrate metabolism during the fed state. Knocking SREBP-1 down in db/db mice resulted in a significant reduction in triglyceride accumulation, as anticipated. However, mice remained hyperglycemic, which was associated with up-regulation of gluconeogenesis gene expression as well as decreased glycolysis and glycogen synthesis gene expression. Furthermore, glycogen synthase activity and glycogen accumulation were significantly reduced. In conclusion, silencing both isoforms of SREBP-1 leads to significant changes in carbohydrate metabolism and does not improve insulin resistance despite reducing steatosis in an animal model of obesity and type 2 diabetes.

Published

2014

20. New insights into the 'Glycogenetic' hypothesis of sleep: brain glycogen availability affects REM-related theta rhythm providing a possible link with emotional memory mechanisms

Author

Pierre J. Magistretti, Anna A. DePaoli-Roach, J.-M. Petit, Sophie Burlet-Godinot, and Peter J. Roach

Subjects

chemistry.chemical_compound, Theta rhythm, Glycogen, chemistry, Emotional memory, General Medicine, Psychology, Neuroscience, Sleep in non-human animals

Published

2019

21. Novel method for detection of glycogen in cells

Author

Peter J. Roach, Anna A. DePaoli-Roach, Alexander V. Skurat, and Dyann M. Segvich

Subjects

0301 basic medicine, Muscle Proteins, Enzyme-Linked Immunosorbent Assay, Biochemistry, Lafora disease, 03 medical and health sciences, chemistry.chemical_compound, Mice, medicine, Glycogen storage disease, Animals, Humans, Glutathione Transferase, chemistry.chemical_classification, Glycogen, biology, Membrane Proteins, medicine.disease, Glycogen Storage Disease, Original articles, Fusion protein, Primary and secondary antibodies, Recombinant Proteins, Staining, 030104 developmental biology, Enzyme, Glucose, chemistry, Lafora Disease, Amylopectin, biology.protein, Lysosomes

Abstract

y Glycogen, a branched polymer of glucose, functions as an energy reserve in many living organisms. Abnormalities in glycogen metabolism, usually excessive accumulation, can be caused genetically, most often through mutation of the enzymes directly involved in synthesis and degradation of the polymer leading to a variety of glycogen storage diseases (GSDs). Microscopic visualization of glycogen deposits in cells and tissues is important for the study of normal glycogen metabolism as well as diagnosis of GSDs. Here, we describe a method for the detection of glycogen using a renewable, recombinant protein which contains the carbohydrate-binding module (CBM) from starch-binding domain containing protein 1 (Stbd1). We generated a fusion protein containing g lutathione S-transferase, a cM c eptitope and the tbd1 BM (GYSC) for use as a glycogen-binding probe, which can be detected with secondary antibodies against glutathione S-transferase or cMyc. By enzyme-linked immunosorbent assay, we demonstrate that GYSC binds glycogen and two other polymers of glucose, amylopectin and amylose. Immunofluorescence staining of cultured cells indicate a GYSC-specific signal that is co-localized with signals obtained with anti-glycogen or anti-glycogen synthase antibodies. GYSC-positive staining inside of lysosomes is observed in individual muscle fibers isolated from mice deficient in lysosomal enzyme acid alpha-glucosidase, a well-characterized model of GSD II (Pompe disease). Co-localized GYSC and glycogen signals are also found in muscle fibers isolated from mice deficient in malin, a model for Lafora disease. These data indicate that GYSC is a novel probe that can be used to study glycogen metabolism under normal and pathological conditions.

Published

2016

22. Pathologic gene network rewiring implicates PPP1R3A as a central cardioprotective factor in pressure overload heart failure

Author

Stephen B. Montgomery, Christine S. Moravec, Frederick E. Dewey, Ching Shang, Euan A. Ashley, Kathia Zaleta, Viterna J, Jeff Brandimarto, Nicole L. Glazer, Pablo Cordero, Scott Ritter, Andrew C. Connolly, Hakon Hakonarson, Thomas P. Cappola, Victoria N. Parikh, Matthew T. Wheeler, Hongzhe Li, Aldonis J Lusis, Michael Morley, Wai Hong Tang, Miao Li, Sridhar Hannenhalli, Anna A. DePaoli-Roach, Kenneth B. Margulies, Ayca Erbilgin, Kevin S. Smith, Malloy C, and A. Pavlovic

Subjects

Pressure overload, 0303 health sciences, Gene regulatory network, Regulator, Disease, Computational biology, 030204 cardiovascular system & hematology, Biology, medicine.disease, 3. Good health, 03 medical and health sciences, 0302 clinical medicine, Gene interaction, Heart failure, Expression quantitative trait loci, medicine, 030304 developmental biology, Regulator gene

Abstract

Heart failure is a leading cause of mortality, yet our understanding of the genetic interactions underlying this disease remains incomplete. Here, we harvested 1352 healthy and failing human hearts directly from transplant center operating rooms, and obtained genome-wide genotyping and gene expression measurements for a subset of 313. We built failing and non-failing cardiac regulatory gene networks, revealing important regulators and cardiac expression quantitative trait loci (eQTLs).PPP1R3Aemerged as a novel regulator whose network connectivity changed significantly between health and disease. Time-course RNA sequencing afterPPP1R3Aknock-down validated network-based predictions of metabolic pathway expression, increased cardiomyocyte size, and perturbed respiratory metabolism. Mice lackingPPP1R3Awere protected against pressure-overload heart failure. We present a global gene interaction map of the human heart failure transition, identify new cardiac eQTLs, and demonstrate the discovery potential of disease-specific networks through the description ofPPP1R3Aas a novel central protective regulator in heart failure.

Published

2016

23. Glycogen and its metabolism: some new developments and old themes

Author

Anna A. DePaoli-Roach, Vincent S. Tagliabracci, Thomas D. Hurley, and Peter J. Roach

Subjects

Models, Molecular, medicine.medical_specialty, Glycogenin, Concept Formation, Molecular Sequence Data, Glycogenolysis, Models, Biological, Biochemistry, Article, Glycogen debranching enzyme, Mice, Glycogen phosphorylase, chemistry.chemical_compound, Internal medicine, Glycogen branching enzyme, medicine, Animals, Humans, Glycogen storage disease, Amino Acid Sequence, Glycogen synthase, Biology, Molecular Biology, Sequence Homology, Amino Acid, biology, Glycogen, Gluconeogenesis, Cell Biology, medicine.disease, Endocrinology, chemistry, Glycogenesis, biology.protein, Carbohydrate Metabolism, Metabolic Networks and Pathways

Abstract

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.

Published

2012

24. Functional consequences of brain glycogen deficiency on the sleep-wake cycle regulation in PTG-KO mice

Author

Pierre J. Magistretti, Peter J. Roach, J.-M. Petit, Anna A. DePaoli-Roach, Gabriele Grenningloh, Sophie Burlet-Godinot, and Igor Allaman

Subjects

chemistry.chemical_compound, Glycogen, chemistry, General Medicine, Circadian rhythm, Psychology, Neuroscience

Abstract

This work was supported by grants from Swiss National Science Foundation (FNRS#31003A_130821 and 310030B_148169) to PJM and NIH grants DK27221 and NS056454 to PJR.

Published

2017

25. Laforin and malin knockout mice have normal glucose disposal and insulin sensitivity

Author

Yasmeen Rahimi, Peter J. Roach, Carolyn A. Worby, Catalina M. Meyer, Dyann M. Segvich, Matthew S. Gentry, and Anna A. DePaoli-Roach

Subjects

Blood Glucose, medicine.medical_specialty, Ubiquitin-Protein Ligases, medicine.medical_treatment, Progressive myoclonus epilepsy, Lafora disease, Mice, chemistry.chemical_compound, Insulin resistance, Internal medicine, Genetics, medicine, Animals, Insulin, Glucose homeostasis, Molecular Biology, Genetics (clinical), Mice, Knockout, biology, Glycogen, Heart, Articles, General Medicine, Protein Tyrosine Phosphatases, Non-Receptor, medicine.disease, Insulin receptor, Endocrinology, chemistry, biology.protein, Dual-Specificity Phosphatases, Insulin Resistance, Laforin, Signal Transduction

Abstract

Lafora disease is a fatal, progressive myoclonus epilepsy caused in ∼90% of cases by mutations in the EPM2A or EPM2B genes. Characteristic of the disease is the formation of Lafora bodies, insoluble deposits containing abnormal glycogen-like material in many tissues, including neurons, muscle, heart and liver. Because glycogen is important for glucose homeostasis, the aberrant glycogen metabolism in Lafora disease might disturb whole-body glucose handling. Indeed, Vernia et al. [Vernia, S., Heredia, M., Criado, O., Rodriguez de Cordoba, S., Garcia-Roves, P.M., Cansell, C., Denis, R., Luquet, S., Foufelle, F., Ferre, P. et al. (2011) Laforin, a dual-specificity phosphatase involved in Lafora disease, regulates insulin response and whole-body energy balance in mice. Hum. Mol. Genet., 20, 2571–2584] reported that Epm2a−/− mice had enhanced glucose disposal and insulin sensitivity, leading them to suggest that laforin, the Epm2a gene product, is involved in insulin signaling. We analyzed 3-month- and 6–7-month-old Epm2a−/− mice and observed no differences in glucose tolerance tests (GTTs) or insulin tolerance tests (ITTs) compared with wild-type mice of matched genetic background. At 3 months, Epm2b−/− mice also showed no differences in GTTs and ITTs. In the 6–7-month-old Epm2a−/− mice, there was no evidence for increased insulin stimulation of the phosphorylation of Akt, GSK-3 or S6 in skeletal muscle, liver and heart. From metabolic analyses, these animals were normal with regard to food intake, oxygen consumption, energy expenditure and respiratory exchange ratio. By dual-energy X-ray absorptiometry scan, body composition was unaltered at 3 or 6–7 months of age. Echocardiography showed no defects of cardiac function in Epm2a−/− or Epm2b−/− mice. We conclude that laforin and malin have no effect on whole-body glucose metabolism and insulin sensitivity, and that laforin is not involved in insulin signaling.

Published

2011

26. Multiple Glycogen-binding Sites in Eukaryotic Glycogen Synthase Are Required for High Catalytic Efficiency toward Glycogen

Author

Peter J. Roach, Wayne A. Wilson, Keri D. DavisK.D. Davis, Vimbai M. Chikwana, Thomas D. Hurley, Anna A. DePaoli-Roach, Christopher J. Contreras, and Sulochanadevi Baskaran

Subjects

Saccharomyces cerevisiae Proteins, Oligosaccharides, Saccharomyces cerevisiae, Biology, Biochemistry, Glycogen debranching enzyme, Glycogen phosphorylase, chemistry.chemical_compound, Glycogen branching enzyme, Protein Structure, Quaternary, Phosphorylase kinase, Glycogen synthase, Molecular Biology, GSK3B, Glycogen binding, Binding Sites, Glycogen, Cell Biology, Protein Structure, Tertiary, Glycogen Synthase, chemistry, Mutation, Enzymology, biology.protein

Abstract

Glycogen synthase is a rate-limiting enzyme in the biosynthesis of glycogen and has an essential role in glucose homeostasis. The three-dimensional structures of yeast glycogen synthase (Gsy2p) complexed with maltooctaose identified four conserved maltodextrin-binding sites distributed across the surface of the enzyme. Site-1 is positioned on the N-terminal domain, site-2 and site-3 are present on the C-terminal domain, and site-4 is located in an interdomain cleft adjacent to the active site. Mutation of these surface sites decreased glycogen binding and catalytic efficiency toward glycogen. Mutations within site-1 and site-2 reduced the V(max)/S(0.5) for glycogen by 40- and 70-fold, respectively. Combined mutation of site-1 and site-2 decreased the V(max)/S(0.5) for glycogen by3000-fold. Consistent with the in vitro data, glycogen accumulation in glycogen synthase-deficient yeast cells (Δgsy1-gsy2) transformed with the site-1, site-2, combined site-1/site-2, or site-4 mutant form of Gsy2p was decreased by up to 40-fold. In contrast to the glycogen results, the ability to utilize maltooctaose as an in vitro substrate was unaffected in the site-2 mutant, moderately affected in the site-1 mutant, and almost completely abolished in the site-4 mutant. These data show that the ability to utilize maltooctaose as a substrate can be independent of the ability to utilize glycogen. Our data support the hypothesis that site-1 and site-2 provide a "toehold mechanism," keeping glycogen synthase tightly associated with the glycogen particle, whereas site-4 is more closely associated with positioning of the nonreducing end during catalysis.

Published

2011

27. Basis for MAP4 Dephosphorylation-related Microtubule Network Densification in Pressure Overload Cardiac Hypertrophy

Author

Joachim Neumann, George Cooper, Donald R. Menick, Anna A. DePaoli-Roach, Anandakumar Shunmugavel, J. Grace Wallenborn, Ulrich Gergs, Masaru Takahashi, Guangmao Cheng, and Dhandapani Kuppuswamy

Subjects

medicine.medical_specialty, Cardiomegaly, Mice, Transgenic, Biology, Microtubules, Biochemistry, Muscle hypertrophy, Dephosphorylation, Mice, Microtubule, Internal medicine, medicine, Animals, Protein Phosphatase 2, Phosphorylation, Molecular Biology, Heart Failure, Pressure overload, Calcium metabolism, Kinase, Molecular Bases of Disease, Cell Biology, medicine.disease, Myocardial Contraction, Endocrinology, Heart failure, Cats, Microtubule-Associated Proteins

Abstract

Increased activity of Ser/Thr protein phosphatases types 1 (PP1) and 2A (PP2A) during maladaptive cardiac hypertrophy contributes to cardiac dysfunction and eventual failure, partly through effects on calcium metabolism. A second maladaptive feature of pressure overload cardiac hypertrophy that instead leads to heart failure by interfering with cardiac contraction and intracellular transport is a dense microtubule network stabilized by decoration with microtubule-associated protein 4 (MAP4). In an earlier study we showed that the major determinant of MAP4-microtubule affinity, and thus microtubule network density and stability, is site-specific MAP4 dephosphorylation at Ser-924 and to a lesser extent at Ser-1056; this was found to be prominent in hypertrophied myocardium. Therefore, in seeking the etiology of this MAP4 dephosphorylation, we looked here at PP2A and PP1, as well as the upstream p21-activated kinase 1, in maladaptive pressure overload cardiac hypertrophy. The activity of each was increased persistently during maladaptive hypertrophy, and overexpression of PP2A or PP1 in normal hearts reproduced both the microtubule network phenotype and the dephosphorylation of MAP4 Ser-924 and Ser-1056 seen in hypertrophy. Given the major microtubule-based abnormalities of contractile and transport function in maladaptive hypertrophy, these findings constitute a second important mechanism for phosphatase-dependent pathology in the hypertrophied and failing heart.

Published

2010

28. Laforin is a glycogen phosphatase, deficiency of which leads to elevated phosphorylation of glycogen in vivo

Author

Jean Marie Girard, Xiaochu Zhao, Vincent S. Tagliabracci, Wei Wang, Anna A. DePaoli-Roach, Antonio V. Delgado-Escueta, Berge A. Minassian, Julie Turnbull, Alexander V. Skurat, and Peter J. Roach

Subjects

Male, congenital, hereditary, and neonatal diseases and abnormalities, Progressive myoclonus epilepsy, Lafora disease, Glycogen debranching enzyme, Mice, chemistry.chemical_compound, Glycogen branching enzyme, medicine, Animals, Phosphorylation, Glycogen synthase, Mice, Knockout, Glycogen binding, Multidisciplinary, biology, Glycogen, Biological Sciences, Protein Tyrosine Phosphatases, Non-Receptor, medicine.disease, Recombinant Proteins, Disease Models, Animal, Glycogen Synthase, Lafora Disease, chemistry, Biochemistry, Mutation, biology.protein, Dual-Specificity Phosphatases, Rabbits, Laforin

Abstract

Lafora disease is a progressive myoclonus epilepsy with onset typically in the second decade of life and death within 10 years. Lafora bodies, deposits of abnormally branched, insoluble glycogen-like polymers, form in neurons, muscle, liver, and other tissues. Approximately half of the cases of Lafora disease result from mutations in the EPM2A gene, which encodes laforin, a member of the dual-specificity protein phosphatase family that additionally contains a glycogen binding domain. The molecular basis for the formation of Lafora bodies is completely unknown. Glycogen, a branched polymer of glucose, contains a small amount of covalently linked phosphate whose origin and function are obscure. We report here that recombinant laforin is able to release this phosphate in vitro , in a time-dependent reaction with an apparent K m for glycogen of 4.5 mg/ml. Mutations of laforin that disable the glycogen binding domain also eliminate its ability to dephosphorylate glycogen. We have also analyzed glycogen from a mouse model of Lafora disease, Epm2a −/− mice, which develop Lafora bodies in several tissues. Glycogen isolated from these mice had a 40% increase in the covalent phosphate content in liver and a 4-fold elevation in muscle. We propose that excessive phosphorylation of glycogen leads to aberrant branching and Lafora body formation. This study provides a molecular link between an observed biochemical property of laforin and the phenotype of a mouse model of Lafora disease. The results also have important implications for glycogen metabolism generally.

Published

2007

29. Structural Basis for Regulation of Protein Phosphatase 1 by Inhibitor-2

Author

Anna A. DePaoli-Roach, Kristie D. Goodwin, Thomas D. Hurley, Jie Yang, A. Keith Dunker, Marc S. Cortese, Lili Zhang, and Qin Zou

Subjects

Phosphatase, Regulator, Sequence (biology), Biology, Crystallography, X-Ray, Inhibitory postsynaptic potential, Biochemistry, Protein Structure, Secondary, Mice, Protein Phosphatase 1, Phosphoprotein Phosphatases, Animals, Protein Structure, Quaternary, Molecular Biology, Hydrolase inhibitor, chemistry.chemical_classification, Phosphoprotein phosphatase, Binding Sites, Proteins, Protein phosphatase 1, Cell Biology, Rats, Amino acid, Enzyme Activation, chemistry, Protein Binding

Abstract

The functional specificity of type 1 protein phosphatases (PP1) depends on the associated regulatory/targeting and inhibitory subunits. To gain insights into the mechanism of PP1 regulation by inhibitor-2, an ancient and intrinsically disordered regulator, we solved the crystal structure of the complex to 2.5A resolution. Our studies show that, when complexed with PP1c, I-2 acquires three regions of order: site 1, residues 12-17, binds adjacent to a region recognized by many PP1 regulators; site 2, amino acids 44-56, interacts along the RVXF binding groove through an unsuspected sequence, KSQKW; and site 3, residues 130-169, forms alpha-helical regions that lie across the substrate-binding cleft. Specifically, residues 148-151 interact at the catalytic center, displacing essential metal ions, accounting for both rapid inhibition and slower inactivation of PP1c. Thus, our structure provides novel insights into the mechanism of PP1 inhibition and subsequent reactivation, has broad implications for the physiological regulation of PP1, and highlights common inhibitory interactions among phosphoprotein phosphatase family members.

Published

2007

30. Glycogen metabolism in tissues from a mouse model of Lafora disease

Author

Berge A. Minassian, Anna A. DePaoli-Roach, Alexander V. Skurat, Peter J. Roach, Wei Wang, and Hannes Lohi

Subjects

congenital, hereditary, and neonatal diseases and abnormalities, medicine.medical_specialty, Biophysics, Mice, Transgenic, Biochemistry, Article, Lafora disease, Glycogen debranching enzyme, Mice, Glycogen phosphorylase, chemistry.chemical_compound, Internal medicine, Glycogen branching enzyme, medicine, Animals, Muscle, Skeletal, Glycogen synthase, Molecular Biology, GSK3B, biology, Glycogen, Glycogen Phosphorylase, Brain, Protein Tyrosine Phosphatases, Non-Receptor, medicine.disease, Disease Models, Animal, Glycogen Synthase, Endocrinology, Lafora Disease, chemistry, biology.protein, Dual-Specificity Phosphatases, Protein Tyrosine Phosphatases, Laforin

Abstract

Laforin, encoded by the EPM2A gene, by sequence is a member of the dual specificity protein phosphatase family. Mutations in the EPM2A gene account for around half of the cases of Lafora disease, an autosomal recessive neurodegenerative disorder, characterized by progressive myoclonus epilepsy. The hallmark of the disease is the presence of Lafora bodies, which contain polyglucosan, a poorly branched form of glycogen, in neurons, muscle and other tissues. Glycogen metabolizing enzymes were analyzed in a transgenic mouse over-expressing a dominant negative form of laforin that accumulates Lafora bodies in several tissues. Skeletal muscle glycogen was increased two-fold as was the total glycogen synthase protein. However, the −/+ glucose-6-P activity of glycogen synthase was decreased from 0.29 to 0.16. Branching enzyme activity was increased by 30%. Glycogen phosphorylase activity was unchanged. In whole brain, no differences in glycogen synthase or branching enzyme activities were found. Although there were significant differences in enzyme activities in muscle, the results do not support the hypothesis that Lafora body formation is caused by a major change in the balance between glycogen elongation and branching activities.

Published

2007

31. Correction for Chikwana et al., Structural basis for 2′-phosphate incorporation into glycogen by glycogen synthase

Author

Anna A. DePaoli-Roach, May Khanna, Peter J. Roach, Christopher J. Contreras, Vincent S. Tagliabracci, Vimbai M. Chikwana, Sulochanadevi Baskaran, and Thomas D. Hurley

Subjects

chemistry.chemical_compound, Multidisciplinary, chemistry, Glycogen, Biochemistry, biology, business.industry, biology.protein, Medicine, Phosphate, Glycogen synthase, business

Published

2015

32. Role of pyruvate dehydrogenase kinase isoenzyme 4 (PDHK4) in glucose homoeostasis during starvation

Author

Mandar Joshi, Jerzy Jaskiewicz, Cheryl B. Bock, Robert A. Harris, Pengfei Wu, Anna A. DePaoli-Roach, and Nam Ho Jeoung

Subjects

Male, Pyruvate decarboxylation, medicine.medical_specialty, Pyruvate dehydrogenase kinase, Diaphragm, Protein Serine-Threonine Kinases, Biology, Pyruvate dehydrogenase phosphatase, Biochemistry, Mice, Internal medicine, Pyruvic Acid, medicine, Animals, Homeostasis, Insulin, Lactic Acid, Molecular Biology, Mice, Knockout, Fatty Acids, Pyruvate Dehydrogenase Acetyl-Transferring Kinase, Cell Biology, Pyruvate dehydrogenase complex, Up-Regulation, Pyruvate carboxylase, Isoenzymes, Citric acid cycle, Glucose, Endocrinology, Liver, Gluconeogenesis, Organ Specificity, Starvation, Branched-chain alpha-keto acid dehydrogenase complex, Glycolysis, Oxidation-Reduction, Protein Kinases, Research Article

Abstract

The PDC (pyruvate dehydrogenase complex) is strongly inhibited by phosphorylation during starvation to conserve substrates for gluconeogenesis. The role of PDHK4 (pyruvate dehydrogenase kinase isoenzyme 4) in regulation of PDC by this mechanism was investigated with PDHK4−/− mice (homozygous PDHK4 knockout mice). Starvation lowers blood glucose more in mice lacking PDHK4 than in wild-type mice. The activity state of PDC (percentage dephosphorylated and active) is greater in kidney, gastrocnemius muscle, diaphragm and heart but not in the liver of starved PDHK4−/− mice. Intermediates of the gluconeogenic pathway are lower in concentration in the liver of starved PDHK4−/− mice, consistent with a lower rate of gluconeogenesis due to a substrate supply limitation. The concentration of gluconeogenic substrates is lower in the blood of starved PDHK4−/− mice, consistent with reduced formation in peripheral tissues. Isolated diaphragms from starved PDHK4−/− mice accumulate less lactate and pyruvate because of a faster rate of pyruvate oxidation and a reduced rate of glycolysis. BCAAs (branched chain amino acids) are higher in the blood in starved PDHK4−/− mice, consistent with lower blood alanine levels and the importance of BCAAs as a source of amino groups for alanine formation. Non-esterified fatty acids are also elevated more in the blood of starved PDHK4−/− mice, consistent with lower rates of fatty acid oxidation due to increased rates of glucose and pyruvate oxidation due to greater PDC activity. Up-regulation of PDHK4 in tissues other than the liver is clearly important during starvation for regulation of PDC activity and glucose homoeostasis.

Published

2006

33. Enhancement of Cardiac Function and Suppression of Heart Failure Progression By Inhibition of Protein Phosphatase 1

Author

Guoli Chen, E. Kevin Heist, Ilona Bodi, Evangelia G. Kranias, John N. Lorenz, Jo El J. Schultz, Harvey S. Hahn, Yehia Marreez, Nirmala Mavila, Doug Weiser, Anand Pathak, Anna A. DePaoli-Roach, Leena Jha, Federica del Monte, Faisal M. Syed, J. Luis Guerrero, Roger J. Hajjar, Jiang Qian, Andrew N. Carr, Wen Zhao, and Dennis W. McGraw

Subjects

medicine.medical_specialty, Physiology, Phosphatase, Cardiomegaly, Mice, Transgenic, Calcium-Transporting ATPases, Biology, Sarcoplasmic Reticulum Calcium-Transporting ATPases, Muscle hypertrophy, Dephosphorylation, Mice, Protein Phosphatase 1, Internal medicine, Phosphoprotein Phosphatases, medicine, Animals, Enzyme Inhibitors, Phosphorylation, Ventricular remodeling, Heart Failure, Ventricular Remodeling, Calcium-Binding Proteins, Proteins, Protein phosphatase 1, Genetic Therapy, medicine.disease, Myocardial Contraction, Rats, Phospholamban, Sarcoplasmic Reticulum, Endocrinology, Heart failure, Calcium, Cardiology and Cardiovascular Medicine

Abstract

Abnormal calcium cycling, characteristic of experimental and human heart failure, is associated with impaired sarcoplasmic reticulum calcium uptake activity. This reflects decreases in the cAMP-pathway signaling and increases in type 1 phosphatase activity. The increased protein phosphatase 1 activity is partially due to dephosphorylation and inactivation of its inhibitor-1, promoting dephosphorylation of phospholamban and inhibition of the sarcoplasmic reticulum calcium-pump. Indeed, cardiac-specific expression of a constitutively active inhibitor-1 results in selective enhancement of phospholamban phosphorylation and augmented cardiac contractility at the cellular and intact animal levels. Furthermore, the β-adrenergic response is enhanced in the transgenic hearts compared with wild types. On aortic constriction, the hypercontractile cardiac function is maintained, hypertrophy is attenuated and there is no decompensation in the transgenics compared with wild-type controls. Notably, acute adenoviral gene delivery of the active inhibitor-1, completely restores function and partially reverses remodeling, including normalization of the hyperactivated p38, in the setting of pre-existing heart failure. Thus, the inhibitor 1 of the type 1 phosphatase may represent an attractive new therapeutic target.

Published

2005

34. Exercise Capacity of Mice Genetically Lacking Muscle Glycogen Synthase

Author

Beth L. Thurberg, Jose M. Irimia, Carlie R. Cope, Anna A. DePaoli-Roach, Jill M. Schroeder, Micah W. Smith, Bartholomew A. Pederson, and Peter J. Roach

Subjects

Genetically modified mouse, chemistry.chemical_classification, medicine.medical_specialty, Glycogen, biology, Wild type, Skeletal muscle, Cell Biology, Polysaccharide, Biochemistry, chemistry.chemical_compound, medicine.anatomical_structure, Endocrinology, chemistry, Internal medicine, medicine, biology.protein, Exercise physiology, Treadmill, Glycogen synthase, Molecular Biology

Abstract

The glucose storage polymer glycogen is generally considered to be an important source of energy for skeletal muscle contraction and a factor in exercise endurance. A genetically modified mouse model lacking muscle glycogen was used to examine whether the absence of the polysaccharide affects the ability of mice to run on a treadmill. The MGSKO mouse has the GYS1 gene, encoding the muscle isoform of glycogen synthase, disrupted so that skeletal muscle totally lacks glycogen. The morphology of the soleus and quadriceps muscles from MGSKO mice appeared normal. MGSKO-null mice, along with wild type littermates, were exercised to exhaustion. There were no significant differences in the work performed by MGSKO mice as compared with their wild type littermates. The amount of liver glycogen consumed during exercise was similar for MGSKO and wild type animals. Fasting reduced exercise endurance, and after overnight fasting, there was a trend to reduced exercise endurance for the MGSKO mice. These studies provide genetic evidence that in mice muscle glycogen is not essential for strenuous exercise and has relatively little effect on endurance.

Published

2005

35. A Protein Phosphatase-1γ1 Isoform Selectivity Determinant in Dendritic Spine-associated Neurabin

Author

Anna A. DePaoli-Roach, Patricia A. Bauman, Martha A. Bass, Leigh C. Carmody, Roger J. Colbran, and Nirmala Mavila

Subjects

Gene isoform, Immunoprecipitation, Recombinant Fusion Proteins, Protein subunit, Amino Acid Motifs, Blotting, Western, Genetic Vectors, Molecular Sequence Data, Phosphatase, Nerve Tissue Proteins, Biology, Biochemistry, Mice, chemistry.chemical_compound, Catalytic Domain, Protein Phosphatase 1, Phosphoprotein Phosphatases, Animals, Protein Isoforms, Amino Acid Sequence, Molecular Biology, Peptide sequence, Glutathione Transferase, chemistry.chemical_classification, Dose-Response Relationship, Drug, Sequence Homology, Amino Acid, Muscles, Microfilament Proteins, Brain, Dendrites, Cell Biology, Glutathione, Precipitin Tests, Fusion protein, Actins, Recombinant Proteins, Protein Structure, Tertiary, Rats, Amino acid, chemistry, Mutation, Mutagenesis, Site-Directed, Gene Deletion, Protein Binding

Abstract

Protein phosphatase-1 (PP1) catalytic subunit isoforms interact with diverse proteins, typically containing a canonical (R/K)(V/I)XF motif. Despite sharing approximately 90% amino acid sequence identity, PP1beta and PP1gamma1 have distinct subcellular localizations that may be determined by selective interactions with PP1-binding proteins. Immunoprecipitation studies from brain and muscle extracts demonstrated that PP1gamma1 selectively interacts with spinophilin and neurabin, F-actin-targeting proteins, whereas PP1beta selectively interacted with G(M)/R(GL), the striated-muscle glycogen-targeting subunit. Glutathione S-transferase (GST) fusion proteins containing residues 146-493 of neurabin (GST-Nb-(146-493)) or residues 1-240 of G(M)/R(GL) (GST-G(M)-(1-240)) recapitulated these isoform selectivities in binding and phosphatase activity inhibition assays. Site-directed mutagenesis indicated that this isoform selectivity was not due to sequence differences between the canonical PP1-binding motifs (neurabin, (457)KIKF(460); G(M)/R(GL), (65)RVSF(68)). A chimeric GST fusion protein containing residues 1-64 of G(M)/R(GL) fused to residues 457-493 of neurabin (GST-G(M)/Nb) selectively bound to and inhibited PP1gamma1, whereas a GST-Nb/G(M) chimera containing Nb-(146-460) fused to G(M)-(69-240) selectively interacted with and weakly inhibited PP1beta, implicating domain(s) C-terminal to the (R/K)(V/I)XF motif as determinants of PP1 isoform selectivity. Deletion of Pro(464) and Ile(465) in neurabin (deltaPI) to equally space a conserved cluster of amino acids from the (R/K)(V/I)XF motif as in G(M)/R(GL) severely compromised the ability of neurabin to bind and inhibit both isoforms but did not affect PP1gamma1 selectivity. Further analysis of a series of C-terminal truncated GST-Nb-(146-493) proteins identified residues 473-479 of neurabin as containing a crucial PP1gamma1-selectivity determinant. In combination, these data identify a novel PP1gamma1-selective interaction domain in neurabin that may allow for selective regulation and/or subcellular targeting of PP1 isoforms.

Published

2004

36. PKC-α regulates cardiac contractility and propensity toward heart failure

Author

Wen Zhao, Arnold Schwartz, Stephen B. Liggett, Su Wang, Evangelia G. Kranias, John N. Lorenz, Anna A. DePaoli-Roach, Margaret V. Westfall, Julian C. Braz, Kimberly N. Gregory, Timothy E. Hewett, Edward G. Lakatta, Ilona Bodi, Thomas F. Kimball, Jeffrey Robbins, Angus C. Nairn, Bogachan Sahin, Anand Pathak, Raisa Klevitsky, James A. Bibb, and Jeffery D. Molkentin

Subjects

medicine.medical_specialty, Protein Kinase C-alpha, Cardiac Output, Low, Mice, Transgenic, Calcium-Transporting ATPases, Biology, PKC alpha, General Biochemistry, Genetics and Molecular Biology, Sarcoplasmic Reticulum Calcium-Transporting ATPases, Contractility, Mice, Risk Factors, Protein Phosphatase 1, Internal medicine, Phosphoprotein Phosphatases, medicine, Animals, Calsequestrin, Myocyte, Myocytes, Cardiac, CSRP3, Protein Kinase C, Protein kinase C, Pressure overload, Myocardium, Calcium-Binding Proteins, General Medicine, Myocardial Contraction, Rats, Phospholamban, Isoenzymes, Endocrinology, Phosphorylation, Calcium, Cardiomyopathies

Abstract

The protein kinase C (PKC) family of serine/threonine kinases functions downstream of nearly all membrane-associated signal transduction pathways. Here we identify PKC-alpha as a fundamental regulator of cardiac contractility and Ca(2+) handling in myocytes. Hearts of Prkca-deficient mice are hypercontractile, whereas those of transgenic mice overexpressing Prkca are hypocontractile. Adenoviral gene transfer of dominant-negative or wild-type PKC-alpha into cardiac myocytes enhances or reduces contractility, respectively. Mechanistically, modulation of PKC-alpha activity affects dephosphorylation of the sarcoplasmic reticulum Ca(2+) ATPase-2 (SERCA-2) pump inhibitory protein phospholamban (PLB), and alters sarcoplasmic reticulum Ca(2+) loading and the Ca(2+) transient. PKC-alpha directly phosphorylates protein phosphatase inhibitor-1 (I-1), altering the activity of protein phosphatase-1 (PP-1), which may account for the effects of PKC-alpha on PLB phosphorylation. Hypercontractility caused by Prkca deletion protects against heart failure induced by pressure overload, and against dilated cardiomyopathy induced by deleting the gene encoding muscle LIM protein (Csrp3). Deletion of Prkca also rescues cardiomyopathy associated with overexpression of PP-1. Thus, PKC-alpha functions as a nodal integrator of cardiac contractility by sensing intracellular Ca(2+) and signal transduction events, which can profoundly affect propensity toward heart failure.

Published

2004

37. Reversal of Diet-induced Glucose Intolerance by Hepatic Expression of a Variant Glycogen-targeting Subunit of Protein Phosphatase-1

Author

Christopher B. Newgard, Catherine Clark, Anna A. DePaoli-Roach, Ruojing Yang, and Rosa Gasa

Subjects

Male, Gene isoform, medicine.medical_specialty, Protein subunit, Phosphatase, Biology, Biochemistry, Adenoviridae, chemistry.chemical_compound, Protein Phosphatase 1, Diabetes mellitus, Internal medicine, Glucose Intolerance, Phosphoprotein Phosphatases, medicine, Animals, Humans, Potency, Transgenes, Rats, Wistar, Muscle, Skeletal, Molecular Biology, chemistry.chemical_classification, Glycogen, Protein phosphatase 1, Fasting, Cell Biology, Glucose Tolerance Test, medicine.disease, Dietary Fats, Rats, Isoenzymes, Protein Subunits, Glucose, Endocrinology, Enzyme, Liver, chemistry, Insulin Resistance

Abstract

Glycogen-targeting subunits of protein phosphatase-1 facilitate interaction of the phosphatase with enzymes of glycogen metabolism. Expression of one family member, PTG, in the liver of normal rats improves glucose tolerance without affecting other plasma variables but leaves animals unable to reduce hepatic glycogen stores in response to fasting. In the current study, we have tested whether expression of other targeting subunit isoforms, such as the liver isoform G(L), the muscle isoform G(M)/R(Gl), or a truncated version of G(M)/R(Gl) termed G(M)DeltaC in liver ameliorates glucose intolerance in rats fed on a high fat diet (HF). HF animals overexpressing G(M)DeltaC, but not G(L) or G(M)/R(Gl), exhibited a decline in blood glucose of 35-44 mg/dl relative to control HF animals during an oral glucose tolerance test (OGTT) such that levels were indistinguishable from those of normal rats fed on standard chow at all but one time point. Hepatic glycogen levels were 2.1-2.4-fold greater in G(L)- and G(M)DeltaC-overexpressing HF rats compared with control HF animals following OGTT. In a second set of studies on fed and 20-h fasted HF animals, G(M)DeltaC-overexpressing rats lowered their liver glycogen levels by 57% (from 402 +/- 54 to 173 +/- 27 microg of glycogen/mg of protein) in the fasted versus fed states compared with only 44% in G(L)-overexpressing animals (from 740 +/- 35 to 413 +/- 141 microg of glycogen/mg of protein). Since the OGTT studies were performed on 20-h fasted rats, this meant that G(M)DeltaC-overexpressing rats synthesized much more glycogen than G(L)-overexpressing HF rats during the OGTT (419 versus 117 microg of glycogen/mg of protein, respectively), helping to explain why G(M)DeltaC preferentially enhanced glucose clearance. We conclude that G(M)DeltaC has a unique combination of glycogenic potency and responsiveness to glycogenolytic signals that allows it to be used to lower blood glucose levels in diabetes.

Published

2002

38. Protein degradation and quality control in cells from laforin and malin knockout mice

Author

Punitee Garyali, Anna A. DePaoli-Roach, Peter J. Roach, and Dyann M. Segvich

Subjects

congenital, hereditary, and neonatal diseases and abnormalities, Proteasome Endopeptidase Complex, Ubiquitin-Protein Ligases, Protein degradation, Biochemistry, Lafora disease, chemistry.chemical_compound, Mice, Ubiquitinated Protein Degradation, medicine, Animals, Molecular Biology, Mice, Knockout, biology, Glycogen, Endoplasmic reticulum, Ubiquitination, Lysosome-Associated Membrane Glycoproteins, Cell Biology, medicine.disease, Endoplasmic Reticulum Stress, Protein Tyrosine Phosphatases, Non-Receptor, Molecular biology, Ubiquitin ligase, Metabolism, chemistry, Ribosomal protein s6, Proteolysis, biology.protein, Dual-Specificity Phosphatases, Lysosomes, Laforin, Transcription Factor CHOP

Abstract

Lafora disease is a progressive myoclonus epilepsy caused by mutations in the EPM2A or EPM2B genes that encode a glycogen phosphatase, laforin, and an E3 ubiquitin ligase, malin, respectively. Lafora disease is characterized by accumulation of insoluble, poorly branched, hyperphosphorylated glycogen in brain, muscle, heart, and liver. The laforinmalin complex has been proposed to play a role in the regulation of glycogen metabolism and protein quality control. We evaluated three arms of the protein degradation/ quality control process (the autophago-lysosomal pathway, the ubiquitin-proteasomal pathway, and the endoplasmic reticulum (ER) stress response) in mouse embryonic fibroblasts from Epm2a(-/-), Epm2b(-/-), and Epm2a(-/-) Epm2b(-/-) mice. The levels of LC3-II, a marker of autophagy, were decreased in all knock-out cells as compared with wild type even though they still showed a slight response to starvation and rapamycin. Furthermore, ribosomal protein S6 kinase and S6 phosphorylation were increased. Under basal conditions there was no effect on the levels of ubiquitinated proteins in the knock-out cells, but ubiquitinated protein degradation was decreased during starvation or stress. Lack of malin (Epm2b(-/-) and Epm2a(-/-) Epm2b(-/-) cells) but not laforin (Epm2a(-/-) cells) decreased LAMP1, a lysosomal marker. CHOP expression was similar in wild type and knock-out cells under basal conditions or with ER stress-inducing agents. In conclusion, both laforin and malin knock-out cells display mTOR-dependent autophagy defects and reduced proteasomal activity but no defects in the ER stress response. We speculate that these defects may be secondary to glycogen overaccumulation. This study also suggests a malin function independent of laforin, possibly in lysosomal biogenesis and/or lysosomal glycogen disposal.

Published

2014

39. The Muscle-specific Protein Phosphatase PP1G/RGL(GM) Is Essential for Activation of Glycogen Synthase by Exercise

Author

Pier Giuseppe Vilardo, Kristine Breeden, Kei Sakamoto, Yoichi Suzuki, William G. Aschenbach, Clara Prats, Marcella Steele, Anna A. DePaoli-Roach, Scott D. Dufresne, Jong-Hwa Kim, Shao-liang Jing, Michael F. Hirshman, and Laurie J. Goodyear

Subjects

medicine.medical_specialty, medicine.medical_treatment, Glucose uptake, Physical Exertion, Sarcoplasm, Motor Activity, Biology, Biochemistry, Mice, chemistry.chemical_compound, Physical Conditioning, Animal, Protein Phosphatase 1, Internal medicine, Phosphoprotein Phosphatases, medicine, Animals, Muscle, Skeletal, Glycogen synthase, Molecular Biology, Exercise Tolerance, Glycogen, Insulin, Glycogen Phosphorylase, Glucose transporter, Skeletal muscle, Biological Transport, Cell Biology, Electric Stimulation, Mice, Mutant Strains, Enzyme Activation, Glucose, Glycogen Synthase, Endocrinology, medicine.anatomical_structure, chemistry, biology.protein, medicine.symptom, Carrier Proteins, Muscle Contraction, Muscle contraction

Abstract

In skeletal muscle both insulin and contractile activity are physiological stimuli for glycogen synthesis, which is thought to result in part from the dephosphorylation and activation of glycogen synthase (GS). PP1G/R(GL)(G(M)) is a glycogen/sarcoplasmic reticulum-associated type 1 phosphatase that was originally postulated to mediate insulin control of glycogen metabolism. However, we recently showed (Suzuki, Y., Lanner, C., Kim, J.-H., Vilardo, P. G., Zhang, H., Jie Yang, J., Cooper, L. D., Steele, M., Kennedy, A., Bock, C., Scrimgeour, A., Lawrence, J. C. Jr., L., and DePaoli-Roach, A. A. (2001) Mol. Cell. Biol. 21, 2683-2694) that insulin activates GS in muscle of R(GL)(G(M)) knockout (KO) mice similarly to the wild type (WT). To determine whether PP1G is involved in glycogen metabolism during muscle contractions, R(GL) KO and overexpressors (OE) were subjected to two models of contraction, in vivo treadmill running and in situ electrical stimulation. Both procedures resulted in a 2-fold increase in the GS -/+ glucose-6-P activity ratio in WT mice, but this response was completely absent in the KO mice. The KO mice, which also have a reduced GS activity associated with significantly reduced basal glycogen levels, exhibited impaired maximal exercise capacity, but contraction-induced activation of glucose transport was unaffected. The R(GL) OE mice are characterized by enhanced GS activity ratio and an approximately 3-4-fold increase in glycogen content in skeletal muscle. These animals were able to tolerate exercise normally. Stimulation of GS and glucose uptake following muscle contraction was not significantly different as compared with WT littermates. These results indicate that although PP1G/R(GL) is not necessary for activation of GS by insulin, it is essential for regulation of glycogen metabolism under basal conditions and in response to contractile activity, and may explain the reduced muscle glycogen content in the R(GL) KO mice, despite the normal insulin activation of GS.

Published

2001

40. Gene Structure and Expression of the Targeting Subunit, RGL, of the Muscle-Specific Glycogen-Associated Type 1 Protein Phosphatase, PP1G

Author

Yoichi Suzuki, Hong Zhang, Chen Bi, Anna A. DePaoli-Roach, Melissa M. Bowker-Kinley, Lori D. Cooper, and Carita Lanner

Subjects

Transcription, Genetic, MyoD, Biochemistry, Rats, Sprague-Dawley, Mice, chemistry.chemical_compound, Exon, Protein Phosphatase 1, Adipocytes, Cyclic AMP, Phosphoprotein Phosphatases, Insulin, Myocyte, Tissue Distribution, Cloning, Molecular, 3' Untranslated Regions, Cells, Cultured, Glycogen, MEF2 Transcription Factors, Muscles, Cardiac muscle, Exons, DNA-Binding Proteins, medicine.anatomical_structure, Myogenic Regulatory Factors, Rabbits, DNA, Complementary, Protein subunit, Blotting, Western, Molecular Sequence Data, Biophysics, Biology, Streptozocin, Proto-Oncogene Proteins c-myc, medicine, Animals, Humans, Amino Acid Sequence, RNA, Messenger, Muscle, Skeletal, Molecular Biology, Gene Library, MyoD Protein, Messenger RNA, Polymorphism, Genetic, Base Sequence, Models, Genetic, Sequence Homology, Amino Acid, Skeletal muscle, Blotting, Northern, Molecular biology, Introns, Rats, chemistry, Protein Biosynthesis, Carrier Proteins, Transcription Factors

Abstract

The type I phosphatase associated with glycogen, PP1G, plays an important role in glycogen metabolism. PP1G is targeted to glycogen by the R(GL) subunit, which regulates the function of the enzyme. We report the cloning and characterization of the gene as well as the pattern of expression of the R(GL) subunit from mouse. The gene covers more than 37 kb, is composed of four exons and three introns, and codes for a 1089 residue polypeptide with a calculated molecular weight of 121,000. The amino acid sequence has 60% identity with the human and rabbit R(GL). The 5' flanking region of the gene contains a TATA box, c-Myc sites, and a potential cAMP-responsive element. Muscle specific motifs, such as MyoD and MEF-2, were also found. The A-T rich 3'-UTR contained several polyadenylation signals, two associated with poly(A) down-stream consensus motifs. ARE elements, which regulate mRNA stability, were dispersed throughout the 3'-UTR. Northern analysis of poly(A) mRNA from various murine tissues indicates a major transcript of 7.5 kb in skeletal muscle and heart. Western analysis demonstrates that R(GL) protein is present in skeletal and cardiac muscle from mouse, rat, and rabbit but not in L6 myoblasts, L6 myotubes, 3T3 L1 fibroblasts, 3T3 L1 or rat primary adipocytes, confirming that expression of the gene is specific to striated muscle. Analysis of skeletal muscle from rats made diabetic by streptozotocin treatment reveals that the level of R(GL) protein is the same as in control animals, indicating that expression is not regulated by insulin.

Published

2001

41. Cellular Mechanisms Regulating Protein Phosphatase-1

Author

John H. Connor, Patricia T.W. Cohen, Deborah Frederick, Jie Yang, Shirish Shenolikar, Kelly Tatchell, Nicholas R. Helps, Hsien-bin Huang, Anna A. DePaoli-Roach, and Angus C. Nairn

Subjects

chemistry.chemical_classification, animal structures, Protein subunit, fungi, Phosphatase, Mutant, Protein phosphatase 1, Peptide, macromolecular substances, Cell Biology, Biology, environment and public health, Biochemistry, Amino acid, Serine, chemistry, Molecular Biology, Peptide sequence

Abstract

Inhibitor-1 (I-1) and inhibitor-2 (I-2) selectively inhibit type 1 protein serine/threonine phosphatases (PP1). To define the molecular basis for PP1 inhibition by I-1 and I-2 charged-to-alanine substitutions in the Saccharomyces cerevisiae, PP1 catalytic subunit (GLC7), were analyzed. Two PP1 mutants, E53A/E55A and K165A/E166A/K167A, showed reduced sensitivity to I-2 when compared with wild-type PP1. Both mutants were effectively inhibited by I-1. Two-hybrid analysis and coprecipitation or pull-down assays established that wild-type and mutant PP1 catalytic subunits bound I-2 in an identical manner and suggested a role for the mutated amino acids in enzyme inhibition. Inhibition of wild-type and mutant PP1 enzymes by full-length I-2(1–204), I-2(1–114), and I-2(36–204) indicated that the mutant enzymes were impaired in their interaction with the N-terminal 35 amino acids of I-2. Site-directed mutagenesis of amino acids near the N terminus of I-2 and competition for PP1 binding by a synthetic peptide encompassing an I-2 N-terminal sequence suggested that a PP1 domain composed of amino acids Glu-53, Glu-55, Asp-165, Glu-166, and Lys-167 interacts with the N terminus of I-2. This defined a novel regulatory interaction between I-2 and PP1 that determines I-2 potency and perhaps selectivity as a PP1 inhibitor.

Published

2000

42. Phosphorylation-dependent Inhibition of Protein Phosphatase-1 by G-substrate

Author

Anna A. DePaoli-Roach, Sean P. Collins, David M. Gamm, Enrique Massa, Michael D. Uhler, and Kelly Umstott Hall

Subjects

biology, Cyclin-dependent kinase 2, Protein phosphatase 1, Cell Biology, Autophagy-related protein 13, Mitogen-activated protein kinase kinase, Biochemistry, Molecular biology, MAP2K7, Cell biology, biology.protein, c-Raf, Protein kinase A, Molecular Biology, cGMP-dependent protein kinase

Abstract

G-substrate, a specific substrate of the cGMP-dependent protein kinase, has previously been localized to the Purkinje cells of the cerebellum. We report here the isolation from mouse brain of a cDNA encoding G-substrate. This cDNA was used to localize G-substrate mRNA expression, as well as to produce recombinant protein for the characterization of G-substrate phosphatase inhibitory activity. Brain and eye were the only tissues in which a G-substrate transcript was detected. Within the brain, G-substrate transcripts were restricted almost entirely to the Purkinje cells of the cerebellum, although transcripts were also detected at low levels in the paraventricular region of the hypothalamus and the pons/medulla. Like the native protein, the recombinant protein was preferentially phosphorylated by cGMP-dependent protein kinase (K m = 0.2 μm) over cAMP-dependent protein kinase (K m = 2.0 μm). Phospho-G-substrate inhibited the catalytic subunit of native protein phosphatase-1 with an IC50 of 131 ± 27 nm. Dephospho-G-substrate was not found to be inhibitory. Both dephospho- and phospho-G-substrate were weak inhibitors of native protein phosphatase-2A1, which dephosphorylated G-substrate 20 times faster than the catalytic subunit of protein phosphatase-1. G-substrate potentiated the action of cAMP-dependent protein kinase on a cAMP-regulated luciferase reporter construct, consistent with an inhibition of cellular phosphatases in vivo. These results provide the first demonstration that G-substrate inhibits protein phosphatase-1 and suggest a novel mechanism by which cGMP-dependent protein kinase I can regulate the activity of the type 1 protein phosphatases.

Published

1999

43. Binding of CTP:Phosphocholine Cytidylyltransferase to Lipid Vesicles: Diacylglycerol and Enzyme Dephosphorylation Increase the Affinity for Negatively Charged Membranes

Author

Rosemary B. Cornell, ‖ and Anna A. DePaoli-Roach, and Rebecca S. Arnold

Subjects

Membranes, Chemistry, Vesicle, Cytidylyltransferase, Phosphatidic Acids, Drug Synergism, Protein phosphatase 1, Phosphoproteins, Nucleotidyltransferases, Biochemistry, Diglycerides, Enzyme Activation, Dephosphorylation, chemistry.chemical_compound, Membrane, Phosphatidylcholine, lipids (amino acids, peptides, and proteins), Choline-Phosphate Cytidylyltransferase, Phosphorylation, Protein Binding, Diacylglycerol kinase, Phosphocholine

Abstract

The regulation of membrane binding and activity of purified CDP:phosphocholine cytidylyl-transferase (CT) by lipid activators and enzyme dephosphorylation was examined. The binding of CT to membranes was analyzed using sucrose-loaded vesicles (SLVs). Binding to phosphatidylcholine vesicles was not detected even at a lipid:protein ratio of approximately 2000 (1 mM PC). CT bound to vesicles containing anionic lipids with apparent molar partition coefficients between 2 x 10(5) and 2 x 10(6), depending on the vesicle charge. The vesicle binding and activation of CT showed very similar sigmoidal dependencies on the lipid negative charge. In addition, diacylglycerol interacted synergistically with anionic phospholipids to stimulate both binding and activation at lower mole percent anionic lipid. These results demonstrate parallel requirements for binding and activity. Dephosphorylation of CT without destabilization was accomplished using the catalytic subunit of protein phosphatase 1. Dephosphorylated CT required a lower mole percent anionic phospholipid than phosphorylated CT for binding to and activation by SLVs. The combination of 10 mol % diacylglycerol and enzyme dephosphorylation shifted the mole percent phosphatidic acid required for half-maximal activation from 25% to 12%. These results suggest a mechanism whereby large changes in CT activity can result from changes in the phosphorylation state combined with small alterations in the membrane content of diacylglycerol. We propose a mechanism whereby dephosphorylation on the domain adjacent to the membrane binding domain increases the affinity of the latter for a negatively charged membrane surface.

Published

1997

44. Structural basis for 2′-phosphate incorporation into glycogen by glycogen synthase

Author

Peter J. Roach, Thomas D. Hurley, Vimbai M. Chikwana, Vincent S. Tagliabracci, May Khanna, Anna A. DePaoli-Roach, Christopher J. Contreras, and Sulochanadevi Baskaran

Subjects

Models, Molecular, Crystallography, Magnetic Resonance Spectroscopy, Multidisciplinary, biology, Glycogen, Chemistry, Active site, Biological Sciences, Corrections, Mass Spectrometry, Phosphates, Glycogen debranching enzyme, Glycogen phosphorylase, chemistry.chemical_compound, Glycogen Synthase, Biochemistry, Mutagenesis, biology.protein, Glycogen branching enzyme, Transferase, Glycogen synthase, Phosphorylase kinase

Abstract

Glycogen is a glucose polymer that contains minor amounts of covalently attached phosphate. Hyperphosphorylation is deleterious to glycogen structure and can lead to Lafora disease. Recently, it was demonstrated that glycogen synthase catalyzes glucose-phosphate transfer in addition to its characteristic glucose transfer reaction. Glucose-1,2-cyclic-phosphate (GCP) was proposed to be formed from UDP-Glc breakdown and subsequently transferred, thus providing a source of phosphate found in glycogen. To gain further insight into the molecular basis for glucose-phosphate transfer, two structures of yeast glycogen synthase were determined; a 3.0-Å resolution structure of the complex with UMP/GCP and a 2.8-Å resolution structure of the complex with UDP/glucose. Structural superposition of the complexes revealed that the bound ligands and most active site residues are positioned similarly, consistent with the use of a common transfer mechanism for both reactions. The N-terminal domain of the UDP-glucose complex was found to be 13.3° more closed compared with a UDP complex. However, the UMP · GCP complex was 4.8° less closed than the glucose complex, which may explain the low efficiency of GCP transfer. Modeling of either α- or β-glucose or a mixture of both anomers can account for the observed electron density of the UDP-glucose complex. NMR studies of UDP-Glc hydrolysis by yeast glycogen synthase were used to verify the stereochemistry of the product, and they also showed synchronous GCP accumulation. The similarities in the active sites of glycogen synthase and glycogen phosphorylase support the idea of a common catalytic mechanism in GT-B enzymes independent of the specific reaction catalyzed.

Published

2013

45. Glycogen Metabolism and Lafora Disease

Author

Anna A. DePaoli-Roach and Peter J. Roach

Subjects

congenital, hereditary, and neonatal diseases and abnormalities, biology, Glycogen, Phosphatase, Hyperphosphorylation, Progressive myoclonus epilepsy, medicine.disease, Lafora disease, Cell biology, chemistry.chemical_compound, chemistry, Dual-specificity phosphatase, medicine, biology.protein, Glycogen synthase, Laforin

Abstract

Lafora disease is a juvenile-onset, fatal epilepsy that is characterized by the formation of Lafora bodies in many tissues, including skeletal muscle, heart, and neurons. Lafora bodies are insoluble deposits that contain polyglucosan, a poorly branched form of glycogen, and associated proteins. Evidence is mounting that Lafora bodies either cause or contribute to the pathology of the disease. It is a genetic disease caused by mutation in one of two genes, EPM2A and EPM2B, which encode, respectively, a phosphatase called laforin and an E3 ubiquitin ligase called malin. Laforin is a phosphatase of the atypical dual specificity phosphatase subfamily that, in vitro and in vivo, removes phosphate monoesters from glycogen. Normal glycogen contains trace amounts of phosphate introduced as a minor side reaction by the synthetic enzyme, glycogen synthase. In laforin knockout mice, glycogen becomes hyperphosphorylated and, as the mice age, acquires structural abnormalities and the tendency to come out of solution, consistent with Lafora body formation. Mutation of malin or laforin results in similar symptoms in patients and malin and laforin knockout mice exhibit phenotypic similarity in terms of neurological defects and abnormal glycogen metabolism, including hyperphosphorylation and Lafora body formation.

Published

2013

46. High Complexity in the Expression of the B′ Subunit of Protein Phosphatase 2A0

Author

Stephen D. Durbin, Stanislaw Zolnierowicz, Anna A. DePaoli-Roach, Éva Bakó, and Csilla Csortos

Subjects

Gene isoform, cDNA library, Protein subunit, Complementary DNA, Alternative splicing, Phosphatase, Cell Biology, Protein phosphatase 2, Biology, Molecular Biology, Biochemistry, Molecular biology, Homology (biology)

Abstract

Association of the catalytic subunit (C2) with a variety of regulatory subunits is believed to modulate the activity and specificity of protein phosphatase 2A (PP2A). In this study we report the cloning and expression of a new family of B-subunit, the B′, associated with the PP2A0 form. Polymerase chain reactions and cDNA library screening have identified at least seven cDNA isotypes, designated α, β1, β2, β3, β4, γ, and δ. The different β subtypes appear to be generated by alternative splicing. The deduced amino acid sequences of the α, β2, β3, β4 and γ isoforms predict molecular weights of 57,600, 56,500, 60,900, 52,500, and 68,000, respectively. The proteins are 60-80% identical and differ mostly at their termini. Two of the isoforms, B′β3 and B′γ, contain a bipartite nuclear localization signal in their COOH terminus. No homology was found with other B- or Brelated subunits. Northern analyses indicate a tissuespecific expression of the isoforms. Expression of B′α protein in Escherichia coli generated a polypeptide of ∼53 kDa, similar to the size of the B′ subunit present in the purified PP2A0. The recombinant protein was recognized by antibody raised against native B′ and interacted with the dimeric PP2A (A•C2) to generate a trimeric phosphatase. The deduced amino acid sequences of the B′ isoforms show significant homology to mammalian, fungal, and plant nucleotide sequences of unknown function present in the data bases. Notably, a high degree of homology (55-66%) was found with a yeast gene, RTS1, encoding a multicopy suppressor of a rox3 mutant. Our data indicate that at least seven B′ subunit isoforms may participate in the generation of a large number of PP2A0 holoenzymes that may be spatially and/or functionally targeted to different cellular processes.

Published

1996

47. Phosphorylation and Activation of the ATP-Mg-dependent Protein Phosphatase by the Mitogen-activated Protein Kinase

Author

Kun-Liang Guan, Peter J. Roach, Q. May Wang, and Anna A. DePaoli-Roach

Subjects

Molecular Sequence Data, Phosphatase, DUSP6, Protein Serine-Threonine Kinases, Biochemistry, Glycogen Synthase Kinase 3, Adenosine Triphosphate, Cytosol, Ca2+/calmodulin-dependent protein kinase, Phosphoprotein Phosphatases, Animals, Amino Acid Sequence, c-Raf, Amino Acids, Phosphorylation, Phosphorylase Phosphatase, Protein kinase A, Molecular Biology, Mitogen-Activated Protein Kinase 3, biology, Chemistry, Akt/PKB signaling pathway, Muscles, Ribosomal Protein S6 Kinases, Glycogen Synthase Kinases, Cell Biology, Protein phosphatase 2, Enzyme Activation, Calcium-Calmodulin-Dependent Protein Kinases, biology.protein, Rabbits, Mitogen-Activated Protein Kinases, Signal Transduction

Abstract

Inhibitor-2 (I-2) is the regulatory subunit of the cytosolic ATP-Mg-dependent form of type 1 serine/threonine protein phosphatase and its phosphorylation at Thr-72 by glycogen synthase kinase-3 results in phosphatase activation. Activation of cytosolic type 1 phosphatase has been observed in cells treated with growth factors. Reported here is the phosphorylation and activation of the ATP-Mg-dependent phosphatase by mitogen-activated protein kinase (MAPK). Recombinant I-2 was phosphorylated by activated MAPK to an extent (~0.3 mol of phosphate/mol of polypeptide) similar to that reported for phosphorylation by the α isoform of glycogen synthase kinase-3. The phosphorylation of I-2 by MAPK was exclusively at Thr-72, the site involved in the activation of phosphatase. Incubation of MAPK with purified ATP-Mg-dependent phosphatase resulted in phosphorylation of the I-2 component and activation of the phosphatase. Ribosomal S6 protein kinase II (p90rsk) was also able to phosphorylate the recombinant I-2; however, this phosphorylation occurred on serines and had no effect on phosphatase activation. Our data may explain growth factor-induced activation of the ATP-Mg-dependent phosphatase and suggest that MAPK may be the physiological kinase responsible for the activation of cytosolic type 1 phosphatase in response to insulin and/or other growth factors.

Published

1995

48. In vivo regulation of protein kinase C by trans-phosphorylation followed by autophosphorylation

Author

Anna A. DePaoli-Roach, Alexandra C. Newton, L. M. Keranen, and E M Dutil

Subjects

MAP kinase kinase kinase, biology, Autophosphorylation, Cyclin-dependent kinase 2, Cell Biology, Mitogen-activated protein kinase kinase, Biochemistry, MAP2K7, biology.protein, Cyclin-dependent kinase 9, c-Raf, Casein kinase 2, Molecular Biology

Abstract

Dephosphorylation by the catalytic subunits of protein phosphatases 1 (CS1) and 2A (CS2) reveals that mature protein kinase C is phosphorylated at two distinct sites. Treatment of protein kinase C beta II with CS1 causes a significant increase in the protein's electrophoretic mobility (approximately 4 kDa) and a coincident loss in catalytic activity. The CS1-dephosphorylated enzyme cannot autophosphorylate or be phosphorylated by mature protein kinase C, indicating that a different kinase catalyzes the phosphorylation at this site. The loss of activity is consistent with dephosphorylation on protein kinase C's activation loop (Orr, J. W., and Newton, A. C., (1994) J. Biol. Chem. 269, 27715-27718). Treatment with CS2 results in a smaller shift in electrophoretic mobility (approximately 2 kDa) and no loss in catalytic activity. Furthermore, the CS2-dephosphorylated form can autophosphorylate and thus regain the electrophoretic mobility of mature enzyme, consistent with dephosphorylation at protein kinase C's carboxyl-terminal autophosphorylation site, which is modified in vivo (Flint, A. J., Paladini, R. D., and Koshland, D. E., Jr. (1990) Science 249, 408-411). In summary, two phosphorylations process protein kinase C to generate the mature form: a transphosphorylation that renders the kinase catalytically competent and an autophosphorylation that may be important for the subcellular localization of the enzyme.

Published

1994

49. Domains of phosphatase inhibitor-2 involved in the control of the ATP-Mg-dependent protein phosphatase

Author

In-Kyung Park and Anna A. DePaoli-Roach

Subjects

Mutation, biology, Protein subunit, Phosphatase, Mutant, Cell Biology, Protein phosphatase 2, medicine.disease_cause, Biochemistry, Molecular biology, medicine, biology.protein, Phosphatase complex, Casein kinase 2, Glycogen synthase, Molecular Biology

Abstract

Inhibitor-2 (I-2) inhibits the free catalytic subunit of type 1 phosphatase (CS1) and controls the cyclic inactivation/activation of CS1 in the ATP-Mg-dependent protein phosphatase complex. We report here the effect of mutations on these two properties of I-2. Substitution of Thr-72 with Ala, Asp, or Glu generated complexes with CS1 that could not be activated. Mutation of Ser-86 did not affect activation by glycogen synthase kinase-3 (GSK-3) alone but impaired synergistic activation by casein kinase II and GSK-3. Mutations in the region between Thr-72 and Ser-86 did not alter the inhibitory potency of I-2 but prevented complete inactivation of CS1. A mutant without the 35 NH2-terminal residues exhibited an IC50 for CS1 200-fold higher than that of wild-type I-2. However, it formed an inactive phosphatase complex with CS1, which was activated by GSK-3. A mutant with the 59 COOH-terminal residues deleted retained full inhibitory activity and formed an inactive complex that could not be activated by GSK-3. We conclude that the NH2-terminal region of I-2 is involved in inhibition, that the sequence between Thr-72 and Ser-86 is necessary for the conversion of CS1 from an active to an inactive conformation, and that the COOH terminus is required for activation by GSK-3. Thus, different functional domains of I-2 may interact with distinct regions of CS1.

Published

1994

50. Diversity in the Regulatory B-Subunits of Protein Phosphatase 2A: Identification of a Novel Isoform Highly Expressed in Brain

Author

Jeffry Bondor, Marc C. Mumby, Anna A. DePaoli-Roach, Alexander D. Verin, Stanislaw Zolnierowicz, and Csilla Csortos

Subjects

Gene isoform, Protein Conformation, Protein subunit, Molecular Sequence Data, Molecular cloning, Biology, Biochemistry, Allosteric Regulation, Western blot, Complementary DNA, Phosphoprotein Phosphatases, medicine, Animals, Tissue Distribution, Amino Acid Sequence, Protein Phosphatase 2, RNA, Messenger, Northern blot, Cloning, Molecular, Muscle, Skeletal, Peptide sequence, G alpha subunit, Base Sequence, Sequence Homology, Amino Acid, medicine.diagnostic_test, Brain, Molecular biology, Rabbits, Sequence Analysis

Abstract

The physiological role of type 2A protein phosphatases (PP2A) is dependent upon the association of the catalytic subunit with a variety of regulatory subunits. In order to understand the function of PP2A, we have undertaken purification of the holoenzymes and molecular cloning of the regulatory subunits. Two trimeric forms containing distinct B-subunits, PP2A0 and PP2A1, have been purified from rabbit skeletal muscle. The B-subunits associated with PP2A0 and PP2A1 migrated on sodium dodecyl sulfate-polyacrylamide gel electrophoresis with slightly different mobility, approximately 52.5 and approximately 51.5 kDa, respectively and showed distinct immunological properties. The B' form of B-subunit associated with PP2A0 was recognized by antibodies against the B-subunit present in bovine heart PP2A but not by antibodies specific to the B subunit isoforms of rabbit PP2A1. Cloning of cDNAs encoding the B subunit of PP2A1 resulted in the isolation of a cDNA highly homologous to, but distinct from, the B alpha subunit isoform. The deduced amino acid sequence of this novel isoform, which was designated B gamma, encoded a protein which was 81% and 87% identical to the B alpha and B beta isoforms, respectively. Northern blot analysis indicated that the B gamma isoform is highly expressed in rabbit brain as a transcript of 3.9 kb. Analysis of B-subunit expression by Western blot indicated a general parallel with the message levels. In conclusion, our data reveal even greater complexity of PP2A trimeric holoenzymes due to the identification of a novel B regulatory subunit isoform of PP2A1 and a distinct B' subunit associated with PP2A0.

Published

1994