Lack of Glycogenin Causes Glycogen Accumulation and Muscle Function Impairment

Giorgia Testoni; Jordi Duran; Mar García-Rocha; Francisco Vilaplana; Antonio L. Serrano; David Sebastián; Iliana López-Soldado; Mitchell A. Sullivan; Felipe Slebe; Marta Vilaseca; Pura Muñoz-Cánoves; Joan J. Guinovart

doi:10.1016/j.cmet.2017.06.008

Lack of Glycogenin Causes Glycogen Accumulation and Muscle Function Impairment

Giorgia Testoni
, Jordi Duran
, Mar García-Rocha
, Francisco Vilaplana
, Antonio L. Serrano
, David Sebastián
, Iliana López-Soldado
, Mitchell A. Sullivan
, Felipe Slebe
, Marta Vilaseca
, Pura Muñoz-Cánoves
, Joan J. Guinovart^*

^*Corresponding author for this work

Research output: Indexed journal article › Article › peer-review

73 Citations (Scopus)

Abstract

Glycogenin is considered essential for glycogen synthesis, as it acts as a primer for the initiation of the polysaccharide chain. Against expectations, glycogenin-deficient mice (Gyg KO) accumulate high amounts of glycogen in striated muscle. Furthermore, this glycogen contains no covalently bound protein, thereby demonstrating that a protein primer is not strictly necessary for the synthesis of the polysaccharide in vivo. Strikingly, in spite of the higher glycogen content, Gyg KO mice showed lower resting energy expenditure and less resistance than control animals when subjected to endurance exercise. These observations can be attributed to a switch of oxidative myofibers toward glycolytic metabolism. Mice overexpressing glycogen synthase in the muscle showed similar alterations, thus indicating that this switch is caused by the excess of glycogen. These results may explain the muscular defects of GSD XV patients, who lack glycogenin-1 and show high glycogen accumulation in muscle. Although glycogenin is thought to be essential for glycogen synthesis, Testoni et al. show that glycogenin-deficient animals still make glycogen. Surprisingly, glycogen accumulates in striated muscle affecting functionality, including decreased exercise endurance.

Original language	English
Pages (from-to)	256-266.e4
Number of pages	15
Journal	Cell Metabolism
Volume	26
Issue number	1
DOIs	https://doi.org/10.1016/j.cmet.2017.06.008
Publication status	Published - 5 Jul 2017
Externally published	Yes

Keywords

GSD XV
Glycogenin
exercise
glycogen
glycogen storage disease XV
glycogenosis
mitochondrial respiration
muscle performance
oxidative metabolism
priming protein

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10.1016/j.cmet.2017.06.008

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title = "Lack of Glycogenin Causes Glycogen Accumulation and Muscle Function Impairment",

abstract = "Glycogenin is considered essential for glycogen synthesis, as it acts as a primer for the initiation of the polysaccharide chain. Against expectations, glycogenin-deficient mice (Gyg KO) accumulate high amounts of glycogen in striated muscle. Furthermore, this glycogen contains no covalently bound protein, thereby demonstrating that a protein primer is not strictly necessary for the synthesis of the polysaccharide in vivo. Strikingly, in spite of the higher glycogen content, Gyg KO mice showed lower resting energy expenditure and less resistance than control animals when subjected to endurance exercise. These observations can be attributed to a switch of oxidative myofibers toward glycolytic metabolism. Mice overexpressing glycogen synthase in the muscle showed similar alterations, thus indicating that this switch is caused by the excess of glycogen. These results may explain the muscular defects of GSD XV patients, who lack glycogenin-1 and show high glycogen accumulation in muscle. Although glycogenin is thought to be essential for glycogen synthesis, Testoni et al. show that glycogenin-deficient animals still make glycogen. Surprisingly, glycogen accumulates in striated muscle affecting functionality, including decreased exercise endurance.",

keywords = "GSD XV, Glycogenin, exercise, glycogen, glycogen storage disease XV, glycogenosis, mitochondrial respiration, muscle performance, oxidative metabolism, priming protein",

author = "Giorgia Testoni and Jordi Duran and Mar Garc{\'i}a-Rocha and Francisco Vilaplana and Serrano, \{Antonio L.\} and David Sebasti{\'a}n and Iliana L{\'o}pez-Soldado and Sullivan, \{Mitchell A.\} and Felipe Slebe and Marta Vilaseca and Pura Mu{\~n}oz-C{\'a}noves and Guinovart, \{Joan J.\}",

note = "Funding Information: We wish to thank the following members of IRB Barcelona: Anna Adrover, Emma Veza, Natalia Plana, and Vanessa Hernandez for technical assistance; and Dr. Antonio Zorzano for essential reagents and advice, the histopathology, the mouse mutant, and the biostatistics/bioinformatics core facilities. Thanks also to Dr. Marina Gay for mass spectrometry advice and data analysis and Dr. Mireia D{\'i}az-Lobo for mass spectrometry experiments. Mass spectrometry was performed at the IRB Barcelona Mass Spectrometry and Proteomics Core Facility, which actively participates in the BMBS European COST Action BM 1403 and is a member of Proteored , PRB2-ISCIII, supported by grant PRB2 (IPT13/0001 - ISCIII-SGEFI / FEDER). Thanks also to Dr. Carmen Lopez-Iglesias (University of Barcelona) for assistance with the electron microscope. G.T. is supported by the “La Caixa” PhD Fellowship Program. IRB Barcelona is the recipient of a Severo Ochoa Award of Excellence from MINECO (Government of Spain). This study was supported by grants from the Spanish MINECO ( BFU2011-30554-C02-00 and SAF2014-54525-P ). M.A.S. was supported by an NHMRC CJ Martin Fellowship ( GNT1092451 ). NIH grants to Velocigene at Regeneron ( U01HG004085 ) and the CSD Consortium ( U01HG004080 ) funded the generation of gene-targeted ES cells in the KOMP Program. None of the supporting agencies had any role in establishing the work or in writing the manuscript. Publisher Copyright: {\textcopyright} 2017 Elsevier Inc.",

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doi = "10.1016/j.cmet.2017.06.008",

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AU - Serrano, Antonio L.

AU - Sebastián, David

AU - López-Soldado, Iliana

AU - Sullivan, Mitchell A.

AU - Slebe, Felipe

AU - Vilaseca, Marta

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AU - Guinovart, Joan J.

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PY - 2017/7/5

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N2 - Glycogenin is considered essential for glycogen synthesis, as it acts as a primer for the initiation of the polysaccharide chain. Against expectations, glycogenin-deficient mice (Gyg KO) accumulate high amounts of glycogen in striated muscle. Furthermore, this glycogen contains no covalently bound protein, thereby demonstrating that a protein primer is not strictly necessary for the synthesis of the polysaccharide in vivo. Strikingly, in spite of the higher glycogen content, Gyg KO mice showed lower resting energy expenditure and less resistance than control animals when subjected to endurance exercise. These observations can be attributed to a switch of oxidative myofibers toward glycolytic metabolism. Mice overexpressing glycogen synthase in the muscle showed similar alterations, thus indicating that this switch is caused by the excess of glycogen. These results may explain the muscular defects of GSD XV patients, who lack glycogenin-1 and show high glycogen accumulation in muscle. Although glycogenin is thought to be essential for glycogen synthesis, Testoni et al. show that glycogenin-deficient animals still make glycogen. Surprisingly, glycogen accumulates in striated muscle affecting functionality, including decreased exercise endurance.

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KW - GSD XV

KW - Glycogenin

KW - exercise

KW - glycogen

KW - glycogen storage disease XV

KW - glycogenosis

KW - mitochondrial respiration

KW - muscle performance

KW - oxidative metabolism

KW - priming protein

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ER -

Lack of Glycogenin Causes Glycogen Accumulation and Muscle Function Impairment

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Keywords

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