Sodium valproate increases the brain isoform of glycogen phosphorylase: looking for a compensation mechanism in McArdle disease using a mouse primary skeletal-muscle culture in vitro

Sodium valproate increases the brain isoform of glycogen phosphorylase: looking for a compensation mechanism in McArdle disease using a mouse primary skeletal-muscle culture in vitro

McArdle disease, also termed ‘glycogen storage disease type V’, is a disorder of skeletal muscle carbohydrate metabolism caused by inherited deficiency of the muscle-specific isoform of glycogen phosphorylase (GP-MM). It is an autosomic recessive disorder that is caused by mutations in the PYGM gene...

Full description

Bibliographic Details
Main Authors: Noemí de Luna, Astrid Brull, Josep Maria Guiu, Alejandro Lucia, Miguel Angel Martin, Joaquin Arenas, Ramon Martí, Antoni L. Andreu, Tomàs Pinós
Format: Article
Language:English
Published: The Company of Biologists 2015-05-01
Series:Disease Models & Mechanisms
Subjects:
Glycogen phosphorylase
Glycogenolysis
McArdle disease
Myotubes
Sodium valproate
Online Access:http://dmm.biologists.org/content/8/5/467
id doaj-25556bc966214bc1b4172e67ed73f5e2
record_format Article
spelling doaj-25556bc966214bc1b4172e67ed73f5e22020-11-24T21:47:26ZengThe Company of BiologistsDisease Models & Mechanisms1754-84111754-84032015-05-018546747210.1242/dmm.020230020230Sodium valproate increases the brain isoform of glycogen phosphorylase: looking for a compensation mechanism in McArdle disease using a mouse primary skeletal-muscle culture in vitroNoemí de Luna0Astrid Brull1Josep Maria Guiu2Alejandro Lucia3Miguel Angel Martin4Joaquin Arenas5Ramon Martí6Antoni L. Andreu7Tomàs Pinós8 Mitochondrial Pathology and Neuromuscular Disorders Laboratory, Vall d'Hebron Research Institute, Universitat Autònoma de Barcelona, Barcelona 08035, Spain Mitochondrial Pathology and Neuromuscular Disorders Laboratory, Vall d'Hebron Research Institute, Universitat Autònoma de Barcelona, Barcelona 08035, Spain Mitochondrial Pathology and Neuromuscular Disorders Laboratory, Vall d'Hebron Research Institute, Universitat Autònoma de Barcelona, Barcelona 08035, Spain Universidad Europea, Madrid 28670, Spain Instituto de Investigación ‘i+12’, Madrid 28041, Spain Instituto de Investigación ‘i+12’, Madrid 28041, Spain Mitochondrial Pathology and Neuromuscular Disorders Laboratory, Vall d'Hebron Research Institute, Universitat Autònoma de Barcelona, Barcelona 08035, Spain Mitochondrial Pathology and Neuromuscular Disorders Laboratory, Vall d'Hebron Research Institute, Universitat Autònoma de Barcelona, Barcelona 08035, Spain Mitochondrial Pathology and Neuromuscular Disorders Laboratory, Vall d'Hebron Research Institute, Universitat Autònoma de Barcelona, Barcelona 08035, Spain McArdle disease, also termed ‘glycogen storage disease type V’, is a disorder of skeletal muscle carbohydrate metabolism caused by inherited deficiency of the muscle-specific isoform of glycogen phosphorylase (GP-MM). It is an autosomic recessive disorder that is caused by mutations in the PYGM gene and typically presents with exercise intolerance, i.e. episodes of early exertional fatigue frequently accompanied by rhabdomyolysis and myoglobinuria. Muscle biopsies from affected individuals contain subsarcolemmal deposits of glycogen. Besides GP-MM, two other GP isoforms have been described: the liver (GP-LL) and brain (GP-BB) isoforms, which are encoded by the PYGL and PYGB genes, respectively; GP-BB is the main GP isoform found in human and rat foetal tissues, including the muscle, although its postnatal expression is dramatically reduced in the vast majority of differentiated tissues with the exception of brain and heart, where it remains as the major isoform. We developed a cell culture model from knock-in McArdle mice that mimics the glycogen accumulation and GP-MM deficiency observed in skeletal muscle from individuals with McArdle disease. We treated mouse primary skeletal muscle cultures in vitro with sodium valproate (VPA), a histone deacetylase inhibitor. After VPA treatment, myotubes expressed GP-BB and a dose-dependent decrease in glycogen accumulation was also observed. Thus, this in vitro model could be useful for high-throughput screening of new drugs to treat this disease. The immortalization of these primary skeletal muscle cultures could provide a never-ending source of cells for this experimental model. Furthermore, VPA could be considered as a gene-expression modulator, allowing compensatory expression of GP-BB and decreased glycogen accumulation in skeletal muscle of individuals with McArdle disease.http://dmm.biologists.org/content/8/5/467Glycogen phosphorylaseGlycogenolysisMcArdle diseaseMyotubesSodium valproate
collection DOAJ
language English
format Article
sources DOAJ
author Noemí de Luna
Astrid Brull
Josep Maria Guiu
Alejandro Lucia
Miguel Angel Martin
Joaquin Arenas
Ramon Martí
Antoni L. Andreu
Tomàs Pinós
spellingShingle Noemí de Luna
Astrid Brull
Josep Maria Guiu
Alejandro Lucia
Miguel Angel Martin
Joaquin Arenas
Ramon Martí
Antoni L. Andreu
Tomàs Pinós
Sodium valproate increases the brain isoform of glycogen phosphorylase: looking for a compensation mechanism in McArdle disease using a mouse primary skeletal-muscle culture in vitro
Disease Models & Mechanisms
Glycogen phosphorylase
Glycogenolysis
McArdle disease
Myotubes
Sodium valproate
author_facet Noemí de Luna
Astrid Brull
Josep Maria Guiu
Alejandro Lucia
Miguel Angel Martin
Joaquin Arenas
Ramon Martí
Antoni L. Andreu
Tomàs Pinós
author_sort Noemí de Luna
title Sodium valproate increases the brain isoform of glycogen phosphorylase: looking for a compensation mechanism in McArdle disease using a mouse primary skeletal-muscle culture in vitro
title_short Sodium valproate increases the brain isoform of glycogen phosphorylase: looking for a compensation mechanism in McArdle disease using a mouse primary skeletal-muscle culture in vitro
title_full Sodium valproate increases the brain isoform of glycogen phosphorylase: looking for a compensation mechanism in McArdle disease using a mouse primary skeletal-muscle culture in vitro
title_fullStr Sodium valproate increases the brain isoform of glycogen phosphorylase: looking for a compensation mechanism in McArdle disease using a mouse primary skeletal-muscle culture in vitro
title_full_unstemmed Sodium valproate increases the brain isoform of glycogen phosphorylase: looking for a compensation mechanism in McArdle disease using a mouse primary skeletal-muscle culture in vitro
title_sort sodium valproate increases the brain isoform of glycogen phosphorylase: looking for a compensation mechanism in mcardle disease using a mouse primary skeletal-muscle culture in vitro
publisher The Company of Biologists
series Disease Models & Mechanisms
issn 1754-8411
1754-8403
publishDate 2015-05-01
description McArdle disease, also termed ‘glycogen storage disease type V’, is a disorder of skeletal muscle carbohydrate metabolism caused by inherited deficiency of the muscle-specific isoform of glycogen phosphorylase (GP-MM). It is an autosomic recessive disorder that is caused by mutations in the PYGM gene and typically presents with exercise intolerance, i.e. episodes of early exertional fatigue frequently accompanied by rhabdomyolysis and myoglobinuria. Muscle biopsies from affected individuals contain subsarcolemmal deposits of glycogen. Besides GP-MM, two other GP isoforms have been described: the liver (GP-LL) and brain (GP-BB) isoforms, which are encoded by the PYGL and PYGB genes, respectively; GP-BB is the main GP isoform found in human and rat foetal tissues, including the muscle, although its postnatal expression is dramatically reduced in the vast majority of differentiated tissues with the exception of brain and heart, where it remains as the major isoform. We developed a cell culture model from knock-in McArdle mice that mimics the glycogen accumulation and GP-MM deficiency observed in skeletal muscle from individuals with McArdle disease. We treated mouse primary skeletal muscle cultures in vitro with sodium valproate (VPA), a histone deacetylase inhibitor. After VPA treatment, myotubes expressed GP-BB and a dose-dependent decrease in glycogen accumulation was also observed. Thus, this in vitro model could be useful for high-throughput screening of new drugs to treat this disease. The immortalization of these primary skeletal muscle cultures could provide a never-ending source of cells for this experimental model. Furthermore, VPA could be considered as a gene-expression modulator, allowing compensatory expression of GP-BB and decreased glycogen accumulation in skeletal muscle of individuals with McArdle disease.
topic Glycogen phosphorylase
Glycogenolysis
McArdle disease
Myotubes
Sodium valproate
url http://dmm.biologists.org/content/8/5/467
work_keys_str_mv AT noemideluna sodiumvalproateincreasesthebrainisoformofglycogenphosphorylaselookingforacompensationmechanisminmcardlediseaseusingamouseprimaryskeletalmusclecultureinvitro
AT astridbrull sodiumvalproateincreasesthebrainisoformofglycogenphosphorylaselookingforacompensationmechanisminmcardlediseaseusingamouseprimaryskeletalmusclecultureinvitro
AT josepmariaguiu sodiumvalproateincreasesthebrainisoformofglycogenphosphorylaselookingforacompensationmechanisminmcardlediseaseusingamouseprimaryskeletalmusclecultureinvitro
AT alejandrolucia sodiumvalproateincreasesthebrainisoformofglycogenphosphorylaselookingforacompensationmechanisminmcardlediseaseusingamouseprimaryskeletalmusclecultureinvitro
AT miguelangelmartin sodiumvalproateincreasesthebrainisoformofglycogenphosphorylaselookingforacompensationmechanisminmcardlediseaseusingamouseprimaryskeletalmusclecultureinvitro
AT joaquinarenas sodiumvalproateincreasesthebrainisoformofglycogenphosphorylaselookingforacompensationmechanisminmcardlediseaseusingamouseprimaryskeletalmusclecultureinvitro
AT ramonmarti sodiumvalproateincreasesthebrainisoformofglycogenphosphorylaselookingforacompensationmechanisminmcardlediseaseusingamouseprimaryskeletalmusclecultureinvitro
AT antonilandreu sodiumvalproateincreasesthebrainisoformofglycogenphosphorylaselookingforacompensationmechanisminmcardlediseaseusingamouseprimaryskeletalmusclecultureinvitro
AT tomaspinos sodiumvalproateincreasesthebrainisoformofglycogenphosphorylaselookingforacompensationmechanisminmcardlediseaseusingamouseprimaryskeletalmusclecultureinvitro
_version_ 1725896915342589952

Similar Items