grant

The effect of muscle-specific anchoring protein on the biology of the Neuromuscular system

Organization UNIVERSITY OF MICHIGAN AT ANN ARBORLocation ANN ARBOR, UNITED STATESPosted 1 Apr 2019Deadline 31 Mar 2027
NIHUS FederalResearch GrantFY202420S Catalytic Proteasome20S Core Proteasome20S Proteasome20S Proteosome21+ years oldACh ReceptorsAPF-1ATP-Dependent Proteolysis Factor 1AbscissionAcetylcholine ReceptorsAdultAdult HumanAffectAnimalsBiologic ModelsBiological ModelsBiologyCa(2+)-Calmodulin Dependent Protein KinaseCaMKCalciumCalcium/calmodulin-dependent protein kinaseCalmodulin-Dependent Protein KinasesCalmodulin-KinaseCell BodyCell surfaceCellsCholinergic ReceptorsCholinoceptive SitesCholinoceptorsComplexDataDevelopmentDoseDystrophinEndocytosisEsteroproteasesExcisionExocytosisExtirpationGenesGlycoproteinsGoalsHMG-20High Mobility Protein 20ImpairmentIn VitroKnock-outKnockoutLifeLinkMacropainMacroxyproteinaseMaintenanceMetabolicMiceMice MammalsModel SystemModelingMolecularMotor CellMotor NeuronsMulticatalytic ProteinaseMurineMusMuscleMuscle CellsMuscle FibersMuscle TissueMutant Strains MiceMyocytesMyoneural JunctionMyotubesNAC precursorNervous System DiseasesNervous System DisorderNeural TransmissionNeurologic DisordersNeurological DisordersNeuromuscular DiseasesNeuromuscular JunctionNicotinic Acetylcholine ReceptorsNicotinic ReceptorsOutcome StudyPARK1 proteinPARK4 proteinPathway interactionsPeptidasesPeptide HydrolasesPhenotypePlayPostsynaptic MembraneProcessProsomeProtease GeneProteasesProteasomeProteasome Endopeptidase ComplexProteinasesProteinsProteolytic EnzymesProteosomeReceptor ProteinRemovalRhabdomyocyteRoleSNCASNCA proteinScaffolding ProteinShapesSiteSkeletal FiberSkeletal MuscleSkeletal Muscle CellSkeletal Muscle FiberSkeletal MyocytesSpinalSurgical RemovalSynapsesSynapticSynaptic ReceptorsSynaptic TransmissionSystemTestingTimeTranscriptTransfectionUbiquitinVoluntary MuscleWorka-syna-synucleinadult youthadulthoodalpha synucleinalpha synuclein genealpha-dystrobrevinalpha-syntrophinalphaSP22asyncalcium-calmodulin-dependent PKcalcium-calmodulin-dependent PK type IIcalmodulin dependent protein kinasede-ubiquitinasede-ubiquitinating enzymedensitydevelopmentalgain of functionin vivo Modelknock-downknockdownloss of functionmicrotubule associated protein 2 kinasemotoneuronmouse mutantmulticatalytic endopeptidase complexmuscularmyoneural disorderneurological diseaseneuromotor systemneuromuscularneuromuscular degenerative disorderneuromuscular disorderneuromuscular systemnew approachesnon A-beta component of AD amyloidnon A4 component of amyloid precursornovel approachesnovel strategiesnovel strategyoverexpressoverexpressionpathwaypost-natal periodpostnatalpostnatal periodpostsynapticprotein complexprotein kinase IIreceptorreceptor densityreceptor recyclingresectionshRNAshort hairpin RNAsmall hairpin RNAsocial rolesynapsesynapse formationsynaptic pruningsynaptogenesissyntrophinsyntrophin alpha1syntrophin-1traffickingubiquitin isopeptidaseubiquitin-specific isopeptidaseyoung adultyoung adulthoodα synuclein geneα-dystrobrevinα-synα-syntrophinα-synuclein
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Full Description

Stable and efficient synaptic transmission depends largely on the maintenance of a high
number/density of postsynaptic receptors at synaptic sites. At the neuromuscular junction
(NMJ), the synapse between spinal motor neurons and skeletal muscle cells, the mechanisms
that regulate the stability of postsynaptic nicotinic acetylcholine receptors (AChRs) over the
lifetime of animals remain largely unknown. Recent studies from our lab showed that αkap, a
non-kinase muscle anchoring protein encoded within the calcium/calmodulin kinase II α gene,
plays an important role in regulating the stability of nicotinic acetylcholine receptors (AChRs)
and the structural integrity of the NMJ. In view of these results, we propose in the first aim to
investigate the effect of αkap knockdown during the development of healthy neuromuscular
synapses. In the second aim we propose to investigate the effect of the gain of function of αkap
on the maturation and maintenance of compromised NMJs using mice deficient in the sub-
complex of the dystrophin glycoprotein complex (DGC) (α-syntrophin and α-dystrobrevin). In the
third aim we propose to investigate the molecular mechanistic link between the DGC sub-
complex/αkap/ the deubiquitinating protease USP9X and the stability of AChR stability in mice
deficient in α-syntrophin/α-dystrobrevin, and USP9X. The outcomes of these studies will be
relevant for many neuromuscular diseases where the number and density of AChRs are
compromised.

Grant Number: 5R01NS111041-05
NIH Institute/Center: NIH
Principal Investigator: MOHAMMED AKAABOUNE

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