Abstract
Glycogen synthase kinase 3beta (GSK3beta) has been identified to play important roles in neuronal death. Evidence from both in vitro and in vivo studies indicates that increased GSK3beta activity contributes to neurodegeneration and to the pathogenesis of Alzheimer disease. But the molecular mechanisms that underlie GSK3beta-mediated neurotoxicity remain poorly understood. We reported here that myocyte enhancer factor 2D (MEF2D), a nuclear transcription factor known to promote neuronal survival, is directly phosphorylated by GSK3beta. Our data showed that phosphorylation of MEF2D by GSK3beta at three specific residues in its transactivation domain inhibits MEF2D transcriptional activity. Withdrawal of neuronal activity in cerebellar granule neurons activated GSK3beta in the nucleus, leading to GSK3beta-dependent inhibition of MEF2 function. This inhibition contributed to GSK3beta-mediated neuronal toxicity. Overexpression of MEF2D mutant that is resistant to GSK3beta inhibition protected cerebellar granule neurons from either GSK3beta activation- or neuronal activity deprivation-induced toxicity. These results identify survival factor MEF2D as a novel downstream effector targeted by GSK3beta and define a molecular link between activation of GSK3beta and neuronal survival machinery which may underlie in part GSK3beta-mediated neurotoxicity.
Highlights
GSK3 has been shown to regulate several substrates implicated in the pathogenesis of Alzheimer disease, including microtubule-associated protein Tau [9], much remains to be learned on whether GSK3 directly regulates factors required for neuronal survival
In this study we examined the regulating of myocyte enhancer factor 2D (MEF2D) in cerebellar granule neuron death induced by potassium withdrawal
To test if nuclear GSK3 is regulated in cerebellar granule neurons under low concentration of potassium chloride, Cerebellar Granule Neurons (CGNs) cultured in medium containing serum and depolarizing concentrations of KCl (29 mM) were switched to medium containing no serum with either depolarizing concentrations or low concentrations of KCl (5 mM)
Summary
GSK3 directly phosphorylated MEF2D at multiple sites, which inhibits MEF2 transactivation activity. MEF2 mutants that are resistant to GSK3 phosphorylation rescued neurons from potassium withdrawal-induced apoptosis. In association with the increased GSK3 activity in nuclei of CGNs after potassium withdrawal, MEF2 DNA binding activity decreased markedly over time compared with that in CGNs cultured in media containing 29 mM KCl (Fig. 3A).
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