?-Synuclein (?Syn) Preformed Fibrils Induce Endogenous ?Syn Aggregation, Compromise Synaptic Activity and Enhance Synapse Loss in Cultured Excitatory Hippocampal Neurons.
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ABSTRACT: Synucleinopathies are characterized by the accumulation of insoluble ?-synuclein (?Syn). To test whether ?Syn aggregates modulate synaptic activity, we used a recently developed model in primary neurons for inducing ?Syn pathology. We demonstrated that preformed fibrils (PFFs) generated with recombinant human ?Syn compromised synaptic activity in a time- and dose-dependent manner and that the magnitude of these deficits correlated with the formation of ?Syn pathology in cultured excitatory hippocampal neurons from both sexes of mice. Remarkably, acute passive infusion of ?Syn PFFs from whole-cell patch-clamp pipette decreased mEPSC frequency within 10 min followed by induction of ?Syn pathology within 1 d. Moreover, by direct addition of ?Syn PFFs into culture medium, the formation of misfolded ?Syn inclusions dramatically compromised the colocalization of synaptic markers and altered dynamic changes of dendritic spines, but the viability of neurons was not affected up to 7 d post-treatment with ?Syn PFFs. Our data indicate that intraneuronal ?Syn fibrils impaired the initiation of synaptogenesis and their physiological functions, thereby suggesting that targeting synaptic dysfunction in synucleinopathies may provide a promising therapeutic direction.SIGNIFICANCE STATEMENT Under pathological conditions, the presynaptic protein ?-synuclein (?Syn) aggregates to form intraneuronal inclusions. To understand how and to what extent ?Syn aggregates modulate synaptic activity before neuron loss, we demonstrate that ?Syn preformed fibrils (PFFs) reduced synaptic activity in a dose- and time-dependent manner. The magnitude of these deficits correlated with the deposition of ?Syn pathology, which dramatically compromised the colocalization of synaptic markers and altered the dendritic spine dynamics. The present work further highlights the impact of ?Syn PFFs on synaptogenesis and physiological function, which may be applicable to other types of synucleinopathies.
SUBMITTER: Wu Q
PROVIDER: S-EPMC6595958 | biostudies-literature | 2019 Jun
REPOSITORIES: biostudies-literature
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