Abstract The protein alpha-synuclein (asyn) is predominantly expressed in neurons and is associated with neurodegenerative diseases like Parkinson’s disease (PD); yet, a functional role for asyn in neurons is not clearly established. We have previously shown that asyn expression is up-regulated following viral infection in neurons and is critical for host immune responses to RNA virus infections. Here, we investigate the mechanisms underlying asyn-dependent immune responses to RNA virus infection in the brain. Using asyn knock-out (KO) mice and human neuronal models, we show that asyn is required for expression of the full repertoire of interferon-stimulated genes (ISGs) in neurons following acute RNA virus infection. Furthermore, treatment of asyn KO human neurons with poly I:C or type I interferon also fail to induce expression of the full complement of ISGs suggesting that asyn plays an important role in modulating neuronal innate immune responses. In brain tissue, asyn-dependent ISG expression is independent of microglia activation and supports activation of infiltrating lymphocytes following viral challenge. We also show that virus infections lead to accumulation of phosphorylated S129 asyn in human and non-human primate neuronal tissues. In a model of pS129 asyn pathology, we found that infection with West Nile virus increases microglia activation but does not significantly alter pS129 asyn pathology in the mouse model. Taken together, our results establish asyn as a novel, neuron-specific modulator of innate immunity by a mechanism that promotes interferon-stimulated gene expression and links responses to virus infection with formation of phosphorylated S129-asyn in neuronal tissue.
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