In vivo validation of novel non-invasive PHP.eB AAVs as a potential therapeutic approach for alpha-synucleinopathies.

Parkinson's disease (PD) is characterized by the accumulation of alpha-synuclein (aSyn) aggregates in specific brain regions, which are likely to be the disease-causing entities. Herein, we employed novel, systemically administered, brain-penetrating viral vectors (PHP.eB AAVs) in order to evaluate the potential therapeutic utility of lowering the endogenous aSyn protein burden in the aSyn pre-formed fibril (PFF)-mouse model. Such vectors expressing short hairpin RNAs or micro RNAs targeting the mouse Snca transcript (or respective scrambled control sequences) were intravenously administered in adult wild-type mice and two weeks later human aSyn PFFs were injected into the dorsal striatum. Following the administration of the Snca-targeting PHP.eB AAVs, a successful widespread viral transduction was achieved throughout the brain, accompanied by an efficient reduction of endogenous aSyn protein levels within transduced dopaminergic neurons. Intrastriatal injection of human aSyn PFFs led to the formation of pSer129-aSyn-rich cytoplasmic inclusions in brain regions connected to the PFF-injection site, nigrostriatal degeneration and relevant behavioral motor deficits, at 2.5 months post PFF-injection. Importantly, PHP.eB AAV-mediated down-regulation of endogenous aSyn reduced the accumulation of pSer129-aSyn inclusions, mitigated nigrostriatal degeneration and alleviated motor impairments. Spread of pathology to other brain regions was also attenuated. Overall, such data highlight further the contribution of the intracellular aSyn protein load to the spread of pathology and suggest that this non-invasive delivery strategy holds promise in the research avenues for treating neurodegenerative diseases with widespread pathology, such as Synucleinopathies.