Scalable Human Cellular Models of Parkinson’s Disease Reveal A Druggable Link Between the Angiotensin Receptor 1 and α-Synuclein Pathology
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Background
Parkinson’s disease (PD) involves progressive loss of midbrain dopaminergic (mDA) neurons in the substantia nigra. No disease-modifying treatments exist, only symptomatic relief. Our lab reported an unbiased screen in larval zebrafish identifying renin-angiotensin-aldosterone system (RAAS) inhibitors, including clinically used AGTR1 inhibitors for hypertension, as potent neuroprotective agents. This study aims to investigate the effects of AGTR1 inhibition on human mDA neuron survival using inducible neurodegenerative 2D and 3D models for human mDA neuron degeneration.
Methods
We report a scalable high-content platform, using CRISPR-engineered human induced pluripotent stem cell (hiPSC)-derived mDA neurons expressing a tyrosine hydroxylase (TH) fluorescent reporter, allowing to track mDA neuron survival live “in a dish”. We developed chemically inducible neurodegenerative 2D and 3D models for human mDA neuron degeneration, allowing to recapitulate PD pathology in human cells in vitro .
Results
Our model establishes scalable human cellular models of PD well-suited for therapeutic discovery. Using 2D and 3D mono and co-cultures, this study demonstrates that inhibition of AGTR1, via chemical or genetic means, protects against chemically induced mDA neuron degeneration. Transcriptomic analyses show AGTR1 inhibition lowers synuclein transcription, by reducing SNCA and SNCB gene expression. In 3D neuron-glia assembloids, AGTR1 inhibition protects against the accumulation of phosphorylated form of α-synuclein (p129α-Syn), key PD pathological marker.
Conclusions
We highlight AGTR1 as a key regulator of α-synuclein transcription and aggregation in human mDA neurons, and AGTR1 inhibition as pro-survival in human iPSC-derived models. These findings position inhibition of AGTR1 as a promising therapeutic strategy for PD neuroprotection.
