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Early deficits in an in vitro striatal microcircuit model carrying the Parkinson's GBA-N370S mutation.

Quyen B DoHumaira NoorRicardo Márquez-GómezKaitlyn M L CrambBryan NgAjantha AbbeyNaroa Ibarra-AizpuruaMaria-Claudia CaiazzaParnaz SharifiCharmaine LangDayne A Beccano-KellyJimena BaleriolaNora Bengoa-VergnioryRichard Wade-Martins
Published in: NPJ Parkinson's disease (2024)
Understanding medium spiny neuron (MSN) physiology is essential to understand motor impairments in Parkinson's disease (PD) given the architecture of the basal ganglia. Here, we developed a custom three-chambered microfluidic platform and established a cortico-striato-nigral microcircuit partially recapitulating the striatal presynaptic landscape in vitro using induced pluripotent stem cell (iPSC)-derived neurons. We found that, cortical glutamatergic projections facilitated MSN synaptic activity, and dopaminergic transmission enhanced maturation of MSNs in vitro. Replacement of wild-type iPSC-derived dopamine neurons (iPSC-DaNs) in the striatal microcircuit with those carrying the PD-related GBA-N370S mutation led to a depolarisation of resting membrane potential and an increase in rheobase in iPSC-MSNs, as well as a reduction in both voltage-gated sodium and potassium currents. Such deficits were resolved in late microcircuit cultures, and could be reversed in younger cultures with antagonism of protein kinase A activity in iPSC-MSNs. Taken together, our results highlight the unique utility of modelling striatal neurons in a modular physiological circuit to reveal mechanistic insights into GBA1 mutations in PD.
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