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New human cell model offers breakthrough path to Parkinson's disease treatments

Researchers created the first human cell model that accurately reproduces Parkinson's disease, revealing how the disease damages mitochondria at the molecular level. Two experimental peptides successfully reversed these changes in the model, offering a faster, more reliable way to test potential therapies—potentially accelerating drug development for a disease affecting 10 million people worldwide.

Originaltitel: Early α-synuclein–mediated mitochondrial dysfunction in a human cell model of Parkinson’s disease dementia

Abstrakt

Parkinson's disease (PD) is a progressive neurodegenerative disorder characterised by the misfolding and accumulation of α-synuclein (α-syn) into pathological aggregates known as Lewy bodies. PD remains incurable, partly due to limited physiologically relevant models that recapitulate human pathology to enable therapeutic development. We developed a novel in vitro PD dementia model using fetal human cortical neurons seeded with α-syn preformed fibrils (PFFs). This model successfully replicates key PD features, including α-syn aggregation and mitochondrial gene dysregulation. Importantly, RNA sequencing revealed significant transcriptomic concordance between our model and PD postmortem tissue, particularly in the downregulation of mitochondrial genes linked to oxidative phosphorylation. We then evaluated two peptide inhibitors, β-syn36D (B36D) and S62. Both peptides demonstrated effective disaggregation of α-syn fibrils, with B36D showing particular promise by reversing PFF-induced functional and transcriptional changes to baseline levels. This human-relevant model captures essential pathological and transcriptomic disease hallmarks as well as demonstrating utility for therapeutic screening of drugs that block α-syn aggregation.

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