Massive-scale single-nucleus multi-omics identifies novel rare noncoding drivers of Parkinson’s disease

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AI-generated deep summary by claude@2026-07, 2026-07-03 · read from full text

The study generated multi-omics single-nucleus data from more than 3.3 million nuclei across five brain regions in 80 individuals with Parkinson’s disease and 21 matched neurologically normal controls, using matched ~30x whole-genome sequencing. The authors characterized cell type–specific features of Parkinson’s disease, mapped chromatin accessibility and expression quantitative trait loci, and trained machine learning models to predict how rare noncoding variants affect gene regulation. They report rare noncoding variants statistically associated with sporadic Parkinson’s disease and extend their framework to predict drivers of familial Parkinson’s disease of unknown genetic origin. The paper does not explicitly state limitations in the provided text, but it emphasizes the challenge of functional interpretation at scale and proposes a generalizable roadmap. The paper does not explicitly discuss endometriosis or adenomyosis; it was included in the corpus via a keyword match in the upstream search index.

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Abstract

Most genetic variants contributing to complex diseases reside in the noncoding genome. While common variants uncovered by genome-wide association studies often fail to explain much of the observed heritability of these diseases, rare variants often have higher effect sizes and cumulatively explain a larger portion of heritability. However, rare variants, particularly rare noncoding variants, have remained under-characterized largely due to the difficulties of accurately predicting variant functionality at scale, given that each individual carries an average of ∼10,000 rare variants. Here, we generated multi-omic data from >3.3 million nuclei sampled from five brain regions across a cohort of 80 individuals with Parkinson’s disease (PD) and 21 neurologically normal control individuals with matched 30x whole-genome sequencing. We use this data to identify cell type-specific features of PD, map cell type-specific chromatin accessibility and expression quantitative trait loci, and train machine learning models to predict the effect of variants on gene regulation. We identify rare noncoding variants statistically associated with sporadic PD and extend our approaches to predict drivers of familial PD of unknown genetic origin. Our results underscore the significance of rare noncoding variants in complex diseases and provide a roadmap for applying similar approaches in other disease systems.
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Abstract Most genetic variants contributing to complex diseases reside in the noncoding genome. While common variants uncovered by genome-wide association studies often fail to explain much of the observed heritability of these diseases, rare variants often have higher effect sizes and cumulatively explain a larger portion of heritability. However, rare variants, particularly rare noncoding variants, have remained under-characterized largely due to the difficulties of accurately predicting variant functionality at scale, given that each individual carries an average of ∼10,000 rare variants. Here, we generated multi-omic data from >3.3 million nuclei sampled from five brain regions across a cohort of 80 individuals with Parkinson’s disease (PD) and 21 neurologically normal control individuals with matched 30x whole-genome sequencing. We use this data to identify cell type-specific features of PD, map cell type-specific chromatin accessibility and expression quantitative trait loci, and train machine learning models to predict the effect of variants on gene regulation. We identify rare noncoding variants statistically associated with sporadic PD and extend our approaches to predict drivers of familial PD of unknown genetic origin. Our results underscore the significance of rare noncoding variants in complex diseases and provide a roadmap for applying similar approaches in other disease systems. Competing Interest Statement The authors have declared no competing interest. Footnotes ↵† Lists of authors and their affiliations appear at the end of the paper

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europepmc
last seen: 2026-05-20T01:45:00.602351+00:00
unpaywall
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License: CC-BY-4.0