Epigenomic and Clinical Analyses of Striatal DAT Binding in Healthy Individuals Reveal Well-known Loci of Parkinson's Disease

Overview

Journal Heliyon

Specialty Social Sciences

Date 2024 Dec 10

PMID 39654757

Authors

Arash Yaghoobi

Homa Seyedmirzaei

Marzie Jamaat

Moein Ala

Affiliations

Soon will be listed here.

Abstract

Background: Striatal dopamine transporter (DAT) binding is a sensitive and specific endophenotype for detecting dopaminergic deficits across Parkinson's disease (PD) spectrum. Molecular and clinical signatures of PD in asymptomatic phases help understand the earliest pathophysiological mechanisms underlying the disease. We aimed to investigate whether blood epigenetic markers are associated with inter-individual variation of striatal DAT binding among healthy elderly individuals. We also investigated whether this potential inter-individual variation can manifest as dysfunction of particular cognitive domains. Omics studies conducted on endophenotypes of PD among healthy asymptomatic individuals can provide invaluable insights into early detection, disease mechanisms, and potential therapeutic targets for PD.

Method: We conducted a blood epigenome-wide association study of striatal DAT binding on 96 healthy individuals using the Illumina EPIC array. For functional annotation of our top results, we employed the enhancer-gene mapping strategy using a midbrain single-nucleus multimodal dataset. Finally, we conducted several investigative regression analyses on several neuropsychological tests across five cognitive domains to assess their association with striatal DAT binding among 250 healthy subjects.

Results: We identified seven suggestive (P-value<10) CpG probes. Specifically, three probes were colocalized with three risk loci previously identified in PD's largest Genome-Wide Association Study (GWAS). and loci were identified as suggestive DMRs associated with striatal DAT binding. Functional analyses prioritized the gene as the potential target gene in the previously reported GWAS locus. We also showed that delayed recall memory impairment was correlated with reduced striatal DAT binding, irrespective of age.

Conclusion: Our study suggested epigenetic and cognitive signatures of striatal DAT binding among healthy individuals, providing valuable insights for future experimental and clinical studies of early PD.

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