Genetic Susceptibility Modifies the Association of Long-term Air Pollution Exposure on Parkinson's Disease

Overview

Journal NPJ Parkinsons Dis

Date 2024 Jan 17

PMID 38233432

Authors

Yi-Ming Huang

Ya-Hui Ma

Pei-Yang Gao

Xi-Han Cui

Jia-Hui Hou

Hao-Chen Chi

Yan Fu

Zhi-Bo Wang

Jian-Feng Feng

Wei Cheng

Lan Tan

Jin-Tai Yu

Affiliations

Soon will be listed here.

Abstract

Inconsistent findings exist regarding the potential association between polluted air and Parkinson's disease (PD), with unclear insights into the role of inherited sensitivity. This study sought to explore the potential link between various air pollutants and PD risk, investigating whether genetic susceptibility modulates these associations. The population-based study involved 312,009 initially PD-free participants with complete genotyping data. Annual mean concentrations of PM, PM, NO, and NO were estimated, and a polygenic risk score (PRS) was computed to assess individual genetic risks for PD. Cox proportional risk models were employed to calculate hazard ratios (HR) and 95% confidence intervals (CI) for the associations between ambient air pollutants, genetic risk, and incident PD. Over a median 12.07-year follow-up, 2356 PD cases (0.76%) were observed. Compared to the lowest quartile of air pollution, the highest quartiles of NO and PM pollution showed HRs and 95% CIs of 1.247 (1.089-1.427) and 1.201 (1.052-1.373) for PD incidence, respectively. Each 10 μg/m increase in NO and PM yielded elevated HRs and 95% CIs for PD of 1.089 (1.026-1.155) and 1.363 (1.043-1.782), respectively. Individuals with significant genetic and PM exposure risks had the highest PD development risk (HR: 2.748, 95% CI: 2.145-3.520). Similarly, those with substantial genetic and NO exposure risks were over twice as likely to develop PD compared to minimal-risk counterparts (HR: 2.414, 95% CI: 1.912-3.048). Findings suggest that exposure to air contaminants heightens PD risk, particularly in individuals genetically predisposed to high susceptibility.

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