Polygenic Nature of Cortical Aging Reveals Cytoskeletal Regulation as a Core Pathway of Resilience
Ayati Mishra, Nicholas Kim, Nahian Chowdhury, Andrei Irimia

TL;DR
This study identifies genetic factors linked to brain aging resilience, showing that cytoskeletal regulation plays a key role in slowing cortical aging.
Contribution
The study introduces a deep learning method to estimate local brain age and identifies novel genetic pathways related to cytoskeletal regulation in cortical aging.
Findings
1,212 SNPs were found to be significantly associated with region-specific cortical aging.
Variants in NUAK1 and LPAR1 were linked to decreased local brain age, indicating protective roles in cortical resilience.
Cytoskeletal regulation is highlighted as a core pathway for preserving cortical structure during aging.
Abstract
Brain aging is spatially heterogeneous, with some cortical regions more resilient than others. To investigate the genetic basis of this variation, we developed a deep learning architecture to estimate voxel-wise local brain age (LBA) from T1-weighted MRI scans of 41,708 cognitively normal adults (21,983 females) aged 45 to 83 years in the UK Biobank. LBA provides a spatially resolved phenotype of cortical aging, where higher values indicate older-appearing regions. We conducted the first genome-wide association study of LBA and identified 1,212 SNPs significantly associated with region-specific cortical aging. Genome-wide significant SNPs were enriched in biological processes related to cytoskeletal regulation, highlighting it as a key determinant of resilience. Variants in NUAK1, a serine/threonine kinase regulating tau phosphorylation and microtubule stability, were associated with…
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Taxonomy
TopicsNeurogenesis and neuroplasticity mechanisms · Functional Brain Connectivity Studies · Epigenetics and DNA Methylation
