Translational Psychiatry (Feb 2023)

Genomic patterns linked to gray matter alterations underlying working memory deficits in adults and adolescents with attention-deficit/hyperactivity disorder

  • Kuaikuai Duan,
  • Jiayu Chen,
  • Vince D. Calhoun,
  • Wenhao Jiang,
  • Kelly Rootes-Murdy,
  • Gido Schoenmacker,
  • Rogers F. Silva,
  • Barbara Franke,
  • Jan K. Buitelaar,
  • Martine Hoogman,
  • Jaap Oosterlaan,
  • Pieter J. Hoekstra,
  • Dirk Heslenfeld,
  • Catharina A. Hartman,
  • Emma Sprooten,
  • Alejandro Arias-Vasquez,
  • Jessica A. Turner,
  • Jingyu Liu

DOI
https://doi.org/10.1038/s41398-023-02349-x
Journal volume & issue
Vol. 13, no. 1
pp. 1 – 10

Abstract

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Abstract Attention-deficit/hyperactivity disorder (ADHD) is a highly heritable neurodevelopmental disorder, with onset in childhood and a considerable likelihood to persist into adulthood. Our previous work has identified that across adults and adolescents with ADHD, gray matter volume (GMV) alteration in the frontal cortex was consistently associated with working memory underperformance, and GMV alteration in the cerebellum was associated with inattention. Recent knowledge regarding ADHD genetic risk loci makes it feasible to investigate genomic factors underlying these persistent GMV alterations, potentially illuminating the pathology of ADHD persistence. Based on this, we applied a sparsity-constrained multivariate data fusion approach, sparse parallel independent component analysis, to GMV variations in the frontal and cerebellum regions and candidate risk single nucleotide polymorphisms (SNPs) data from 341 unrelated adult participants, including 167 individuals with ADHD, 47 unaffected siblings, and 127 healthy controls. We identified one SNP component significantly associated with one GMV component in superior/middle frontal regions and replicated this association in 317 adolescents from ADHD families. The association was stronger in individuals with ADHD than in controls, and stronger in adults and older adolescents than in younger ones. The SNP component highlights 93 SNPs in long non-coding RNAs mainly in chromosome 5 and 21 protein-coding genes that are significantly enriched in human neuron cells. Eighteen identified SNPs have regulation effects on gene expression, transcript expression, isoform percentage, or methylation level in frontal regions. Identified genes highlight MEF2C, CADM2, and CADPS2, which are relevant for modulating neuronal substrates underlying high-level cognition in ADHD, and their causality effects on ADHD persistence await further investigations. Overall, through a multivariate analysis, we have revealed a genomic pattern underpinning the frontal gray matter variation related to working memory deficit in ADHD.