Cell type-specific methylome-wide association studies of childhood ADHD symptoms

  1. Mandy Meijer
  2. Marieke Klein
  3. Doretta Caramaschi
  4. Shaunna L. Clark
  5. Marta Cosin-Tomas
  6. Nastassja Koen
  7. Xueling Lu
  8. Rosa H. Mulder
  9. Stefan W. Röder
  10. Yining Zhang
  11. Lea Zilich
  12. Mariona Bustamente
  13. Michael Deuschle
  14. Janine F. Felix
  15. Juan Ramos González
  16. Regina Gražulevičiene
  17. Fabian Streit
  18. John Wright
  19. Angel Carracedo
  20. Charlotte A.M. Cecil
  21. Eva Corpeleijn
  22. Catharina A. Hartman
  23. Gunda Herberth
  24. Anke Huels
  25. Caroline Relton
  26. Harold Snieder
  27. Dan J. Stein
  28. Jordi Sunyer
  29. Stephanie H. Witt
  30. Heather J. Zar
  31. Ana C. Zenclussen
  32. Barbara Franke
  33. William Copeland
  34. Karolina A. Aberg
  35. Edwin J.C.G. van den Oord
0 evaluations Published on
Read the full article Related papers
This article on Sciety

Abstract

Objective

Studying DNA methylation (DNAm) can provide insights into gene-regulatory mechanisms underlying attention-deficit/hyperactivity disorder (ADHD). While most DNAm studies were performed in bulk tissue, this study used statistical deconvolution to identify cell type-specific DNAm profiles, from five major blood cell types, associated with childhood ADHD symptoms.

Methods

We performed meta-analyses of methylome-wide association studies (MWAS) for ADHD symptoms (agerange=4-16 years) in peripheral blood collected during childhood and in cord blood. The investigated cohorts included seven array-based methylation datasets assaying up to 450K CpGs from the Pregnancy And Childhood Epigenetics Consortium (N=2 934 peripheral blood; N=2 546 cord blood) and a sequencing-based methylation dataset assaying nearly all 28 million CpGs in blood from the Great Smoky Mountain Study (GSMS; N=583).

Results

The meta-analyses resulted in methylome-wide significant (FDR<0.05) ADHD associations in CD8T cells (RPL31P11andKCNJ5)for peripheral blood, and, in cord blood, in monocytes (PDE6B), CD8T cells (KCNA3andHAND2), and NK cells (KIFC1). Notably, several significant sites detected in peripheral blood (RPL31P11andKCNJ5) were also detected in cord blood. Furthermore, extended MWAS of all sites available for GSMS detected 69 and 17 additional CpGs in monocytes and granulocytes, respectively. In this first cell type-specific MWAS for ADHD, we identified DNAm associations for ADHD symptoms; some associations were seen in both peripheral blood and cord blood, suggesting potential susceptibility markers for increased ADHD risk.

Conclusions

These findings show that cell type-specific analyses and sequencing-based approaches can increase insights into the epigenetic patterns associated with ADHD symptoms in childhood.

Related articles

Related articles are currently not available for this article.