Your search keyword '"Gerard van Grootheest"' showing total 2 results

1. Cell-type-specific methylome-wide association studies implicate neurodegenerative processes and neuroimmune communication in major depressive disorder

Author

Robin F. Chan, Brenda W.J.H. Penninx, Andrey A. Shabalin, Gerard van Grootheest, Gustavo Turecki, Jerry Guintivano, Karolina A. Aberg, Min Zhao, Lin Y. Xie, Zachary Kaminsky, Brian Dean, and Edwin J. C. G. van den Oord

Subjects

0303 health sciences, Cell type, CD14, Neurodegeneration, Genome-wide association study, Biology, medicine.disease, 03 medical and health sciences, 0302 clinical medicine, DNA methylation, medicine, Major depressive disorder, Neuroscience, 030217 neurology & neurosurgery, 030304 developmental biology, Epigenomics, Genetic association

Abstract

We studied the methylome in three collections of human postmortem brain (N=206) and blood samples (N=1,132) of subjects with major depressive disorder (MDD) and controls. Using an epigenomic deconvolution approach we performed cell-type-specific methylome-wide association studies (MWAS) within sub-populations of neurons/glia and granulocytes/T-cells/B-cells/monocytes for bulk brain and blood data, respectively. Multiple MWAS findings in neurons/glia replicated across brain collections (ORs=509-538, P-values−5) and were reproducible in an array-based MWAS of sorted neurons/glia from a fourth brain collection (N=58). Pathway analyses implicated p75NTR/VEGF signaling, neurodegeneration, and blood-brain barrier perturbation. Cell-type-specific analysis in blood identified associations in CD14+ monocytes -- a cell type strongly linked to neuroimmune processes and stress. Top results in neurons/glia/bulk and monocytes were enriched for genes supported by GWAS for MDD (ORs=2.02-2.87, P-values=0.003 to −5), neurodegeneration and other psychiatric disorders. In summary, we identified novel MDD-methylation associations by using epigenomic deconvolution that provided important mechanistic insights for the disease.

Published

2018

2. Evolutionary and functional data power search for obsessive-compulsive disorder genes

Author

Hyun Ji Noh, Ruqi Tang, Jason Flannick, Colm O’Dushlaine, Ross Swofford, Daniel Howrigan, Diane P. Genereux, Jeremy Johnson, Gerard van Grootheest, Edna Grünblatt, Erik Andersson, Diana R. Djurfeldt, Paresh D. Patel, Michele Koltookian, Christina Hultman, Michele T. Pato, Carlos N. Pato, Steven A. Rasmussen, Michael A. Jenike, Gregory L. Hanna, S. Evelyn Stewart, James A. Knowles, Stephan Ruhrmann, Hans-Jörgen Grabe, Michael Wagner, Christian Rück, Carol A. Mathews, Susanne Walitza, Daniëlle C. Cath, Guoping Feng, Elinor K. Karlsson, and Kerstin Lindblad-Toh

Subjects

Genetics, Neuroblastoma cell, Postsynaptic potential, Obsessive compulsive, Transcription (biology), Genomic data, Glutamate receptor, Genomics, Biology, Gene

Abstract

SUMMARYObsessive-compulsive disorder (OCD) is a severe psychiatric disorder linked to abnormalities in the cortico-striatal circuit and in glutamate signaling. We sequenced coding and regulatory elements for 608 genes implicated in OCD from humans and two animal models (mouse and dog). Using a new method, PolyStrat, which prioritizes variants disrupting evolutionarily conserved, functional regions, we found four strongly associated genes when comparing 592 cases to 560 controls. These results were validated in a second, larger cohort. NRXN1 and HTR2A are enriched for coding variants altering postsynaptic protein-binding domains, while CTTNBP2 (synapse maintenance) and REEP3 (vesicle trafficking) are enriched for regulatory variants. The rare coding variant burden in NRXN1 achieves genomewide significance (p=6.37×10−11) when we include public data for 33,370 controls. Of 17 regulatory variants identified in CTTNBP2 and REEP3, we show that at least six alter transcription factor-DNA binding in human neuroblastoma cells. Our findings suggest synaptic adhesion as a key function in compulsive behaviors across three species, and demonstrate how combining targeted sequencing with functional annotations can identify potentially causative variants in both coding and noncoding regions, even when genomic data is limited.

Published

2017