DeepWAS: Multivariate genotype-phenotype associations by directly integrating regulatory information using deep learning

6533b86dfe1ef96bd12caaa5

RESEARCH PRODUCT

DeepWAS: Multivariate genotype-phenotype associations by directly integrating regulatory information using deep learning

S. Nischwitz S. Nischwitz Bernhard Hemmer Susanne Lucae Tim Kacprowski Tim Kacprowski Brigitte Kühnel Gökcen Eraslan Konstantin Strauch Bertram Müller-myhsok Bertram Müller-myhsok Josef Frank Felix Luessi Felix Luessi Thomas Meitinger Elisabeth B. Binder Elisabeth B. Binder Stella Iurato Marcella Rietschel Fabian J. Theis Christian Gieger Stefanie Heilmann-heimbach Nikola S. Mueller Matthias Laudes Friedemann Paul Friedemann Paul Rajesh Rawal Melanie Waldenberger Janine Arloth Till F. M. Andlauer Till F. M. Andlauer Ralf Gold Ralf Gold Jade Martins Annette Peters H. Wiendl H. Wiendl

subject

0301 basic medicine Multivariate analysis Gene Expression Genome-wide association study Biochemistry 0302 clinical medicine Genotype Medicine and Health Sciences Biology (General)0303 health sciences DNA methylation Ecology Chromosome Biology Neurodegenerative Diseases Genomics Chromatin Chromatin Nucleic acids Neurology Computational Theory and Mathematics Modeling and Simulation DNA methylation Trait Epigenetics DNA modification Function and Dysfunction of the Nervous System Chromatin modification Research Article Multiple Sclerosis QH301-705.5 Quantitative Trait Loci Immunology Single-nucleotide polymorphism Computational biology Biology Quantitative trait locus Polymorphism Single Nucleotide Autoimmune Diseases Molecular Genetics 03 medical and health sciences Cellular and Molecular Neuroscience Deep Learning Genome-Wide Association Studies Genetics Humans Gene Molecular Biology Genetic Association Studies Ecology Evolution Behavior and Systematics 030304 developmental biology Genetic association Biology and Life Sciences Computational Biology Human Genetics Cell Biology DNA Genome Analysis Demyelinating Disorders 030104 developmental biology Genetic Loci Multivariate Analysis Clinical Immunology Clinical Medicine 030217 neurology & neurosurgery Genome-Wide Association Study

description

Genome-wide association studies (GWAS) identify genetic variants associated with traits or diseases. GWAS never directly link variants to regulatory mechanisms. Instead, the functional annotation of variants is typically inferred by post hoc analyses. A specific class of deep learning-based methods allows for the prediction of regulatory effects per variant on several cell type-specific chromatin features. We here describe “DeepWAS”, a new approach that integrates these regulatory effect predictions of single variants into a multivariate GWAS setting. Thereby, single variants associated with a trait or disease are directly coupled to their impact on a chromatin feature in a cell type. Up to 61 regulatory SNPs, called dSNPs, were associated with multiple sclerosis (MS, 4,888 cases and 10,395 controls), major depressive disorder (MDD, 1,475 cases and 2,144 controls), and height (5,974 individuals). These variants were mainly non-coding and reached at least nominal significance in classical GWAS. The prediction accuracy was higher for DeepWAS than for classical GWAS models for 91% of the genome-wide significant, MS-specific dSNPs. DSNPs were enriched in public or cohort-matched expression and methylation quantitative trait loci and we demonstrated the potential of DeepWAS to generate testable functional hypotheses based on genotype data alone. DeepWAS is available at https://github.com/cellmapslab/DeepWAS.

year	journal	country	edition	language
2020-02-03	PLOS Computational Biology

10.1371/journal.pcbi.1007616 http://dx.doi.org/10.1371/journal.pcbi.1007616