A putative role for genome-wide epigenetic regulatory mechanisms in Huntington’s disease: A computational assessment

Abstract

Background: Huntington's Disease (HD) is an incurable disease of the adult brain. Massive changes in gene expression are a prominent feature. Epigenetic effects have been reported to be implicated in HD, but the role of chromatin is not well understood. We tested if the chromatin state of dysregulated genes in HD is affected at a genome-wide scale and examined how epigenetic processes are associated with CpG-island-mediated gene expression. Methods: Our general approach incorporates computational and functional analysis of public data before embarking on expensive wet-lab experiments. We compared the location in the genome of the genes that were deregulated in HD human brain, obtained from public gene expression data, to the location of particular chromatin marks in reference tissues using data from the ENCODE project. Results: We found that differentially expressed genes were enriched in the active chromatin state, but not enriched in the silent state. In the caudate nucleus, the most highly affected brain region in HD, genes in the active state were associated with transcription, cell cycle, protein transport and modification, RNA splicing, histone post-translational modifications and RNA processing. Genes in the repressed state were linked with developmental processes and responses related to zinc and cadmium stimulus. We confirmed that genes within CpG-islands are enriched among HD dysregulated genes in human and mouse in HD. Epigenetic processes were associated more with genes that overlap with CpG-islands than genes that do not. Conclusion: Our results suggest that massive transcriptional dysregulation in HD is not matched by large-scale relocation of gene activity, i.e. inactive chromatin regions are altered into actively expressed chromatin regions and vice versa. We expect that changes in epigenetic chromatin state might occur at the level of single genes (e.g. promoters, gene body) and scattered genomic sites (e.g. CTCF sites, enhancer regions) instead of large-scale genomic regions.