Abstract
The development and function of the brain require tight control of gene expression. Genome architecture is thought to play a critical regulatory role in gene expression, but the mechanisms governing genome architecture in the brain in vivo remain poorly understood. Here, we report that conditional knockout of the chromatin remodeling enzyme Chd4 in granule neurons of the mouse cerebellum increases accessibility of gene regulatory sites genome-wide in vivo. Conditional knockout of Chd4 promotes recruitment of the architectural protein complex cohesin preferentially to gene enhancers in granule neurons in vivo. Importantly, in vivo profiling of genome architecture reveals that conditional knockout of Chd4 strengthens interactions among developmentally repressed contact domains as well as genomic loops in a manner that tightly correlates with increased accessibility, enhancer activity, and cohesin occupancy at these sites. Collectively, our findings define a role for chromatin remodeling in the control of genome architecture organization in the mammalian brain.
Highlights
The development and function of the brain require tight control of gene expression
To characterize the nucleosome remodeling activity of Chd[4] in the brain, we assessed the effect of conditional knockout of Chd[4] in granule neurons of the mouse cerebellum on genomic accessibility using DNaseI-hypersensitivity sequencing (DNaseI-seq)[16,18]
We found that contact domains with altered interactions in the cerebellum upon conditional Chd[4] knockout contained regulatory sites that were dynamic during brain development
Summary
The development and function of the brain require tight control of gene expression. Genome architecture is thought to play a critical regulatory role in gene expression, but the mechanisms governing genome architecture in the brain in vivo remain poorly understood. We report that conditional knockout of the chromatin remodeling enzyme Chd[4] in granule neurons of the mouse cerebellum increases accessibility of gene regulatory sites genome-wide in vivo. Regulation of chromatin organization through DNA methylation, posttranslational modifications of histone proteins, and nucleosome remodeling represents a fundamental facet of gene expression control[3,4,5,6]. Among these mechanisms, nucleosome remodeling, which comprises changes in nucleosome spacing, density, or subunit composition, remains perhaps the most poorly understood[7,8]. The composite of these local interactions emerges as higher order structures termed compartments[6,25]
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