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HNF4A defines tissue-specific circadian rhythms by beaconing BMAL1::CLOCK chromatin binding and shaping the rhythmic chromatin landscape
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HNF4A defines tissue-specific circadian rhythms by beaconing BMAL1::CLOCK chromatin binding and shaping the rhythmic chromatin landscape
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Journal Article
HNF4A defines tissue-specific circadian rhythms by beaconing BMAL1::CLOCK chromatin binding and shaping the rhythmic chromatin landscape
2021
Overview
Transcription modulated by the circadian clock is diverse across cell types, underlying circadian control of peripheral metabolism and its observed perturbation in human diseases. We report that knockout of the lineage-specifying
Hnf4a
gene in mouse liver causes associated reductions in the genome-wide distribution of core clock component BMAL1 and accessible chromatin marks (H3K4me1 and H3K27ac). Ectopically expressing HNF4A remodels chromatin landscape and nucleates distinct tissue-specific BMAL1 chromatin binding events, predominantly in enhancer regions. Circadian rhythms are disturbed in
Hnf4a
knockout liver and HNF4A-MODY diabetic model cells. Additionally, the epigenetic state and accessibility of the liver genome dynamically change throughout the day, synchronized with chromatin occupancy of HNF4A and clustered expression of circadian outputs. Lastly,
Bmal1
knockout attenuates HNF4A genome-wide binding in the liver, likely due to downregulated
Hnf4a
transcription. Our results may provide a general mechanism for establishing circadian rhythm heterogeneity during development and disease progression, governed by chromatin structure.
Genome-wide occupancy of the master circadian clock transcription factor BMAL1::CLOCK varies across tissues and is reprogrammed in cancers, but how specificity is governed is not known. Here the authors show BMAL1::CLOCK in liver tissue is guided by chromatin accessibility remodeled by HNF4A, shedding new lights onto mechanisms of dysregulated circadian rhythms in hepatocarcinoma.
Publisher
Nature Publishing Group UK,Nature Publishing Group,Nature Portfolio
Subject
/ 14/5
/ 38/1
/ 38/23
/ 38/43
/ 38/88
/ 45/15
/ 45/22
/ 45/77
/ 64/60
/ Animals
/ ARNTL Transcription Factors - genetics
/ ARNTL Transcription Factors - metabolism
/ Binding
/ Circadian Rhythm - physiology
/ DNA-Binding Proteins - genetics
/ DNA-Binding Proteins - metabolism
/ Genome
/ Genomes
/ Hepatocyte Nuclear Factor 4 - genetics
/ Hepatocyte Nuclear Factor 4 - metabolism
/ Histones
/ Humanities and Social Sciences
/ Humans
/ Liver
/ Male
/ Mice
/ Mutation
/ Science
