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Discovering How Heme Controls Genome Function Through Heme-omics

Ruiqi Liao, Ye Zheng, Xin Liu, Yuannyu Zhang, Gretchen Seim, Nobuyuki Tanimura, Gary M. Wilson, Peiman Hematti, Joshua J. Coon, Jing Fan, Jian Xu, Sündüz Keleş, Emery H. Bresnick

2020Cell Reports47 citationsDOIOpen Access PDF

Abstract

Protein ensembles control genome function by establishing, maintaining, and deconstructing cell-type-specific chromosomal landscapes. A plethora of small molecules orchestrate cellular functions and therefore may link physiological processes with genome biology. The metabolic enzyme and hemoglobin cofactor heme induces proteolysis of a transcriptional repressor, Bach1, and regulates gene expression post-transcriptionally. However, whether heme controls genome function broadly or through prescriptive actions is unclear. Using assay for transposase-accessible chromatin sequencing (ATAC-seq), we establish a heme-dependent chromatin atlas in wild-type and mutant erythroblasts lacking enhancers that confer normal heme synthesis. Amalgamating chromatin landscapes and transcriptomes in cells with sub-physiological heme and post-heme rescue reveals parallel Bach1-dependent and Bach1-independent mechanisms that target heme-sensing chromosomal hotspots. The hotspots harbor a DNA motif demarcating heme-regulated chromatin and genes encoding proteins not known to be heme regulated, including metabolic enzymes. The heme-omics analysis establishes how an essential biochemical cofactor controls genome function and cellular physiology.

Topics & Concepts

HemeBiologyChromatinTranscriptomeGenomeComputational biologyHemeproteinGeneGeneticsCell biologyBiochemistryGene expressionEnzymeRNA modifications and cancerEpigenetics and DNA MethylationGenomics and Chromatin Dynamics
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