Chemical perturbations impacting histone acetylation regulate colorectal cancer differentiation
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Description
M60.count.Rdata: Rdata that includes the raw count, scaled CPM value and meta data of each sample. (Fig. 1 & 4)
DAP.merged.Log2FC.csv: integrated DiffBind results that shows the log2FC and P-value/FDR of peaks. (Fig. 1 & 4)
rawdata_scRNA-seq.zip: raw count data of scRNA-seq data from cellranger (labels: A: DMSO, B: MRK60, D: MRK60 + JQAD1). (Fig. 5)
Abstract
Histone acetylation governs broad gene expression programs in normal tissue and disease states. By applying a small chemical compound library targeting epigenetic regulators to a dual endogenous reporter system, we found that inhibiting histone deacetylase (HDAC) 1/2 initiates colorectal cancer (CRC) differentiation. Inhibiting the enzymatic pocket of HDAC1/2 induced differentiation and reduced proliferation across in vitro and in vivo models. On-target HDAC1/2 inhibition was validated using biochemical, chemical, and genetic approaches. A survey of histone posttranslational modifications from HDAC1/2 selective inhibition nominated acetylation of specific H3 and H4 lysine (K) residues as potential regulators of differentiation. Genome-wide profiles of these histone acetylation marks indicated that gains in histone 3 lysine 27 acetylation (H3K27ac) most strongly correlated to opening of chromatin and upregulation of genes associated with differentiation upon HDAC1/2 inhibition. Blocking acetylation of H3K27 by degrading its writer EP300 rescued the differentiation phenotype induced by HDAC1/2 inhibition in a patient-derived CRC model by single cell RNA-sequencing among other readouts. These results highlight the importance of specific chemically targetable histone modifications in governing cancer cell states and implicate precision targeting of H3K27ac as a potential therapeutic approach for CRC.