Deciphering histone mark-specific fine-scale chromatin organization at high resolution with Micro-C-ChIP

The regulation of cell-type-specific transcription programs is a highly controlled and complex process that needs to be fully understood. The gene regulation is often influenced by distal regulatory elements and their interactions with promoters in three-dimensional space. Although proximity ligation techniques like Hi-C have revolutionized our understanding of genome organization, the genomic resolution for many of these methods is limited by both experimental and financial constraints. Here, we introduce Micro-C-ChIP to provide extremely high-resolution views of chromosome architecture at genomic loci marked by specific covalent histone modifications. This is achieved by affinity isolation of specific chromatin states in order to target chromosome folding libraries to focus on chromatin domains (regulatory elements, heterochromatin, etc.) of interest, yielding extremely high sequencing depth at these loci. We applied Micro-C-ChIP to mouse embryonic stem cells (mESC) and hTERT-immortalized human retinal epithelial cells (hTERT-RPE1), revealing architectural features of genome organization with comparable or higher resolution than Micro-C datasets sequenced to 10X higher depth. In particular, we discovered extensive promoter-promoter networks in both cell types and characterized the specific architecture of bivalently bookmarked promoters in mESC. Together, these data highlight Micro-C-ChIP as a cost-effective approach to exploring the landscape of genome folding at extraordinarily high resolution. Micro-C-ChIP was performed against H3K4me3 and H3K27me3 in two cell types, mESC and hTERT-RPE1. Each condition (histone marks and cell types) has two biological replicates.The replicates for each condition were merged and converted to mcool format.