Abstract
BACKGROUND: Although liquid-liquid phase separation (LLPS) proteins are known to participate in genome organization and transcriptional regulation through the formation of biomolecular condensates, their functional interplay with other regulatory proteins and histone modifications in chromatin loop formation remains poorly characterized. By combining Hi-C chromatin interaction data with ChIP-seq profiles of 12, 27, and 24 LLPS proteins in GM12878, K562, and HepG2 cell lines, respectively, we identified chromatin loops associated with LLPS proteins and systematically analysed patterns of cooperative protein binding and histone modification enrichment within these loop-associated peaks. RESULTS: We identified 162, 313, and 431 chromatin loops associated with LLPS proteins in GM12878, K562, and HepG2 cell lines, respectively. These loops were relatively small in size and predominantly anchored at enhancer regions. Examination of cooperative binding of proteins within loop-associated peaks revealed that transcriptional repressor IKZF1, HDAC1, and SAP130 most frequently co-localized with LLPS proteins in GM12878, K562, and HepG2 cells, respectively. Further analysis of histone modification enrichment patterns revealed that active histone modifications, such as H3K4me2, H3K4me3, H3K9ac, and H3K27ac, co-localized at loop-associated peaks, with H3K4me1 exhibiting additional specific co-localization with these four histone modifications at enhancer-localized loop-associated peaks. Notably, bivalent chromatin domains where H3K27me3 co-localized with active histone modifications were identified at promoter-localized loop-associated peaks in HepG2 cells, and elevated H3K27me3 occupancy at these peaks was associated with transcriptional repression of target genes. Moreover, quantitative RNA-seq analysis revealed that the expression of target genes associated with enhancer-promoter loops was correlated with both the binding of LLPS proteins and the enrichment patterns of histone modifications within their ChIP-seq peaks at loop anchors. CONCLUSIONS: Our study suggests that LLPS proteins may cooperate with transcriptional repressors to facilitate chromatin looping. Furthermore, local enrichment of histone modifications at loop-associated peaks provides additional regulatory control over chromatin architecture and gene transcription.