Abstract
Proximity ligation assays such as circularized chromosome conformation capture and high-throughput chromosome capture assays have shed light on the structural organization of the interphase genome. Functional topologically associating domains (TADs) that constitute the building blocks of genomic organization are disrupted and reconstructed during the cell cycle. Epigenetic memory, as well as the sequence of chromosomes, regulate TAD reconstitution. Sub-TAD domains that are invariant across cell types have been identified, and contacts between these domains, rather than looping, are speculated to drive chromatin folding. Replication domains are established simultaneously with TADs during the cell cycle and the two correlate well in terms of characteristic features, such as lamin association and histone modifications. CCCTC-binding factor (CTCF) and cohesin cooperate across different cell types to regulate genes and genome organization. CTCF elements that demarcate TAD boundaries are commonly disrupted in cancer and promote oncogene activation. Chromatin looping facilitates interactions between distant promoters and enhancers, and the resulting enhanceosome complex promotes gene expression. Deciphering the chromatin tangle requires comprehensive integrative analyses of DNA- and protein-dependent factors that regulate genomic organization.
Highlights
Genomic DNA in each human diploid cell, which is 2 m in total length, is folded around histone proteins to form the compact nucleosome, which in addition to DNA and the histone octamer core, contains the tail regions of histone proteins
This review focuses on recent insights into genome organization, regulatory mechanisms of genome organization, and the significance of genome organization to gene regulation, development, and disease
The A and B compartments appear to be cell-type specific [8]. They can be reorganized to lie closer to the nuclear periphery or the center based on chromatin modifications, which in turn depend on what genes are necessary at eachpoint during development [9]
Summary
Genomic DNA in each human diploid cell, which is 2 m in total length, is folded around histone proteins to form the compact nucleosome, which in addition to DNA and the histone octamer core, contains the tail regions of histone proteins. The predominant histone octamer core contains two of each of the four histones, H2A, H2B, H3, and H4, around which ≈147 bp of DNA is wound. The mechanisms by which regulatory elements such as enhancers and CCCTC-binding factor (CTCF) sites control genome organization have been elucidated. This review focuses on recent insights into genome organization, regulatory mechanisms of genome organization, and the significance of genome organization to gene regulation, development, and disease. This review focuses on recent insights into genome organization, regulatory mechanisms of genome organization, and the significance of genome organization to gene
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