ABSTRACT
Chromatin undergoes drastic structural organization and epigenetic reprogramming during embryonic development. We present here a consistent view of the chromatin structural change, epigenetic reprogramming and the corresponding sequence dependence in both mouse and human embryo development. The two types of domains, identified earlier as forests and prairies, become spatially segregated during embryonic development, with the exception of zygotic genome activation (ZGA) and implantation, at which notable domain mixing occurs. Structural segregation largely coincides with DNA methylation and gene expression changes. Genes located in mixed prairie domains show proliferation and ectoderm differentiation-related function in ZGA and implantation, respectively. Chromatin of ectoderm shows the weakest and endoderm the strongest domain segregation in germ layers. This chromatin structure difference between different germ layers generally enlarges in further differentiation. The systematic chromatin structure establishment and its sequence-based segregation strongly suggest DNA sequence as a possible driving force for the establishment of chromatin 3D structures which affect profoundly the expression profile. Other possible factors correlated with/influencing chromatin structures, including temperature, germ layers, and cell cycle, were discussed for an understanding of concerted chromatin structure and epigenetic changes in development.
Competing Interest Statement
The authors have declared no competing interest.