Publication

Cell-type-specific 3D-genome organization and transcription regulation in the brain.

current
   April 1st, 2024 at 4:30pm

Overview


Abstract

3D organization of the genome plays a critical role in regulating gene expression. However, it remains unclear how chromatin organization differs among different cell types in the brain. Here we used genome-scale DNA and RNA imaging to investigate 3D-genome organization in transcriptionally distinct cell types in the primary motor cortex of the mouse brain. We uncovered a wide spectrum of differences in the nuclear architecture and 3D-genome organization among different cell types, ranging from the physical size of the cell nucleus to the active-inactive chromatin compartmentalization and radial positioning of chromatin loci within the nucleus. These cell-type-dependent variations in nuclear architecture and chromatin organization exhibited strong correlation with both total transcriptional activity of the cell and transcriptional regulation of cell-type-specific marker genes. Moreover, we found that the methylated-DNA-binding protein MeCP2 regulates transcription in a divergent manner, depending on the nuclear radial positions of chromatin loci, through modulating active-inactive chromatin compartmentalization.

Authors

Liu S  •  Zheng P  •  Wang CY  •  Jia BB  •  Zemke NR  •  Ren B  •  Zhuang X

Link

https://www.ncbi.nlm.nih.gov/pubmed/38105994


Journal

bioRxiv : the preprint server for biology

doi:10.1101/2023.12.04.570024

Published

December 5th, 2023