Conserved H3K27me3‐associated chromatin looping mediates physical interactions of gene clusters in plants

ABSTRACT Higher‐order chromatin organization is essential for transcriptional regulation, genome stability maintenance, and other genome functions. Increasing evidence has revealed significant differences in 3D chromatin organization between plants and animals. However, the extent, pattern, and rules of chromatin organization in plants are still unclear. In this study, we systematically identified and characterized long‐range chromatin loops in the Arabidopsis 3D genome. We identified hundreds of long‐range cis chromatin loops and found their anchor regions are closely associated with H3K27me3 epigenetic modifications. Furthermore, we demonstrated that these chromatin loops are dependent on Polycomb group (PcG) proteins, suggesting that the Polycomb repressive complex 2 (PRC2) complex is essential for establishing and maintaining these novel loops. Although most of these PcG‐medicated chromatin loops are stable, many of these loops are tissue‐specific or dynamically regulated by different treatments. Interestingly, tandemly arrayed gene clusters and metabolic gene clusters are enriched in anchor regions. Long‐range H3K27me3‐marked chromatin interactions are associated with the coregulation of specific gene clusters. Finally, we also identified H3K27me3‐associated chromatin loops associated with gene clusters in Oryza sativa and Glycine max, indicating that these long‐range chromatin loops are conserved in plants. Our results provide novel insights into genome evolution and transcriptional coregulation in plants. Many H3K27me3‐associated long‐range chromatin loops in plants are tissue‐specific or dynamically regulated by different treatments and tandemly arrayed gene clusters and metabolic gene clusters are enriched in anchor regions, providing insight into 3D genome and transcriptional coregulation in plants.