Differential Regulation of Large-scale Chromosome Conformations in Osteoblasts and Osteosarcoma

Correct chromosome organization in the cell nucleus is essential for genome function. However, dynamics and regulations of large-scale chromosomal conformations beyond single compartments at larger than ten megabases in vivo in single cells remain largely unknown. Here we use CRISPR-Sirius, a high-resolution and high-sensitivity real-time imaging technique, to directly visualize distinctions in large-scale chromosomal conformations between live osteosarcoma (OS) cells and osteoblasts, suggesting extensive chromatin reorganization during cell transformation. A surprising discovery is that chromosome 19 long arm is primarily extended in osteoblasts and maintained by H3K27me3. Extended chromosome conformation has been reported in fly and mouse but not in human cells yet. However, in OS cells, chromosome 19 primarily folded into collapsed conformations, which reshape in minutes and are regulated by the chromosome architectural proteins CTCF and cohesin in the presence of H3K27ac. Changes in chromosome conformations by knocking down the cohesin subunit RAD21 resulted in altered gene expression, including proto-oncogenes. Transcription inhibition by a small molecule inhibitor did not have detectable effects on large-scale chromosome conformation, suggesting that local transcription events have limited effects on large-scale chromosomal architecture. Our results provide unique insights into the complex regulatory mechanisms of endogenous large-scale chromosome organization in normal and transformed osteogenic tissues.