Synthetic analysis of chromatin tracing and live-cell imaging indicates pervasive spatial coupling between genes.
Christopher H BohrerDaniel R LarsonPublished in: eLife (2023)
The role of the spatial organization of chromosomes in directing transcription remains an outstanding question in gene regulation. Here, we analyze two recent single-cell imaging methodologies applied across hundreds of genes to systematically analyze the contribution of chromosome conformation to transcriptional regulation. Those methodologies are (1) single-cell chromatin tracing with super-resolution imaging in fixed cells; and (2) high-throughput labeling and imaging of nascent RNA in living cells. Specifically, we determine the contribution of physical distance to the coordination of transcriptional bursts. We find that individual genes adopt a constrained conformation and reposition toward the centroid of the surrounding chromatin upon activation. Leveraging the variability in distance inherent in single-cell imaging, we show that physical distance - but not genomic distance - between genes on individual chromosomes is the major factor driving co-bursting. By combining this analysis with live-cell imaging, we arrive at a corrected transcriptional correlation of [Formula: see text] for genes separated by < 400 nm. We propose that this surprisingly large correlation represents a physical property of human chromosomes and establishes a benchmark for future experimental studies.
Keyphrases
- single cell
- high resolution
- genome wide
- high throughput
- gene expression
- transcription factor
- physical activity
- living cells
- rna seq
- mental health
- dna damage
- endothelial cells
- dna methylation
- fluorescence imaging
- genome wide identification
- bioinformatics analysis
- preterm infants
- signaling pathway
- photodynamic therapy
- fluorescent probe
- heat stress
- induced pluripotent stem cells
- electron transfer