High-resolution single-cell 3D-models of chromatin ensembles during Drosophila embryogenesis.
Qiu SunAlan Perez-RathkeDaniel M CzajkowskyZhifeng ShaoJie LiangPublished in: Nature communications (2021)
Single-cell chromatin studies provide insights into how chromatin structure relates to functions of individual cells. However, balancing high-resolution and genome wide-coverage remains challenging. We describe a computational method for the reconstruction of large 3D-ensembles of single-cell (sc) chromatin conformations from population Hi-C that we apply to study embryogenesis in Drosophila. With minimal assumptions of physical properties and without adjustable parameters, our method generates large ensembles of chromatin conformations via deep-sampling. Our method identifies specific interactions, which constitute 5-6% of Hi-C frequencies, but surprisingly are sufficient to drive chromatin folding, giving rise to the observed Hi-C patterns. Modeled sc-chromatins quantify chromatin heterogeneity, revealing significant changes during embryogenesis. Furthermore, >50% of modeled sc-chromatin maintain topologically associating domains (TADs) in early embryos, when no population TADs are perceptible. Domain boundaries become fixated during development, with strong preference at binding-sites of insulator-complexes upon the midblastula transition. Overall, high-resolution 3D-ensembles of sc-chromatin conformations enable further in-depth interpretation of population Hi-C, improving understanding of the structure-function relationship of genome organization.
Keyphrases
- genome wide
- dna damage
- single cell
- gene expression
- transcription factor
- high resolution
- dna methylation
- rna seq
- copy number
- high throughput
- mass spectrometry
- induced apoptosis
- physical activity
- oxidative stress
- genome wide identification
- single molecule
- optical coherence tomography
- signaling pathway
- mental health
- healthcare