AI Article Synopsis
- The arrangement of genes along chromosomes and their location in the nucleus play a key role in how genes are regulated during myogenesis (muscle formation).
- The study found certain regions called topologically associated domains (TADs) that contain muscle-specific genes; these regions affect the positioning of surrounding gene areas in the nucleus based on gene expression.
- Additionally, the proximity of specific gene domains, like Myogenin, appears to stabilize gene expression and relies on cell division for maintaining this unique nuclear organization during muscle cell development.
Article Abstract
The linear distribution of genes across chromosomes and the spatial localization of genes within the nucleus are related to their transcriptional regulation. The mechanistic consequences of linear gene order, and how it may relate to the functional output of genome organization, remain to be fully resolved, however. Here we tested the relationship between linear and 3D organization of gene regulation during myogenesis. Our analysis has identified a subset of topologically associated domains (TADs) that are significantly enriched for muscle-specific genes. These lineage-enriched TADs demonstrate an expression-dependent pattern of nuclear organization that influences the positioning of adjacent nonenriched TADs. Therefore, lineage-enriched TADs inform cell-specific genome organization during myogenesis. The reduction of allelic spatial distance of one of these domains, which contains Myogenin, correlates with reduced transcriptional variability, identifying a potential role for lineage-specific nuclear topology. Using a fusion-based strategy to decouple mitosis and myotube formation, we demonstrate that the cell-specific topology of syncytial nuclei is dependent on cell division. We propose that the effects of linear and spatial organization of gene loci on gene regulation are linked through TAD architecture, and that mitosis is critical for establishing nuclear topologies during cellular differentiation.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC4812766 | PMC |
| http://dx.doi.org/10.1073/pnas.1521826113 | DOI Listing |
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