AI Article Synopsis
- Scientists usually study how parts of the same chromosome (intrachromosomal contacts) connect, but not much about how different chromosomes (interchromosomal contacts) interact.
- They created a new computer method called trans-C that helps to find these important connections using data from experiments called Hi-C.
- This method was tested with different models and showed that genes that work together often stay close to each other in the cell, which helps in making RNA better and faster.
Article Abstract
Most studies of genome organization have focused on intrachromosomal () contacts because they harbor key features such as DNA loops and topologically associating domains. Interchromosomal () contacts have received much less attention, and tools for interrogating potential biologically relevant structures are lacking. Here, we develop a computational framework that uses Hi-C data to identify sets of loci that jointly interact in This method, trans-C, initiates probabilistic random walks with restarts from a set of seed loci to traverse an input Hi-C contact network, thereby identifying sets of -contacting loci. We validate trans-C in three increasingly complex models of established contacts: the genes, the mouse olfactory receptor "Greek islands," and the human RBM20 cardiac splicing factory. We then apply trans-C to systematically test the hypothesis that genes coregulated by the same -acting element (i.e., a transcription or splicing factor) colocalize in three dimensions to form "RNA factories" that maximize the efficiency and accuracy of RNA biogenesis. We find that many loci with multiple binding sites of the same DNA-binding proteins interact with one another in , especially those bound by factors with intrinsically disordered domains. Similarly, clustered binding of a subset of RNA-binding proteins correlates with interaction of the encoding loci. We observe that these -interacting loci are close to nuclear speckles. These findings support the existence of interacting chromatin domains (TIDs) driven by RNA biogenesis. Trans-C provides an efficient computational framework for studying these and other types of interactions, empowering studies of a poorly understood aspect of genome architecture.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11529845 | PMC |
| http://dx.doi.org/10.1101/gr.278327.123 | DOI Listing |
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