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Kinetic organization of the genome revealed by ultraresolution multiscale live imaging

Joo Lee, Liangfu Chen, Simon Gaudin, Kavvya Gupta, Ana Novačić, Andrew J. Spakowitz, Alistair N. Boettiger

2025Science20 citationsDOIOpen Access PDF

Abstract

Genome function requires regulated genome motion. However, tools to directly observe this motion in vivo have been limited in coverage and resolution. Here we introduce an approach to tile mammalian chromosomes with self-mapping fluorescent labels and track them at ultraresolution. We find that sequences separated by submegabase distances transition to proximity in tens of seconds. This rapid search is dependent on cohesin and is exhibited only within domains. Domain borders act as kinetic impediments to this search process, rather than structural boundaries. The genomic separation-dependent scaling of the search time for cis interactions violated predictions of diffusion, suggesting motor-driven folding. We also uncover cohesin-dependent processive motion at 2.7 kilobases per second. Together, these multiscale dynamics reveal the organization of the genome into kinetically associated domains.

Topics & Concepts

GenomeLive cell imagingBiologyComputational biologyGenomic organizationFunction (biology)CohesinDynamics (music)Domain (mathematical analysis)Genome evolutionGeneticsScalingHuman genomeEvolutionary biologyGenomicsCTCFMotion (physics)Diffusion and Search DynamicsBacteriophages and microbial interactionsRNA and protein synthesis mechanisms
Kinetic organization of the genome revealed by ultraresolution multiscale live imaging | Litcius