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Hauptverfasser: Vinayak, Vinayak, Lakadamyali, Melike, Shenoy, Vivek B
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2510.09375
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author Vinayak, Vinayak
Lakadamyali, Melike
Shenoy, Vivek B
author_facet Vinayak, Vinayak
Lakadamyali, Melike
Shenoy, Vivek B
contents Nanoscale chromatin domains, variously termed nucleosome clutches, nanodomains, or packing domains, have emerged as fundamental architectural units of the mammalian genome during interphase and mitosis. Unlike cohesin-dependent loops or TADs, these 50-200 nm structures persist in the absence of loop extrusion, pointing to a distinct organizing principle shaped by histone post-translational modifications and constrained by interactions with the nuclear lamina. Super-resolution microscopy and electron tomography now enable their direct visualization, revealing conserved features such as fractal packing, enrichment for linker histone H1, and radial stratification of active and repressive histone marks. Accumulating evidence indicates that these domains act as transcriptional hubs, dynamically remodel in response to developmental and environmental cues, and undergo pathological disruption in disease. Integrated experimental, theoretical, and computational insights suggest that chromatin-protein interactions, epigenetic read-write processes, and diffusion-driven dynamics together govern their formation, persistence, and nuclear positioning. Viewed in this light, nanoscale domains represent a privileged regulatory tier, complementary to compartments and loop-based structures, that bridges local chromatin states with global nuclear architecture. By situating them alongside lamin-associated (LADs) and nucleolus-associated domains (NADs), we propose a unified biophysical framework for chromatin organization across scales and outline key open questions for future exploration. Because their structural disruption is a recurring feature of aging, cancer, and degenerative diseases, understanding these domains may open new avenues for diagnostics and therapeutic intervention.
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id arxiv_https___arxiv_org_abs_2510_09375
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Sub-Diffraction Chromatin Domains: Architecture, Regulation, and Functional Roles in Nuclear Organization
Vinayak, Vinayak
Lakadamyali, Melike
Shenoy, Vivek B
Biological Physics
Nanoscale chromatin domains, variously termed nucleosome clutches, nanodomains, or packing domains, have emerged as fundamental architectural units of the mammalian genome during interphase and mitosis. Unlike cohesin-dependent loops or TADs, these 50-200 nm structures persist in the absence of loop extrusion, pointing to a distinct organizing principle shaped by histone post-translational modifications and constrained by interactions with the nuclear lamina. Super-resolution microscopy and electron tomography now enable their direct visualization, revealing conserved features such as fractal packing, enrichment for linker histone H1, and radial stratification of active and repressive histone marks. Accumulating evidence indicates that these domains act as transcriptional hubs, dynamically remodel in response to developmental and environmental cues, and undergo pathological disruption in disease. Integrated experimental, theoretical, and computational insights suggest that chromatin-protein interactions, epigenetic read-write processes, and diffusion-driven dynamics together govern their formation, persistence, and nuclear positioning. Viewed in this light, nanoscale domains represent a privileged regulatory tier, complementary to compartments and loop-based structures, that bridges local chromatin states with global nuclear architecture. By situating them alongside lamin-associated (LADs) and nucleolus-associated domains (NADs), we propose a unified biophysical framework for chromatin organization across scales and outline key open questions for future exploration. Because their structural disruption is a recurring feature of aging, cancer, and degenerative diseases, understanding these domains may open new avenues for diagnostics and therapeutic intervention.
title Sub-Diffraction Chromatin Domains: Architecture, Regulation, and Functional Roles in Nuclear Organization
topic Biological Physics
url https://arxiv.org/abs/2510.09375