Genome Compartmentalization with Nuclear Landmarks: Random yet Precise

Kamat, Kartik; Qi, Yuanming; Wang, Yuchuan; Ma, Jian; Zhang, Bin

doi:10.1101/2021.11.12.468401

Cited by 8 publications

(12 citation statements)

References 103 publications

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“…Higher order chromatin arrangements differ substantially not only between different cell types and species, but also from cell to cell of a given cell population of the same cell type 5, 13 . This heterogeneity may reflect in part functionally irrelevant stochastic features of 4D spatial genomics, while other features, including the space-time organization of nuclear landscapes at mesoscale, reflect a functionally indispensable preciseness of genome organization 14, 15 (see Discussion).…”

Section: Introductionmentioning

confidence: 99%

True-to-scale DNA-density maps correlate with major accessibility differences between active and inactive chromatin

Gelléri

Chen

Szczurek

et al. 2022

Preprint

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Chromatin compaction differences may have a strong impact on accessibility of individual macromolecules and macromolecular assemblies to their DNA target sites. Estimates based on fluorescence microscopy with conventional resolution, however, suggested only modest compaction differences (~2-10x) between active and inactive nuclear compartments (ANC and INC). Here, we present maps of nuclear landscapes with true-to-scale DNA-densities, ranging from <5 Mbp/μm3 to >300 Mbp/μm3. Maps were generated from individual human and mouse cell nuclei with single-molecule localization microscopy at ~20 nm lateral and ~100 nm axial resolution and supplemented by electron spectroscopic imaging. Live cell microinjection experiments with 20 nm and 40 nm sized fluorescent beads, corresponding to macromolecular assemblies for transcription and replication, indicated movements within the ANC, but exclusion from the INC. In line with previous studies of transcription, pulse-chase labeling experiments of DNA demonstrated replication within the ANC, followed by re-location of replicated, inactive chromatin into the INC.

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Section: Introductionmentioning

confidence: 99%

True-to-scale DNA-density maps correlate with major accessibility differences between active and inactive chromatin

Gelléri

Chen

Szczurek

et al. 2022

Preprint

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“…S1, rather than a lack of parameter fine tuning. Indeed, as recognized in previous studies, explicit interactions with nuclear lamina, 19,32,65,66 separate treatment of intra-and inter-chromosome interactions, 17 or assuming repulsive interactions between the compartments, 18 might be necessary to position B compartments towards the nuclear envelope.…”

Section: Computational Model For the Motorized Genomementioning

confidence: 88%

“…Euchromatin and heterochromatin are known to exhibit distinct chemical modifications [27][28][29][30] and interact with different regulatory proteins 28,29 and nuclear bodies. 9,[31][32][33] The chemical modifications themselves could drive chromatin demixing by altering nucleosome interactions. For example, acetylation could neutralize the positive charges on histone tails to weaken their binding with DNA, [34][35][36][37] while methylation may lead to under-twisted DNA that strengthens its interactions with histones.…”

Section: Introductionmentioning

confidence: 99%

Phase Separation and Correlated Motions in Motorized Genome

Jiang

Kamat

et al. 2022

Preprint

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The human genome is arranged in the cell nucleus non-randomly, and phase separation has been proposed as an important driving force for genome organization. However, the cell nucleus is an active system, and the contribution of non-equilibrium activities to phase separation and genome structure and dynamics remains to be explored. We simulated the genome using an energy function parameterized with chromosome conformation capture (Hi-C) data with the presence of active, nondirectional forces that break the detailed balance. We found that active forces that may arise from transcription and chromatin remodeling can dramatically impact the spatial localization of heterochromatin. When applied to euchromatin, active forces can drive heterochromatin to the nuclear envelope and compete with passive interactions among heterochromatin that tend to pull them in opposite directions. Furthermore, active forces induce long-range spatial correlations among genomic loci beyond single chromosome territories. We further showed that the impact of active forces could be understood from the effective temperature defined as the fluctuation-dissipation ratio. Our study suggests that non-equilibrium activities can significantly impact genome structure and dynamics, producing unexpected collective phenomena.

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“…Given that clinical samples are often limited in number and given in a sectioned form, GAM can be more practical than other methods when studying disease-related genome reorganization. While not easily accessible in Hi-C, a number of important properties of 3D genome, such as higher-order chromatin contact (16)(17)(18)(19)(20)(21), lamin and nuclear body association (22)(23)(24)(25)(26), can be measured by leveraging cryoFISH-combined GAM. From an ensemble of cells, Hi-C measures the cross-linking frequencies between two genomic loci; GAM measures the co-segregation frequencies in a nuclear profile; FISH measures the inter-locus spatial distances.…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Dissecting the co-segregation probability from genome architecture mapping

Liu

Cao

Zhang

et al. 2022

Preprint

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The genome architecture mapping (GAM) is a recently developed methodology that offers the co-segregation probability of two genomic segments from an ensemble of thinly sliced nuclear profiles, enabling to probe and decipher the 3D chromatin organization. The co-segregation probability from GAM, which typically probes the length scale associated with the genomic separation greater than 1 MB, is, however, not identical to the contact probability obtained in Hi-C, and its correlation with inter-locus distance measured with FISH is not so good as the contact probability. In this study, by using a polymer-based model of chromatins, we derive a theoretical expression of the co-segregation probability as well as that of the contact probability, and carry out quantitative analyses of how they differ from each other. The results from our study, validated with in-silico GAM analysis on 3D genome structures from FISH, suggest that to attain strong correlation with the inter-locus distance, a properly normalized version of co-segregation probability needs to be calculated based on a large number of nuclear slices (n>103).

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Genome Compartmentalization with Nuclear Landmarks: Random yet Precise

Cited by 8 publications

References 103 publications

True-to-scale DNA-density maps correlate with major accessibility differences between active and inactive chromatin

True-to-scale DNA-density maps correlate with major accessibility differences between active and inactive chromatin

Phase Separation and Correlated Motions in Motorized Genome

Dissecting the co-segregation probability from genome architecture mapping

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