Deep-learning microscopy image reconstruction with quality control reveals second-scale rearrangements in RNA polymerase II clusters

Hajiabadi, Hamideh; Mamontova, Irina; Prizak, Roshan; Pancholi, Agnieszka; Koziolek, Anne; Hilbert, Lennart

doi:10.1093/pnasnexus/pgac065

Cited by 7 publications

(10 citation statements)

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“…Size-control by amphiphiles can be seen in several biological example cases. − A particularly well-studied case is the compartmentalization of transcription inside of the cell nucleus. One prominent example is RNA polymerase II (Pol II), the enzyme complex responsible for transcribing most eukaryotic genes, which acts as a bivalent connecting particle between microphase-separated domains enriched in either DNA or RNA. − An amphiphilic effect of ongoing transcription can also be seen by super-resolution microscopy of clusters of transcriptional machinery in stem cells. , These clusters form by a phase-separation mechanism − and unfold or even split into smaller clusters when they are engaged by genes that undergo transcriptional activation. , This effect can be reproduced in detail by a polymer model, in which transcribed genes are described as amphiphiles that associate with transcriptional clusters that, in turn, form by a liquid condensation mechanism . Here, we extend the synthetic DNA-nanomotif droplet platform by amphiphile-motifs and show that the effect of these amphiphile-motifs closely resembles key features of the dispersal of embryonic transcriptional clusters.…”

Section: Dispersal Of Rna Polymerase II Clusters By An Amphiphilic Ef...mentioning

confidence: 99%

“…To allow for the comparison of the effect of DNA-based amphiphiles against a biological model system, we first characterize how transcriptional clusters are affected by the amphiphilic effects exerted by the transcribed genes. In the zebrafish embryo, for a number of genes, transient visits to especially long-lived and prominent transcriptional clusters occur, which are tightly coupled with the transcriptional control of these genes by so-called “super-enhancers”. ,, As genes engage with transcriptional clusters and transcript elongation begins, transcriptional clusters unfold or even split into multiple parts (Figure A). This effect has been attributed to an amphiphilic property of genes that undergo activation in association with these prominent transcriptional clusters: while these genes exhibit an increased tendency to associate with transcriptional clusters, the beginning of transcript elongation additionally drives the exclusion of these genes from the transcriptional cluster …”

Section: Dispersal Of Rna Polymerase II Clusters By An Amphiphilic Ef...mentioning

confidence: 99%

“…27,28 These clusters form by a phase-separation mechanism 29−36 and unfold or even split into smaller clusters when they are engaged by genes that undergo transcriptional activation. 27,37 This effect can be reproduced in detail by a polymer model, in which transcribed genes are described as amphiphiles that associate with transcriptional clusters that, in turn, form by a liquid condensation mechanism. 27 Here, we extend the synthetic DNA-nanomotif droplet platform by amphiphilemotifs and show that the effect of these amphiphile-motifs closely resembles key features of the dispersal of embryonic transcriptional clusters.…”

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confidence: 98%

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Amphiphiles Formed from Synthetic DNA-Nanomotifs Mimic the Stepwise Dispersal of Transcriptional Clusters in the Cell Nucleus

Tschurikow,

Gadzekpo,

Tran

et al. 2023

Nano Lett.

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Stem cells exhibit prominent clusters controlling the transcription of genes into RNA. These clusters form by a phaseseparation mechanism, and their size and shape are controlled via an amphiphilic effect of transcribed genes. Here, we construct amphiphilenanomotifs purely from DNA, and we achieve similar size and shape control for phase-separated droplets formed from fully synthetic, selfinteracting DNA-nanomotifs. Increasing amphiphile concentrations induce rounding of droplets, prevent droplet fusion, and, at high concentrations, cause full dispersal of droplets. Super-resolution microscopy data obtained from zebrafish embryo stem cells reveal a comparable transition for transcriptional clusters with increasing transcription levels. Brownian dynamics and lattice simulations further confirm that the addition of amphiphilic particles is sufficient to explain the observed changes in shape and size. Our work reproduces key aspects of transcriptional cluster formation in biological cells using relatively simple DNA sequence-programmable nanostructures, opening novel ways to control the mesoscopic organization of synthetic nanomaterials.

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Section: Dispersal Of Rna Polymerase II Clusters By An Amphiphilic Ef...mentioning

confidence: 99%

Section: Dispersal Of Rna Polymerase II Clusters By An Amphiphilic Ef...mentioning

confidence: 99%

mentioning

confidence: 98%

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Amphiphiles Formed from Synthetic DNA-Nanomotifs Mimic the Stepwise Dispersal of Transcriptional Clusters in the Cell Nucleus

Tschurikow,

Gadzekpo,

Tran

et al. 2023

Nano Lett.

Self Cite

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“…The authors performed Monte Carlo simulations to explain the experimentally observed microphase separation. In subsequent studies ( Pancholi et al, 2021 ; Hajiabadi et al, 2022 ), it was shown that RNA Pol II exhibit different types of organization depending on its phosphorylation state and interactions with active genes. Our findings complement these previous studies by showing experimental evidence of a robust core-shell organization of chromatin and RNA Pol II.…”

Section: Introductionmentioning

confidence: 99%

Regulation of chromatin microphase separation by binding of protein complexes

Adame-Arana

Bajpai

Lorber

et al. 2023

eLife

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We show evidence of the association of RNA polymerase II (RNAP) with chromatin in a core-shell organization, reminiscent of microphase separation where the cores comprise dense chromatin and the shell, RNAP and chromatin with low density. These observations motivate our physical model for the regulation of core-shell chromatin organization. Here, we model chromatin as a multiblock copolymer, comprising active and inactive regions (blocks) that are both in poor solvent and tend to be condensed in the absence of binding proteins. However, we show that the solvent quality for the active regions of chromatin can be regulated by the binding of protein complexes (e.g., RNAP and transcription factors). Using the theory of polymer brushes, we find that such binding leads to swelling of the active chromatin regions which in turn modifies the spatial organization of the inactive regions. In addition, we use simulations to study spherical chromatin micelles, whose cores comprise inactive regions and shells comprise active regions and bound protein complexes. In spherical micelles the swelling increases the number of inactive cores and controls their size. Thus, genetic modifications affecting the binding strength of chromatin-binding protein complexes may modulate the solvent quality experienced by chromatin and regulate the physical organization of the genome.

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“…The authors performed Monte Carlo simulations to explain the experimentally observed microphase separation. In subsequent studies [43,44], it was shown that RNA Pol II exhibit different types of organization depending on its phosphorylation state and interactions with active genes. Our findings complement these previous studies by showing experimental evidence of a robust core-shell organization of chromatin and RNA Pol II.…”

Section: Introductionmentioning

confidence: 99%

Regulation of chromatin microphase separation by adsorbed protein complexes

Adame-Arana

Bajpai

Lorber

et al. 2022

Preprint

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We show evidence of the association of RNA Polymerase II (RNAP) with chromatin in a core-shell organization, reminiscent of microphase separation where the cores comprise dense chromatin and the shell, RNAP and chromatin with low density. These observations motivate our physical model for the regulation of core-shell chromatin organization. Here, we model chromatin as a multiblock copolymer, comprising active and inactive regions (blocks) that are both in poor solvent and tend to be condensed in the absence of binding proteins. However, we show that the solvent quality for the active regions of chromatin can be regulated by the binding of protein complexes (e.g. RNAP). Using the theory of polymer brushes, we find that such binding leads to swelling of the active chromatin regions which in turn, modifies the spatial organization of the inactive regions. In addition, we use simulations to study spherical chromatin micelles, whose cores comprise inactive regions and shells comprise active regions and bound protein complexes. In spherical micelles the swelling increases the number of inactive cores and controls their size. Thus, genetic modifications affecting the binding strength of chromatin-binding protein complexes may modulate the solvent quality experienced by chromatin and regulate the physical organization of the genome.

show abstract

Deep-learning microscopy image reconstruction with quality control reveals second-scale rearrangements in RNA polymerase II clusters

Cited by 7 publications

References 70 publications

Amphiphiles Formed from Synthetic DNA-Nanomotifs Mimic the Stepwise Dispersal of Transcriptional Clusters in the Cell Nucleus

Amphiphiles Formed from Synthetic DNA-Nanomotifs Mimic the Stepwise Dispersal of Transcriptional Clusters in the Cell Nucleus

Regulation of chromatin microphase separation by binding of protein complexes

Regulation of chromatin microphase separation by adsorbed protein complexes

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