Luca Fiorillo scite author profile

The spatial organization of chromosomes has key functional roles, yet how chromosomes fold remains poorly understood at the single-molecule level. Here, we employ models of polymer physics to investigate DNA loci in human HCT116 and IMR90 wild-type and cohesin depleted cells. Model predictions on single-molecule structures are validated against singlecell imaging data, providing evidence that chromosomal architecture is controlled by a thermodynamics mechanism of polymer phase separation whereby chromatin self-assembles in segregated globules by combinatorial interactions of chromatin factors that include CTCF and cohesin. The thermodynamics degeneracy of single-molecule conformations results in broad structural and temporal variability of TAD-like contact patterns. Globules establish stable environments where specific contacts are highly favored over stochastic encounters. Cohesin depletion reverses phase separation into randomly folded states, erasing average interaction patterns. Overall, globule phase separation appears to be a robust yet reversible mechanism of chromatin organization where stochasticity and specificity coexist.

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Cell-type specialization is encoded by specific chromatin topologies

Winick-Ng

Kukalev

Harabula

et al. 2021

Nature

131

139

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The three-dimensional (3D) structure of chromatin is intrinsically associated with gene regulation and cell function1–3. Methods based on chromatin conformation capture have mapped chromatin structures in neuronal systems such as in vitro differentiated neurons, neurons isolated through fluorescence-activated cell sorting from cortical tissues pooled from different animals and from dissociated whole hippocampi4–6. However, changes in chromatin organization captured by imaging, such as the relocation of Bdnf away from the nuclear periphery after activation7, are invisible with such approaches8. Here we developed immunoGAM, an extension of genome architecture mapping (GAM)2,9, to map 3D chromatin topology genome-wide in specific brain cell types, without tissue disruption, from single animals. GAM is a ligation-free technology that maps genome topology by sequencing the DNA content from thin (about 220 nm) nuclear cryosections. Chromatin interactions are identified from the increased probability of co-segregation of contacting loci across a collection of nuclear slices. ImmunoGAM expands the scope of GAM to enable the selection of specific cell types using low cell numbers (approximately 1,000 cells) within a complex tissue and avoids tissue dissociation2,10. We report cell-type specialized 3D chromatin structures at multiple genomic scales that relate to patterns of gene expression. We discover extensive ‘melting’ of long genes when they are highly expressed and/or have high chromatin accessibility. The contacts most specific of neuron subtypes contain genes associated with specialized processes, such as addiction and synaptic plasticity, which harbour putative binding sites for neuronal transcription factors within accessible chromatin regions. Moreover, sensory receptor genes are preferentially found in heterochromatic compartments in brain cells, which establish strong contacts across tens of megabases. Our results demonstrate that highly specific chromatin conformations in brain cells are tightly related to gene regulation mechanisms and specialized functions.

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A Dynamic Folded Hairpin Conformation Is Associated with α-Globin Activation in Erythroid Cells

et al. 2020

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Graphical AbstractHighlights d The structure of the mouse a-globin locus is investigated with polymer physics models d The conformation is highly intermingled when the globin genes are inactive in ESCs d The locus is folded in a hairpin-shaped conformation when active in erythroid cells d The model accurately predicts three-way contacts, as confirmed by TriC experimental data Correspondence chiariello@na.infn.it (A.M.C.), mario.nicodemi@na.infn.it (M.N.) In BriefChiariello et al. use polymer physics models to infer the 3D conformations of the murine a-globin locus. In the transition from ESCs to erythroid cells, the locus rearranges from an inactive highly intermingled conformation to an active, hairpin-shaped structure, marked by cell-specific three-way contacts accurately predicted by the models. SUMMARYWe investigate the three-dimensional (3D) conformations of the a-globin locus at the single-allele level in murine embryonic stem cells (ESCs) and erythroid cells, combining polymer physics models and high-resolution Capture-C data. Model predictions are validated against independent fluorescence in situ hybridization (FISH) data measuring pairwise distances, and Tri-C data identifying three-way contacts. The architecture is rearranged during the transition from ESCs to erythroid cells, associated with the activation of the globin genes. We find that in ESCs, the spatial organization conforms to a highly intermingled 3D structure involving non-specific contacts, whereas in erythroid cells the a-globin genes and their enhancers form a self-contained domain, arranged in a folded hairpin conformation, separated from intermingling flanking regions by a thermodynamic mechanism of micro-phase separation. The flanking regions are rich in convergent CTCF sites, which only marginally participate in the erythroid-specific geneenhancer contacts, suggesting that beyond the interaction of CTCF sites, multiple molecular mechanisms cooperate to form an interacting domain.

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Polymer physics reveals a combinatorial code linking 3D chromatin architecture to 1D chromatin states

et al. 2022

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Luca Fiorillo

Polymer physics indicates chromatin folding variability across single-cells results from state degeneracy in phase separation

Cell-type specialization is encoded by specific chromatin topologies

A Dynamic Folded Hairpin Conformation Is Associated with α-Globin Activation in Erythroid Cells

Polymer physics reveals a combinatorial code linking 3D chromatin architecture to 1D chromatin states

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