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207 results on '"Chiariello, Andrea M."'

4. The interplay between phase-separation and gene-enhancer communication: a theoretical study

Author

Chiariello, Andrea M., Corberi, Federico, and Salerno, Mario

Subjects
Condensed Matter - Soft Condensed Matter, Condensed Matter - Statistical Mechanics, Physics - Biological Physics
Abstract

The phase-separation occurring in a system of mutually interacting proteins that can bind on specific sites of a chromatin fiber is here investigated. This is achieved by means of extensive Molecular Dynamics simulations of a simple polymer model which includes regulatory proteins as interacting spherical particles. Our interest is particularly focused on the role played by phase-separation in the formation of molecule aggregates that can join distant regulatory elements, such as gene promoters and enhancers, along the DNA. We find that the overall equilibrium state of the system resulting from the mutual interplay between binding molecules and chromatin can lead, under suitable conditions that depend on molecules concentration, molecule-molecule and molecule-DNA interactions, to the formation of phase-separated molecular clusters allowing robust contacts between regulatory sites. Vice-versa, the presence of regulatory sites can promote the phase-separation process. Different dynamical regimes can generate the enhancer-promoter contact, either by cluster nucleation at binding sites or by bulk spontaneous formation of the mediating cluster to which binding sites are successively attracted. The possibility that such processes can explain experimental live-cell imaging data measuring distances between regulatory sites during time is also discussed., Comment: 29 pages, 7 figures

Published
2020
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5. CTCF mediates dosage- and sequence-context-dependent transcriptional insulation by forming local chromatin domains

Author

Huang, Hui, Zhu, Quan, Jussila, Adam, Han, Yuanyuan, Bintu, Bogdan, Kern, Colin, Conte, Mattia, Zhang, Yanxiao, Bianco, Simona, Chiariello, Andrea M, Yu, Miao, Hu, Rong, Tastemel, Melodi, Juric, Ivan, Hu, Ming, Nicodemi, Mario, Zhuang, Xiaowei, and Ren, Bing

Subjects
Stem Cell Research - Nonembryonic - Non-Human, Stem Cell Research, Genetics, 1.1 Normal biological development and functioning, Underpinning research, Generic health relevance, Animals, Binding Sites, CCCTC-Binding Factor, Chromatin, Enhancer Elements, Genetic, Gene Expression Regulation, Humans, Insulator Elements, Mice, Mouse Embryonic Stem Cells, Promoter Regions, Genetic, Protein Binding, Transcription, Genetic, Biological Sciences, Medical and Health Sciences, Developmental Biology
Abstract

Insulators play a critical role in spatiotemporal gene regulation in animals. The evolutionarily conserved CCCTC-binding factor (CTCF) is required for insulator function in mammals, but not all of its binding sites act as insulators. Here we explore the sequence requirements of CTCF-mediated transcriptional insulation using a sensitive insulator reporter in mouse embryonic stem cells. We find that insulation potency depends on the number of CTCF-binding sites in tandem. Furthermore, CTCF-mediated insulation is dependent on upstream flanking sequences at its binding sites. CTCF-binding sites at topologically associating domain boundaries are more likely to function as insulators than those outside topologically associating domain boundaries, independently of binding strength. We demonstrate that insulators form local chromatin domain boundaries and weaken enhancer-promoter contacts. Taken together, our results provide genetic, molecular and structural evidence connecting chromatin topology to the action of insulators in the mammalian genome.

Published
2021

10. Analysis of Genome Architecture Mapping Data with a Machine Learning and Polymer-Physics-Based Tool

Author

Fiorillo, Luca, Conte, Mattia, Esposito, Andrea, Musella, Francesco, Flora, Francesco, Chiariello, Andrea M., Bianco, Simona, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Balis, Bartosz, editor, B. Heras, Dora, editor, Antonelli, Laura, editor, Bracciali, Andrea, editor, Gruber, Thomas, editor, Hyun-Wook, Jin, editor, Kuhn, Michael, editor, Scott, Stephen L., editor, Unat, Didem, editor, and Wyrzykowski, Roman, editor

Published
2021
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11. Dynamic 3D chromatin architecture contributes to enhancer specificity and limb morphogenesis

Author

Kragesteen, Bjørt K, Spielmann, Malte, Paliou, Christina, Heinrich, Verena, Schöpflin, Robert, Esposito, Andrea, Annunziatella, Carlo, Bianco, Simona, Chiariello, Andrea M, Jerković, Ivana, Harabula, Izabela, Guckelberger, Philine, Pechstein, Michael, Wittler, Lars, Chan, Wing-Lee, Franke, Martin, Lupiáñez, Darío G, Kraft, Katerina, Timmermann, Bernd, Vingron, Martin, Visel, Axel, Nicodemi, Mario, Mundlos, Stefan, and Andrey, Guillaume

Subjects
Biochemistry and Cell Biology, Biological Sciences, Genetics, Pediatric, Congenital Structural Anomalies, Underpinning research, 1.1 Normal biological development and functioning, Animals, CRISPR-Cas Systems, Chromatin, Chromatin Assembly and Disassembly, DNA, Embryo, Mammalian, Enhancer Elements, Genetic, Forelimb, Gene Expression Regulation, Developmental, Hindlimb, Mice, Mice, Transgenic, Molecular Conformation, Morphogenesis, Nucleic Acid Conformation, Paired Box Transcription Factors, Medical and Health Sciences, Developmental Biology, Agricultural biotechnology, Bioinformatics and computational biology
Abstract

The regulatory specificity of enhancers and their interaction with gene promoters is thought to be controlled by their sequence and the binding of transcription factors. By studying Pitx1, a regulator of hindlimb development, we show that dynamic changes in chromatin conformation can restrict the activity of enhancers. Inconsistent with its hindlimb-restricted expression, Pitx1 is controlled by an enhancer (Pen) that shows activity in forelimbs and hindlimbs. By Capture Hi-C and three-dimensional modeling of the locus, we demonstrate that forelimbs and hindlimbs have fundamentally different chromatin configurations, whereby Pen and Pitx1 interact in hindlimbs and are physically separated in forelimbs. Structural variants can convert the inactive into the active conformation, thereby inducing Pitx1 misexpression in forelimbs, causing partial arm-to-leg transformation in mice and humans. Thus, tissue-specific three-dimensional chromatin conformation can contribute to enhancer activity and specificity in vivo and its disturbance can result in gene misexpression and disease.

Published
2018

12. A single dose of cocaine rewires the 3D genome structure of midbrain dopamine neurons

Author

Szabo, Dominik, primary, Franke, Vedran, additional, Bianco, Simona, additional, Batiuk, Mykhailo Y., additional, Paul, Eleanor J., additional, Kukalev, Alexander, additional, Pfisterer, Ulrich G., additional, Irastorza-Azcarate, Ibai, additional, Chiariello, Andrea M., additional, Demharter, Samuel, additional, Zea Redondo, Luna, additional, Lopez-Atalaya, Jose P., additional, Nicodemi, Mario, additional, Khodosevich, Konstantin, additional, Akalin, Altuna, additional, Ungless, Mark A., additional, Winick-Ng, Warren, additional, and Pombo, Ana, additional

Published
2024
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13. Cell-type specialization is encoded by specific chromatin topologies

Author

Winick-Ng, Warren, Kukalev, Alexander, Harabula, Izabela, Zea-Redondo, Luna, Szabó, Dominik, Meijer, Mandy, Serebreni, Leonid, Zhang, Yingnan, Bianco, Simona, Chiariello, Andrea M., Irastorza-Azcarate, Ibai, Thieme, Christoph J., Sparks, Thomas M., Carvalho, Silvia, Fiorillo, Luca, Musella, Francesco, and Irani, Ehsan

Subjects
Chromatin -- Physiological aspects, Genetic regulation -- Physiological aspects, Cells -- Genetic aspects, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

The three-dimensional (3D) structure of chromatin is intrinsically associated with gene regulation and cell function.sup.1-3. 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 hippocampi.sup.4-6. However, changes in chromatin organization captured by imaging, such as the relocation of Bdnf away from the nuclear periphery after activation.sup.7, are invisible with such approaches.sup.8. Here we developed immunoGAM, an extension of genome architecture mapping (GAM).sup.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 dissociation.sup.2,10. 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. A new technique called immunoGAM, which combines genome architecture mapping (GAM) with immunoselection, enabled the discovery of specialized chromatin conformations linked to gene expression in specific cell populations from mouse brain tissues., Author(s): Warren Winick-Ng [sup.1] , Alexander Kukalev [sup.1] , Izabela Harabula [sup.1] [sup.2] , Luna Zea-Redondo [sup.1] [sup.2] , Dominik Szabó [sup.1] [sup.2] , Mandy Meijer [sup.3] , Leonid Serebreni [...]

Published
2021
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15. Understanding Chromatin Structure: Efficient Computational Implementation of Polymer Physics Models

Author

Bianco, Simona, Annunziatella, Carlo, Esposito, Andrea, Fiorillo, Luca, Conte, Mattia, Campanile, Raffaele, Chiariello, Andrea M., Hutchison, David, Series Editor, Kanade, Takeo, Series Editor, Kittler, Josef, Series Editor, Kleinberg, Jon M., Series Editor, Mattern, Friedemann, Series Editor, Mitchell, John C., Series Editor, Naor, Moni, Series Editor, Pandu Rangan, C., Series Editor, Steffen, Bernhard, Series Editor, Terzopoulos, Demetri, Series Editor, Tygar, Doug, Series Editor, Mencagli, Gabriele, editor, B. Heras, Dora, editor, Cardellini, Valeria, editor, Casalicchio, Emiliano, editor, Jeannot, Emmanuel, editor, Wolf, Felix, editor, Salis, Antonio, editor, Schifanella, Claudio, editor, Manumachu, Ravi Reddy, editor, Ricci, Laura, editor, Beccuti, Marco, editor, Antonelli, Laura, editor, Garcia Sanchez, José Daniel, editor, and Scott, Stephen L., editor

Published
2019
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30. Repression and 3D-restructuring resolves regulatory conflicts in evolutionarily rearranged genomes

Author

Ringel, Alessa R., primary, Szabo, Quentin, additional, Chiariello, Andrea M., additional, Chudzik, Konrad, additional, Schöpflin, Robert, additional, Rothe, Patricia, additional, Mattei, Alexandra L., additional, Zehnder, Tobias, additional, Harnett, Dermot, additional, Laupert, Verena, additional, Bianco, Simona, additional, Hetzel, Sara, additional, Glaser, Juliane, additional, Phan, Mai H.Q., additional, Schindler, Magdalena, additional, Ibrahim, Daniel M., additional, Paliou, Christina, additional, Esposito, Andrea, additional, Prada-Medina, Cesar A., additional, Haas, Stefan A., additional, Giere, Peter, additional, Vingron, Martin, additional, Wittler, Lars, additional, Meissner, Alexander, additional, Nicodemi, Mario, additional, Cavalli, Giacomo, additional, Bantignies, Frédéric, additional, Mundlos, Stefan, additional, and Robson, Michael I., additional

Published
2022
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31. Repression and 3D-restructuring resolves regulatory conflicts in evolutionarily rearranged genomes

Author

Centre National de la Recherche Scientifique (France), Université de Montpellier, CINECA, European Research Council, EMBO, Wellcome Trust, German Research Foundation, Ringel, Alessa R., Szabo, Quentin, Chiariello, Andrea M., Chudzik, Konrad, Schöpflin, Robert, Rothe, Patricia, Mattei, Alexandra L., Zehnder, Tobias, Harnett, Dermot, Laupert, Verena, Bianco, Simona, Hetzel, Sara, Glaser, Juliane, Phan, Mai H.Q., Schindler, Magdalena, Ibrahim, Daniel M., Paliou, Christina, Esposito, Andrea, Prada-Medina, César A., Haas, Stefan A., Robson, Michael I., Centre National de la Recherche Scientifique (France), Université de Montpellier, CINECA, European Research Council, EMBO, Wellcome Trust, German Research Foundation, Ringel, Alessa R., Szabo, Quentin, Chiariello, Andrea M., Chudzik, Konrad, Schöpflin, Robert, Rothe, Patricia, Mattei, Alexandra L., Zehnder, Tobias, Harnett, Dermot, Laupert, Verena, Bianco, Simona, Hetzel, Sara, Glaser, Juliane, Phan, Mai H.Q., Schindler, Magdalena, Ibrahim, Daniel M., Paliou, Christina, Esposito, Andrea, Prada-Medina, César A., Haas, Stefan A., and Robson, Michael I.

Abstract

Regulatory landscapes drive complex developmental gene expression, but it remains unclear how their integrity is maintained when incorporating novel genes and functions during evolution. Here, we investigated how a placental mammal-specific gene, Zfp42, emerged in an ancient vertebrate topologically associated domain (TAD) without adopting or disrupting the conserved expression of its gene, Fat1. In ESCs, physical TAD partitioning separates Zfp42 and Fat1 with distinct local enhancers that drive their independent expression. This separation is driven by chromatin activity and not CTCF/cohesin. In contrast, in embryonic limbs, inactive Zfp42 shares Fat1’s intact TAD without responding to active Fat1 enhancers. However, neither Fat1 enhancer-incompatibility nor nuclear envelope-attachment account for Zfp42’s unresponsiveness. Rather, Zfp42’s promoter is rendered inert to enhancers by context-dependent DNA methylation. Thus, diverse mechanisms enabled the integration of independent Zfp42 regulation in the Fat1 locus. Critically, such regulatory complexity appears common in evolution as, genome wide, most TADs contain multiple independently expressed genes.

Published
2022

33. Further Delineation of Duplications of ARX Locus Detected in Male Patients with Varying Degrees of Intellectual Disability

Author

Poeta, Loredana, primary, Malacarne, Michela, additional, Padula, Agnese, additional, Drongitis, Denise, additional, Verrillo, Lucia, additional, Lioi, Maria Brigida, additional, Chiariello, Andrea M., additional, Bianco, Simona, additional, Nicodemi, Mario, additional, Piccione, Maria, additional, Salzano, Emanuela, additional, Coviello, Domenico, additional, and Miano, Maria Giuseppina, additional

Published
2022
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36. Additional file 6 of Hmga2 protein loss alters nuclear envelope and 3D chromatin structure

Author

Divisato, Giuseppina, Chiariello, Andrea M., Esposito, Andrea, Zoppoli, Pietro, Zambelli, Federico, Elia, Maria Antonietta, Pesole, Graziano, Incarnato, Danny, Passaro, Fabiana, Piscitelli, Silvia, Oliviero, Salvatore, Nicodemi, Mario, Parisi, Silvia, and Russo, Tommaso

Abstract

Additional file 6: Figure S4. Absence of nuclear alterations in Hmga2 KO undifferentiated cells. Lmnb1 (red) and Emerin (green) immunofluorescence on undifferentiated Hmga2 wt and KO cells showing the absence of nuclear abnormalities. DAPI (blue) was used to counterstain the nuclei. Maximum projection of z-slices (ROI 1024x1024) is shown. Scale bar = 50 μm.

Published
2022
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37. Additional file 7 of Hmga2 protein loss alters nuclear envelope and 3D chromatin structure

Author

Divisato, Giuseppina, Chiariello, Andrea M., Esposito, Andrea, Zoppoli, Pietro, Zambelli, Federico, Elia, Maria Antonietta, Pesole, Graziano, Incarnato, Danny, Passaro, Fabiana, Piscitelli, Silvia, Oliviero, Salvatore, Nicodemi, Mario, Parisi, Silvia, and Russo, Tommaso

Abstract

Additional file 7: Figure S5. Hmga2 wt and KO cells showed a similar localization of several histone H3 modifications upon the induction of EpiLCs. Immunoflurescence experiments on Hmga2 wt and KO cells at day 1 after the induction of EpiLCs. Lmnb1 (red) and H3K4me3, H3K9me2, H3K27me3 and H3K27ac (green) as indicated. Scale bars=50 μm. Quantification graphs obtained by counting >200 nuclei/condition. Error bars represent standard deviation. Statistical significance on three biological replicate experiments was determined using the student’s t-test, ns: not significant).

Published
2022
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38. Additional file 4 of Hmga2 protein loss alters nuclear envelope and 3D chromatin structure

Author

Divisato, Giuseppina, Chiariello, Andrea M., Esposito, Andrea, Zoppoli, Pietro, Zambelli, Federico, Elia, Maria Antonietta, Pesole, Graziano, Incarnato, Danny, Passaro, Fabiana, Piscitelli, Silvia, Oliviero, Salvatore, Nicodemi, Mario, Parisi, Silvia, and Russo, Tommaso

Abstract

Additional file 4: Figure S2. Histone marks at Hmga2 peaks in wt and Hmga2 KD EpiSCs. Chromatin from EpiSCs transfected with control (WT) and Hmga2 targeting siRNAs (KD) was immunoprecipitated with IgG or anti-H3K4me1 or anti-H3K27ac antibodies. Immunoprecipitated DNA was amplified by using oligo pairs annealing to the indicated Hmga2 peaks, which were associated by ChIP-seq with H3K4me1 and/or H3K27ac peaks. A region overlapping the miR-23a gene enhancer was used as a control; Hmga2 peak 10319, not associated with histone modifications, was used as a negative control.

Published
2022
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39. Additional file 8 of Hmga2 protein loss alters nuclear envelope and 3D chromatin structure

Author

Divisato, Giuseppina, Chiariello, Andrea M., Esposito, Andrea, Zoppoli, Pietro, Zambelli, Federico, Elia, Maria Antonietta, Pesole, Graziano, Incarnato, Danny, Passaro, Fabiana, Piscitelli, Silvia, Oliviero, Salvatore, Nicodemi, Mario, Parisi, Silvia, and Russo, Tommaso

Abstract

Additional file 8: Figure S6. Treatment of wt and KO cells with PRC2 inhibitor and its effect on nuclear lamina. (A) Western blotting image showing the level of H3K27me3 histone modifications in Hmga2 wt and KO PSCs treated or not with PRC2 inhibitor at day 0 and at day 1 after the induction of the transition into EpiLCs. The levels of the histone H3 were used as control. (B) Immunoflurescence experiments on Hmga2 wt and KO cells treated or not with PRC2 inhibitor at day 1 after the induction of EpiLCs showing the nuclear lamina phenotype. All pictures are shown as single z-plane, ROI 1024x1024, scale bar=50μm. Quantification graph showing the percentage of cells with nuclear lamina distortion in Hmga2 wt and KO cells treated or not with PRC2 inhibitor (n≤100 nuclei per condition). The count was performed at day 1 of EpiLC transition on three biological replicates. Error bars represent standard deviation. Statistical significance was determined using the student’s t-test (ns: not significant).

Published
2022
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40. Additional file 1 of Hmga2 protein loss alters nuclear envelope and 3D chromatin structure

Author

Divisato, Giuseppina, Chiariello, Andrea M., Esposito, Andrea, Zoppoli, Pietro, Zambelli, Federico, Elia, Maria Antonietta, Pesole, Graziano, Incarnato, Danny, Passaro, Fabiana, Piscitelli, Silvia, Oliviero, Salvatore, Nicodemi, Mario, Parisi, Silvia, and Russo, Tommaso

Abstract

Additional file 1: Figure S1. Hmga2 western blot in wt and KO cells; quantification of western blot of Fig. 1A. (A) western blot analysis of wt and KO cells with Hmga2 ab; Gapdh was used as loading control. (B) The data in the graphs represent the mean ± SD (n=3 biological replicates) of H3K27me3, H3K4me3, H3K9me2, H3K9me3 and H3K27ac against total H3. Student’s t-test, two tailed (ns: not significant, *p

Published
2022
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41. Additional file 5 of Hmga2 protein loss alters nuclear envelope and 3D chromatin structure

Author

Divisato, Giuseppina, Chiariello, Andrea M., Esposito, Andrea, Zoppoli, Pietro, Zambelli, Federico, Elia, Maria Antonietta, Pesole, Graziano, Incarnato, Danny, Passaro, Fabiana, Piscitelli, Silvia, Oliviero, Salvatore, Nicodemi, Mario, Parisi, Silvia, and Russo, Tommaso

Abstract

Additional file 5: Figure S3. Lmnb1 abnormalities occur during the transition from the naïve state to the primed state of pluripotency. (A) Western blotting image showing Lmnb1 expression in Hmga2 wt and KO cells at day 3 after the induction of EpiLCs. Two different clones of PSCs were induced into EpiLCs for each condition. Western blotting quantification revealed no differences in terms of Lmnb1 expression between Hmga2 wild type and knock-out cells. The data in the graphs represent the mean ± SD of the Lmnb1 signal against Gapdh (n=3 biological replicates). ns: not significant (Student’s t-test, two tailed). (B) Lmnb1 immunofluorescence (red) on undifferentiated Hmga2 wt and KO cells showing no structural abnormalities of the nuclei. DAPI (blue) was used to counterstain the nuclei. A single plane of z-stack projection is shown. Scale bar = 50 μm. The data in the graphs represent the mean ± SD of the Lmnb1 signal against Gapdh (n=3 biological replicates). ns: not significant (Student’s t-test, two tailed). (C) q-PCR analysis to evaluate the levels of Hmga2 mRNA in EpiLCs upon transfection of siRNA. Non-silencing siRNA was used as control. The data in the graphs are reported as mean ± SD of relative values (fold changes) obtained normalizing the data of Hmga2 silencing with those of non-silencing control siRNA. **p

Published
2022
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44. Promoter repression and 3D-restructuring resolves divergent developmental gene expression in TADs

Author

Ringel, Alessa R., primary, Szabo, Quentin, additional, Chiariello, Andrea M., additional, Chudzik, Konrad, additional, Schöpflin, Robert, additional, Rothe, Patricia, additional, Mattei, Alexandra L., additional, Zehnder, Tobias, additional, Harnett, Dermot, additional, Laupert, Verena, additional, Bianco, Simona, additional, Hetzel, Sara, additional, Phan, Mai, additional, Schindler, Magdalena, additional, Ibrahim, Daniel, additional, Paliou, Christina, additional, Esposito, Andrea, additional, Prada-Medina, Cesar A., additional, Haas, Stefan, additional, Giere, Peter, additional, Vingron, Martin, additional, Wittler, Lars, additional, Meissner, Alexander, additional, Nicodemi, Mario, additional, Cavalli, Giacomo, additional, Bantignies, Frédéric, additional, Mundlos, Stefan, additional, and Robson, Michael I., additional

Published
2021
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45. Hierarchical folding and reorganization of chromosomes are linked to transcriptional changes in cellular differentiation

Author

Fraser, James, Ferrai, Carmelo, Chiariello, Andrea M, Schueler, Markus, Rito, Tiago, Laudanno, Giovanni, Barbieri, Mariano, Moore, Benjamin L, Kraemer, Dorothee CA, Aitken, Stuart, Xie, Sheila Q, Morris, Kelly J, Itoh, Masayoshi, Kawaji, Hideya, Jaeger, Ines, Hayashizaki, Yoshihide, Carninci, Piero, Forrest, Alistair RR, Semple, Colin A, Dostie, Josée, Pombo, Ana, and Nicodemi, Mario

Published
2015
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48. Physical mechanisms of chromatin spatial organization

Author

Chiariello, Andrea M., primary, Bianco, Simona, additional, Esposito, Andrea, additional, Fiorillo, Luca, additional, Conte, Mattia, additional, Irani, Ehsan, additional, Musella, Francesco, additional, Abraham, Alex, additional, Prisco, Antonella, additional, and Nicodemi, Mario, additional

Published
2021
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49. Physical mechanisms of chromatin spatial organization.

Author

Chiariello, Andrea M., Bianco, Simona, Esposito, Andrea, Fiorillo, Luca, Conte, Mattia, Irani, Ehsan, Musella, Francesco, Abraham, Alex, Prisco, Antonella, and Nicodemi, Mario

Subjects
*CELL nuclei, *CHROMATIN, *REGULATOR genes, *PHASE separation, *GENETIC regulation, *CONGENITAL disorders, *GENETIC mutation
Abstract

In higher eukaryotes, chromosomes have a complex three‐dimensional (3D) conformation in the cell nucleus serving vital functional purposes, yet their folding principles remain poorly understood at the single‐molecule level. Here, we summarize recent approaches from polymer physics to comprehend the physical mechanisms underlying chromatin architecture. In particular, we focus on two models that have been supported by recent, growing experimental evidence, the Loop Extrusion model and the Strings&Binders phase separation model. We discuss their key ingredients, how they compare to experimental data and some insight they provide on chromatin architecture and gene regulation. Progress in that research field are opening the possibility to predict how genomic mutations alter the network of contacts between genes and their regulators and how that is linked to genetic diseases, such as congenital disorders and cancer. [ABSTRACT FROM AUTHOR]

Published
2022
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