Your search keyword '"loop extrusion"' showing total 12 results

1. Multi-scale phase separation by explosive percolation with single-chromatin loop resolution

Author

Sengupta, Kaustav, Denkiewicz, Michał, Chiliński, Mateusz, Szczepińska, Teresa, Mollah, Ayatullah Faruk, Korsak, Sevastianos, D'Souza, Raissa, Ruan, Yijun, and Plewczynski, Dariusz

Subjects

Biochemistry and Cell Biology, Biological Sciences, Human Genome, Bioengineering, Genetics, 1.1 Normal biological development and functioning, Underpinning research, 3D genomics, Chromatin folding, Compartmentalisation, Loop extrusion, Networks, Percolation, Phase separation, Scalar parameter, Numerical and Computational Mathematics, Computation Theory and Mathematics, Biochemistry and cell biology, Applied computing

Abstract

The 2 m-long human DNA is tightly intertwined into the cell nucleus of the size of 10 μm. The DNA packing is explained by folding of chromatin fiber. This folding leads to the formation of such hierarchical structures as: chromosomal territories, compartments; densely-packed genomic regions known as Topologically Associating Domains (TADs), or Chromatin Contact Domains (CCDs), and loops. We propose models of dynamical human genome folding into hierarchical components in human lymphoblastoid, stem cell, and fibroblast cell lines. Our models are based on explosive percolation theory. The chromosomes are modeled as graphs where CTCF chromatin loops are represented as edges. The folding trajectory is simulated by gradually introducing loops to the graph following various edge addition strategies that are based on topological network properties, chromatin loop frequencies, compartmentalization, or epigenomic features. Finally, we propose the genome folding model - a biophysical pseudo-time process guided by a single scalar order parameter. The parameter is calculated by Linear Discriminant Analysis of chromatin features. We also include dynamics of loop formation by using Loop Extrusion Model (LEM) while adding them to the system. The chromatin phase separation, where fiber folds in 3D space into topological domains and compartments, is observed when the critical number of contacts is reached. We also observe that at least 80% of the loops are needed for chromatin fiber to condense in 3D space, and this is constant through various cell lines. Overall, our in-silico model integrates the high-throughput 3D genome interaction experimental data with the novel theoretical concept of phase separation, which allows us to model event-based time dynamics of chromatin loop formation and folding trajectories.

Published

2022

2. Spatial Organization of Chromatin: Emergence of Chromatin Structure During Development

Author

Ghosh, Rajarshi P and Meyer, Barbara J

Subjects

Human Genome, Genetics, Biotechnology, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Chromatin, Chromosomes, DNA, Genome, In Situ Hybridization, Fluorescence, chromosome topology, cohesin and condensin complexes, loop extrusion, phase separation, gametogenesis, zygotic genome activation, neural development, Biological Sciences, Medical and Health Sciences, Developmental Biology

Abstract

Nuclei are central hubs for information processing in eukaryotic cells. The need to fit large genomes into small nuclei imposes severe restrictions on genome organization and the mechanisms that drive genome-wide regulatory processes. How a disordered polymer such as chromatin, which has vast heterogeneity in its DNA and histone modification profiles, folds into discernibly consistent patterns is a fundamental question in biology. Outstanding questions include how genomes are spatially and temporally organized to regulate cellular processes with high precision and whether genome organization is causally linked to transcription regulation. The advent of next-generation sequencing, super-resolution imaging, multiplexed fluorescent in situ hybridization, and single-molecule imaging in individual living cells has caused a resurgence in efforts to understand the spatiotemporal organization of the genome. In this review, we discuss structural and mechanistic properties of genome organization at different length scales and examine changes in higher-order chromatin organization during important developmental transitions.

Published

2021

3. Defining the relative and combined contribution of CTCF and CTCFL to genomic regulation

Author

Nishana, Mayilaadumveettil, Ha, Caryn, Rodriguez-Hernaez, Javier, Ranjbaran, Ali, Chio, Erica, Nora, Elphege P, Badri, Sana B, Kloetgen, Andreas, Bruneau, Benoit G, Tsirigos, Aristotelis, and Skok, Jane A

Subjects

Human Genome, Stem Cell Research - Nonembryonic - Non-Human, Stem Cell Research, Genetics, Cancer, Underpinning research, 1.1 Normal biological development and functioning, Animals, CCCTC-Binding Factor, Chromatin Assembly and Disassembly, DNA-Binding Proteins, Embryonic Stem Cells, Female, Gene Expression Regulation, Neoplastic, Humans, Male, Mice, CTCF, CTCFL, Cohesin, Loop extrusion, 3D chromatin architecture, Gene regulation, Chromatin insulation, Environmental Sciences, Biological Sciences, Information and Computing Sciences, Bioinformatics

Abstract

BackgroundUbiquitously expressed CTCF is involved in numerous cellular functions, such as organizing chromatin into TAD structures. In contrast, its paralog, CTCFL, is normally only present in the testis. However, it is also aberrantly expressed in many cancers. While it is known that shared and unique zinc finger sequences in CTCF and CTCFL enable CTCFL to bind competitively to a subset of CTCF binding sites as well as its own unique locations, the impact of CTCFL on chromosome organization and gene expression has not been comprehensively analyzed in the context of CTCF function. Using an inducible complementation system, we analyze the impact of expressing CTCFL and CTCF-CTCFL chimeric proteins in the presence or absence of endogenous CTCF to clarify the relative and combined contribution of CTCF and CTCFL to chromosome organization and transcription.ResultsWe demonstrate that the N terminus of CTCF interacts with cohesin which explains the requirement for convergent CTCF binding sites in loop formation. By analyzing CTCF and CTCFL binding in tandem, we identify phenotypically distinct sites with respect to motifs, targeting to promoter/intronic intergenic regions and chromatin folding. Finally, we reveal that the N, C, and zinc finger terminal domains play unique roles in targeting each paralog to distinct binding sites to regulate transcription, chromatin looping, and insulation.ConclusionThis study clarifies the unique and combined contribution of CTCF and CTCFL to chromosome organization and transcription, with direct implications for understanding how their co-expression deregulates transcription in cancer.

Published

2020

4. Resolving the 3D Landscape of Transcription-Linked Mammalian Chromatin Folding

Author

Hsieh, Tsung-Han S, Cattoglio, Claudia, Slobodyanyuk, Elena, Hansen, Anders S, Rando, Oliver J, Tjian, Robert, and Darzacq, Xavier

Subjects

Human Genome, Genetics, Bioengineering, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Animals, CCCTC-Binding Factor, Chromatin, Chromatin Assembly and Disassembly, DNA Polymerase II, Embryonic Stem Cells, Enhancer Elements, Genetic, Gene Expression Regulation, Genome Components, Mice, Promoter Regions, Genetic, Transcription Factors, Transcription, Genetic, 30 nm chromatin fiber, 3D genome, CTCF, Micro-C, Pol II, TAD, enhancer-promoter (E-P) interactions, loop extrusion, transcription, Biological Sciences, Medical and Health Sciences, Developmental Biology

Abstract

Whereas folding of genomes at the large scale of epigenomic compartments and topologically associating domains (TADs) is now relatively well understood, how chromatin is folded at finer scales remains largely unexplored in mammals. Here, we overcome some limitations of conventional 3C-based methods by using high-resolution Micro-C to probe links between 3D genome organization and transcriptional regulation in mouse stem cells. Combinatorial binding of transcription factors, cofactors, and chromatin modifiers spatially segregates TAD regions into various finer-scale structures with distinct regulatory features including stripes, dots, and domains linking promoters-to-promoters (P-P) or enhancers-to-promoters (E-P) and bundle contacts between Polycomb regions. E-P stripes extending from the edge of domains predominantly link co-expressed loci, often in the absence of CTCF and cohesin occupancy. Acute inhibition of transcription disrupts these gene-related folding features without altering higher-order chromatin structures. Our study uncovers previously obscured finer-scale genome organization, establishing functional links between chromatin folding and gene regulation.

Published

2020

5. Distinct Classes of Chromatin Loops Revealed by Deletion of an RNA-Binding Region in CTCF

Author

Hansen, Anders S, Hsieh, Tsung-Han S, Cattoglio, Claudia, Pustova, Iryna, Saldaña-Meyer, Ricardo, Reinberg, Danny, Darzacq, Xavier, and Tjian, Robert

Subjects

Genetics, 1.1 Normal biological development and functioning, Underpinning research, Animals, CCCTC-Binding Factor, Cell Line, Chromatin, Gene Expression Regulation, Developmental, Male, Mice, Mice, Transgenic, Mouse Embryonic Stem Cells, Mutation, Nucleic Acid Conformation, Protein Binding, Protein Interaction Domains and Motifs, Structure-Activity Relationship, CTCF, Micro-C, RNA, TAD, cohesin, genome organization, loop, loop extrusion, super-resolution imaging, Biological Sciences, Medical and Health Sciences, Developmental Biology

Abstract

Mammalian genomes are folded into topologically associating domains (TADs), consisting of chromatin loops anchored by CTCF and cohesin. Some loops are cell-type specific. Here we asked whether CTCF loops are established by a universal or locus-specific mechanism. Investigating the molecular determinants of CTCF clustering, we found that CTCF self-association in vitro is RNase sensitive and that an internal RNA-binding region (RBRi) mediates CTCF clustering and RNA interaction in vivo. Strikingly, deleting the RBRi impairs about half of all chromatin loops in mESCs and causes deregulation of gene expression. Disrupted loop formation correlates with diminished clustering and chromatin binding of RBRi mutant CTCF, which in turn results in a failure to halt cohesin-mediated extrusion. Thus, CTCF loops fall into at least two classes: RBRi-independent and RBRi-dependent loops. We speculate that evidence for RBRi-dependent loops may provide a molecular mechanism for establishing cell-specific CTCF loops, potentially regulated by RNA(s) or other RBRi-interacting partners.

Published

2019

6. Determining cellular CTCF and cohesin abundances to constrain 3D genome models.

Author

Cattoglio, Claudia, Pustova, Iryna, Walther, Nike, Ho, Jaclyn J, Hantsche-Grininger, Merle, Inouye, Carla J, Hossain, M Julius, Dailey, Gina M, Ellenberg, Jan, Darzacq, Xavier, Tjian, Robert, and Hansen, Anders S

Subjects

Chromatin, Animals, Humans, Cell Cycle Proteins, Chromosomal Proteins, Non-Histone, CCCTC-Binding Factor, CTCF, Rad21, TAD, biochemistry, chemical biology, chromosomes, cohesin, gene expression, genome organization, human, loop extrusion, mouse, Chromosomal Proteins, Non-Histone, Biochemistry and Cell Biology

Abstract

Achieving a quantitative and predictive understanding of 3D genome architecture remains a major challenge, as it requires quantitative measurements of the key proteins involved. Here, we report the quantification of CTCF and cohesin, two causal regulators of topologically associating domains (TADs) in mammalian cells. Extending our previous imaging studies (Hansen et al., 2017), we estimate bounds on the density of putatively DNA loop-extruding cohesin complexes and CTCF binding site occupancy. Furthermore, co-immunoprecipitation studies of an endogenously tagged subunit (Rad21) suggest the presence of cohesin dimers and/or oligomers. Finally, based on our cell lines with accurately measured protein abundances, we report a method to conveniently determine the number of molecules of any Halo-tagged protein in the cell. We anticipate that our results and the established tool for measuring cellular protein abundances will advance a more quantitative understanding of 3D genome organization, and facilitate protein quantification, key to comprehend diverse biological processes.

Published

2019

7. Recent evidence that TADs and chromatin loops are dynamic structures

Author

Hansen, Anders S, Cattoglio, Claudia, Darzacq, Xavier, and Tjian, Robert

Subjects

Genetics, Generic health relevance, Animals, Chromatin, Chromatin Assembly and Disassembly, Humans, Models, Molecular, CTCF, cohesin, 3D genome, single-molecule imaging, dynamics, FRAP, topological domains, chromatin loops, loop extrusion, modeling

Abstract

Mammalian genomes are folded into spatial domains, which regulate gene expression by modulating enhancer-promoter contacts. Here, we review recent studies on the structure and function of Topologically Associating Domains (TADs) and chromatin loops. We discuss how loop extrusion models can explain TAD formation and evidence that TADs are formed by the ring-shaped protein complex, cohesin, and that TAD boundaries are established by the DNA-binding protein, CTCF. We discuss our recent genomic, biochemical and single-molecule imaging studies on CTCF and cohesin, which suggest that TADs and chromatin loops are dynamic structures. We highlight complementary polymer simulation studies and Hi-C studies employing acute depletion of CTCF and cohesin, which also support such a dynamic model. We discuss the limitations of each approach and conclude that in aggregate the available evidence argues against stable loops and supports a model where TADs are dynamic structures that continually form and break throughout the cell cycle.

Published

2018

8. Non-coding Transcription Instructs Chromatin Folding and Compartmentalization to Dictate Enhancer-Promoter Communication and T Cell Fate

Author

Isoda, Takeshi, Moore, Amanda J, He, Zhaoren, Chandra, Vivek, Aida, Masatoshi, Denholtz, Matthew, van Hamburg, Jan Piet, Fisch, Kathleen M, Chang, Aaron N, Fahl, Shawn P, Wiest, David L, and Murre, Cornelis

Subjects

Genetics, Animals, CCCTC-Binding Factor, Chromatin, Enhancer Elements, Genetic, Leukemia, Locus Control Region, Lymphoma, Mice, Nuclear Lamina, Promoter Regions, Genetic, RNA, Untranslated, Repressor Proteins, T-Lymphocytes, Thymus Gland, Transcription, Genetic, Tumor Suppressor Proteins, CTCF, Non-coding transcription, T cell development, cohesin, compartmentalization, leukemia, loop extrusion, lymphoma, phase separation, single-loop domain, Biological Sciences, Medical and Health Sciences, Developmental Biology

Abstract

It is now established that Bcl11b specifies T cell fate. Here, we show that in developing T cells, the Bcl11b enhancer repositioned from the lamina to the nuclear interior. Our search for factors that relocalized the Bcl11b enhancer identified a non-coding RNA named ThymoD (thymocyte differentiation factor). ThymoD-deficient mice displayed a block at the onset of T cell development and developed lymphoid malignancies. We found that ThymoD transcription promoted demethylation at CTCF bound sites and activated cohesin-dependent looping to reposition the Bcl11b enhancer from the lamina to the nuclear interior and to juxtapose the Bcl11b enhancer and promoter into a single-loop domain. These large-scale changes in nuclear architecture were associated with the deposition of activating epigenetic marks across the loop domain, plausibly facilitating phase separation. These data indicate how, during developmental progression and tumor suppression, non-coding transcription orchestrates chromatin folding and compartmentalization to direct with high precision enhancer-promoter communication.

Published

2017

9. Multi-scale phase separation by explosive percolation with single-chromatin loop resolution

Author

Kaustav Sengupta, Michał Denkiewicz, Mateusz Chiliński, Teresa Szczepińska, Ayatullah Faruk Mollah, Sevastianos Korsak, Raissa D'Souza, Yijun Ruan, and Dariusz Plewczynski

Subjects

Scalar parameter, Numerical and Computational Mathematics, 1.1 Normal biological development and functioning, Compartmentalisation, Human Genome, Biophysics, Phase separation, Chromatin folding, Percolation, Bioengineering, Computation Theory and Mathematics, Biochemistry, Loop extrusion, Computer Science Applications, Structural Biology, Underpinning research, Genetics, 3D genomics, Networks, Biotechnology

Abstract

The 2m-long human DNA is tightly intertwined into the cell nucleus of the size of 10μm. The DNA packing is explained by folding of chromatin fiber. This folding leads to the formation of such hierarchical structures as: chromosomal territories, compartments; densely-packed genomic regions known as Topologically Associating Domains (TADs), or Chromatin Contact Domains (CCDs), and loops. We propose models of dynamical human genome folding into hierarchical components in human lymphoblastoid, stem cell, and fibroblast cell lines. Our models are based on explosive percolation theory. The chromosomes are modeled as graphs where CTCF chromatin loops are represented as edges. The folding trajectory is simulated by gradually introducing loops to the graph following various edge addition strategies that are based on topological network properties, chromatin loop frequencies, compartmentalization, or epigenomic features. Finally, we propose the genome folding model - a biophysical pseudo-time process guided by a single scalar order parameter. The parameter is calculated by Linear Discriminant Analysis of chromatin features. We also include dynamics of loop formation by using Loop Extrusion Model (LEM) while adding them to the system. The chromatin phase separation, where fiber folds in 3D space into topological domains and compartments, is observed when the critical number of contacts is reached. We also observe that at least 80% of the loops are needed for chromatin fiber to condense in 3D space, and this is constant through various cell lines. Overall, our in-silico model integrates the high-throughput 3D genome interaction experimental data with the novel theoretical concept of phase separation, which allows us to model event-based time dynamics of chromatin loop formation and folding trajectories.

Published

2022

10. Spatial Organization of Chromatin: Emergence of Chromatin Structure During Development

Author

Barbara J Meyer and Rajarshi P. Ghosh

Subjects

1.1 Normal biological development and functioning, Biology, Genome, Medical and Health Sciences, DNA sequencing, Article, Chromosomes, Fluorescence, gametogenesis, neural development, Underpinning research, Genetics, Spatial organization, In Situ Hybridization, Fluorescence, In Situ Hybridization, Genomic organization, zygotic genome activation, loop extrusion, Human Genome, Cell Biology, DNA, Biological Sciences, cohesin and condensin complexes, Chromatin, Histone, Evolutionary biology, biology.protein, Maternal to zygotic transition, chromosome topology, Generic health relevance, phase separation, Developmental biology, Biotechnology, Developmental Biology

Abstract

Nuclei are central hubs for information processing in eukaryotic cells. The need to fit large genomes into small nuclei imposes severe restrictions on genome organization and the mechanisms that drive genome-wide regulatory processes. How a disordered polymer such as chromatin, which has vast heterogeneity in its DNA and histone modification profiles, folds into discernibly consistent patterns is a fundamental question in biology. Outstanding questions include how genomes are spatially and temporally organized to regulate cellular processes with high precision and whether genome organization is causally linked to transcription regulation. The advent of next-generation sequencing, super-resolution imaging, multiplexed fluorescent in situ hybridization, and single-molecule imaging in individual living cells has caused a resurgence in efforts to understand the spatiotemporal organization of the genome. In this review, we discuss structural and mechanistic properties of genome organization at different length scales and examine changes in higher-order chromatin organization during important developmental transitions. Expected final online publication date for the Annual Review of Cell and Developmental Biology, Volume 37 is October 2021. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.

Published

2021

11. Recent evidence that TADs and chromatin loops are dynamic structures.

Author

Hansen, Anders, Hansen, Anders, Cattoglio, Claudia, Darzacq, Xavier, Tjian, Robert, Hansen, Anders, Hansen, Anders, Cattoglio, Claudia, Darzacq, Xavier, and Tjian, Robert

Abstract

Mammalian genomes are folded into spatial domains, which regulate gene expression by modulating enhancer-promoter contacts. Here, we review recent studies on the structure and function of Topologically Associating Domains (TADs) and chromatin loops. We discuss how loop extrusion models can explain TAD formation and evidence that TADs are formed by the ring-shaped protein complex, cohesin, and that TAD boundaries are established by the DNA-binding protein, CTCF. We discuss our recent genomic, biochemical and single-molecule imaging studies on CTCF and cohesin, which suggest that TADs and chromatin loops are dynamic structures. We highlight complementary polymer simulation studies and Hi-C studies employing acute depletion of CTCF and cohesin, which also support such a dynamic model. We discuss the limitations of each approach and conclude that in aggregate the available evidence argues against stable loops and supports a model where TADs are dynamic structures that continually form and break throughout the cell cycle.

Published

2018

12. Recent evidence that TADs and chromatin loops are dynamic structures

Author

Xavier Darzacq, Anders S. Hansen, Claudia Cattoglio, and Robert Tjian

Subjects

0301 basic medicine, Models, Molecular, single-molecule imaging, cohesin, Computational biology, 03 medical and health sciences, Models, Genetics, Animals, Humans, Physics, loop extrusion, Cohesin, Molecular, modeling, Cell Biology, dynamics, Chromatin Assembly and Disassembly, CTCF, chromatin loops, Chromatin, 3D genome, Structure and function, topological domains, 030104 developmental biology, FRAP, Generic health relevance

Abstract

Mammalian genomes are folded into spatial domains, which regulate gene expression by modulating enhancer-promoter contacts. Here, we review recent studies on the structure and function of Topologically Associating Domains (TADs) and chromatin loops. We discuss how loop extrusion models can explain TAD formation and evidence that TADs are formed by the ring-shaped protein complex, cohesin, and that TAD boundaries are established by the DNA-binding protein, CTCF. We discuss our recent genomic, biochemical and single-molecule imaging studies on CTCF and cohesin, which suggest that TADs and chromatin loops are dynamic structures. We highlight complementary polymer simulation studies and Hi-C studies employing acute depletion of CTCF and cohesin, which also support such a dynamic model. We discuss the limitations of each approach and conclude that in aggregate the available evidence argues against stable loops and supports a model where TADs are dynamic structures that continually form and break throughout the cell cycle.

Published

2018