Your search keyword '"CTCF"' showing total 142 results

1. Combined CRISPRi and proteomics screening reveal a cohesin-CTCF-bound allele contributing to increased expression of RUVBL1 and prostate cancer progression.

Author

Tian, Yijun, Dong, Dandan, Wang, Zixian, Wu, Lang, Park, Jong Y., Wei, Gong-Hong, and Wang, Liang

Subjects

*LOCUS (Genetics), *CRISPRS, *MEDICAL screening, *ALLELES, *ANDROGEN receptors, *GENOME editing, *PROTEOMICS

Abstract

Genome-wide association studies along with expression quantitative trait locus (eQTL) mapping have identified hundreds of single-nucleotide polymorphisms (SNPs) and their target genes in prostate cancer (PCa), yet functional characterization of these risk loci remains challenging. To screen for potential regulatory SNPs, we designed a CRISPRi library containing 9,133 guide RNAs (gRNAs) to cover 2,166 candidate SNP loci implicated in PCa and identified 117 SNPs that could regulate 90 genes for PCa cell growth advantage. Among these, rs60464856 was covered by multiple gRNAs significantly depleted in screening (FDR < 0.05). Pooled SNP association analysis in the PRACTICAL and FinnGen cohorts showed significantly higher PCa risk for the rs60464856 G allele (p value = 1.2 × 10−16 and 3.2 × 10−7, respectively). Subsequent eQTL analysis revealed that the G allele is associated with increased RUVBL1 expression in multiple datasets. Further CRISPRi and xCas9 base editing confirmed that the rs60464856 G allele leads to elevated RUVBL1 expression. Furthermore, SILAC-based proteomic analysis demonstrated allelic binding of cohesin subunits at the rs60464856 region, where the HiC dataset showed consistent chromatin interactions in prostate cell lines. RUVBL1 depletion inhibited PCa cell proliferation and tumor growth in a xenograft mouse model. Gene-set enrichment analysis suggested an association of RUVBL1 expression with cell-cycle-related pathways. Increased expression of RUVBL1 and activation of cell-cycle pathways were correlated with poor PCa survival in TCGA datasets. Our CRISPRi screening prioritized about one hundred regulatory SNPs essential for prostate cell proliferation. In combination with proteomics and functional studies, we characterized the mechanistic role of rs60464856 and RUVBL1 in PCa progression. [Display omitted] A major goal of post-GWAS studies is to functionally characterize causal SNPs that confer increased risk to disease phenotypes. Here, we applied CRISPRi and proteomics screening to identify regulatory SNPs at prostate-cancer risk loci and functionally characterized the impact of the rs60464856- RUVBL1 locus via in vitro and in vivo approaches. [ABSTRACT FROM AUTHOR]

Published

2023

2. Members of an array of zinc-finger proteins specify distinct Hox chromatin boundaries.

Author

Ortabozkoyun, Havva, Huang, Pin-Yao, Gonzalez-Buendia, Edgar, Cho, Hyein, Kim, Sang Y., Tsirigos, Aristotelis, Mazzoni, Esteban O., and Reinberg, Danny

Subjects

*ZINC-finger proteins, *HOMEOBOX genes, *GENE expression, *MOTOR neurons, *GENETIC regulation

Abstract

Partitioning of repressive from actively transcribed chromatin in mammalian cells fosters cell-type-specific gene expression patterns. While this partitioning is reconstructed during differentiation, the chromatin occupancy of the key insulator, CCCTC-binding factor (CTCF), is unchanged at the developmentally important Hox clusters. Thus, dynamic changes in chromatin boundaries must entail other activities. Given its requirement for chromatin loop formation, we examined cohesin-based chromatin occupancy without known insulators, CTCF and Myc-associated zinc-finger protein (MAZ), and identified a family of zinc-finger proteins (ZNFs), some of which exhibit tissue-specific expression. Two such ZNFs foster chromatin boundaries at the Hox clusters that are distinct from each other and from MAZ. PATZ1 was critical to the thoracolumbar boundary in differentiating motor neurons and mouse skeleton, while ZNF263 contributed to cervicothoracic boundaries. We propose that these insulating activities act with cohesin, alone or combinatorially, with or without CTCF, to implement precise positional identity and cell fate during development. [Display omitted] • ZNFs function at chromatin boundaries to determine cellular identities • PATZ1 and ZNF263 regulate distinct Hox gene borders in motor neurons • Loss of PATZ1 results in reduction of looping interactions • PATZ1 loss in mice leads to homeotic transformations in skeletal patterning How insulation regulates genome organization and cellular fate remains unresolved. Ortabozkoyun et al. identify a family of zinc-finger proteins (ZNFs), including PATZ1 and ZNF263, which regulate Hox gene borders in motor neurons. Importantly, loss of PATZ1 impacts genome organization in cells and skeletal patterning in mice, highlighting insulation activities. [ABSTRACT FROM AUTHOR]

Published

2024

3. Multiple allelic configurations govern long-range Shh enhancer-promoter communication in the embryonic forebrain.

Author

Harke J, Lee JR, Nguyen SC, Arab A, Rakowiecki SM, Hugelier S, Paliou C, Rauseo A, Yunker R, Xu K, Yao Y, Lakadamyali M, Andrey G, Epstein DJ, and Joyce EF

Abstract

Developmental gene regulation requires input from enhancers spread over large genomic distances. Our understanding of long-range enhancer-promoter (E-P) communication, characterized as loops, remains incomplete without addressing the role of intervening chromatin. Here, we examine the topology of the entire Sonic hedgehog (Shh) regulatory domain in individual alleles from the mouse embryonic forebrain. Through sequential Oligopaint labeling and super-resolution microscopy, we find that the Shh locus maintains a compact structure that adopts several diverse configurations independent of Shh expression. The most frequent configuration contained distal E-P contacts at the expense of those more proximal to Shh, consistent with an interconnected loop. Genetic perturbations demonstrate that this long-range E-P communication operates by Shh-expression-independent and dependent mechanisms, involving CTCF binding sites and active enhancers, respectively. We propose a model whereby gene regulatory elements secure long-range E-P interactions amid an inherent architectural framework to coordinate spatiotemporal patterns of gene expression., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

4. Systematic screening of enhancer-blocking insulators in Drosophila identifies their DNA sequence determinants.

Author

Tonelli A, Cousin P, Jankowski A, Wang B, Dorier J, Barraud J, Zunjarrao S, and Gambetta MC

Abstract

Long-range transcriptional activation of gene promoters by abundant enhancers in animal genomes calls for mechanisms to limit inappropriate regulation. DNA elements called insulators serve this purpose by shielding promoters from an enhancer when interposed. Unlike promoters and enhancers, insulators have not been systematically characterized due to lacking high-throughput screening assays, and questions regarding how insulators are distributed and encoded in the genome remain. Here, we establish "insulator-seq" as a plasmid-based massively parallel reporter assay in Drosophila cultured cells to perform a systematic insulator screen of selected genomic loci. Screening developmental gene loci showed that not all insulator protein binding sites effectively block enhancer-promoter communication. Deep insulator mutagenesis identified sequences flexibly positioned around the CTCF insulator protein binding motif that are critical for functionality. The ability to screen millions of DNA sequences without positional effect has enabled functional mapping of insulators and provided further insights into the determinants of insulators., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

5. SRF promotes long-range chromatin loop formation and stem cell pluripotency.

Author

Tsaytler P, Blaess G, Scholze-Wittler M, Meierhofer D, Wittler L, Koch F, and Herrmann BG

Subjects

Animals, Mice, CCCTC-Binding Factor metabolism, Humans, Pluripotent Stem Cells metabolism, Pluripotent Stem Cells cytology, Chromosomal Proteins, Non-Histone metabolism, Cell Cycle Proteins metabolism, Cell Cycle Proteins genetics, Cohesins, Cell Differentiation, Protein Binding, Embryonic Stem Cells metabolism, Embryonic Stem Cells cytology, Serum Response Factor metabolism, Chromatin metabolism, Nanog Homeobox Protein metabolism, Nanog Homeobox Protein genetics, SOXB1 Transcription Factors metabolism, SOXB1 Transcription Factors genetics

Abstract

Serum response factor (SRF) is a transcription factor essential for cell proliferation, differentiation, and migration and is required for primitive streak and mesoderm formation in the embryo. The canonical roles of SRF are mediated by a diverse set of context-dependent cofactors. Here, we show that SRF physically interacts with CTCF and cohesin subunits at topologically associating domain (TAD) boundaries and loop anchors. SRF promotes long-range chromatin loop formation and contributes to TAD insulation. In embryonic stem cells (ESCs), SRF associates with SOX2 and NANOG and contributes to the formation of three-dimensional (3D) pluripotency hubs. Our findings reveal additional roles of SRF in higher-order chromatin organization., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2024

6. A walk through the SMC cycle: From catching DNAs to shaping the genome.

Author

Oldenkamp, Roel and Rowland, Benjamin D.

Subjects

*DNA structure, *CHROMOSOME structure, *DNA, *CONDENSIN, *CHROMATIDS

Abstract

SMC protein complexes are molecular machines that provide structure to chromosomes. These complexes bridge DNA elements and by doing so build DNA loops in cis and hold together the sister chromatids in trans. We discuss how drastic conformational changes allow SMC complexes to build such intricate DNA structures. The tight regulation of these complexes controls fundamental chromosomal processes such as transcription, recombination, repair, and mitosis. SMC complexes such as cohesin and condensin shape the DNA of all life on earth. Oldenkamp et al. consider general principles across SMC protein complexes. A chain of conformational states enables this family of molecular machines to structure DNAs and control fundamental chromosomal processes. [ABSTRACT FROM AUTHOR]

Published

2022

7. The activity of early-life gene regulatory elements is hijacked in aging through pervasive AP-1-linked chromatin opening.

Author

Patrick R, Naval-Sanchez M, Deshpande N, Huang Y, Zhang J, Chen X, Yang Y, Tiwari K, Esmaeili M, Tran M, Mohamed AR, Wang B, Xia D, Ma J, Bayliss J, Wong K, Hun ML, Sun X, Cao B, Cottle DL, Catterall T, Barzilai-Tutsch H, Troskie RL, Chen Z, Wise AF, Saini S, Soe YM, Kumari S, Sweet MJ, Thomas HE, Smyth IM, Fletcher AL, Knoblich K, Watt MJ, Alhomrani M, Alsanie W, Quinn KM, Merson TD, Chidgey AP, Ricardo SD, Yu D, Jardé T, Cheetham SW, Marcelle C, Nilsson SK, Nguyen Q, White MD, and Nefzger CM

Subjects

Animals, Mice, Humans, Mice, Inbred C57BL, Binding Sites, Aging genetics, Aging metabolism, Transcription Factor AP-1 metabolism, Chromatin metabolism

Abstract

A mechanistic connection between aging and development is largely unexplored. Through profiling age-related chromatin and transcriptional changes across 22 murine cell types, analyzed alongside previous mouse and human organismal maturation datasets, we uncovered a transcription factor binding site (TFBS) signature common to both processes. Early-life candidate cis-regulatory elements (cCREs), progressively losing accessibility during maturation and aging, are enriched for cell-type identity TFBSs. Conversely, cCREs gaining accessibility throughout life have a lower abundance of cell identity TFBSs but elevated activator protein 1 (AP-1) levels. We implicate TF redistribution toward these AP-1 TFBS-rich cCREs, in synergy with mild downregulation of cell identity TFs, as driving early-life cCRE accessibility loss and altering developmental and metabolic gene expression. Such remodeling can be triggered by elevating AP-1 or depleting repressive H3K27me3. We propose that AP-1-linked chromatin opening drives organismal maturation by disrupting cell identity TFBS-rich cCREs, thereby reprogramming transcriptome and cell function, a mechanism hijacked in aging through ongoing chromatin opening., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

8. Hypoxia-induced CTCF promotes EMT in breast cancer.

Author

Kakani P, Dhamdhere SG, Pant D, Joshi R, Mishra J, Samaiya A, and Shukla S

Subjects

Humans, Female, Cell Line, Tumor, Gene Expression Regulation, Neoplastic, Dioxygenases, Epigenesis, Genetic, DNA-Binding Proteins metabolism, DNA-Binding Proteins genetics, DNA Methyltransferase 3A metabolism, DNA (Cytosine-5-)-Methyltransferases metabolism, DNA (Cytosine-5-)-Methyltransferases genetics, Proto-Oncogene Proteins metabolism, Proto-Oncogene Proteins genetics, CCCTC-Binding Factor metabolism, Epithelial-Mesenchymal Transition genetics, Breast Neoplasms pathology, Breast Neoplasms genetics, Breast Neoplasms metabolism, Hypoxia-Inducible Factor 1, alpha Subunit metabolism, Hypoxia-Inducible Factor 1, alpha Subunit genetics, Promoter Regions, Genetic genetics, DNA Methylation genetics, Cell Hypoxia

Abstract

Cancer cells experiencing hypoxic stress employ epithelial-mesenchymal transition (EMT) to undergo metastasis through rewiring of the chromatin landscape, epigenetics, and importantly, gene expression. Here, we showed that hypoxia modulates the epigenetic landscape on CTCF promoter and upregulates its expression. Hypoxia-driven epigenetic regulation, specifically DNA demethylation mediated by TET2, is a prerequisite for CTCF induction. Mechanistically, in hypoxic conditions, Hypoxia-inducible factor 1-alpha (HIF1α) binds to the unmethylated CTCF promoter, causing transcriptional upregulation. Further, we uncover the pivotal role of CTCF in promoting EMT as loss of CTCF abrogated invasiveness of hypoxic breast cancer cells. These findings highlight the functional contribution of HIF1α-CTCF axis in promoting EMT in hypoxic breast cancer cells. Lastly, CTCF expression is alleviated and the potential for EMT is diminished when the HIF1α binding is particularly disrupted through the dCas9-DNMT3A system-mediated maintenance of DNA methylation on the CTCF promoter. This axis may offer a unique therapeutic target in breast cancer., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2024

9. A self-complementary AAV proviral plasmid that reduces cross-packaging and ITR promoter activity in AAV vector preparations.

Author

Taylor NK, Guggenbiller MJ, Mistry PP, King OD, and Harper SQ

Abstract

Adeno-associated viral vectors (AAVs) are a leading delivery system for gene therapy in animal models and humans. With several Food and Drug Administration-approved AAV gene therapies on the market, issues related to vector manufacturing have become increasingly important. In this study, we focused on potentially toxic DNA contaminants that can arise from AAV proviral plasmids, the raw materials required for manufacturing recombinant AAV in eukaryotic cells. Typical AAV proviral plasmids are circular DNAs containing a therapeutic gene cassette flanked by natural AAV inverted terminal repeat (ITR) sequences, and a plasmid backbone carrying prokaryotic sequences required for plasmid replication and selection in bacteria. While the majority of AAV particles package the intended therapeutic payload, some capsids instead package the bacterial sequences located on the proviral plasmid backbone. Since ITR sequences also have promoter activity, potentially toxic bacterial open reading frames can be produced in vivo , thereby representing a safety risk. In this study, we describe a new AAV proviral plasmid for vector manufacturing that (1) significantly decreases cross-packaged bacterial sequences, (2) increases correctly packaged AAV payloads, and (3) blunts ITR-driven transcription of cross-packaged material to avoid expressing potentially toxic bacterial sequences. This system may help improve the safety of AAV vector products., Competing Interests: S.Q.H. is the co-founder and Chief Scientific Advisor for Armatus Bio. S.Q.H. currently serves as a Scientific Advisory Board Member of the Charcot-Marie-Tooth Association. The C1 through C5 proviral plasmid sequence technologies are listed under New International Patent Application No. PCT/US24/27396., (© 2024 The Author(s).)

Published

2024

10. A CTCF-binding site in the Mdm1-Il22-Ifng locus shapes cytokine expression profiles and plays a critical role in early Th1 cell fate specification.

Author

Liu, Chunhong, Nagashima, Hiroyuki, Fernando, Nilisha, Bass, Victor, Gopalakrishnan, Jaanam, Signorella, Sadie, Montgomery, Will, Lim, Ai Ing, Harrison, Oliver, Reich, Lauren, Yao, Chen, Sun, Hong-Wei, Brooks, Stephen R., Jiang, Kan, Nagarajan, Vijayaraj, Zhao, Yongbing, Jung, Seolkyoung, Phillips, Rachael, Mikami, Yohei, and Lareau, Caleb A.

Subjects

*CELL differentiation, *GENE expression, *TH1 cells, *KILLER cells, *T cell differentiation

Abstract

Cytokine expression during T cell differentiation is a highly regulated process that involves long-range promoter-enhancer and CTCF-CTCF contacts at cytokine loci. Here, we investigated the impact of dynamic chromatin loop formation within the topologically associating domain (TAD) in regulating the expression of interferon gamma (IFN-γ) and interleukin-22 (IL-22); these cytokine loci are closely located in the genome and are associated with complex enhancer landscapes, which are selectively active in type 1 and type 3 lymphocytes. In situ Hi-C analyses revealed inducible TADs that insulated Ifng and Il22 enhancers during Th1 cell differentiation. Targeted deletion of a 17 bp boundary motif of these TADs imbalanced Th1- and Th17-associated immunity, both in vitro and in vivo , upon Toxoplasma gondii infection. In contrast, this boundary element was dispensable for cytokine regulation in natural killer cells. Our findings suggest that precise cytokine regulation relies on lineage- and developmental stage-specific interactions of 3D chromatin architectures and enhancer landscapes. [Display omitted] • Profiling 3D genome architecture reveals a boundary between Il22 and Ifng enhancers • Deletion of a 17 bp CTCF-binding motif dysregulates Il22 and Ifng expression in Th1 cells • The mutation does not impair Ifng production in NK cells • The mutant mice are susceptible to Toxoplasma gondii infection Multilayered gene regulation orchestrates cell-type-specific cytokine expression. Liu et al. examine the impact of chromatin loop formation on the expression of IFN-γ and IL-22, which are cytokine loci closely located in the genome, and identify an inducible topologically associating domain required for proper IFN-γ production in Th1 cells. Deleting a CTCF-binding site within this domain leads to lineage-specific cytokine dysregulation and increased susceptibility to pathogens. [ABSTRACT FROM AUTHOR]

Published

2024

11. ZNF143 deletion alters enhancer/promoter looping and CTCF/cohesin geometry.

Author

Zhang M, Huang H, Li J, and Wu Q

Subjects

CCCTC-Binding Factor metabolism, Chromatin, Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, Binding Sites, Cohesins, Chromosomal Proteins, Non-Histone metabolism

Abstract

The transcription factor ZNF143 contains a central domain of seven zinc fingers in a tandem array and is involved in 3D genome construction. However, the mechanism by which ZNF143 functions in chromatin looping remains unclear. Here, we show that ZNF143 directionally recognizes a diverse range of genomic sites directly within enhancers and promoters and is required for chromatin looping between these sites. In addition, ZNF143 is located between CTCF and cohesin at numerous CTCF sites, and ZNF143 removal narrows the space between CTCF and cohesin. Moreover, genetic deletion of ZNF143, in conjunction with acute CTCF degradation, reveals that ZNF143 and CTCF collaborate to regulate higher-order topological chromatin organization. Finally, CTCF depletion enlarges direct ZNF143 chromatin looping. Thus, ZNF143 is recruited by CTCF to the CTCF sites to regulate CTCF/cohesin configuration and TAD (topologically associating domain) formation, whereas directional recognition of genomic DNA motifs directly by ZNF143 itself regulates promoter activity via chromatin looping., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2024

12. Epigenetic balance ensures mechanistic control of MLL amplification and rearrangement.

Author

Gray, Zach H., Chakraborty, Damayanti, Duttweiler, Reuben R., Alekbaeva, Gulnaz D., Murphy, Sedona E., Chetal, Kashish, Ji, Fei, Ferman, Benjamin I., Honer, Madison A., Wang, Zhentian, Myers, Cynthia, Sun, Renhong, Kaniskan, H. Ümit, Toma, Monika Maria, Bondarenko, Elena A., Santoro, John N., Miranda, Christopher, Dillingham, Megan E., Tang, Ran, and Gozani, Or

Subjects

*DOXORUBICIN, *EPIGENETICS, *DRUG target, *DEMETHYLASE, *GENE amplification, *LYSINE

Abstract

MLL/KMT2A amplifications and translocations are prevalent in infant, adult, and therapy-induced leukemia. However, the molecular contributor(s) to these alterations are unclear. Here, we demonstrate that histone H3 lysine 9 mono- and di-methylation (H3K9me1/2) balance at the MLL/KMT2A locus regulates these amplifications and rearrangements. This balance is controlled by the crosstalk between lysine demethylase KDM3B and methyltransferase G9a/EHMT2. KDM3B depletion increases H3K9me1/2 levels and reduces CTCF occupancy at the MLL/KMT2A locus, in turn promoting amplification and rearrangements. Depleting CTCF is also sufficient to generate these focal alterations. Furthermore, the chemotherapy doxorubicin (Dox), which associates with therapy-induced leukemia and promotes MLL/KMT2A amplifications and rearrangements, suppresses KDM3B and CTCF protein levels. KDM3B and CTCF overexpression rescues Dox-induced MLL/KMT2A alterations. G9a inhibition in human cells or mice also suppresses MLL/KMT2A events accompanying Dox treatment. Therefore, MLL/KMT2A amplifications and rearrangements are controlled by epigenetic regulators that are tractable drug targets, which has clinical implications. [Display omitted] • KDM3B and G9a regulate MLL/KMT2A copy gains and rearrangements through H3K9me1/2 • CTCF depletion and reduced binding associate with KMT2A copy gains and break aparts • Doxorubicin reduces KDM3B and CTCF levels, promoting MLL/KMT2A alterations • G9a inhibition suppresses Dox-induced MLL/KMT2A alterations in mice and human cells An imbalance in histone modifications contributes to both transient amplifications and integrated rearrangements and amplifications observed in leukemia, which can be induced by a commonly used chemotherapy but prevented by chemical intervention. [ABSTRACT FROM AUTHOR]

Published

2023

13. Cohesin mediates DNA loop extrusion and sister chromatid cohesion by distinct mechanisms.

Author

Nagasaka, Kota, Davidson, Iain F., Stocsits, Roman R., Tang, Wen, Wutz, Gordana, Batty, Paul, Panarotto, Melanie, Litos, Gabriele, Schleiffer, Alexander, Gerlich, Daniel W., and Peters, Jan-Michael

Subjects

*COHESINS, *COHESION, *LETHAL mutations, *GENETIC mutation, *CHROMATIN

Abstract

Cohesin connects CTCF-binding sites and other genomic loci in cis to form chromatin loops and replicated DNA molecules in trans to mediate sister chromatid cohesion. Whether cohesin uses distinct or related mechanisms to perform these functions is unknown. Here, we describe a cohesin hinge mutant that can extrude DNA into loops but is unable to mediate cohesion in human cells. Our results suggest that the latter defect arises during cohesion establishment. The observation that cohesin's cohesion and loop extrusion activities can be partially separated indicates that cohesin uses distinct mechanisms to perform these two functions. Unexpectedly, the same hinge mutant can also not be stopped by CTCF boundaries as well as wild-type cohesin. This suggests that cohesion establishment and cohesin's interaction with CTCF boundaries depend on related mechanisms and raises the possibility that both require transient hinge opening to entrap DNA inside the cohesin ring. • A method for analyzing lethal gene mutations in human cells • Identification of a cohesin mutant that is defective in cohesion but not in DNA looping • Cohesin's hinge domain is required for cohesion and cohesin's response to CTCF Nagasaka et al. discover that cohesin's sister chromatid cohesion and DNA loop extrusion functions can be partially separated. Their observations support the notion that cohesion establishment and the accumulation of cohesin at CTCF boundaries both depend on entrapment of DNA inside the cohesin ring via opening of cohesin's hinge domain. [ABSTRACT FROM AUTHOR]

Published

2023

14. G-quadruplexes associated with R-loops promote CTCF binding.

Author

Wulfridge, Phillip, Yan, Qingqing, Rell, Nathaniel, Doherty, John, Jacobson, Skye, Offley, Sarah, Deliard, Sandra, Feng, Kelly, Phillips-Cremins, Jennifer E., Gardini, Alessandro, and Sarma, Kavitha

Subjects

*NUCLEOTIDE sequence, *GENE expression, *EMBRYONIC stem cells, *QUADRUPLEX nucleic acids, *DNA sequencing, *GENOMES

Abstract

CTCF is a critical regulator of genome architecture and gene expression that binds thousands of sites on chromatin. CTCF genomic localization is controlled by the recognition of a DNA sequence motif and regulated by DNA modifications. However, CTCF does not bind to all its potential sites in all cell types, raising the question of whether the underlying chromatin structure can regulate CTCF occupancy. Here, we report that R-loops facilitate CTCF binding through the formation of associated G-quadruplex (G4) structures. R-loops and G4s co-localize with CTCF at many genomic regions in mouse embryonic stem cells and promote CTCF binding to its cognate DNA motif in vitro. R-loop attenuation reduces CTCF binding in vivo. Deletion of a specific G4-forming motif in a gene reduces CTCF binding and alters gene expression. Conversely, chemical stabilization of G4s results in CTCF gains and accompanying alterations in chromatin organization, suggesting a pivotal role for G4 structures in reinforcing long-range genome interactions through CTCF. [Display omitted] • CTCF-bound regions are enriched for R-loops and G-quadruplexes • G4s proximal to CTCF consensus motif strengthens CTCF interactions in vitro • G4 stabilization strengthens CTCF binding genome wide • Strengthened CTCF binding through G4s enhances chromatin looping CTCF is a highly conserved protein that is essential for genome organization. Although CTCF recognizes specific DNA sequences, it does not bind to all its potential sites. Wulfridge et al. report that CTCF-bound sites are enriched for R-loops and G-quadruplex chromatin structures. These structures facilitate CTCF binding to promote looping interactions, which contribute to proper gene expression. [ABSTRACT FROM AUTHOR]

Published

2023

15. CTCF coordinates cell fate specification via orchestrating regulatory hubs with pioneer transcription factors.

Author

Liu Y, Wan X, Li H, Chen Y, Hu X, Chen H, Zhu D, Li C, and Zhang Y

Subjects

Animals, Humans, Mice, Cell Differentiation, Chromatin, B-Lymphocytes metabolism, CCCTC-Binding Factor genetics, CCCTC-Binding Factor metabolism, Transcription Factors genetics, Transcription Factors metabolism

Abstract

CCCTC-binding factor (CTCF), a ubiquitously expressed architectural protein, has emerged as a key regulator of cell identity gene transcription. However, the precise molecular mechanism underlying specialized functions of CTCF remains elusive. Here, we investigate the mechanism through integrative analyses of primary hepatocytes, myocytes, and B cells from mouse and human. We demonstrate that CTCF cooperates with lineage-specific pioneer transcription factors (TFs), including MyoD, FOXA, and PU.1, to control cell identity at 1D and 3D levels. At the 1D level, pioneer TFs facilitate lineage-specific CTCF occupancy via opening chromatin. At the 3D level, CTCF and pioneer TFs form regulatory hubs to govern the expression of cell identity genes. This mechanism is validated using MyoD-null mice, CTCF knockout mice, and CRISPR editing during myogenic differentiation. Collectively, these findings uncover a general mechanism whereby CTCF acts as a cell identity cofactor to control cell identity genes via orchestrating regulatory hubs with pioneer TFs., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

16. CTCF and R-loops are boundaries of cohesin-mediated DNA looping.

Author

Zhang, Hongshan, Shi, Zhubing, Banigan, Edward J., Kim, Yoori, Yu, Hongtao, Bai, Xiao-chen, and Finkelstein, Ilya J.

Subjects

*ZINC-finger proteins, *DNA condensation, *COHESINS, *NUCLEOPROTEINS, *DNA, *BINDING sites

Abstract

Cohesin and CCCTC-binding factor (CTCF) are key regulatory proteins of three-dimensional (3D) genome organization. Cohesin extrudes DNA loops that are anchored by CTCF in a polar orientation. Here, we present direct evidence that CTCF binding polarity controls cohesin-mediated DNA looping. Using single-molecule imaging, we demonstrate that a critical N-terminal motif of CTCF blocks cohesin translocation and DNA looping. The cryo-EM structure of the cohesin-CTCF complex reveals that this CTCF motif ahead of zinc fingers can only reach its binding site on the STAG1 cohesin subunit when the N terminus of CTCF faces cohesin. Remarkably, a C-terminally oriented CTCF accelerates DNA compaction by cohesin. DNA-bound Cas9 and Cas12a ribonucleoproteins are also polar cohesin barriers, indicating that stalling may be intrinsic to cohesin itself. Finally, we show that RNA-DNA hybrids (R-loops) block cohesin-mediated DNA compaction in vitro and are enriched with cohesin subunits in vivo , likely forming TAD boundaries. [Display omitted] • CTCF is a polar barrier to cohesin-mediated DNA looping • A structure of the cohesin-NIPBL-CTCF-DNA complex reveals CTCF-cohesin interactions • R-loops slow cohesin translocation in vitro and are enriched with cohesin in vivo CTCF and cohesin organize the 3D eukaryotic genome. Zhang et al. report direct single-molecule and structure evidence that CTCF is a polar cohesin barrier. R-loops are also cohesin barriers and likely play a role in organizing the 3D genome. [ABSTRACT FROM AUTHOR]

Published

2023

17. A Dementia-Associated Risk Variant near TMEM106B Alters Chromatin Architecture and Gene Expression.

Author

Gallagher, Michael D., Posavi, Marijan, Huang, Peng, Unger, Travis L., Berlyand, Yosef, Gruenewald, Analise L., Chesi, Alessandra, Manduchi, Elisabetta, Wells, Andrew D., Grant, Struan F.A., Blobel, Gerd A., Brown, Christopher D., and Chen-Plotkin, Alice S.

Subjects

*DEMENTIA risk factors, *MEMBRANE proteins, *CHROMATIN, *GENE expression, *NEURODEGENERATION

Abstract

Neurodegenerative diseases pose an extraordinary threat to the world’s aging population, yet no disease-modifying therapies are available. Although genome-wide association studies (GWASs) have identified hundreds of risk loci for neurodegeneration, the mechanisms by which these loci influence disease risk are largely unknown. Here, we investigated the association between common genetic variants at the 7p21 locus and risk of the neurodegenerative disease frontotemporal lobar degeneration. We showed that variants associated with disease risk correlate with increased expression of the 7p21 gene TMEM106B and no other genes; co-localization analyses implicated a common causal variant underlying both association with disease and association with TMEM106B expression in lymphoblastoid cell lines and human brain. Furthermore, increases in the amount of TMEM106B resulted in increases in abnormal lysosomal phenotypes and cell toxicity in both immortalized cell lines and neurons. We then combined fine-mapping, bioinformatics, and bench-based approaches to functionally characterize all candidate causal variants at this locus. This approach identified a noncoding variant, rs1990620, that differentially recruits CTCF in lymphoblastoid cell lines and human brain to influence CTCF-mediated long-range chromatin-looping interactions between multiple cis -regulatory elements, including the TMEM106B promoter. Our findings thus provide an in-depth analysis of the 7p21 locus linked by GWASs to frontotemporal lobar degeneration, nominating a causal variant and causal mechanism for allele-specific expression and disease association at this locus. Finally, we show that genetic variants associated with risk of neurodegenerative diseases beyond frontotemporal lobar degeneration are enriched in CTCF-binding sites found in brain-relevant tissues, implicating CTCF-mediated gene regulation in risk of neurodegeneration more generally. [ABSTRACT FROM AUTHOR]

Published

2017

18. DNA architectural protein CTCF facilitates subset-specific chromatin interactions to limit the formation of memory CD8+ T cells.

Author

Quon, Sara, Yu, Bingfei, Russ, Brendan E., Tsyganov, Kirill, Nguyen, Hongtuyet, Toma, Clara, Heeg, Maximilian, Hocker, James D., Milner, J. Justin, Crotty, Shane, Pipkin, Matthew E., Turner, Stephen J., and Goldrath, Ananda W.

Subjects

*IMMUNOLOGIC memory, *T cell differentiation, *CHROMATIN, *DNA, *CELLULAR control mechanisms, *TRANSCRIPTION factors

Abstract

Although the importance of genome organization for transcriptional regulation of cell-fate decisions and function is clear, the changes in chromatin architecture and how these impact effector and memory CD8+ T cell differentiation remain unknown. Using Hi-C, we studied how genome configuration is integrated with CD8+ T cell differentiation during infection and investigated the role of CTCF, a key chromatin remodeler, in modulating CD8+ T cell fates through CTCF knockdown approaches and perturbation of specific CTCF-binding sites. We observed subset-specific changes in chromatin organization and CTCF binding and revealed that weak-affinity CTCF binding promotes terminal differentiation of CD8+ T cells through the regulation of transcriptional programs. Further, patients with de novo CTCF mutations had reduced expression of the terminal-effector genes in peripheral blood lymphocytes. Therefore, in addition to establishing genome architecture, CTCF regulates effector CD8+ T cell heterogeneity through altering interactions that regulate the transcription factor landscape and transcriptome. [Display omitted] • Genome organization changes with effector CD8+ T cell differentiation • CTCF-binding patterns are altered with effector CD8+ T cell differentiation • CTCF regulates subset-specific transcriptional programs and chromatin accessibility • CTCF controls optimal CD8+ T cell-fate decisions in response to infection How changes in spatial chromatin organization are integrated into the network of molecular mechanisms mediating CD8+ T cell effector functions and memory formation is not well understood. Quon et al. characterize genome interactions accompanying the CD8+ T cell response to infection and find that the DNA architectural protein, CTCF, regulates the balance of terminally differentiated-effector cells and memory-fated cells. [ABSTRACT FROM AUTHOR]

Published

2023

19. Loop stacking organizes genome folding from TADs to chromosomes.

Author

Hafner, Antonina, Park, Minhee, Berger, Scott E., Murphy, Sedona E., Nora, Elphège P., and Boettiger, Alistair N.

Subjects

*CHROMOSOMES, *EMBRYONIC stem cells, *COHESINS, *CHROMATIN, *GENE expression, *PROTEIN folding

Abstract

Although population-level analyses revealed significant roles for CTCF and cohesin in mammalian genome organization, their contributions at the single-cell level remain incompletely understood. Here, we used a super-resolution microscopy approach to measure the effects of removal of CTCF or cohesin in mouse embryonic stem cells. Single-chromosome traces revealed cohesin-dependent loops, frequently stacked at their loop anchors forming multi-way contacts (hubs), bridging across TAD boundaries. Despite these bridging interactions, chromatin in intervening TADs was not intermixed, remaining separated in distinct loops around the hub. At the multi-TAD scale, steric effects from loop stacking insulated local chromatin from ultra-long range (>4 Mb) contacts. Upon cohesin removal, the chromosomes were more disordered and increased cell-cell variability in gene expression. Our data revise the TAD-centric understanding of CTCF and cohesin and provide a multi-scale, structural picture of how they organize the genome on the single-cell level through distinct contributions to loop stacking. [Display omitted] • Chromosome tracing shows radially organized chromosome loops • CTCF boundary sites form hubs that depend on cohesin and CTCF • Loss of cohesin leads to expansion at the <4 Mb scale and increased mixing at >4 Mb scale • Loss of cohesin increases entropy in genome folding and variation in gene expression Hafner et al. use microscopy to trace folding of individual chromosomes. They observe and quantify chromatin loops and find that loop stacking is important for 3D organization across genomic scales. CTCF is important for preferential clustering of TAD-boundary sites. Cohesin is essential for both TAD and chromosome-scale folding. [ABSTRACT FROM AUTHOR]

Published

2023

20. Structural elements promote architectural stripe formation and facilitate ultra-long-range gene regulation at a human disease locus.

Author

Chen, Liang-Fu, Long, Hannah Katherine, Park, Minhee, Swigut, Tomek, Boettiger, Alistair Nicol, and Wysocka, Joanna

Subjects

*GENETIC regulation, *ARCHITECTURAL details, *HUMAN genes, *CENTROID, *STRIPES

Abstract

Enhancer clusters overlapping disease-associated mutations in Pierre Robin sequence (PRS) patients regulate SOX9 expression at genomic distances over 1.25 Mb. We applied optical reconstruction of chromatin architecture (ORCA) imaging to trace 3D locus topology during PRS-enhancer activation. We observed pronounced changes in locus topology between cell types. Subsequent analysis of single-chromatin fiber traces revealed that these ensemble-average differences arise through changes in the frequency of commonly sampled topologies. We further identified two CTCF-bound elements, internal to the SOX9 topologically associating domain, which promote stripe formation, are positioned near the domain's 3D geometric center, and bridge enhancer-promoter contacts in a series of chromatin loops. Ablation of these elements results in diminished SOX9 expression and altered domain-wide contacts. Polymer models with uniform loading across the domain and frequent cohesin collisions recapitulate this multi-loop, centrally clustered geometry. Together, we provide mechanistic insights into architectural stripe formation and gene regulation over ultra-long genomic ranges. [Display omitted] • SOX9 domain topology dynamically changes during a developmental transition • Structural elements promote TAD-wide interactions, stripe formation, and transcription • Structural elements are CTCF dependent and situated centrally in the 3D TAD structure • Polymer simulations of the multi-loop model best recapitulate the topological features Enhancer clusters overlapping disease-associated mutations in Pierre Robin sequence (PRS) patients regulate SOX9 expression at genomic distances over 1.25 Mb. Chen and Long et al. trace the 3D topology of the SOX9 locus during PRS-enhancer activation and identify structural elements that promote domain-wide interactions and facilitate ultra-long-range gene regulation. [ABSTRACT FROM AUTHOR]

Published

2023

21. Synthetic regulatory genomics uncovers enhancer context dependence at the Sox2 locus.

Author

Brosh, Ran, Coelho, Camila, Ribeiro-dos-Santos, André M., Ellis, Gwen, Hogan, Megan S., Ashe, Hannah J., Somogyi, Nicolette, Ordoñez, Raquel, Luther, Raven D., Huang, Emily, Boeke, Jef D., and Maurano, Matthew T.

Subjects

*GENOMICS, *EMBRYONIC stem cells, *MOLECULAR cloning, *LOCUS (Genetics), *LOCUS of control

Abstract

Sox2 expression in mouse embryonic stem cells (mESCs) depends on a distal cluster of DNase I hypersensitive sites (DHSs), but their individual contributions and degree of interdependence remain a mystery. We analyzed the endogenous Sox2 locus using Big-IN to scarlessly integrate large DNA payloads incorporating deletions, rearrangements, and inversions affecting single or multiple DHSs, as well as surgical alterations to transcription factor (TF) recognition sequences. Multiple mESC clones were derived for each payload, sequence-verified, and analyzed for Sox2 expression. We found that two DHSs comprising a handful of key TF recognition sequences were each sufficient for long-range activation of Sox2 expression. By contrast, three nearby DHSs were entirely context dependent, showing no activity alone but dramatically augmenting the activity of the autonomous DHSs. Our results highlight the role of context in modulating genomic regulatory element function, and our synthetic regulatory genomics approach provides a roadmap for the dissection of other genomic loci. [Display omitted] • Synthetic regulatory genomics enables dissection of enhancer necessity and sufficiency • Replacing the Sox2 locus control region with a single DHS retains 30% of its activity • Neighboring DHSs synergistically modulate each other's activity • Context-dependent DHSs cannot work alone but double the activity of neighboring DHSs Enhancer clusters are hallmarks of tissue-specific regulation, but the contributions of individual enhancers and their degree of interdependence remain unclear. Brosh et al. use synthetic regulatory genomics to repeatedly rewrite the Sox2 locus, dissecting its overall architecture and precisely delineating distinct roles for individual regulatory elements. [ABSTRACT FROM AUTHOR]

Published

2023

22. Human SMARCA5 is continuously required to maintain nucleosome spacing.

Author

Bomber, Monica L., Wang, Jing, Liu, Qi, Barnett, Kelly R., Layden, Hillary M., Hodges, Emily, Stengel, Kristy R., and Hiebert, Scott W.

Subjects

*CHROMATIN, *PROTEOLYSIS, *GENETIC models, *DNA repair, *BINDING sites, *CELL cycle, *MULTIOMICS, *DNA replication, *TANDEM repeats

Abstract

Genetic models suggested that SMARCA5 was required for DNA-templated events including transcription, DNA replication, and DNA repair. We engineered a degron tag into the endogenous alleles of SMARCA5 , a catalytic component of the imitation switch complexes in three different human cell lines to define the effects of rapid degradation of this key regulator. Degradation of SMARCA5 was associated with a rapid increase in global nucleosome repeat length, which may allow greater chromatin compaction. However, there were few changes in nascent transcription within the first 6 h of degradation. Nevertheless, we demonstrated a requirement for SMARCA5 to control nucleosome repeat length at G 1 /S and during the S phase. SMARCA5 co-localized with CTCF and H2A.Z, and we found a rapid loss of CTCF DNA binding and disruption of nucleosomal phasing around CTCF binding sites. This spatiotemporal analysis indicates that SMARCA5 is continuously required for maintaining nucleosomal spacing. [Display omitted] • Target-specific protein degradation of endogenous human SMARCA5 • Degradation of SMARCA5 leads to a rapid loss in CTCF DNA binding • SMARCA5 regulates nucleosome repeat length independent of the cell cycle • CTCF and SMARCA5 co-localize at H2A.Z-containing sites Bomber et al. utilize degron tagging of the endogenous human chromatin-remodeling enzyme SMARCA5, coupled with a multi-omics approach, to define the requirements for SMARCA5-mediated nucleosome sliding. SMARCA5 co-localized with H2A.Z and CTCF and was required for CTCF DNA binding, nucleosomal phasing at these sites, and maintaining nucleosome repeat length. [ABSTRACT FROM AUTHOR]

Published

2023

23. SATB1 regulates 3D genome architecture in T cells by constraining chromatin interactions surrounding CTCF-binding sites.

Author

Wang B, Ji L, and Bian Q

Subjects

Animals, Humans, Mice, Binding Sites, CCCTC-Binding Factor metabolism, Chromosomes metabolism, T-Lymphocytes metabolism, Transcription Factors metabolism, Chromatin, Matrix Attachment Region Binding Proteins genetics, Matrix Attachment Region Binding Proteins metabolism

Abstract

Special AT-rich sequence binding protein 1 (SATB1) has long been proposed to act as a global chromatin loop organizer in T cells. However, the exact functions of SATB1 in spatial genome organization remain elusive. Here we show that the depletion of SATB1 in human and murine T cells leads to transcriptional dysregulation for genes involved in T cell activation, as well as alterations of 3D genome architecture at multiple levels, including compartments, topologically associating domains, and loops. Importantly, SATB1 extensively colocalizes with CTCF throughout the genome. Depletion of SATB1 leads to increased chromatin contacts among and across the SATB1/CTCF co-occupied sites, thereby affecting the transcription of critical regulators of T cell activation. The loss of SATB1 does not affect CTCF occupancy but significantly reduces the retention of CTCF in the nuclear matrix. Collectively, our data show that SATB1 contributes to 3D genome organization by constraining chromatin topology surrounding CTCF-binding sites., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2023

24. The 3D Genome as Moderator of Chromosomal Communication.

Author

Dekker, Job and Mirny, Leonid

Subjects

*CHROMOSOMES, *GENE expression, *CELL communication, *CHROMATIN, *BIOPHYSICS, *CELL compartmentation, *GENOMES

Abstract

Proper expression of genes requires communication with their regulatory elements that can be located elsewhere along the chromosome. The physics of chromatin fibers imposes a range of constraints on such communication. The molecular and biophysical mechanisms by which chromosomal communication is established, or prevented, have become a topic of intense study, and important roles for the spatial organization of chromosomes are being discovered. Here we present a view of the interphase 3D genome characterized by extensive physical compartmentalization and insulation on the one hand and facilitated long-range interactions on the other. We propose the existence of topological machines dedicated to set up and to exploit a 3D genome organization to both promote and censor communication along and between chromosomes. [ABSTRACT FROM AUTHOR]

Published

2016

25. Chromatin jets define the properties of cohesin-driven in vivo loop extrusion.

Author

Guo, Ya, Al-Jibury, Ediem, Garcia-Millan, Rosalba, Ntagiantas, Konstantinos, King, James W.D., Nash, Alex J., Galjart, Niels, Lenhard, Boris, Rueckert, Daniel, Fisher, Amanda G., Pruessner, Gunnar, and Merkenschlager, Matthias

Subjects

*DNA-binding proteins, *CHROMATIN, *PLASTIC extrusion, *COHESINS

Abstract

Complex genomes show intricate organization in three-dimensional (3D) nuclear space. Current models posit that cohesin extrudes loops to form self-interacting domains delimited by the DNA binding protein CTCF. Here, we describe and quantitatively characterize cohesin-propelled, jet-like chromatin contacts as landmarks of loop extrusion in quiescent mammalian lymphocytes. Experimental observations and polymer simulations indicate that narrow origins of loop extrusion favor jet formation. Unless constrained by CTCF, jets propagate symmetrically for 1–2 Mb, providing an estimate for the range of in vivo loop extrusion. Asymmetric CTCF binding deflects the angle of jet propagation as experimental evidence that cohesin-mediated loop extrusion can switch from bi- to unidirectional and is controlled independently in both directions. These data offer new insights into the physiological behavior of in vivo cohesin-mediated loop extrusion and further our understanding of the principles that underlie genome organization. [Display omitted] • Cohesin-powered chromatin jets emerge from focal areas of accessible chromatin • Unless constrained by CTCF, jets can propagate symmetrically for 1–2 Mb • CTCF can block jets or deflect the angle of jet propagation • These data suggest that loop extrusion is controlled independently in both directions Cohesin organizes the genome in 3D nuclear space. In this issue of Molecular Cell , Guo et al. describe and characterize "jets," an unusual form of cohesin-mediated chromatin interactions. Jets offer insights into the physiological behavior of cohesin-mediated loop extrusion and the principles that underlie genome organization. [ABSTRACT FROM AUTHOR]

Published

2022

26. Repression and 3D-restructuring resolves regulatory conflicts in evolutionarily rearranged genomes.

Author

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, Cesar A., and Haas, Stefan A.

Subjects

*GENOMES, *REGULATOR genes, *GENE enhancers, *GENE expression, *DNA methylation, *NUCLEAR membranes

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. [Display omitted] • Novel genes can emerge in evolution without adopting or disrupting existing regulation • TADs can be grossly restructured by chromatin activity independently of cohesin/CTCF • NE attachment need not block gene activation or enhancer communication • Context-dependent promoter silencing can refine enhancer usage in multi-gene TADs Multiple genetic and epigenetic mechanisms resolve the gene regulatory conflicts that inevitably arise during genome evolution. [ABSTRACT FROM AUTHOR]

Published

2022

27. Chromatin-bound RB targets promoters, enhancers, and CTCF-bound loci and is redistributed by cell-cycle progression.

Author

Sanidas, Ioannis, Lee, Hanjun, Rumde, Purva H., Boulay, Gaylor, Morris, Robert, Golczer, Gabriel, Stanzione, Marcelo, Hajizadeh, Soroush, Zhong, Jun, Ryan, Meagan B., Corcoran, Ryan B., Drapkin, Benjamin J., Rivera, Miguel N., Dyson, Nicholas J., and Lawrence, Michael S.

Subjects

*CELL cycle, *TRANSCRIPTION factors, *RETINOBLASTOMA protein, *CHROMATIN, *GENES

Abstract

The interaction of RB with chromatin is key to understanding its molecular functions. Here, for first time, we identify the full spectrum of chromatin-bound RB. Rather than exclusively binding promoters, as is often described, RB targets three fundamentally different types of loci (promoters, enhancers, and insulators), which are largely distinguishable by the mutually exclusive presence of E2F1, c-Jun, and CTCF. While E2F/DP facilitates RB association with promoters, AP-1 recruits RB to enhancers. Although phosphorylation in CDK sites is often portrayed as releasing RB from chromatin, we show that the cell cycle redistributes RB so that it enriches at promoters in G1 and at non-promoter sites in cycling cells. RB-bound promoters include the classic E2F-targets and are similar between lineages, but RB-bound enhancers associate with different categories of genes and vary between cell types. Thus, RB has a well-preserved role controlling E2F in G1, and it targets cell-type-specific enhancers and CTCF sites when cells enter S-phase. [Display omitted] • RB associates with E2F-promoters, AP-1 enhancers, and CTCF-insulators • RB-bound promoters and enhancers target different sets of genes • Cell-cycle progression redistributes chromatin-bound RB toward enhancers • RB-bound promoters are conserved while enhancers are cell-type specific Sanidas et al. show that, rather than exclusively targeting E2F-promoters, RB associates with specific groups of promoters, enhancers, and insulators to target different sets of genes. Cell-cycle progression redistributes RB toward cell-type-specific enhancers. PanChIP software confirms that RB associates with distinct transcription factors at different types of loci. [ABSTRACT FROM AUTHOR]

Published

2022

28. Chromatin 3D interaction analysis of the STARD10 locus unveils FCHSD2 as a regulator of insulin secretion

Author

Inês Cebola, Michele Solimena, Mickaël Canouil, Paul Gadue, Guy A. Rutter, Sameena Nawaz, Piero Marchetti, Leonardo Alemeida-Souza, Amna Khamis, Anke M. Schulte, Harvey T. McMahon, Gaelle Carrat, Benoit Hastoy, Shuying Jiang, Ming Hu, Fabian L. Cardenas-Diaz, Philippe Froguel, Mark Ibberson, MRC Programme Grant, Wellcome Trust, and Helsinki Institute of Life Science HiLIFE

Subjects

0301 basic medicine, insulin secretion, Regulator, 0601 Biochemistry and Cell Biology, Chromosome conformation capture, 0302 clinical medicine, Insulin-Secreting Cells, GWAS, T2D, TRANSCRIPTION, Fchsd2, Gwas, Stard10, T2d, Chromatin Structure, Enhancer Cluster, Gene Regulation, Genetic Variant, Insulin Secretion, Type 2 Diabetes, Regulation of gene expression, chromatin structure, 0303 health sciences, FCHSD2, Chromatin, Cell biology, ISLETS, DEFINES, type 2 diabetes, enhancer cluster, gene regulation, genetic variant, STARD10, EXPRESSION, PATHOPHYSIOLOGY, PROVIDES INSIGHTS, Locus (genetics), Biology, General Biochemistry, Genetics and Molecular Biology, Article, GENETIC ARCHITECTURE, ENHANCER, 03 medical and health sciences, Humans, GENOME-WIDE ASSOCIATION, Allele, Enhancer, Gene, 030304 developmental biology, Correction, Membrane Proteins, CTCF, Phosphoproteins, 030104 developmental biology, 1116 Medical Physiology, 1182 Biochemistry, cell and molecular biology, Carrier Proteins, 030217 neurology & neurosurgery

Abstract

Summary Using chromatin conformation capture, we show that an enhancer cluster in the STARD10 type 2 diabetes (T2D) locus forms a defined 3-dimensional (3D) chromatin domain. A 4.1-kb region within this locus, carrying 5 T2D-associated variants, physically interacts with CTCF-binding regions and with an enhancer possessing strong transcriptional activity. Analysis of human islet 3D chromatin interaction maps identifies the FCHSD2 gene as an additional target of the enhancer cluster. CRISPR-Cas9-mediated deletion of the variant region, or of the associated enhancer, from human pancreas-derived EndoC-βH1 cells impairs glucose-stimulated insulin secretion. Expression of both STARD10 and FCHSD2 is reduced in cells harboring CRISPR deletions, and lower expression of STARD10 and FCHSD2 is associated, the latter nominally, with the possession of risk variant alleles in human islets. Finally, CRISPR-Cas9-mediated loss of STARD10 or FCHSD2, but not ARAP1, impairs regulated insulin secretion. Thus, multiple genes at the STARD10 locus influence β cell function., Graphical Abstract, Highlights • Type 2 risk variants at STARD10 reside in CTCF-flanked enhancer clusters • Loss of the risk variant-bearing region inhibits regulated insulin secretion • 3D chromatin interaction maps reveal FCHSD2 as target of the enhancer cluster • Deletion of STARD10 or FCHSD2 from EndoC-βH1 β cells inhibits insulin secretion, In this article, Hu et al. show the importance, for gene regulation, of a genomic region harboring GWAS variants that affect type 2 diabetes risk at the STARD10 locus. They also identify FCHSD2 as a likely mediator of the effects of these variants on insulin secretion.

Published

2021

29. Genomic profiling of HIV-1 integration in microglia cells links viral integration to the topologically associated domains.

Author

Rheinberger M, Costa AL, Kampmann M, Glavas D, Shytaj IL, Sreeram S, Penzo C, Tibroni N, Garcia-Mesa Y, Leskov K, Fackler OT, Vlahovicek K, Karn J, Lucic B, Herrmann C, and Lusic M

Subjects

Microglia metabolism, CCCTC-Binding Factor metabolism, Chromatin, Genomics, Virus Integration genetics, HIV-1 genetics, HIV-1 metabolism

Abstract

HIV-1 encounters the hierarchically organized host chromatin to stably integrate and persist in anatomically distinct latent reservoirs. The contribution of genome organization in HIV-1 infection has been largely understudied across different HIV-1 targets. Here, we determine HIV-1 integration sites (ISs), associate them with chromatin and expression signatures at different genomic scales in a microglia cell model, and profile them together with the primary T cell reservoir. HIV-1 insertions into introns of actively transcribed genes with IS hotspots in genic and super-enhancers, characteristic of blood cells, are maintained in the microglia cell model. Genome organization analysis reveals dynamic CCCTC-binding factor (CTCF) clusters in cells with active and repressed HIV-1 transcription, whereas CTCF removal impairs viral integration. We identify CTCF-enriched topologically associated domain (TAD) boundaries with signatures of transcriptionally active chromatin as HIV-1 integration determinants in microglia and CD4 + T cells, highlighting the importance of host genome organization in HIV-1 infection., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2023

30. Principles of 3D chromosome folding and evolutionary genome reshuffling in mammals.

Author

Álvarez-González L, Arias-Sardá C, Montes-Espuña L, Marín-Gual L, Vara C, Lister NC, Cuartero Y, Garcia F, Deakin J, Renfree MB, Robinson TJ, Martí-Renom MA, Waters PD, Farré M, and Ruiz-Herrera A

Subjects

Animals, Chromosomes genetics, Mammals genetics, Genome, Vertebrates genetics, Chromatin genetics, Evolution, Molecular, Marsupialia

Abstract

Studying the similarities and differences in genomic interactions between species provides fertile grounds for determining the evolutionary dynamics underpinning genome function and speciation. Here, we describe the principles of 3D genome folding in vertebrates and show how lineage-specific patterns of genome reshuffling can result in different chromatin configurations. We (1) identified different patterns of chromosome folding in across vertebrate species (centromere clustering versus chromosomal territories); (2) reconstructed ancestral marsupial and afrotherian genomes analyzing whole-genome sequences of species representative of the major therian phylogroups; (3) detected lineage-specific chromosome rearrangements; and (4) identified the dynamics of the structural properties of genome reshuffling through therian evolution. We present evidence of chromatin configurational changes that result from ancestral inversions and fusions/fissions. We catalog the close interplay between chromatin higher-order organization and therian genome evolution and introduce an interpretative hypothesis that explains how chromatin folding influences evolutionary patterns of genome reshuffling., Competing Interests: Declaration of interests M.A.M.-R. serves as a consultant to Acuity Spatial Genomics, Inc., and receives compensation for these services., (Copyright © 2022 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2022

31. Distinct properties and functions of CTCF revealed by a rapidly inducible degron system

Author

Yemin Lan, Haoyue Zhang, Yu Zhang, Marit W. Vermunt, Belinda Giardine, Jacob M Tome, Guanjue Xiang, Jing Luan, Pablo Aurelio Gómez-García, Cheryl A. Keller, Zhe Zhang, Gerd A. Blobel, John T. Lis, Anran Huang, Melike Lakadamyali, and Ross C. Hardison

Subjects

0301 basic medicine, CCCTC-Binding Factor, Erythroblasts, Transcription, Genetic, transcription elongation stalling, cohesin, Biology, Molecular Dynamics Simulation, General Biochemistry, Genetics and Molecular Biology, Article, Cell Line, Cromatina, 03 medical and health sciences, Mice, 0302 clinical medicine, chromatin architecture, Transcriptional regulation, degradation dynamics, Animals, Gene, lcsh:QH301-705.5, residence time, Zinc finger transcription factor, Gene Editing, Binding Sites, Cohesin, CTCF, Chromatin Assembly and Disassembly, Chromatin, Single Molecule Imaging, Cell biology, Kinetics, Genòmica, 030104 developmental biology, lcsh:Biology (General), Proteolysis, Chromatin Immunoprecipitation Sequencing, Chromatin Loop, RNA Polymerase II, Degron, CRISPR-Cas Systems, 030217 neurology & neurosurgery, Protein Binding

Abstract

SUMMARY CCCTC-binding factor (CTCF) is a conserved zinc finger transcription factor implicated in a wide range of functions, including genome organization, transcription activation, and elongation. To explore the basis for CTCF functional diversity, we coupled an auxin-induced degron system with precision nuclear run-on. Unexpectedly, oriented CTCF motifs in gene bodies are associated with transcriptional stalling in a manner independent of bound CTCF. Moreover, CTCF at different binding sites (CBSs) displays highly variable resistance to degradation. Motif sequence does not significantly predict degradation behavior, but location at chromatin boundaries and chromatin loop anchors, as well as co-occupancy with cohesin, are associated with delayed degradation. Single-molecule tracking experiments link chromatin residence time to CTCF degradation kinetics, which has ramifications regarding architectural CTCF functions. Our study highlights the heterogeneity of CBSs, uncovers properties specific to architecturally important CBSs, and provides insights into the basic processes of genome organization and transcription regulation., Graphical Abstract, In brief Using an inducible CTCF degradation approach, Luan et al. show that sensitivity to degradation of CTCF on chromatin is highly variable, reflecting its diverse roles in chromatin architecture and transcription.

Published

2021

32. Establishment of 3D chromatin structure after fertilization and the metabolic switch at the morula-to-blastocyst transition require CTCF.

Author

Andreu MJ, Alvarez-Franco A, Portela M, Gimenez-Llorente D, Cuadrado A, Badia-Careaga C, Tiana M, Losada A, and Manzanares M

Subjects

Mice, Animals, Morula metabolism, Chromatin metabolism, Fertilization, CCCTC-Binding Factor metabolism, Mammals metabolism, Blastocyst metabolism, Embryonic Development genetics

Abstract

The eukaryotic genome is organized in 3D at different scales. This structure is driven and maintained by different chromatin states and by architectural factors, such as the zinc finger protein CTCF. Zygotic genome structure is established de novo after fertilization, but its impact during the first stages of mammalian development is unclear. We show that deletion of Ctcf in mouse embryos impairs the establishment of chromatin structure, but the first cell fate decision is unperturbed and embryos are viable until the late blastocyst. Furthermore, maternal CTCF is not necessary for development. Gene expression changes in metabolic and protein homeostasis programs that occur during the morula-to-blastocyst transition depend on CTCF. However, these changes do not correlate with disruption of chromatin but with binding of CTCF to the promoter of downregulated genes. Our results show that CTCF regulates both 3D genome organization and transcription during mouse preimplantation development, but as independent processes., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2022 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2022

33. Promoter and enhancer RNAs regulate chromatin reorganization and activation of miR-10b/HOXD locus, and neoplastic transformation in glioma.

Author

Deforzh, Evgeny, Uhlmann, Erik J., Das, Eashita, Galitsyna, Aleksandra, Arora, Ramil, Saravanan, Harini, Rabinovsky, Rosalia, Wirawan, Aditya D., Teplyuk, Nadiya M., El Fatimy, Rachid, Perumalla, Sucika, Jairam, Anirudh, Wei, Zhiyun, Mirny, Leonid, and Krichevsky, Anna M.

Subjects

*GENE enhancers, *CHROMATIN, *GLIOMAS, *NEOPLASTIC cell transformation, *RNA, *LOCUS (Genetics), *ASTROCYTES

Abstract

miR-10b is silenced in normal neuroglial cells of the brain but commonly activated in glioma, where it assumes an essential tumor-promoting role. We demonstrate that the entire miR-10b-hosting HOXD locus is activated in glioma via the cis -acting mechanism involving 3D chromatin reorganization and CTCF-cohesin-mediated looping. This mechanism requires two interacting lncRNAs, HOXD-AS2 and LINC01116, one associated with HOXD3/HOXD4/miR-10b promoter and another with the remote enhancer. Knockdown of either lncRNA in glioma cells alters CTCF and cohesin binding, abolishes chromatin looping, inhibits the expression of all genes within HOXD locus, and leads to glioma cell death. Conversely, in cortical astrocytes, enhancer activation is sufficient for HOXD/miR-10b locus reorganization, gene derepression, and neoplastic cell transformation. LINC01116 RNA is essential for this process. Our results demonstrate the interplay of two lncRNAs in the chromatin folding and concordant regulation of miR-10b and multiple HOXD genes normally silenced in astrocytes and triggering the neoplastic glial transformation. [Display omitted] • Chromatin topology of the HOXD locus is altered between the brain and glioblastoma • lncRNAs regulate CTCF/cohesin-dependent loop formation and HOXD gene expression • Activation of LINC01116 enhancer RNA leads to astrocyte transformation • The transformation depends on the loop formation and miR-10b derepression Deforzh et al. investigated a common mechanism of HOXD/miR-10b genes' derepression in glioblastoma and revealed the coordinated activity of two lncRNAs, HOXD-embedded HOXD-AS2 and distant enhancer-associated LINC01116, in CTCF/cohesin binding, chromatin topology, and astrocyte transformation. The work shed light on the molecular mechanisms of gliomagenesis. [ABSTRACT FROM AUTHOR]

Published

2022

34. Characterization and perturbation of CTCF-mediated chromatin interactions for enhancing myogenic transdifferentiation.

Author

Ren R, Fan Y, Peng Z, Wang S, Jiang Y, Fu L, Cao J, Zhao S, and Wang H

Subjects

Animals, CCCTC-Binding Factor metabolism, Cell Differentiation genetics, Mice, Muscle Development genetics, Swine, Cell Transdifferentiation genetics, Chromatin

Abstract

Expression of key transcription factors can induce transdifferentiation in somatic cells; however, this conversion is usually incomplete due to undefined intrinsic barriers. Here, we employ MyoD-induced transdifferentiation of fibroblasts as a model to illustrate the chromatin structures that impede the cell-fate transition. Focusing on the three-dimensional (3D) chromatin interactions, we show that MyoD directly establishes chromatin loops to activate myogenic transcriptional program. Similarly, dynamic changes of CTCF-mediated chromatin interactions are favorable for fibroblast-to-myoblast conversion. However, a substantial portion of CTCF-mediated chromatin interactions remain stable, and the associated genes are steady in expression and enriched for fibroblast function that may restrict cell-identity transformation. Temporal CTCF depletion can interrupt the resistant chromatin loops to enhance myogenic transdifferentiation in mice, pig, and chicken fibroblasts. Therefore, during induced transdifferentiation, the transcription factor can directly reorganize the 3D chromatin interactions, and perturbation of CTCF-mediated genome topology may resolve the limitations of cell fate transitions., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2022 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2022

35. Jpx RNA regulates CTCF anchor site selection and formation of chromosome loops.

Author

Oh, Hyun Jung, Aguilar, Rodrigo, Kesner, Barry, Lee, Hun-Goo, Kriz, Andrea J., Chu, Hsueh-Ping, and Lee, Jeannie T.

Subjects

*CHROMOSOMES, *RNA, *NON-coding RNA, *GENETIC regulation, *HUMAN chromosomes, *CHROMATIN

Abstract

Chromosome loops shift dynamically during development, homeostasis, and disease. CCCTC-binding factor (CTCF) is known to anchor loops and construct 3D genomes, but how anchor sites are selected is not yet understood. Here, we unveil Jpx RNA as a determinant of anchor selectivity. Jpx RNA targets thousands of genomic sites, preferentially binding promoters of active genes. Depleting Jpx RNA causes ectopic CTCF binding, massive shifts in chromosome looping, and downregulation of >700 Jpx target genes. Without Jpx, thousands of lost loops are replaced by de novo loops anchored by ectopic CTCF sites. Although Jpx controls CTCF binding on a genome-wide basis, it acts selectively at the subset of developmentally sensitive CTCF sites. Specifically, Jpx targets low-affinity CTCF motifs and displaces CTCF protein through competitive inhibition. We conclude that Jpx acts as a CTCF release factor and shapes the 3D genome by regulating anchor site usage. [Display omitted] • Jpx RNA binds and activates hundreds of mammalian genes in the mouse genome • Jpx selectively evicts CTCF bound to low-affinity, developmentally sensitive sites • Jpx loss causes genome-wide shifts in CTCF binding and chromosome looping • Jpx determines anchor site usage by serving as a CTCF release factor Jpx RNA regulates chromosome looping throughout the genome by releasing CTCF from chromatin, thereby determining where CTCF binds, how anchor sites are selected, and how genome architecture is regulated. [ABSTRACT FROM AUTHOR]

Published

2021

36. Argonaute proteins regulate a specific network of genes through KLF4 in mouse embryonic stem cells.

Author

Müller M, Schaefer M, Fäh T, Spies D, Hermes V, Ngondo RP, Peña-Hernández R, Santoro R, and Ciaudo C

Subjects

Animals, Chromatin genetics, Kruppel-Like Factor 4 genetics, Mice, Mouse Embryonic Stem Cells metabolism, Polycomb Repressive Complex 2 genetics, Argonaute Proteins genetics, Argonaute Proteins metabolism, MicroRNAs genetics, MicroRNAs metabolism

Abstract

The Argonaute proteins (AGOs) are well known for their role in post-transcriptional gene silencing in the microRNA (miRNA) pathway. Here we show that in mouse embryonic stem cells, AGO1&2 serve additional functions that go beyond the miRNA pathway. Through the combined deletion of both Agos, we identified a specific set of genes that are uniquely regulated by AGOs but not by the other miRNA biogenesis factors. Deletion of Ago2&1 caused a global reduction of the repressive histone mark H3K27me3 due to downregulation at protein levels of Polycomb repressive complex 2 components. By integrating chromatin accessibility, prediction of transcription factor binding sites, and chromatin immunoprecipitation sequencing data, we identified the pluripotency factor KLF4 as a key modulator of AGO1&2-regulated genes. Our findings revealed a novel axis of gene regulation that is mediated by noncanonical functions of AGO proteins that affect chromatin states and gene expression using mechanisms outside the miRNA pathway., (Copyright © 2022 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2022

37. CTCF functions as an insulator for somatic genes and a chromatin remodeler for pluripotency genes during reprogramming.

Author

Song Y, Liang Z, Zhang J, Hu G, Wang J, Li Y, Guo R, Dong X, Babarinde IA, Ping W, Sheng YL, Li H, Chen Z, Gao M, Chen Y, Shan G, Zhang MQ, Hutchins AP, Fu XD, and Yao H

Subjects

Animals, Humans, Mice, Promoter Regions, Genetic, CCCTC-Binding Factor genetics, CCCTC-Binding Factor metabolism, Cellular Reprogramming genetics, Chromatin, Enhancer Elements, Genetic genetics

Abstract

CTCF mediates chromatin insulation and long-distance enhancer-promoter (EP) interactions; however, little is known about how these regulatory functions are partitioned among target genes in key biological processes. Here, we show that Ctcf expression is progressively increased during induced pluripotency. In this process, CTCF first functions as a chromatin insulator responsible for direct silencing of the somatic gene expression program and, interestingly, elevated Ctcf expression next ensures chromatin accessibility and contributes to increased EP interactions for a fraction of pluripotency-associated genes. Therefore, CTCF functions in a context-specific manner to modulate the 3D genome to enable cellular reprogramming. We further discover that these context-specific CTCF functions also enlist SMARCA5, an imitation switch (ISWI) chromatin remodeler, together rewiring the epigenome to facilitate cell-fate switch. These findings reveal the dual functions of CTCF in conjunction with a key chromatin remodeler to drive reprogramming toward pluripotency., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

38. Two Mutually Exclusive Local Chromatin States Drive Efficient V(D)J Recombination

Author

Simon Andrews, Andrew L. Wood, Amanda Baizan-Edge, Hashem Koohy, Felix Krueger, Daniel J. Bolland, Mikhail Spivakov, Kristina Tabbada, Louise S. Matheson, Peter Chovanec, Anne E. Corcoran, Bryony A. Stubbs, and Michael J. T. Stubbington

Subjects

0301 basic medicine, Transcription, Genetic, Sequence analysis, Immunoglobulin Variable Region, Biology, General Biochemistry, Genetics and Molecular Biology, Article, Epigenesis, Genetic, Evolution, Molecular, 03 medical and health sciences, chemistry.chemical_compound, Mice, 0302 clinical medicine, Animals, Humans, lcsh:QH301-705.5, Gene, Regulation of gene expression, Genetics, Homeodomain Proteins, V(D)J recombination, Sequence Analysis, DNA, Chromatin, V(D)J Recombination, Receptors, Antigen, 030104 developmental biology, lcsh:Biology (General), chemistry, Gene Expression Regulation, CTCF, Genetic Loci, Immunoglobulin Heavy Chains, Recombination, DNA, Algorithms, 030215 immunology

Abstract

Summary Variable (V), diversity (D), and joining (J) (V(D)J) recombination is the first determinant of antigen receptor diversity. Understanding how recombination is regulated requires a comprehensive, unbiased readout of V gene usage. We have developed VDJ sequencing (VDJ-seq), a DNA-based next-generation-sequencing technique that quantitatively profiles recombination products. We reveal a 200-fold range of recombination efficiency among recombining V genes in the primary mouse Igh repertoire. We used machine learning to integrate these data with local chromatin profiles to identify combinatorial patterns of epigenetic features that associate with active VH gene recombination. These features localize downstream of VH genes and are excised by recombination, revealing a class of cis-regulatory element that governs recombination, distinct from expression. We detect two mutually exclusive chromatin signatures at these elements, characterized by CTCF/RAD21 and PAX5/IRF4, which segregate with the evolutionary history of associated VH genes. Thus, local chromatin signatures downstream of VH genes provide an essential layer of regulation that determines recombination efficiency., Graphical Abstract, Highlights • VDJ-seq enables precise quantification of antibody V(D)J recombination products • Two distinct cis-regulatory designs characterize actively recombining V genes • Putative recombination regulatory elements map downstream of mouse Igh V genes • Recombination regulatory architecture reflects the V genes’ evolutionary history, Bolland et al. develop a technique to quantitatively profile antigen receptor diversity. Using VDJ-seq in the mouse Igh locus, they uncover the regulatory logic underlying the highly varying recombination rates of V gene segments, with implications for immune disorders and aberrant recombination in cancer.

Published

2016

39. Interplay between CTCF boundaries and a super enhancer controls cohesin extrusion trajectories and gene expression.

Author

Vos, Erica S.M., Valdes-Quezada, Christian, Huang, Yike, Allahyar, Amin, Verstegen, Marjon J.A.M., Felder, Anna-Karina, van der Vegt, Floor, Uijttewaal, Esther C.H., Krijger, Peter H.L., and de Laat, Wouter

Subjects

*COHESINS, *GENE expression, *EMBRYONIC stem cells, *GENETIC regulation, *CIS-regulatory elements (Genetics), *GENE enhancers, *INVERTED repeats (Genetics)

Abstract

To understand how chromatin domains coordinate gene expression, we dissected select genetic elements organizing topology and transcription around the Prdm14 super enhancer in mouse embryonic stem cells. Taking advantage of allelic polymorphisms, we developed methods to sensitively analyze changes in chromatin topology, gene expression, and protein recruitment. We show that enhancer insulation does not rely strictly on loop formation between its flanking boundaries, that the enhancer activates the Slco5a1 gene beyond its prominent domain boundary, and that it recruits cohesin for loop extrusion. Upon boundary inversion, we find that oppositely oriented CTCF terminates extrusion trajectories but does not stall cohesin, while deleted or mutated CTCF sites allow cohesin to extend its trajectory. Enhancer-mediated gene activation occurs independent of paused loop extrusion near the gene promoter. We expand upon the loop extrusion model to propose that cohesin loading and extrusion trajectories originating at an enhancer contribute to gene activation. [Display omitted] • An enhancer initiates loop extrusion trajectories that delineate activatable genes • Enhancer insulation does not depend strictly on looping between its CTCF boundaries • A loop-engaged inverted CTCF boundary can also block cohesin extrusion trajectories • A strong CTCF boundary permits rare but productive enhancer-promoter contacts The three-dimensional structure of the genome, organized by architectural proteins CTCF and cohesin, has a strong influence on how genes are expressed. Here, Vos et al. allele-specifically dissect an active genomic region to reveal how an enhancer and CTCF boundaries organize cohesin extrusion trajectories, build structural domains, and regulate genes. [ABSTRACT FROM AUTHOR]

Published

2021

40. Cohesin Disrupts Polycomb-Dependent Chromosome Interactions in Embryonic Stem Cells

Author

Noelia Díaz, Angelika Feldmann, Veronica J. Buckle, Miles K. Huseyin, James D.P. Rhodes, Paula Dobrinić, Praveen Prathapan, Neil P. Blackledge, Aleksander T. Szczurek, Kai Kruse, Juan M. Vaquerizas, Nadezda A. Fursova, Kim Nasmyth, Robert J. Klose, Jill M. Brown, and Benjamín Hernández-Rodríguez

Subjects

0301 basic medicine, Male, Cell type, CCCTC-Binding Factor, Chromosomal Proteins, Non-Histone, cohesin, Polycomb-Group Proteins, Cell Cycle Proteins, macromolecular substances, Biology, Genome, General Biochemistry, Genetics and Molecular Biology, Article, Chromosomes, Cell Line, 03 medical and health sciences, Mice, 0302 clinical medicine, Hi-C, Animals, TADs, lcsh:QH301-705.5, Embryonic Stem Cells, Regulation of gene expression, loop extrusion, Cohesin, Chromosome, Embryonic stem cell, Chromatin, Cell biology, Polycomb, 030104 developmental biology, lcsh:Biology (General), Gene Expression Regulation, CTCF, PRC1, biological phenomena, cell phenomena, and immunity, gene regulation, 030217 neurology & neurosurgery

Abstract

Summary How chromosome organization is related to genome function remains poorly understood. Cohesin, loop extrusion, and CCCTC-binding factor (CTCF) have been proposed to create topologically associating domains (TADs) to regulate gene expression. Here, we examine chromosome conformation in embryonic stem cells lacking cohesin and find, as in other cell types, that cohesin is required to create TADs and regulate A/B compartmentalization. However, in the absence of cohesin, we identify a series of long-range chromosomal interactions that persist. These correspond to regions of the genome occupied by the polycomb repressive system and are dependent on PRC1. Importantly, we discover that cohesin counteracts these polycomb-dependent interactions, but not interactions between super-enhancers. This disruptive activity is independent of CTCF and insulation and appears to modulate gene repression by the polycomb system. Therefore, we discover that cohesin disrupts polycomb-dependent chromosome interactions to modulate gene expression in embryonic stem cells., Graphical Abstract, Highlights • Interaction between polycomb target genes in ESCs occurs independently of cohesin • Loop extrusion by cohesin disrupts interactions between polycomb target genes • Cohesin removal enhances repression at polycomb target genes with increased interactions, Using Hi-C, Capture-C, and DNA-FISH, Rhodes et al. discover that interactions between polycomb target genes occur independently of cohesin in embryonic stem cells. This relies on PRC1, and these interactions are disrupted by cohesin-mediated loop extrusion. Upon removal of cohesin, gene repression is enhanced at polycomb-occupied genes with increased interactions.

Published

2020

41. Principles of 3D compartmentalization of the human genome.

Author

Nichols MH and Corces VG

Subjects

Animals, Chromatin metabolism, Chromosomes, Human, Pair 14 genetics, Drosophila genetics, Genome, Insect, HCT116 Cells, Histone Code genetics, Humans, Transcription, Genetic, Cell Compartmentation genetics, Genome, Human, Imaging, Three-Dimensional

Abstract

Chromatin is organized in the nucleus via CTCF loops and compartmental domains. Here, we compare different cell types to identify distinct paradigms of compartmental domain formation in human tissues. We identify and quantify compartmental forces correlated with histone modifications characteristic of transcriptional activity and previously underappreciated roles for distinct compartmental domains correlated with the presence of H3K27me3 and H3K9me3, respectively. We present a computer simulation model capable of predicting compartmental organization based on the biochemical characteristics of independent chromatin features. Using this model, we show that the underlying forces responsible for compartmental domain formation in human cells are conserved and that the diverse compartmentalization patterns seen across cell types are due to differences in chromatin features. We extend these findings to Drosophila to suggest that the same principles are at work beyond humans. These results offer mechanistic insights into the fundamental forces driving the 3D organization of the genome., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2021

42. STAG2 mutations alter CTCF-anchored loop extrusion, reduce cis-regulatory interactions and EWSR1-FLI1 activity in Ewing sarcoma.

Author

Surdez D, Zaidi S, Grossetête S, Laud-Duval K, Ferre AS, Mous L, Vourc'h T, Tirode F, Pierron G, Raynal V, Baulande S, Brunet E, Hill V, and Delattre O

Subjects

Bone Neoplasms mortality, Bone Neoplasms pathology, CCCTC-Binding Factor chemistry, CCCTC-Binding Factor genetics, Cell Cycle Proteins metabolism, Cell Line, Tumor, Cell Movement genetics, Chromatin Immunoprecipitation, Chromosomal Proteins, Non-Histone metabolism, Enhancer Elements, Genetic, Gene Expression Regulation, Neoplastic, Histones metabolism, Humans, Loss of Function Mutation, Lysine metabolism, Oncogene Proteins, Fusion metabolism, Promoter Regions, Genetic, Sarcoma, Ewing mortality, Sarcoma, Ewing pathology, Cohesins, Bone Neoplasms genetics, CCCTC-Binding Factor metabolism, Cell Cycle Proteins genetics, Oncogene Proteins, Fusion genetics, Sarcoma, Ewing genetics

Abstract

STAG2, a cohesin family gene, is among the most recurrently mutated genes in cancer. STAG2 loss of function (LOF) is associated with aggressive behavior in Ewing sarcoma, a childhood cancer driven by aberrant transcription induced by the EWSR1-FLI1 fusion oncogene. Here, using isogenic Ewing cells, we show that, while STAG2 LOF profoundly changes the transcriptome, it does not significantly impact EWSR1-FLI1, CTCF/cohesin, or acetylated H3K27 DNA binding patterns. In contrast, it strongly alters the anchored dynamic loop extrusion process at boundary CTCF sites and dramatically decreases promoter-enhancer interactions, particularly affecting the expression of genes regulated by EWSR1-FLI1 at GGAA microsatellite neo-enhancers. Down-modulation of cis-mediated EWSR1-FLI1 activity, observed in STAG2-LOF conditions, is associated with enhanced migration and invasion properties of Ewing cells previously observed in EWSR1-FLI1 low cells. Our study illuminates a process whereby STAG2-LOF fine-tunes the activity of an oncogenic transcription factor through altered CTCF-anchored loop extrusion and cis-mediated enhancer mechanisms., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

43. Opposing Effects of Cohesin and Transcription on CTCF Organization Revealed by Super-resolution Imaging.

Author

Gu, Bo, Comerci, Colin J., McCarthy, Dannielle G., Saurabh, Saumya, Moerner, W.E., and Wysocka, Joanna

Subjects

*COHESINS, *HIGH resolution imaging, *STEREOLOGY, *MOLECULAR interactions, *GENETIC engineering, *RNA polymerases

Abstract

CCCTC-binding factor (CTCF) and cohesin play critical roles in organizing mammalian genomes into topologically associating domains (TADs). Here, by combining genetic engineering with quantitative super-resolution stimulated emission depletion (STED) microscopy, we demonstrate that in living cells, CTCF forms clusters typically containing 2–8 molecules. A fraction of CTCF clusters, enriched for those with ≥3 molecules, are coupled with cohesin complexes with a characteristic physical distance suggestive of a defined molecular interaction. Acute degradation of the cohesin unloader WAPL or transcriptional inhibition (TI) result in increased CTCF clustering. Furthermore, the effect of TI on CTCF clusters is alleviated by the acute loss of the cohesin subunit SMC3. Our study provides quantitative characterization of CTCF clusters in living cells, uncovers the opposing effects of cohesin and transcription on CTCF clustering, and highlights the power of quantitative super-resolution microscopy as a tool to bridge the gap between biochemical and genomic methodologies in chromatin research. • Live-cell, quantitative super-resolution imaging of chromatin organizing proteins • CTCF forms clusters of 2–8 molecules, with ∼25% of clusters coupled to cohesin • No detectable coupling between CTCF/cohesin and Pol II clusters • Cohesin and transcription play opposing roles in CTCF cluster formation The chromatin organizing proteins CTCF and cohesin are known to exhibit spatial heterogeneity, forming "clusters" inside the nucleus. Here, Gu, Comerci, McCarthy, et al. use super-resolution microscopy to measure quantitative parameters governing CTCF and cohesin cluster formation and demonstrate that cohesin and transcription play opposing roles in CTCF clustering. [ABSTRACT FROM AUTHOR]

Published

2020

44. DNA Methylation Regulates Alternative Polyadenylation via CTCF and the Cohesin Complex.

Author

Nanavaty, Vishal, Abrash, Elizabeth W., Hong, Changjin, Park, Sunho, Fink, Emily E., Li, Zhuangyue, Sweet, Thomas J., Bhasin, Jeffrey M., Singuri, Srinidhi, Lee, Byron H., Hwang, Tae Hyun, and Ting, Angela H.

Subjects

*DNA methylation, *DNA, *BINDING sites, *BETAINE, *CHROMATIN, *COHESINS, *GENE enhancers

Abstract

Dysregulation of DNA methylation and mRNA alternative cleavage and polyadenylation (APA) are both prevalent in cancer and have been studied as independent processes. We discovered a DNA methylation-regulated APA mechanism when we compared genome-wide DNA methylation and polyadenylation site usage between DNA methylation-competent and DNA methylation-deficient cells. Here, we show that removal of DNA methylation enables CTCF binding and recruitment of the cohesin complex, which, in turn, form chromatin loops that promote proximal polyadenylation site usage. In this DNA demethylated context, either deletion of the CTCF binding site or depletion of RAD21 cohesin complex protein can recover distal polyadenylation site usage. Using data from The Cancer Genome Atlas, we authenticated the relationship between DNA methylation and mRNA polyadenylation isoform expression in vivo. This DNA methylation-regulated APA mechanism demonstrates how aberrant DNA methylation impacts transcriptome diversity and highlights the potential sequelae of global DNA methylation inhibition as a cancer treatment. • DNA methylation regulates mRNA alternative cleavage and polyadenylation • CTCF binds unmethylated CpG islands downstream of proximal poly(A) sites • CTCF subsequently recruits cohesin complex to form chromatin loops • Chromatin loops promote usage of proximal poly(A) sites in vitro and in vivo The functions of DNA methylation outside of gene promoters are not fully understood. Nanavaty et al. found gene-body methylation to modulate transcriptome diversity through alternative cleavage and polyadenylation. In the absence of DNA methylation, CTCF and the cohesin complex orchestrate chromatin loop formation and promote proximal polyadenylation isoform expressions. [ABSTRACT FROM AUTHOR]

Published

2020

45. Ultrastructural Details of Mammalian Chromosome Architecture.

Author

Krietenstein, Nils, Abraham, Sameer, Venev, Sergey V., Abdennur, Nezar, Gibcus, Johan, Hsieh, Tsung-Han S., Parsi, Krishna Mohan, Yang, Liyan, Maehr, René, Mirny, Leonid A., Dekker, Job, and Rando, Oliver J.

Subjects

*CHROMOSOMES, *HUMAN chromosomes, *HUMAN gene mapping, *CHROMOSOME analysis, *GENE mapping, *BINDING sites

Abstract

Over the past decade, 3C-related methods have provided remarkable insights into chromosome folding in vivo. To overcome the limited resolution of prior studies, we extend a recently developed Hi-C variant, Micro-C, to map chromosome architecture at nucleosome resolution in human ESCs and fibroblasts. Micro-C robustly captures known features of chromosome folding including compartment organization, topologically associating domains, and interactions between CTCF binding sites. In addition, Micro-C provides a detailed map of nucleosome positions and localizes contact domain boundaries with nucleosomal precision. Compared to Hi-C, Micro-C exhibits an order of magnitude greater dynamic range, allowing the identification of ∼20,000 additional loops in each cell type. Many newly identified peaks are localized along extrusion stripes and form transitive grids, consistent with their anchors being pause sites impeding cohesin-dependent loop extrusion. Our analyses comprise the highest-resolution maps of chromosome folding in human cells to date, providing a valuable resource for studies of chromosome organization. • Micro-C provides nucleosome resolution maps of chromosome folding • The resolution and signal-to-noise are significantly improved relative to Hi-C • Thousands of new loops are identified, suggesting weak pauses to loop extrusion • New loops suggest TADs represent heterogeneous collections of transient loops Krietenstein et al. extend analyses of chromosome folding to nucleosome resolution in human cells. These ultra-deep Micro-C maps capture known features of chromosomes with improved signal-to-noise, identifying tens of thousands of new looping interactions. Newly identified loops reveal weak pause sites along cohesin extrusion tracks, providing insight into TAD structural heterogeneity. [ABSTRACT FROM AUTHOR]

Published

2020

46. 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

*CHROMATIN, *TRANSCRIPTION factors, *GENE silencing, *EPIGENOMICS, *HISTONES, *GENETIC regulation, *CHROMOSOMES, *STEM cells

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. • Micro-C resolves mammalian chromatin folding down to single nucleosomes • Nested structures are the prevalent folding feature within TADs • Transcription drives short-range interactions connecting enhancers and promoters • Only a subset of fine-scale structures appears to be CTCF- and cohesin-specific Hsieh et al. describe chromatin folding at single-nucleosome resolution in mammalian cells using Micro-C, an enhanced chromosome conformation capture method. Micro-C uncovers genome-wide, fine-scale chromatin organizational features shaped by gene activity, transcriptional regulation, and gene silencing. [ABSTRACT FROM AUTHOR]

Published

2020

47. TFIIIC Binding to Alu Elements Controls Gene Expression via Chromatin Looping and Histone Acetylation.

Author

Ferrari, Roberto, de Llobet Cucalon, Lara Isabel, Di Vona, Chiara, Le Dilly, François, Vidal, Enrique, Lioutas, Antonios, Oliete, Javier Quilez, Jochem, Laura, Cutts, Erin, Dieci, Giorgio, Vannini, Alessandro, Teichmann, Martin, de la Luna, Susana, and Beato, Miguel

Subjects

*HISTONE acetylation, *GENE expression, *HISTONES, *CHROMATIN, *HOMEOBOX proteins, *RNA polymerases, *TRANSCRIPTION factors

Abstract

How repetitive elements, epigenetic modifications, and architectural proteins interact ensuring proper genome expression remains poorly understood. Here, we report regulatory mechanisms unveiling a central role of Alu elements (AEs) and RNA polymerase III transcription factor C (TFIIIC) in structurally and functionally modulating the genome via chromatin looping and histone acetylation. Upon serum deprivation, a subset of AEs pre-marked by the activity-dependent neuroprotector homeobox Protein (ADNP) and located near cell-cycle genes recruits TFIIIC, which alters their chromatin accessibility by direct acetylation of histone H3 lysine-18 (H3K18). This facilitates the contacts of AEs with distant CTCF sites near promoter of other cell-cycle genes, which also become hyperacetylated at H3K18. These changes ensure basal transcription of cell-cycle genes and are critical for their re-activation upon serum re-exposure. Our study reveals how direct manipulation of the epigenetic state of AEs by a general transcription factor regulates 3D genome folding and expression. • Serum starvation recruits TFIIIC at ADNP-bound Alu Elements (AEs) near Pol II genes • TFIIIC-associated histone acetylase activity acetylates H3K18 over the bound AEs • TFIIIC-bound acetylated AEs loop to contact CTCF at distal cell-cycle genes' promoters • CTCF-TFIIIC interaction ensures rapid cell-cycle genes' reactivation on serum exposure Repetitive elements shape genome structure and function. Ferrari et al. find that cells respond to serum deprivation by redirecting the general transcription factor TFIIIC to acetylate ADNP-bound Alu elements in order to rewire the 3D genome architecture via CTCF looping, ultimately sustaining steady-state levels of cell-cycle-regulated gene expression. [ABSTRACT FROM AUTHOR]

Published

2020

48. The Transition from Quiescent to Activated States in Human Hematopoietic Stem Cells Is Governed by Dynamic 3D Genome Reorganization.

Author

Takayama N, Murison A, Takayanagi SI, Arlidge C, Zhou S, Garcia-Prat L, Chan-Seng-Yue M, Zandi S, Gan OI, Boutzen H, Kaufmann KB, Trotman-Grant A, Schoof E, Kron K, Díaz N, Lee JJY, Medina T, De Carvalho DD, Taylor MD, Vaquerizas JM, Xie SZ, Dick JE, and Lupien M

Subjects

Cell Differentiation, Cell Division, Hematopoiesis, Humans, Chromatin, Hematopoietic Stem Cells

Abstract

Lifelong blood production requires long-term hematopoietic stem cells (LT-HSCs), marked by stemness states involving quiescence and self-renewal, to transition into activated short-term HSCs (ST-HSCs) with reduced stemness. As few transcriptional changes underlie this transition, we used single-cell and bulk assay for transposase-accessible chromatin sequencing (ATAC-seq) on human HSCs and hematopoietic stem and progenitor cell (HSPC) subsets to uncover chromatin accessibility signatures, one including LT-HSCs (LT/HSPC signature) and another excluding LT-HSCs (activated HSPC [Act/HSPC] signature). These signatures inversely correlated during early hematopoietic commitment and differentiation. The Act/HSPC signature contains CCCTC-binding factor (CTCF) binding sites mediating 351 chromatin interactions engaged in ST-HSCs, but not LT-HSCs, enclosing multiple stemness pathway genes active in LT-HSCs and repressed in ST-HSCs. CTCF silencing derepressed stemness genes, restraining quiescent LT-HSCs from transitioning to activated ST-HSCs. Hence, 3D chromatin interactions centrally mediated by CTCF endow a gatekeeper function that governs the earliest fate transitions HSCs make by coordinating disparate stemness pathways linked to quiescence and self-renewal., Competing Interests: Declaration of Interests J.E.D. served on the SAB at Trillium Therapeutics, reports receiving a commercial research grant from Celgene, and has ownership interest (including patents) in Trillium Therapeutics., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2021

49. Distinct properties and functions of CTCF revealed by a rapidly inducible degron system.

Author

Luan J, Xiang G, Gómez-García PA, Tome JM, Zhang Z, Vermunt MW, Zhang H, Huang A, Keller CA, Giardine BM, Zhang Y, Lan Y, Lis JT, Lakadamyali M, Hardison RC, and Blobel GA

Subjects

Animals, Binding Sites, CCCTC-Binding Factor genetics, CRISPR-Cas Systems, Cell Line, Chromatin genetics, Chromatin Assembly and Disassembly, Gene Editing, Kinetics, Mice, Molecular Dynamics Simulation, Protein Binding, Proteolysis, RNA Polymerase II metabolism, Transcription, Genetic, CCCTC-Binding Factor metabolism, Chromatin metabolism, Chromatin Immunoprecipitation Sequencing, Erythroblasts metabolism, Single Molecule Imaging

Abstract

CCCTC-binding factor (CTCF) is a conserved zinc finger transcription factor implicated in a wide range of functions, including genome organization, transcription activation, and elongation. To explore the basis for CTCF functional diversity, we coupled an auxin-induced degron system with precision nuclear run-on. Unexpectedly, oriented CTCF motifs in gene bodies are associated with transcriptional stalling in a manner independent of bound CTCF. Moreover, CTCF at different binding sites (CBSs) displays highly variable resistance to degradation. Motif sequence does not significantly predict degradation behavior, but location at chromatin boundaries and chromatin loop anchors, as well as co-occupancy with cohesin, are associated with delayed degradation. Single-molecule tracking experiments link chromatin residence time to CTCF degradation kinetics, which has ramifications regarding architectural CTCF functions. Our study highlights the heterogeneity of CBSs, uncovers properties specific to architecturally important CBSs, and provides insights into the basic processes of genome organization and transcription regulation., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2021

50. CTCF Is Required for Neural Development and Stochastic Expression of Clustered Pcdh Genes in Neurons

Author

Teruyoshi Hirayama, Yumiko Yoshimura, Niels Galjart, Takeshi Yagi, Etsuko Tarusawa, and Cell biology

Subjects

CCCTC-Binding Factor, Neurogenesis, Hippocampus, Protocadherin, Nerve Tissue Proteins, Biology, General Biochemistry, Genetics and Molecular Biology, Mice, Conditional gene knockout, medicine, Animals, Protein Isoforms, lcsh:QH301-705.5, Genetics, Mice, Knockout, Cerebrum, Brain, Gene Expression Regulation, Developmental, Dendrites, Cadherins, Cell biology, Repressor Proteins, medicine.anatomical_structure, lcsh:Biology (General), nervous system, CTCF, Excitatory postsynaptic potential, Neuron, Neural development

Abstract

SummaryThe CCCTC-binding factor (CTCF) is a key molecule for chromatin conformational changes that promote cellular diversity, but nothing is known about its role in neurons. Here, we produced mice with a conditional knockout (cKO) of CTCF in postmitotic projection neurons, mostly in the dorsal telencephalon. The CTCF-cKO mice exhibited postnatal growth retardation and abnormal behavior and had defects in functional somatosensory mapping in the brain. In terms of gene expression, 390 transcripts were expressed at significantly different levels between CTCF-deficient and control cortex and hippocampus. In particular, the levels of 53 isoforms of the clustered protocadherin (Pcdh) genes, which are stochastically expressed in each neuron, declined markedly. Each CTCF-deficient neuron showed defects in dendritic arborization and spine density during brain development. Their excitatory postsynaptic currents showed normal amplitude but occurred with low frequency. Our results indicate that CTCF regulates functional neural development and neuronal diversity by controlling clustered Pcdh expression.

Published

2012