scholarly journals NSD2 overexpression drives clustered chromatin and transcriptional changes in a subset of insulated domains

2019 ◽  
Author(s):  
Priscillia Lhoumaud ◽  
Sana Badri ◽  
Javier Rodriguez Hernaez ◽  
Theodore Sakellaropoulos ◽  
Gunjan Sethia ◽  
...  
Keyword(s):  
Gene Regulation ◽  
Ctcf Binding ◽  
Ctcf Binding Site ◽  
Chromatin Modifications ◽  
3D Genome ◽  
Bidirectional Relationship ◽  
Oncogene Activation ◽  
Transcriptional Changes ◽  
Low Levels ◽  
Gene Sharing

AbstractCTCF and cohesin play a key role in organizing chromatin into TAD structures. Disruption of a single CTCF binding site is sufficient to change chromosomal interactions leading to alterations in chromatin modifications and gene regulation. However, the extent to which alterations in chromatin modifications can disrupt 3D chromosome organization leading to transcriptional changes is unknown. In multiple myeloma a 4;14 translocation induces overexpression of the histone methyltransferase, NSD2 resulting in expansion of H3K36me2 and shrinkage of antagonistic H3K27me3 domains. Using isogenic cell lines producing high and low levels of NSD2, we find oncogene activation is linked to alterations in H3K27ac and CTCF within H3K36me2 enriched chromatin. A linear regression model reveals that changes in both CTCF and/or H3K27ac significantly increase the probability that a gene sharing the same insulated domain will be differentially expressed. These results identify a bidirectional relationship between 2D chromatin and 3D genome organization in gene regulation.

scholarly journals NSD2 overexpression drives clustered chromatin and transcriptional changes in a subset of insulated domains

2019 ◽  
Vol 10 (1) ◽  
Author(s):  
Priscillia Lhoumaud ◽  
Sana Badri ◽  
Javier Rodriguez-Hernaez ◽  
Theodore Sakellaropoulos ◽  
Gunjan Sethia ◽  
...  
Keyword(s):  
Gene Regulation ◽  
Ctcf Binding ◽  
Ctcf Binding Site ◽  
Chromatin Modifications ◽  
3D Genome ◽  
Topologically Associating Domain ◽  
Bidirectional Relationship ◽  
Oncogene Activation ◽  
Transcriptional Changes ◽  
Low Levels

Abstract CTCF and cohesin play a key role in organizing chromatin into topologically associating domain (TAD) structures. Disruption of a single CTCF binding site is sufficient to change chromosomal interactions leading to alterations in chromatin modifications and gene regulation. However, the extent to which alterations in chromatin modifications can disrupt 3D chromosome organization leading to transcriptional changes is unknown. In multiple myeloma, a 4;14 translocation induces overexpression of the histone methyltransferase, NSD2, resulting in expansion of H3K36me2 and shrinkage of antagonistic H3K27me3 domains. Using isogenic cell lines producing high and low levels of NSD2, here we find oncogene activation is linked to alterations in H3K27ac and CTCF within H3K36me2 enriched chromatin. A logistic regression model reveals that differentially expressed genes are significantly enriched within the same insulated domain as altered H3K27ac and CTCF peaks. These results identify a bidirectional relationship between 2D chromatin and 3D genome organization in gene regulation.

scholarly journals Determining cellular CTCF and cohesin abundances to constrain 3D genome models

eLife ◽  
2019 ◽  
Vol 8 ◽  
Author(s):  
Claudia Cattoglio ◽  
Iryna Pustova ◽  
Nike Walther ◽  
Jaclyn J Ho ◽  
Merle Hantsche-Grininger ◽  
...  
Keyword(s):  
Mammalian Cells ◽  
Site Occupancy ◽  
Cellular Protein ◽  
Protein Quantification ◽  
Ctcf Binding ◽  
Ctcf Binding Site ◽  
3D Genome ◽  
Quantitative Measurements ◽  
Dna Loop ◽  
Predictive Understanding

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

scholarly journals Transposable elements strongly contribute to cell-specific and species-specific looping diversity in mammalian genomes

2019 ◽  
Author(s):  
Adam G Diehl ◽  
Ningxin Ouyang ◽  
Alan P Boyle
Keyword(s):  
Transposable Elements ◽  
Large Fraction ◽  
Population Level ◽  
Cell Types ◽  
Ctcf Binding ◽  
Ctcf Binding Site ◽  
3D Genome ◽  
Chromatin Looping ◽  
Mammalian Genomes ◽  
Species Specific

AbstractBackgroundChromatin looping is exceedingly important to gene regulation and a host of other nuclear processes. Many recent insights into 3D chromatin structure across species and cell types have contributed to our understanding of the principles governing chromatin looping. However, 3D genome evolution and how it relates to Mendelian selection remain largely unexplored. CTCF, an insulator protein found at most loop anchors, has been described as the “master weaver” of mammalian genomes, and variations in CTCF occupancy are known to influence looping divergence. A large fraction of mammalian CTCF binding sites fall within transposable elements (TEs) but their contributions to looping variation are unknown. Here we investigated the effect of TE-driven CTCF binding site expansions on chromatin looping in human and mouse.ResultsTEs have broadly contributed to CTCF binding and loop boundary specification, primarily forming variable loops across species and cell types and contributing nearly 1/3 of species-specific and cell-specific loops.ConclusionsOur results demonstrate that TE activity is a major source of looping variability across species and cell types. Thus, TE-mediated CTCF expansions explain a large fraction of population-level looping variation and may play a role in adaptive evolution.

scholarly journals Determining cellular CTCF and cohesin abundances to constrain 3D genome models

2018 ◽  
Author(s):  
Claudia Cattoglio ◽  
Iryna Pustova ◽  
Nike Walther ◽  
Jaclyn J. Ho ◽  
Merle Hantsche-Grininger ◽  
...  
Keyword(s):  
Mammalian Cells ◽  
Site Occupancy ◽  
Cellular Protein ◽  
Protein Quantification ◽  
Ctcf Binding ◽  
Ctcf Binding Site ◽  
3D Genome ◽  
Quantitative Measurements ◽  
Dna Loop ◽  
Predictive Understanding

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

scholarly journals Co-opted transposons help perpetuate conserved higher-order chromosomal structures

2018 ◽  
Author(s):  
Mayank NK Choudhary ◽  
Ryan Z Friedman ◽  
Julia T Wang ◽  
Hyo Sik Jang ◽  
Xiaoyu Zhuo ◽  
...  
Keyword(s):  
Transposable Elements ◽  
Binding Site ◽  
Ctcf Binding ◽  
Ctcf Binding Site ◽  
Genome Architecture ◽  
3D Genome ◽  
Domain Structures ◽  
Architectural Proteins ◽  
Mammalian Genomes ◽  
Species Specific

ABSTRACTTransposable elements (TEs) make up half of mammalian genomes and shape genome regulation by harboring binding sites for regulatory factors. These include architectural proteins—such as CTCF, RAD21 and SMC3—that are involved in tethering chromatin loops and marking domain boundaries. The 3D organization of the mammalian genome is intimately linked to its function and is remarkably conserved. However, the mechanisms by which these structural intricacies emerge and evolve have not been thoroughly probed. Here we show that TEs contribute extensively to both the formation of species-specific loops in humans and mice via deposition of novel anchoring motifs, as well as to the maintenance of conserved loops across both species via CTCF binding site turnover. The latter function demonstrates the ability of TEs to contribute to genome plasticity and reinforce conserved genome architecture as redundant loop anchors. Deleting such candidate TEs in human cells leads to a collapse of such conserved loop and domain structures. These TEs are also marked by reduced DNA methylation and bear mutational signatures of hypomethylation through evolutionary time. TEs have long been considered a source of genetic innovation; by examining their contribution to genome topology, we show that TEs can contribute to regulatory plasticity by inducing redundancy and potentiating genetic drift locally while conserving genome architecture globally, revealing a paradigm for defining regulatory conservation in the noncoding genome beyond classic sequence-level conservation.One-sentence summaryCo-option of transposable elements maintains conserved 3D genome structures via CTCF binding site turnover in human and mouse.

scholarly journals CRISPRi screens reveal a DNA methylation-mediated 3D genome dependent causal mechanism in prostate cancer

2021 ◽  
Vol 12 (1) ◽  
Author(s):  
Musaddeque Ahmed ◽  
Fraser Soares ◽  
Ji-Han Xia ◽  
Yue Yang ◽  
Jing Li ◽  
...  
Keyword(s):  
Prostate Cancer ◽  
Dna Methylation ◽  
Cell Proliferation ◽  
Cell Line ◽  
Regulatory Elements ◽  
Ctcf Binding ◽  
Ctcf Binding Site ◽  
Causal Mechanism ◽  
3D Genome ◽  
Risk Snps

AbstractProstate cancer (PCa) risk-associated SNPs are enriched in noncoding cis-regulatory elements (rCREs), yet their modi operandi and clinical impact remain elusive. Here, we perform CRISPRi screens of 260 rCREs in PCa cell lines. We find that rCREs harboring high risk SNPs are more essential for cell proliferation and H3K27ac occupancy is a strong indicator of essentiality. We also show that cell-line-specific essential rCREs are enriched in the 8q24.21 region, with the rs11986220-containing rCRE regulating MYC and PVT1 expression, cell proliferation and tumorigenesis in a cell-line-specific manner, depending on DNA methylation-orchestrated occupancy of a CTCF binding site in between this rCRE and the MYC promoter. We demonstrate that CTCF deposition at this site as measured by DNA methylation level is highly variable in prostate specimens, and observe the MYC eQTL in the 8q24.21 locus in individuals with low CTCF binding. Together our findings highlight a causal mechanism synergistically driven by a risk SNP and DNA methylation-mediated 3D genome architecture, advocating for the integration of genetics and epigenetics in assessing risks conferred by genetic predispositions.

scholarly journals Spontaneous HTLV-1 transcription is accompanied by distinct epigenetic changes in the 5′ and 3′ long terminal repeats

2018 ◽  
Vol 3 ◽  
pp. 105 ◽  
Author(s):  
Michi Miura ◽  
Paola Miyazato ◽  
Yorifumi Satou ◽  
Yuetsu Tanaka ◽  
Charles R.M. Bangham
Keyword(s):  
Histone Modifications ◽  
Insertion Site ◽  
Rapid Change ◽  
Epigenetic Modifications ◽  
The Body ◽  
Ctcf Binding ◽  
Ctcf Binding Site ◽  
Long Terminal Repeats ◽  
Terminal Repeats ◽  
The Impact

Background:The human retrovirus HTLV-1 inserts the viral complementary DNA of 9 kb into the host genome. Both plus- and minus-strands of the provirus are transcribed, respectively from the 5′ and 3′ long terminal repeats (LTR). Plus-strand expression is rapid and intense once activated, whereas the minus-strand is transcribed at a lower, more constant level. To identify how HTLV-1 transcription is regulated, we investigated the epigenetic modifications associated with the onset of spontaneous plus-strand expression and the potential impact of the host factor CTCF.Methods:Patient-derived peripheral blood mononuclear cells (PBMCs) and in vitro HTLV-1-infected T cell clones were examined. Cells were stained for the plus-strand-encoded viral protein Tax, and sorted into Tax+and Tax–populations. Chromatin immunoprecipitation and methylated DNA immunoprecipitation were performed to identify epigenetic modifications in the provirus. Bisulfite-treated DNA fragments from the HTLV-1 LTRs were sequenced. Single-molecule RNA-FISH was performed, targeting HTLV-1 transcripts, for the estimation of transcription kinetics. The CRISPR/Cas9 technique was applied to alter the CTCF-binding site in the provirus, to test the impact of CTCF on the epigenetic modifications.Results:Changes in the histone modifications H3K4me3, H3K9Ac and H3K27Ac were strongly correlated with plus-strand expression. DNA in the body of the provirus was largely methylated except for the pX and 3′ LTR regions, regardless of Tax expression. The plus-strand promoter was hypomethylated when Tax was expressed. Removal of CTCF had no discernible impact on the viral transcription or epigenetic modifications.Conclusions:The histone modifications H3K4me3, H3K9Ac and H3K27Ac are highly dynamic in the HTLV-1 provirus: they show rapid change with the onset of Tax expression, and are reversible. The HTLV-1 provirus has an intrinsic pattern of epigenetic modifications that is independent of both the provirus insertion site and the chromatin architectural protein CTCF which binds to the HTLV-1 provirus.

scholarly journals 3'HS1 CTCF binding site in human β-globin locus regulates fetal hemoglobin expression

2021 ◽  
Author(s):  
Pamela Himadewi ◽  
Xue Qing David Wang ◽  
Fan Feng ◽  
Haley Gore ◽  
Yushuai Liu ◽  
...  
Keyword(s):  
Binding Site ◽  
Progenitor Cells ◽  
Globin Gene ◽  
Fetal Hemoglobin ◽  
Ctcf Binding ◽  
Ctcf Binding Site ◽  
Distal Enhancer ◽  
Erythroid Progenitor ◽  
Hematopoietic Stem ◽  
Ctcf Site

Mutations in the adult β-globin gene can lead to a variety of hemoglobinopathies, including sickle cell disease and β-thalassemia. An increase in fetal hemoglobin expression throughout adulthood, a condition named Hereditary Persistence of Fetal Hemoglobin (HPFH), has been found to ameliorate hemoglobinopathies. Deletional HPFH occurs through the excision of a significant portion of the 3 prime end of the β-globin locus, including a CTCF binding site termed 3'HS1. Here, we show that the deletion of this CTCF site alone induces fetal hemoglobin expression in both adult CD34+ hematopoietic stem and progenitor cells and HUDEP-2 erythroid progenitor cells. This induction is driven by the ectopic access of a previously postulated distal enhancer located in the OR52A1 gene downstream of the locus, which can also be insulated by the inversion of the 3'HS1 CTCF site. This suggests that genetic editing of this binding site can have therapeutic implications to treat hemoglobinopathies.

scholarly journals Repeat elements organize 3D genome structure and mediate transcription in the filamentous fungusEpichloë festucae

2018 ◽  
Author(s):  
David J Winter ◽  
Austen RD Ganley ◽  
Carolyn A Young ◽  
Ivan Liachko ◽  
Christopher L Schardl ◽  
...  
Keyword(s):  
Genome Structure ◽  
Regulation Of Gene Expression ◽  
Three Dimensional ◽  
Structural Features ◽  
Dimensional Structure ◽  
In Planta ◽  
Repeat Elements ◽  
Symbiotic Relationships ◽  
3D Genome ◽  
Transcriptional Changes

AbstractStructural features of genomes, including the three-dimensional arrangement of DNA in the nucleus, are increasingly seen as key contributors to the regulation of gene expression. However, studies on how genome structure and nuclear organization influence transcription have so far been limited to a handful of model species. This narrow focus limits our ability to draw general conclusions about the ways in which three-dimensional structures are encoded, and to integrate information from three-dimensional data to address a broader gamut of biological questions. Here, we generate a complete and gapless genome sequence for the filamentous fungus,Epichloë festucae. Coupling it with RNAseq and HiC data, we investigate how the structure of the genome contributes to the suite of transcriptional changes that anEpichloëspecies needs to maintain symbiotic relationships with its grass host. Our results reveal a unique “patchwork” genome, in which repeat-rich blocks of DNA with discrete boundaries are interspersed by gene-rich sequences. In contrast to other species, the three-dimensional structure of the genome is anchored by these repeat blocks, which act to isolate transcription in neighbouring gene-rich regions. Genes that are differentially expressed in planta are enriched near the boundaries of these repeat-rich blocks, suggesting that their three-dimensional orientation partly encodes and regulates the symbiotic relationship formed by this organism.

CTCF, a conserved nuclear factor required for optimal transcriptional activity of the chicken c-myc gene, is an 11-Zn-finger protein differentially expressed in multiple forms

1993 ◽  
Vol 13 (12) ◽  
pp. 7612-7624
Author(s):  
E M Klenova ◽  
R H Nicolas ◽  
H F Paterson ◽  
A F Carne ◽  
C M Heath ◽  
...  
Keyword(s):  
Dna Binding ◽  
Cell Lines ◽  
Gene Promoter ◽  
Differentially Expressed ◽  
Ctcf Binding ◽  
Ctcf Binding Site ◽  
Mobility Shift ◽  
Chicken Cell ◽  
Nuclear Extracts ◽  
Myc Gene

A novel sequence-specific DNA-binding protein, CTCF, which interacts with the chicken c-myc gene promoter, has been identified and partially characterized (V. V. Lobanenkov, R. H. Nicolas, V. V. Adler, H. Paterson, E. M. Klenova, A. V. Polotskaja, and G. H. Goodwin, Oncogene 5:1743-1753, 1990). In order to test directly whether binding of CTCF to one specific DNA region of the c-myc promoter is important for chicken c-myc transcription, we have determined which nucleotides within this GC-rich region are responsible for recognition of overlapping sites by CTCF and Sp1-like proteins. Using missing-contact analysis of all four nucleotides in both DNA strands and homogeneous CTCF protein purified by sequence-specific chromatography, we have identified three sets of nucleotides which contact either CTCF or two Sp1-like proteins binding within the same DNA region. Specific mutations of 3 of 15 purines required for CTCF binding were designed to eliminate binding of CTCF without altering the binding of other proteins. Electrophoretic mobility shift assay of nuclear extracts showed that the mutant DNA sequence did not bind CTCF but did bind two Sp1-like proteins. When introduced into a 3.3-kbp-long 5'-flanking noncoding c-myc sequence fused to a reporter CAT gene, the same mutation of the CTCF binding site resulted in 10- and 3-fold reductions, respectively, of transcription in two different (erythroid and myeloid) stably transfected chicken cell lines. Isolation and analysis of the CTCF cDNA encoding an 82-kDa form of CTCF protein shows that DNA-binding domain of CTCF is composed of 11 Zn fingers: 10 are of C2H2 class, and 1 is of C2HC class. CTCF was found to be abundant and conserved in cells of vertebrate species. We detected six major nuclear forms of CTCF protein differentially expressed in different chicken cell lines and tissues. We conclude that isoforms of 11-Zn-finger factor CTCF which are present in chicken hematopoietic HD3 and BM2 cells can act as a positive regulator of the chicken c-myc gene transcription. Possible functions of other CTCF forms are discussed.

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