Human β-Globin Locus Control Region HS5Contains CTCF- and Developmental Stage-Dependent Enhancer-BlockingActivity in ErythroidCells

Tanimoto, Koichi; Sugiura, Akiko; Omori, Akane; Felsenfeld, Gary; Engel, James Douglas; Fukamizu, Akiyoshi

doi:10.1128/mcb.23.24.8946-8952.2003

Cited by 52 publications

(51 citation statements)

References 38 publications

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“…Ectopic HS5 reduced globin gene transcription at all stages of mouse development as determined by RT-qPCR (Fig. S2), substantially recapitulating earlier work using semiquantitative PCR (20). Deletion of the HS5 CTCF site restored ␥-and ␤-globin expression, although it had little effect on -globin expression.…”

Section: Resultssupporting

confidence: 68%

“…We investigated the insulator function of HS5 in mice carrying a single copy of a complete ␤-globin locus transgene with a copy of HS5 placed between the LCR and -globin, containing either an intact (HS5) or mutated CTCF site (⌬CTCF) or no HS5 (WT) (Fig. 1A) (20). CTCF occupies endogenous HS5 and 3ЈHS1 sites flanking the mouse and human ␤-globin loci in vivo (14, 21).…”

Section: Resultsmentioning

confidence: 99%

“…Earlier studies suggested that human HS5 could function as a transcriptional enhancer-blocker when placed between the LCR and the globin genes on a transgene (20). We used this system to investigate the mechanism underlying enhancer-blocking.…”

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confidence: 99%

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CTCF-dependent enhancer-blocking by alternative chromatin loop formation

Hou

Zhao

Tanimoto

et al. 2008

Proc. Natl. Acad. Sci. U.S.A.

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The mechanism underlying enhancer-blocking by insulators is unclear. We explored the activity of human ␤-globin HS5, the orthologue of the CTCF-dependent chicken HS4 insulator. An extra copy of HS5 placed between the ␤-globin locus control region (LCR) and downstream genes on a transgene fulfills the classic predictions for an enhancer-blocker. Ectopic HS5 does not perturb the LCR but blocks gene activation by interfering with RNA pol II, activator and coactivator recruitment, and epigenetic modification at the downstream ␤-globin gene. Underlying these effects, ectopic HS5 disrupts chromatin loop formation between ␤-globin and the LCR, and instead forms a new loop with endogenous HS5 that topologically isolates the LCR. Both enhancer-blocking and insulatorloop formation depend on an intact CTCF site in ectopic HS5 and are sensitive to knock-down of the CTCF protein by siRNA. Thus, intrinsic looping activity of CTCF sites can nullify LCR function.beta-globin genes ͉ insulator ͉ locus control region ͉ epigenetics ͉ transcription regulation C hromatin insulators are thought to establish domains within which proper enhancer-gene interactions occur: these domains can be visualized in Drosophila cells where a protein complex including Su(Hw) forms loops that tether gypsy insulators to the nuclear lamina (1, 2). Insulators can also interfere with enhancer-gene interaction when placed between the two elements, but the molecular mechanisms underlying enhancerblocking are not well understood.In vertebrates, the protein CTCF is associated with enhancerblocking (3). On maternal chromosomes, the CTCF-dependent imprinting control region (ICR) in the Igf2/H19 locus is thought to form a small loop with a second site, DMR1, upstream of Igf2 that includes Igf2 and restricts access to the gene by enhancers it shares with H19 (4, 5). Because detection of CTCF at DMR1 is dependent on its interaction at ICR, it is not clear whether CTCF or other proteins interact at DMR1 and participate in the long-range interactions. Other data indicate the ICR directly contacts Igf2 and the enhancers (6), suggesting that a complex series of chromosomal interactions may be involved in enhancerblocking at this locus. CTCF also mediates the enhancerblocking activity of the chicken ␤-globin insulator, 5ЈHS4, which forms the upstream border of the globin locus (7). Although a prediction (8), enhancer-blocking through loop formation by interacting CTCF insulator sites has not been demonstrated.Locus control regions (LCRs) are complex enhancers that activate genes over long distances through their ability to establish close contacts with target promoters (9). For example, the ␤-globin LCR and active globin genes come into proximity to form a chromatin loop in erythroid cells (10, 11), an interaction that requires the erythroid factors GATA-1 and erythroid Kruppel-like factor (EKLF) (12, 13). The human ␤-globin LCR is composed of four DNase I hypersensitive sites, HS1 to HS4, far upstream of the structural genes. HS5, 3-Kb upstream of HS4, is more widely ...

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Section: Resultssupporting

confidence: 68%

Section: Resultsmentioning

confidence: 99%

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CTCF-dependent enhancer-blocking by alternative chromatin loop formation

Hou

Zhao

Tanimoto

et al. 2008

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

195

142

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“…However, their specific binding sites on the ␤-globin locus have not been determined. The role of a boundary element in controlling the spread of the heterochromatin from an upstream end of the ␤-globin LCR is well studied (3,4,35,36), but so far the isolation of any chromatin opening activity of the LCR has proved elusive. Here, we describe the structural and functional properties of a biochemically purified ␤-globin LARC.…”

Section: Discussionmentioning

confidence: 99%

“…Of these seven HS sites, the first four, HS1, HS2, HS3, and HS4, are erythroid specific (1). HS5 is present in several hematopoietic lineages and is suggested to possess insulator activity (3)(4)(5), and HS6 and HS7 are present in a variety of cell types.…”

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confidence: 99%

Heterogeneous nuclear ribonucleoprotein C1/C2, MeCP1, and SWI/SNF form a chromatin remodeling complex at the β-globin locus control region

Mahajan

Narlikar

Boyapaty

et al. 2005

Proc. Natl. Acad. Sci. U.S.A.

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Locus control regions (LCRs) are regulatory DNA sequences that are situated many kilobases away from their cognate promoters. LCRs protect transgenes from position effect variegation and heterochromatinization and also promote copy-number dependence of the levels of transgene expression. In this work, we describe the biochemical purification of a previously undescribed LCR-associated remodeling complex (LARC) that consists of heterogeneous nuclear ribonucleoprotein C1͞C2, nucleosome remodeling SWI͞ SNF, and nucleosome remodeling and deacetylating (NuRD)͞ MeCP1 as a single homogeneous complex. LARC binds to the hypersensitive 2 (HS2)-Maf recognition element (MARE) DNA in a sequence-specific manner and remodels nucleosomes. Heterogeneous nuclear ribonucleoprotein C1͞C2, previously known as a general RNA binding protein, provides a sequence-specific DNA recognition element for LARC, and the LARC DNA-recognition sequence is essential for the enhancement of transcription by HS2. Independently of the initiation of transcription, LARC becomes associated with ␤-like globin promoters.NuRD͞MeCP1 ͉ HS2

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Three‐Dimensional Architecture of Genomes

Dekker

2011

Genome Organization and Function in the Cell Nucleus

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Human β-Globin Locus Control Region HS5Contains CTCF- and Developmental Stage-Dependent Enhancer-BlockingActivity in ErythroidCells

Cited by 52 publications

References 38 publications

CTCF-dependent enhancer-blocking by alternative chromatin loop formation

CTCF-dependent enhancer-blocking by alternative chromatin loop formation

Heterogeneous nuclear ribonucleoprotein C1/C2, MeCP1, and SWI/SNF form a chromatin remodeling complex at the β-globin locus control region

Three‐Dimensional Architecture of Genomes

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