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Query: EC:2.7.7.6 (
RNA polymerase
)
34,946
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The oncogenic potential of latent Epstein-Barr virus (EBV) can be regulated by epigenetic factors controlling LMP1 and EBNA2 gene transcription. The EBV latency control region (LCR) constitutes approximately 12 kb of viral sequence spanning the divergent promoters of LMP1 and EBNA2 and encompasses the EBV latent replication origin OriP and
RNA polymerase III
-transcribed EBV-encoded RNA genes. We have used the chromatin immunoprecipitation assay to examine the chromatin architecture of the LCR in different types of EBV latency programs. We have found that histone H3 K4 methylation (H3mK4) was enriched throughout a large domain that extended from internal repeat 1 (IR1) to the terminal repeat in type III latency where EBNA2 and LMP1 genes are expressed. In type I latency where EBNA2 and LMP1 genes are transcriptionally silent, the H3mK4 domain contracts and does not enter the EBNA2 or LMP1 promoters. In contrast, histone H3 K9 methylation (H3mK9), associated with silent heterochromatin, was enriched in the EBNA2 and LMP1 upstream control regions in type I but not type III cells. MTA [5'-deoxy-5'(methylthio)adenosine], a pharmacological inhibitor of protein methylation, globally reduced histone H3mK4 and inhibited EBNA2 transcription in type III cells. 5'-Azacytidine, an inhibitor of DNA methylation that derepresses EBNA2 transcription in type I latency, caused H3mK4 expansion and a corresponding loss of H3mK9 at IR1. The chromatin boundary protein and transcription repressor
CCCTC-binding factor
was enriched at the EBNA2 transcription control region in type I but not type III cells. We also present evidence that OriP binding factors EBNA1 and ORC2 can interact with sequences outside of OriP including a region within IR1 that may influence EBNA2 transcription status. These results indicate that types I and III latency programs have distinct histone methylation patterns in the LCR and suggest that chromatin architecture coordinates gene expression of LMP1 and EBNA2.
...
PMID:Dynamic chromatin boundaries delineate a latency control region of Epstein-Barr virus. 1550 18
The 5'-HS4 chicken beta-globin insulator functions as a positional enhancer blocker on chromatinized episomes in human cells, blocking the HS2 enhancer of the human beta-globin locus control region from activating a downstream epsilon-globin gene. 5'-HS4 interrupted formation of a domain of histone H3 and H4 acetylation encompassing the 6-kb minilocus and inhibited transfer of
RNA polymerase
from the enhancer to the gene promoter. We found that the enhancer blocking phenotype was amplified when the insulated locus contained a weakened HS2 enhancer in which clustered point mutations eliminated interaction of the transcription factor GATA-1. The GATA-1 mutation compromised recruitment of histone acetyltransferases and
RNA polymerase II
to HS2. Enhancer blocking correlated with a significant depletion of nucleosomes in the core region of the insulator as revealed by micrococcal nuclease and DNase I digestion studies. Nucleosome depletion at 5'-HS4 was dependent on interaction of the insulator protein
CCCTC-binding factor
(
CTCF
) and was required for enhancer blocking. These findings provide evidence that a domain of active chromatin is formed by spreading from an enhancer to a target gene and can be blocked by a nucleosome-free gap in an insulator.
...
PMID:Enhancer blocking by chicken beta-globin 5'-HS4: role of enhancer strength and insulator nucleosome depletion. 1687 59
Genome-wide studies reveal that transcription by
RNA polymerase II
(Pol II) is dynamically regulated. To obtain a comprehensive view of a single transcription cycle, we switched on transcription of five long human genes (>100 kbp) with tumor necrosis factor-alpha (TNFalpha) and monitored (using microarrays, RNA fluorescence in situ hybridization, and chromatin immunoprecipitation) the appearance of nascent RNA, changes in binding of Pol II and two insulators (the cohesin subunit RAD21 and the
CCCTC-binding factor
CTCF), and modifications of histone H3. Activation triggers a wave of transcription that sweeps along the genes at approximately 3.1 kbp/min; splicing occurs cotranscriptionally, a major checkpoint acts several kilobases downstream of the transcription start site to regulate polymerase transit, and Pol II tends to stall at cohesin/CTCF binding sites.
...
PMID:A wave of nascent transcription on activated human genes. 1982 84
Recent studies have identified FKBP51 (FK506-binding protein 51) as a sensitive biomarker of corticosteroid responsiveness in vivo. In this work, we have elucidated the molecular mechanisms underlying the induction of FKBP51 by the glucocorticoid receptor (GR) in human A549 lung cancer cells showing robust accumulation of FKBP51 mRNA in response to dexamethasone exposure. Our quantitative chromatin immunoprecipitation scans and enhancer activity analyses indicate that activation of the FKBP51 locus by glucocorticoids in vivo is triggered by the loading of GR to enhancers at about 34 kb 5' and about 87 kb 3' of the transcription start site. Interestingly, the region encompassing these enhancers is bordered by
CCCTC-binding factor
- and cohesin-binding sites. Dexamethasone treatment also decreased the histone density at several regions of the gene, which was paralleled with the occupancy of SWI/SNF chromatin remodeling complexes within the locus. Moreover, silencing of BRM subunit of the SWI/SNF complex blunted the glucocorticoid induction of the locus. The proximal promoter region along with the major intronic enhancer at approximately 87 kb, at which the GR binding peaked, had elevated levels of histone 3 acetylation and H3K4 trimethylation, whereas H3K36 trimethylation more generally marked the gene body and reflected the occupancy of
RNA polymerase II
. The occurrence of these active chromatin marks within the FKBP51 locus before glucocorticoid exposure suggests that it is poised for transcription in A549 cells. Taken together, these results indicate that the holo-GR is capable of activating transcription and evoking changes in chromatin structure through distant-acting enhancers.
...
PMID:Glucocorticoid receptor activates poised FKBP51 locus through long-distance interactions. 2009 18
The p53 transcriptional program orchestrates alternative responses to stress, including cell cycle arrest and apoptosis, but the mechanism of cell fate choice upon p53 activation is not fully understood. Here we report that PUMA (p53 up-regulated modulator of apoptosis), a key mediator of p53-dependent cell death, is regulated by a noncanonical, gene-specific mechanism. Using chromatin immunoprecipitation assays, we found that the first half of the PUMA locus (approximately 6 kb) is constitutively occupied by
RNA polymerase II
and general transcription factors regardless of p53 activity. Using various RNA analyses, we found that this region is constitutively transcribed to generate a long unprocessed RNA with no known coding capacity. This permissive intragenic domain is constrained by sharp chromatin boundaries, as illustrated by histone marks of active transcription (histone H3 Lys9 trimethylation [H3K4me3] and H3K9 acetylation [H3K9Ac]) that precipitously transition into repressive marks (H3K9me3). Interestingly, the insulator protein CTCF (
CCCTC-binding factor
) and the Cohesin complex occupy these intragenic chromatin boundaries. CTCF knockdown leads to increased basal expression of PUMA concomitant with a reduction in chromatin boundary signatures. Importantly, derepression of PUMA upon CTCF depletion occurs without p53 activation or activation of other p53 target genes. Therefore, CTCF plays a pivotal role in dampening the p53 apoptotic response by acting as a gene-specific repressor.
...
PMID:Gene-specific repression of the p53 target gene PUMA via intragenic CTCF-Cohesin binding. 2058 71
Long-range DNA interactions play an important role in gene expression.
CCCTC-binding factor
(
CTCF
), a ubiquitously expressed and evolutionarily conserved 11-zinc-finger DNA binding protein, is intimately involved in gene regulation, helping to establish and maintain chromatin architecture and long-range DNA interactions. In order to study the effects of manipulating long range chromatin interactions in the regulation of the neurofibromatosis gene NF1, we targeted Zorro locked nucleic acids (Zorro LNA) to a single
CTCF
binding site at an NF1 locus in human fibroblast cells. Using chromatin immunoprecipitation, we determined that this Zorro LNA altered
CTCF
and
RNA polymerase II
binding at three separate and distinct regions in the NF1 gene. This change in protein binding was associated with changes in long-range DNA interactions at the NF1 locus and downregulation of NF1 gene expression. This study describes an efficient and convenient method to manipulate chromatin structure and alter gene expression that is regulated by long-range DNA interactions without changing the DNA sequence. The use of specific Zorro LNA probes may facilitate our efforts to understand the interactions between chromatin architecture and gene expression.
...
PMID:Long-range DNA interactions are specifically altered by locked nucleic acid-targeting of a CTCF binding site. 2111 Oct 75
One of the most outstanding nuclear factors, which has chromatin insulator and transcriptional properties and also contribute to genomic organization, is the zinc-finger protein
CCCTC-binding factor
(
CTCF
). Among its multiple functions, a growing amount of evidence implicates
CTCF
in the epigenetic regulation of genes responsible for the control of the cell cycle, and its mis-regulation can lead to aberrant epigenetic silencing of genes involved in cancer development. Detailed studies are now revealing that
CTCF
can serve as a barrier against the spread of DNA methylation and histone repressive marks over promoter regions of tumor suppressor genes. Moreover, new evidences points out to the capacity of
CTCF
to be covalently modified, in particular, through poly(ADP-ribosyl)ation with regulatory consequences. An unexplored aspect of
CTCF
is its intergenic and intragenic distribution in certain loci. Such distribution seems to facilitate the formation of an optimal chromatin structure and the recruitment of chromatin remodelers with the possible incorporation of
RNA polymerase II
. Therefore, in the context of tumor suppressor genes and cancer development,
CTCF
appears to play a relevant role by incorporating a combination of mechanisms involved in the protection against epigenetic silencing components and the maintenance of optimal higher-order organization of the corresponding loci.
...
PMID:Insulation of tumor suppressor genes by the nuclear factor CTCF. 2184 16
Alternative splicing of pre-messenger RNA is a key feature of transcriptome expansion in eukaryotic cells, yet its regulation is poorly understood. Spliceosome assembly occurs co-transcriptionally, raising the possibility that DNA structure may directly influence alternative splicing. Supporting such an association, recent reports have identified distinct histone methylation patterns, elevated nucleosome occupancy and enriched DNA methylation at exons relative to introns. Moreover, the rate of transcription elongation has been linked to alternative splicing. Here we provide the first evidence that a DNA-binding protein,
CCCTC-binding factor
(
CTCF
), can promote inclusion of weak upstream exons by mediating local
RNA polymerase II
pausing both in a mammalian model system for alternative splicing, CD45, and genome-wide. We further show that
CTCF
binding to CD45 exon 5 is inhibited by DNA methylation, leading to reciprocal effects on exon 5 inclusion. These findings provide a mechanistic basis for developmental regulation of splicing outcome through heritable epigenetic marks.
...
PMID:CTCF-promoted RNA polymerase II pausing links DNA methylation to splicing. 2196 34
RNA polymerase III
(Pol III) transcription is regulated by modifications of the chromatin. DNA methylation and post-translational modifications of histones, such as acetylation, phosphorylation and methylation have been linked to Pol III transcriptional activity. In addition to being regulated by modifications of DNA and histones, Pol III genes and its transcription factors have been implicated in the organization of nuclear chromatin in several organisms. In yeast, the ability of the Pol III transcription system to contribute to nuclear organization seems to be dependent on direct interactions of Pol III genes and/or its transcription factors TFIIIC and TFIIIB with the structural maintenance of chromatin (SMC) protein-containing complexes cohesin and condensin. In human cells, Pol III genes and transcription factors have also been shown to colocalize with cohesin and the transcription regulator and genome organizer
CCCTC-binding factor
(
CTCF
). Furthermore, chromosomal sites have been identified in yeast and humans that are bound by partial Pol III machineries (extra TFIIIC sites - ETC; chromosome organizing clamps - COC). These ETCs/COC as well as Pol III genes possess the ability to act as boundary elements that restrict spreading of heterochromatin.
...
PMID:RNA polymerase III transcription - regulated by chromatin structure and regulator of nuclear chromatin organization. 2315 Feb 55
CCCTC-binding factor
(
CTCF
) has been implicated in various aspects of viral and host chromatin organization and transcriptional control. We showed previously that
CTCF
binds to a cluster of three sites in the first intron of the Kaposi's sarcoma-associated herpesvirus (KSHV) multicistronic latency-associated transcript that encodes latency-associated nuclear antigen (LANA), viral cyclin (vCyclin), vFLIP, viral microRNAs, and kaposin. We show here that these
CTCF
binding sites regulate mRNA production,
RNA polymerase II
(RNAPII) programming, and nucleosome organization of the KSHV latency transcript control region. We also show that KSHV bacmids lacking these
CTCF
binding sites have elevated and altered ratios of spliced latency transcripts.
CTCF
binding site mutations altered RNAPII and RNAPII-accessory factor interactions with the latency control region.
CTCF
binding sites were required for the in vitro recruitment of RNAPII to the latency control region, suggesting that direct interactions between
CTCF
and RNAPII contribute to transcription regulation. Histone modifications in the latency control region were also altered by mutations in the
CTCF
binding sites. Finally, we show that
CTCF
binding alters the regular phasing of nucleosomes in the latency gene transcript and intron, suggesting that nucleosome positioning can be an underlying biochemical mechanism of
CTCF
function. We propose that RNAPII interactions and nucleosome displacement serve as a biochemical basis for programming RNAPII in the KSHV transcriptional control region.
...
PMID:CTCF regulates Kaposi's sarcoma-associated herpesvirus latency transcription by nucleosome displacement and RNA polymerase programming. 2319 70
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