EC:2.7.7.6 - FACTA Search

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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)

Histone-like nucleoid structuring protein (H-NS) is a modular protein that is associated with the bacterial nucleoid. We used chromatin immunoprecipitation to determine the binding sites of H-NS and RNA polymerase on the Salmonella enterica serovar Typhimurium chromosome. We found that H-NS does not bind to actively transcribed genes and does not co-localize with RNA polymerase. This shows that H-NS principally silences gene expression by restricting the access of RNA polymerase to the DNA. H-NS had previously been shown to preferentially bind to curved DNA in vitro. In fact, at the genomic level we discovered that the level of H-NS binding correlates better with the AT-content of DNA. This is likely to have evolutionary consequences because we show that H-NS binds to many Salmonella genes acquired by lateral gene transfer, and functions as a gene silencer. The removal of H-NS from the cell causes un-controlled expression of several Salmonella pathogenicity islands, and we demonstrate that this has deleterious consequences for bacterial fitness. Our discovery of this novel role for H-NS may have implications for the acquisition of foreign genes by enteric bacteria.
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PMID:H-NS mediates the silencing of laterally acquired genes in bacteria. 1693 88

During mammalian hibernation, metabolic rate can be reduced to <5% of the euthermic rate as a result of coordinated suppression of multiple energy expensive metabolic processes. Gene transcription is one of these and the present study examines mechanisms of transcriptional control that could contribute to lowering the rate of gene expression in torpor. Histone deacetylases (HDAC) have been linked to gene silencing and measured HDAC activity was 1.82-fold higher in skeletal muscle of hibernating thirteen-lined ground squirrels, Spermophilus tridecemlineatus, compared with euthermic controls. Western blotting also showed that HDAC1 and HDAC4 protein levels were 1.21-and 1.48-fold higher, respectively, in muscle from torpid animals. Histone H3 was also evaluated by Western blotting. Total histone H3 was unchanged but two forms of covalently modified histone H3 that are associated with active transcription (phosphorylated Ser 10 and acetylated Lys 23) were significantly reduced by 38-39% in muscle during hibernation. Finally, RNA polymerase II activity was measured using a PCR-based approach; activity in muscle from hibernating squirrels was only 57% of the euthermic value. These data support an overall decrease in transcriptional activity in skeletal muscle of hibernating animals that is accomplished by multiple molecular mechanisms.
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PMID:Evidence for a reduced transcriptional state during hibernation in ground squirrels. 1697 17

Mouse Grb10 is a tissue-specific imprinted gene with promoter-specific expression. In most tissues, Grb10 is expressed exclusively from the major-type promoter of the maternal allele, whereas in the brain, it is expressed predominantly from the brain type promoter of the paternal allele. Such reciprocally imprinted expression in the brain and other tissues is thought to be regulated by DNA methylation and the Polycomb group (PcG) protein Eed. To investigate how DNA methylation and chromatin remodeling by PcG proteins coordinate tissue-specific imprinting of Grb10, we analyzed epigenetic modifications associated with Grb10 expression in cultured brain cells. Reverse transcriptase PCR analysis revealed that the imprinted paternal expression of Grb10 in the brain implied neuron-specific and developmental stage-specific expression from the paternal brain type promoter, whereas in glial cells and fibroblasts, Grb10 was reciprocally expressed from the maternal major-type promoter. The cell-specific imprinted expression was not directly related to allele-specific DNA methylation in the promoters because the major-type promoter remained biallelically hypomethylated regardless of its activity, whereas gametic DNA methylation in the brain type promoter was maintained during differentiation. Histone modification analysis showed that allelic methylation of histone H3 lysine 4 and H3 lysine 9 were associated with gametic DNA methylation in the brain type promoter, whereas that of H3 lysine 27 regulated by the Eed PcG complex was detected in the paternal major-type promoter, corresponding to its allele-specific silencing. Here, we propose a molecular model that gametic DNA methylation and chromatin remodeling by PcG proteins during cell differentiation cause tissue-specific imprinting in embryonic tissues.
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PMID:Role of DNA methylation and histone H3 lysine 27 methylation in tissue-specific imprinting of mouse Grb10. 1710 88

Histone lysine acetylation is a major mechanism by which cells regulate the structure and function of chromatin, and new sites of acetylation continue to be discovered. Here we identify and characterize histone H3K36 acetylation (H3K36ac). By mass spectrometric analyses of H3 purified from Tetrahymena thermophila and Saccharomyces cerevisiae (yeast), we find that H3K36 can be acetylated or methylated. Using an antibody specific to H3K36ac, we show that this modification is conserved in mammals. In yeast, genome-wide ChIP-chip experiments show that H3K36ac is localized predominantly to the promoters of RNA polymerase II-transcribed genes, a pattern inversely related to that of H3K36 methylation. The pattern of H3K36ac localization is similar to that of other sites of H3 acetylation, including H3K9ac and H3K14ac. Using histone acetyltransferase complexes purified from yeast, we show that the Gcn5-containing SAGA complex that regulates transcription specifically acetylates H3K36 in vitro. Deletion of GCN5 completely abolishes H3K36ac in vivo. These data expand our knowledge of the genomic targets of Gcn5, show H3K36ac is highly conserved, and raise the intriguing possibility that the transition between H3K36ac and H3K36me acts as an "acetyl/methyl switch" governing chromatin function along transcription units.
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PMID:Identification of histone H3 lysine 36 acetylation as a highly conserved histone modification. 1718 64

Histone acetylation is a highly dynamic posttranslational modification that plays an important role in gene expression. Previous work showed that promoter histone deacetylation is accompanied by progesterone receptor (PR)-mediated activation of the mouse mammary tumor virus (MMTV) promoter. We investigated the role of this deacetylation and found that this histone deacetylation is not a singular event. In fact, histone acetylation at the MMTV promoter is highly dynamic, with an initial increase in acetylation followed by an eventual net deacetylation of histone H4. The timing of increase in acetylation of H4 coincides with the time at which PR, RNA polymerase II, and histone acetyltransferases cAMP response element-binding protein (CREB)-binding protein and p300 are recruited to the MMTV promoter. The timing in which histone H4 deacetylation occurs (after PR and RNA polymerase II recruitment) and the limited effect that trichostatin A and small interfering RNA knockdown of histone deacetylase (HDAC)3 have on MMTV transcription suggests that this deacetylation activity is not required for the initiation of PR-mediated transcription. Interestingly, two HDACs, HDAC1 and HDAC3, are already present at the MMTV before transcription activation. HDAC association at the MMTV promoter fluctuates during the hormone treatment. In particular, HDAC3 is temporarily undetected at the MMTV promoter within minutes after hormone treatment when the histone H4 acetylation increases but returns to the promoter near the time when histone acetylation levels start to decline. These results demonstrate the dynamic nature of coactivator/corepressor-promoter association and histone modifications such as acetylation during a transcription activation event.
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PMID:Dynamic histone acetylation/deacetylation with progesterone receptor-mediated transcription. 1722 84

Histone acetyltransferases are associated with the elongating RNA polymerase II (Pol II) complex, supporting the idea that histone acetylation and transcription are intertwined mechanistically in gene coding sequences. Here, we studied the establishment and function of histone acetylation and transcription in noncoding sequences by using a model locus linking the beta-globin HS2 enhancer and the embryonic epsilon-globin gene in chromatin. An intact HS2 enhancer that recruits RNA Pol II is required for intergenic transcription and histone H3 acetylation and K4 methylation between the enhancer and target gene. RNA Pol II recruitment to the target gene TATA box is not required for the intergenic transcription or intergenic histone modifications, strongly implying that they are properties conferred by the enhancer. However, Pol II recruitment at HS2, intergenic transcription, and intergenic histone modification are not sufficient for transcription or modification of the target gene: these changes require initiation at the TATA box of the gene. The results suggest that intergenic and genic transcription complexes are independent and possibly differ from one another.
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PMID:Beta-globin intergenic transcription and histone acetylation dependent on an enhancer. 1728 48

The packaging of the eukaryotic genome into chromatin severely restricts the access of the transcriptional machinery to the DNA. Recent studies reveal that histones are removed and replaced to enable or restrict, respectively, access of the transcription machinery to regulate transcription. Chromatin disassembly at promoters enables transcriptional activation, whereas promoter chromatin reassembly represses transcription. Histone loss also occurs within transcription units to enable passage of the RNA polymerase, but in this case the histones are rapidly replaced, sometimes by 'variant' histones with specific properties that might serve as a memory of transcriptional competence. Furthermore, the ultimate goal of some epigenetic modifications might well turn out to be the regulation of histone occupancy on the DNA.
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PMID:Transcriptional regulation by chromatin disassembly and reassembly. 1730 51

Epigenetics is defined as mitotically and meiotically heritable changes in gene expression that do not involve a change in the DNA sequence. Two major areas of epigenetics-DNA methylation and histone modifications-are known to have profound effects on controlling gene expression. DNA methylation is involved in normal cellular control of expression, and aberrant hypermethylation can lead to silencing of tumor-suppressor genes in carcinogenesis. Histone modifications control the accessibility of the chromatin and transcriptional activities inside a cell. MicroRNAs (miRNAs) are small RNA molecules, approximately 22 nucleotides long that can negatively control their target gene expression posttranscriptionally. There are currently more than 460 human miRNAs known, and the total number is predicted to be much larger. Recently, the expression of miRNAs has been definitively linked to cancer development, and miRNA profiles can be used to classify human cancers. miRNAs are encoded in our genome and are generally transcribed by RNA polymerase II. Despite the growing evidence for their importance in normal physiology, little is known about the regulation of miRNA expression. In this review, we will examine the relationship between miRNAs and epigenetics. We examine the effects of miRNAs on epigenetic machinery, and the control of miRNA expression by epigenetic mechanisms. Epigenetics is defined as heritable changes in gene expression that do not involve a change in DNA sequence.
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PMID:Epigenetics and microRNAs. 1741 52

Noncoding, or intergenic, transcription by RNA polymerase II (RNAPII) is remarkably widespread in eukaryotic organisms, but the effects of such transcription remain poorly understood. Here we show that noncoding transcription plays a role in activation, but not repression, of the Saccharomyces cerevisiae PHO5 gene. Histone eviction from the PHO5 promoter during activation occurs with normal kinetics even in the absence of the PHO5 TATA box, showing that transcription of the gene itself is not required for promoter remodeling. Nevertheless, we find that mutations that impair transcript elongation by RNAPII affect the kinetics of histone eviction from the PHO5 promoter. Most dramatically, inactivation of RNAPII itself abolishes eviction completely. Under repressing conditions, an approximately 2.4-kb noncoding exosome-degraded transcript is detected that originates near the PHO5 termination site and is transcribed in the antisense direction. Abrogation of this transcript delays chromatin remodeling and subsequent RNAPII recruitment to PHO5 upon activation. We propose that noncoding transcription through positioned nucleosomes can enhance chromatin plasticity so that chromatin remodeling and activation of traversed genes occur in a timely manner.
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PMID:A role for noncoding transcription in activation of the yeast PHO5 gene. 1747 Aug 1

Histone modifications are implicated in influencing gene expression. We have generated high-resolution maps for the genome-wide distribution of 20 histone lysine and arginine methylations as well as histone variant H2A.Z, RNA polymerase II, and the insulator binding protein CTCF across the human genome using the Solexa 1G sequencing technology. Typical patterns of histone methylations exhibited at promoters, insulators, enhancers, and transcribed regions are identified. The monomethylations of H3K27, H3K9, H4K20, H3K79, and H2BK5 are all linked to gene activation, whereas trimethylations of H3K27, H3K9, and H3K79 are linked to repression. H2A.Z associates with functional regulatory elements, and CTCF marks boundaries of histone methylation domains. Chromosome banding patterns are correlated with unique patterns of histone modifications. Chromosome breakpoints detected in T cell cancers frequently reside in chromatin regions associated with H3K4 methylations. Our data provide new insights into the function of histone methylation and chromatin organization in genome function.
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PMID:High-resolution profiling of histone methylations in the human genome. 1804 24

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