Control of gene expression and assembly of chromosomal subdomains by chromatin regulators with antagonistic functions

Lam, Ai Leen; Pazin, Dorothy E.; Sullivan, Beth A.

doi:10.1007/s00412-005-0001-0

Cited by 27 publications

(18 citation statements)

References 61 publications

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“…Many epigenetic modifications are known to occur in active and repressed chromatin regions (for review, see Jenuwein and Allis 2001;Felsenfeld and Groudine 2003;Peterson and Laniel 2004;Lam et al 2005;Margueron et al 2005;Martin and Zhang 2005), and many of these modifications are known to occur at important regulatory elements, e.g., the high levels of histone acetylation that are found at gene promoters and at many enhancers. Some of these modifications are known to be associated with active chromatin, including acetylation of histone H3 on lysines 9 and 14 and methylation on lysines 4, 36, and 79, while other modifications, including methylation of histone H3 on lysines 9 and 27, are linked with repressive chromatin environments, although recent data have shown an overlap of active and repressive modifications in distinct chromatin subpopulations (Bernstein et al 2006;Roh et al 2006).…”

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confidence: 99%

Genome-wide prediction of conserved and nonconserved enhancers by histone acetylation patterns

Roh

Wei²,

Farrell³

et al. 2006

Genome Res.

116

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Comparative genomic studies have been useful in identifying transcriptional regulatory elements in higher eukaryotic genomes, but many important regulatory elements cannot be detected by such analyses due to evolutionary variations and alignment tool limitations. Therefore, in this study we exploit the highly conserved nature of epigenetic modifications to identify potential transcriptional enhancers. By using a high-resolution genome-wide mapping technique, which combines the chromatin immunoprecipitation and serial analysis of gene expression assays, we have recently determined the distribution of lysine 9/14-diacetylated histone H3 in human T cells. We showed the existence of 46,813 regions with clusters of histone acetylation, termed histone acetylation islands, some of which correspond to known transcriptional regulatory elements. In the present study, we find that 4679 sequences conserved between human and pufferfish coincide with histone acetylation islands, and random sampling shows that 33% (13/39) of these can function as transcriptional enhancers in human Jurkat T cells. In addition, by comparing the human histone acetylation island sequences with mouse genome sequences, we find that despite the conservation of many of these regions between these species, 21,855 of these sequences are not conserved. Furthermore, we demonstrate that about 50% (26/51) of these nonconserved sequences have enhancer activity in Jurkat cells, and that many of the orthologous mouse sequences also have enhancer activity in addition to conserved epigenetic modification patterns in mouse T-cell chromatin. Therefore, by combining epigenetic modification and sequence data, we have established a novel genome-wide method for identifying regulatory elements not discernable by comparative genomics alone.

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confidence: 99%

Genome-wide prediction of conserved and nonconserved enhancers by histone acetylation patterns

Roh

Wei²,

Farrell³

et al. 2006

Genome Res.

116

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“…10 Mechanistically, both agents bind a central zinc atom in HDAC to produce hyperacetylation of histone H3 (H3) and H4 28,29 to activate gene transcription. 30,31 We previously proposed a dual mechanism for ␥-globin gene activation by HDACIs involving (1) hyperacetylation of histone tails to produce open chromatin configurations and (2) transcription factor binding. 16 We expanded our investigations to identify the effector molecules involved in ␥-globin trans-activation by NaB and TSA via p38 MAPK signaling.…”

Section: Introductionmentioning

confidence: 99%

Mechanism for fetal hemoglobin induction by histone deacetylase inhibitors involves γ-globin activation by CREB1 and ATF-2

Sangerman

Lee

Xiao

et al. 2006

Blood

105

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The histone deacetylase inhibitors (HDACIs) butyrate and trichostatin A activate ␥-globin expression via a p38 mitogenactivating protein kinase (MAPK)-dependent mechanism. We hypothesized that downstream effectors of p38 MAPK, namely activating transcription factor-2 (ATF-2) and cyclic AMP response element (CRE) binding protein (CREB), are intimately involved in fetal hemoglobin induction by these agents. In this study, we observed increased ATF-2 and CREB1 phosphorylation mediated by the HDACIs in K562 cells, in conjunction with histone H4 hyperacetylation. Moreover, enhanced DNAprotein interactions occurred in the CRE in the G ␥-globin promoter (G-CRE) in vitro after drug treatments; subsequent chromatin immunoprecipitation assay confirmed ATF-2 and CREB1 binding to the G-CRE in vivo. Enforced expression of ATF-2 and CREB produced G ␥-promoter IntroductionThe growth factor erythropoietin (Epo) exerts its effects on commitment, proliferation, and differentiation of erythroid progenitors and globin chain synthesis through Janus kinase 2/Stat5 signaling and crosstalk with mitogen-activated protein kinase (MAPK) pathways. 1-3 p38 MAPK signaling is required for Epo mRNA stability and hemoglobin synthesis. 4,5 The reversible inhibition of p38 MAPK using SB203580 blocked Epo-dependent accumulation of mouse globin chains, 6 and studies in p38␣ Ϫ/Ϫ knockout mice showed a failure of definitive ␤ maj -globin gene expression. These studies confirm an Epo-p38 MAPK-dependent mechanism for hemoglobin synthesis. 7 The HDACI sodium butyrate (NaB) induces differentiation in erythroleukemia cells via Stat5 8,9 and p38 MAPK signaling. 10,11 Butyrate is a clinically useful fetal hemoglobin (HbF) inducer which has been used to treat individuals with sickle cell disease 12 and thalassemia 13 ; however, the molecular mechanism for NaB-mediated HbF induction is poorly understood. Recent data from Weinberg et al 14 showed that HbF induction by arginine butyrate is due in part to posttranslational mechanisms and increased ␥-globin mRNAtranslation.Several HDACIs, including trichostatin A (TSA), 10, and scriptaid,15,16 induce ␥-globin expression via p38 MAPK signaling. These studies suggest that different pharmacologic agents converge on the p38 MAPK pathway to activate ␥-globin expression. Four major MAPK pathways have been characterized: ERK1/2, ERK5/BMK1, cJun amino-terminal signal kinases (JNK), and p38. [17][18][19][20] Studies using erythroid progenitors, 21,22 knockout mice, 7 and K562 stable lines 10 suggest that p38␣ is the primary mediator of globin gene regulation.The downstream effector molecules of p38 MAPK signaling include MAPK-activated protein kinases 1 and 2, 23,24 PRAK, 25 ATF-1-4, CREB1, CREB2, and CREM. 26,27 Commonly, p38 phosphorylates ATF-2 and CREB to augment gene transcription. We recently demonstrated a p38 MAPK-dependent mechanism for NaB and TSA-induced ␥-globin expression. 10 Mechanistically, both agents bind a central zinc atom in HDAC to produce hyperacetylation of histone H3 (H3) and H4 28,29 to activate...

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“…These modifications form an epigenetic pattern along the genome, or "histone code" [80], and provide binding sites for specific proteins that in turn induce alterations in chromatin structure and gene expression. Acetylation of lysine residues in histones is generally linked with open chromatin and active transcription, whereas methylation of lysine and arginine residues of histones is associated with either chromatin activation or silencing depending on methylation sites [81].…”

Section: Mapping Of Chromatin Regions Containing Modified Histonesmentioning

confidence: 99%

Maps of cis-Regulatory Nodes in Megabase Long Genome Segments are an Inevitable Intermediate Step Toward Whole Genome Functional Mapping

Николаев

Akopov²,

Чернов³

2007

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Abstract:The availability of complete human and other metazoan genome sequences has greatly facilitated positioning and analysis of various genomic functional elements, with initial emphasis on coding sequences. However, complete functional maps of sequenced eukaryotic genomes should include also positions of all non-coding regulatory elements. Unfortunately, experimental data on genomic positions of a multitude of regulatory sequences, such as enhancers, silencers, insulators, transcription terminators, and replication origins are very limited, especially at the whole genome level. Since most genomic regulatory elements (e.g. enhancers) are generally gene-, tissue-, or cell-specific, the prediction of these elements by computational methods is difficult and often ambiguous. Therefore, the development of high-throughput experimental approaches for identifying and mapping genomic functional elements is highly desirable. At the same time, the creation of whole-genome map of hundreds of thousands of regulatory elements in several hundreds of tissue/cell types is presently far beyond our capabilities. A possible alternative for the whole genome approach is to concentrate efforts on individual genomic segments and then to integrate the data obtained into a whole genome functional map. Moreover, the maps of polygenic fragments with functional cis-regulatory elements would provide valuable data on complex regulatory systems, including their variability and evolution. Here, we reviewed experimental approaches to the realization of these ideas, including our own developments of experimental techniques for selection of cis-acting functionally active DNA fragments from large (megabase-sized) segments of mammalian genomes.

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Control of gene expression and assembly of chromosomal subdomains by chromatin regulators with antagonistic functions

Cited by 27 publications

References 61 publications

Genome-wide prediction of conserved and nonconserved enhancers by histone acetylation patterns

Genome-wide prediction of conserved and nonconserved enhancers by histone acetylation patterns

Mechanism for fetal hemoglobin induction by histone deacetylase inhibitors involves γ-globin activation by CREB1 and ATF-2

Maps of cis-Regulatory Nodes in Megabase Long Genome Segments are an Inevitable Intermediate Step Toward Whole Genome Functional Mapping

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