Histone acetyltransferases and histone deacetylases of Physarum polycephalum

DEAE-Sepharose chromatography of plasmodial extracts of the myxomycete Physarum polycephalum reveals the presence of multiple histone acetyltransferases and histone deacetylases. Five putative histone acetyltransferases and histone deacetylases. Five putative histone acetyltransferase forms with different substrate specificity can be discriminated: one enzyme which acetylates all core histones and four enzymes with a preference for each of H3, H2A, H2B or H4. Two histone deacetylases, HD1 and HD2, can be discriminated. They differ with respect to substrate specificity and pH-dependence. The substrate specificity of histone deacetylases is determined using HPLC-purified individual core histone species. The order of acetylated substrate preference is H2A>>H3≥H4> H2B for HD1, H3>H2A>H4 for HD2, respectively; HD2 is inactive with H2B as substrate.     

Histone acetylation in Zea mays.I. Activities of histone acetyltransferases and histone deacetylases

DEAE-Sepharose chromatography of extracts from Zea mays meristematic cells revealed multiple histone acetyltransferase and histone deacetylase enzyme forms. An improved method for nuclear isolation allowed us to discriminate nuclear and cytoplasmic enzymes. Two nuclear histone acetyltransferases, A1 and A2, a cytoplasmic B-enzyme and two nuclear histone deacetylases, HD1 and HD2, have been identified. The histone specificity of the different enzyme forms has been studied in an in vitro system, using chicken erythrocyte histones as substrate. The cytoplasmic histone acetyltransferase B is the predominant enzyme, which acetylates mainly histone H4 and to a lesser extent H2A. The nuclear histone acetyltransferase A1 preferentially acetylates H3 and also H4, whereas enzyme A2 is specific for H3. This substrate specificity was confirmed with homologous Z. mays histones. The two histone deacetylases differ from each other with respect to ionic strength dependence, inhibition by acetate and butyrate, and substrate specificity. The strong inhibitory effect of acetate on histone deacetylases was exploited to distinguish different histone acetyltransferase forms.     

Histone acetyltransferases and histone deacetyl transferases play crucial role during oogenesis and early embryo development

Dynamic epigenetic regulation is critical for proper oogenesis and early embryo development. During oogenesis, fully grown germinal vesicle oocytes develop to mature Metaphase II oocytes which are ready for fertilization. Fertilized oocyte proliferates mitotically until blastocyst formation and the process is called early embryo development. Throughout oogenesis and early embryo development, spatio-temporal gene expression takes place, and this dynamic gene expression is controlled with the aid of epigenetics. Epigenetic means that gene expression can be altered without changing DNA itself. Epigenome is regulated through DNA methylation and histone modifications. While DNA methylation generally ends up with repression of gene expression, histone modifications can result in expression or repression depending on type of modification, type of histone protein and its specific residue. One of the modifications is histone acetylation which generally ends up with gene expression. Histone acetylation occurs through the addition of acetyl group onto amino terminal of the core histone proteins by histone acetyltransferases (HATs). Contrarily, histone deacetylation is associated with repression of gene expression, and it is catalyzed by histone deacetylases (HDACs). This review article focuses on what is known about alterations in the expression of HATs and HDACs and emphasizes importance of HATs and HDACs during oogenesis and early embryo development.     

The MYST histone acetyltransferases are essential for gametophyte development in Arabidopsis

Background  

Histone acetyltransferases (HATs) play critical roles in the regulation of chromatin structure and gene expression. Arabidopsis genome contains 12 HAT genes, but the biological functions of many of them are still unknown. In this work, we studied the evolutionary relationship and cellular functions of the two Arabidopsis HAT genes homologous to the MYST family members.     

Structure of histone acetyltransferases

Histone acetyltranferase (HAT) enzymes are the catalytic subunits of multisubunit protein complexes that acetylate specific lysine residues on the N-terminal regions of the histone components of chromatin to promote gene activation. These enzymes, which now include more than 20 members, fall into distinct families that generally have high sequence similarity and related substrate specificity within families, but have divergent sequence and substrate specificity between families. Significant insights into the mode of catalysis and histone substrate binding have been provided by the structure determination of the divergent HAT enzymes Hat1, Gcn5/PCAF and Esa1. A comparison of these structures reveals a structurally conserved central core domain that mediates extensive interactions with the acetyl-coenzyme A cofactor, and structurally divergent N and C-terminal domains. A correlation of these structures with other studies reveals that the core domain plays a particularly important role in histone substrate catalysis and that the N and C-terminal domains play important roles in histone substrate binding. These correlations imply a related mode of catalysis and histone substrate binding by a diverse group of HAT enzymes.     

Histone acetylation in gene regulation.

Genetic information is packaged in the highly dynamic nucleoprotein structure called chromatin. Many biological processes are regulated via post-translational modifications of key proteins. Acetylation of lysine residues at the N-terminal histone tails is one of the most studied covalent modifications influencing gene regulation in eukaryotic cells. This review focuses on the role of enzymes involved in controlling both histone and non-histone proteins acetylation levels in the cell, with particular emphasis on their effects on cancer.     

组蛋白乙酰转移酶的研究进展

组蛋白乙酰化与基因转录等生物效应有密切的关系,组蛋白乙酰化主要是由组蛋白乙酰转移酶催化的。 要介绍了基因转录有关组蛋白乙酰转移酶,包括ＨＡＴＡ／Ｇｃｎ５ｐ、ｐ３００／ＣＢＰ、ｐ／ＣＡＦ、ＡＣＴＲ、Ｓｒｃ１、ＴＡＦ Ⅱ ２５０、Ｅｌｐ３等的来源,与其相互作用的蛋白质及其主要功能。     

Genetic regulation of gene expression during shoot development in Arabidopsis

The genetic control of gene expression during shoot development in Arabidopsis thaliana was analyzed by combining quantitative trait loci (QTL) and microarray analysis. Using oligonucleotide array data from 30 recombinant inbred lines derived from a cross of Columbia and Landsberg erecta ecotypes, the Arabidopsis genome was scanned for marker-by-gene linkages or so-called expression QTL (eQTL). Single-feature polymorphisms (SFPs) associated with sequence disparities between ecotypes were purged from the data. SFPs may alter the hybridization efficiency between cDNAs from one ecotype with probes of another ecotype. In genome scans, five eQTL hot spots were found with significant marker-by-gene linkages. Two of the hot spots coincided with classical QTL conditioning shoot regeneration, suggesting that some of the heritable gene expression changes observed in this study are related to differences in shoot regeneration efficiency between ecotypes. Some of the most significant eQTL, particularly those at the shoot regeneration QTL sites, tended to show cis-chromosomal linkages in that the target genes were located at or near markers to which their expression was linked. However, many linkages of lesser significance showed expected "trans-effects," whereby a marker affects the expression of a target gene located elsewhere on the genome. Some of these eQTL were significantly linked to numerous genes throughout the genome, suggesting the occurrence of large groups of coregulated genes controlled by single markers.