组蛋白乙酰化／脱乙酰化与DNA甲基化的关系

组蛋白乙酰化和脱乙酰化与DNA甲基化有密切的关系,本文介绍了DNA甲基化对组蛋白乙酰化／脱乙酰化影响,组蛋白乙酰化／脱乙酰化对DNA甲基化的影响,以及组蛋白乙酰化／脱乙酰化和DNA甲基化协同效应。     

Histone H4 acetylation and DNA methylation dynamics during pollen development

Summary The first pollen mitosis results in generative and vegetative cells which are characterised by a striking difference in their chromatin structure. In this study, histone H4 acetylation and DNA methylation have been analysed during pollen development inLilium longiflorum. Indirect immunofluorescence procedures followed by epifluorescence and laser scanning microscopy enabled a relative quantification of H4 acetylation and DNA methylation in microspores, immature binucleate pollen, mature pollen, and pollen tubes. The results show that histone H4 of the vegetative nucleus, in spite of its decondensed chromatin structure, is strongly hypoacetylated at lysine positions 5 and 8 in comparison with both the original microspore nucleus and the generative-cell nucleus. These H4 terminal lysines in the vegetative nucleus are, however, progressively acetylated during the following pollen tube growth. The DNA methylation analysis inversely correlates with the histone acetylation data. The vegetative nucleus in mature pollen grains is heavily methylated, but a dramatic nonreplicative demethylation occurs during the pollen tube development. Changes neither in H4 acetylation nor in DNA methylation have been found during development of the generative nucleus. The results obtained indicate that the vegetative nucleus enters the quiescent state (accompanied by DNA hypermethylation and H4 underacetylation) during the maturation of pollen grain which enables pollen grains a long-term survival without external source of nutrients until they reach the stigma.     

DNA methylation, histone H3 methylation, and histone H4 acetylation in the genome of a crustacean.

In this work, we used antibodies against histone H3 trimethylated at lysine 9 (H3K9m3); against histone H4 acetylated at lysines 5, 8, 12, and 16 (H4ac); and against DNA methylated at 5C cytosine (m5C) to study the presence and distribution of these markers in the genome of the isopod crustacean Asellus aquaticus. The use of these 3 antibodies to immunolabel spermatogonial metaphases yields reproducible patterns on the chromosomes of this crustacean. The X and Y chromosomes present an identical banding pattern with each of the antibodies. The heterochromatic telomeric regions and the centromeric regions are rich in H3K9m3, but depleted in m5C and H4ac. Thus, m5C does not seem to be required to stabilize the silence of these regions in this organism.     

Cross-talk between histone modifications in response to histone deacetylase inhibitors: MLL4 links histone H3 acetylation and histone H3K4 methylation

Histones are subject to a wide variety of post-translational modifications that play a central role in gene activation and silencing. We have used histone modification-specific antibodies to demonstrate that two histone modifications involved in gene activation, histone H3 acetylation and H3 lysine 4 methylation, are functionally linked. This interaction, in which the extent of histone H3 acetylation determines both the abundance and the "degree" of H3K4 methylation, plays a major role in the epigenetic response to histone deacetylase inhibitors. A combination of in vivo knockdown experiments and in vitro methyltransferase assays shows that the abundance of H3K4 methylation is regulated by the activities of two opposing enzyme activities, the methyltransferase MLL4, which is stimulated by acetylated substrates, and a novel and as yet unidentified H3K4me3 demethylase.     

Histone H4 acetylation dynamics determined by stable isotope labeling with amino acids in cell culture and mass spectrometry

This paper describes an integrated approach that couples stable isotope labeling with amino acids in cell culture to acetic acid-urea polyacrylamide gel electrophoresis (AU-PAGE) and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) for the quantitation and dynamics of histone H4 acetylation. The 697 acute lymphoblastic cell lines were grown in regular medium and in medium in which lysine was substituted with deuterium-labeled lysine. Histone deacetylase (HDAC) activity was inhibited by addition of the HDAC inhibitor depsipeptide to the culture medium for different exposure times. Histones were extracted from cells pooled from unlabeled, untreated cells and from labeled, treated cells, followed by AU-PAGE separation. Gel bands corresponding to different acetylation states of H4 were excised, in-gel digested with trypsin, and analyzed by MALDI-TOF MS. Detailed information was obtained for both the change of histone H4 acetylation specific to the N terminus and the global transformation of H4 from one acetylation state to another following treatment with the HDAC inhibitor depsipeptide. The kinetics of H4 acetylation was also assessed. This study provides a quantitative basis for developing potential therapies by using epigenetic regulation and the developed methodology can be applied to quantitation of change for other histone modifications induced by external stimuli.     

Characterization of phosphorylation sites on histone H1 isoforms by tandem mass spectrometry

Histone H1 isoforms isolated from asynchronously grown HeLa cells were subjected to enzymatic digestion and analyzed by nano-flow reversed-phase high performance liquid chromatography (RP-HPLC) tandem mass spectrometry (MS/MS) on both quadrupole ion trap and linear quadrupole ion trap-Fourier transform ion cyclotron resonance mass spectrometers. We have observed all five major isoforms of histone H1 (H1.1, H1.2, H1.3, H1.4, and H1.5) as well as a lesser studied H1, isoform H1.X. MS/MS experiments confirmed N-terminal acetylation on all isoforms plus a single internal acetylation site. Immobilized metal affinity chromatography in combination with tandem mass spectrometry was utilized to identify 19 phosphorylation sites on the five major H1 isoforms plus H1.X. Fourteen of these phosphorylation sites were located on peptides containing the cyclin dependent kinase (CDK) consensus motif (S/T)-P-X-Z (where X is any amino acid and Z is a basic amino acid). Five phosphorylation sites were identified in regions that did not fit the consensus CDK motif. One of these phosphorylation sites was found on the serine residue on the H1.4 peptide KARKSAGAAKR. The adjacent lysine residue to the phosphoserine was also shown to be methylated. This finding raises the question of whether the hypothesized "methyl/phos" switch could be extended to linker histones, and not exclusive to core histones.     

Identification of five sites of acetylation in alfalfa histone H4.

Radioactive acetylation in vivo of plant histone H4 of alfalfa, Arabidopsis, tobacco, and carrot revealed five distinct forms of radioactive, acetylated histone. In histone H4 of eukaryotes ranging from fungi to man, acetylation is restricted to four lysines (residues 5, 8, 12, and 16) possibly caused by a quantitative methylation of lysine-20. Chemical and proteolytic fragmentation of the amino terminally blocked alfalfa H4 protein, dynamically acetylated by radioactive acetate in vivo, allowed protein sequencing and identification of selected peptides. Peptide identification was facilitated by analyzing fully characterized calf histone H4 in parallel. Acetylation in vivo of alfalfa histone H4 was restricted to the lysines in the amino-terminal domain of the protein, residues 1-23. Lysine-20 was shown to be free of methylation, as in pea histone H4. This apparently makes lysine-20 accessible as a novel target for histone acetylation. The in vivo pattern of lysine acetylation (16 greater than 12 greater than 8 greater than or equal to 5 = 20) revealed a preference for lysines -16 and -12 without an apparent strict sequential specificity of acetylation.     

Histone H3-K56 acetylation is catalyzed by histone chaperone-dependent complexes

Acetylation of histone H3 on lysine 56 occurs during mitotic and meiotic S phase in fungal species. This acetylation blocks a direct electrostatic interaction between histone H3 and nucleosomal DNA, and the absence of this modification is associated with extreme sensitivity to genotoxic agents. We show here that H3-K56 acetylation is catalyzed when Rtt109, a protein that lacks significant homology to known acetyltransferases, forms an active complex with either of two histone binding proteins, Asf1 or Vps75. Rtt109 binds to both these cofactors, but not to histones alone, forming enzyme complexes with kinetic parameters similar to those of known histone acetyltransferase (HAT) enzymes. Therefore, H3-K56 acetylation is catalyzed by a previously unknown mechanism that requires a complex of two proteins: Rtt109 and a histone chaperone. Additionally, these complexes are functionally distinct, with the Rtt109/Asf1 complex, but not the Rtt109/Vps75 complex, being critical for resistance to genotoxic agents.     

Histone H4 acetylation in human cells. Frequency of acetylation at different sites defined by immunolabeling with site-specific antibodies

Histone H4 can be reversibly acetylated at lysine residues 5, 8, 12 and 16. It is possible that acetylation of individual residues will exert specific effects on chromatin function, but this hypothesis is difficult to test with present techniques for analysis of acetylation. To address this problem, we have prepared antibodies which distinguish H4 molecules acetylated at each of the sites used in vivo. By electrophoresis and immunolabeling we have shown that, in H4 from human cells, the four lysine residues are acetylated in a preferred, but not exclusive order, namely lysine 16, followed by 12 and 8, followed by 5.     

Histone H4 from cuttlefish testis is sequentially acetylated. Comparison with acetylation of calf thymus histone H4

The differently acetylated subfractions of histone H4 isolated from cuttlefish testis and from calf thymus were separated by ion exchange chromatography on sulfopropyl-Sephadex, using a shallow linear gradient of guanidine hydrochloride in the presence of 6 M urea at pH 3.0. The tetra-, tri-, di-, mono-, and nonacetylated forms of cuttlefish H4 represent 2, 6.4, 18, 32.2, and 41.4% of the whole histone, respectively. The di-, mono-, and nonacetylated forms of calf H4 represent 11.7, 41.3, and 44% of the whole histone, respectively. The acetylation sites were determined in each subfraction by identification of the acetylated peptides. In each acetylated H4 subfraction, the acetylated tryptic peptides were identified by peptide mapping and amino acid analysis with reference to the peptide map of nonacetylated H4. In cuttlefish testis H4, lysine 12 is the main site of acetylation in the monoacetylated subfraction; lysines 5 and 12 are found acetylated in diacetylated H4; lysines 5, 12, and 16 are found acetylated in triacetylated H4. From these results and the stoichiometry of the different H4 subfractions, it can be concluded that lysine 5 is acetylated after lysine 12. In calf thymus, lysine 16 is the only site of acetylation in the monoacetylated subfraction. All the diacetylated forms are acetylated in lysine 16, the second site of acetylation being, in decreasing order, lysine 12, lysine 5, or lysine 8. These observations suggest that acetylation occurs in a sequential manner. Moreover, the sites of acetylation depend upon the biological event in which acetylation is involved.