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

Make your best BET: The emerging role of BET inhibitor treatment in malignant tumors

Bromodomains are protein-protein interaction modules with a great diversity in terms of number of proteins and their function. The bromodomain and extraterminal protein (BET) represents a distinct subclass of bromodomain proteins mainly involved in transcriptional regulation via their interaction with acetylated chromatin. In cancer cells BET proteins are found to be altered in many ways such as overexpression, mutations and fusions of BET proteins or their interference with cancer relevant signaling pathways and transcriptional programs in order to sustain cancer growth and viability. Blocking BET protein function with small molecules is associated with therapeutic activity. Consequently, a variety of small molecules have been developed and a number of phase I clinical trials have explored their tolerability and efficacy in patients with solid tumors and hematological malignancies. We will review the rational for applying BET inhibitors in the clinic and we will discuss the toxicity profile as well as efficacy of this new class of protein inhibitors. We will also highlight the emerging problem of treatment resistance and the potential these drugs might have when combined with other anti-cancer therapies.

Histone Post-Translational Modifications and Nucleosome Organisation in Transcriptional Regulation: Some Open Questions

The organisation of chromatin is first discussed to conclude that nucleosomes play both structural and transcription-regulatory roles. The presence of nucleosomes makes difficult the access of transcriptional factors to their target sequences and the action of RNA polymerases. The histone post-translational modifications and nucleosome remodelling are first discussed, from a historical point of view, as mechanisms to remove the obstacles imposed by chromatin structure to transcription. Instead of reviewing the state of the art of the whole field, this review is centred on some open questions. First, some "non-classical" histone modifications, such as short-chain acylations other than acetylation, are considered to conclude that their relationship with the concentration of metabolic intermediaries might make of them a sensor of the physiological state of the cells. Then attention is paid to the interest of studying chromatin organisation and epigenetic marks at a single nucleosome level as a complement to genome-wide approaches. Finally, as a consequence of the above questions, the review focuses on the presence of multiple histone post-translational modifications on a single nucleosome. The methods to detect them and their meaning, with special emphasis on bivalent marks, are discussed.

Histone deacetylases and their functions in plants

Histone deacetylases (HDACs) mediate histone deacetylation and act in concert with histone acetyltransferases to regulate dynamic and reversible histone acetylation which modifies chromatin structure and function, affects gene transcription, thus, controlling multiple cellular processes. HDACs are widely distributed in almost all eukaryotes, and there have been many researches focusing on plant HDACs recently. An increasing number of HDAC genes have been identified and characterized in a variety of plant species and the functions of certain HDACs have been studied. The present studies indicate that HDACs play a key role in regulating plant growth, development and stress responses. This paper reviews recent findings on HDACs and their functions in plants, especially their roles in development and stress responses.

Hat1: the emerging cellular roles of a type B histone acetyltransferase

Hat1 is the sole known example of a type B histone acetyltransferase. While it has long been presumed that type B histone acetyltransferases participate in the acetylation of newly synthesized histones during the process of chromatin assembly, definitive evidence linking these enzymes to this process has been scarce. This review will discuss recent results that have begun to shed light on the roles of Hat1 and also address several outstanding questions relating to the cellular function of this enzyme.

Analysis of the histone acetyltransferase B complex of maize embryos

Purified histone acetyltransferase B (HAT-B) from maize consists of two subunits, p50 and p45. Cloning of the cDNA and genomic DNA encoding the catalytic subunit p50 revealed a consensus motif reminiscent of other acetyltransferases. Internal peptide sequences and immunological studies identified p45 as a protein related to the Retinoblastoma associated protein Rbap. Antibodies against recombinant p50 were able to immunoprecipitate the enzymatic activity of p50 as well as p45. Consistent with the idea that HAT-B is involved in acetylation of newly synthesized histone H4 during DNA replication, mRNA and protein levels are correlated with S-phases during embryo germination. Inhibition of histone deacetylases by HC toxin or Trichostatin A caused a decrease of the in vivo expression of HAT-B mRNA. Regardless of its predominant cytoplasmic localization, a significant proportion of HAT-B-p50 is present in nuclei, irrespective of the cell cycle stage, suggesting an additional nuclear function.

Dynamics of histone acetylation in Chlamydomonas reinhardtii

The dynamic character of core histone post-translational acetylation in the unicellular green alga Chlamydomonas reinhardtii was studied by tritiated acetate incorporation. Histone H3 is the major target of acetylation, steady state, and in pulse and pulse-chase analyses. Acetylation turnover rates were measured by tracer labeling under steady-state conditions. Half-lives of 1.5-3 min were found for penta- to mono-acetylation of H3, dynamically acetylated to the 30% level. Twenty percent of H3 was multi-acetylated, on average with 3. 2 acetyl-lysines, all with rapid turnover. Deacetylase inhibitor trichostatin A (TSA) caused doubling of average acetylation levels, primarily as penta-acetylated H3, but half of H3 was not acetylated at all. The level of histone H4 acetylation was only half that of H3 and a major fraction of mono- and di-acetylated forms appeared static. The dynamic fraction had an average half-life of 3.5 min with higher turnover rates for more highly acetylated H4 forms. TSA, inhibiting less effectively deacetylases active on H4, strongly increased multi-acetylated H4 levels and doubled average acetylation. As for H3, half of histone H4 remained unacetylated. Acetylation of histone H2B was low and of H2A was barely measurable. Despite turnover with half-lives of approximately 2 min, no increase beyond di-acetylation was seen upon TSA treatment.

Alteration of nucleosome structure as a mechanism of transcriptional regulation

The nucleosome, which is the primary building block of chromatin, is not a static structure: It can adopt alternative conformations. Changes in solution conditions or changes in histone acetylation state cause nucleosomes and nucleosomal arrays to behave with altered biophysical properties. Distinct subpopulations of nucleosomes isolated from cells have chromatographic properties and nuclease sensitivity different from those of bulk nucleosomes. Recently, proteins that were initially identified as necessary for transcriptional regulation have been shown to alter nucleosomal structure. These proteins are found in three types of multiprotein complexes that can acetylate nucleosomes, deacetylate nucleosomes, or alter nucleosome structure in an ATP-dependent manner. The direct modification of nucleosome structure by these complexes is likely to play a central role in appropriate regulation of eukaryotic genes.

Nucleosomal DNA regulates the core-histone-binding subunit of the human Hat1 acetyltransferase

BACKGROUND

In eukaryotic cells, newly synthesized histone H4 is acetylated at lysines 5 and 12, a transient modification erased by deacetylases shortly after deposition of histones into chromosomes. Genetic studies in Saccharomyces cerevisiae revealed that acetylation of newly synthesized histones H3 and H4 is likely to be important for maintaining cell viability; the precise biochemical function of this acetylation is not known, however. The identification of enzymes mediating site-specific acetylation of H4 at Lys5 and Lys12 may help explain the function of the acetylation of newly synthesized histones.

RESULTS

A cDNA encoding the catalytic subunit of the human Hat1 acetyltransferase was cloned and, using specific antibodies, the Hat1 holoenzyme was purified from human 293 cells. The human enzyme acetylates soluble but not nucleosomal H4 at Lys5 and Lys12 and acetylates histone H2A at Lys5. Unexpectedly, we found Hat1 in the nucleus of S-phase cells. Like its yeast counterpart, the human holoenzyme consists of two subunits: a catalytic subunit, Hat1, and a subunit that binds core histones, p46, which greatly stimulates the acetyltransferase activity of Hat1. Both p46 and the highly related p48 polypeptide (the small subunit of human chromatin assembly factor 1; CAF-1) bind directly to helix 1 of histone H4, a region that is not accessible when H4 is in chromatin.

CONCLUSIONS

We suggest that p46 and p48 are core-histone-binding subunits that target chromatin assembly factors, chromatin remodeling factors, histone acetyltransferases and histone deacetylases to their histone substrates in a manner that is regulated by nucleosomal DNA.

Induction of γ-Globin by Histone Deacetylase Inhibitors

The short-chain fatty acid butyrate has been shown to elevate fetal hemoglobin (HbF ) by inducing expression of the γ-globin gene. Regulation of gene expression by butyrate is thought to proceed via inhibition of the enzyme histone deacetylase, leading to elevated levels of core histone acetylation which affect chromatin structure and transcription rates. To determine whether changes in histone acetylation are critical for the regulation of the γ-globin gene, we tested three potent and specific inhibitors of histone deacetylase, the cyclic tetrapeptides trapoxin and Helminthsporium carbonum toxin (HC toxin), and the antifungal antibiotic trichostatin A for their ability to induce fetal hemoglobin expression in erythroid cells. These compounds induced fetal hemoglobin in both primary erythroid cell cultures and human erythroleukemia (K562) cells. A butyrate-responsive element spanning the duplicated CCAAT box region of the γ-globin promoter has been identified in transient transfection assays using a reporter construct in K562 cells, and we show that the same promoter region is required for response to trapoxin and trichostatin. Mutational analysis of the γ-globin promoter indicates that the distal CCAAT box and 3′ flanking sequence (CCAATAGCC) is critical for activation by butyrate, trapoxin, and trichostatin, whereas the proximal element (CCAATAGTC) plays a less important role. These results show that inhibition of histone deacetylase can lead to transcriptional activation of γ-globin promoter reporter gene constructs through proximal promoter elements, and suggest that butyrate induces γ-globin expression via such changes in histone acetylation.

Cell growth inhibition by the Mad/Max complex through recruitment of histone deacetylase activity

BACKGROUND

The organization of chromatin is crucial for the regulation of gene expression. In particular, both the positioning and properties of nucleosomes influence promoter-specific transcription. The acetylation of core histones has been suggested to alter the properties of nucleosomes and affect the access of DNA-binding transcriptional regulators to promoters. A recently identified mammalian histone deacetylase (HD1) shows homology to the yeast Rpd3 protein, which together with Sin3 affects the transcription of several genes. Mammalian Sin3 proteins interact with the Mad components of the Myc/Max/Mad network of cell growth regulators. Mad/Max complexes may recruit mammalian Rpd3-like enzymes, therefore, directing histone deacetylase activity to promoters and negatively regulating cell growth.

RESULTS

We report the identification of a tetrameric complex composed of Max, Mad1, Sin3B and HD1. This complex has histone deacetylase activity which can be blocked by the histone deacetylase inhibitors trichostatin A and sodium butyrate. The inhibition of cell growth by Mad1 is enhanced by Sin3B and HD1, as measured by colony formation assays. Furthermore, a Mad1-induced block of S-phase progression can be overcome by trichostatin A, as shown in microinjection experiments.

CONCLUSIONS

The recruitment of a histone deacetylase by sequence-specific DNA-binding proteins provides a mechanism by which the state of acetylation of histones in nucleosomes and hence the activity of specific promoters can be influenced. The finding that Mad/Max complexes interact with Sin3 and HD1 in vivo suggests a model for the role of Mad proteins in antagonizing the function of Myc proteins.

Histones in transit: cytosolic histone complexes and diacetylation of H4 during nucleosome assembly in human cells

The organization and acetylation of nascent histones prior to their stable incorporation into chromatin were examined. Through sedimentation and immunoprecipitation analyses of HeLa cytosolic extracts, two somatic non-nucleosomal histone complexes were detected: one containing nascent H3 and H4, and a second containing H2A (and probably H2B) in association with the nonhistone protein NAP-1. The H3/H4 complex has a sedimentation coefficient of 5-6S, consistent with the presence of one or more escort proteins. H4 in the cytosolic H3/H4 complex is diacetylated, fully in accord with the acetylation state of newly synthesized H4 in chromatin. The diacetylation of nascent human H4 is therefore completed prior to nucleosome assembly. As part of our studies of the nascent H3/H4 complex, the cytoplasmic histone acetyltransferase most likely responsible for acetylating newly synthesized H4 was also investigated. HeLa histone acetyltransferase B (HAT B) acetylates H4 but not H3 in vitro, and maximally diacetylates H4 even in the presence of sodium butyrate. Human HAT B acetylates H4 exclusively on the lysine residues at positions 5 and 12, in complete agreement with the highly conserved acetylation pattern of nascent nucleosomal H4 (Sobel et al., 1995), and has a native molecular weight of approximately 100 kDa. Based on our findings a model is presented for the involvement of histone acetylation and NAP-1 in H2A/H2B deposition and exchange, during nucleosome assembly and chromatin remodeling in vivo.

Purification and characterization of a high molecular weight histone deacetylase complex (HD2) of maize embryos

The dynamic state of core histone acetylation is maintained by histone acetyltransferases and deacetylases. In germinating maize embryos, four nuclear histone deacetylases can be distinguished. From a chromatin fraction prepared at 72 h after start of embryo germination, we have purified the nuclear histone deacetylase HD2 to homogeneity. Using a sequence of chromatographic steps, we achieved the purification of an enzymatically active high molecular weight protein complex with an apparent molecular mass of 400 kDa, as determined by gel filtration chromatography. The purified enzyme was characterized in terms of enzymatic and kinetic properties, and sensitivity to several histone deacetylase inhibitors. In SDS-polyacrylamide gels, HD2 split into three polypeptides of 45, 42, and 39 kDa, suggesting that the native enzyme is a multimer-protein complex. Electrophoresis under nondenaturing conditions in combination with second dimension SDS-gel electrophoresis indicated that all three protein components of the HD2 complex were enzymatically active. Polyclonal antibodies against each of the three polypeptides were raised in rabbits. Each antiserum reacted with all three polypeptides on Western blots, suggesting that p45, p42, and p39 are highly homologous. This homology was confirmed by amino acid sequencing of peptides generated from each of the three HD2 components.

Purification of histone deacetylase HD1-A of germinating maize embryos

We have purified the soluble nuclear histone deacetylase HD1-A of germinating maize embryos. By a combination of 6 chromatographic steps we achieved a 77,000-fold purification of an enzymatically active protein. Gel filtration chromatography revealed a molecular weight of 45 kDa of the native enzyme and electrophoretic analysis of the purified enzyme by SDS-PAGE resulted in a single band at a molecular weight of 48 kDa, indicating that the enzyme is a monomer protein. When fractions with enzyme activity of different stages of chromatographic purification were subjected to isoelectric focusing, enzyme activity focused at a pH of around 6.4 as measured in an activity gel assay; second dimension SDS-PAGE again revealed a protein spot at a molecular weight of 48 kDa.

A comparative study of histone deacetylases of plant, fungal and vertebrate cells

The enzymatic equilibrium of reversible core histone acetylation is maintained by two enzyme activities, histone acetyltransferase and histone deacetylase (HD). These enzyme activities exist as multiple enzyme forms. The present report describes methods to extract different HD-forms from three organisms, germinating maize embryos, the myxomycete Physarum polycephalum, and chicken red blood cells; it provides data on the chromatographic separation and partial purification of HD-forms. In germinating maize embryos three HDs (HD1-A, HD1-B, HD2) can be discriminated; HD1-A, HD1-B, and HD2 were characterized in terms of their dependence on pH, temperature and various ions, as well as kinetic parameters (Km for core histones) and inhibition by various compounds. The same parameters were investigated for the corresponding enzymes of Physarum polycephalum, and mature and immature chicken erythrocytes. Based on these results, optimum assay conditions were established for the different enzyme forms. The kinetic data revealed that the maize histone deacetylase HD1-B peak after partial purification by Q-Sepharose chromatography was heterogeneous and consisted of two histone binding sites that differed significantly in their affinity for purified core histones. Optimized affinity chromatography on poly-Lysine Agarose indeed showed that the former defined deacetylase HD1-B can be separated clearly into two individual HD enzyme forms. The high multiplicity of histone deacetylases underlines the importance of these enzymes for the complex regulation of core histone acetylation.

HDA1 and HDA3 are components of a yeast histone deacetylase (HDA) complex

Histone acetylation is maintained through the action of histone acetyltransferases and deacetylases and has been correlated with increased gene activity. To investigate the functional role of these enzymes in the regulation of transcription, we have purified from Saccharomyces cerevisiae two histone deacetylase activities, HDA and HDB, with molecular masses of approximately 350 and 600 kDa, respectively. In vitro, the HDA activity deacetylates all four core histones, has a preference for histone H3, and is strongly inhibited by trichostatin A (a specific inhibitor of histone deacetylases). HDB is considerably less sensitive to trichostatin A. We report the extensive purification of the HDA activity and the identification of peptides (p75, p73, p72, and p71) whose presence correlates with deacetylase activity on native polyacrylamide gels. An antibody to p75 immunoprecipitates peptides with molecular masses similar to those in the 350-kDa complex. Additionally, antibodies to p75 and p71 specifically precipitate histone deacetylase activity and co-immunoprecipitate each other. Gene disruptions of p75 (HDA1) or p71 (HDA3) cause the loss of the 350-kDa (but not the 600-kDa) activity from our chromatography profiles. These data argue strongly that HDA1 and HDA3 are subunits of the HDA complex, which is structurally distinct from the second, HDB complex.

Purification and characterization of the cytoplasmic histone acetyltransferase B of maize embryos

From a soluble cellular fraction of maize embryos we purified to apparent homogeneity a cytoplasmic histone acetyltransferase, which matches all criteria for a B-type enzyme. Using 8 chromatographic steps, we achieved a 6700-fold purification of an enzymatically active protein with a molecular weight of approximately 90 kDa. Under denaturing conditions the protein split into 2 components which migrated at 45 and 50 kDa in SDS-PAGE, suggesting that the native enzyme is a heterodimer. The purified enzyme was characterized in terms of physicochemical and kinetic properties, and substrate specificity. It was specific for histone H4, leading to acetylation of non-acetylated H4 subspecies into the di-acetylated state in vitro. Its activity was coincident with the intensity of DNA replication in meristematic cells during embryo germination. We established an electrophoretic system under non-denaturing conditions for detection of enzyme activity within the gel matrix; in combination with second dimension SDS-PAGE the procedure allowed the unambiguous identification of histone acetyltransferase, even in crude enzyme preparations.

Nuclear matrix and the cell cycle

The facts that the nuclear matrix represents a structural framework of the cell nucleus and that nuclear events, such as DNA replication, transcription, and DNA repair, are associated with this skeletal structure suggest that its components are subject to cell cycle-regulatory mechanisms. Cell cycle regulation has been shown for nuclear lamina assembly and disassembly during mitosis and chromatin reorganization. Little attention has so far been paid to internal nuclear matrix proteins and matrix-associated proteins with respect to the cell cycle. This survey attempts to summarize available data and presents experimental evidence that important metabolic functions of the nucleus are regulated by the transient, cell cycle-dependent attachment of enzymes and regulatory proteins to the nuclear matrix. Results on thymidine kinase and RNA polymerase during the synchronous cell cycle of Physarum polycephalum demonstrate that reversible binding to the nuclear matrix represents an additional level of regulation for nuclear processes.

Histone acetylation: facts and questions

The DNA of eukaryotic cells is organized in a complex with proteins, either as interphase chromatin or mitotic chromosomes. Nucleosomes, the structural subunits of chromatin, have long been considered as static structures, incompatible with processes occurring in chromatin. During the past few years it has become evident that the histone part of the nucleosome has important regulatory functions. Some of these functions are mediated by the N-terminal core histone domains which contain sites for posttranslational modifications, among them lysine residues for reversible acetylation. Recent results indicate that acetylation and deacetylation of N-terminal lysines of nucleosomal core histones represent a means of molecular communication between chromatin and the cellular signal transduction network, resulting in heritable epigenetic information. Data on enzymes involved in acetylation and the pattern of acetylated lysine sites on chromosomes, as well as genetic data on yeast transcriptional repression, suggest that acetylation may lead to structural transitions as well as specific signalling within distinct chromatin domains.

Histone deacetylase. A key enzyme for the binding of regulatory proteins to chromatin

Core histones can be modified by reversible, posttranslational acetylation of specific lysine residues within the N-terminal protein domains. The dynamic equilibrium of acetylation is maintained by two enzyme activities, histone acetyltransferase and histone deacetylase. Recent data on histone deacetylases and on anionic motifs in chromatin- or DNA-binding regulatory proteins (e.g. transcription factors, nuclear proto-oncogenes) are summarized and united into a hypothesis which attributes a key function to histone deacetylation for the binding of regulatory proteins to chromatin by a transient, specific local increase of the positive charge in the N-terminal domains of nucleosomal core histones. According to our model, the rapid deacetylation of distinct lysines in especially H2A and H2B would facilitate the association of anionic protein domains of regulatory proteins to specific nucleosomes. Therefore histone deacetylation (histone deacetylases) may represent a unique regulatory mechanism in the early steps of gene activation, in contrast to the more structural role of histone acetylation (histone acetyltransferases) for nucleosomal transitions during the actual transcription process.