Accumulation of multiacetylated forms of histones by trichostatin A and its developmental consequences in early starfish embryos

Inhibition of histone acetylation and deacetylation enzymes affects longevity, development, and fecundity in the pea aphid (Acyrthosiphon pisum)

Histone acetylation is an evolutionarily conserved epigenetic mechanism of eukaryotic gene regulation which is tightly controlled by the opposing activities of histone acetyltransferases (HATs) and histone deacetylases (HDACs). In insects, life-history traits such as longevity and fecundity are severely affected by the suppression of HAT/HDAC activity, which can be achieved by RNA-mediated gene silencing or the application of chemical inhibitors. We used both experimental approaches to investigate the effect of HAT/HDAC inhibition in the pea aphid (Acyrthosiphon pisum) a model insect often used to study complex life-history traits. The silencing of HAT genes (kat6b, kat7, and kat14) promoted survival or increased the number of offspring, whereas targeting rpd3 (HDAC) reduced the number of viviparous offspring but increased the number of premature nymphs, suggesting a role in embryogenesis and eclosion. Specific chemical inhibitors of HATs/HDACs showed a remarkably severe impact on life-history traits, reducing survival, delaying development, and limiting the number of offspring. The selective inhibition of HATs and HDACs also had opposing effects on aphid body weight. The suppression of HAT/HDAC activity in aphids by RNA interference or chemical inhibition revealed similarities and differences compared to the reported role of these enzymes in other insects. Our data suggest that gene expression in A. pisum is regulated by multiple HATs/HDACs, as indicated by the fitness costs triggered by inhibitors that suppress several of these enzymes simultaneously. Targeting multiple HATs or HDACs with combined effects on gene regulation could, therefore, be a promising approach to discover novel targets for the management of aphid pests.

Boundary maintenance in the ancestral metazoan Hydra depends on histone acetylation

Much of boundary formation during development remains to be understood, despite being a defining feature of many animal taxa. Axial patterning of Hydra, a member of the ancient phylum Cnidaria which diverged prior to the bilaterian radiation, involves a steady-state of production and loss of tissue, and is dependent on an organizer located in the upper part of the head. We show that the sharp boundary separating tissue in the body column from head and foot tissue depends on histone acetylation. Histone deacetylation disrupts the boundary by affecting numerous developmental genes including Wnt components and prevents stem cells from entering the position dependent differentiation program. Overall, our results suggest that reversible histone acetylation is an ancient regulatory mechanism for partitioning the body axis into domains with specific identity, which was present in the common ancestor of cnidarians and bilaterians, at least 600 million years ago.

Ectopic hbox12 Expression Evoked by Histone Deacetylase Inhibition Disrupts Axial Specification of the Sea Urchin Embryo

Dorsal/ventral patterning of the sea urchin embryo depends upon the establishment of a Nodal-expressing ventral organizer. Recently, we showed that spatial positioning of this organizer relies on the dorsal-specific transcription of the Hbox12 repressor. Building on these findings, we determined the influence of the epigenetic milieu on the expression of hbox12 and nodal genes. We find that Trichostatin-A, a potent and selective histone-deacetylases inhibitor, induces histone hyperacetylation in hbox12 chromatin, evoking broad ectopic expression of the gene. Transcription of nodal concomitantly drops, prejudicing dorsal/ventral polarity of the resulting larvae. Remarkably, impairing hbox12 function, either in a spatially-restricted sector or in the whole embryo, specifically rescues nodal transcription in Trichostatin-A-treated larvae. Beyond strengthen the notion that nodal expression is not allowed in the presence of functional Hbox12 in the same cells, these results highlight a critical role of histone deacetylases in regulating the spatial expression of hbox12.

Histone deacetylase is required for the activation of Wnt/β-catenin signaling crucial for heart valve formation in zebrafish embryos

During vertebrate heart valve formation, Wnt/β-catenin signaling induces BMP signals in atrioventricular canal (AVC) myocardial cells and underlying AVC endocardial cells then undergo endothelial-mesenchymal transdifferentiation (EMT) by receiving this BMP signals. Histone deacetylases (HDACs) have been implicated in numerous developmental processes by regulating gene expression. However, their specific roles in controlling heart valve development are largely unexplored. To investigate the role of HDACs in vertebrate heart valve formation, we treated zebrafish embryos with trichostatin A (TSA), an inhibitor of class I and II HDACs, from 36 to 48 h post-fertilization (hpf) during which heart looping and valve formation occur. Following TSA treatment, abnormal linear heart tube development was observed. In these embryos, expression of AVC myocardial bmp4 and AVC endocardial notch1b genes was markedly reduced with subsequent failure of EMT in the AVC endocardial cells. However, LiCl-mediated activation of Wnt/β-catenin signaling was able to rescue defective heart tube formation, bmp4 and notch1b expression, and EMT in the AVC region. Taken together, our results demonstrated that HDAC activity plays a pivotal role in vertebrate heart tube formation by activating Wnt/β-catenin signaling which induces bmp4 expression in AVC myocardial cells.

Inhibition of histone deacetylase as a new mechanism of teratogenesis

Histone deacetylases (HDACs) are nuclear and cytoplasmic enzymes that deacetylate a number of substrates, of which histones are the best known and described in the literature. HDACs are present in eukaryotic and bacteria cells, and are fundamental for a number of cellular functions, including correct gene expression. Surprisingly, only up to 20% of the whole genome is controlled by HDACs, but key processes for survival, proliferation, and differentiation have been strictly linked to HDAC enzyme functioning. The use of HDAC inhibitors (HDACi) has been proposed for the treatment of neoplastic diseases. Their effectiveness has been suggested for a number of liquid and solid tumors, particularly acute promyelocytic leukemia (APL). The role of HDACs in embryo development is currently under investigation. Published data indicate knockout phenotype analysis to be of particular interest, in which a number of HDACs play a key role during development. Little data have been published on the effects of HDACi on embryonic development, although for valproic acid (VPA), literature from the 1980s described its teratogenic effects in experimental animals and humans. To date, all tested HDACi have shown teratogenic effects similar to those described for VPA when tested in zebrafish, Xenopus laevis, and mice. HDACs were also able to alter embryo development in invertebrates and plants. A model, similar to that proposed in APL, involving retinoic acid receptors (RAR) and tissue specific Hox gene expression, is suggested to explain the HDAC effects on embryo development.

The effects of histone deacetylase inhibitors on heterochromatin: implications for anticancer therapy?

Histone acetylation regulates many chromosome functions, such as gene expression and chromosome segregation. Histone deacetylase inhibitors (HDACIs) induce growth arrest, differentiation and apoptosis of cancer cells ex vivo, as well as in vivo in tumour-bearing animal models, and are now undergoing clinical trials as anti-tumour agents. However, little attention has been paid to how HDACIs function in these biological settings and why different cells respond in different ways. Here, we discuss the consequences of inhibiting histone deacetylases in cycling versus non-cycling cells, in light of the dynamics of histone acetylation patterns with a specific emphasis on heterochromatic regions of the genome.

Histone deacetylase 1 (HDAC-1) required for the normal formation of craniofacial cartilage and pectoral fins of the zebrafish

Histone deacetylases interact with nucleosomes to facilitate the formation of transcriptionally repressed chromatin. In the present study, we show that histone deacetylase 1 (hdac-1) is expressed throughout embryonic development of the zebrafish. The expression of hdac-1 is ubiquitous in early embryos (2-16 hr postfertilization), but at later stages (36 and 48 hr postfertilization), it is primarily restricted to the branchial arches, fin bud mesenchyme, and hindbrain. We report the phenotypes of hdac-1 homozygous mutant embryos and embryos injected with an hdac-1 antisense morpholino. These embryos possess a complex phenotype affecting several embryonic structures. We observed developmental abnormalities in the heart and neural epithelial structures, including the retina and the loss of craniofacial cartilage and pectoral fins.

Nuclear import and activity of histone deacetylase in Xenopus oocytes is regulated by phosphorylation

Most of the histone deacetylase (HDAC) activity detected in oocytes and early embryos of Xenopus can be accounted for by the presence of a protein complex that contains the maternal HDACm protein. This complex appears to fulfil the conditions required of a 'deposition' histone deacetylase, its primary function being to deacetylate the core histones incorporated into newly-synthesized chromatin during the rapid cell cycles leading up to blastula. A major event in the assembly and accumulation of the HDAC complex is the translocation of the HDACm protein into the germinal vesicle during oogenesis. Here we examine the features of HDACm that are responsible for its nuclear uptake and enzyme activity, identifying the charged C-terminal domain as a target for modification by phosphorylation. Whereas, one phosphorylation site lying within the putative nuclear localization signal, T445, is required for efficient nuclear import of a GST-carboxy-tail fusion, two others, S421 and S423, appear to effect release from the import receptors. Although overexpression of recombinant HDACm in oocytes leads to premature condensation of endogenous chromatin, this effect is abrogated in vivo by mutation of S421A and S423A. Thus, both translocation and activity of HDACm appear to be regulated by specific phosphorylation events. These results have implications for techniques involving the transfer of somatic nuclei into enucleated oocytes.

Molecular characterization of a novel nuclear transglutaminase that is expressed during starfish embryogenesis

We report the constitution and molecular characterization of a novel transglutaminase (EC 2.3.2.13) that starts to accumulate specifically in the nucleus in the starfish (Asterina pectinifera) embryo after progression through the early blastula stage. The cDNA for the nuclear transglutaminase was cloned and the cDNA-deduced sequence defines a single open reading frame encoding a protein with 737 amino acids and a predicted molecular mass of 83 kDa. A comparison of this transglutaminase with other members of the gene family revealed an overall sequence identity of 33-41%. A special sequence feature of this transglutaminase, which is not found in other transglutaminases, is the presence of nuclear localization signal-like sequences in the N-terminal region. Microinjection of hybrid constructs that encode the N-terminal segment fused to reporter proteins into the germinal vesicle of an oocyte produced chimeric proteins by transcription-coupled translation. It was found that the N-terminal segment alone was sufficient to effect nuclear accumulation of an otherwise cytoplasmic protein. These results suggest that the nuclear accumulation of the transglutaminase may play an important role in nuclear remodeling during early starfish embryogenesis.

Involvement of histone deacetylase at two distinct steps in gene regulation during intestinal development in Xenopus laevis

Amphibian metamorphosis is marked by dramatic thyroid hormone (T(3))-induced changes including de novo morphogenesis, tissue remodeling and organ resorption through programmed cell death. These changes involve cascades of gene regulation initiated by thyroid hormone and its receptors. Previous studies suggest that chromatin remodeling involving changes in core histone acetylation plays a fundamental role in transcriptional regulation. A basic model has been suggested where targeted histone deacetylation is involved in transcriptional repression and histone acetylation is involved in transcriptional activation. On the other hand, the developmental roles of histone acetylation remain to be elucidated. Here we demonstrate that tadpole treatment with trichostatin A, a specific potent histone deacetylase inhibitor, blocks metamorphosis. Gene expression analyses show that trichostatin A induces the release of T(3)-response gene repression without affecting T(3)-induction of direct T(3)-response genes. However, the drug blocks the regulation of late T(3)-response genes, which may be responsible for its inhibitory effects on metamorphosis. These data support a role of deacetylases in transcriptional repression by unliganded T(3) receptor during premetamorphosis and another role at a downstream step of the gene regulation cascade induced by T(3) during metamorphosis.

Chromatin and chromosomal controls in development

Chromatin and chromosomes have major regulatory roles in development. Nucleosome positioning and modification, chromatin structural transitions and domain organization all contribute to the regulation of individual genes and gene families. Chromosomal position and nuclear compartmentalization represent important contributory factors in determining cell fate. These controls may explain many interesting and unexplored features of developmental systems.

Control of gene expression at the onset of bovine embryonic development

The objective of this study was to examine the timing and mechanisms involved in transcription initiation in bovine embryos. Transcriptional activity and its regulation were explored by labeling 1-cell zygotes and 2-cell embryos with [(3)H]uridine in the presence or absence of alpha-amanitin, aphidicolin, and tricostatin A (TSA) (inhibitors of mRNA synthesis, DNA replication, and histone deacetylases, respectively) followed by a total RNA isolation and determination of [(3)H]uridine incorporation. We also analyzed translation of zygotic/embryonic mRNAs by labeling zygotes and 2-cell embryos with [(35)S]methionine in the presence or absence of alpha-amanitin, aphidicolin, and TSA followed by two-dimensional PAGE and autoradiography. We show that bovine 1-cell zygotes and 2-cell embryos are transcriptionally and translationally active. The first and second rounds of DNA replication are important regulators of early gene expression as the inhibition of DNA replication resulted in a dramatic decrease in both transcriptional and translational activity. Moreover, acetylation of histones plays an important role in this early gene activation at the onset of embryonic development in the cow.

Histone deacetylase mRNA temporally and spatially regulated in its expression in sea urchin embryos

SpHDAC1, a cDNA homolog of the yeast Rpd3 and higher eukaryotic histone deacetylases (HDAC), was cloned from the sea urchin Strongylocentrotus purpuratus. Its predicted polypeptide and the Rpd3 homologs were highly identical in two-thirds of their lengths, but diverged in their carboxyl-terminal regions in both length and sequence. SpHDAC1 transcripts, which reached maximal concentration at the blastula stages, and diminished thereafter, were neither ubiquitously expressed nor restricted to particular cell lineages, but appeared successively in distinct embryonic regions. In the blastula, transcripts were concentrated in a ring within the vegetal plate, comprising primordial endoderm, and, at the outset of gastrulation, in primordial hindgut endoderm. However, in early to mid-gastrula transcripts, they also appeared in oral ectoderm. In the late-stage gastrula, expression developed in the foregut. These shifts in spatial expression, together with an observed developmental blockage prior to sea urchin gastrulation by the histone deacetylase inhibitor trichostatin A, suggest a stepwise involvement of SpHDAC1 gene expression or SpHDAC1 functionality in the events of normal gastrulation.

FR901228, a potent antitumor antibiotic, is a novel histone deacetylase inhibitor

Screening for microbial metabolites that induce transcriptional activation of the SV40 promoter resulted in the identification of two known compounds, FR901228 and trichostatin A (TSA). FR901228 is a potent antitumor drug that is currently under clinical investigation. TSA is a specific inhibitor of histone deacetylase. Despite structural unrelatedness, both FR901228 and TSA greatly enhanced the transcriptional activity of the SV40 promoter in an enhancer-dependent manner. The effects of FR901228 on the cell cycle, chromatin structure, and histone acetylation were examined and compared with those of TSA. Both compounds caused arrest of the cell cycle at both G1 and G2/M phases and induction of internucleosomal breakdown of chromatin. FR901228, like TSA, inhibited intracellular histone deacetylase activity, as a result of which marked amounts of acetylated histone species accumulated. FR901228 is therefore a new type of histone deacetylase inhibitor, whose chemical structure is unrelated to known inhibitors such as trichostatins and trapoxins.

Xenopus HDm, a maternally expressed histone deacetylase, belongs to an ancient family of acetyl-metabolizing enzymes

Modification of core histones can alter chromatin structure, facilitating the activation and repression of genes. A key example is the acetylation of N-terminal lysines of the core histones. Recently, the mammalian histone deacetylase HD1 was cloned from Jurkat T cells, and shown to be 60% identical to the yeast global gene regulator Rpd3 (Taunton et al., 1996). Here we report the cloning of HDm, a maternally expressed putative deposition histone deacetylase from Xenopus laevis. Comparison of the amino acid sequences of histone deacetylases from diverse eukaryotes shows high levels of identity within a putative enzyme core region. Further alignment with other types of protein: acetoin-utilizing enzymes from eubacteria; acetylpolyamine hydrolases from mycoplasma and cyanobacteria; and a protein of unknown function from an archaebacterium, reveals an apparently conserved core, and suggests that histone deacetylases belong to an ancient family of enzymes with related functions.

High-sensitivity mass spectrometry for analysis of posttranslational modifications

Pulsed fast atom bombardment ionization (pulsed-FAB) mass spectrometry has been developed to improve the sensitivity of tandem mass spectrometry (MS/MS), allowing it to be used for the analysis of very small samples. MS/MS, when used with a magnetic four-sector instrument coupled with the pulsed-FAB system, allows significant enhancement in product ion intensity of over ten-fold in magnitude over conventional FAB. MS/MS was applied to the structural analysis of a unique nuclear protein, designated p28, which was isolated from a histone fraction obtained from starfish testes. The results clearly show that protein p28 is a heterodimer composed of testicular histones H2B and H4 which are cross-linked between Gln9 of H2B and Lys5 of H4.

Turnover of histone acetyl groups during sea urchin early development is not required for histone, heat shock and actin gene transcription

Histone acetylation is an extremely complex, reversible and specific process. In order to evaluate the importance of this modification for gene expression during sea urchin development, acetyl group turnover of histone lysine residues was blocked by sodium butyrate. The continuous presence of 15 Mm sodium butyrate in the incubation medium from the onset of development blocked gastrulation and resulted in chromatin containing hyperacetylated histone molecules in amounts usually not found in nature. At the mesenchyme blastula stage, the expression of the early histone genes was shut off and the expression of the late genes was switched on both in control and sodium butyrate-treated embryos. Investigation of the early histone gene chromatin structure in butyrate-treated embryos revealed a random distribution of nucleosomes when the genes were transcriptionally active as compared to regular nucleosomal packaging when genes were inactive. These changes in chromatin structure during development mimicked the chromatin structural transition of the early histone genes in control embryos. In addition, the ability of heat shock genes to be induced at elevated temperature and repressed at normal temperature was unaffected in butyrate treatment of embryos. Finally, the developmental profiles of the cytoskeletal CyIIIa actin gene expression in control and butyrate-treated embryos were very similar. The data presented suggest that turnover of histone acetyl groups and the overall level of histone acetylation are not determining factors in the up and down regulation of a number of genes during early development of sea urchin.

Trichostatin A and trapoxin: novel chemical probes for the role of histone acetylation in chromatin structure and function

Reversible acetylation at the epsilon-amino group of lysines located at the conserved domain of core histones is supposed to play an important role in the regulation of chromatin structure and its transcriptional activity. One promising strategy for analyzing the precise function of histone acetylation is to block the activities of acetylating or deacetylating enzymes by specific inhibitors. Recently, two microbial metabolites, trichostatin A and trapoxin, were found to be potent inhibitors of histone deacetylases. Trichostatin A reversibly inhibits the mammalian histone deacetylase, whereas trapoxin causes inhibition through irreversible binding to the enzyme. The histone deacetylase from a trichostatin A-resistant cell line is resistant to trichostatin A, indicating that the enzyme is the primary target. Both of the agents induce a variety of biological responses of cells such as induction of differentiation and cell cycle arrest. Trichostatin A and trapoxin are useful in analyzing the role of histone acetylation in chromatin structure and function as well as in determining the genes whose activities are regulated by histone acetylation.

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.