Mutations in the acetylation hotspots of Rbl2 are associated with increased risk of breast cancer.

Retinoblastoma like protein-2 (Rbl2) is functionally regulated by phosphorylation and acetylation. Previously, we demonstrated that lysine K1083 (K1079 in human Rbl2) is a potential target for acetylation but its functional role remains elusive. We investigated alterations in human Rbl2 gene specifically targeting exons 19-22 harbouring acetylatable residues i.e. K1072, K1083 and K1115 through single stranded conformation polymorphism (SSCP) in breast cancer patients. The K1083 was found altered into arginine (R) in 51% of the cases but K1072 and K1115 remained conserved. The 'K1083R' mutation impairs the acetylation potential of this motif that may result in functional inactivation of Rbl2. These patients also showed poor survival outcome that highlights prognostic relevance of this residue. NIH3T3 cells expressing glutamine (K1083Q) mutated Rbl2 could not be arrested in G1 by serum starvation, whereas cells expressing Rbl2 with K1083R showed prolonged G1 arrest in fluorescence activated cell sorting (FACS) analysis. This suggests that K1083 acetylation is important for G1/S transition. Further, we performed molecular dynamic simulations (MDS) to analyse kinetics of residue K1083 with Cyc-D1/CDK4. Mutations at K1083 impaired this binding exposing neighbouring residues S1080, P1081, S1082 and R1084, hence enhancing the possibility of accelerated phosphorylation. S1080 has previously been reported as a promising candidate of cell cycle dependent phosphorylation in Rbl2. This highlights significance of mutations in the pocket domain of Rbl2 gene in breast cancer, and also strengthen the supposition that K1083 acetylation is pre-requisite for its phosphorylation.

In vitro phosphorylation and acetylation of the murine pocket protein Rb2/p130.

The retinoblastoma protein (pRb) and the related proteins Rb2/p130 and 107 represent the "pocket protein" family of cell cycle regulators. A key function of these proteins is the cell cycle dependent modulation of E2F-regulated genes. The biological activity of these proteins is controlled by acetylation and phosphorylation in a cell cycle dependent manner. In this study we attempted to investigate the interdependence of acetylation and phosphorylation of Rb2/p130 in vitro. After having identified the acetyltransferase p300 among several acetyltransferases to be associated with Rb2/p130 during S-phase in NIH3T3 cells in vivo, we used this enzyme and the CDK4 protein kinase for in vitro modification of a variety of full length Rb2/p130 and truncated versions with mutations in the acetylatable lysine residues 1079, 128 and 130. Mutation of these residues results in the complete loss of Rb2/p130 acetylation. Replacement of lysines by arginines strongly inhibits phosphorylation of Rb2/p130 by CDK4; the inhibitory effect of replacement by glutamines is less pronounced. Preacetylation of Rb2/p130 strongly enhances CDK4-catalyzed phosphorylation, whereas deacetylation completely abolishes in vitro phosphorylation. In contrast, phosphorylation completely inhibits acetylation of Rb2/p130 by p300. These results suggest a mutual interdependence of modifications in a way that acetylation primes Rb2/p130 for phosphorylation and only dephosphorylated Rb2/p130 can be subject to acetylation. Human papillomavirus 16-E7 protein, which increases acetylation of Rb2/p130 by p300 strongly reduces phosphorylation of this protein by CDK4. This suggests that the balance between phosphorylation and acetylation of Rb2/p130 is essential for its biological function in cell cycle control.

Novel insights into the functional role of three protein arginine methyltransferases in Aspergillus nidulans.

Protein arginine methylation has been implicated in different cellular processes including transcriptional regulation by the modification of histone proteins. Here we demonstrate significant in vitro activities and multifaceted specificities of Aspergillus protein arginine methyltransferases (PRMTs) and we provide evidence for a role of protein methylation in mechanisms of oxidative stress response. We have isolated all three Aspergillus PRMTs from fungal extracts and could assign significant histone specificity to RmtA and RmtC. In addition, both enzymes were able to methylate several non-histone proteins in chromatographic fractions. For endogenous RmtB a remarkable change in its substrate specificity compared to the recombinant enzyme form could be obtained. Phenotypic analysis of mutant strains revealed that growth of DeltarmtA and DeltarmtC strains was significantly reduced under conditions of oxidative stress. Moreover, mycelia of DeltarmtC mutants showed a significant retardation of growth under elevated temperatures.

A novel motif in fungal class 1 histone deacetylases is essential for growth and development of Aspergillus.

Acetylation of the N-terminal tails of core histones is an important regulatory mechanism in eukaryotic organisms. In filamentous fungi, little is known about the enzymes that modify histone tails. However, it is increasingly evident that histone deacetylases and histone acetyltransferases are critical factors for the regulation of genes involved in fungal pathogenicity, stress response, and production of secondary metabolites such as antibiotics or fungal toxins. Here, we show that depletion of RpdA, an RPD3-type histone deacetylase of Aspergillus nidulans, leads to a pronounced reduction of growth and sporulation of the fungus. We demonstrate that a so far unnoticed motif in the C terminus of fungal RpdA histone deacetylases is required for the catalytic activity of the enzyme and consequently is essential for the viability of A. nidulans. Moreover, we provide evidence that this motif is also crucial for the survival of other, if not all, filamentous fungi, including pathogens such as Aspergillus fumigatus or Cochliobolus carbonum. Thus, the extended C terminus of RpdA-type enzymes represents a promising target for fungal-specific histone deacetylase-inhibitors that may have potential as novel antifungal compounds with medical and agricultural applications.

Cell cycle dependent role of HDAC1 for proliferation control through modulating ribosomal DNA transcription.

Ribosome biogenesis and ribosomal DNA transcription are closely correlated with the growth and proliferation of cells, with these processes being under tight epigenetic control. We have investigated the effect of ectopically expressed murine HDAC1 in reporter assays, on ribosomal DNA transcription, cell cycle progression and proliferation in transfected mammalian cells. Ectopically expressed mHDAC1 represses transcription in ribosomal reporter assays driven by ribosomal promoter elements in NIH3T3 cells as well as Cos-7 cells. Following stable transfection of NIH3T3 cells, flag-tagged HDAC1 is assembled into functional, enzymatically active HDAC-complexes that display correct nuclear localization. Induction of flag-HDAC1 expression in NIH3T3 cells caused a cell-cycle phase specific reduction in the initiation of endogenous rDNA transcription, reflected in a reduction of nascent rRNA as well as a marked depression of proliferation due to prolongation of G2-phase. This was substantiated by FACS analysis and cyclin B1 expression analysis. However, prolongation of the G2-phase in HDAC1-overexpressing cells finally led to overcompensation and thus to an increase in total ribosomal RNA. The transient downregulation of rRNA synthesis after induction of HDAC1 overexpression led to a prolongation of G2-phase. These observations were most likely a consequence of HDAC1-mediated deacetylation of upstream binding factor (UBF).

Histone modifications and chromatin dynamics: a focus on filamentous fungi.

The readout of the genetic information of eukaryotic organisms is significantly regulated by modifications of DNA and chromatin proteins. Chromatin alterations induce genome-wide and local changes in gene expression and affect a variety of processes in response to internal and external signals during growth, differentiation, development, in metabolic processes, diseases, and abiotic and biotic stresses. This review aims at summarizing the roles of histone H1 and the acetylation and methylation of histones in filamentous fungi and links this knowledge to the huge body of data from other systems. Filamentous fungi show a wide range of morphologies and have developed a complex network of genes that enables them to use a great variety of substrates. This fact, together with the possibility of simple and quick genetic manipulation, highlights these organisms as model systems for the investigation of gene regulation. However, little is still known about regulation at the chromatin level in filamentous fungi. Understanding the role of chromatin in transcriptional regulation would be of utmost importance with respect to the impact of filamentous fungi in human diseases and agriculture. The synthesis of compounds (antibiotics, immunosuppressants, toxins, and compounds with adverse effects) is also likely to be regulated at the chromatin level.

Acetylation of UBF changes during the cell cycle and regulates the interaction of UBF with RNA polymerase I.

The upstream binding factor UBF, an activator of RNA polymerase I transcription, is posttranslationally modified by phosphorylation and acetylation. We found that in NIH3T3 cells, UBF is acetylated in S-phase but not in G1-phase. To assess the role of acetylation in regulation of UBF activity, we have established an NIH3T3 cell line that inducibly overexpresses HDAC1. Both in vivo and in vitro, HDAC1 efficiently hypoacetylates UBF. Immunoprecipitation with antibodies against the Pol I-associated factor PAF53 co-precipitated UBF in mock cells but not in cells overexpressing HDAC1. Pull-down experiments showed that acetylation of UBF augments the interaction with Pol I. Consistent with acetylation of UBF being important for association of PAF53 and recruitment of Pol I, the level of Pol I associated with rDNA and pre-rRNA synthesis were reduced in cells overexpressing HDAC1. The results suggest that acetylation and deacetylation of UBF regulate rRNA synthesis during cell cycle progression.

HdaA, a major class 2 histone deacetylase of Aspergillus nidulans, affects growth under conditions of oxidative stress.

Histone deacetylases (HDACs) catalyze the removal of acetyl groups from the epsilon-amino group of distinct lysine residues in the amino-terminal tail of core histones. Since the acetylation status of core histones plays a crucial role in fundamental processes in eukaryotic organisms, such as replication and regulation of transcription, recent research has focused on the enzymes responsible for the acetylation/deacetylation of core histones. Very recently, we showed that HdaA, a member of the Saccharomyces cerevisiae HDA1-type histone deacetylases, is a substantial contributor to total HDAC activity in the filamentous fungus Aspergillus nidulans. Now we demonstrate that deletion of the hdaA gene indeed results in the loss of the main activity peak and in a dramatic reduction of total HDAC activity. In contrast to its orthologs in yeast and higher eukaryotes, HdaA has strong intrinsic activity as a protein monomer when expressed as a recombinant protein in a prokaryotic expression system. In vivo, HdaA is involved in the regulation of enzymes which are of vital importance for the cellular antioxidant response in A. nidulans. Consequently, deltahdaA strains exhibit significantly reduced growth on substrates whose catabolism generates molecules responsible for oxidative stress conditions in the fungus. Our analysis revealed that reduced expression of the fungal catalase CatB is jointly responsible for the significant growth reduction of the hdaA mutant strains.

Class II (IIa)-selective histone deacetylase inhibitors. 1. Synthesis and biological evaluation of novel (aryloxopropenyl)pyrrolyl hydroxyamides.

Chemical manipulations performed on aroyl-pyrrolyl-hydroxyamides (APHAs) led to (aryloxopropenyl)pyrrolyl hydroxamates 2a-w, and their inhibition against maize HDACs and their class I or class II HDAC selectivity were determined. In particular, from these studies some benzene meta-substituted compounds emerged as highly class II (IIa)-selective HDAC inhibitors, the most selective being the 3-chloro- and 3-fluoro-substituted compounds 2c (SI = 71.4) and2f (SI = 176.4). The replacement of benzene with a 1-naphthyl ring afforded 2s, highly active against the class II homologue HD1-A (IC(50) = 10 nM) but less class II-selective than 2c,f. When tested against human HDAC1 and HDAC4, 2f showed no inhibitory activity against HDAC1 but was able to inhibit HDAC4. Moreover, in human U937 acute myeloid leukaemia cells 2f did not produce any effect on apoptosis, granulocytic differentiation, and the cell cycle, whereas 2s (that retain class I HDAC inhibitory activity) was 2-fold less potent than SAHA used as reference.

Mad1 function in cell proliferation and transcriptional repression is antagonized by cyclin E/CDK2.

The transcription factors of the Myc/Max/Mad network play essential roles in the regulation of cellular behavior. Mad1 inhibits cell proliferation by recruiting an mSin3-corepressor complex that contains histone deacetylase activity. Here we demonstrate that Mad1 is a potent inhibitor of the G(1) to S phase transition, a function that requires Mad1 to heterodimerize with Max and to bind to the corepressor complex. Cyclin E/CDK2, but not cyclin D and cyclin A complexes, fully restored S phase progression. In addition inhibition of colony formation and gene repression by Mad1 were also efficiently antagonized by cyclin E/CDK2. This was the result of cyclin E/CDK2 interfering with the interaction of Mad1 with HDAC1 and reducing HDAC activity. Our findings define a novel interplay between the cell cycle regulator cyclin E/CDK2 and Mad1 and its associated repressor complex and suggests an additional mechanism how cyclin E/CDK2 affects the G(1) to S phase transition.

Histone methyltransferases in Aspergillus nidulans: evidence for a novel enzyme with a unique substrate specificity.

We have studied enzymes involved in histone arginine methylation in the filamentous fungus Aspergillus nidulans. Three distinct protein arginine methyltransferases (PRMTs) could be identified, which all exhibit intrinsic histone methyltransferase activity when expressed as glutathione S-transferase (GST) fusion proteins. Two of these proteins, termed RmtA (arginine methyltransferase A) and RmtC, reveal significant sequence homology to the well-characterized human proteins PRMT1 and PRMT5, respectively. Native as well as recombinant RmtA is specific for histone H4 with arginine 3 as the methylation site. Furthermore, methylation of histone H4 by recombinant RmtA affects the acetylation by p300/CBP, supporting an interrelation of histone methylation and acetylation in transcriptional regulation. The second methyltransferase, named RmtB, is only distantly related to human/rat PRMT3 and must be considered as a member of a separate group within the PRMT family. The 61 kDa protein, expressed as a GST fusion protein, exhibits a unique substrate specificity in catalyzing the methylation of histones H4, H3, and H2A. Unlike human PRMT3, the Aspergillus enzyme lacks a Zn-finger domain in the amino-terminal part indicating functional differences of RmtB. Furthermore, phylogenetic analysis indicated that RmtB together with other fungal homologues is a member of a separate group within the PRMT proteins. The existence of in vivo arginine methylation on histones as demonstrated by site-specific antibodies and the high level and specificity of PRMTs for individual core histones in A. nidulans suggests an important role of these enzymes for chromatin modulating activities.

A new amidohydrolase from Bordetella or Alcaligenes strain FB188 with similarities to histone deacetylases.

The full-length gene encoding the histone deacetylase (HDAC)-like amidohydrolase (HDAH) from Bordetella or Alcaligenes (Bordetella/Alcaligenes) strain FB188 (DSM 11172) was cloned using degenerate primer PCR combined with inverse-PCR techniques and ultimately expressed in Escherichia coli. The expressed enzyme was biochemically characterized and found to be similar to the native enzyme for all properties examined. Nucleotide sequence analysis revealed an open reading frame of 1,110 bp which encodes a polypeptide with a theoretical molecular mass of 39 kDa. Interestingly, peptide sequencing disclosed that the N-terminal methionine is lacking in the mature wild-type enzyme, presumably due to the action of methionyl aminopeptidase. Sequence database searches suggest that the new amidohydrolase belongs to the HDAC superfamily, with the closest homologs being found in the subfamily assigned acetylpolyamine amidohydrolases (APAH). The APAH subfamily comprises enzymes or putative enzymes from such diverse microorganisms as Pseudomonas aeruginosa, Archaeoglobus fulgidus, and the actinomycete Mycoplana ramosa (formerly M. bullata). The FB188 HDAH, however, is only moderately active in catalyzing the deacetylation of acetylpolyamines. In fact, FB188 HDAH exhibits significant activity in standard HDAC assays and is inhibited by known HDAC inhibitors such as trichostatin A and suberoylanilide hydroxamic acid (SAHA). Several lines of evidence indicate that the FB188 HDAH is very similar to class 1 and 2 HDACs and contains a Zn(2+) ion in the active site which contributes significantly to catalytic activity. Initial biotechnological applications demonstrated the extensive substrate spectrum and broad optimum pH range to be excellent criteria for using the new HDAH from Bordetella/Alcaligenes strain FB188 as a biocatalyst in technical biotransformations, e.g., within the scope of human immunodeficiency virus reverse transcriptase inhibitor synthesis.

A plant dialect of the histone language.

The genome contains all the information needed to build an organism. However, during differentiation and development, additional epigenetic information determines the functional state of cells and tissues. This epigenetic information can be introduced by cytosine methylation and by marking nucleosomal histones. The code written on histones consists of post-translational modifications, including acetylation and methylation. In contrast to the universal nature of the DNA code, the histone language and its decoding machinery differ among animals, plants and fungi. Plant cells have retained totipotency to generate the entire plant and maintained the ability to dedifferentiate, which suggests that the establishment and maintenance of epigenetic information differs from animals. Here, I aim to summarize the histone code and plant-specific aspects of setting and translating the code.

3-(4-Aroyl-1-methyl-1H-pyrrol-2-yl)-N-hydroxy-2-propenamides as a new class of synthetic histone deacetylase inhibitors. 3. Discovery of novel lead compounds through structure-based drug design and docking studies.

Aroyl-pyrrole-hydroxy-amides (APHAs) are a new class of synthetic HDAC inhibitors recently described by us. Through three different docking procedures we designed, synthesized, and tested two new isomers of APHA lead compound 3-(4-benzoyl-1-methyl-1H-pyrrol-2-yl)-N-hydroxy-2-propenamide (1), compounds 3 and 4, characterized by different insertions of benzoyl and propenoylhydroxamate groups onto the pyrrole ring. Biological activities of 3 and 4 were predicted by computational tools up to 617-fold more potent than that of 1 against HDAC1; thus, 3 and 4 were synthesized and tested against both mouse HDAC1 and maize HD2 enzymes. Predictions of biological affinities (K(i) values) of 3 and 4, performed by a VALIDATE model (applied on either SAD or automatic DOCK or Autodock results) and by the Autodock internal scoring function, were in good agreement with experimental activities. Ligand/receptor positive interactions made by 3 and 4 into the catalytic pocket, in addition to those showed by 1, could at least in part account for their higher HDAC1 inhibitory activities. In particular, in mouse HDAC1 inhibitory assay 3 and 4 were 19- and 6-times more potent than 1, respectively, and 3 and 4 antimaize HD2 activities were 16- and 76-times higher than that of 1, 4 being as potent as SAHA in this assay. Compound 4, tested as antiproliferative and cytodifferentiating agent on MEL cells, showed dose-dependent growth inhibition and hemoglobin accumulation effects.

3-(4-Aroyl-1-methyl-1H-2-pyrrolyl)-N-hydroxy-2-propenamides as a new class of synthetic histone deacetylase inhibitors. 2. Effect of pyrrole-C2 and/or -C4 substitutions on biological activity.

Previous SAR studies (Part 1: Mai, A.; et al. J. Med. Chem. 2003, 46, 512-524) performed on some portions (pyrrole-C4, pyrrole-N1, and hydroxamate group) of 3-(4-benzoyl-1-methyl-1H-pyrrol-2-yl)-N-hydroxy-2-propenamide (1a) highlighted its 4-phenylacetyl (1b) and 4-cynnamoyl (1c) analogues as more potent compounds in inhibiting maize HD2 activity in vitro. In the present paper, we investigated the effect on anti-HD2 activity of chemical substitutions performed on the pyrrole-C2 ethene chains of 1a-c, which were replaced with methylene, ethylene, substituted ethene, and 1,3-butadiene chains (compounds 2). Biological results clearly indicated the unsubstituted ethene chain as the best structural motif to get the highest HDAC inhibitory activity, the sole exception to this rule being the introduction of the 1,3-butadienyl moiety into the 1a chemical structure (IC50(2f) = 0.77 microM; IC50(1a) = 3.8 microM). IC50 values of compounds 3, prepared as 1b homologues, revealed that between benzene and carbonyl groups at the pyrrole-C(4) position a hydrocarbon spacer length ranging from two to five methylenes is well accepted by the APHA template, being that 3a (two methylenes) and 3d (five methylenes) are more potent (2.3- and 1.4-fold, respectively) than 1b, while the introduction of a higher number of methylene units (see 3e,f) decreased the inhibitory activities of the derivatives. Particularly, 3a (IC50 = 0.043 microM) showed the same potency as SAHA in inhibiting HD2 in vitro, and it was 3000- and 2.6-fold more potent than sodium valproate and HC-toxin and was 4.3- and 6-fold less potent than trapoxin and TSA, respectively. Finally, conformationally constrained forms of 1b,c (compounds 4), prepared with the aim to obtain some information potentially useful for a future 3D-QSAR study, showed the same (4a,b) or higher (4c,d) HD2 inhibiting activities in comparison with those of the reference drugs. Molecular modeling and docking calculations on the designed compounds performed in parallel with the chemistry work fully supported the synthetic effort and gave insights into the binding mode of the more flexible APHA derivatives (i.e., 3a). Despite the difference of potency between 1b and 3a in the enzyme assay, the two APHA derivatives showed similar antiproliferative and cytodifferentiating activities in vivo on Friends MEL cells, being that 3a is more potent than 1b in the differentiation assay only at the highest tested dose (48 microM).

Discovery of (aryloxopropenyl)pyrrolyl hydroxyamides as selective inhibitors of class IIa histone deacetylase homologue HD1-A.

Chemical manipulations performed on aroyl pyrrolyl hydroxyamides, a new class of HDAC inhibitors previously reported by us, led to (aryloxopropenyl)pyrrolyl hydroxyamides 3a-g. Such compounds, showing better inhibitory activity against maize HD1-A than HD1-B (two homologues of mammalian class IIa and I HDACs, respectively), are the first class of IIa-selective inhibitors (fold selectivity: 7-78). They could be useful as tools for probing the biology of these enzymes and eventually as new anticancer agents with low toxicity.

Regulation and processing of maize histone deacetylase Hda1 by limited proteolysis.

A maize histone deacetylase gene was identified as a homolog of yeast Hda1. The predicted protein corresponds to a previously purified maize deacetylase that is active as a protein monomer with a molecular weight of 48,000 and is expressed in all tissues of germinating embryos. Hda1 is synthesized as an enzymatically inactive protein with an apparent molecular weight of 84,000 that is processed to the active 48-kD form by proteolytic removal of the C-terminal part, presumably via a 65-kD intermediate. The enzymatically inactive 84-kD protein also is part of a 300-kD protein complex of unknown function. The proteolytic cleavage of ZmHda1 is regulated during maize embryo germination in vivo. Expression of the recombinant full-length protein and the 48-kD form confirmed that only the smaller enzyme form is active as a histone deacetylase. In line with this finding, we show that the 48-kD protein is able to repress transcription efficiently in a reporter gene assay, whereas the full-length protein, including the C-terminal part, lacks full repression activity. This report on the processing of Hda1-p84 to enzymatically active Hda1-p48 demonstrates that proteolytic cleavage is a mechanism to regulate the function of Rpd3/Hda1-type histone deacetylases.

Histone deacetylases in fungi: novel members, new facts.

Acetylation is the most prominent modification on core histones that strongly affects nuclear processes such as DNA replication, DNA repair and transcription. Enzymes responsible for the dynamic equilibrium of histone acetylation are histone acetyltransferases (HATs) and histone deacetylases (HDACs). In this paper we describe the identification of novel HDACs from the filamentous fungi Aspergillus nidulans and the maize pathogen Cochliobolus carbonum. Two of the enzymes are homologs of Saccharomyces cerevisiae HOS3, an enzyme that has not been identified outside of the established yeast systems until now. One of these homologs, HosB, showed intrinsic HDAC activity and remarkable resistance against HDAC inhibitors like trichostatin A (TSA) when recombinant expressed in an Escherichia coli host system. Phylo genetic analysis revealed that HosB, together with other fungal HOS3 orthologs, is a member of a separate group within the classical HDACs. Immunological investigations with partially purified HDAC activities of Aspergillus showed that all classical enzymes are part of high molecular weight complexes and that a TSA sensitive class 2 HDAC constitutes the major part of total HDAC activity of the fungus. However, further biochemical analysis also revealed an NAD(+)-dependent activity that could be separated from the other activities by different types of chromatography and obviously represents an enzyme of the sirtuin class.

3-(4-Aroyl-1-methyl-1H-2-pyrrolyl)-N-hydroxy-2-alkylamides as a new class of synthetic histone deacetylase inhibitors. 1. Design, synthesis, biological evaluation, and binding mode studies performed through three different docking procedures.

Recently we reported a novel series of hydroxamates, called 3-(4-aroyl-1H-2-pyrrolyl)-N-hydroxy-2-propenamides (APHAs), acting as HDAC inhibitors (Massa, S.; et al. J. Med. Chem. 2001, 44, 2069-2072). Among them, 3-(4-benzoyl-1-methyl-1H-2-pyrrolyl)-N-hydroxy-2-propenamide 1 was chosen as lead compound, and its binding mode into the modeled HDAC1 catalytic core together with its histone hyperacetylation, antiproliferative, and cytodifferentiating properties in cell-based assays were investigated (Mai, A.; et al. J. Med. Chem. 2002, 45, 1778-1784). Here we report the results of some chemical manipulations performed on (i) the aroyl portion at the C4-pyrrole position, (ii) the N(1)-pyrrole substituent, and (iii) the hydroxamate moiety of 1 to determine structure-activity relationships and to improve enzyme inhibitory activity of APHAs. In the 1 structure, pyrrole N(1)-substitution with groups larger than methyl gave a reduction in HDAC inhibiting activity, and replacement of hydroxamate function with various non-hydroxamate, metal ion-complexing groups yielded poorly active or totally inactive compounds. On the contrary, proper substitution at the C4-position favorably affected enzyme inhibiting potency, leading to 8 (IC50 = 0.1 micro M) and 9 (IC50 = 1.0 micro M) which were 38- and 3.8-fold more potent than 1 in in vitro anti-HD2 assay. Against mouse HDAC1, 8 showed an IC50 = 0.5 micro M (IC50 of 1 = 4.9 micro M), and also in cell-based assay, 8 was endowed with higher histone hyperacetylating activity than 1, although it was less potent than TSA and SAHA. Such enhancement of inhibitory activity can be explained by the higher flexibility of the pyrrole C4-substituent of 8 which accounts for a considerably better fitting into the HDAC1 pocket and a more favorable enthalpy ligand receptor energy compared to 1. The enhanced fit allows a closer positioning of 8 hydroxamate moiety to the zinc ion. These findings were supported by extensive docking studies (SAD, DOCK, and Autodock) performed on both APHAs and reference drugs (TSA and SAHA).

Molecular identification of PpHDAC1, the first histone deacetylase fron the slime mold Physarum polycephalum.

The dynamic state of post-translational acetylation of eukaryotic histones is maintained by histone acetyltransferases (HATs) and histone deacetylases (HDACs). HATs and HDACs have been shown to be components of various regulatory protein complexes in the cell. Their enzymatic activities, intracellular localization and substrate specificities are regulated in a complex, cell cycle related manner. In the myxomycete Physarum polycephalum multiple HATs and HDACs can be distinguished in biochemical terms and they exhibit dynamic activity patterns depending on the cell cycle stage. Here we report on the cloning of the first P. polycephalum HDAC (PpHDAC1) related to the S. cerevisiae Rpd3 protein. The expression pattern of PpHDAC1 mRNA was analysed at different time points of the cell cycle and found to be largely constant. Treatment of macroplasmodia with the HDAC inhibitor trichostatin A at several cell cycle stages resulted in a significant delay in entry into mitosis of treated versus untreated plasmodia. No effect of TSA treatment could be observed on PpHDAC1 expression itself.