In contrast to studies on class I histone deacetylase (HDAC) inhibitors, the elucidation of the molecular mechanisms and therapeutic potential of class IIa HDACs (HDAC4, HDAC5, HDAC7 and HDAC9) is impaired by the lack of potent and selective chemical probes. Here we report the discovery of inhibitors that fill this void with an unprecedented metal-binding group, trifluoromethyloxadiazole (TFMO), which circumvents the selectivity and pharmacologic liabilities of hydroxamates. We confirm direct metal binding of the TFMO through crystallographic approaches and use chemoproteomics to demonstrate the superior selectivity of the TFMO series relative to a hydroxamate-substituted analog. We further apply these tool compounds to reveal gene regulation dependent on the catalytic active site of class IIa HDACs. The discovery of these inhibitors challenges the design process for targeting metalloenzymes through a chelating metal-binding group and suggests therapeutic potential for class IIa HDAC enzyme blockers distinct in mechanism and application compared to current HDAC inhibitors.
Histone deacetylases (HDACs) represent an expanding family of protein modifying-enzymes that play important roles in cell proliferation, chromosome remodeling, and gene transcription. We have previously shown that recombinant human HDAC8 can be expressed in bacteria and retain its catalytic activity. To further explore the catalytic activity of HDACs, we expressed two additional human class I HDACs, HDAC1 and HDAC3, in baculovirus. Recombinant HDAC1 and HDAC3 fusion proteins remained soluble and catalytically active and were purified to near homogeneity. Interestingly, trichostatin (TSA) was found to be a potent inhibitor for all three HDACs (IC 50 value of ϳ0.1-0.3 M), whereas another HDAC inhibitor MS-27-275 (N-(2-aminophenyl)-4-[N-(pyridin-3-methyloxycarbonyl)-aminomethyl]benzamide) preferentially inhibited HDAC1 (IC 50 value of ϳ0.3 M) versus HDAC3 (IC 50 value of ϳ8 M) and had no inhibitory activity toward HDAC8 (IC 50 value Ͼ100 M). MS-27-275 as well as TSA increased histone H4 acetylation, induced apoptosis in the human colon cancer cell line SW620, and activated the simian virus 40 early promoter. HDAC1 protein was more abundantly expressed in SW620 cells compared with that of HDAC3 and HDAC8. Using purified recombinant HDAC proteins, we identified several novel HDAC inhibitors that preferentially inhibit HDAC1 or HDAC8. These inhibitors displayed distinct properties in inducing histone acetylation and reporter gene expression. These results suggest selective HDAC inhibitors could be identified using recombinantly expressed HDACs and that HDAC1 may be a promising therapeutic target for designing HDAC inhibitors for proliferative diseases such as cancer.
The p170 and p180 forms of topoisomerase II have been compared. The concentration dependence of ATP for catalytic activity of the two forms of the enzyme was identical, and each was equally sensitive to novobiocin. Orthovanadate was found to be a potent inhibitor of catalytic activity of both p170 and p180, with an IC50 value of about 2 microM for each. Under standard reaction conditions, relaxation of supercoiled pBR322 by p180 was highly processive, while p170 performed the same reaction in a distributive manner. The optimal concentration of KCl for catalytic activity of p180 was 20-30 mM higher than that for p170. Comparison of their thermal stability showed that p180 was inactivated at twice the rate of p170. Teniposide and merbarone selectively inhibited catalytic activity of p170, requiring concentrations 3-fold and 8-fold lower, respectively, than those required for equivalent inhibition of p180. Similar selectivity for p170 was seen for teniposide-stimulated DNA cleavage or its inhibition by merbarone. Analysis of sites of DNA cleavage indicated a subset of sites that were either preferred or unique for each of the enzymes. A synthetic oligonucleotide representative of p170 sites selectively inhibited the p170 enzyme. Immunoblotting of p170 and p180 from U937 cells at different stages of proliferation showed that p170 levels declined as the cells reached the plateau phase of growth, while p180 levels were low during rapid proliferation and increased as the growth rate slowed. The data indicate that the p170 and p180 forms of topoisomerase II can be distinguished biochemically, pharmacologically, and by differential cellular regulation.
The hepatitis C virus (HCV) NS5B protein encodes an RNA-dependent RNA polymerase (RdRp), the primary catalytic enzyme of the HCV replicase complex. We established a biochemical RNA synthesis assay, using purified recombinant NS5B lacking the C-terminal 21 amino acid residues, to identify potential polymerase inhibitors from a high throughput screen of the GlaxoSmithKline proprietary compound collection. The benzo-1,2,4-thiadiazine compound 1 was found to be a potent, highly specific inhibitor of NS5B. This agent interacts directly with the viral polymerase and inhibits RNA synthesis in a manner noncompetitive with respect to GTP. Furthermore, in the absence of an in vitro-reconstituted HCV replicase assay employing viral and host proteins, the ability of compound 1 to inhibit NS5B-directed viral RNA replication was determined using the Huh7 cell-based HCV replicon system. Compound 1 reduced viral RNA in replicon cells with an IC 50 of ϳ0.5 M, suggesting that the inhibitor was able to access the perinuclear membrane and inhibit the polymerase activity in the context of a replicase complex. Preliminary structure-activity studies on compound 1 led to the identification of a modified inhibitor, compound 4, showing an improvement in both biochemical and cell-based potency. Lastly, data are presented suggesting that these compounds interfere with the formation of negative and positive strand progeny RNA by a similar mode of action. Investigations are ongoing to assess the potential utility of such agents in the treatment of chronic HCV disease.Hepatitis C virus (HCV), 1 a positive strand RNA virus of the Flaviviridae family, is the major etiological agent of post-transfusion and sporadic non-A, non-B hepatitis (1). An estimated 2-3% of the world population is chronically infected with HCV, which causes significant liver disease, cirrhosis, and can eventually lead to the development of hepatocellular carcinoma. In infected cells, translation of the viral RNA yields a 3011-residue polyprotein chain (2-4), which is subsequently cleaved to generate envelope and core proteins, for assembly of new virus particles and nonstructural enzymes essential for viral replication (5-7). Studies using recombinant NS5B polymerase have provided direct evidence for RNA-dependent RNA polymerase activity (8, 9), and this catalytic activity has been confirmed to be required for infectivity in chimpanzees (10).NS5B polymerase contains a hydrophobic C-terminal domain thought to be responsible for anchoring the protein to mammalian cell membranes. Removal of the C-terminal 21 residues has been reported to facilitate protein isolation from Escherichia coli without compromising RdRp activity (11). The HCV RdRp initiates RNA synthesis preferentially from the 3Ј terminus of the template RNA (12, 13-15) but lacks specificity for HCV RNA in vitro, because it readily utilizes heterologous nonviral templates (8). Based on crystallographic studies of the enzyme containing C-terminal truncations (16, 17), the hydrophobic tail present in the full-length ...
c-Abl kinase activity is regulated by a unique mechanism involving the formation of an autoinhibited conformation in which the N-terminal myristoyl group binds intramolecularly to the myristoyl binding site on the kinase domain and induces the bending of the αI helix that creates a docking surface for the SH2 domain. Here, we report a small-molecule c-Abl activator, DPH, that displays potent enzymatic and cellular activity in stimulating c-Abl activation. Structural analyses indicate that DPH binds to the myristoyl binding site and prevents the formation of the bent conformation of the αI helix through steric hindrance, a mode of action distinct from the previously identified allosteric c-Abl inhibitor, GNF-2, that also binds to the myristoyl binding site. DPH represents the first cell-permeable, small-molecule tool compound for c-Abl activation.
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