Discovery of a series of small molecules as potent histone deacetylase inhibitors

Abstract

A series of small molecules were designed and synthesized based on our previous virtual screening approach, which was performed to discover potent histone deacetylase inhibitors (HDACIs) with novel structures. The derived compounds were tested by Hela cell nucleus extract for enzyme inhibition assay. Tumor cell growth inhibition assays were performed using a series of tumor cell lines. Molecule 4h has the best performance among these compounds with enzyme inhibition IC₅₀ of 0.14?μM and tumor cell growth inhibition IC₅₀ of 1.85 (U937), 2.02 (HL60), 2.67 (K562). Docking studies showed that multiple H-bonds and hydrophobic interactions make 4h binding to the active site of HDAC. 4h has the advantage of low molecular weight, so a variety of structural modifications can be performed in our further studies.     

Effect of wine inhibitors on the proteolytic activity of papain from Carica papaya L. latex

The influence of potential inhibitors naturally present in wine on the proteolytic activity of papain from Carica papaya latex was investigated to evaluate its applicability in white wine protein haze stabilization. Enzymatic activity was tested against a synthetic tripeptide chromogenic substrate in wine‐like acidic medium that consisted of tartaric buffer (pH 3.2) supplemented with ethanol, free sulfur dioxide (SO₂), grape skin and seed tannins within the average ranges of concentrations that are typical in wine. The diagnosis of inhibition type, performed with the graphical method, demonstrated that all of tested wine constituents were reversible inhibitors of papain. The strongest inhibition was exerted by free SO₂, which acted as a mixed‐type inhibitor, similar to grape skin and seed tannins. Finally, when tested in table white wines, the catalytic activity of papain, even when if it was ascribable to the hyperbolic behavior of Michaelis‐Menten equation, was determined to be strongly affected by free SO₂ and total phenol level. © 2014 American Institute of Chemical Engineers Biotechnol. Prog., 31:48–54, 2015     

Structural analysis of PI3-kinase isoforms: identification of residues enabling selective inhibition by small molecule ATP-competitive inhibitors

A series of small molecule, ATP-competitive phosphoinositide 3-kinase inhibitors have been examined in homology models of the four class I isoforms, p110α, p110β, p110δ and p110γ. This analysis provided an insight into the mode of binding of these inhibitors to the hinge and to other key regions of the ATP binding site in each of the four subtypes. Significantly, residues were identified that differ between these proteins, and which help explain the isoform-selective inhibition profiles of the compounds.     

Immobilization of papain on cotton fabric by sol–gel method

A method has been developed to immobilize papain on cotton fabric by means of sol–gel technique. The activity of free papain and papain in silica sol under sonication was studied. Scanning electron microscopy, energy dispersive spectrometer and the Bradford method were used to characterize papain immobilization. The efficiency of the immobilization was investigated by examining the relative enzymatic activity of free and immobilized papain, respectively. The results show that the optimum pH value in the medium for immobilized papain is shifted to alkaline side. In addition, the adaptability of papain to environmental acidity is significantly increased. The thermostability of immobilized papain shows no significant change compared to the free enzyme. The papain immobilized on fabric by sol–gel technique retains more than 30% of the original activity after six reuses continuously.     

Design,synthesis and in vitro evaluation studies of sulfonyl-amino-acetamides as small molecule BACE-1 inhibitors

The identification of a series of sulfonyl-amino-acetamides as BACE-1 (β-secretase) inhibitors for the treatment of Alzheimer’s disease is reported. The derivatives were designed based on the docking simulation study, synthesized and assessed for BACE-1 inhibition in vitro. The designed ligands revealed desired binding interactions with the catalytic aspartate dyad and occupance of S1 and S2′ active site regions. These in silico results correlated well with in vitro activity. Out of 33 compounds synthesized, 12 compounds showed significant inhibition at 10 μM concentration. The most active compound 2.17S had IC₅₀ of 7.90 μM against BACE-1, which was concomitant with results of in silico docking study.     

Evaluation of new antimicrobial agents on Bacillus spp. strains: docking affinity and in vitro inhibition of glutamate-racemase

Three glutamic acid derivatives, two boron-containing and one imide-containing compound, were synthesized and tested for antimicrobial activity targeting glutamate-racemase. Antimicrobial effect was evaluated over Bacillus spp. Docking analysis shown that the test compounds bind near the active site of racemase isoforms, suggesting an allosteric effect. The boron derivatives had greater affinity than the imide derivative. In vitro assays shown good antimicrobial activity for the boron-containing compounds, and no effectiveness for the imide-containing compounds. The minimum inhibitory concentration of tetracycline, used as standard, was lower than that of the boron-containing derivatives. However, it seems that the boron-containing derivatives are more selective for bacteria. Experimental evidence suggests that the boron-containing derivatives act by inhibiting the racemase enzyme. Therefore, these test compounds probably impede the formation of the bacterial cell wall. Thus, the boron-containing glutamic acid derivatives should certainly be of interest for future studies as antimicrobial agents for Bacillus spp.     

Identification of small molecule inhibitors against UBE2C by using docking studies

An increased expression of UBE2C (Ubiquitin-conjugating enzyme E2C) has been associated with high tumor grade and cancer progression. It is an essential indicator of the mitotic destruction events. Our microarray study on cervical cancers showed UBE2C to be over expressed in cervical cancer. Subsequent studies from our laboratory, showed that inhibition of UBE2C can enhance radiation and chemosensitivity. Therefore it can be an appropriate target for drug development to identify potential and specific inhibitor of cancer. To identify small molecule inhibitors, a computational approach was used to model UBE2C and further docking studies were carried out. Different ligand subsets such as ChemBank, PDB, KEGG, Drug-likeness NCI, Not annotated NCI of ligand library ligands were downloaded and docked with UBE2C. Schrodinger tools were used for identifying active sites and docking studies of ligands with UBE2C. Based on glide score, the potential ligands were screened and its interaction with UBE2C was identified. We also analyzed the drug like properties such as absorption, distribution, metabolism, excretion and toxicity (ADME/T) of docked compounds. Our results suggest that 2,4-diimino-1-methyl-1,3,5-triazepan-6-one, sulfuric acid compound with 5,6-diamino-2,4-pyrimidinediol (1:1) and 7-alpha-d-ribofuranosyl-2-aminopurine-5''-phosphate may act as best inhibitors and further in vitro studies, may lead to development of novel and best inhibitor of UBE2C.     

Synthesis,anticancer, and docking studies of salicyl-hydrazone analogues: A novel series of small potent tropomyosin receptor kinase A inhibitors

A series of novel salicyl-hydrazone analogues were synthesized and evaluated for their in vitro cytotoxic activities in five human cancer cell lines, namely, lung cancer (A549), ovarian cancer (SK-OV-3), skin cancer (SK-MEL-2), colon cancer (HCT15) and pancreatic cancer (MIA-PaCa-2) cells, and for their in vitro tropomyosin receptor kinase A (TrkA) inhibitory activities. Each of the compounds showed significant cytotoxicity against all cancer cells. Compound 3i was found to be most potent against all cancer cell lines with IC₅₀ values of 2.46 (A549), 0.87 (SK-OV-3), 1.43 (SK-MEL-2), 0.89 (HCT15), and 0.48 μM (MIA-PaCa-2), followed by compound 3l. Cytotoxicity of 3i was similar to that of doxorubicin (0.87 μM) against HCT15 cells. Compounds 3i and 3l also showed highest TrkA inhibitory activities with IC₅₀ values of 0.231 and 0.380 μM, respectively. A SAR study of the series revealed that compounds with hydroxyl groups showed better cytotoxicity and TrkA inhibitory potency (in the following order 2,4-OH > 2,3,4-OH > 3,4-OH > 4-OH) than compounds possessing electron donating or withdrawing groups on the benzylidenephenyl ring. Docking studies of compounds 3i and 3l conducted on the crystal structure of TrkA receptor (a promising target for anticancer agents) showed both had a high docking score and similar order of experimental TrkA inhibitory activities. The formation of several hydrogen bonds involving N and O containing moieties contributed most significantly to ligand binding and stabilization at the active site of the receptor. In addition, ligand-receptor complexes were further stabilized by π-cation, π-anion, amide-π stacked, and van der Waal’s interactions. Conformational analyses showed ligand molecules adopted similar conformations at the receptor active site during interactions, but that the low energy optimized conformations of compounds 3i and 3l differed.     

Discovery of a cobalt complex with high MEK1 binding affinity

A series of Schiff base ligands (L¹–L⁵) and their cobalt(II) complexes (1–5) were designed and synthesized for MEK1 binding experiment. The biological evaluation results showed that Bis(N,N′-disalicylidene)-3,4-phenylenediamine-cobalt(II) 1 and Bis(N,N′-disalicylidene)-1,2-cyclohexanediamine-cobalt(II) 2 are much more effective than the parent Schiff bases (L¹ and L²). Importantly, 2 exhibited MEK1 binding affinity with IC₅₀71 nM, which is so far the best result for metal complexes and more potent than U0126 (7.02 μM) and AZD6244 (2.20 μM). Docking study was used to elucidate the binding modes of complex 2 with MEK1. Thus cobalt(II) complex 2 may be further developed as a novel MEK1 inhibitor.     

Design, synthesis and biological evaluation of small molecule inhibitors of CD4-gp120 binding based on virtual screening

The low-molecular-weight compound JRC-II-191 inhibits infection of HIV-1 by blocking the binding of the HIV-1 envelope glycoprotein gp120 to the CD4 receptor and is therefore an important lead in the development of a potent viral entry inhibitor. Reported here is the use of two orthogonal screening methods, gold docking and ROCS shape-based similarity searching, to identify amine-building blocks that, when conjugated to the core scaffold, yield novel analogs that maintain similar affinity for gp120. Use of this computational approach to expand SAR produced analogs of equal inhibitory activity but with diverse capacity to enhance viral infection. The novel analogs provide additional lead scaffolds for the development of HIV-1 entry inhibitors that employ protein-ligand interactions in the vestibule of gp120 Phe 43 cavity.     

Rational design,synthesis, pharmacophore modeling,and docking studies for identification of novel potent DNA-PK inhibitors

Drugs of cancer based upon ionizing radiation or chemotherapeutic treatment may affect breaking of DNA double strand in cell. DNA-PK enzyme has emerged as an attractive target for drug discovery efforts toward DNA repair pathways. Hence, the search for potent and selective DNA-PK inhibitors has particularly considered state-of-the art and several series of inhibitors have been designed. In this article, a novel benchmark DNA-PK database of 43 compounds was built and described. Ligand-based approaches including pharmacophore and QSAR modeling were applied and novel models were introduced and analyzed for predicting activity test for DNA-PK drug candidates. Based upon the modeling results, we gave a report of synthesis of fifteen novel 2-((8-methyl-2-morpholino-4-oxo-4H-benzo[e][1,3]oxazin-7-yl)oxy)acetamide derivatives and in vitro evaluation for DNA-PK inhibitory and antiproliferative activities. These fifteen compounds overall are satisfied with Lipinski's rule of five. The biological testing of target compounds showed five promising active compounds 7c, 7d, 7f, 9e and 9f with micromolar DNA-PK activity range from 0.25 to 5 µM. In addition, SAR of the compounds activity was investigated and confirmed that the terminal aryl moiety was found to be quite crucial for DNA-PK activity. Moreover flexible docking simulation was done for the potent compounds into the putative binding site of the 3D homology model of DNA-PK enzyme and the probable interaction model between DNA-PK and the ligands was investigated and interpreted.     

Asymmetric synthesis and affinity of potent sialyltransferase inhibitors based on transition-state analogues

Inhibitors that are structurally related to the transition-state model of the proposed SN1-type mechanism of sialyl transfer, exhibit particularly high binding affinities to alpha(2-6)sialyltransferases. Furthermore, replacing the neuraminyl residue with a simple aryl or hetaryl ring and substituting the carboxylate group for a phosphonate moiety, improves both binding affinity and synthetic accessibility. Herein we report on the synthesis and inhibition of a wide range of novel, potent transition-state analogue based alpha(2-6)sialyltransferase inhibitors comprising a planar anomeric carbon, an increased distance between the anomeric carbon and the CMP leaving group, and at least two negative charges. We also present a short, efficient asymmetric synthesis of the most promising benzyl inhibitors, providing rapid access to large quantities of highly potent, stereochemically-pure (>96% de) inhibitors for further biological investigation (e.g.(R)-3b, Ki = 70 nM).     

Novel strategy to boost oral anticoagulant activity of blood coagulation enzyme inhibitors based on biotransformation into hydrophilic conjugates

The blood coagulation cascade represents an attractive target for antithrombotic drug development, and recent studies have attempted to identify oral anticoagulants with inhibitory activity for enzymes in this cascade, with particular attention focused on thrombin and factor Xa (fXa) as typical targets. We previously described the discovery of the orally active fXa inhibitor darexaban (1) and reported a unique profile that compound 1 rapidly transformed into glucuronide YM-222714 (2) after oral administration. Here, we propose a novel strategy towards the discovery of an orally active anticoagulant that is based on the bioconversion of a non-amidine inhibitor into the corresponding conjugate to boost ex vivo anticoagulant activity via an increase in hydrophilicity. Computational molecular modeling was utilized to select a template scaffold and design a substitution point to install a potential functional group for conjugation. This strategy led to the identification of the phenol-derived fXa inhibitor ASP8102 (14), which demonstrated highly potent anticoagulant activity after biotransformation into the corresponding glucuronide (16) via oral dosing.     

Biological evaluation and docking studies of natural isocoumarins as inhibitors for human kallikrein 5 and 7

Human kallikrein 5 and 7 (KLK5 and KLK7) are trypsin-like and chymotrypsin-like serine proteases, respectively, and promising targets for the treatment of skin desquamation, inflammation and cancer. In an effort to develop new inhibitors for these enzymes, we carried out enzymatic inhibition assays and docking studies with three isocoumarin compounds. Some promising inhibitors were uncovered, with vioxanthin and 8,8'-paepalantine being the most potent competitive inhibitors of KLK5 (K(i)=22.9 μM) and KLK7 (K(i)=12.2 μM), respectively. Our docking studies showed a good correlation with the experimental results, and revealed a distinct binding mode for the inhibitors at the binding sites of KLK5 and KLK7. In addition, the docking results suggested that the formation of hydrogen bonds at the oxyanion hole is essential for a good inhibitor.     

Effect of solid-state buffers on the catalytic activity of papain in low water media

The catalytic activity of papain in the synthesis of Z-Gly-Phe-NH₂ in tert-butanol has been studied in the presence of solid-state acid–base buffers (acids and their sodium salts). All buffer pairs tested reduced the reaction rate compared with the control, particularly the most acidic and basic (assessed by either aqueous pK_a or the response of an organic phase indicator). The highest rates, close to the control, were found with glutamic acid/glutamate-Na, PIPES/PIPES-Na and NaH₂PO₄/Na₂HPO₄. However, these pairs were unable to erase the pH memory phenomenon, or to overcome the effect of spiking with acetic acid. Hence, at least these buffers do not seem to be able to affect the protonation state and catalytic activity of papain. In the last aqueous solution before drying, the presence of activating agents (cysteine plus EDTA) was more important than buffer ions.     

Dual binding site inhibitors of B-RAF kinase

Computer aided modeling guided the design of a series of diarylimidazole compounds (11–22) intended to interact with both the ATP and adjacent allosteric binding domains of B-RAF kinase. Their ability to inhibit the function of B-RAF kinase and intracellular ERK1/2 phosphorylation were evaluated.     

Understanding the relative affinity and specificity of the substrate binding site of protein kinase B for substrate-mimetic inhibitors

Designing selective inhibitor of protein kinase B (PKB/Akt) is an area of intense research to develop potential anticancer drugs. As a general point of strategy, the peptide substrate-binding site only responds to a highly specific sequence of amino acids. Targeting the substrate-mimetic inhibitors to the peptide substrate-binding site has the potential for better selectivity. It is therefore of great interest to understand the peptide substrate binding mode of PKB, as well as its specificity and affinity for different substrate-mimetic inhibitors. In the present study, we used molecular dynamic simulations to better understand the interactions of the PKB substrate-binding site with the substrate-mimetic inhibitors. Our computational models successfully mirrored PKB’s selectivity for the substrate-mimetic inhibitors. Furthermore, the key residues interacting with the substrate-mimetic inhibitor were discussed by analysing the different interaction modes of these inhibitors, with different inhibitory potencies, binding to PKB and by comparing the different binding free energy contributions of corresponding residues around the binding pocket. The pharmacophoric requirements were then also summarised for the substrate-mimetic inhibitor binding to PKB. It is expected that this work will provide useful chemical or biochemical informatics for the design of novel and potent substrate-mimetic inhibitors of PKB.     

Amino derivatives of glycyrrhetinic acid as potential inhibitors of cholinesterases

The development of remedies against the Alzheimer’s disease (AD) is one of the biggest challenges in medicinal chemistry nowadays. Although not completely understood, there are several strategies fighting this disease or at least bringing some relief. During the progress of AD, the level of acetylcholine (ACh) decreases; hence, a therapy using inhibitors should be of some benefit to the patients. Drugs presently used for the treatment of AD inhibit the two ACh controlling enzymes, acetylcholinesterase as well as butyrylcholinesterase; hence, the design of selective inhibitors is called for. Glycyrrhetinic acid seems to be an interesting starting point for the development of selective inhibitors. Although its glycon, glycyrrhetinic acid is known for being an AChE activator, several derivatives, altered in position C-3 and C-30, exhibited remarkable inhibition constants in micro-molar range. Furthermore, five representative compounds were subjected to three more enzyme assays (on carbonic anhydrase II, papain and the lipase from Candida antarctica) to gain information about the selectivity of the compounds in comparison to other enzymes. In addition, photometric sulforhodamine B assays using murine embryonic fibroblasts (NiH 3T3) were performed to study the cytotoxicity of these compounds. Two derivatives, bearing either a 1,3-diaminopropyl or a 1H-benzotriazolyl residue, showed a BChE selective inhibition in the single-digit micro-molar range without being cytotoxic up to 30 μM. In silico molecular docking studies on the active sites of AChE and BChE were performed to gain a molecular insight into the mode of action of these compounds and to explain the pronounced selectivity for BChE.     

Design,synthesis and biological evaluation of type-II VEGFR-2 inhibitors based on quinoxaline scaffold

In an effort to develop ATP-competitive VEGFR-2 selective inhibitors, a series of new quinoxaline-based derivatives was designed and synthesized. The target compounds were biologically evaluated for their inhibitory activity against VEGFR-2. The design of the target compounds was accomplished after a profound study of the structure activity relationship (SAR) of type-II VEGFR-2 inhibitors. Among the synthesized compounds, 1-(2-((4-methoxyphenyl)amino)-3-oxo-3,4 dihydroquinoxalin-6-yl)-3-phenylurea (VIIa) displayed the highest inhibitory activity against VEGFR-2. Molecular modeling study involving molecular docking and field alignment was implemented to interpret the variable inhibitory activity of the newly synthesized compounds.