Structure-activity relationships of natural quinone vegfrecine analogs with potent activity against VEGFR-1 and -2 tyrosine kinases.

A series of analogs of vegfrecine, a natural quinone vascular endothelial growth factor receptor (VEGFR) tyrosine kinase inhibitor, was synthesized via oxidative amination of 2,5-dihydroxybenzamide with functionalized arylamine followed by ammonolysis and substitution of the quinone ring. The inhibitory activities of the analogs against the VEGFR-1 and -2 tyrosine kinases were assayed in vitro with the aim to identify a compound suitable to treat cancer and inflammatory diseases. Alterations of the functionality of the phenyl group, substitution of the quinone ring, and oxidative cyclization of the 1-carboxamide-2-aminoquinone moiety to form an isoxazole quinone ring were examined. Introduction of halo- and alkyl-substituents at the 5'-position of the phenyl ring resulted in potent inhibition of the VEGFR-1 and -2 tyrosine kinases. In particular, structural modification at C-5' on the phenyl ring was shown to significantly affect the selectivity of the inhibition between the VEGFR-1 and -2 tyrosine kinases. Compound 8, 5'-methyl-vegfrecine, showed superior selectivity toward the VEGFR-2 tyrosine kinase over the VEGFR-1 tyrosine kinase.

CH-π hydrogen bonds in biological macromolecules.

This is a sequel to the previous Perspective "The CH-π hydrogen bond in chemistry. Conformation, supramolecules, optical resolution and interactions involving carbohydrates", which featured in a PCCP themed issue on "Weak Hydrogen Bonds - Strong Effects?": Phys. Chem. Chem. Phys., 2011, 13, 13873-13900. Evidence that weak hydrogen bonds play an enormously important role in chemistry and biochemistry has now accumulated to an extent that the rigid classical concept of hydrogen bonds formulated by Pauling needs to be seriously revised and extended. The concept of a more generalized hydrogen bond definition is indispensable for understanding the folding mechanisms of proteins. The CH-π hydrogen bond, a weak molecular force occurring between a soft acid CH and a soft base π-electron system, among all is one of the most important and plays a functional role in defining the conformation and stability of 3D structures as well as in many molecular recognition events. This concept is also valuable in structure-based drug design efforts. Despite their frequent occurrence in organic molecules and bio-molecules, the importance of CH-π hydrogen bonds is still largely unknown to many chemists and biochemists. Here we present a review that deals with the evidence, nature, characteristics and consequences of the CH-π hydrogen bond in biological macromolecules (proteins, nucleic acids, lipids and polysaccharides). It is hoped that the present Perspective will show the importance of CH-π hydrogen bonds and stimulate interest in the interactions of biological macromolecules, one of the most fascinating fields in bioorganic chemistry. Implication of this concept is enormous and valuable in the scientific community.

Inhibitors of human 2,3-oxidosqualene cyclase (OSC) discovered by virtual screening.

Five human 2,3-oxidosqualnene cyclase (OSC) inhibitors were discovered using the combination of a virtual screening based on a docking study and an isotope-free assay system. All of these inhibitors were revealed to have activities comparable or superior to that of LDAO, a known OSC inhibitor. The computational study of the newly identified inhibitors suggested that CH/π interactions with F444 and W581 contribute to the binding, and these interactions are candidates for additional structural filters in the next generation of virtual screening.

Novel pyrrole- and 1,2,3-triazole-based 2,3-oxidosqualene cyclase inhibitors.

Pyrrole- and 1,2,3-triazole-based 2,3-oxidosqualene cyclase (OSC) inhibitors 3 and 4 were discovered by conducting a virtual screening, a docking study based on the crystallographic structure of OSC, and biological assays. The hit rate of the assays was increased by establishing appropriate substructural filters in the virtual screening stage. Amide derivatives of 8 and 12 preserved the inhibitory activity of parent compound 3, which provided a reasonable starting point for further structure-activity-relationship (SAR) studies on related compounds.

Rubratoxin A specifically and potently inhibits protein phosphatase 2A and suppresses cancer metastasis.

Although cytostatin analog protein phosphatase 2A (PP2A)-specific inhibitors are promising candidates of a new type of anticancer drug, their development has been hindered because of their liability. To find new classes of PP2A-specific inhibitors, we conducted a screening with microbial metabolites and found that rubratoxin A, a classical mycotoxin, is a highly specific and potent inhibitor of the enzyme. While rubratoxin A inhibits PP2A at Ki = 28.7 nm, it hardly inhibited any other phosphatases examined. Rubratoxin B, a close analog, also specifically but weakly inhibits PP2A at Ki = 3.1 microM. The inhibition of intracellular PP2A in cultured cells is obviously observed with 20 microM rubratoxin A treatment for 3 h, inducing the overphosphorylation in PP2A substrate proteins. Although rubratoxins and cytostatin differ in the apparent structures, these compounds share similarities in the structures in detail and PP2A-binding manners. Rubratoxin A showed higher suppression of tumor metastasis and reduction of the primary tumor volume than cytostatin in mouse experiments. As a successor of cytostatin analogs, rubratoxin A should be a good compound leading to the development of antitumor drugs targeting PP2A.

Synthesis of boronic acid derivatives of tyropeptin: proteasome inhibitors.

Boronic acid derivatives of tyropeptin were synthesized with TP-110 as the lead compound. Due to the lability of the aminoboronic acid moiety, careful design of the deprotection and coupling sequence was required. Liquid-liquid partition chromatography was found to be a powerful tool for purification of compounds of this class. The obtained derivatives showed potent inhibitory activities against the human 20S proteasome in vitro.

The anomeric effect revisited. A possible role of the CH/n hydrogen bond.

Ab initio MO calculations were carried out at the MP2/6-311++G(d,p) level to investigate the conformational energy of 2-substituted oxanes and 1,3-dioxanes. It has been found that the Gibbs free energies of the axial conformers are smaller than those of the corresponding equatorial conformers in every case when the 2-substituent Z is electron withdrawing (OCH(3), F, Cl, Br). The difference in Gibbs energy between the equatorial and axial conformers DeltaG(eq-ax) increases from Z=OCH(3) to F, Cl, and then to Br. In the axial conformers, the interatomic distance between Z and the axial C-H, separated by four covalent bonds, has been found to be appreciably shorter than the van der Waals distance, suggesting the importance of the five-membered CH/n (CH/O or CH/halogen) hydrogen bond in stabilizing these conformations. Natural bonding orbital (NBO) charges of the relevant atoms have been shown to be different between the two conformers: more positive for H and more negative for C in the axial conformers than in the corresponding equatorial conformers. In view of the above findings, we suggest that the CH/n hydrogen bond plays an important role in stabilizing the axial conformation in 2-substituted oxanes and 1,3-dioxanes, and by implication, in the anomeric effect in carbohydrate chemistry.

Designed ATRA analogue active against ATRA-resistant acute promyelocytic leukemia cells having a single nucleotide substitution in their retinoic acid receptor.

All-trans retinoic acid (ATRA) induces the differentiation of acute promyelocytic leukemia (APL) cells into neutrophils. UF-1 cells were established from an ATRA-resistant APL patient, and were previously shown to possess a single amino acid (or nucleotide) substitution, Arg276Trp, in their ATRA receptor. In the present research, we designed several ATRA derivatives having a hydrophobic alkyl ketone moiety instead of the negatively charged carboxylic acid moiety. Among them the ethyl ketone derivative, Et-ketone ATRA, was shown to induce the differentiation of UF-1 cells when assessed in terms of intracellular ROS production. It also induced the formation of PML NBs and expression of CD11b antigen marker and p21, transcriptional targets of RARalpha. Et-ketone ATRA did not induce these phenotypic changes in wild-type APL NB4 cells. Furthermore, we found that Et-ketone ATRA induced apoptosis selectively in UF-1 cells, i.e., not in other leukemic cells. The induction of apoptosis was shown to be partly due to the up-regulation of Bax protein. Thus, Et-ketone ATRA selectively induced differentiation and apoptosis in ATRA-resistant APL UF-1 cells, and is likely to be useful for the clinical treatment of the Arg276Trp-type of ATRA-resistant APL.

Synthesis and inhibitory activity of 8-substituted 2-deoxy-beta-KDO against CMP-KDO synthetase.

3-Deoxy-D-manno-octulosonate cytidyltransferase (CMP-KDO synthetase) is involved in the biosynthesis of lipopolysaccharide (LPS) which is an essential component of the outer membrane of gram-negative bacteria. New CMP-KDO synthetase inhibitors, 8-substituted derivatives of 2-deoxy-beta-KDO (2) have been prepared. Compounds 8, 11, 15 and 16 in which the 8-hydroxyl group of 2 is replaced by guanidine, di(carbamoylethyl)amino, p-methoxy- or p-nitro-benzyloxycarbonylamino, respectively affect moderately the CMP-KDO synthetase activity.

Synthesis and activity of tyropeptin A derivatives as potent and selective inhibitors of mammalian 20S proteasome.

Tyropeptin A, a potent proteasome inhibitor, was isolated from the culture broth of Kitasatospora sp. MK993-dF2. We synthesized the derivatives of tyropeptin A to enhance its inhibitory potency. Among the synthesized derivatives, the most potent compound, TP-104, exhibited a 20-fold inhibitory potency enhancement for chymotrypsin-like activity of 20S proteasome compared to tyropeptin A. Additionally, TP-110 specifically inhibited the chymotrypsin-like activity, but did not inhibit the post-glutamyl-peptide hydrolyzing (PGPH) and the trypsin-like activities of 20S proteasome. In vitro TP-110 strongly inhibited the growth of various cell lines.

CH/pi hydrogen bonds as evidenced in the substrate specificity of acetylcholine esterase.

The crystal structure of acetylcholine esterase (AchE) in complex with various inhibitors, investigated as drugs for improvement of the cognitive ability of early stage Alzheimer's disease, has been analyzed with the use of our program CHPI. A number of CH/pi hydrogen bonds have been disclosed in the binding of the inhibitors with Torpedo californica AchE. It has been demonstrated that, in order to be effective in the binding with AchE, C-H bonds in the inhibitor need not be polarized.

Structure-based design of derivatives of tyropeptin A as the potent and selective inhibitors of mammalian 20S proteasome.

Tyropeptin A, a new potent proteasome inhibitor, was produced by Kitasatospora sp. MK993-dF2. To enhance the inhibitory potency of tyropeptin A, we constructed the structural model of tyropeptin A bound to the site responsible for the chymotrypsin-like activity of mammalian 20S proteasome. Based on these modeling experiments, we designed and synthesized several derivatives of tyropeptin A. Among them, the most potent compound, TP-104, exhibited a 20-fold enhancement in its inhibitory potency compared to tyropeptin A. Additionally, TP-110 specifically inhibited the chymotrypsin-like activity, but did not inhibit the PGPH and the trypsin-like activities.

Synthesis and biological activity of sulphostin analogues, novel dipeptidyl peptidase IV inhibitors.

The structure of sulphostin (1), a novel dipeptidyl peptidase IV (DPP-IV) inhibitor, is consisted of three key functional groups, including a characteristic amino(sulfoamino)phosphinyl group, on a piperidine ring. To examine the relationship between its structure and the inhibitory activity against DPP-IV, various analogues were synthesized and their activities were investigated. These results indicated that all of the functional groups on the piperidine ring were crucial to the DPP-IV inhibitory activity of sulphostin, and that the sulfonic acid group, which constructed the amino(sulfoamino)phosphinyl group, contributed to the stability of the compound. Moreover, those functional groups should be adjoined on the piperidine ring for the inhibitory activity. The size of the nitrogen-containing heterocyclic ring including piperidine appeared to scarcely affect the activity. In the present study, the sulfonic acid-deficient five-membered ring analogue 27a showed the strongest inhibitory activity (IC50=11 nM).

Thymine-methyl/pi interaction implicated in the sequence-dependent deformability of DNA.

The crystal structures of deoxy-oligonucleotides were retrieved from the Nucleic Acid Database and analyzed with the use of our program CHPI. The structure of 5'-ApTpApT-3' has been shown to be stabilized by the 5-methyl group in the thymidine moiety that favorably interacts with the adenine pi-ring preceding it. H2' of the deoxyribose in adenine also interacts with the thymine ring next to it. Since a 5'-ApT-3' sequence is accompanied by another 5'-ApT-3' in the complementary strand, the interaction is duplicated, thus forming a 'twin A/T-Me interaction'. Coordinates of oligonucleotides with A-T rich sequences were retrieved and analyzed. In almost every case, the thymidine 5-methyl group favorably interacts with an adenine ring in the same strand. The structure of duplexes incorporating A-tracts was also analyzed. The 5-methyl group in the thymidine moiety has been found to interact favorably with the base pi-ring before it. Since an A-tract is lined with an oligo-T sequence in the complementary strand, a successive N/T-Me stacking may contribute in making the A-tracts robust and straight. The possible involvement of the N/T-Me and the twin A/T-Me motif in the deformability of DNA has been suggested. The role of methyl groups in modified DNA has been discussed on a similar basis.

Flexible Enantiodivergent Synthesis and Biological Activity of Mannostatin Analogues, New Cyclitol Glycosidase Inhibitors.

Mannostatin A (1) is a new cyclitol inhibitor of glycoprotein processing. 2-Epimannostatin A (12) and its enantiomer (13) as well as their positional isomers (14, 15) were designed for probing structure-activity relationships in this class of glycosidase inhibitors. The analogues have been synthesized from (S)-4-((tert-butyldimethylsilyl)oxy)-2-cyclopentenone by an enantiodivergent strategy in a totally stereospecific fashion. Compound 13 showed inhibition against almond beta-glucosidase and is shown to be a topographical analogue of beta-D-glucopyranoside.