Nonparametric chemical descriptors for the calculation of ligand-biopolymer affinities with machine-learning scoring functions.

The computational prediction of ligand-biopolymer affinities is a crucial endeavor in modern drug discovery and one that still poses major challenges. The choice of the appropriate computational method often reveals itself as a trade-off between accuracy and speed, with mathematical devices referred to as scoring functions being the fastest. Among the many shortcomings of scoring functions there is the lack of universal applicability to every molecular system. This is so largely due to their reliance on atom type perception and/or parametrization. This article proposes the use of nonparametric Model of Effective Radii of Atoms descriptors that can be readily computed for the entire Periodic Table and demonstrate that, in combination with machine learning algorithms, they can yield competitive performances and chemically meaningful insights.

Furoates and thenoates inhibit pyruvate dehydrogenase kinase 2 allosterically by binding to its pyruvate regulatory site.

The last decade has witnessed the reawakening of cancer metabolism as a therapeutic target. In particular, inhibition of pyruvate dehydrogenase kinase (PDK) holds remarkable promise. Dichloroacetic acid (DCA), currently undergoing clinical trials, is a unique PDK inhibitor in which it binds to the allosteric pyruvate site of the enzyme. However, the safety of DCA as a drug is compromised by its neurotoxicity, whereas its usefulness as an investigative tool is limited by the high concentrations required to exert observable effects in cell culture. Herein, we report the identification - by making use of saturation-transfer difference NMR spectroscopy, enzymatic assays and computational methods - of furoate and thenoate derivatives as allosteric pyruvate-site-binding PDK2 inhibitors. This work substantiates the pyruvate regulatory pocket as a druggable target.

Functionalization of non-activated C-H bonds in the synthesis of vitamin D metabolites and analogs.

The development of non-microbial methods for the selective functionalization of non-activated C-H bonds has constituted a challenge, with important economical and environmental implications, for chemists for over a century. The present review provides a comprehensive and current compendium that illustrates the power of C-H functionalization and, namely, of remote functionalization strategies, to expeditiously access vitamin D analogs with intricate structures.

Inhibition of platelet adhesion by peptidomimetics mimicking the interactive ß-hairpin of glycoprotein Ibα.

ß-Hairpin peptidomimetics mimicking the interaction sites of the platelet receptor glycoprotein (GP)Ibα with von Willebrand factor (vWF) were synthesised and evaluated for their ability to increase platelet velocity under high shear conditions and to inhibit shear-induced platelet aggregation. A cyclic and bridged dodecapeptide 2e containing a heterochiral diproline motif was identified as a lead compound for the generation of a novel class of potential antiplatelet agents.

Common architecture of nuclear receptor heterodimers on DNA direct repeat elements with different spacings.

Nuclear hormone receptors (NHRs) control numerous physiological processes through the regulation of gene expression. The present study provides a structural basis for understanding the role of DNA in the spatial organization of NHR heterodimers in complexes with coactivators such as Med1 and SRC-1. We have used SAXS, SANS and FRET to determine the solution structures of three heterodimer NHR complexes (RXR-RAR, PPAR-RXR and RXR-VDR) coupled with the NHR interacting domains of coactivators bound to their cognate direct repeat elements. The structures show an extended asymmetric shape and point to the important role played by the hinge domains in establishing and maintaining the integrity of the structures. The results reveal two additional features: the conserved position of the ligand-binding domains at the 5' ends of the target DNAs and the binding of only one coactivator molecule per heterodimer, to RXR's partner.

Synthesis, structure, and biological activity of des-side chain analogues of 1α,25-dihydroxyvitamin†D3 with substituents at C18.

An improved synthetic route to 1α,25-dihydroxyvitamin D(3) des-side chain analogues 2 a and 2 b with substituents at C18 is reported, along with their biological activity. These analogues display significant antiproliferative effects toward MCF-7 breast cancer cells and prodifferentiation activity toward SW480-ADH colon cancer cells; they are also characterized by a greatly decreased calcemic profile. The crystal structure of the human vitamin D receptor (hVDR) complexed to one of these analogues, 20(17→18)-abeo-1α,25-dihydroxy-22-homo-21-norvitamin D(3) (2 a) reveals that the side chain introduced at position C18 adopts the same orientation in the ligand binding pocket as the side chain of 1α,25-dihydroxyvitamin D(3).

Observation of an unusual electronically distorted semiquinone radical of PCB metabolites in the active site of prostaglandin H synthase-2.

The activation of the metabolites of airborne polychlorinated biphenyls (PCBs) into highly reactive radicals is of fundamental importance. We found that human recombinant prostaglandin H synthase-2 (hPGHS-2) biotransforms dihydroxy-PCBs, such as 4-chlorobiphenyl-2',5'-hydroquinone (4-CB-2',5'-H(2)Q), into semiquinone radicals via one-electron oxidation. Using electron paramagnetic resonance (EPR) spectroscopy, we observed the formation of the symmetric quartet spectrum (1:3:3:1 by area) of 4-chlorobiphenyl-2',5'-semiquinone radical (4-CB-2',5'-SQ()(-)) from 4-CB-2',5'-H(2)Q. This spectrum changed to an asymmetric spectrum with time: the change can be explained as the overlap of two different semiquinone radical species. Hindered rotation of the 4-CB-2',5'-SQ()(-) appears not to be a major factor for the change in lineshape because increasing the viscosity of the medium with glycerol produced no significant change in lineshape. Introduction of a fluorine, which increases the steric hindrance for rotation of the dihydroxy-PCB studied, also produced no significant changes. An in silico molecular docking model of 4-CB-2',5'-H(2)Q in the peroxidase site of hPGHS-2 together with ab initio quantum mechanical studies indicate that the close proximity of a negatively charged carboxylic acid in the peroxidase active site may be responsible for the observed perturbation in the spectrum. This study provides new insights into the formation of semiquinones from PCB metabolites and underscores the potential role of PGHS-2 in the metabolic activation of PCBs.

Molecular framework of steroid/retinoid discrimination in 17beta-hydroxysteroid dehydrogenase type 1 and photoreceptor-associated retinol dehydrogenase.

Steroids and retinoids are signaling molecules that control a variety of physiological processes. 17beta-Hydroxysteroid dehydrogenase type 1 (17beta-HSD1) catalyzes the reduction of estrone to estradiol, supplying biologically active estrogen-regulating sex-specific differentiation. Photoreceptor-associated retinol dehydrogenase (prRDH) is evolutionarily closely related to 17beta-HSD1 but reduces all-trans retinal to all-trans retinol, contributing to rhodopsin regeneration in the visual cycle. Sequence alignment revealed a new enzyme-specific conserved amino acid close to the active site: methionine (position 144 in human enzyme) in prRDH and glycine (position 145) in 17beta-HSD1. We investigated the role of this residue in substrate discrimination in human and zebrafish enzymes. Both recombinant enzymes were expressed in HEK 293 cells followed by normalization of expression by semiquantitative Western blots. Changing of the prRDH-specific methionine to glycine resulted in a gain of function: the mutants now catalyzed the reduction of estrone and all-trans retinal. Human and zebrafish wild-type 17beta-HSD1s efficiently catalyzed the reduction of all-trans retinal to its alcohol. Exchange of glycine for methionine increased the catalytic activity of 17beta-HSD1 toward all-trans retinal in zebrafish but not in the human enzyme, in which the opposite effect was observed. Molecular modeling showed that the zebrafish 17beta-HSD1 substrate-binding pocket is similar to that of prRDH and methionine insertion benefits all-trans retinal reduction. In contrast, in human 17beta-HSD1, the insertion of the bulky methionine causes a disruption of substrate-binding site. We demonstrate for the first time the role of a single amino acid in the evolution of these functionally diverse enzymes and suggest new physiological functions for 17beta-HSD1 in retinoid metabolism. This has implications for the validation of inhibitors of 17beta-HSD1 developed for cancer treatment.

Design, synthesis and evaluation of aspirin analogues having an additional carboxylate substituent for antithrombotic activity.

Acetylsalicylic acid (aspirin) is an effective long-term prophylaxis of thrombotic events such as heart attacks and strokes. It covalently inhibits prostaglandin-H-synthase by interacting with Arg120 or Tyr385 at the active site allowing delivery of its acetyl group to Ser530. However the structure has not been optimized to fit the active site. We have designed acetylsalicylate analogues with an additional carboxylate substituent which allows simultaneous interaction with Arg120 and Tyr385 whilst positioning the acetyl group in close proximity to Ser530. One of these, an ester derivative which unlike acetylsalicylic acid is non-acidic, may act as useful lead compound for further exploitation of this approach.

Strained polycycles by H5C5x free-radical cascades.

[reaction: see text] An H(5)C(5x)-type free-radical chain reaction selectively generates up to three new bonds and three new stereocenters in one pot. This previously unexploited strategy provides a straightforward route to the tricyclic cyclopenta[c]indene skeleton, present in a wide range of pharmacologically active natural products, and can significantly simplify the synthesis of other strained polycyclic structures by sidestepping protection, deprotection, and functional group interconversion steps.

The productive conformation of prostaglandin G2 at the peroxidase site of prostaglandin endoperoxide H synthase: docking, molecular dynamics, and site-directed mutagenesis studies.

We present a plausible productive conformation obtained by docking calculations for the binding of prostaglandin G2 (PGG2) to the peroxidase site of prostaglandin endoperoxide H synthase-1 (PGHS-1, COX-1). The enzyme-substrate complex stability was verified by molecular dynamics. Structural analysis reveals the requirements for enzyme-substrate recognition and binding: the PGG2 15-hydroperoxide group is in the proximity of the heme iron and participates in a hydrogen bond network with the conserved His207 and Gln203 and a water molecule, whereas the carboxylate group forms salt bridges with the remote Lys215 and Lys222. Site-directed mutagenesis showed that a single mutation of Lys215 or Lys222 does not affect enzyme activity, whereas dual mutation of these residues, to either alanine or glutamate, significantly decreases turnover. This indicates that the conserved cationic pocket is involved in enzyme-substrate binding.

Parallel synthesis and in vitro activity of novel anthranilic hydroxamate-based inhibitors of the prostaglandin H2 synthase peroxidase activity.

Currently available non-steroidal anti-inflammatory drugs (NSAIDs) such as aspirin are directed at the cyclooxygenase (COX) site, but not the peroxidase (POX) activity of prostaglandin H2 synthase (PGHS). They are thus unable to inhibit the free-radical induced tissue injury associated with PGHS peroxidase activity, which can occur independently of the COX site. A lead compound, anthranilic hydroxamic acid (AHA) was found to have significant PGHS-POX inhibitory activity (IC50= 72 microM). To define the critical parameters for PGHS-POX inhibition, we investigated 29 AHA derivatives, synthesised from their acid precursors, using solid phase synthesis. In vitro analysis demonstrated a ten-fold improvement in inhibition with 3,5-diiodoanthranilic hydroxamic acid (IC50= 7 microM).

Synthesis of novel analogues of 1alpha,25-dihydroxyvitamin D(3) with side chains at C-18.

Novel analogues of the hormone 1alpha,25-(OH)(2)-D(3) with side chains attached to C-18 were synthesized by a versatile route in which key steps were the remote radical-induced functionalization of the 18-methyl by the C-8beta-hydroxyl group and the introduction of the side chains by Wittig reactions on a C-18-aldehyde. The triene system of the novel analogues was constructed by the convergent Lythgoe-Hoffmann la Roche approach, which involves reaction of a phosphine oxide (the ring A fragment) with a ketone (the upper fragment).