Heteroaromatic salvinorin A analogue (P-3 l) elicits antinociceptive and anxiolytic-like effects.

Previous studies have attributed the prominent analgesic, hallucinogenic, sedative, and anxiolytic properties of Salvia divinorum to Salvinorin A. However, the overall pharmacological profile of this isolate limits its clinical applications. To address these limitations, our study evaluates the C(22)-fused-heteroaromatic analogue of salvinorin A [2-O-salvinorin B benzofuran-2-carboxylate] (P-3l) in mice nociception and anxiety models while assessing possible mechanism of action. In comparison with the control group, orally administered P-3l (1, 3, 10, and 30 mg/kg) attenuates acetic acid-induced abdominal writhing, formalin-induced hind paw licking, the thermal reaction to the hotplate, and/or aversive response in the elevated plus-maze, open field, and light-dark box; and potentiates the effect of morphine and diazepam at sub-effective doses (1.25 and 0.25 mg/kg, respectively) without eliciting significant alterations in relative organ weight, or haematological or biochemical parameters. The in vivo blockade of P-3 l effects by naloxone (non-selective opioid receptor antagonist), naloxonazine (antagonist of specific subtypes mu1 of µ-OR), and nor-binaltorphimine (selective ĸ-OR antagonist) supports initial results from binding assays and the interpretations made possible from computational modeling of the interactions of P-3 l with the opioid receptor subtypes. In addition to the opioidergic mechanism, the blockade of the P-3 l effect by flumazenil suggests benzodiazepine binding site involvement in its biological activities. These results support P-3 l potentially possessing clinical utility and substantiate the need for additional pharmacological characterization.

Conformational properties of l-fucose and the tetrasaccharide building block of the sulfated l-fucan from Lytechinus variegatus.

Although the 3D structure of carbohydrates is known to contribute to their biological roles, conformational studies of sugars are challenging because their chains are flexible in solution and consequently the number of 3D structural restraints is limited. Here, we investigate the conformational properties of the tetrasaccharide building block of the Lytechinus variegatus sulfated fucan composed of the following structure [l-Fucp4(SO3-)-α(1-3)-l-Fucp2,4(SO3-)-α(1-3)-l-Fucp2(SO3-)-α(1-3)-l-Fucp2(SO3-)] and the composing monosaccharide unit Fucp, primarily by nuclear magnetic resonance (NMR) experiments performed at very low temperatures and using H2O as the solvent for the sugars rather than using the conventional deuterium oxide. By slowing down the fast chemical exchange rates and forcing the protonation of labile sites, we increased the number of through-space 1H-1H distances that could be measured by NMR spectroscopy. Following this strategy, additional conformational details of the tetrasaccharide and l-Fucp in solution were obtained. Computational molecular dynamics was performed to complement and validate the NMR-based measurements. A model of the NMR-restrained 3D structure is offered for the tetrasaccharide.

Antimalarial naphthoquinones. Synthesis via click chemistry, in vitro activity, docking to PfDHODH and SAR of lapachol-based compounds.

Lapachol is an abundant prenyl naphthoquinone occurring in Brazilian Bignoniaceae that was clinically used, in former times, as an antimalarial drug, despite its moderate effect. Aiming to search for potentially better antimalarials, a series of 1,2,3-triazole derivatives was synthesized by chemical modification of lapachol. Alkylation of the hydroxyl group gave its propargyl ether which, via copper-catalyzed cycloaddition (CuAAC) click chemistry with different organic azides, afforded 17 naphthoquinonolyl triazole derivatives. All the synthetic compounds were evaluated for their in vitro activity against chloroquine resistant Plasmodium falciparum (W2) and for cytotoxicity to HepG2 cells. Compounds containing the naphthoquinolyl triazole moieties showed higher antimalarial activity than lapachol (IC50 123.5 µM) and selectivity index (SI) values in the range of 4.5-197.7. Molecular docking simulations of lapachol, atovaquone and all the newly synthesized compounds were carried out for interactions with PfDHODH, a mitochondrial enzyme of the parasite respiratory chain that is essential for de novo pyrimidine biosynthesis. Docking of the naphthoquinonolyl triazole derivatives to PfDHODH yielded scores between -9.375 and -14.55 units, compared to -9.137 for lapachol and -12.95 for atovaquone and disclosed the derivative 17 as a lead compound. Therefore, the study results show the enhancement of DHODH binding affinity correlated with improvement of SI values and in vitro activities of the lapachol derivatives.