In Silico Design of New Inhibitors of Guanine Phosphoribosyltransferase (GPRT) from Giardia lamblia as Antiparasitic Drug Candidates.

BACKGROUND: Guanine phosphoribosyltransferase (GPRT) is a very attractive target for the development of new drugs against G. lamblia because of its critical role in the synthesis of DNA and RNA. Herein we report the use of in silico approaches to identify potential G. lamblia GPRT inhibitors. METHODS: Analyses of the binding site of the enzyme accomplished through the use of several methods allowed the construction of a pharmacophore model, which was screened against a database of commercial substances. The resulting retrieved compounds were then screened against GPRT by consensus docking with two different methods, and the top 10% scored compounds had their poses visually inspected. Root Mean Square Deviation (RMSD) values ≤ 2.0 Å were used to define a consensual pose while RMSD values between 2 and 3 Å defined a partial consensus. Main toxicity endpoints were predicted through substructural analyses. RESULTS: From the 1,230 compounds retrieved in the pharmacophore-based screening, eleven had their binding modes consensually ascribed by the docking methods, suggesting a better selectivity for the parasite enzyme in comparison to the human counterpart by avoiding steric bumps with a flexible loop in the human enzyme binding site. One compound, ZINC38139588, was predicted to be totally devoid of toxicity, being perhaps the most promising of this series. CONCLUSION: Through rigorously validated docking protocols, we predicted the binding mode of these compounds in the GPRT binding site. The use of a consensus docking strategy yielded more reliable predictions of the binding modes to guide the future biological assays.

Endo-xylanase GH11 activation by the fungal metabolite eugenitin.

Eugenitin, a chromone derivative and a metabolite of the endophyte Mycoleptodiscus indicus, at 5 mM activated a recombinant GH11 endo-xylanase by 40 %. The in silico prediction of ligand-binding sites on the three-dimensional structure of the endo-xylanase revealed that eugenitin interacts mainly by a hydrogen bond with a serine residue and a stacking interaction of the heterocyclic aromatic ring system with a tryptophan residue. Eugenitin improved the GH11 endo-xylanase activity on different substrates, modified the optimal pH and temperature activities and slightly affected the kinetic parameters of the enzyme.

Molecular dynamics, flexible docking, virtual screening, ADMET predictions, and molecular interaction field studies to design novel potential MAO-B inhibitors.

Monoamine oxidase is a flavoenzyme bound to the mitochondrial outer membranes of the cells, which is responsible for the oxidative deamination of neurotransmitter and dietary amines. It has two distinct isozymic forms, designated MAO-A and MAO-B, each displaying different substrate and inhibitor specificities. They are the well-known targets for antidepressant, Parkinson's disease, and neuroprotective drugs. Elucidation of the x-ray crystallographic structure of MAO-B has opened the way for the molecular modeling studies. In this work we have used molecular modeling, density functional theory with correlation, virtual screening, flexible docking, molecular dynamics, ADMET predictions, and molecular interaction field studies in order to design new molecules with potential higher selectivity and enzymatic inhibitory activity over MAO-B.

Use of virtual screening, flexible docking, and molecular interaction fields to design novel HMG-CoA reductase inhibitors for the treatment of hypercholesterolemia.

Dietary changes associated with drug therapy can reduce high serum cholesterol levels and dramatically decrease the risk of coronary artery disease, stroke, and overall mortality. Statins are hypolipemic drugs that are effective in the reduction of cholesterol serum levels, attenuating cholesterol synthesis in liver by competitive inhibition regarding the substrate or molecular target HMG-CoA reductase. We have herewith used computer-aided molecular design tools, i.e., flexible docking, virtual screening in large data bases, molecular interaction fields to propose novel potential HMG-CoA reductase inhibitors that are promising for the treatment of hypercholesterolemia.

Dehydromonocrotaline inhibits mitochondrial complex I. A potential mechanism accounting for hepatotoxicity of monocrotaline.

Monocrotaline is a pyrrolizidine alkaloid present in plants of the Crotalaria species, which causes cytotoxicity and genotoxicity, including hepatotoxicity in animals and humans. It is metabolized by cytochrome P-450 in the liver to the alkylating agent dehydromonocrotaline. We evaluated the effects of monocrotaline and its metabolite on respiration, membrane potential and ATP levels in isolated rat liver mitochondria, and on respiratory chain complex I NADH oxidase activity in submitochondrial particles. Dehydromonocrotaline, but not the parent compound, showed a concentration-dependent inhibition of glutamate/malate-supported state 3 respiration (respiratory chain complex I), but did not affect succinate-supported respiration (complex II). Only dehydromonocrotaline dissipated mitochondrial membrane potential, depleted ATP, and inhibited complex I NADH oxidase activity (IC50=62.06 microM) through a non-competitive type of inhibition (K(I)=8.1 microM). Therefore, dehydromonocrotaline is an inhibitor of the activity of respiratory chain complex I NADH oxidase, an action potentially accounting for the well-documented monocrotaline's hepatotoxicity to animals and humans. The mechanism probably involves change of the complex I conformation resulting from modification of cysteine thiol groups by the metabolite.