Docking of peptide-T onto the D1 domain of the CD4 receptor.

Peptide T (pepT) is a segment of the human immunodeficiency virus (HIV) envelope protein gp120. The peptide competitively binds to the CD4 receptor of a subset of peripheral T lymphocytes and inhibits binding of gp120. Previous studies of this laboratory allowed the assessment of a bioactive form of the peptide and a pharmacophore for the peptide-receptor interaction. In the present study the proposed bioactive form of pepT and its (4-8) segment, the smallest pepT fragment shown to retain full activity, were docked onto the D1 domain of the CD4 receptor. The bioactive conformation of the peptides complements well a cleft on the surface of the CD4 receptor, shown to be the attachment site of gp120 from site directed mutagenesis experiments. These studies provide an improved description of the ligand-receptor pharmacophore.

Identification of selective inhibitors of acetylcholinesterase from a combinatorial library of 2,5-piperazinediones.

The potentiation of central cholinergic activity has been proposed as a therapeutic approach for improving cognitive function in patients with Alzheimer's disease. Increasing the acetylcholine concentration in brain by modulating acetylcholinesterase (AChE) activity is among the most promising strategies. We have used a combinatorial approach to identify different 2,5-piperazinediones (DKP) with AChE inhibitory activity. Our goal was to find inhibitors exhibiting high AChE/BuChE (butyrylcholinesterase) selectivity, in order to reduce the undesirable side effects elicited by most of the inhibitors that have been developed to date. Screening of a DKP library constructed on solid-phase using the multiple parallel synthesis format, resulted in the identification of several compounds with moderate efficacy on AChE. In particular, DKP-80 had an IC50 = 2.2 microM with no significant inhibitory activity on BuChE. Moreover, estimated values of Clog P and log BB for the most active compounds fulfilled the bioavailability requirements for enzyme inhibitors acting on the central nervous system. In order to understand the inhibitory properties of the ligand at the molecular level, molecular dynamics simulations were computed on DKP-80 complexed to AChE, and the most relevant binding interactions of this inhibitor to the active center of the enzyme were characterized. Overall the present results indicate that the DKP-based compounds identified are novel AChE inhibitors which may be considered likely lead compounds for further development of drug candidates against Alzheimer's disease.

Assessment of the bioactive conformation of the farnesyltransferase protein binding recognition motif by computational methods.

Ras farnesyltransferase catalyzes the carboxyl-terminal farnesylation of Ras as well as other proteins involved in signal transduction processes. Previous studies demonstrated that its inhibition suppresses the activity of Ras transformed phenotypes in cultured cells, causing tumor regression in animal models. This observation led to the consideration of farnesyltransferase as a target for cancer therapy. In the present work we report the results of a computational study aimed at assessing the bioactive conformation of the peptide Cys-Val-Phe-Met, known to be the minimum peptide sequence that inhibits farnesyltransferase. For this purpose the conformational preferences of four analogs of the peptide were assessed by means of thorough searches of their respective conformational spaces, using a simulated annealing protocol as sampling technique. Specifically, two active analogs: Cys-Val-Tic-Met and Cys-Val-psi(CH2NH)Tic-Met and two inactive analogs: Cys-Val-Tic-psi(CH2NH)Met and Cys-Val-Aic-Met were selected for the present study. Low energy conformations of the four analogs were classified according to their structural motifs. The putative bioactive conformation of the minimum farnesyltransferase recognition motif was assessed by cross-comparison of the different classes of conformations obtained for the two active and the two inactive analogs. The putative bioactive conformation is characterized by two structural motifs: i) a C14 pseudo-ring stabilized by a hydrogen bond between the amino group of Cys1 and the carboxylate group of Met4 and a C11 pseudo-ring involving the residues Cys1 and Tic3. In addition, the thiol group of Cys1 side chain of the bioactive conformation points to the carboxylate moiety of Met4.