Rational conversion of noncontinuous active region in proteins into a small orally bioavailable macrocyclic drug-like molecule: the HIV-1 CD4:gp120 paradigm.

Rational conversion of noncontinuous active regions of proteins into a small orally bioavailable molecule is crucial for the discovery of new drugs based on inhibition of protein-protein interactions. We developed a method that utilizes backbone cyclization as an intermediate step for conversion of the CD4 noncontinuous active region into small macrocyclic molecules. We demonstrate that this method is feasible by preparing small inhibitor for human immunodeficiency virus infection. The lead compound, CG-1, proved orally available in the rat model.

Cyclizing Painkillers: Development of Backbone-Cyclic TAPS Analogs.

Painkillers are commonly used medications. Native peptide painkillers suffer from various pharmacological disadvantages, while small molecule painkillers like morphine are highly addictive. We present a general approach aimed to use backbone-cyclization to develop a peptidomimetic painkiller. Backbone-cyclization was applied to transform the linear peptide Tyr-Arg-Phe-Sar (TAPS) into an active backbone-cyclic peptide with improved drug properties. We designed and synthesized a focused backbone-cyclic TAPS library with conformational diversity, in which the members of the library have the generic name TAPS c(n-m) where n and m represent the lengths of the alkyl chains on the nitrogens of Gly and Arg, respectively. We used a combined screening approach to evaluate the pharmacological properties and the potency of the TAPS c(n-m) library. We focused on an in vivo active compound, TAPS c(2-6), which is metabolically stable and has the potential to become a peripheral painkiller being a full µ opioid receptor functional agonist. To prepare a large quantity of TAPS c(2-6), we optimized the conditions of the on-resin reductive alkylation step to increase the efficiency of its SPPS. NMR was used to determine the solution conformation of the peptide lead TAPS c(2-6).

The role of P-glycoprotein in intestinal transport versus the BBB transport of tetraphenylphosphonium.

Tetraphenylphosphonium (TPP), a phosphonium cation, is a promising means for tumor imaging. A major contributor to the pharmacokinetics of phosphonium cations is the efflux transporter P-glycoprotein (P-gp). For this application it is important to ascertain the influence of the multidrug resistance system on TPP. Therefore, our aim was to characterize the interaction of TPP with P-gp, in vitro and in in vivo models. P-gp-mediated transport of [3H]-TPP was assessed in Caco-2 cells and ex vivo in rat intestinal wall by the use of a diffusion cell system. The distribution of [3H]-TPP across the blood-brain barrier (BBB) was studied in rats and mice treated with P-gp modulators and in Mdr-1a/b((-/-)) knockout mice. The in vitro permeability coefficient of basolateral-to-apical transfer (PappB-A) of [3H]-TPP was 8-fold greater than apical-to-basolateral (PappA-B) coefficient, indicative of net mucosal secretion. A concentration dependent decrease of this secretion was obtained by the P-gp substrate verapamil, while no effect was evident by the MRP2 inhibitor MK-571 and the BCRP inhibitor FTC. [3H]-TPP transfer across rat jejunum wall was directional and concentration-dependent. 2,4-Dinitrophenol, cyclosporin A (CsA), verapamil and PSC-833 enhanced A-B transport of TPP 3.6-fold, 4-fold, 4.6-fold and 5.3-fold respectively. Likewise, PappA-B of [3H]-TPP was 5-fold greater in P-gp knockout mice than in controls. In vivo, PSC-833, P-gp inhibitor, significantly increased the uptake of [3H]-TPP in the liver, heart, small intestine and the lungs but not the brain. Similar results were obtained in P-gp knockout mice. Our study demonstrates that P-gp mediates TPP efflux in vitro and in vivo; however, the consistently poor BBB permeation of TPP in all in vivo studies including P-gp knockout animals indicates that it is most likely mediated by other mechanisms. These findings are important for optimized clinical application of TPP as an imaging agent in cancer.

Backbone cyclic peptidomimetic melanocortin-4 receptor agonist as a novel orally administrated drug lead for treating obesity.

The tetrapeptide sequence His-Phe-Arg-Trp, derived from melanocyte-stimulating hormone (alphaMSH) and its analogs, causes a decrease in food intake and elevates energy utilization upon binding to the melanocortin-4 receptor (MC4R). To utilize this sequence as an effective agent for treating obesity, we improved its metabolic stability and intestinal permeability by synthesizing a library of backbone cyclic peptidomimetic derivatives. One analog, peptide 1 (BL3020-1), was selected according to its selectivity in activating the MC4R, its favorable transcellular penetration through enterocytes and its enhanced intestinal metabolic stability. This peptide was detected in the brain following oral administration to rats. A single oral dose of 0.5 mg/kg in mice led to reduced food consumption (up to 48% vs the control group) that lasted for 5 h. Repetitive once daily oral dosing (0.5 mg/kg/day) for 12 days reduced weight gain. Backbone cyclization was shown to produce a potential drug lead for treating obesity.

Superiority of the S,S conformation in diverse pharmacological processes: Intestinal transport and entry inhibition activity of novel anti-HIV drug lead.

Chirality is an important aspect in many pharmacological processes including drug transport and metabolism. The current investigation examined the stereospecific transport and entry inhibitory activity of four diastereomers derived from a small (macrocyclic) molecule that has two chiral centers. These molecules were designed to mimic the interaction between CD4 and gp120 site of HIV-1 and thereby to function as entry inhibitor(s). Intestinal permeability was assessed by ex-vivo model using excised rat intestine mounted in side-by-side diffusion chambers. The entry inhibitory activity was monitored using indicator HeLa-CD4-LTR-beta-gal cells (MAGI assay). The (S/S) diastereomer, named CG-1, exhibited superiority in both unrelated tested biological processes: (I) high transport through the intestine and (II) entry inhibition activity (in the low µM range). The permeability screening revealed a unique transporter-mediated absorption pathway of CG-1, suggesting a significant role of the molecule's conformation on the mechanism of intestinal absorption. Here we highlight that only the S,S enantiomer (CG-1) has both (I) promising anti HIV-1 entry inhibitory properties and (II) high transporter mediated intestinal permeability. Hence we suggest preference in pharmacological processes to the S,S conformation. This report augments the knowledge regarding stereoselectivity in receptor mediated and protein-protein interaction processes.