Structure-based design of inhibitors of purine nucleoside phosphorylase. 2. 9-Alicyclic and 9-heteroalicyclic derivatives of 9-deazaguanine.

Alicyclic and heteroalicyclic derivatives of 9-deazaguanine (2-amino-1,5-dihydro-4H-pyrrolo[3,2-d] [pyrimidin-4-one) are, with one exception, potent inhibitors of purine nucleoside phosphorylase (PNP) equaling the corresponding 9-arylmethyl derivatives previously investigated. The mode of binding of these compounds to PNP was determined by X-ray crystallography.

Structure-based design of inhibitors of purine nucleoside phosphorylase. 4. A study of phosphate mimics.

9-(3,3-Dimethyl-5-phosphonopentyl)guanine was synthesized and found to be a potent inhibitor of purine nucleoside phosphorylase (PNP) (IC50 = 44 nM). A number of other functional end groups were investigated as phosphate mimics attached to the 9-position of guanine by this same alkyl side chain, which provided a sensitive method for the detection of any interaction of these groups with the phosphate binding site of PNP. Both the sulfonic acid (compound 13) and the carboxylic acid (compound 15) end groups interact significantly with the phosphate binding site, but in different ways, as determined by X-ray crystallographic analysis of the complexes. The sulfonic acid of 13, which binds about one-fourth as tightly as the phosphonate 12, binds in the phosphate subsite much like the phosphonic acid. The carboxylic acid, the interaction of which is much weaker, turns away from the center of the phosphate binding site to form hydrogen bonds with Ser 200 and Met 219. Thus, the only phosphate mimics that bind like phosphate itself are themselves highly ionic, probably with limited ability to penetrate cell membranes.

Structure-based design of inhibitors of purine nucleoside phosphorylase. 3. 9-Arylmethyl derivatives of 9-deazaguanine substituted on the methylene group.

X-ray crystallography and computer-assisted molecular modeling (CAMM) studies aided in the design of a potent series of mammalian purine nucleoside phosphorylase (PNP) inhibitors. Enhanced potency was achieved by designing substituted 9-(arylmethyl)-9-deazaguanine analogs that interact favorably with all three of the binding subsites of the PNP active site, namely the purine binding site, the hydrophobic pocket, and the phosphate binding site. The most potent PNP inhibitor prepared during our investigation, (S)-9-[1-(3-chlorophenyl)-2-carboxyethyl]-9-deazaguanine (18b), was shown to have an IC50 of 6 nM, whereas the corresponding (R)-isomer was 30-fold less potent.

Structure-based design of inhibitors of purine nucleoside phosphorylase. 1. 9-(arylmethyl) derivatives of 9-deazaguanine.

Purine nucleoside phosphorylase (PNP, EC 2.4.2.1) is a salvage enzyme important to the T-cell-mediated part of the immune system and as such is an important therapeutic target. This paper describes the design, synthesis, and enzymatic evaluation of potent, competitive inhibitors of PNP. Potential inhibitors were designed using the three-dimensional structure of the enzyme in an iterative process that involved interactive computer graphics to model the native enzyme and complexes of it with the inhibitors, Monte Carlo-based conformational searching, and energy minimization. Studies of the enzyme/inhibitor complexes were used to determine priorities of the synthetic efforts. The resulting compounds were then evaluated by determination of their IC50 values and by X-ray diffraction analysis using difference Fourier maps. In this manner, we have developed a series of 9-(arylmethyl)-9-deazapurines (2-amino-7-(arylmethyl)-4H-pyrrolo[3,2-d]-pyrimidin-4-ones) that are potent, membrane-permeable inhibitors of the enzyme. The IC50 values of these compounds range from 17 to 270 nM (in 1 mM phosphate), with 9-(3,4-dichlorobenzyl)-9-deazaguanine being the most potent inhibitor. X-ray analysis explained the role of the aryl groups and revealed the rearrangement of hydrogen bonds in the binding of the 9-deazaguanines in the active site of PNP relative to the binding of the 8-aminoguanines that results in more potent inhibition of the enzyme.

The significance of chirality in drug design and development.

Proteins are often enantioselective towards their binding partners. When designing small molecules to interact with these targets, one should consider stereoselectivity. As considerations for exploring structure space evolve, chirality is increasingly important. Binding affinity for a chiral drug can differ for diastereomers and between enantiomers. For the virtual screening and computational design stage of drug development, this problem can be compounded by incomplete stereochemical information in structure libraries leading to a "coin toss" as to whether or not the "ideal" chiral structure is present. Creating every stereoisomer for each chiral compound in a structure library leads to an exponential increase in the number of structures resulting in potentially unmanageable file sizes and screening times. Therefore, only key chiral structures, enantiomeric pairs based on relative stereochemistry need be included, and lead to a compromise between exploration of chemical space and maintaining manageable libraries. In clinical environments, enantiomers of chiral drugs can have reduced, no, or even deleterious effects. This underscores the need to avoid mixtures of compounds and focus on chiral synthesis. Governmental regulations emphasizing the need to monitor chirality in drug development have increased. The United States Food and Drug Administration issued guidelines and policies in 1992 concerning the development of chiral compounds. These guidelines require that absolute stereochemistry be known for compounds with chiral centers and that this information should be established early in drug development in order that the analysis can be considered valid. From exploration of structure space to governmental regulations it is clear that the question of chirality in drug design is of vital importance.

A rapid method for the computation, comparison and display of molecular volumes.

This paper presents a method for the rapid computation of approximate molecular van der Waals volumes and their subsequent display. The procedure relies on bit representation of individual volume elements that are mapped into an array that stores the total molecular volume. Our method differs from previously described algorithms in its use of bit-encoded templates that define atomic van der Waals radii. For each atom in the molecule, for which the volume is to be computed, the relevant template is mapped into a bit array with an offset corresponding to the appropriate atomic position. Bit-wise Boolean operations can be used for volume comparisons (e.g., common volume and excluded volume). An algorithm for the graphical display of the molecular surface encompassing the computed volumes is also described. The speed of the method enables users to perform volume computations in a reasonable period of time with VAX-class computers on molecules containing as many as several hundred atoms.

Compare-Conformer: a program for the rapid comparison of molecular conformers based on interatomic distances and torsion angles.

A computer program for comparison of the conformations of a number of related molecular structures is described. The comparisons are performed on either interatomic distances or torsion angles. The comparisons are accomplished on ordered pairs of distances or torsion angles, and the distance comparisons can be performed in a manner that allows permutation of the distance pairs being compared. The algorithm utilizes bit-string Boolean operations that allow the comparisons to be performed rapidly. The program should be useful for computer-assisted molecular modeling studies in which the viable conformers of bioactive analogues are compared in order to locate those conformers that place key substituents in the same spatial orientation.

Purine nucleoside phosphorylase. 2. Catalytic mechanism.

X-ray crystallography, molecular modeling, and site-directed mutagenesis were used to delineate the catalytic mechanism of purine nucleoside phosphorylase (PNP). PNP catalyzes the reversible phosphorolysis of purine nucleosides to the corresponding purine base and ribose 1-phosphate using a substrate-assisted catalytic mechanism. The proposed transition state (TS) features an oxocarbenium ion that is stabilized by the cosubstrate phosphate dianion which itself functions as part of a catalytic triad (Glu89-His86-PO4=). Participation of phosphate in the TS accounts for the poor hydrolytic activity of PNP and is likely to be the mechanistic feature that differentiates phosphorylases from glycosidases. The proposed PNP TS also entails a hydrogen bond between N7 and a highly conserved Asn. Hydrogen bond donation to N7 in the TS stabilizes the negative charge that accumulates on the purine ring during glycosidic bond cleavage. Kinetic studies using N7-modified analogs provided additional support for the hydrogen bond. Crystallographic studies of 13 human PNP-ligand complexes indicated that PNP uses a ligand-induced conformational change to position Asn243 and other key residues in the active site for catalysis. These studies also indicated that purine nucleosides bind to PNP with a nonstandard glycosidic torsion angle (+anticlinal) and an uncommon sugar pucker (C4'-endo). Single point energy calculations predicted the binding conformation to enhance phosphorolysis through ligand strain. Structural data also suggested that purine binding precedes ribose 1-phosphate binding in the synthetic direction whereas the order of substrate binding was less clear for phosphorolysis. Conservation of the catalytically important residues across nucleoside phosphorylases with specificity for 6-oxopurine nucleosides provided further support for the proposed catalytic mechanism.

Structure-based design of inhibitors of purine nucleoside phosphorylase.

Inhibitors of purine nucleoside phosphorylase may have therapeutic value in the treatment of T-cell proliferative diseases such as T-cell leukemia, in the suppression of host-versus-graft response in organ transplants, and in the treatment of T-cell-mediated autoimmune diseases. Competitive inhibitors of this enzyme have been designed using the three-dimensional structure of the enzyme determined by X-ray crystallography. This approach has resulted in the synthesis of the most potent and membrane-permeable inhibitors of purine nucleoside phosphorylase reported so far.

Solvent effects on the conformation of cyclo(-D-Trp-D-Asp-Pro-D-Val-Leu-). An NMR spectroscopy and molecular modeling study.

The conformations of cyclo(-D-Trp-D-Asp-Pro-D-Val-Leu-) in dimethyl sulfoxide-d6 (DMSO-d6) and water were determined using two-dimensional nuclear magnetic resonance spectroscopy and restrained molecular dynamics. Comparisons were made between conformations of the cyclic pentapeptide in both solvents. The NMR study revealed that, while the backbone remained relatively unchanged in both solvents, the side-chains adopted distinctly different orientations in DMSO-d6 vs. H2O. A modeling study, minus NOE constraints, produced a set of low-energy conformers possessing agreement in backbone conformation with the NMR-derived structures; however, lowest-energy conformers did not have this agreement. These results show that different solvents can significantly affect the preferred side-chain conformation of small cyclic peptides in solution. This finding will impact the selection of solvent when determining structures for use as templates in rational drug design.

Application of crystallographic and modeling methods in the design of purine nucleoside phosphorylase inhibitors.

Competitive inhibitors of the salvage pathway enzyme purine-nucleoside phosphorylase (purine-nucleoside:orthophosphate ribosyltransferase, EC 2.4.2.1) have been designed by using the three-dimensional structure of the enzyme as determined by x-ray crystallography. The process was an iterative one that utilized interactive computer graphics, Monte Carlo-based conformational searching, energy minimization, and x-ray crystallography. The proposed compounds were synthesized and tested by an in vitro assay. Among the compounds designed and synthesized are the most potent competitive inhibitors of purine nucleoside phosphorylase thus far reported.