Paul R. Menard scite author profile

A new 4-point pharmacophore method for molecular similarity and diversity that rapidly calculates all potential pharmacophores/pharmacophoric shapes for a molecule or a protein site is described. The method, an extension to the ChemDiverse/Chem-X software (Oxford Molecular, Oxford, England), has also been customized to enable a new internally referenced measure of pharmacophore diversity. The "privileged" substructure concept for the design of high-affinity ligands is presented, and an example of this new method is described for the design of combinatorial libraries for 7-transmembrane G-protein-coupled receptor targets, where "privileged" substructures are used as special features to internally reference the pharmacophoric shapes. Up to 7 features and 15 distance ranges are considered, giving up to 350 million potential 4-point 3D pharmacophores/molecule. The resultant pharmacophore "key" ("fingerprint") serves as a powerful measure for diversity or similarity, calculable for both a ligand and a protein site, and provides a consistent frame of reference for comparing molecules, sets of molecules, and protein sites. Explicit "on-the-fly" conformational sampling is performed for a molecule to enable the calculation of all geometries accessible for all combinations of four features (i.e., 4-point pharmacophores) at any desired sampling resolution. For a protein site, complementary site points to groups displayed in the site are generated and all combinations of four site points are considered. In this paper we report (i) the details of our customized implementation of the method and its modification to systematically measure 4-point pharmacophores relative to a "special" substructure of interest present in the molecules under study; (ii) comparisons of 3- and 4-point pharmacophore methods, highlighting the much increased resolution of the 4-point method; (iii) applications of the 4-point potential pharmacophore descriptors as a new measure of molecular similarity and diversity and for the design of focused/biased combinatorial libraries.

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Chemistry Space Metrics in Diversity Analysis, Library Design, and Compound Selection

Menard¹,

Mason²,

Morize³

et al. 1998

J. Chem. Inf. Comput. Sci.

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DiverseSolutions software was used to generate a “universal” chemistry space that can be used as a standard for profiling most structural sets of interest. A nonlinear method for assigning structures to bins within chemistry space descriptors was developed. This allows the use of chemistry spaces scaled to include all structures within a set, while maintaining a reasonable distribution of structures within bins and providing target percentage cell occupancies. The universal chemistry space and nonlinear binning method were validated using random structures extracted from the Beilstein database. The approach was then used, in conjunction with other diversity analyses, for diverse subset selection and comparison of compound collections.

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Rational Screening Set Design and Compound Selection: Cascaded Clustering

Menard¹,

Lewis²,

Mason³

1998

J. Chem. Inf. Comput. Sci.

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The use of cascaded clustering is reported. This technique was developed to permit the application of Jarvis-Patrick clustering based on structural fingerprints to large chemical databases, while keeping the maximum cluster size and the number of singletons produced at reasonable levels. The basis for the algorithm, its implementation, and validation are described. In the first part of the paper, the approach is used to create a representative subset of compounds for biological testing from the corporate compound repository. A variation of the method is then used for the comparison of relatively large databases. Finally, compound selection using cascaded clustering is shown to be complementary to the Diverse Property-Derived approach, which is based on partitioning by six molecular descriptors.

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Applications of N-BOC-diamines for the solution phase synthesis of ketopiperazine libraries utilizing a Ugi/De-BOC/Cyclization (UDC) strategy

Hulme¹,

Peng²,

Louridas³

et al. 1998

Tetrahedron Letters

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Angiotensin-converting enzyme inhibitors: new orally active 1,4-thiazepine-2,5-diones, 1,4-thiazine-2,5-diones, and 1,4-benzothiazepine-2,5-diones possessing antihypertensive activity

Skiles¹,

Suh²,

Williams³

et al. 1986

J. Med. Chem.

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The preparation of a series of 1,4-thiazepine-2,5-diones, 1,4-thiazine-2,5-diones, and 1,4-benzothiazepine-2,5-diones and their ability in inhibiting the activity of angiotensin-converting enzyme (ACE) in vitro and in vivo were examined. These compounds are assumed to act as prodrugs since they undergo rapid ring-opening reactions to give the corresponding biologically active free SH compounds when incubated with rat plasma or when treated with aqueous 0.1 N HCl or phosphate buffer (pH 7.4). The thiazepines 23-25 and 30 are potent inhibitors of ACE when administered po to rats and are comparable in potency to captopril (1). The most active thiazines in rats, po, were 42 and 45. Of the benzothiazepines studied, 22a was the most active in inhibiting ACE in the conscious normotensive rat, ID50 = 0.15 mg/kg, po. The acute antihypertensive effects of oral administration of a number of these compounds on mean arterial pressure and heart rate were studied in spontaneously hypertensive rats (SHR) maintained on a sodium-deficient diet.

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Paul R. Menard

New 4-Point Pharmacophore Method for Molecular Similarity and Diversity Applications: Overview of the Method and Applications, Including a Novel Approach to the Design of Combinatorial Libraries Containing Privileged Substructures

Chemistry Space Metrics in Diversity Analysis, Library Design, and Compound Selection

Rational Screening Set Design and Compound Selection: Cascaded Clustering

Applications of N-BOC-diamines for the solution phase synthesis of ketopiperazine libraries utilizing a Ugi/De-BOC/Cyclization (UDC) strategy

Angiotensin-converting enzyme inhibitors: new orally active 1,4-thiazepine-2,5-diones, 1,4-thiazine-2,5-diones, and 1,4-benzothiazepine-2,5-diones possessing antihypertensive activity

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