Synthesis and SAR of novel 4,5-diarylimidazolines as potent P2X7 receptor antagonists

A series of 4,5-diarylimidazoline libraries were prepared using high-throughput solid-phase and microwave techniques. The compounds were evaluated as P2X(7) antagonists and their SAR is described.     

Small molecule biaryl FSH receptor agonists. Part 2: Lead optimization via parallel synthesis

Potent small molecule biaryl diketopiperazine FSH receptor agonists such as 10c (EC(50)=13 nM) and 11f (EC(50)=1.2 nM) were discovered through the design, synthesis and evaluation of three biaryl diketopiperazine optimization libraries with over 300 compounds. These libraries were prepared via solid-phase parallel synthesis using a cyclization-release method.     

Discovery and optimization of (R)-prolinol-derived agonists of the Growth Hormone Secretagogue receptor (GHSR)

The discovery and optimization of a novel series of prolinol-derived GHSR agonists is described. This series emerged from a 11,520-member solid-phase library targeting the GPCR protein superfamily, and the rapid optimization of low micromolar hits into single-digit nanomolar leads can be attributed to the solid-phase synthesis of matrix libraries, which revealed multiple non-additive structure-activity relationships. In addition, the separation of potent diastereomers highlighted the influence of the alpha-methyl stereochemistry of the phenoxyacetamide sidechain on GHSR activity.     

Dendritic supports in organic synthesis

An overview is presented of the recent developments in the use of dendritic supports in organic synthesis. Examples are presented of the application of dendritic supports in both liquid- and solid-phase organic synthesis. In liquid-phase synthesis, soluble dendrimers are used as the substrate support, while in solid-phase synthesis, 'dendronized' insoluble resins are used for this purpose. Selected examples of the synthesis of compound libraries on dendritic supports via combinatorial techniques are discussed.     

Solid-phase synthesis of thrombin inhibitors

A newly developed convergent solid-phase synthesis provides efficient access to thrombin inhibitors of the D-Phe-Pro-Arg type. Members of the synthesized libraries inhibited thrombin with IC(50)s in the nanomolar range.     

Solid-phase combinatorial synthesis using MicroKan reactors, Rf tagging, and directed sorting

A modular system for high-output solid-phase combinatorial synthesis has been designed and developed. The system employs three technological innovations to achieve its high efficiency and reliability: (1) application of microreactors as the reaction units in solid-phase synthesis; (2) use of radiofrequency tagging as the non-chemical tracking method; and (3) development of the directed sorting technology for split & pool synthesis. The system has been successfully applied in the synthesis of compound libraries of several hundred to several thousand compounds in multi-milligrams per compound quantity by many organizations.     

Synthesis of nucleoside libraries on solid support. II. 2,6,8-Trisubstituted purine nucleosides using 8-bromoguanosine as precursor

A series of 2,6,8-trisubstituted purine nucleoside libraries was prepared by parallel solid-phase synthesis using 8-bromoguanosine as a common synthetic precursor. Polystyrene-methoxytrityl chloride resin was linked to the N2 or O5' position of the guanosine analogues. 8-Bromoguanosine was derivatized at the C8 position via carbon-carbon bond formation. Nucleophilic aromatic substitution at C2 and/or C6 positions with various amines produced two series of purine nucleoside libraries with very diverse substitution.     

3-Azido-3-deoxy-glycopyranoside derivatives as scaffolds for the synthesis of carbohydrate-based universal pharmacophore mapping libraries

The regiospecific syntheses of six monosaccharide scaffolds, 1-6, containing a carboxylic acid, an azido and a free hydroxyl group were accomplished through the utilization of a key intermediate, namely, methyl 3-azido-3-deoxy-beta-D-glucopyranoside (10). Scaffold 2 was also used in generating combinatorial libraries using solid-phase methodologies.     

Methods for mapping protease specificity

The study of protease specificity provides information on active-site structure and function, protein-protein interaction, regulation of intracellular and extracellular pathways, and evolution of protease and substrate genes. Peptide libraries that include fluorogenic and binding tags are often generated by solid-phase synthesis. Even larger explorations of cleavage site preferences employ positional scanning libraries or phage display. Microarrays enable presentation of individual peptides to proteases, DNA sequences for capture of peptide nucleic acid encoded peptides, or nanodroplets containing soluble peptide sequences. These new methods continue to inform the design of chemical inhibitors and the identification of substrates of proteases.     

Libraries of non-polymeric organic molecules

New technology is emerging that permits the chemical synthesis of large numbers of different compounds simultaneously. Combinatorial chemistry is heavily dependent upon the adaption of organic synthesis to solid supports and has necessitated the development of appropriate analytical and chemical approaches to both monitor solid-phase reactions and release finished compounds into solution. Considerable progress has recently been made in all of these areas. Small-molecule libraries of medicinally important chemical classes, such as 1,4-benzodiazepines, mercaptopropionyl amino acids, and peptidyl phosphonates, have recently been reported. Encoded combinatorial libraries of dihydrobenzopyran-based and acylpiperidine-based pharmacophores have yielded potent inhibitors of carbonic anhydrase. Automated instrumentation is growing in importance for the synthesis of small-molecule libraries.     

Pyrazole CCK(1) receptor antagonists. Part 2: SAR studies by solid-phase library synthesis and determination of Free-Wilson additivity

High-throughput screening revealed compound 1 as a potent antagonist of the CCK(1) receptor. Here, we disclose the synthesis of combinatorial libraries by solid-phase synthesis on Kenner 'safety catch' resin. Additive QSAR models were used to determine a lack of consistent additive SAR within the matrix.     

Synthetic libraries of tyrosine-derived bacterial metabolites

The preparation of a collection of 131 small molecules, reminiscent of families of long chain N-acyl tyrosines, enamides and enol esters that have been isolated from heterologous expression of environmental DNA (eDNA) in Escherichia coli, is reported. The synthetic libraries of N-acyl tyrosines and their 3-keto counterparts were prepared via solid-phase routes, whereas the enamides and enol esters were synthesized in solution-phase.     

Protected aminooxyprolines for expedited library synthesis: application to Tsg101-directed proline-oxime containing peptides

The stereoselective synthesis of aminooxy-containing proline analogues bearing Fmoc/Boc or Fmoc/Mtt protection that renders them suitable for incorporation into peptides using Fmoc protocols is reported. Acid-catalyzed unmasking at the completion of peptide synthesis yields free aminooxy-functionalities for oxime formation through reaction with libraries of aldehydes. This allows post solid-phase diversification strategies that may facilitate structure-activity relationship studies.     

High-speed combinatorial synthesis utilizing microwave irradiation

Recent advances in microwave-assisted combinatorial chemistry include high-speed solid-phase and polymer-supported organic synthesis, rapid parallel synthesis of compound libraries, and library generation by automated sequential microwave irradiation. In addition, new instrumentation for high-throughput microwave-assisted synthesis continues to be developed at a steady pace. The impressive speed combined with the unmatched control over reaction parameters justifies the growing interest in this application of microwave heating.     

Combinatorial synthesis of natural products

Combinatorial syntheses allow production of compound libraries in an expeditious and organized manner immediately applicable for high-throughput screening. Natural products possess a pedigree to justify quality and appreciation in drug discovery and development. Currently, we are seeing a rapid increase in application of natural products in combinatorial chemistry and vice versa. The therapeutic areas of infectious disease and oncology still dominate but many new areas are emerging. Several complex natural products have now been synthesised by solid-phase methods and have created the foundation for preparation of combinatorial libraries. In other examples, natural products or intermediates have served as building blocks or scaffolds in the synthesis of complex natural products, bioactive analogues or designed hybrid molecules. Finally, structural motifs from the biologically active parent molecule have been identified and have served for design of natural product mimicry, which facilitates the creation of combinatorial libraries.     

Parallel solid-phase synthesis of nucleoside phosphoramidate libraries

Combinatorial chemistry is playing an increasingly prominent role in the process of drug discovery. A nucleic acid-based (NAB) scaffold can be engineered to create functional group and topological diversity in a library. Described herein is the parallel solid-phase synthesis of combinatorial libraries of nucleoside phosphoramidates, and the first evaluation of antiviral activity against hepatitis B virus (HBV).     

Discovery of selective metal-binding peptoids using 19F encoded combinatorial libraries

A method for encoding solid-phase split/mix combinatorial libraries using the chemical shift of synthetic fluoroarenes ('F-codes') has been developed. They have wide chemical shift dispersion and are detectable at the sub-micromol level. 19F NMR is used for decoding. Nine fluoroarenes bearing linkers for attachment to solid-phase synthesis supports through a photocleavable group were prepared. A library of 90 N-alkylglycines bearing substituted succinamides was prepared on solid phase from nine amines, in which the amine is encoded by the fluorinated tag, and 10 anhydrides. Metal binding studies followed by decoding identified unique, specific binders of copper(II) and iron(III) with microM K(D)s.     

Studies on Substrate Specificity at PR/p3 Cleavage Site of HTLV-1 Protease

Substrate specificities for recognition at the PR/p3 site of HTLV-1 protease were clarified using small libraries of substrate peptides. Specificities at P₁ and P₁′ positions were examined by parallel synthesis/digestion of synthetic peptides covering the PR/p3 site (KGPPVILPIQA). Specificities at P₂ to P₄ positions were examined by split and mix syntheses of olefin-peptide libraries containing the substrate sequence (PPVILPIQ). The solid-phase Horner-Emmons reaction was successfully applied to syntheses of multi-component substrates for library preparation. From the digestion of substrate peptides by a chemically synthesized mutant of HTLV-1 protease (C2A HTLV-1 PR), it was found for the first time that the preference for Pro at the P₁′ position and for Ile at the P₂ position is unique for this enzyme. We dedicate this article to Prof. Bruce Merrifield for his great role and impact on solid-phase chemistry.     

Recent developments and applications of liquid-phase strategies in organic synthesis.

Chemistry on soluble polymer supports, termed liquid-phase organic synthesis, is developing into an increasingly viable alternative or adjunct to the classical solid-phase approach across the broad spectrum of polymer-supported organic chemistry. Recent advances in the field include the use of soluble polymers in the combinatorial synthesis of peptide and small-molecule libraries, as catalyst and reagent supports, and as functionalized polymer-quench reagents for purifying solution-phase combinatorial libraries.     

A multidetachable sulfamate linker successfully used in a solid-phase strategy to generate libraries of sulfamate and phenol derivatives

The sulfamates and phenols constitute two families of compounds with numerous interesting biological properties. Using the ability of a new multidetachable sulfamate linker to generate these two families of compounds from the same resin, we designed and synthesized libraries of estradiol derivatives, sulfamoylated or not. A C-16beta side chain was then judiciously diversified to target two key steroidogenic enzymes, the steroid sulfates and the type 1 17beta-HSD. Four libraries of sulfamate and phenol derivatives were easily obtained by solid-phase parallel synthesis in good crude overall yields (13-62%) and HPLC purities (85-96%). Such strategy using the new two-in-line sulfamate linker could be also extended to other therapeutic targets than steroidogenic enzymes, thus adding to its potential.