Click-Chemistry-Mediated Synthesis of Selective Melanocortin Receptor 4 Agonists.

The melanocortin receptor 4 (MC4R) subtype of the melanocortin receptor family is a target for therapeutics to ameliorate metabolic dysfunction. Endogenous MC4R agonists possess a critical pharmacophore (HFRW), and cyclization of peptide agonists often enhances potency. Thus, 17 cyclized peptides were synthesized by solid phase click chemistry to develop novel, potent, selective MC4R agonists. Using cAMP measurements and a transcriptional reporter assay, we observed that several constrained agonists generated by a cycloaddition reaction displayed high selectivity (223- to 467-fold) toward MC4R over MC3R and MC5R receptor subtypes without compromising agonist potency. Significant variation was also observed between the EC50 values for the two assays, with robust levels of reporter expression measured at lower concentrations than those effecting appreciable increases in cAMP levels for the majority of the compounds tested. Collectively, we characterized significant elements that modulate the activity of the core pharmacophore for MC4R and provide a rationale for careful assay selection for agonist screening.

Novel diversity-oriented synthesis-derived respiratory syncytial virus inhibitors identified via a high throughput replicon-based screen.

Respiratory syncytial virus (RSV) infections affect millions of children and adults every year. Despite the significant disease burden, there are currently no safe and effective vaccines or therapeutics. We employed a replicon-based high throughput screen combined with live-virus triaging assays to identify three novel diversity-oriented synthesis-derived scaffolds with activity against RSV. One of these small molecules is shown to target the RSV polymerase (L protein) to inhibit viral replication and transcription; the mechanisms of action of the other small molecules are currently unknown. The compounds described herein may provide attractive inhibitors for lead optimization campaigns.

Synthesis of a natural product-like compound collection through oxidative cleavage and cyclization of linear peptides.

Massive efforts in molecular library synthesis have strived for the development of synthesis methodology which systematically delivers natural product-like compounds of high spatial complexity. Herein, we present a conceptually simple approach that builds on the power of solid-phase peptide synthesis to assemble precursor peptides (oligomers) designed to undergo oxidative cascade reactions. By harnessing the structural side-chain diversity and inherent stereochemical features offered by readily available amino acids (monomers), a proof-of-concept collection of 54 skeletally and stereochemically diverse compounds was generated, and selected compounds were elaborated into isoform-selective metalloprotease inhibitors.

Solid-phase synthesis of smac peptidomimetics incorporating triazoloprolines and biarylalanines.

Apoptotic induction mechanisms are of crucial importance for the general homeostasis of multicellular organisms. In cancer the apoptotic pathways are downregulated, which, at least partly, is due to an abundance of inhibitors of apoptosis proteins (IAPs) that block the apoptotic cascade by deactivating proteolytic caspases. The Smac protein has an antagonistic effect on IAPs, thus providing structural clues for the synthesis of new pro-apoptotic compounds. Herein, we report a solid-phase approach for the synthesis of Smac-derived tetrapeptide libraries. On the basis of a common (N-Me)AVPF sequence, peptides incorporating triazoloprolines and biarylalanines were synthesized by means of Cu(I)-catalyzed azide-alkyne cycloaddition and Pd-catalyzed Suzuki cross-coupling reactions. Solid-phase procedures were optimized to high efficiency, thus accessing all products in excellent crude purities and yields (both typically above 90%). The peptides were subjected to biological evaluation in a live/dead cellular assay which revealed that structural decorations on the AVPF sequence indeed are highly important for cytotoxicity toward HeLa cells.

N-acyliminium intermediates in solid-phase synthesis.

N-Acyliminium ions are powerful intermediates in synthetic organic chemistry. Examples of their use are numerous in solution-phase synthesis, but there are unmerited few reports on these highly reactive electrophiles in solid-phase synthesis. The present review covers the literature to date and illustrates the methods used to generate N-acyliminium intermediates on solid support and their further elaboration to a range of pharmacologically interesting peptidomimetics, heterocycles, and other small molecules.

Ralph F. Hirschmann award address 2009: Merger of organic chemistry with peptide diversity.

A huge unleashed potential lies hidden in the large and diverse pool of encoded and particularly nonencoded chiral alpha-, beta-, and gamma-amino acids available today. Although these have been extensively exploited in peptide science, the community of organic chemistry has only used this source of diversity in a quite focused and targeted manner. The properties and behavior of peptides as functional molecules in biology are well documented and based on the ability of peptides to adapt a range of discrete conformers at a minimal entropic penalty and therefore ideally fitting their endogenous targets. The development of new organic reactions and chemistries that in a general and quantitative way transform peptides into new functional molecules, preferably on solid support, is a source of completely new classes of molecules with important and advantageous functional properties. The peptide diversity and the ability to perform chemistry on solid support add tremendously to the combinatorial scope of such reactions in pharmaceutical and materials screening scenario. In recent years, the need for "click" reactions to shape complex molecular architecture has been realized mainly with a basis in the world of peptides and DNA, and in polymer chemistry where connection of highly functionalized biologically active substances or property bearing fragments are assembled as molecular LEGO using quantitative and orthogonal click chemistries. In this article, three such new reactions originating in the Carlsberg Laboratory over the last decade taking advantage of organic transformations in the peptide framework is presented. Initially, the click reaction between azide and terminal alkynes catalyzed by Cu(1) (CuAAC-reaction) is described. This CuAAC "click" reaction was observed first at Carlsberg Laboratory in reactions of azido acid chlorides with alkynes on solid support. Second, the Electrophilic Aromatic Substitution Cyclization-Intramolecular Click-Cascade (EASCy-ICC) reaction will be presented. This quantitative stereo-selective cascade reaction provides a highly diverse set of interesting novel scaffolds from peptides. Finally, we describe the preparation of solid phase peptide phosphine- and carbene-based green catalysts (organozymes), which upon complex formation with transition metal perform with high turnovers under aqueous conditions. These catalysts thrive from the peptide folding and diversity, while phosphines and carbenes in the backbone provide for bidental complex formation with transition metals in a format providing an excellent entry into combinatorial catalyst chemistry.

Divergent pathway for the solid-phase conversion of aromatic acetylenes to carboxylic acids, alpha-ketocarboxylic acids, and methyl ketones.

An efficient divergent pathway for the selective and quantitative solid-phase conversion of aromatic acetylenes to the corresponding carboxylic acids, alpha-keto-carboxylic acids, and methyl ketones is presented. A range of aromatic trimethylsilyl-protected acetylene building blocks was synthesized in excellent yields using a Sonogashira cross-coupling protocol and used in solid-phase synthesis on PEGA resin. Dependent on the selection of conditions, the same solid-supported alkyne could be quantitatively converted to an aromatic carboxylic acid, an aromatic alpha-ketocarboxylic acid, or an aromatic methyl ketone. The conversion to carboxylic acid involved an OsO4/NaIO4/HMTA-mediated oxidative cleavage of the silyl-deprotected alkyne to provide the aromatic carboxylate in excellent yield. The alpha-ketocarboxylic acids were obtained by direct treatment of the trimethylsilyl-protected alkyne with OsO4/NMO/HMTA, while the ketones were obtained by simple acid-mediated hydration of the alkyne using aqueous TFA. In general, all products were obtained in excellent purities, typically above 90%. In addition, it was shown that the alkyne-containing building blocks could easily be incorporated into resin-bound peptides and after chemoselective conversion of the alkyne the new functional groups could be used for further derivatization into peptidomimetic compounds.

Scaffold diversity through intramolecular cascade reactions of solid-supported cyclic N-acyliminium intermediates.

The solid-phase synthesis of pharmacologically interesting heterocycles is presented. The formation of a series of (5,5)-, (5,6)-, (6,5)-, and (6,6)-fused bicyclic ring systems was systematically studied by implementation of a common strategy involving N-acyliminium intermediates. These are highly reactive and transformed further in intramolecular cascade reactions with strong as well as weak C, N, S, and O-nucleophiles. The methodology was successfully applied to the conversion of peptidomimetics into constrained small molecule core structures, such as the hexahydropyrrolo[2,1- b][1,3]oxazines, generally with full control of diastereoselectivity (>20:1) and in purities above 90%.

Solid-phase synthesis of carboxylic and oxamic acids via OsO4/NaIO4/HMTA-mediated oxidative cleavage of acetylenic peptides.

A general method for the solid-phase synthesis of carboxy-functionalized peptides by oxidative cleavage of alkynes is presented. Clean and quantitative conversion is enabled by the addition of bases, such as DABCO and HMTA, to the classical OsO4/NaIO4 mixture. The utility of the reaction is further illustrated by the synthesis of oxamic acids.