Rational Strategy for Designing Peptidomimetic Small Molecules Based on Cyclic Peptides Targeting Protein-Protein Interaction between CTLA-4 and B7-1.

Currently, various pharmaceutical modalities are being developed rapidly. Targeting protein-protein interactions (PPIs) is an important objective in such development. Cyclic peptides, because they have good specificity and activity, have been attracting much attention as an alternative to antibody drugs. However, cyclic peptides involve some difficulties, such as oral availability and cell permeability. Therefore, while small-molecule drugs still present many benefits, the screening of functional small-molecule compounds targeting PPIs requires a great deal of time and effort, including structural analysis of targets and hits. In this study, we investigated a rational two-step strategy to design small-molecule compounds targeting PPIs. First, we obtained inhibitory cyclic peptides that bind to cytotoxic T-lymphocyte-associated protein 4 (CTLA-4) by ribosomal display using PUREfrex® (PUREfrex®RD) to get structure-activity relation (SAR) information. Based on that information, we converted cyclic peptides to small molecules using PepMetics® scaffolds that can mimic the α-helix or ß-turn of the peptide. Finally, we succeeded in generating small-molecule compounds with good IC50 (single-digit µM values) against CTLA-4. This strategy is expected to be a useful approach for small-molecule design targeting PPIs, even without having structural information such as that associated with X-ray crystal structures.

Visualized and Quantitative Conformational Analysis of Peptidomimetics.

Protein-protein interactions (PPIs) are fundamentally important and challenging drug targets. Peptidomimetic molecules of various types have been developed to modulate PPIs. A particularly promising drug discovery strategy, structural peptidomimetics, was designed based on special mimicking of side-chain Cα-Cß bonds. It is simple and versatile. Nevertheless, no quantitative method has been established to evaluate its similarity to a target peptide motif. We developed two methods that enable visual, comprehensive, and quantitative analysis of peptidomimetics: peptide conformation distribution (PCD) plot and peptidomimetic analysis (PMA) map. These methods specifically examine multiple side-chain Cα-Cß bonds of a peptide fragment motif and their corresponding bonds (pseudo-Cα-Cß bonds) in a mimetic molecule instead of φ and ψ angles of a single amino acid in the traditional Ramachandran plot. The PCD plot is an alignment-free method, whereas the PMA map is an alignment-based method providing distinctive and complementary analysis. Results obtained from analysis using these two methods indicate our multifacial α-helix mimetic scaffold 12 as an excellent peptidomimetic that can precisely mimic the spatial positioning of side-chain functional groups of α-helix. These methods are useful for visualized and quantified evaluation of peptidomimetics and for the rational design of new mimetic scaffolds.

Design and synthesis of piperazine derivatives as a novel class of γ-secretase modulators that selectively lower Aß42 production.

Novel piperazine derivatives as γ-secretase modulators (GSMs) were prepared and tested for their ability to selectively lower Aß42 production. Lead compound 3, with selective Aß42-lowering activity, was modified by replacing its imidazolylphenyl moiety with an oxazolylphenyl moiety. Optimization of the urea group significantly improved mouse microsomal stability, while retaining both activity and selectivity. These efforts led to the successful identification of an orally available and brain-penetrant GSM, 6j, which selectively reduced brain Aß42 in mice.

Design, synthesis, and biological activities of 1-aryl-1,4-diazepan-2-one derivatives as novel triple reuptake inhibitors.

A novel series of triple reuptake inhibitors were explored by ligand-based drug design. A cyclic structure was designed from cyclopropane derivative 5 using the core structure of reported monoamine reuptake inhibitors, leading to the formation of the 1-aryl-1,4-diazepan-2-one derivative 23j-S. Compound 23j-S was shown to act as a potent TRI with an excellent ADME-Tox profile. Oral administration of 23j-S significantly enhanced norepinephrine, dopamine, and serotonin levels in the mouse prefrontal cortex and showed significant antidepressant-like activity in tail suspension tests in mouse.

Novel triple reuptake inhibitors with low risk of CAD associated liabilities: design, synthesis and biological activities of 4-[(1S)-1-(3,4-dichlorophenyl)-2-methoxyethyl]piperidine and related compounds.

A novel triple reuptake inhibitor with low potential of liabilities associated with cationic amphiphilic drug (CAD) was identified following an analysis of existing drugs. Low molecular weight (MW < ca. 300), low aromatic ring count (number = 1) and reduced lipophilicity (ClogP < 3.5) were hypothesized to be key factors to avoid the CAD associated liabilities (CYP2D6 inhibition, hERG inhibition and phospholipidosis). Based on the hypothesis, a series of piperidine compounds was designed with consideration of the common characteristic features of CNS drugs. Optimization of the side chain by adjusting overall lipophilicity suggested that incorporation of a methoxymethyl group could provide compounds with a balance of both potent reuptake inhibition and low liability potential. Compound (S)-3a showed a potent antidepressant-like effect in the mice tail suspension test (MED = 10 mg/kg, p.o.), proportional monoamine transporter occupancies and enhancement of monoamine concentrations in mouse prefrontal cortex.

C2-hydroxyglycosylation with glycal donors. Probing the mechanism of sulfonium-mediated oxygen transfer to glycal enol ethers.

The C2-hydroxyglycosylation reaction employing the reagent combination of a diaryl sulfoxide and triflic anhydride offers a novel method for glycal assembly whereby a hydroxyl functionality is stereoselectively installed at the C2-position of a glycal donor with concomitant glycosylation of a nucleophilic acceptor. Mechanistic investigations into this reaction revealed a novel process for sulfonium-mediated oxidation of glycal enol ethers in which the sulfoxide oxygen atom is stereoselectively transferred to the C2-position of the glycal. (18)O-labeling studies revealed that the S-to-C2 oxygen-transfer process involves initial formation of a C1[bond]O linkage followed by O-migration to C2, leading to the generation of an intermediate glycosyl 1,2-anhydropyranoside that serves as an in situ glycosylating agent. These findings are consistent with the initial formation of a C2-sulfonium[bond]C1-oxosulfonium pyranosyl species upon activation of the glycal donor with Aryl(2)SO x Tf(2)O.