An Alkyne Rod to Constrain a Peptide Backbone in an Extended Conformation

Stretching Peptides to Generate Small Molecule β-Strand Mimics

Advances in the modulation of protein-protein interactions (PPIs) enable both characterization of PPI networks that govern diseases and design of therapeutics and probes. The shallow protein surfaces that dominate PPIs are challenging to target using standard methods, and approaches for accessing extended backbone structures are limited. Here, we incorporate a rigid, linear, diyne brace between side chains at the i to i+2 positions to generate a family of low-molecular-weight, extended-backbone peptide macrocycles. NMR and density functional theory studies show that these stretched peptides adopt stable, rigid conformations in solution and can be tuned to explore extended peptide conformational space. The diyne brace is formed in excellent conversions (>95%) and amenable to high-throughput synthesis. The minimalist structure-inducing tripeptide core (<300 Da) is amenable to further synthetic elaboration. Diyne-braced inhibitors of bacterial type 1 signal peptidase demonstrate the utility of the technique.

The 1,3-diyne linker as a rigid "i,i+7" staple for α-helix stabilization: Stereochemistry at work

Short alphahelical peptide sequences were stabilized through Glaser-Hay couplings of propargylated l- and/or d-serine residues at positions i and i+7. NMR analysis confirmed a full stabilization of the helical structure when a d-Ser (i), l-Ser (i+7) combination was applied. In case two l-Ser residues were involved in the cyclization, the helical conformation is disrupted outside the peptide's macrocycle.

Application of Glaser-Hay Diyne Coupling To Constrain Nα-Amino Acid Amides via a N-N Bridge

We present the application of a Glaser-Hay diyne coupling for the synthesis of conformationally constrained N^α-amino acid amides with different diyne ring sizes. Twelve-membered rings were the smallest rings that could be prepared by this approach. We observed the formation of triethylammonium adducts in the cases of smaller (10- and 11-membered) rings. Calculation of the conformational barriers for the cyclization reactions of various ring sizes demonstrated that the formation of amino acid-derived smaller rings by this reaction is thermodynamically unfavorable.