Project description:Appropriately-placed hydrogen bond surrogates have been demonstrated to efficiently nucleate helical conformations. Herein we describe an efficient method for the synthesis of thioether-based hydrogen bond surrogate (teHBS) helices. A teHBS helix is shown to adopt a stable conformation and target its cognate protein receptor with high affinity.

Project description:Substitution of a main chain i ? i + 4 hydrogen bond with a covalent bond can nucleate and stabilize the ?-helical conformation in peptides. Herein we describe the potential of different alkene isosteres to mimic intramolecular hydrogen bonds and stabilize ?-helices in diverse peptide sequences.

Project description:Solid phase synthesis of HBS helices involving the Fukuyama-Mitsunobu reaction and triphosgene coupling is described.

Project description: Not available

Project description:We previously reported the design and synthesis of a new class of artificial alpha-helices in which an N-terminal main-chain hydrogen bond is replaced by a carbon-carbon bond derived from a ring-closing metathesis reaction [Chapman, R. N.; Dimartino, G.; Arora, P. S. J. Am. Chem. Soc. 2004, 126, 12252-12253]. Our initial study utilized an alanine-rich sequence; in the present manuscript we evaluate the potential of this method for the synthesis of very short (10 residues) alpha-helices representing two different biologically relevant alpha-helical domains. We extensively characterized these two sets of artificial helices by NMR and circular dichroism spectroscopies and find that the hydrogen-bond surrogate approach can afford well-defined short alpha-helical structures from sequences that do not spontaneously form alpha-helical conformations.

Project description:A new peptide modification strategy was recently developed to replace the i to i + 4 hydrogen bond of the main chain of an alpha-helix with a carbon-carbon covalent bond to afford highly stable constrained alpha-helices, termed hydrogen-bond surrogate (HBS) helices. HBS helices that mimic the Bak BH3 domains were experimentally demonstrated to target protein Bcl-x(L) with high affinity. In this study, molecular dynamics (MD) simulation is used to understand how the covalent modification of the natural Bak sequence affects the binding to Bcl-x(L) at molecular levels. The binding mechanism of HBS helix to Bcl-x(L) and the effect of synthesized cyclic structures are analyzed by MD and MM-PBSA calculations for comparison with the native binding of Bak-Bcl-x(L). The present MD result shows that the entropy of the HBS structure is considerably reduced, and the presence of the N-terminal HBS macrocycle impacts residues at the C-terminus of the helix, but the conformation of the corresponding binding structures is not significantly changed. Our analysis shows that substitution of an aspartic acid residue--a helix breaker--with a hydrophobic residue not only enhances the helicity of the peptide but also stabilizes the structure of the binding complex. The present computational result is consistent with the experimental observation and provides explanations for the altered binding properties of the artificial Bak alpha-helix. Our study underscores the importance of the dynamical effect in protein-peptide interaction in which entropic effect plays a major role.

Project description: Not available

Project description:This manuscript discusses microwave-assisted solid-phase synthesis of hydrogen-bond surrogate based alpha-helices and analogues by ring-closing metathesis (RCM). Microwave-mediated RCM allows access to a greater variety of amino acid residues in the macrocycles in shorter reaction times and higher yields compared to conventional heating. Surprisingly, we discovered that the Grubbs II catalyst is highly active under the influence of microwaves but catalytically dead under oil-bath conditions for the metathesis of these peptide bisolefins. [reaction: see text]

Project description:Strategically placed covalent linkages have been shown to stabilize helical conformations in short peptide sequences. Here we report the synthesis of a stabilized α-helix that utilizes an internal disulfide linkage. Structural analysis indicates that the dynamic nature of the disulfide bridge allows for the reversible formation of an α-helix through oxidation and reduction reactions.

Project description:Peptide secondary and tertiary structure motifs frequently serve as inspiration for the development of protein-protein interaction (PPI) inhibitors. While a wide variety of strategies have been used to stabilize or imitate α-helices, similar strategies for β-sheet stabilization are more limited. Synthetic scaffolds that stabilize reverse turns and cross-strand interactions have provided important insights into β-sheet stability and folding. However, these templates occupy regions of the β-sheet that might impact the β-sheet's ability to bind at a PPI interface. Here, we present the hydrogen bond surrogate (HBS) approach for stabilization of β-hairpin peptides. The HBS linkage replaces a cross-strand hydrogen bond with a covalent linkage, conferring significant conformational and proteolytic resistance. Importantly, this approach introduces the stabilizing linkage in the buried β-sheet interior, retains all side chains for further functionalization, and allows efficient solid-phase macrocyclization. We anticipate that HBS stabilization of PPI β-sheets will enhance the development of β-sheet PPI inhibitors and expand the repertoire of druggable PPIs.