Unexpectedly rigid short peptide foldamers in which NH-π and CH-π interactions are preserved in solution.

NH-π and CH-π interactions, due to their weak character, are not easily identified in solution. We report a group of isolable short peptides with stable folds, in which NH-π and CH-π main chain-side chain interactions can be detected in solution by means of NMR and ATR-IR spectroscopy.

Peptide-based short single ß-strand mimics without hydrogen bonding or aggregation.

Generation of short peptides with a single ß-strand structure in solution is difficult. Herein, we design a new class of single ß-strand peptidic mimics that are stable without self-aggregation in protic and non-protic solvents. Introduction of one present ß-strand mimic can induce and propagate the ß-strand structure for at least a penta-peptide sequence.

Non-naturally Occurring Helical Molecules Can Interfere with p53-MDM2 and p53-MDMX Protein-Protein Interactions.

We have discovered that ß-amino acid homooligomers with cis- or trans-amide conformation can fold themselves into highly ordered helices. Moreover, unlike α-amino acid peptides, which are significantly stabilized by intramolecular hydrogen bonding, these helical structures are autogenous conformations that are stable without the aid of hydrogen bonding and irrespective of solvent (protic/aprotic/halogenated) or temperature. A structural overlap comparison of helical cis/trans bicyclic ß-proline homooligomers with typical α-helix structure of α-amino acid peptides reveals clear differences of pitch and diameter per turn. Bridgehead substituents of the present homooligomers point outwards from the helical surface. We were interested to know whether such non-naturally occurring divergent helical molecules could mimic α-helix structures. In this study, we show that bicyclic ß-proline oligomer derivatives inhibit p53-MDM2 and p53-MDMX protein-protein interactions, exhibiting MDM2-antagonistic and MDMX-antagonistic activities.

Overall Shape Constraint of Alternating α/ß-Hybrid Peptides Containing Bicyclic ß-Proline.

Our NMR, IR/Raman, CD spectroscopic, and X-ray crystallographic studies, as well as accelerated molecular dynamics simulations, showed that alternating hybrid α/ß-peptides containing a bicyclic ß-proline surrogate form unique extended curved folds, regardless of the peptide length and solvent environment. It is suggested that extended ß/PPII structures are preferred in the insulating α-alanine moieties between the rigid bicyclic ß-proline structures. These hybrid peptides inhibit p53-MDM2 and p53-MDMX protein-protein interactions.

Uncovering the Networks of Topological Neighborhoods in ß-Strand and Amyloid ß-Sheet Structures.

Although multiple hydrophobic, aromatic π-π, and electrostatic interactions are proposed to be involved in amyloid fibril formation, the precise interactions within amyloid structures remain poorly understood. Here, we carried out detailed quantum theory of atoms-in-molecules (QTAIM) analysis to examine the hydrophobic core of amyloid parallel and antiparallel ß-sheet structures, and found the presence of multiple inter-strand and intra-strand topological neighborhoods, represented by networks of through-space bond paths. Similar bond paths from side chain to side chain and from side chain to main chain were found in a single ß-strand and in di- and tripeptides. Some of these bond-path networks were enhanced upon ß-sheet formation. Overall, our results indicate that the cumulative network of weak interactions, including various types of hydrogen bonding (X-H-Y; X, Y = H, C, O, N, S), as well as non-H-non-H bond paths, is characteristic of amyloid ß-sheet structure. The present study postulated that the presence of multiple through-space bond-paths, which are local and directional, can coincide with the attractive proximity effect in forming peptide assemblies. This is consistent with a new view of the van der Waals (vdW) interactions, one of the origins of hydrophobic interaction, which is updating to be a directional intermolecular force.

Amide nitrogen pyramidalization changes lactam amide spinning.

Although cis-trans lactam amide rotation is fundamentally important, it has been little studied, except for a report on peptide-based lactams. Here, we find a consistent relationship between the lactam amide cis/trans ratios and the rotation rates between the trans and cis lactam amides upon the lactam chain length of the stapling side-chain of two 7-azabicyclo[2.2.1]heptane bicyclic units, linked through a non-planar amide bond. That is, as the chain length increased, the rotational rate of trans to cis lactam amide was decreased, and consequently the trans ratio was increased. This chain length-dependency of the lactam amide isomerization and our simulation studies support the idea that the present lactam amides can spin through 360 degrees as in open-chain amides, due to the occurrence of nitrogen pyramidalization. The tilting direction of the pyramidal amide nitrogen atom of the bicyclic systems is synchronized with the direction of the semicircle-rotation of the amide.

Application of C-Terminal 7-Azabicyclo[2.2.1]heptane to Stabilize ß-Strand-like Extended Conformation of a Neighboring α-Amino Acid.

ß-Strands are formed by extended linear peptide chains that are usually paired to form ß-sheet structure through interstrand hydrogen bonding. Linking a structured organic molecule with α-amino acid(s) can enforce or stabilize ß-strand-like extended structures of the jointed amino acids. Spectroscopic and simulation studies indicated that the presence of a C-terminal 7-azabicyclo[2.2.1]heptane amine (Abh) favors a ß-strand-like extended conformation of the adjacent α-amino acid on the N side. The bridgehead substitution of the Abh unit biases the amide cis-trans equilibrium of the adjacent α-amino acid residue to cis conformation. The proximity, specified by the presence of bond paths (such as H-H bond path) between the bridgehead proton of Abh and the α-proton of the α-amino acid provides a driving force favoring the extended conformation, which is independent of solvents. These results provide a basis for de novo design of ß-strand-mimicking extended peptides by using ß-strand enforcer/stabilizer even in the absence of the interstrand hydrogen bonding.

Unexpected Resistance to Base-Catalyzed Hydrolysis of Nitrogen Pyramidal Amides Based on the 7-Azabicyclic[2.2.1]heptane Scaffold.

Non-planar amides are usually transitional structures, that are involved in amide bond rotation and inversion of the nitrogen atom, but some ground-minimum non-planar amides have been reported. Non-planar amides are generally sensitive to water or other nucleophiles, so that the amide bond is readily cleaved. In this article, we examine the reactivity profile of the base-catalyzed hydrolysis of 7-azabicyclo[2.2.1]heptane amides, which show pyramidalization of the amide nitrogen atom, and we compare the kinetics of the base-catalyzed hydrolysis of the benzamides of 7-azabicyclo[2.2.1]heptane and related monocyclic compounds. Unexpectedly, non-planar amides based on the 7-azabicyclo[2.2.1]heptane scaffold were found to be resistant to base-catalyzed hydrolysis. The calculated Gibbs free energies were consistent with this experimental finding. The contribution of thermal corrections (entropy term, ⁻TΔS‡) was large; the entropy term (ΔS‡) took a large negative value, indicating significant order in the transition structure, which includes solvating water molecules.