Steric and electronic interactions controlling the cis/trans isomer equilibrium at X-pro tertiary amide motifs in solution

cisPro stabilization in prolyl carbamates influenced by tetrel bonding interactions

NMR spectral and theoretical analyses of homologous prolyl carbamates reveal subtle charge transfer tetrel bonding interactions (TBIs), selectively stabilizing their cisPro rotamers. These TBIs involve C-terminal-amide to N-terminal carbamate carbonyl-carbonyl (n → π* type) followed by intra-carbamate (n → σ* type) charge transfer interactions exclusively in the cisPro motif. The number of TBIs and hence the cisPro stability increase with increasing number of Cβ groups at the carbamate alcohol. Increasing solvent polarities also increase the relative cisPro carbamate stabilities.

Understanding the anomaly of cis-trans isomerism in Pro-His sequence

The anomalous absence of cisPro stabilizing C^αH^α_Xaa···π_Aro interactions at Xaa-Pro-Aro exclusively when Aro is His, is understood by NMR structural analyses of model peptides, as due to i → i backbone-side chain C₆ H-bond that forms uniquely when Aro is His, which significantly decreases its χ₁-g^- population essential for C^αH^α_Xaa···π_Aro formation.

Energetic Descriptors of Steric Hindrance in Real Space: An Improved IQA Picture*

Steric hindrance (SH) plays a central role in the modern chemical narrative, lying at the core of chemical intuition. As it however happens with many successful chemical concepts, SH lacks an underlying physically sound root, and multiple mutually inconsistent approximations have been devised to relate this fuzzy concept to computationally derivable descriptors. We here argue that being SH related to spatial as well as energetic features of interacting systems, SH can be properly handled if we chose a real space energetic stance like the Interacting Quantum Atoms (IQA) approach. Drawing on previous work by Popelier and coworkers (ChemistryOpen 8, 560, 2019) we build an energetic estimator of SH, referred to as E_ST . We show that the rise in the self-energy of a fragment that accompanies steric congestion is a faithful proxy for the chemist's SH concept if we remove the effect of charge transfer. This can be done rigorously, and the E_ST here defined provides correct sterics even for hydrogen atoms, where the plain use of deformation energies leads to non-chemical results. The applicability of E_ST is validated in several chemical scenarios, going from atomic compressions to archetypal S_N2 reactions. E_ST is shown to be a robust steric hindrance descriptor.

A kinetic method for detecting intramolecular peptide H-bonds

The current method for the detection of peptide hydrogen bond (PHB) formation places charge donors/acceptors (D/A) at the N-/C-termini of the peptides involved in the putative PHB.

The Distinct Conformational Landscapes of 4S-Substituted Prolines That Promote an endo Ring Pucker

4-Substitution on proline directly impacts protein main chain conformational preferences. The structural effects of N-acyl substitution and of 4-substitution were examined by NMR spectroscopy and X-ray crystallography on minimal molecules with a proline 4S-nitrobenzoate. The effects of N-acyl substitution on conformation were attenuated in the 4S-nitrobenzoate context, due to the minimal role of the n→π* interaction in stabilizing extended conformations. By X-ray crystallography, an extended conformation was observed for most molecules. The formyl derivative adopted a δ conformation that is observed at the i+2 position of β-turns. Computational analysis indicated that the structures observed crystallographically represent the inherent conformational preferences of 4S-substituted prolines with electron-withdrawing 4-position substituents. The divergent conformational preferences of 4R- and 4S-substituted prolines suggest their wider structure-specific application in molecular design. In particular, the proline endo ring pucker favored by 4S-substituted prolines uniquely promotes the δ conformation [(ϕ, ψ) ≈(-80°, 0°)] found in β-turns. In contrast to other acyl capping groups, the pivaloyl group strongly promoted trans amide bond and polyproline II helix conformation, with a close n→π* interaction in the crystalline state, despite the endo ring pucker, suggesting its special capabilities in promoting compact conformations in ϕ due to its strongly electron-donating character.

Electronic and Steric Control of n→π* Interactions: Stabilization of the α-Helix Conformation without a Hydrogen Bond

The preferred conformations of peptides and proteins are dependent on local interactions that bias the conformational ensemble. The n→π* interaction between consecutive carbonyls promotes compact conformations, including the α-helix and polyproline II helix. In order to further understand the n→π* interaction and to develop methods to promote defined conformational preferences through acyl N-capping motifs, a series of peptides was synthesized in which the electronic and steric properties of the acyl group were modified. Using NMR spectroscopy, van't Hoff analysis of enthalpies, X-ray crystallography, and computational investigations, we observed that more electron-rich donor carbonyls (pivaloyl, iso-butyryl, propionyl) promote stronger n→π* interactions and more compact conformations than acetyl or less electron-rich donor carbonyls (methoxyacetyl, fluoroacetyl, formyl). X-ray crystallography indicates a strong, electronically tunable preference for the α-helix conformation, as observed directly on the φ and ψ torsion angles. Electron-donating acyl groups promote the α-helical conformation, even in the absence of the hydrogen bonding that stabilizes the α-helix. In contrast, electron-withdrawing acyl groups led to more extended conformations. More sterically demanding groups can promote trans amide bonds independent of the electronic effect on n→π* interactions. Chloroacetyl groups additionally promote n→π* interactions through the interaction of the chlorine lone pair with the proximal carbonyl π*. These data provide additional support for an important role of n→π* interactions in the conformational ensemble of disordered or unfolded proteins. Moreover, this work suggests that readily incorporated acyl N-capping motifs that modulate n→π* interactions may be employed rationally to promote conformational biases in peptides, with potential applications in molecular design and medicinal chemistry.