Abstract
Prolyl-4-hydroxylation is an ancient evolutionarily conserved post-translational modification (PTM) critical for both structural and regulatory functions in multicellular life forms. This PTM plays a pivotal role in stabilizing collagen's triple helix by influencing the puckering of the pyrrolidine ring. The elegant interplay between ring pucker, torsional angles, peptide bond isomerization, and charge-transfer interactions (O···C=O n→π∗ and σ→σ∗) attaining the helical stability remains underappreciated. Using density functional theory calibrated against gold standard ab initio methods, we analyzed a physiologically relevant collagenous peptide proline-4-hydroxyproline-glycine (PO(4)G) to establish the correlation between stereo-electronic effects due to prolyl-4-hydroxylation. Our results show that 4(R)-hydroxylation promotes an exo ring pucker, optimizing main-chain torsional angles for a stable trans peptide bond and maximizing the n→π∗ interaction (E (n→π∗) = 0.9 kcal/mol) by tuning Bürgi-Dunitz trajectory, and maximizes σ→σ∗ interactions between axial C-H σ-electrons and C-OH∗ orbitals of the pyrrolidine ring. This study reveals the intricate stereo-electronic effects driving collagen's structural stability.