The single crystal X-ray diffraction analysis of a nonchiral beta-Ala-containing model peptide, Boc-beta-Ala-Aib-OCH3 1 (beta-Ala, 3-aminopropionic acid; Aib, alpha-aminoisobutyric acid), establishes the coexistence of distinctly different backbone conformations in two crystallographically independent molecules, A and B, in the asymmetric unit. Interestingly, the central mu torsion angle around the -C-beta-C-alpha- bond of the conformationally flexible beta-Ala residue appears to be critical in dictating the overall distinct structural features, i.e., in molecule A it adopts a folded gauche conformation: mu = -71.0 degrees, whereas it favors an extended trans conformation, mu = 161.2 degrees, in molecule B. As expected, the stereochemically constrained Aib residue preferred an energetically favorable folded backbone conformation, the torsion angles being phi = 46.2 degrees and psi = 48.3 degrees for molecule A and phi = -43.6 degrees and psi = -45.5 degrees for molecule B, lying in the left-handed and right-handed helical regions of the Ramachandran map, respectively. Considering the signs as well as the magnitudes of the backbone torsional angles, molecule A typically folds into a pseudo type III' beta-turn-like structure while molecule B prefers an overall extended conformation. Entrapping the two dramatically distinct conformational characteristics in the crystalline state clearly suggests that the gauche and the trans effects of the beta-Ala moieties are indeed energetically accessible to a short linear peptide and receive strong experimental support. The analyses permitted us to emphasize that in addition to conformational constraints of the neighboring residue, the chemical nature of the side-chain acyclic substituents and the "local environments" collectively seem to influence the stabilization of the folding-unfolding behavior of the two methylene units (-CONH-CH2-CH2-CONH-) in 1.