Nmr study of the structure of short‐chain peptides in solution

The electron‐mediated spin–spin coupling constant J between the amide NH and the α‐CH protons in the dipeptide fragment C α CO(NHC α H)RC′ONHC α is dependent on the dihedral angle of rotation (Φ) around the NC bond. Measurement of J in a series of zwitterionic dipeptides H 3 N + CHR 1 CONHCHR 2 CO 2 − (which is conformationally similar to the dipeptide fragment) in TFA solution shows that J is independent of R 1 , but dependent on the steric bulk of R 2 . The data are interpreted in terms of a model that assumes that what we measure is an average value of J a thermal average over all the possible rotamers. The groups R 1 and R 2 are, in most cases, sterically kept apart by the trans and planar amide bonds, and hence the independence of J of R 1 . This model is consistent with the theoretical calculations done on the dipeptide fragment. The effect of the structural characteristics of the side chains (e.g., the effect of lengthening and branching the side chains) on the J values in dipeptides is discussed in the light of the existing results of theoretical calculations. Study of 〈 J 〉 values in tripeptides (C 6 H 5 CH 2 OCONHCHR 1 CONHCHR 2 CO 2 CH 3 , essentially three linked peptide units) shows that electrostatic interaction between the two amide bonds modifies the potential energy surface and the 〈 J 〉 value of a dipeptide subunit in the tripeptides. Also in some cases, direct steric interaction between the two side chains in the two adjacent dipeptide subunits in the tripeptide affects the potential energy surfaces of the individual dipeptide subunits and hence the 〈 J 〉 values. The influence of the structural characteristics of the side chains of individual amino acids on structure formation at or beyond the dipeptide level is discussed at various points. The J (NH α CH) values of CH 3 CONHCHRCONH 2 and CH 3 CONHCHRCO 2 CH 3 with the same R are quite different for R = valine, leucine, phenylalanine, methionine, but equal for R = glycine. This, coupled with the fact that one of the carboxamide NH resonances has a chemical shift different from its counterpart in simple amides like CH 3 CONH 2 and the other carboxamide NH has the same chemical shift as its counterpart in CH 3 CONH 2 , suggest the presence of a hydrogen bond in dipeptide CH 3 CONHCHRCONH 2 with carboxamide NH as the donor. Theoretical evidence for two seven‐membered hydrogen‐bonded rings with the carboxamide NH as donor and the acetyl oxygen as acceptor is summarized. Our data cannot suggest the number of such hydrogen‐bonded rings, nor can they conclude the relative proportion of these rings in a particular dipeptide. A discussion of the difficulty of interpretation is presented and the data are discussed under certain simplifying assumptions.