Didemnin B Conformation and dynamics of an antitumour and antiviral depsipeptide studied in solution by 1H and 13C. n.m.r. spectroscopy

Abstract

The solution conformation of didemnin B, the most potent member of a family of depsipeptides that shows antitumour, antiviral, and immunosuppressive activity, has been studied in chloroform solution using n.m.r. spectroscopy. ¹H and ¹³C spectra have been assigned from analysis of a number of two‐dimensional homonuclear and heteronuclear chemical shift correlation experiments which confirm the recently corrected primary structure of the molecule. The conformation of the peptide has been deduced from measurements of the temperature dependence of the NH chemical shifts, analysis of coupling constant data and primarily through NOE effects observed in the rotating frame. Interproton distance bounds determined from a quantitative analysis of the ROE data provide 41 constraints from which a family of closely related structures were calculated using distance geometry algorithms. A type II β‐turn involving residues Thr⁶, Leu⁷, and Pro⁸ is well represented in the computed conformers as is a hydrogen bonding interaction between the NH of Leu³ and the carbonyl oxygen of Thr⁶. This latter interaction causes the linear portion of the structure to fold back over the depsipeptide ring, imparting to it a degree of structural stability as well as giving the molecule a somewhat globular character. Only one transannular hydrogen bond, between 1st¹ NH and Leu³ carbonyl, stabilizes the conformation of the depsipeptide, which has an irregular non‐planar configuration. The small temperature coefficients (< 2.0 × 10⁻³ppm/°C) for the NHs of 1st¹ and Leu³ are consistent with their involvement in these hydrogen bonding interactions. We find that many of the structural features observed in the crystalline form of didemnin B are conserved in solution. Analysis of the ¹³C spin‐lattice relaxation rates of the protonated carbons reveals small variations in effective correlation times at specific sites in the molecule. The data suggests that the peptide segment encompassing residues Leu³through to Thr⁶ is in a more motionally restricted part of the structure.