Quantitative determination of conformations of flexible molecules in solution using lanthanide ions as nuclear magnetic resonance probes: Application to adenosine-5′-monophosphate

A procedure is described here whereby the conformation, of a flexible molecule in solution can be found. The method depends on the study of the nuclear magnetic resonance spectrum of the molecule in the presence of perturbations due to specifically bound lanthanide cations. The magnetic perturbations are of two kinds: shifts of nuclear magnetic resonance spectral lines in the presence of cations such as Eu 3+ and changes in relaxation rates of the nuclear magnetic resonance excitations in the presence of cations such as Gd 3+. Suitable expressions are given for the relation between the magnitude of the perturbations and the geometry of the lanthanide complex in the absence of through-bond perturbations and for an axially symmetric system. It is proved that the spectral changes described here are not due to through-bond (contact) effects. The circumstances, in which the anisotropy of the magnetic susceptibility tensor, as seen in the nuclear magnetic resonance spectra, is of axial symmetry, are defined. The experimental systems described are of this kind. A computer program has been devised that searches for the conformations of the molecule which fit the nuclear magnetic resonance data. We outline here the principles of the method and how we have used a combination of relaxation and shift probes to obtain the conformation of adenosine-5′-monophosphate at pH 2. It is shown that a small family of closely related conformations fit the nuclear magnetic resonance data. These conformations are very similar to that of the crystal structure of AMP.