Ab initio studies of conformational properties of dimethyl diphosphate dianion and its complex with magnesium

The conformational properties of the diphosphate linkage have been studied with ab initio methods using the dimethyl diphosphate dianion (1) and magnesium dimethyl diphosphate (2) as models. The ab initio energy and geometry of the conformers around the P-O bonds have been determined at the self-consistent-field (SCF) using the 6-31G* and the tzp basis sets; whereas, the 6-31G* basis set alone has been used for 2. In addition, the adiabatic connection method (ACM) of density functional theory (DFT) using the dzvp basis set has been employed for 1. The optimization of all possible staggered conformers assumed for the four P-O bonds, led to nine minima for 1. In agreement with the general anomeric effect, the sc conformation about the P-O bonds is clearly preferred over the ap one. Vibrational frequencies were calculated at the SCF level using the 6-31G* basis set and used to evaluate zero-point energies, thermal energies, and entropies for all minima of 1. The effect of zero-point energies and thermal energies is quite small. However, the effect of entropies, mainly resulting from a multiplicity contribution, changes the stability of the conformers. For each minimum of 1, up to six different arrangements of the Mg²⁺ were used to determine minima of 2. This procedure led to 21 distinct minima. The presence of the magnesium counter-ion appeared to completely change the structure and relative energy of the conformers. The preferred structures of the complex exhibit the (sc, ap) orientation around the two central P–O bonds and an arrangement in which the magnesium cation is coordinated by three phosphoryl oxygen atoms. The results of this work clearly demonstrate that interactions with the metal counter-ion can induce conformational changes in the overall 3D-shape adopted by molecules containing diphosphate linkages. The PM3 and MNDO quantum semi-empirical methods and molecular mechanics methods using the CVFF force field were tested and large differences in the minimum structures, as well as in the conformational energies between these and ab initio methods, are discussed.