文摘
Relativistic density functional theory (DFT) has been applied to explore electron paramagnetic resonance (EPR) parameters as well as ground-state spin properties of cob(II)alamin. Cob(II)alamin is an intermediate which participates in many reactions catalyzed by derivatives of vitamin B12 and that can be detected by EPR spectroscopy due to the presence of the paramagnetic CoII(d7) center. The full structure of cob(II)alamin and its truncated analogues were examined. Three different DFT functionals, B3LYP, BP86, and PBE, have been applied to obtain the g- and A-tensors. Both tensors are axially symmetric and can provide useful insight into specific axial ligand interactions. Of the functionals tested, the hybrid B3LYP functional, was found to overestimate the axial bond length, whereas the GGA-type functionals, BP86 and PBE, produced geometries consistent with experimental data. The reliability of nonrelativistic and approximate relativistic methods for the calculation of EPR parameters has also been tested against a fully relativistic four-component approach. Since the EPR parameters are very sensitive to the local environment surrounding CoII, a theoretical (DFT-BP86) estimate of the dependence of the g- and A-tensors on the metal-to-axial ligand interatomic distance can be directly correlated with EPR measurements. The usefulness of such an approach has been demonstrated for the methionine synthase enzyme where the reduction of cob(II)alamin takes place during the reactivation cycle.