| Abstract: | This study was undertaken to investigate the conformational states of the two metal sites in the human serum transferrin molecule. The 9.2 GHz electron paramagnetic resonance spectra of frozen solutions of divanadyl(IV) transferrin consist of a superposition of two sets of resonances, A and B, due to the magnetically nonequivalent binding environments of the VO2+ ion. Examination of the intensities of the A and B resonances as a function of pH from 6.0 to 10.7 reveals that they arise from two conformational states of the metal sites in which the geometrical arrangement and/or identity of one or more ligands in the first coordination sphere are different. From pH 7.5 to 9.0, the metal sites exist in A and B conformations but above pH 9.0 the A conformation. This transformation is coupled to the ionization of an apparently noncoordinating protein functional group with a pK - 10.0 +/- 0.1. Below pH 7.0, binding in the B conformation is rapidly lost, driven in part by the protonation of a functional group, possibly the anion, with a pK - 6.6 +/- 0.1. In 90% D2O, this pK is elevated to 7.8 +/- 0.1. At pH 6.0 in H2O, essentially one VO2+ ion remains bound to the protein with the metal site in the A conformation. Experiments with mixed VO2+ -Fe3+ transferrin complexes indicate that the same may be true of Fe3+. At pH 10.7, a new set of VO2+ resonances, labeled C, are observed; they possibly arise from a third conformation of the metal site. One bicarbonate or corbonate is required per VO2+ ion bound to the protein. 2.7 H+ are released per VO2+ bound in either the A or B conformations. The above results are discussed in terms of the "equivalence" and "nonequivalence" of the metal sites. |
