Spectroscopic studies on cadmium(II)‐ and cobalt(II)‐substituted metallothionein from the crab Cancer pagurus

Abstract

The binding of diamagnetic Cd(II) and paramagnetic Co(II) ions to the metal‐free form of crab, Cancer pagurus , metallothionein (MT) was studied by various spectroscopic techniques. Both reconstituted and native Cd(II)‐MT containing 6 mol Cd(II)/mol protein display electronic absorption, circular dichroism (CD) and magnetic circular dichroism (MCD) spectra which were indistinguishable. The stoichiometric replacement of Cd(II) ions in native Cd(II) 6 ‐MT by paramagnetic Co(II) ions enabled the geometry of the metal‐binding sites to be probed. The electronic absorption and MCD spectra of Co(II) 6 ‐MT revealed features characteristic of distorted tetrahedral tetrathiolate Co(II) coordination for all six metal‐binding sites. The stepwise incorporation of Cd(II) and Co(II) ions into this protein was monitored by electronic absorption and CD, and by electronic absorption and EPR spectroscopy, respectively. The results indicate that the metal‐thiolate cluster structure is generated when more than four metal ions are bound. Below this titration point separate tetrahedral tetrathiolate complexes exist. This suggests that the cluster formation occurs in a two‐step process. Furthermore, the spectroscopic features in both Cd(II)‐ and Co(II)‐metal derivatives above the full metal occupancy of six suggest the existence of one additional metal‐binding site. The subsequent loss of one Cd(II) ion from crab Cancer Cd(II) 7 ‐MT in the gel filtration studies demonstrate the low metal‐binding affinity of the latter site. While the spectroscopic properties indicate an exclusively tetrahedral type of metal‐thiolate sulfur coordination for the binding of the first six metal ions, they suggest that the seventh metal ion is coordinated in a different fashion.