The seaweed
Fucus vesiculosus is unusual when compared with other algal species, in that it cansurvive in toxic-metal-contaminated aquatic environments. The metallothionein gene has been identifiedin
F. vesiculosus by Kille and co-workers (Morris, C. A., Nicolaus, B., Sampson, V., Harwood, J. L.,and Kille, P. (1999)
Biochem. J. 338, 553), which suggests a possible protective mechanism againsttoxic metals for this species. We report the first detailed study of the metal binding properties of
F.vesiculosus metallothionein using UV absorption, circular dichroism (CD), and electrospray mass spectraltechniques. The overall metal-to-sulfur ratios of this novel algal protein when bound to divalent cadmiumand zinc were determined to be Cd
6S
16 and Zn
6S
16, respectively. Mixed Cd/Zn species were also formedwhen Cd
2+ was added to the Zn-containing
Fucus metallothionein. Only one conformation was identifiedat low pH for the native protein. Analysis of the UV absorption, CD, and ESI-MS spectral data recordedduring stepwise, acid-induced demetalation supports a two-domain structure for the protein, with two3-metal binding sites. The data suggest that one of the domains is significantly less stable than the other,and we tentatively propose from the arrangement of cysteines in the sequence that the two domains areM
3S
7 and M
3S
9 (where M = Cd
2+ or Zn
2+). While the M
3S
9 cluster is known in the
clusters of crab,lobster, and mammalian metallothioneins, the M
3S
7 is a hitherto unknown cluster structure. Metallothioneinin
F. vesiculosus is thought to act as a protective mechanism against incoming toxic metals. The metalbinding studies reported are a putative model for metal binding in vivo.