Cellular Zinc and Redox States Converge in the Metallothionein/Thionein Pair

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Supplement: 11th International Symposium on Trace Elements in Man and Animals

Cellular Zinc and Redox States Converge in the Metallothionein/Thionein Pair^{¹ ^,2}

Wolfgang Maret³

Center for Biochemical and Biophysical Sciences and Medicine, Harvard Medical School, Cambridge, MA 02139

³ To whom correspondence should be addressed. E-mail: wolfgang_maret{at}hms.harvard.edu.

The paramount importance of zinc for a wide range of biologicalfunctions is based on its occurrence in thousands of known zincproteins. To regulate the availability of zinc dynamically,eukaryotes have compartmentalized zinc and the metallothionein/thioneinpair, which controls the pico- to nanomolar concentrations ofmetabolically active cellular zinc. Interactions of zinc withsulfur ligands of cysteines turn out to be critical both fortight binding and creation of a redox-active coordination environmentfrom which the redox-inert zinc can be distributed. Biologicaloxidants such as disulfides and S-nitrosothiols oxidize thezinc/thiolate clusters in metallothionein with concomitant zincrelease. In addition, selenium compounds that have the capacityto form selenol(ate)s catalytically couple with the glutathione/glutathionedisulfide and metallothionein/thionein redox pairs to eitherrelease or bind zinc. In this pathway, selenium expresses itsantioxidant effects through redox catalysis in zinc metabolism.Selenium affects the redox state of thionein, an endogenouschelating agent. With its 20 cysteines, thionein contributessignificantly to the zinc- and thiol-redox–buffering capacityof the cell. Thus, hitherto unknown interactions between theessential micronutrients zinc and selenium on the one hand andzinc and redox metabolism on the other are key features of thecellular homeostatic zinc system.

KEY WORDS: • metallothionein • thionein • zinc • redox • mitochondria

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Supplement: 11th International Symposium on Trace Elements in Man and Animals

Cellular Zinc and Redox States Converge in the Metallothionein/Thionein Pair 1 ,2

Cellular Zinc and Redox States Converge in the Metallothionein/Thionein Pair^{¹ ^,2}