Abstract
The NIFS protein from Azobacter vinelandii is a pyridoxal phosphate-containing homodimer that catalyzes the formation of equimolar amounts of elemental sulfur and L-alanine from the substrate L-cysteine (Zheng, L., White, R. H., Cash, V. L., Jack, R. F., and Dean, D. R. (1993) Proc. Natl. Acad. Sci. U. S. A. 90, 2754-2758). A sulfur transfer role of NIFS in which the enzyme donates sulfur for iron sulfur center formation in nitrogenase was suggested. The fact that NIFS also can catalyze the decomposition of L-selenocysteine to elemental selenium and L-alanine suggested the possibility that this enzyme might serve as a selenide delivery protein for the in vitro biosynthesis of selenophosphate. In agreement with this hypothesis, we have shown that replacement of selenide with NIFS and L-selenocysteine in the in vitro selenophosphate synthetase assay results in an increased rate of formation of selenophosphate. These results thus support the view that a selenocysteine-specific enzyme similar to NIFS may be involved as an in vivo selenide delivery protein for selenophosphate biosynthesis. A kinetic characterization of the two NIFS catalyzed reactions carried out in the present study indicates that the enzyme favors L-cysteine as a substrate compared with its selenium analog. A specific activity for L-cysteine of 142 nmol/min/mg compared with 55 nmol/min/mg for L-selenocysteine was determined. This level of enzyme activity on the selenoamino acid substrate is adequate to deliver selenium to selenophosphate synthetase in the in vitro assay system described.
Highlights
Selenophosphate synthetase from E. coli has been characterized previously (2)
nifS gene product (NIFS) cysteine desulfurase activity was determined by monitoring the production of H2S in the methylene blue assay
A specific activity of 142 nmol/min/mg was determined for the NIFS reaction with L-cysteine, as well as a kcat of 6 minϪ1 and a Vmax of 2.4 nmol/min
Summary
Selenophosphate synthetase from E. coli has been characterized previously (2). The enzyme has a determined specific activity of 83 nmol/min/mg (kcat ϭ 3 minϪ1). Despite being below the Km value for one essential enzyme in the pathway, this concentration of selenide is sufficient for the biosynthesis of selenium-containing proteins and tRNAs. The E. coli selenophosphate synthetase contains an essential cysteine, Cys[17], within the glycine-rich sequence -Gly-Ala-GlyCys17-Gly-Cys-Lys-Ile-. There was no detectable incorporation of 14C or 3H into the selenocysteine amino acid of selenoprotein A (6) These results suggest an activated selenium derived from L-selenocysteine may be the optimal substrate for selenophosphate synthetase. This suggests the involvement of a selenocysteine lyase protein in substrate formation. Mihara et al (9) have found that the N-terminal amino acid sequence of the pig liver selenocysteine lyase is similar to the amino acid sequence of the cysteine desulfurase protein NIFS
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