Abstract
The formate dehydrogenases (Fdh) Fdh-O, Fdh-N, and Fdh-H, are the only proteins in Escherichia coli that incorporate selenocysteine at a specific position by decoding a UGA codon. However, an excess of selenium can lead to toxicity through misincorporation of selenocysteine into proteins. To determine whether selenocysteine substitutes for cysteine, we grew Escherichia coli in the presence of excess sodium selenite. The respiratory Fdh-N and Fdh-O enzymes, along with nitrate reductase (Nar) were co-purified from wild type strain MC4100 after anaerobic growth with nitrate and either 2 µM or 100 µM selenite. Mass spectrometric analysis of the catalytic subunits of both Fdhs identified the UGA-specified selenocysteine residue and revealed incorporation of additional, ‘non-specific’ selenocysteinyl residues, which always replaced particular cysteinyl residues. Although variable, their incorporation was not random and was independent of the selenite concentration used. Notably, these cysteines are likely to be non-essential for catalysis and they do not coordinate the iron-sulfur cluster. The remaining cysteinyl residues that could be identified were never substituted by selenocysteine. Selenomethionine was never observed in our analyses. Non-random substitution of particular cysteinyl residues was also noted in the electron-transferring subunit of both Fdhs as well as in the subunits of the Nar enzyme. Nar isolated from an E. coli selC mutant also showed a similar selenocysteine incorporation pattern to the wild-type indicating that non-specific selenocysteine incorporation was independent of the specific selenocysteine pathway. Thus, selenide replaces sulfide in the biosynthesis of cysteine and misacylated selenocysteyl-tRNACys decodes either UGU or UGC codons, which usually specify cysteine. Nevertheless, not every UGU or UGC codon was decoded as selenocysteine. Together, our results suggest that a degree of misincorporation of selenocysteine into enzymes through replacement of particular, non-essential cysteines, is tolerated and this might act as a buffering system to cope with excessive intracellular selenium.
Highlights
The 21st amino acid is selenocysteine and it is co-translationally incorporated at a specific position in the amino acid sequence of selenoproteins such as the formate dehydrogenases (Fdh) of Escherichia coli [1,2]
The advantage of the selenol over thiol in catalysis is exemplified by a Fdh-H SecRCys variant of E. coli, which is approximately 300fold less catalytically active compared with the wild-type selenocysteine-containing enzyme [5]
Despite early reports suggesting that selenomethionine could be synthesized and incorporated in E. coli [8], later studies with mutants defective in cysteine and methionine biosynthesis [7] indicated that selenocysteine is likely the form in which selenium is nonspecifically incorporated into proteins
Summary
The 21st amino acid is selenocysteine and it is co-translationally incorporated at a specific position in the amino acid sequence of selenoproteins such as the formate dehydrogenases (Fdh) of Escherichia coli [1,2]. Specific incorporation of selenocysteine is directed by an in-frame UGA codon in the mRNA encoding these enzymes. As well as being an essential trace element excess selenium can be toxic for cells. This is mainly due to the high reactivity of the selenol group, e.g. of selenocysteine, which is strongly nucleophilic [4]. The advantage of the selenol over thiol in catalysis is exemplified by a Fdh-H SecRCys variant of E. coli, which is approximately 300fold less catalytically active compared with the wild-type selenocysteine-containing enzyme [5]. The limited studies performed on selenium toxicity in E. coli strongly suggest that selenium is incorporated non- into proteins as selenocysteine, presumably by replacing cysteines [6,7]. The fact that the O-acetylserine synthetases of E. coli can accept selenide as a substrate [9], coupled with the effective aminoacylation of cysteinyl-tRNA by selenocysteine [6,10] supports this proposal
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