Abstract
Selenoproteins serve important functions in many organisms, usually providing essential oxidoreductase enzymatic activity, often for defense against toxic xenobiotic substances. Most eukaryotic genomes possess a small number of these proteins, usually not more than 20. Selenoproteins belong to various structural classes, often related to oxidoreductase function, yet a few of them are completely uncharacterised.Here, the structural and functional prediction for the uncharacterised selenoprotein O (SELO) is presented. Using bioinformatics tools, we predict that SELO protein adopts a three-dimensional fold similar to protein kinases. Furthermore, we argue that despite the lack of conservation of the “classic” catalytic aspartate residue of the archetypical His-Arg-Asp motif, SELO kinases might have retained catalytic phosphotransferase activity, albeit with an atypical active site. Lastly, the role of the selenocysteine residue is considered and the possibility of an oxidoreductase-regulated kinase function for SELO is discussed.The novel kinase prediction is discussed in the context of functional data on SELO orthologues in model organisms, FMP40 a.k.a.YPL222W (yeast), and ydiU (bacteria). Expression data from bacteria and yeast suggest a role in oxidative stress response. Analysis of genomic neighbourhoods of SELO homologues in the three domains of life points toward a role in regulation of ABC transport, in oxidative stress response, or in basic metabolism regulation. Among bacteria possessing SELO homologues, there is a significant over-representation of aquatic organisms, also of aerobic ones. The selenocysteine residue in SELO proteins occurs only in few members of this protein family, including proteins from Metazoa, and few small eukaryotes (Ostreococcus, stramenopiles). It is also demonstrated that enterobacterial mchC proteins involved in maturation of bactericidal antibiotics, microcins, form a distant subfamily of the SELO proteins.The new protein structural domain, with a putative kinase function assigned, expands the known kinome and deserves experimental determination of its biological role within the cell-signaling network.
Highlights
Selenoproteins are an intriguing evolutionary creation, characterised by the presence of an atypical aminoacid residue, selenocysteine
Human selenoproteins are encoded by 25 genes, and most of those with known functions are oxidoreductases with a selenocysteine being in the active site
Similar results were obtained for the Escherichia coli and yeast orthologues
Summary
Selenoproteins are an intriguing evolutionary creation, characterised by the presence of an atypical aminoacid residue, selenocysteine. Among the unique properties of selenocysteine, instead of cysteine in enzymatic active sites, higher nucleophilicity of Sec versus Cys, higher oxidoreductase efficiency, and lower pKa, have been cited [1]. Human selenoproteins are encoded by 25 genes, and most of those with known functions are oxidoreductases with a selenocysteine being in the active site. We suppose that in the uncharacterised selenoproteins, a selenocysteine residue conserved in evolution is not very likely to be just a troublesome decoration. We undertook a structural and functional prediction study for the human selenoprotein O (SELO), one of the very few uncharacterised selenoproteins in humans. SELO selenoproteins have a single selenocysteine residue while those family members that are not selenoproteins, usually have a cysteine residue instead in the corresponding position. In most eukaryotes and many bacteria, SELO is present as a single-copy protein, while duplicate copies in many metazoans and a few bacteria exist
Sign-in/Register to view highlights & summary 
Published Version (
Free)
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call