Unlike thioredoxins, glutaredoxins are involved in ironsulfur cluster assembly and in reduction of specific disulfides (i.e. protein-glutathione adducts), and thus they are also important redox regulators of chloroplast metabolism. Using GFP fusion, AtGrxC5 isoform, present exclusively in Brassicaceae, was shown to be localized in chloroplasts. A comparison of the biochemical, structural, and spectroscopic properties of Arabidopsis GrxC5 (WCSYC active site) with poplar GrxS12 (WCSYS active site), a chloroplastic paralog, indicated that, contrary to the solely apomonomeric GrxS12 isoform, AtGrxC5 exists as two forms when expressed in Escherichia coli. The monomeric apoprotein possesses deglutathionylation activity mediating the recycling of plastidial methionine sulfoxide reductase B1 and peroxiredoxin IIE, whereas the dimeric holoprotein incorporates a [2Fe-2S] cluster. Site-directed mutagenesis experiments and resolution of the x-ray crystal structure of AtGrxC5 in its holoform revealed that, although not involved in its ligation, the presence of the second active site cysteine (Cys 32 ) is required for cluster formation. In addition, thiol titrations, fluorescence measurements, and mass spectrometry analyses showed that, despite the presence of a dithiol active site, AtGrxC5 does not form any inter-or intramolecular disulfide bond and that its activity exclusively relies on a monothiol mechanism.
Glutaredoxins (Grxs) are major oxidoreductases involved in the reduction of glutathionylated proteins. Owing to the capacity of several class I Grxs and likely all class II Grxs to incorporate iron-sulfur (Fe-S) clusters, they are also linked to iron metabolism. Most Grxs bind [2Fe-2S] clusters which are oxidatively- and reductively-labile and have identical ligation, involving notably external glutathione. However, subtle differences in the structural organization explain that class II Fe-S Grxs, having more labile and solvent-exposed clusters, can accept Fe-S clusters and transfer them to client proteins, whereas class I Fe-S Grxs usually do not. From the observed glutathione disulfide-mediated Fe-S cluster degradation, the current view is that the more stable Fe-S clusters found in class I Fe-S Grxs might constitute a sensor of oxidative stress conditions by modulating their activity. Indeed, in response to an oxidative signal, inactive holoforms i.e., without disulfide reductase activity, should be converted to active apoforms. Among class II Fe-S Grxs, monodomain Grxs likely serve as carrier proteins for the delivery of preassembled Fe-S clusters to acceptor proteins in organelles. Another proposed function is the repair of Fe-S clusters. From their cytoplasmic and/or nuclear localization, multidomain Grxs function in signalling pathways. In particular, they regulate iron homeostasis in yeast species by modulating the activity of transcription factors and eventually forming heterocomplexes with BolA-like proteins in response to the cellular iron status. We provide an overview of the biochemical and structural properties of Fe-S cluster-loaded Grxs in relation to their hypothetical or confirmed associated functions. This article is part of a Special Issue entitled: Fe/S proteins: Analysis, structure, function, biogenesis and diseases.
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