Monothiol Glutaredoxins and A-Type Proteins: Partners in Fe–S Cluster Trafficking

Monothiol glutaredoxins (Grxs) are proposed to function in Fe-S cluster storage and delivery, based on their ability to exist as apo monomeric forms and dimeric forms containing a subunit-bridging [Fe2S2](2+) cluster, and to accept [Fe2S2](2+) clusters from primary scaffold proteins. In addition yeast cytosolic monothiol Grxs interact with Fra2 (Fe repressor of activation-2), to form a heterodimeric complex with a bound [Fe2S2](2+) cluster that plays a key role in iron sensing and regulation of iron homeostasis. In this work, we report on in vitro UV-visible CD studies of cluster transfer between homodimeric monothiol Grxs and members of the ubiquitous A-type class of Fe-S cluster carrier proteins ((Nif)IscA and SufA). The results reveal rapid, unidirectional, intact and quantitative cluster transfer from the [Fe2S2](2+) cluster-bound forms of A. thaliana GrxS14, S. cerevisiae Grx3, and A. vinelandii Grx-nif homodimers to A. vinelandii (Nif)IscA and from A. thaliana GrxS14 to A. thaliana SufA1. Coupled with in vivo evidence for interaction between monothiol Grxs and A-type Fe-S cluster carrier proteins, the results indicate that these two classes of proteins work together in cellular Fe-S cluster trafficking. However, cluster transfer is reversed in the presence of Fra2, since the [Fe2S2](2+) cluster-bound heterodimeric Grx3-Fra2 complex can be formed by intact [Fe2S2](2+) cluster transfer from (Nif)IscA. The significance of these results for Fe-S cluster biogenesis or repair and the cellular regulation of the Fe-S cluster status are discussed

Plastidial glutaredoxins: glutathione-dependent enzymes involved in detoxification, redox signalling and iron-sulfur cluster biogenesis.

International audienceGlutaredoxins (Grxs) are oxidoreductases structurally related to thioredoxins (Trxs). They have two major proposed biochemical roles, the reduction of disulfide bonds and the binding of iron-sulfur (Fe-S) clusters, both of which usually involve glutathione. In photosynthetic organisms, Grxs are distributed into six classes. Several Grxs from classes I and II can indeed exist either as apoforms which display deglutathionylation activity or as holoforms which bind Fe-S clusters. Using biochemical, spectroscopic and structural approaches, we have characterized four plastidial Grxs, showing that three of these can bind an Fe-S cluster. Site-directed mutagenesis experiments and resolution of the crystal structure of class I Grxs (GrxC5 and S12) revealed the critical role of some active site residues for cluster formation and for protein activity. The deglutathionylation activity of these two Grxs proceeds through a monothiol mechanism, which is important for the regeneration of the thiol-peroxidase and methionine sulfoxide reductase families. The two plastidial class II Grxs (GrxS14 and S16) can bind more labile Fe-S clusters that can serve for the maturation of other proteins as demonstrated by in vitro Fe-S cluster transfer experiments and by the complementation of a yeast strain deleted for the mitochondrial Grx5. Using yeast two hybrid and bimolecular fluorescence complementation, we have shown that class II but not class I Grxs interact with plastidial BolA proteins, including SufE1, a sulfurtransferase required for the maturation of plastidial Fe-S proteins.Hence, we propose (i) that, based on its peculiar catalytic and thermodynamic properties, GrxS12 and potentially GrxC5 could act as redox sensors, and (ii) that GrxS14 and GrxS16 could participate to the maturation of iron-sulfur proteins either by being directly involved in Fe-S cluster trafficking or by having regulatory roles in particular via their interaction with BolA proteins

Plastidial glutaredoxins: glutathione-dependent enzymes involved in detoxification, redox signalling and iron-sulfur cluster biogenesis.

International audienceGlutaredoxins (Grxs) are oxidoreductases structurally related to thioredoxins (Trxs). They have two major proposed biochemical roles, the reduction of disulfide bonds and the binding of iron-sulfur (Fe-S) clusters, both of which usually involve glutathione. In photosynthetic organisms, Grxs are distributed into six classes. Several Grxs from classes I and II can indeed exist either as apoforms which display deglutathionylation activity or as holoforms which bind Fe-S clusters. Using biochemical, spectroscopic and structural approaches, we have characterized four plastidial Grxs, showing that three of these can bind an Fe-S cluster. Site-directed mutagenesis experiments and resolution of the crystal structure of class I Grxs (GrxC5 and S12) revealed the critical role of some active site residues for cluster formation and for protein activity. The deglutathionylation activity of these two Grxs proceeds through a monothiol mechanism, which is important for the regeneration of the thiol-peroxidase and methionine sulfoxide reductase families. The two plastidial class II Grxs (GrxS14 and S16) can bind more labile Fe-S clusters that can serve for the maturation of other proteins as demonstrated by in vitro Fe-S cluster transfer experiments and by the complementation of a yeast strain deleted for the mitochondrial Grx5. Using yeast two hybrid and bimolecular fluorescence complementation, we have shown that class II but not class I Grxs interact with plastidial BolA proteins, including SufE1, a sulfurtransferase required for the maturation of plastidial Fe-S proteins.Hence, we propose (i) that, based on its peculiar catalytic and thermodynamic properties, GrxS12 and potentially GrxC5 could act as redox sensors, and (ii) that GrxS14 and GrxS16 could participate to the maturation of iron-sulfur proteins either by being directly involved in Fe-S cluster trafficking or by having regulatory roles in particular via their interaction with BolA proteins

Plastidial glutaredoxins: glutathione-dependent enzymes involved in detoxification, redox signalling and iron-sulfur cluster biogenesis.

International audienceGlutaredoxins (Grxs) are oxidoreductases structurally related to thioredoxins (Trxs). They have two major proposed biochemical roles, the reduction of disulfide bonds and the binding of iron-sulfur (Fe-S) clusters, both of which usually involve glutathione. In photosynthetic organisms, Grxs are distributed into six classes. Several Grxs from classes I and II can indeed exist either as apoforms which display deglutathionylation activity or as holoforms which bind Fe-S clusters. Using biochemical, spectroscopic and structural approaches, we have characterized four plastidial Grxs, showing that three of these can bind an Fe-S cluster. Site-directed mutagenesis experiments and resolution of the crystal structure of class I Grxs (GrxC5 and S12) revealed the critical role of some active site residues for cluster formation and for protein activity. The deglutathionylation activity of these two Grxs proceeds through a monothiol mechanism, which is important for the regeneration of the thiol-peroxidase and methionine sulfoxide reductase families. The two plastidial class II Grxs (GrxS14 and S16) can bind more labile Fe-S clusters that can serve for the maturation of other proteins as demonstrated by in vitro Fe-S cluster transfer experiments and by the complementation of a yeast strain deleted for the mitochondrial Grx5. Using yeast two hybrid and bimolecular fluorescence complementation, we have shown that class II but not class I Grxs interact with plastidial BolA proteins, including SufE1, a sulfurtransferase required for the maturation of plastidial Fe-S proteins.Hence, we propose (i) that, based on its peculiar catalytic and thermodynamic properties, GrxS12 and potentially GrxC5 could act as redox sensors, and (ii) that GrxS14 and GrxS16 could participate to the maturation of iron-sulfur proteins either by being directly involved in Fe-S cluster trafficking or by having regulatory roles in particular via their interaction with BolA proteins

The multiple facets of glutaredoxins: one fold, several partners and functions

International audienceGlutaredoxins (Grxs) are oxidoreductases structurally related to thioredoxins (Trxs). They have two major proposed biochemical roles, the reduction of disulfide bonds and the binding of iron-sulfur (Fe-S) clusters, both of which usually involve glutathione. In photosynthetic organisms, Grxs are distributed into six classes. Several Grxs from classes I and II can indeed exist either as apoforms which display deglutathionylation activity or as holoforms which bind Fe-S clusters. Using biochemical, spectroscopic and structural approaches, we have characterized four plastidial Grxs, showing that three of these can bind an Fe-S cluster. Site-directed mutagenesis experiments and resolution of the crystal structure of class I Grxs (GrxC5 and S12) revealed the critical role of some active site residues for cluster formation and for protein activity. The deglutathionylation activity of these two Grxs proceeds through a monothiol mechanism, which is important for the regeneration of the thiol-peroxidase and methionine sulfoxide reductase families. The two plastidial class II Grxs (GrxS14 and S16) can bind more labile Fe-S clusters that can serve for the maturation of other proteins as demonstrated by in vitro Fe-S cluster transfer experiments and by the complementation of a yeast strain deleted for the mitochondrial Grx5. Using binary yeast two hybrid and bimolecular fluorescence complementation experiments, we have shown that class II but not class I Grxs interact with plastidial BolA proteins, including SufE1, a sulfurtransferase required for the maturation of plastidial Fe-S proteins. Finally, using spectroscopic and structural approaches, we have determined that the Grx-BolA couples form two types of complexes involving distinct regions of both partners. Hence, we propose (i) that, based on its peculiar catalytic and thermodynamic properties, GrxS12 and potentially GrxC5 could rather act as oxidoreductases and/or redox sensors, and (ii) that GrxS14 and GrxS16 could participate to the maturation of iron-sulfur proteins either by being directly involved in Fe-S cluster trafficking or by having regulatory roles in particular via their interaction with BolA proteins

The <i>Escherichia coli</i> BolA Protein IbaG Forms a Histidine-Ligated [2Fe-2S]-Bridged Complex with Grx4

Two ubiquitous protein families have emerged as key players in iron metabolism, the CGFS-type monothiol glutaredoxins (Grxs) and the BolA proteins. Monothiol Grxs and BolA proteins form heterocomplexes that have been implicated in Fe–S cluster assembly and trafficking. The <i>Escherichia coli</i> genome encodes members of both of these proteins families, namely, the monothiol glutaredoxin Grx4 and two BolA family proteins, BolA and IbaG. Previous work has demonstrated that <i>E. coli</i> Grx4 and BolA interact as both apo and [2Fe-2S]-bridged heterodimers that are spectroscopically distinct from [2Fe-2S]-bridged Grx4 homodimers. However, the physical and functional interactions between Grx4 and IbaG are uncharacterized. Here we show that co-expression of Grx4 with IbaG yields a [2Fe-2S]-bridged Grx4–IbaG heterodimer. <i>In vitro</i> interaction studies indicate that IbaG binds the [2Fe-2S] Grx4 homodimer to form apo Grx4–IbaG heterodimer as well as the [2Fe-2S] Grx4–IbaG heterodimer, altering the cluster stability and coordination environment. Additionally, spectroscopic and mutagenesis studies provide evidence that IbaG ligates the Fe–S cluster via the conserved histidine that is present in all BolA proteins and by a second conserved histidine that is present in the H/C loop of two of the four classes of BolA proteins. These results suggest that IbaG may function in Fe–S cluster assembly and trafficking in <i>E. coli</i> as demonstrated for other BolA homologues that interact with monothiol Grxs

The multiple facets of glutaredoxins: one fold, several partners and functions

International audienceGlutaredoxins (Grxs) are oxidoreductases structurally related to thioredoxins (Trxs). They have two major proposed biochemical roles, the reduction of disulfide bonds and the binding of iron-sulfur (Fe-S) clusters, both of which usually involve glutathione. In photosynthetic organisms, Grxs are distributed into six classes. Several Grxs from classes I and II can indeed exist either as apoforms which display deglutathionylation activity or as holoforms which bind Fe-S clusters. Using biochemical, spectroscopic and structural approaches, we have characterized four plastidial Grxs, showing that three of these can bind an Fe-S cluster. Site-directed mutagenesis experiments and resolution of the crystal structure of class I Grxs (GrxC5 and S12) revealed the critical role of some active site residues for cluster formation and for protein activity. The deglutathionylation activity of these two Grxs proceeds through a monothiol mechanism, which is important for the regeneration of the thiol-peroxidase and methionine sulfoxide reductase families. The two plastidial class II Grxs (GrxS14 and S16) can bind more labile Fe-S clusters that can serve for the maturation of other proteins as demonstrated by in vitro Fe-S cluster transfer experiments and by the complementation of a yeast strain deleted for the mitochondrial Grx5. Using binary yeast two hybrid and bimolecular fluorescence complementation experiments, we have shown that class II but not class I Grxs interact with plastidial BolA proteins, including SufE1, a sulfurtransferase required for the maturation of plastidial Fe-S proteins. Finally, using spectroscopic and structural approaches, we have determined that the Grx-BolA couples form two types of complexes involving distinct regions of both partners. Hence, we propose (i) that, based on its peculiar catalytic and thermodynamic properties, GrxS12 and potentially GrxC5 could rather act as oxidoreductases and/or redox sensors, and (ii) that GrxS14 and GrxS16 could participate to the maturation of iron-sulfur proteins either by being directly involved in Fe-S cluster trafficking or by having regulatory roles in particular via their interaction with BolA proteins