The Glutaredoxin Family in Oxygenic Photosynthetic Organisms

Glutaredoxins (GRXs) are small redox proteins of the thioredoxin (TRX) superfamily. Compared to TRXs, much less information on the GRX family is available, especially in photosynthetic organisms since GRXs have been mainly studied in E. coli, yeast and mammal cells. The analysis of the TRX family in oxygenic photosynthetic organisms revealed an unsuspected multiplicity of TRXs but it is not known if the same situation holds for GRXs. Despite the availability of genome sequences from different oxygenic photosynthetic organisms, the number of GRXs and the different groups present in these organisms are still undescribed. This paper presents a comparative analysis of the GRX families present in Arabidopsis, Chlamydomonas and Synechocystis which were found to contain 30, 6 and 3 GRX genes, respectively. The putative subcellular localization of each GRX and its relative expression level, based on EST data, have been investigated. This analysis reveals the presence of three major classes of GRXs, the CPYC type, the CGFS type and a previously undescribed type, called the CC type that appears specific to higher plants. These data are discussed in view of recent results suggesting a complex cross-regulation between the TRX and GRX systems.     

Biochemical characterization of glutaredoxins from Chlamydomonas reinhardtii reveals the unique properties of a chloroplastic CGFS-type glutaredoxin

Glutaredoxins (GRXs) are small ubiquitous disulfide oxidoreductases known to use GSH as electron donor. In photosynthetic organisms, little is known about the biochemical properties of GRXs despite the existence of approximately 30 different isoforms in higher plants. We report here the biochemical characterization of Chlamydomonas GRX1 and GRX3, the major cytosolic and chloroplastic isoforms, respectively. Glutaredoxins are classified on the basis of the amino acid sequence of the active site. GRX1 is a typical CPYC-type GRX, which is reduced by GSH and exhibits disulfide reductase, dehydroascorbate reductase, and deglutathionylation activities. In contrast, GRX3 exhibits unique properties. This chloroplastic CGFS-type GRX is not reduced by GSH and has an atypically low redox potential (-323 +/- 4 mV at pH 7.9). Remarkably, GRX3 can be reduced in the light by photoreduced ferredoxin and ferredoxin-thioredoxin reductase. Both GRXs proved to be very efficient catalysts of A(4)-glyceraldehyde-3-phosphate dehydrogenase deglutathionylation, whereas cytosolic and chloroplastic thioredoxins were inefficient. Glutathionylated A(4)-glyceraldehyde-3-phosphate dehydrogenase is the first physiological substrate identified for a CGFS-type GRX.     

Genome-Wide Survey and Expression Analysis Suggest Diverse Roles of Glutaredoxin Gene Family Members During Development and Response to Various Stimuli in Rice

Glutaredoxins (GRXs) are glutathione-dependent oxidoreductase enzymes involved in a variety of cellular processes. In this study, our analysis revealed the presence of 48 genes encoding GRX proteins in the rice genome. GRX proteins could be classified into four classes, namely CC-, CGFS-, CPYC- and GRL-type, based on phylogenetic analysis. The classification was supported with organization of predicted conserved putative motifs in GRX proteins. We found that expansion of this gene family has occurred largely via whole genome duplication events in a species-specific manner. We explored rice oligonucleotide array data to gain insights into the function of GRX gene family members during various stages of development and in response to environmental stimuli. The comprehensive expression analysis suggested diverse roles of GRX genes during growth and development in rice. Some of the GRX genes were expressed in specific organs/developmental stages only. The expression of many of rice GRX genes was influenced by various phytohormones, abiotic and biotic stress conditions, suggesting an important role of GRX proteins in response to these stimuli. The identification of GRX genes showing differential expression in specific tissues or in response to environmental stimuli provide a new avenue for in-depth characterization of selected genes of importance.     

The integration of glutathione homeostasis and redox signaling

Formation of reactive oxygen species (ROS) is a common feature of abiotic and biotic stress reactions. ROS need to be detoxified to avoid deleterious reactions, but at the same time, the increased formation of ROS can also be exploited for redox signaling. Glutathione, as the most abundant low-molecular weight thiol in the cellular redox system, is used for both detoxification of ROS and transmission of redox signals. Detoxification of H(2)O(2) through the glutathione-ascorbate cycle leads to a transient change in the degree of oxidation of the cellular glutathione pool, and thus a change in the glutathione redox potential. The shift in the glutathione redox potential can be sensed by glutaredoxins (GRXs), small ubiquitous oxidoreductases, which reversibly transfer electrons between the glutathione redox buffer and thiol groups of target proteins. While very little is known about native GRX target proteins and their behavior in vivo, it is shown here that reduction-oxidation-sensitive GFP (roGFP), when expressed in plants, is an artificial target protein of GRXs. The specific interaction of roGFP with GRX results in continuous formation and release of the roGFP disulfide bridge depending on the actual redox potential of the cellular glutathione buffer. Ratiometric analysis of redox-dependent fluorescence allows dynamic imaging of the glutathione redox potential. It was hypothesized that a similar equilibration occurs between the glutathione buffer and native target proteins of GRXs. As a consequence, even minor deviations in the glutathione redox potential due to either depletion of reduced glutathione (GSH) or increasing oxidation can be exploited for fine tuning the activity of target proteins. The integration of the glutathione buffer with redox-active target proteins is a local reaction in specific subcellular compartments. This observation emphasizes the importance of subcellular compartmentalization in understanding the biology of the cellular redox system in plants.     

The thioredoxin superfamily in <Emphasis Type="Italic">Chlamydomonas reinhardtii</Emphasis>

The thioredoxin (TRX) superfamily includes redox proteins such as thioredoxins, glutaredoxins (GRXs) and protein disulfide isomerases (PDI). These proteins share a common structural motif named the thioredoxin fold. They are involved in disulfide oxido-reduction and/or isomerization. The sequencing of the Arabidopsisgenome revealed an unsuspected multiplicity of TRX and GRX genes compared to other organisms. The availability of full Chlamydomonasgenome sequence offers the opportunity to determine whether this multiplicity is specific to higher plant species or common to all photosynthetic eukaryotes. We have previously shown that the multiplicity is more limited in Chlamydomonas for TRX and GRX families. We extend here our analysis to the PDI family. This paper presents a comparative analysis of the TRX, GRX and PDI families present in Arabidopsis,Chlamydomonas and Synechocystis. The putative subcellular localization of each protein and its relative expression level, based on EST data, have been investigated. This analysis provides a large overview of the redox regulatory systems present in Chlamydomonas. The data are discussed in view of recent results suggesting a complex cross-talk between the TRX, GRX and PDI redox regulatory networks.     

A novel human homologue of the SH3BGR gene encodes a small protein similar to Glutaredoxin 1 of Escherichia coli.

Glutaredoxins (GRXs) are ubiquitous GSH-dependent oxidoreductases, which catalyze the reduction of protein-glutathionyl-mixed disulfides and are considered to play an important role in the enzymatic regulation of redox-sensitive proteins. In this paper, we describe the identification and characterization of a new human homologue of the SH3BGR gene, named SH3BGRL3 (SH3 domain binding glutamic acid-rich protein like 3). SH3BGRL3 is widely expressed and codes for a highly conserved small protein, which shows a significant similarity to Glutaredoxin 1 (GRX1) of Escherichia coli and is predicted to belong to the Thioredoxin Superfamily. However, the SH3BGRL3 protein lacks both the conserved cysteine residues, which characterize the enzymatic active site of GRX. This structural feature raises the possibility that SH3BGRL3 could function as an endogenous modulator of GRX biological activity. EGFP-SH3BGRL3 fusion protein expressed in COS-7 cells localizes both to the nucleus and to the cytoplasm. The SH3BGRL3 gene was mapped to chromosome 1p34.3-35.     

Sulfate Assimilation in Basal Land Plants ‐ What Does Genomic Sequencing Tell Us?

Sulfate assimilation is a pathway providing reduced sulfur for the synthesis of cysteine, methionine, co-enzymes such as iron-sulfur centres, thiamine, lipoic acid, or Coenzyme A, and many secondary metabolites, e.g., glucosinolates or alliins. The pathway is relatively well understood in flowering plants, but very little information exists on sulfate assimilation in basal land plants. Since the finding of a putative 3'-phosphoadenosine 5'-phosphosulfate reductase in PHYSCOMITRELLA PATENS, an enigmatic enzyme thought to exist in fungi and some bacteria only, it has been evident that sulfur metabolism in lower plants may substantially differ from seed plant models. The genomic sequencing of two basal plant species, the Bryophyte PHYSCOMITRELLA PATENS, and the Lycophyte SELAGINELLA MOELLENDORFFII, opens up the possibility to search for differences between lower and higher plants at the genomic level. Here we describe the similarities and differences in the organisation of the sulfate assimilation pathway between basal and advanced land plants derived from genome comparisons of these two species with ARABIDOPSIS THALIANA and ORYZA SATIVA, two seed plants with sequenced genomes. We found differences in the number of genes encoding sulfate transporters, adenosine 5'-phosphosulfate reductase, and sulfite reductase between the lower and higher plants. The consequences for regulation of the pathway and evolution of sulfate assimilation in plants are discussed.     

Comparative structural modeling of a monothiol GRX from chickpea: insight in iron-sulfur cluster assembly

Glutaredoxins (GRXs) are small, ubiquitous, multifunctional, heat-stable and glutathione-dependent thiol-disulphide oxidoreductases, classified under thioredoxin-fold superfamily. In the green lineage, GRXs constitute a complex family of proteins. Based on their active site, GRXs are classified into two subfamilies: dithiol and monothiol. Monothiol GRXs contain 'CGFS' as a redox active motif and assist in maintaining redox state and iron homeostasis within the cell. Using RACE strategy, a full length cDNA of chickpea (Cicer arietinum) glutaredoxin 3 (CarGRX3) was cloned and sequenced. The cDNA contains open reading frame of 537 bp encoding 178 amino acids and exhibits features of other known 'CGFS' type GRXs. Based on the multiple sequence alignment among CarGRX3 and monothiol GRXs of other photosynthetic organisms, the characteristic motif (KGX4PXCGFSX([29/30/32])KX4WPTXPQX4GX3GGXDI) with 18 invariant residues was observed. The proposed structure of CarGRX3 was compared with structurally resolved monothiol GRXs of other organisms. The CarGRX3 and nearest Arabidopsis homolog (AtGRXcp) shares 76% sequence identity which was reflected by their 3D-structure conservation. The structure of chickpea monothiol GRX (CarGRX3) coordinates glutathione ligated [2Fe-2S] cluster in a homodimeric form, highlighting the structural basis for iron-sulfur cluster (ISC) assembly and delivery to acceptor proteins. The present study on CarGRX3 model highlighted the utility of the theoretical approaches to understand complex biological phenomena such as glutathione docking and incorporation of GSH-ligated [2Fe-2S] cluster.     

The Arabidopsis TONNEAU2 gene encodes a putative novel protein phosphatase 2A regulatory subunit essential for the control of the cortical cytoskeleton

In Arabidopsis ton2 mutants, abnormalities of the cortical microtubular cytoskeleton, such as disorganization of the interphase microtubule array and lack of the preprophase band before mitosis, markedly affect cell shape and arrangement as well as overall plant morphology. We present the molecular isolation of the TON2 gene, which is highly conserved in higher plants and has a vertebrate homolog of unknown function. It encodes a protein similar in its C-terminal part to B" regulatory subunits of type 2A protein phosphatases (PP2As). We show that the TON2 protein interacts with an Arabidopsis type A subunit of PP2A in the yeast two-hybrid system and thus likely defines a novel subclass of PP2A subunits that are possibly involved in the control of cytoskeletal structures in plants.     

Redox-sensitive GFP in Arabidopsis thaliana is a quantitative biosensor for the redox potential of the cellular glutathione redox buffer

The cellular glutathione redox buffer is assumed to be part of signal transduction pathways transmitting environmental signals during biotic and abiotic stress, and thus is essential for regulation of metabolism and development. Ratiometric redox-sensitive GFP (roGFP) expressed in Arabidopsis thaliana reversibly responds to redox changes induced by incubation with H(2)O(2) or DTT. Kinetic analysis of these redox changes, combined with detailed characterization of roGFP2 in vitro, shows that roGFP2 expressed in the cytosol senses the redox potential of the cellular glutathione buffer via glutaredoxin (GRX) as a mediator of reversible electron flow between glutathione and roGFP2. The sensitivity of roGFP2 toward the glutathione redox potential was tested in vivo through manipulating the glutathione (GSH) content of wild-type plants, through expression of roGFP2 in the cytosol of low-GSH mutants and the endoplasmic reticulum (ER) of wild-type plants, as well as through wounding as an example for stress-induced redox changes. Provided the GSH concentration is known, roGFP2 facilitates the determination of the degree of oxidation of the GSH solution. Assuming sufficient glutathione reductase activity and non-limiting NADPH supply, the observed almost full reduction of roGFP2 in vivo suggests that a 2.5 mm cytosolic glutathione buffer would contain only 25 nm oxidized glutathione disulfide (GSSG). The high sensitivity of roGFP2 toward GSSG via GRX enables the use of roGFP2 for monitoring stress-induced redox changes in vivo in real time. The results with roGFP2 as an artificial GRX target further suggest that redox-triggered changes of biologic processes might be linked directly to the glutathione redox potential via GRX as the mediator.     

The redox switch of gamma-glutamylcysteine ligase via a reversible monomer-dimer transition is a mechanism unique to plants

In plants, the first committed enzyme for glutathione biosynthesis, γ-glutamylcysteine ligase (GCL), is under multiple controls. The recent elucidation of GCL structure from Brassica juncea (BjGCL) has revealed the presence of two intramolecular disulfide bridges (CC1, CC2), which both strongly impact on GCL activity in vitro . Here we demonstrate that cysteines of CC1 are confined to plant species from the Rosids clade, and are absent in other plant families. Conversely, cysteines of CC2 involved in the monomer–dimer transition in BjGCL are not only conserved in the plant kingdom, but are also conserved in the evolutionarily related α- (and some γ-) proteobacterial GCLs. Focusing on the role of CC2 for GCL redox regulation, we have extended our analysis to all available plant (31; including moss and algal) and related proteobacterial GCL (46) protein sequences. Amino acids contributing to the homodimer interface in BjGCL are highly conserved among plant GCLs, but are not conserved in related proteobacterial GCLs. To probe the significance of this distinction, recombinant GCLs from Nicotiana tabacum (NtGCL), Agrobacterium tumefaciens (AtuGCL, α-proteobacteria) and Xanthomonas campestris (XcaGCL, γ-proteobacteria) were analyzed for their redox response. As expected, NtGCL forms a homodimer under oxidizing conditions, and is activated more than threefold. Conversely, proteobacterial GCLs remain monomeric under oxidizing and reducing conditions, and their activities are not inhibited by DTT, despite the presence of CC2. We conclude that although plant GCLs are evolutionarily related to proteobacterial GCLs, redox regulation of their GCLs via CC2-dependent dimerization has been acquired later in evolution, possibly as a consequence of compartmentation in the redox-modulated plastid environment.     

Involvement of Arabidopsis glutaredoxin S14 in the maintenance of chlorophyll content

Plant class‐II glutaredoxins (GRXs) are oxidoreductases carrying a CGFS active site signature and are able to bind iron–sulfur clusters in vitro. In order to explore the physiological functions of the 2 plastidial class‐II isoforms, GRXS14 and GRXS16, we generated knockdown and overexpression Arabidopsis thaliana lines and characterized their phenotypes using physiological and biochemical approaches. Plants deficient in one GRX did not display any growth defect, whereas the growth of plants lacking both was slowed. Plants overexpressing GRXS14 exhibited reduced chlorophyll content in control, high‐light, and high‐salt conditions. However, when exposed to prolonged darkness, plants lacking GRXS14 showed accelerated chlorophyll loss compared to wild‐type and overexpression lines. We observed that the GRXS14 abundance and the proportion of reduced form were modified in wild type upon darkness and high salt. The dark treatment also resulted in decreased abundance of proteins involved in the maturation of iron–sulfur proteins. We propose that the phenotype of GRXS14‐modified lines results from its participation in the control of chlorophyll content in relation with light and osmotic conditions, possibly through a dual action in regulating the redox status of biosynthetic enzymes and contributing to the biogenesis of iron–sulfur clusters, which are essential cofactors in chlorophyll metabolism.     

Diverse functions and molecular properties emerging for CAX cation/H+ exchangers in plants

Steep concentration gradients of many ions are actively maintained, with lower concentrations typically located in the cytosol, and higher concentrations in organelles and outside the cell. The vacuole is an important storage organelle for many ions. The concentration gradient of cations is established across the plant tonoplast, in part, by high-capacity cation/H+ (CAX) exchange activity. While plants may not be green yeast, analysis of CAX regulation and substrate specificity has been greatly aided by utilizing yeast as an experimental tool. The basic CAX biology in ARABIDOPSIS has immediate relevance toward understanding the functional interplay between diverse transport processes. The long-range applied goals are to identify novel transporters and express them in crop plants in order to "mine" nutrients out of the soil and into plants. In doing so, this could boost the levels of essential nutrients in plants.     

Biochemical characterization of glutaredoxins from Chlamydomonas reinhardtii: Kinetics and specificity in deglutathionylation reactions

Protein deglutathionylation is mainly catalyzed by glutaredoxins (GRXs). We have analyzed the biochemical properties of four of the six different GRXs of Chlamydomonas reinhardtii. Kinetic parameters were determined for disulfide and dehydroascorbate reduction but also for deglutathionylation of artificial and protein substrates. The results indicate that GRXs exhibit striking differences in their catalytic properties, mainly linked to the class of GRX considered but also to the pK_a of the N-terminal catalytic cysteine. Furthermore, glutathionylated proteins were found to exhibit distinct reactivities with GRXs. These results suggest that glutathionylation may allow a fine tuning of cell metabolism under stress conditions.

Structured summary

MINT-7761120: GRX6 (uniprotkb:A8HN52) and GRX6 (uniprotkb:A8HN52) bind (MI:0408) by comigration in non denaturing gel electrophoresis (MI:0404)MINT-7761098:GRX5 (uniprotkb:A8I7Q4) and GRX5 (uniprotkb:A8I7Q4) bind (MI:0408) by comigration in non denaturing gel electrophoresis (MI:0404)     

Plant-specific regulation of replication protein A2 (OsRPA2) from rice during the cell cycle and in response to ultraviolet light exposure

DNA replication is a process that is highly conserved among eukaryotes. Nonetheless, little is known about the proteins involved in it in plants. Replication protein A (RPA) is a heterotrimeric, single-stranded DNA-binding protein with several functions in DNA metabolism in humans and yeast and supposedly also in plants. Here we report on the regulation of OsRPA2, the 32-kDa subunit of RPA from rice ( Oryza sativa L.). We found conserved regulation mechanisms at the level of gene expression between animal and plant RPA2 genes and distinct features of OsRPA2 regulation at the level of protein expression. Unlike in animals or in yeast, protein abundance in rice was regulated in a cell cycle phase-specific manner and was altered after UV-C light exposure. On the other hand, posttranslational modification through phosphorylation did not appear to play a pivotal role in rice as it does in animal cells. Our results indicate that plant-specific mechanisms of regulation have evolved for RPA2 within the generally well-conserved process of DNA replication, suggesting specific requirements for regulation of DNA metabolism in plants as compared to other eukaryotes.