Subdivision of the bacterioferritin comigratory protein family of bacterial peroxiredoxins based on catalytic activity.

© American Chemical Society,2010. Post-print version of article deposited in accordance with SHERPA RoMEO guidelinesPeroxiredoxins are ubiquitous proteins that catalyze the reduction of hydroperoxides, thus conferring resistance to oxidative stress. Using high-resolution mass spectrometry, we recently reclassified one such peroxiredoxin, bacterioferritin comigratory protein (BCP) of Escherichia coli, as an atypical 2-Cys peroxiredoxin that functions through the formation of an intramolecular disulfide bond between the active and resolving cysteine. An engineered E. coli BCP, which lacked the resolving cysteine, retained enzyme activity through a novel catalytic pathway. Unlike the active cysteine, the resolving cysteine of BCP peroxiredoxins is not conserved across all members of the family. To clarify the catalytic mechanism of native BCP enzymes that lack the resolving cysteine, we have investigated the BCP homologue of Burkholderia cenocepacia. We demonstrate that the B. cenocepacia BCP (BcBCP) homologue functions through a 1-Cys catalytic pathway. During catalysis, BcBCP can utilize thioredoxin as a reductant for the sulfenic acid intermediate. However, significantly higher peroxidase activity is observed utilizing glutathione as a resolving cysteine and glutaredoxin as a redox partner. Introduction of a resolving cysteine into BcBCP changes the activity from a 1-Cys pathway to an atypical 2-Cys pathway, analogous to the E. coli enzyme. In contrast to the native B. cenocepacia enzyme, thioredoxin is the preferred redox partner for this atypical 2-Cys variant. BCP-deficient B. cenocepacia exhibit a growth-phase-dependent hypersensitivity to oxidative killing. On the basis of sequence alignments, we believe that BcBCP described herein is representative of the major class of bacterial BCP peroxiredoxins. To our knowledge, this is the first detailed characterization of their catalytic activity. These studies support the subdivision of the BCP family of peroxiredoxins into two classes based on their catalytic activity

Characterisation of XvPrx2 : a type II peroxiredoxin isolated from the resurrection plant Xerophyta viscosa (Baker)

Includes bibliographical references.Knowledge of the biochemical and molecular mechanisms by which plants tolerate environmental stresses is necessary for genetic engineering approaches to improve crop performance. A unique feature of resurrection plants, such as Xerophyta viscosa, is their ability to cope with severe water loss of greater than 90%. A full-length cDNA library was synthesised from a cold stressed X viscosa plant. Sequencing and BLAST analysis revealed the identity of sixty genes. A type 2 peroxiredoxin (XvPrx2) was selected for further analyses as it was observed, by northern analyses, to be stress-inducible. The XvPrx2 protein was confirmed to be involved in the stress response by Western analyses. The XvPrx2 gene, which displays highest identity to a rice orthologue, has an open reading frame of 162 amino acids, and codes for a hydrophilic polypeptide of 162 residues with a predicted molecular weight of 17.5 kDa. The XvPrx2 polypeptide displays significant identity with other plant type II Prxs, with an absolutely conserved amino acid sequence proposed to constitute the active site of the enzyme (PGAFTPTCS). The XvPrx2 protein has a single cataly1ic cysteine residue at position 51 similar to Prxs from Oryza sativa and Candida boidinii. A mutated protein (XvV76C) was generated by converting the valine at position 76 to a cysteine resulting in a conformational change as determined by limited proteolysis. An in vitro DNA protection assay showed that, in the presence of either XvPrx2 or XvV76C, DNA protection occurred. In addition, an in vivo assay showed that increased protection was conferred on cell lines over-expressing either XvPrx2 or XvV76C. Several upstream promoter regions were identified for the XvPrx2 gene using the splinkerette method. Southern and two dimensional gel analyses revealed that multiple XvPrx2 homologues exist within the X viscosa genome. These homologues have similar pI values to Arabidopsis orthologues. Immuno-cytochemical data revealed that XvPrx2 is localised to the chloroplast, however, this could be attributed to cross reactivity with a chloroplastic homologue. Using YFP technology, the protein was observed to be expressed in the cytosol, and this location is supported by the absence of an upstream targeting signal in the XvPrx2 sequence. The XvPrx2 activity was maximal with DTT as electron donor and HzOz as substrate with t-BOOH being the next preferred. Using Trx£. coli a 2-15 fold lower enzyme activity was observed. The XvPrx2 activity with GSH was significantly lower and Grx had no measurable effect on this reaction. The XvV76C protein displayed significantly lower activity compared to XvPrx2 for all substrates assessed. Enzymatic kinetic parameter values determined for XvPrx2 using DTT as electron donor and HzOz as substrate were: Km = 45 IlM, V max = 278 Ilmol min-I.mg-I protein, kcat 6.173 x 103 s-1 and kcaJKm = 0.136 X 103 IlM-1.s-l. Based on knowledge-based models of XvPrx2 and XvV76C no structural differences were observed between the two molecules

Expression Analysis of Four Peroxiredoxin Genes from Tamarix hispida in Response to Different Abiotic Stresses and Exogenous Abscisic Acid (ABA)

Peroxiredoxins (Prxs) are a recently discovered family of antioxidant enzymes that catalyze the reduction of peroxides and alkyl peroxides. In this study, four Prx genes (named as ThPrxII, ThPrxIIE, ThPrxIIF, and Th2CysPrx) were cloned from Tamarix hispida. Their expression profiles in response to stimulus of NaCl, NaHCO3, PEG, CdCl2 and abscisic acid (ABA) in roots, stems and leaves of T. hispida were investigated using real-time RT-PCR. The results showed that the four ThPrxs were all expressed in roots, stems and leaves. Furthermore, the transcript levels of ThPrxIIE and ThPrxII were the lowest and the highest, respectively, in all tissue types. All the ThPrx genes were induced by both NaCl and NaHCO3 and reached their highest expression levels at the onset of stress in roots. Under PEG and CdCl2 stress, the expression patterns of these ThPrxs showed temporal and spatial specificity. The expressions of the ThPrxs were all differentially regulated by ABA, indicating that they are all involved in the ABA signaling pathway. These findings reveal a complex regulation of Prxs that is dependent on the type of Prx, tissue, and the signaling molecule. The divergence of the stress-dependent transcriptional regulation of the ThPrx gene family in T. hispida may provide an essential basis for the elucidation of Prx function in future work

Function and Regulation of Chloroplast Peroxiredoxin IIE

Peroxiredoxins (PRX) are thiol peroxidases that are highly conserved throughout all biological kingdoms. Increasing evidence suggests that their high reactivity toward peroxides has a function not only in antioxidant defense but in particular in redox regulation of the cell. Peroxiredoxin IIE (PRX-IIE) is one of three PRX types found in plastids and has previously been linked to pathogen defense and protection from protein nitration. However, its posttranslational regulation and its function in the chloroplast protein network remained to be explored. Using recombinant protein, it was shown that the peroxidatic Cys121 is subjected to multiple posttranslational modifications, namely disulfide formation, S-nitrosation, S-glutathionylation, and hyperoxidation. Slightly oxidized glutathione fostered S-glutathionylation and inhibited activity in vitro. Immobilized recombinant PRX-IIE allowed trapping and subsequent identification of interaction partners by mass spectrometry. Interaction with the 14-3-3 υ protein was confirmed in vitro and was shown to be stimulated under oxidizing conditions. Interactions did not depend on phosphorylation as revealed by testing phospho-mimicry variants of PRX-IIE. Based on these data it is proposed that 14-3-3υ guides PRX‑IIE to certain target proteins, possibly for redox regulation. These findings together with the other identified potential interaction partners of type II PRXs localized to plastids, mitochondria, and cytosol provide a new perspective on the redox regulatory network of the cell

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 Poplar Rust-Induced Secreted Protein (RISP) Inhibits the Growth of the Leaf Rust Pathogen Melampsora larici-populina and Triggers Cell Culture Alkalinisation

Plant cells secrete a wide range of proteins in extracellular spaces in response to pathogen attack. The poplar rust-induced secreted protein (RISP) is a small cationic protein of unknown function that was identified as the most induced gene in poplar leaves during immune responses to the leaf rust pathogen Melampsora larici-populina, an obligate biotrophic parasite. Here, we combined in planta and in vitro molecular biology approaches to tackle the function of RISP. Using a RISP-mCherry fusion transiently expressed in Nicotiana benthamiana leaves, we demonstrated that RISP is secreted into the apoplast. A recombinant RISP specifically binds to M. larici-populina urediniospores and inhibits their germination. It also arrests the growth of the fungus in vitro and on poplar leaves. Interestingly, RISP also triggers poplar cell culture alkalinisation and is cleaved at the C-terminus by a plant-encoded mechanism. Altogether our results indicate that RISP is an antifungal protein that has the ability to trigger cellular responses

Functional Diversification of Fungal Glutathione Transferases from the Ure2p Class

The glutathione-S-transferase (GST) proteins represent an extended family involved in detoxification processes. They are divided into various classes with high diversity in various organisms. The Ure2p class is especially expanded in saprophytic fungi compared to other fungi. This class is subdivided into two subclasses named Ure2pA and Ure2pB, which have rapidly diversified among fungal phyla. We have focused our analysis on Basidiomycetes and used Phanerochaete chrysosporium as a model to correlate the sequence diversity with the functional diversity of these glutathione transferases. The results show that among the nine isoforms found in P. chrysosporium, two belonging to Ure2pA subclass are exclusively expressed at the transcriptional level in presence of polycyclic aromatic compounds. Moreover, we have highlighted differential catalytic activities and substrate specificities between Ure2pA and Ure2pB isoforms. This diversity of sequence and function suggests that fungal Ure2p sequences have evolved rapidly in response to environmental constraints

Analysis of the transcriptional repressor function of Arabidopsis glutaredoxin ROXY19

Glutaredoxins (GRXs) are small ubiquitous proteins that are characterized by a thioredoxin (TRX) fold and a glutathione (GSH) reducible active site, which is a CPYC motif in class I GRXs and a CGFS motif in class II GRXs. Biochemically, GRXs can function as thiol-reductases or as scaffold proteins to coordinate Fe-S clusters. Functionally, they are involved in maintaining the reduced state of proteins in the cell and to regulate signaling processes. Only plants encode a third class of GRXs (called ROXYs) which is characterized by a CCMC/S motif. Loss- and gain-of-function experiments have so far revealed that ROXYs regulate both developmental and stress-responsive processes. ROXYs physically and genetically interact with bZIP transcription factors of the TGA family. It has been a long-held hypothesis that ROXYs modulate the activities of corresponding members of the TGA family through redox modification of their cysteine residues. Ectopically expressed ROXY19 suppresses ethylene/jasmonic acid (ET/JA)-induced defense genes through an unknown mechanism that requires the class II TGA transcription factors (namely TGA2, TGA5 and TGA6). The aim of this study was to investigate whether the transcriptional repressor function of ROXY19 involves redox modifications of TGA transcription factors or other targets and to investigate whether its function as a transcriptional repressor can be confirmed by loss of function evidence. Using the protoplast transient expression assays, we identified that ROXY19 represses expression from its own promoter. The capacity of ROXY19 to repress its own promoter in transiently transformed Arabidopsis protoplasts requires TGA-binding sites in the promoter, TGA factors, the C-terminal ALWL motif and a conserved glycine that is required for glutathione binding. Surprisingly, the conserved active site was not important. Moreover, the single conserved cysteine of class II TGA transcription factors is not important for these proteins to confer activation and ROXY19-repressibility to the promoter. Preliminary data obtained from transient expression assays imply that ROXY19, which interacts with the transcriptional co-repressor TOPLESS (TPL) through the ALWL motif, recruits TPL to repress target gene expression. For reasons yet unknown, the active site is required for the negative effects on endogenous ROXY19 and other target genes when ROXY19 is ectopically expressed in transgenic plants. Loss of function evidence of the ROXY function might be hampered by potential redundant function of the 21 members in Arabidopsis. Since only ROXY19 is induced by JA and since it can represses the JA-induced TGA-dependent CYP81D11 promoter when ectopically expressed, we hypothesized that CYP81D11 transcription should be hyper-induced in the roxy19 mutant. However, CYP81D11 transcript levels were not influenced by JA-induced ROXY19. In order to identify potential target genes of ROXY19, the transcriptomes of wild-type, roxy19 and plants ectopically expressing ROXYs were performed. While these experiments did not unravel any genes that were affected by the roxy19 allele, genes from all three phases of the detoxification system were found to be down-regulated in plants ectopically expressing ROXY19. This result is consistent with the well-known function of class II TGA factors as activators of the detoxification pathway upon chemical stress. A motif based analysis revealed that the TGA-binding sites are the over-represented motifs in the promoters of ROXY19-repressed genes. Decreased expression of detoxification genes leads to higher sensitivity of the tga256 triple mutant and plants ectopically expressing ROXY19 towards the xenobiotic chemical TIBA (2,3,5-Triiodobenzoic). However, loss of function analysis showed that plants with mutations in roxy19 and roxy18 (ROXY18 is a closest homolog of ROXY19) do not gain enhanced tolerance to TIBA stress