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First published online May 27, 2005; 10.1104/pp.105.062430 Plant Physiology 138:909-922 (2005) © 2005 American Society of Plant Biologists
The Arabidopsis Plastidic Methionine Sulfoxide Reductase B Proteins. Sequence and Activity Characteristics, Comparison of the Expression with Plastidic Methionine Sulfoxide Reductase A, and Induction by Photooxidative StressCommissariat à l'Energie Atomique/Cadarache, Direction des Sciences du Vivant, Département d'Ecophysiologie Végétale et de Microbiologie, Laboratoire d'Ecophysiologie de la Photosynthèse, 13108 Saint-Paul-lez-Durance cedex, France (C.V.D.S., S.C., P.R.); and IFR110, Unité Mixte de Recherche 1136, Interaction Arbres Microorganismes, Institut National de la Recherche Agronomique, Université Nancy I Henri Poincaré, 54506 Vandoeuvre cedex, France (N.R.)
Two types of methionine (Met) sulfoxide reductases (Msr) catalyze the reduction of Met sulfoxide (MetSO) back to Met. MsrA, well characterized in plants, exhibits an activity restricted to the Met-S-SO-enantiomer. Recently, a new type of Msr enzyme, called MsrB, has been identified in various organisms and shown to catalytically reduce the R-enantiomer of MetSO. In plants, very little information is available about MsrB and we focused our attention on Arabidopsis (Arabidopsis thaliana) MsrB proteins. Searching Arabidopsis genome databases, we have identified nine open reading frames encoding proteins closely related to MsrB proteins from bacteria and animal cells. We then analyzed the activity and abundance of the two chloroplastic MsrB proteins, MsrB1 and MsrB2. Both enzymes exhibit an absolute R-stereospecificity for MetSO and a higher catalytic efficiency when using protein-bound MetSO as a substrate than when using free MetSO. Interestingly, we observed that MsrB2 is reduced by thioredoxin, whereas MsrB1 is not. This feature of MsrB1 could result from the lack of the catalytical cysteine (Cys) corresponding to Cys-63 in Escherichia coli MsrB that is involved in the regeneration of Cys-117 through the formation of an intramolecular disulfide bridge followed by thioredoxin reduction. We investigated the abundance of plastidial MsrA and B in response to abiotic (water stress, photooxidative treatment) and biotic (rust fungus) stresses and we observed that MsrA and B protein levels increase in response to the photooxidative treatment. The possible role of plastidic MsrB in the tolerance to oxidative damage is discussed.
Oxygen is essential to all aerobic organisms but can also lead to many harmful effects (Davies, 1995  ). Proteins are easily damaged by reactive oxygen species, with Met being one of the amino acid residues most susceptible to oxidation (Dann and Pell, 1989). The generation of Met sulfoxide (MetSO) is mediated by various biological oxidants such as hydrogen peroxide, hydroxyl radicals, ozone as well as by metals, and results in modifications of activity and conformation for many proteins (Gao et al., 1998; Davis et al., 2000). Oxidation of Met residues is readily reversed by the action of an enzyme initially referred as peptide MetSO reductase (PMSR), which catalyzes the thioredoxin-dependent reduction of MetSO back to Met (Brot et al., 1981). The enzyme is present in most living organisms and has been described as belonging to the minimal set of proteins sufficient for cell life (Mushegian and Koonin, 1996). PMSR has a protective role against oxidative damage (Moskovitz et al., 1997). Indeed, pmsr null mutants of Escherichia coli and Saccharomyces cerevisiae show a decreased resistance toward oxidative stress conditions (Moskovitz et al., 1995, 1997). Accordingly, PMSR overexpression in S. cerevisiae or in human T-cells results in an increased resistance to oxidative treatments (Moskovitz et al., 1998). The first PMSR has been renamed Met sulfoxide reductase A (MsrA) and has been shown to be specific to the Met-S-SO-enantiomer (Sharov et al., 1999). Note that another enzyme, biotin sulfoxide reductase BisC from E. coli, has been very recently reported to reduce free Met-S-SO (Ezraty et al., 2005). In the last years, a new type of Msr enzyme, termed MsrB, has been identified and shown to catalytically reduce the R-enantiomer of MetSO (Grimaud et al., 2001; Kryukov et al., 2002; Kumar et al., 2002; Olry et al., 2002). Both Msr activities are essential for organisms, since Met oxidation results in a racemic mixture of R- and S-enantiomers. It is noteworthy that MsrB proteins do not display any sequence or structural homology with MsrA. In Neisseria gonorrhoeae, the protein PILB is composed of three subdomains, a domain with thioredoxin-like activity in the N terminus, a domain displaying MsrA activity, and the last one strikingly similar to human SelX, a selenoprotein that exhibits MsrB activity (Olry et al., 2002; Wu et al., 2005). Selenoproteins contain the rare amino acid selenocysteine instead of Cys. This new type of Msr activity has also been reported for SelX homologs in E. coli (Grimaud et al., 2001), Staphylococcus aureus (Singh et al., 2001), and mouse (Moskovitz et al., 2002).
With regard to the plant kingdom, Sanchez et al. (1983)
Until now, very few studies concerning plant MsrB proteins have been reported. Three genes showing strong similarity with SelX selenoproteins have been described in Arabidopsis (Rodrigo et al., 2002 In this work, we describe the characteristics of the MsrB family in Arabidopsis that appears even more complex than the MsrA family. We cloned the two cDNAs encoding the predicted plastidic MsrB proteins, named MsrB1 and MsrB2. The catalytic activity of recombinant proteins has been studied using free or protein-bound MetSO substrates and dithioerythritol (DTE) or Trx as electron donors. We then investigated the abundance of the two plastidic MsrB proteins, in comparison with that of pMsrA, in the different organs of Arabidopsis plants. We also checked protein level during abiotic stresses in Arabidopsis leaves subjected to water deficit and photooxidative treatments or during a biotic stress, in poplar (Populus x interamericana) leaves infected by the rust fungus Melampsora larici-populina.
The MsrB Gene Family in Arabidopsis Searching the Arabidopsis genome sequence databases (The Arabidopsis Information Resource, Munich Information Center for Protein Sequences), we identified nine open reading frames encoding proteins closely related to the MsrB proteins from Drosophila melanogaster, Mus musculus, or S. cerevisiae. All genes are located in chromosome IV except At1g53670. Accession numbers and location in each chromosome are shown in Table I. Noteworthy, MsrB genes in chromosome IV are grouped in two clusters, the first comprising At4g04800, At4g04810, At4g04830, and At4g04840 and the second At4g21830, At4g21840, At4g21850, and At4g21860. To gain insight into functionality of the genes, the expressed sequence tag (EST) database at the National Center for Biotechnology Information (NCBI) site was searched and cDNA were detected for all of them. Only one EST was found for At4g04810 and At4g21840, whereas At4g21850 and At4g21860 seem to be highly expressed with 22 and 24 ESTs, respectively. These data indicate that the nine MsrB genes are expressed and that they display dramatic differences in expression. The genes were named MsrB1-MsrB9 according to their predicted subcellular location (chloroplast, secretory pathway, and cytosol) and also according to the order in which they are located in each chromosome.
A detailed alignment of the proteins encoded by Arabidopsis MsrB genes is shown in Figure 1. The proteins display different sizes, ranging from 139 to 202 amino acids. Multiple alignment of MsrB sequences revealed that all members have four conserved Cys residues, which are organized in two CxxC motifs and could potentially be involved in zinc fixation as proposed for Drosophila MsrB (Kumar et al., 2002 ). MsrB protein sequences also contain one strictly conserved Cys residue (Cys-117 in E. coli). A second Cys (Cys-63 in E. coli) is present in eight of them, MsrB1 possessing a Thr residue instead of this Cys. Moreover, MsrB1 also exhibits a peculiar feature with another Cys located in position 47, between the two Cys potentially involved in zinc fixation. According to prediction software (TargetP and Predotar), MsrB3 is predicted to be addressed to a secretory pathway. MsrB1 and MsrB2, which have N-terminal extensions of 65 and 68 residues, respectively, are predicted to be addressed to the chloroplast. As shown in Figure 1, MsrB proteins from Arabidopsis are highly conserved. MsrB4, MsrB5, and MsrB6, assumed to be cytosolic enzymes, display 87% to 97% identity. These three MsrB share about 70% to 80% identity with MsrB2 without the predicted N-terminal extension, but only 40% with predicted mature MsrB1. Thus, the sequence of MsrB1 appears as the most divergent in comparison with the eight others. For example, it exhibits an extension of nine amino acids in the N-terminal region. Thereafter, we focused our studies on the two predicted plastidic MsrB with regard to their activity and expression characteristics.
Production and Purification of MsrB1 and MsrB2 Recombinant Proteins We investigated the biological activities of Arabidopsis MsrB1 and B2 proteins by producing recombinant proteins in E. coli. Both MsrB proteins were expressed as mature proteins without the transit peptide predicted by the ChloroP software and with an N-terminal poly-His tag to allow purification using affinity chromatography as shown in Figure 2A. Fractions collected during the purification steps were analyzed using SDS-PAGE. Recombinant MsrB1 and MsrB2 exhibited apparent molecular masses of approximate 15 to 16 kD. Note that MsrB2 was visualized as two distinct bands using Coomassie Blue and western analyses. In order to test whether the two forms correspond to different redox states or to degradation products, we carried out incubation experiments of the MsrB2 protein in the presence of reducing reagents (Fig. 2B), followed by SDS-PAGE and revelation by Coomassie Blue or western analysis. Without any reagent, MsrB2 was visualized as two bands, the most abundant form being the one with the higher apparent molecular mass (lane 1). When MsrB2 was incubated with reducing reagents (DTE or dithiothreitol [DTT]), the ratio between the two forms was modified with the most abundant form corresponding to the band with the lower apparent molecular mass (lanes 2 and 4). If urea, a denaturing reagent, was added to the MsrB2 protein, no change was noted when compared to the untreated protein (lane 3). We conclude, from these experiments, that the two bands correspond to two redox states of MsrB2, the one with the apparent lower molecular mass corresponding to a reduced form. During purification of recombinant MsrB2, we also noticed that the protein has the ability to form dimers in the absence of reducing reagent (Fig. 2C). This feature of MsrB2 was enhanced by adding diamide that favors the formation of disulfide bridges. These results indicate that MsrB2 forms homodimers in vitro through disulfide bridges.
Activity of Recombinant Arabidopsis MsrB1 and MsrB2 To compare the efficiencies of the two MsrB, a steady-state kinetic analysis was performed using an HPLC method, dabsyl-MetSO, a protein-bound-like MetSO substrate, and DTE as a reductant. In our assay conditions, MsrB1 and MsrB2 exhibited Michaelis-Menten kinetics (data not shown). Km values for the substrate were close since they ranged from 55 µM for MsrB2 to 80 µM for MsrB1 (Table II). Turnover numbers (kcat) were 0.07 s–1 and 0.02 s–1 for MsrB1 and MsrB2, respectively. These results indicate that MsrB1 has a kcat and a catalytic efficiency (kcat/Km) 2.5- to 3-fold greater than that of MsrB2, using protein-bound MetSO. Altogether, these data show that both MsrB exhibit Msr activities, with MsrB1 being more efficient than MsrB2.
Then, we investigated the stereospecificity of the two MsrB proteins, using HPLC and the dabsyl-MetSO substrate, as shown in Figure 3. In the absence of Msr, MetSO was separated into two pools corresponding to the R and S forms (Fig. 3A). The Met-R-SO form was always found to be slightly more abundant than the S form. The proportion of reduced Met, before the addition of Msr, was about 2%. As a control, we assayed the activity of the recombinant poplar pMsrA. The chromatogram shows a noticeable decrease of the Met-S-SO form together with a strong increase of the peak corresponding to Met, whereas no change in the Met-R-SO amount was noticed (Fig. 3B). These data confirm the specific pMsrA activity toward Met-S-SO. When similar experiments were performed with MsrB1 (Fig. 3C) and MsrB2 (Fig. 3D), we observed that the peaks corresponding to Met-R-SO decreased, whereas the Met-S-SO amount did not vary. Using equimolar amounts of the two catalysts, the decrease in peak height was substantially more pronounced when assaying MsrB1 activity. These data are fully consistent with MsrB1 having a 2.5-fold higher catalytic efficiency than MsrB2 (Table II) using dabsyl-MetSO as a substrate. From these results, we conclude that both MsrB proteins exhibit an absolute R-stereospecificity for MetSO.
Finally, the nature of the physiological reductant of MsrB was tested using Trx as an electron donor instead of DTE. The Msr activity was assayed by following spectrophotometrically the oxidation of NADPH at 340 nm in the presence of free MetSO or N-acetyl-MetSO as substrates, and a Trx system constituted of various poplar cytosolic Trx (either Trx h1, or h3, or h5; Gelhaye et al., 2004 ) in combination with the Arabidopsis NADPH-linked Trx reductase. MsrB1 was not able to reduce free MetSO or N-acetyl-MetSO in the presence of the Trx reducing system whatever the Trx isoforms and the concentrations used (data not shown). On the contrary, we observed that the MsrB2 protein can be reduced by all Trx h tested, with a Km value around 8 µM for Trx h1 (Table III; data not shown). MsrB2 displayed dramatic differences depending on the substrate used, since the Km values for sulfoxides ranged from 2 mM with N-acetyl-MetSO to 30 mM with free MetSO, reflecting the much lower ability of MsrB2 to reduce free MetSO. The kcat values found with MsrB2 were 1.37 and 2.94 s–1 with free MetSO and N-acetyl-MetSO, respectively. Based on these kinetic parameters, we conclude that MsrB2 preferentially reduces protein-bound substrates like N-acetyl-MetSO with a catalytic efficiency (kcat/Km) 30-fold higher compared to that observed with free MetSO. All these results indicate that MsrB1 and MsrB2 exhibit Msr activities with different kinetic parameters according to the type of substrate and use specific electron donors.
Western Analysis of pMsrA, MsrB1, and MsrB2 in Leaf Proteins and Localization in Chloroplast
Using a serum raised against a synthetic peptide corresponding to a part of MsrB1 (from residue 89 to residue 103), two main bands, with apparent molecular masses of around 15 and 17 kD (Fig. 4B, lane 2), were revealed in leaf soluble proteins. Both proteins were not revealed when using the preimmune serum (data not shown). We hypothesized that the two proteins could correspond to MsrB1 and MsrB2 proteins since the MsrB1 sequence part selected for raising the serum displays 73% amino acid identity with the corresponding MsrB2 sequence. Both recombinant proteins were recognized by the serum, which nevertheless appeared more specific for MsrB1 (data not shown). To determine precisely the identity of the proteins recognized by the serum in plants, we characterized Arabidopsis knockout mutants for MsrB1 and MsrB2 genes. The MsrB1 mutant, corresponding to a transgenic T-DNA insertion plant, was obtained from Max Planck Institute (Germany) and termed GABI-Kat line 540H01 (Rosso et al., 2003
We then investigated the subcellular localization of the MsrB1 and MsrB2 proteins. Arabidopsis leaf chloroplasts were purified on Percoll gradients and immunoblotting experiments were carried out on leaf and chloroplastic soluble proteins using the serum recognizing both MsrB1 and MsrB2 proteins (Fig. 5). We first checked the purity of the chloroplast preparation using a serum raised against the cytosolic type-IIB peroxiredoxin (Bréhelin et al., 2003 ). The protein was revealed at a high level in leaves, but was not detected in chloroplastic proteins, showing the absence of cytosolic contamination in purified chloroplasts. With regard to MsrB1 and MsrB2, western data exhibited a higher abundance for both proteins in chloroplast samples. This result is consistent with the predictions obtained using TargetP and Predator software. Note also that the potato MsrB1 protein was isolated from purified potato chloroplasts, as a potential target of the CDSP32 Trx (Rey et al., 2005). We conclude from these data that MsrB1 and MsrB2 are located in the chloroplast.
Using a serum raised against the recombinant poplar plastidic MsrA (pMsrA) protein, two bands at around 25 kD were revealed in leaves and in chloroplasts from Arabidopsis, but only the highest one was found to be more abundant in the plastidic fraction. We then investigated whether the redox state could modify the pMsrA migration properties by running SDS-PAGE gel without DTT and western analysis (Fig. 6). We observed that under nonreducing conditions, the serum mainly reveals the lower form of pMsrA in plastidic Arabidopsis proteins, whereas the higher form was more abundant following a DTT treatment. Interestingly, a similar migration shift was noticed for the recombinant poplar pMsrA protein, when migration was carried out with or without DTT. Consequently, we propose that the two pMsrA forms revealed in plastidic samples correspond to two redox forms, the reduced form migrating with a higher apparent molecular mass.
Abundance of Plastidic Msr Proteins in Arabidopsis Organs The abundance of MsrB1 and MsrB2 proteins was investigated in various plant tissues from Arabidopsis by western analysis and compared to that of pMsrA (Fig. 7). In most organs, except mature and old leaves, MsrB2 was found to be more abundant than MsrB1. The highest MsrB2 protein levels were detected in developing organs such as young leaves and floral buds, and noticeable amounts were also observed in stems and in flowers. MsrB1 exhibits a pattern of expression close to that of MsrB2 with higher protein amounts in young leaves and in floral buds. It is noteworthy that the abundance of both MsrB proteins decreases with leaf age. MsrB proteins were much less abundant in siliques and in roots and were not detected in seeds. pMsrA showed two different patterns depending on which form was observed. The reduced form with the higher apparent molecular mass was found, as for MsrB proteins, to be the most abundant in young developing leaves and in floral buds. This form was revealed at a very low level in roots and in stems and was undetected in flowers, siliques, and seeds. The lower pMsrA form was present at a substantial level in most organs, but was revealed to a much lesser extent in siliques and in seeds.
Abundance of Plastidic Msr Proteins under Stress Conditions We then analyzed the abundance of the plastidic MsrA and B proteins under various stress conditions. First, we subjected Arabidopsis plants to water deficit. After 6 d, plants displayed severe wilting symptoms, which mainly concerned mature leaves (data not shown). No noticeable change was noticed in MsrB1 and MsrB2 amounts in young and mature leaves under water stress (Fig. 8A). With regard to the plastidic MsrA protein, the reduced form appeared to be less abundant in young and in mature leaves of water-stressed plants compared to controls. The abundance of the oxidized form decreased in young leaves, but substantially increased in mature leaves upon water deficit.
Arabidopsis plants were then subjected to photooxidative stress by exposure to high light (1,400 µE m–2 s–1) and low temperature (8°C) for 8 d. After 3 d, mature and old leaves exhibited symptoms as bleaching and necrosis and were more damaged than young leaves (data not shown). The treatment also resulted in an anthocyanin accumulation occurring earlier in young leaves than in mature leaves. In young leaves, a slight decrease in MsrB2 level was observed during the treatment, whereas the MsrB1 amount was not noticeably modified (Fig. 8B). In mature leaves, a substantial increase in MsrB1 abundance occurred from the first day of treatment and the protein amount was much higher during the whole stress period than in control conditions. Compared to MsrB1, the MsrB2 level was found to increase later and to a lesser extent in response to the photooxidative treatment. An increase in the level of the pMsrA reduced form was observed during the first 3 d of treatment in young leaves. Then, the reduced form became much less abundant compared to the oxidized form. In mature leaves, an increase in the amount of the reduced form was observed from the third day of the stress period and a decrease was noticed thereafter. The pMsrA level is close in young and mature leaves after 8 d, with a much higher abundance of the oxidized form in both leaves. Note that this form was found to accumulate with some delay in mature leaves compared to young ones. We also followed Msr protein amount in poplar leaves infected by the rust fungus M. larici-populina, in the case of two different reactions, either compatible, i.e. the fungus is able to invade the plant cells, or incompatible, i.e. the fungus is killed after the plant generates reactive oxygen species, a process known as oxidative burst. As observed previously, the pMsrA was present under two forms, the reduced form being predominant (Fig. 9). The level of pMsrA increased slightly with time (after 1 h of infection) in the case of the incompatible reaction, whereas it is decreased during the compatible reaction with a minimum after 8 h of infection (Fig. 9, A and B). As in Arabidopsis, the anti-MsrB1 antibody was found to react with two isoforms of MsrB in poplar leaf proteins, corresponding in size to AtMsrB1 and AtMsrB2. Accordingly, two ESTs very similar to AtMsrB1 and AtMsrB2 have been found from Populus trichocarpa sequence genome databases. MsrB1 was hardly detected (Fig. 9). This may be due to a weak expression of the corresponding gene or to low cross reaction with the serum raised against the Arabidopsis protein. The MsrB1 amount seems to be unchanged except in the compatible reaction, where the level increased 10 d after infection (Fig. 9B). Conversely, the poplar MsrB2 was well recognized by the serum and the abundance of the protein decreased strongly after several hours of infection in both reactions (Fig. 9, A and B).
This paper provides the first report on the activity and expression characteristics of two plant MsrB that reduce the R enantiomer of MetSO. These proteins belong to a complex multigenic family composed of nine members in Arabidopsis. Plants exhibit the largest number of Msr genes compared to bacteria and animal cells (Kryukov et al., 2002 ). Searching nucleotide sequence databases revealed that several eukaryotes, such as D. melanogaster, Caenorhabditis elegans, and S. cerevisiae, possess only one MsrA and one MsrB gene (Kryukov et al., 2002). In Arabidopsis, the MsrB family is more complex than the MsrA one, which is composed of five members. This complexity suggests that plant MsrB proteins exhibit specific expression or activity characteristics that could be required for a range of distinct physiological functions. This is illustrated by the fact that PMSR2, an Arabidopsis MsrA, was found to protect plants from oxidative damage especially during long dark periods (Bechtold et al., 2004).
In this work, we focused our attention on the two MsrB members that were predicted to be addressed to the chloroplast and whose localization has been confirmed by western analysis. Experiments carried out on Arabidopsis wild-type and knockout mutant plants indicate that MsrB2 and MsrB1 proteins exhibit 15- and 17-kD apparent molecular masses, respectively. These migration characteristics likely result from amino acid sequence differences, since an alignment of the two MsrB sequences shows a nine-residue extension in MsrB1. Moreover, we cannot exclude that the MsrB1 target signal could have a shorter length than the one predicted by the ChloroP software. It is noteworthy that MsrB1 does not present distinct redox states compared to MsrB2, which is detected under two forms. This major difference could be related to the lack in MsrB1 of the Cys-132, corresponding to Cys-63 in the E. coli protein, which could result in an incapacity to form an intramolecular disulfide bridge between Cys-132 and Cys-185. Interestingly, we observed that the pMsrA protein also exhibits two redox states. Previously, Sadanandom et al. (2000)
The finding that AtMsrB1 and AtMsrB2 proteins have Met-R-sulfoxide reductase activity was consistent with functional predictions based on sequence homologies. MsrB2 exhibits a higher catalytic efficiency with protein-bound MetSO than with free MetSO, as reported for PILB-MsrB from Neisseria meningitidis (Olry et al., 2002
Although MsrB1 and MsrB2 exhibit different catalytic properties, they display relatively similar expression patterns, since their abundance is much higher in developing tissues. In leaves, MsrB1 and MsrB2 show a decrease in abundance with ageing, as reported during senescence in human fibroblasts WI-38 (Petropoulos and Friguet, 2005
When Arabidopsis plants were exposed to photooxidative stress, an increase in plastidial MsrB abundance was observed in mature leaves. Previously, the Arabidopsis AtSXL3 transcript, corresponding to MsrB9 in our study, has been reported to accumulate in seedlings subjected to dehydration and to oxidative stress generated in vitro by H2O2 treatment (Rodrigo et al., 2002
In poplar plants infected by two races of the rust fungus M. larici-populina, we observed that pMsrA and MsrB display different patterns of expression during compatible or incompatible reactions. In the case of the incompatible interaction, pMsrA and MsrB1 levels do not significantly change, whereas the MsrB2 amount decreases markedly after 24 h. In the compatible reaction, pMsrA and MsrB2 abundances substantially decrease after 8 h. Note that the poplar peroxiredoxin Q, which protects cells from oxidative damage by detoxifying peroxides, exhibits an expression pattern almost similar to that of pMsrA during infection by the rust fungus (Rouhier et al., 2004
Our results, showing that both plastidic MsrB levels are higher in response to photooxidative stress, lead us to propose that the two proteins participate in the protection of chloroplasts against oxidative damage. These organelles need an efficient antioxidant machinery since they are the site of the photosynthetic process that can generate reactive oxygen species. In various cultivated plant species (cotton, pea, wheat, and potato) subjected to high temperature and water-deficit stress effects, protein MetSO contents have been investigated and no change was observed in leaves (Fergusson and Burke, 1994
Plant Material
Arabidopsis (Arabidopsis thaliana) ecotype Columbia plants were grown in a growth chamber with an 8-h photoperiod, a photon flux density of 250 µE m–2 s–1, a temperature regime of 22°C/18°C (day/night), and a relative humidity of 55%. Water deficit was applied on 6-week-old plants by withholding watering for about 6 d. Photooxidative treatment was carried out by exposing 6-week-old plants to a high light intensity (1,400 µE m–2 s–1) at 8°C for 8 d. The infection of the beaupré cultivar of poplar (Populus x interamericana) by two races of Melampsora larici-populina and the protocol of protein extraction were described in Rouhier et al. (2004)
Arabidopsis knockout mutants for MsrB1 and MsrB2 genes were characterized as follows. The MsrB1 knockout mutant, corresponding to a transgenic T-DNA insertion plant, was obtained from Max Planck Institute (Germany) and termed GABI-Kat line 540H01 (Rosso et al., 2003
A fragment containing AtMsrB1 coding region was synthesized by PCR using the clone RAFL16-88-B20 (AK117314), provided by RIKEN Genomic Sciences Center (Seki et al., 1998 AtMsrB2 was cloned using a reverse transcription-PCR strategy. Leaves of Arabidopsis plants were excised and frozen immediately in liquid nitrogen and stored at –80°C. RNA was extracted using TRIzol reagent (Invitrogen, Cergy-Pontoise, France) according to the manufacturer's instructions. A total of 1 µg of RNA was used for cDNA synthesis using a poly(A+) specific primer. AtMsrB2 specific primers (5'-CGCGGATCCGCTCCTGAATCG-3' and 5'-CCCAAGCTTCAGGG TCGGATT-3') were used to amplify by PCR the coding sequence corresponding to the MsrB2 mature protein.
Recombinant MsrB1 and MsrB2 proteins, containing an N-terminal 6xHis-tag, were produced in Escherichia coli. The MsrB1 coding region without its N-terminal targeting sequence was ligated into the EcoRI and PstI restriction sites of the expression vector pSD80 (Patel and Dunn, 1995
The nucleotidic sequence encoding the mature pMsrA form (GenBank accession no. AAS46232) was cloned by PCR into the expression plasmid pET-3d using a leaf cDNA library of Populus tremula x tremuloides as a template and the two following primers: 5'-CCCCCCATGGCTAACATCCTTAGCAAACTAGGC-3' and 5'-CCCCGGATCCTTAGCCATAGCATCGGATTGGATC-3' (cloning sites underlined). In addition, a codon for Ala (in bold) was inserted downstream the Met closest to the putative cleavage site and the corresponding N-terminal amino acid sequence was thus MANIL. The recombinant plasmid was used to transform the BL21(DE3) E. coli strain, which also contains the helper plasmid pSBET (Schenk et al., 1995
Dabsyl-MetSO was prepared by incubating 50 mM Dabsyl-Met (Interchim, Montluçon, France) with 500 mM H2O2 overnight at room temperature. In these conditions, around 95% dabsyl-Met was oxidized to dabsyl-MetSO. After centrifugation at 3,250g for 10 min at room temperature, the supernatant was loaded on a C18 column (Sep-Pak C18 cartridges, Millipore) and dabsyl-MetSO was eluted with 5 mL acetonitrile. After evaporation of the solution under vacuum, the powder was dissolved in dimethyl sulfoxide. The actual concentration of dabsyl-MetSO was assayed by HPLC.
N-acetyl-MetSO was obtained by acetylation of free MetSO (Sigma, St. Louis) by anhydride acetic (Sanchez et al., 1983
MsrB activity in the presence of Trx was measured by following NADPH oxidation at 340 nm. A 500-µL cuvette was constituted of 30 mM Tris-HCl, pH 8.0, 1 mM EDTA, 200 µM NADPH, 1.3 µM Arabidopsis NADPH Trx reductase, saturating concentrations of poplar Trx h1 (42.5 µM) and free MetSO (100 mM) or N-acetyl-MetSO (20 mM) and 0.56 µM of MsrB2 or 1 to 10 µM MsrB1. The reaction was carried out at 30°C with a Cary 50 spectrophotometer (Varian, Palo Alto, CA). The catalytic parameters for Trx h1, free MetSO, or N-acetyl-MetSO were determined at saturating concentrations of the other enzyme substrate. The activity of MsrB recombinant proteins was also determined by monitoring the reduction of the synthetic substrate, dabsyl-MetSO, in the presence of DTE. The reaction mixture, containing purified proteins MsrB1 and MsrB2 in 15 mM HEPES, pH 8, 10 mM MgCl2, 30 mM KCl, 20 mM DTE, 0.5 mM dabsyl-MetSO in a final volume of 100 µL was incubated for 1 h at 37°C. The reaction was stopped by adding 450 µL of ethanol:acetate buffer 29 mM, pH 4.16 (50:50, v/v) to 50 µL of the mixture. After centrifugation at 12,000g for 30 min at 4°C, 20 µL of supernatant were loaded on a C18 reverse phase column.
The method was modified from that of Minetti et al. (1994) The program used for routine analysis of enzymatic reaction mixtures, called program 1, starts with 20% solvent B, up to 66.7% solvent B in 10 min, up to 100% solvent B in 0.2 min, 100% B for 3.3 min, then back to 20% B in 0.2 min, equilibration at 20% solvent B for 8.3 min. The solvent A is replaced with solvent B to reached 100%. The whole program lasts 22 min. In these conditions, dabsyl-MetSO is eluted at 9.7 min and dabsyl-Met at 12.1 min. The program 2 is used for discriminating dabsyl-MetSO diastereomers. It starts with 20% solvent B, up to 48% solvent B in 20 min, up to 100% solvent B in 1 min, at 100% B for 7 min, down to 20% B in 2.5 min, equilibration at 20% solvent B for 9.5 min. The whole program lasts 41 min. In these conditions, dabsyl-Met-S-SO, dabsyl-Met-R-SO, and dabsyl-Met elute at 17.1 min, 17.6 min, and 25.1 min, respectively.
Crude chloroplasts were obtained from 5 to 7 g Arabidopsis leaves blended in 50 mL extraction buffer (50 mM Tris-HCl, pH 8.0, 20 mM EDTA, 0.33 M sorbitol, 28.6 mM
For preparing leaf soluble proteins, leaf samples were ground in liquid nitrogen, and the powder was resuspended in 50 mM Tris-HCl, pH 8.0, 1 mM phenylmethylsulfonylfluoride, 50 mM
Antibodies against the recombinant poplar pMsrA were raised in rabbit and then purified from the serum onto an affinity column constituted of the recombinant pMsrA coupled to CnBr sepharose following a procedure described in Rouhier et al. (2004)
We are very grateful to Stéphanie Verrier for helpful assistance in western experiments and to Dr. Gilles Peltier (CEA, DSV, DEVM-LEP) and Dr. Jean-Pierre Jacquot (Université de Nancy-INRA) for critical reading of the manuscript. We wish to thank the Groupe de Recherche Appliquée en Phytotechnologie team for technical assistance with controlled growth chambers. We also thank Dr. Yves Meyer (CNRS-Université de Perpignan) for providing us the antibody raised against Arabidopsis PrxIIB. We wish to thank the Max Planck Institute for providing the GABI-Kat line 540H01. The T-DNA mutants were generated in the context of the GABI-Kat program and provided by Bernd Weisshaar (MPI for Plant Breeding Research, Cologne, Germany). We are grateful to the ABRC that provided us the SAIL_383_G12 line obtained from the SAIL collection and to the RIKEN Genomic Sciences Center for providing the clone RAFL16-88-B20 (AK117314). Received March 8, 2005; returned for revision April 13, 2005; accepted April 13, 2005.
Article, publication date, and citation information can be found at www.plantphysiol.org/cgi/doi/10.1104/pp.105.062430. * Corresponding author; e-mail pascal.rey{at}cea.fr; fax 33–4–42–25–62–65.
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-mercaptoethanol. 25 and 0.1 µg proteins per lane for Arabidopsis leaf proteins and poplar recombinant pMsrA, respectively.
