Redox-dependent chaperone/peroxidase function of 2-Cys-Prx from the cyanobacterium Anabaena PCC7120: role in oxidative stress tolerance.

Background Cyanobacteria, progenitors of plant chloroplasts, provide a suitable model system for plants to study adaptation towards different abiotic stresses. Genome of the filamentous, heterocystous, nitrogen-fixing cyanobacterium Anabaena PCC7120 harbours a single gene (alr4641) encoding a typical 2-Cys-Peroxiredoxins (2-Cys-Prxs). 2-Cys-Prxs are thiol-based peroxidases that also function as molecular chaperones in plants and other systems. The Alr4641 protein from Anabaena PCC7120 shows high level biochemical similarities with the plant 2-Cys-Prx. The physiological role played by the Alr4641 protein in Anabaena was addressed in this study. Results In Anabaena PCC7120, alr4641 transcript /Alr4641 protein was induced in response to abiotic stresses and its promoter was active in the vegetative cells as well as heterocysts. The wild-type Alr4641 protein or Alr4641 lacking the peroxidatic cysteine (Alr4641C56S) or the resolving cysteine (Alr4641C178S) existed as higher oligomers in their native form. The wild-type or the mutant Alr4641 proteins showed similar chaperone activity, but only the wild-type protein exhibited peroxidase activity indicating that unlike peroxidase activity, chaperone activity was not dependent on cysteines. In contrast to other 2-Cys-Prxs, chaperone/peroxidase activity of Alr4641 was dependent on its redox state and not oligomerization status. Alr4641 could protect plasmid DNA from oxidative damage and physically associate with NADPH-dependent thioredoxin reductase (NTRC). Like 2-Cys-Prxs from plants (e.g. rice), Alr4641 could detoxify various peroxides using NTRC as reductant. On exposure to H2O2, recombinant Anabaena PCC7120 strain over-expressing Alr4641 (An4641+) showed reduced content of reactive oxygen species (ROS), intact photosynthetic functions and consequently better survival than the wild-type Anabaena PCC7120, indicating that Alr4641 can protect Anabaena from oxidative stress. Conclusions The peroxidase/chaperone function of Alr4641, its inherent transcriptional/translational induction under different abiotic stresses and localization in both vegetative cells and heterocysts could be an adaptive strategy to battle various oxidative stresses that Anabaena encounters during its growth. Moreover, the recombinant Anabaena strain over expressing Alr4641 showed higher resistance to oxidative stress, suggesting its potential to serve as stress-tolerant biofertilizers in rice fields. Electronic supplementary material The online version of this article (doi:10.1186/s12870-015-0444-2) contains supplementary material, which is available to authorized users.

while Cr is located in the vicinity of C-terminus. On reaction with a peroxide substrate, Cp (Cys-SH) is oxidized to sulfenic acid (Cys-SOH), which in turn reacts with the thiol group of the resolving cysteine from other subunit to form an intermolecular disulfide bridge [5]. The active form of enzyme is regenerated with the help of reductants like thioredoxin. In the presence of excess substrate (e.g. H 2 O 2 ), Cp of 2-Cys-Prx may undergo overoxidation to form sulfinic acid (Cys-SO 3 ), which prevents disulfide bond formation, rendering the enzyme inactive. However, in many organisms, sulfiredoxin (Srx) reduces the overoxidized Cp to its catalytically active form [6,7]. Sensitivity to overoxidation depends on the structural motifs, GG(L/V/I)G and YF, which are believed to be present in the eukaryotic 2-Cys-Prxs, but generally absent in the corresponding prokaryotic enzymes [8].
The typical 2-Cys-Prx plays a vital role in detoxifying peroxides in all the kingdoms of life. Transgenic Arabidopsis with decreased 2-Cys-Prx in chloroplast showed oxidative damage of chloroplastid proteins indicating that 2-Cys-Prx protects the photosynthetic machinery from oxidative damage [9,10]. Also, Arabidopsis mutant lacking both the chloroplastid 2-Cys-Prx displayed altered redox homeostasis and showed increased H 2 O 2 levels in leaves [11]. Overexpression of 2-Cys-Prx has been shown to protect potato plants from oxidative stress and high temperature [12]. In tobacco, the chloroplastid 2-Cys-Prx has been implicated in protecting cells from photoinhibition following exposure to high light, methyl viologen (MV) or t-butyl hydroperoxide [13]. Disruption of gene encoding 2-Cys-Prx in Synechocystis as well as in Synechococcus eliminated tolerance against H 2 O 2 [14,15]. In bacteria like Sulfolobus solfataricus and Vibrio vulnificus, 2-Cys-Prx has been proposed to detoxify endogenously generated hydrogen peroxide, thus, supporting its role as an anti-oxidative stress protein [16,17].
Interestingly, the typical 2-Cys-Prx not only defends cells from oxidative stress, but also functions as redox-regulated chaperone depending on its oligomerization status [18]. The 2-Cys Prx from Pseudomonas aeruginosa, on exposure to H 2 O 2 , converts into a low molecular weight (LMW) form from its high molecular weight (HMW) form. This change triggers a chaperone to peroxidase functional switch [19]. In case of 2-Cys Prx from yeast, oxidative stress and heat shock triggers conversion from LMW form to HMW structure, which shows chaperone activity [20]. In stroma of chloroplast, under conditions of stress, the dimeric 2-Cys-Prx switches to its oligomeric form and binds reversibly to the thylakoid membrane [21]. It is widely believed that the dimeric form of 2-Cys-Prx shows peroxidatic functions while oligomerization is essential for chaperone activity [2].
Earlier, 2-Cys-Prx from Anabaena was shown to be prone to over-oxidation [8] and was found to utilize NADPH-dependent thioredoxin reductase (NTRC) as reducing agent for peroxidase activity like the 2-Cys-Prx from rice [32]. In this study, expression analysis in response to various stresses, redox dependent chaperone/peroxidase function and the role played by this enzyme in protecting Anabaena from oxidative stress were addressed. Along with oxidative stress, alr4641/Alr4641 was induced by salt/osmotic/γ-radiation stress in Anabaena and the Alr4641 protein was expressed in the vegetative cells as well as heterocysts. Alr4641 formed higher oligomeric complexes and showed peroxidase/chaperone function. Unlike peroxidase activity, chaperone activity of Alr4641 did not depend on the conserved cysteine residues. Interestingly, reduction of Alr4641 with DTT resulted in loss of chaperone activity whereas treatment with H 2 O 2 inactivated peroxidase function. Over-expression of Alr4641 in Anabaena protected the photosynthetic machinery from H 2 O 2 -induced damage via its peroxidatic cysteine, leading to better survival than the wild-type Anabaena; thus, establishing its protective role in overcoming oxidative stress.

Abiotic stresses induce alr4641/Alr4641 expression in Anabaena
Expression of alr4641 in response to different oxidative stress inducing agents was assessed by Northern blottinghybridization/dot blot analysis. The wild-type Anabaena PCC7120 cells were treated with methyl viologen (MV), hydrogen peroxide (H 2 O 2 ) or tertiary butyl hydroperoxide (t-Bx) for 1 h. Subsequently, cells were harvested, total RNA isolated and probed with the alr4641 gene probe. Results showed distinct induction of~0.9-knt transcript in RNA isolated from Anabaena cells exposed to the above-mentioned oxidizing agents as compared to the untreated (control) cells ( Figure 1A).
Interestingly, treatment with sucrose or NaCl also enhanced the levels of the alr4641 transcript ( Figure 1A). Although, alr4641 expression was observed as early as after 30 min of exposure to H 2 O 2 , maximal expression occurred by 1 h after which it declined and disappeared at the end of 6 h ( Figure 1B). Expression profile of the alr4641 transcript exposed to different concentrations of oxidative/osmotic stress causing agents for 1 h was monitored. With increasing concentrations, a concomitant rise in the level of the alr4641 transcript was observed ( Figure 1C). Western blotting followed by immunodetection with the Alr4641 antiserum revealed salt, sucrose and MV to increase the content of the Alr4641 protein as compared to the untreated control cells ( Figure 1D). Interestingly, the alr4641 transcript was also induced in response to ionizing (γ) radiation, a physical agent that causes oxidative stress ( Figure 1E). Post irradiation, during recovery, a clear enhancement in the content of the 2-Cys-Prx protein was observed ( Figure 1E).

Alr4641 promoter is expressed in the vegetative cells as well as heterocysts
As distinct induction of alr4641 was observed in response to various abiotic stresses, it was desired to locate the alr4641 promoter and indentify the regulatory elements associated with it. Rapid amplification of cDNA ends (RACE) with the total RNA isolated from the H 2 O 2treated cells showed a distinct~200-bp cDNA product ( Figure 2A). Sequence analysis of~200-bp product identified the start of alr4641 transcript to be 165-nt upstream of the translational start of the alr4641 ORF ( Figure 2B). Bioinformatic analysis revealed the presence of a prokaryotic −10 and −35-like promoter sequence and a putative FurA binding box within this promoter ( Figure 2B). Electrophoretic mobility shift assays (EMSAs) showed the purified FurA protein from Anabaena PCC7120 to bind the FurA binding box (Additional file 1).
The alr4641 promoter and its adjacent DNA were cloned upstream of the gfp reporter gene in reporter vector, pAM1956, and transferred into Anabaena PCC7120 Figure 1 Induction of alr4641/Alr4641. (A) Northern-blotting hybridization analysis. Total RNA was isolated from Anabaena PCC7120 grown in BG-11 medium without any oxidative stress-causing agent (Un) or with 1 μM methyl viologen (MV), 1 mM H 2 O 2 (H 2 O 2 ), 0.25 mM t-butyl hydroperoxide (t-Bx), 50 mM NaCl (NaCl), 100 mM sucrose (Suc), resolved (5 μg per lane) on formaldehyde-agarose gels, transferred onto a nylon membrane and probed with the DIG-labeled alr4641 ORF. The~900-nt transcript is shown by an arrow. Blot on the left panel was exposed to the X-ray film for 30 s whereas the one on the right was exposed for 15 min. (B) Time course of alr4641 expression. The wild-type Anabaena PCC7120 cells were treated with H 2 O 2 (250 μM) and total RNA isolated at time points indicated. Total RNA (1 μg) from each time point was spotted on a nylon membrane and hybridized to the DIG-labeled alr4641 probe. (C) The wild-type Anabaena PCC7120 was treated with different concentrations of MV, H 2 O 2 , t-Bx, cumeme hydroperoxide (Cux), NaCl or sucrose as indicated in the figure. Total RNA was isolated after 1 h of stress and was hybridized to the alr4641 probe. Un, RNA from untreated control cells (D) Induction of the Alr4641 protein in Anabaena. Total proteins (20 μg per lane) were isolated from Anabaena cells treated with sucrose (300 mM) or NaCl (150 mM) or MV (2 μM) and probed with the Alr4641 antiserum. The 23 kD Alr4641 protein is shown by an arrow. (E) Total RNA isolated from untreated Anabaena cells (Un) or cells treated with 1 kGy or 3 kGy dose of gamma radiation was hybridized to the alr4641 probe. After exposure to 3 kGy dose of gamma radiation, total proteins were extracted from Anabaena cells and probed with the Alr4641 antiserum.
(An4641prom). An4641prom was grown under nitrogenfixing conditions and subjected to microscopic analysis. Interestingly, along with the vegetative cells, GFP fluorescence was also observed in the heterocysts indicating that the alr4641 promoter was active in heterocysts as well as in the vegetative cells ( Figure 2C). Moreover, the Alr4641 protein was also detected in proteins extracted from heterocysts on Western blots ( Figure 2D). Expression of the Alr4641 protein was monitored in the wild-type Anabaena cultures grown under nitrogen-supplemented or nitrogen-fixing conditions. No significant difference in the production of Alr4641 was observed ( Figure 2E) suggesting that the absence of combined nitrogen in the growth medium does not affect Alr4641 expression in Anabaena.

Oligomerization of Alr4641 is independent of cysteine residues
Enhanced production of the Alr4641 protein in response to abiotic stresses and its localization in both heterocysts as well as vegetative cells suggested that Alr4641 could be an important player in detoxification of ROS in Anabaena. Hence, we wished to characterize the biophysical and biochemical properties of the Alr4641 protein in order to gain insights into its function. Analysis with the SMART (http://smart.embl-heidelberg.de/) or BLAST revealed the protein encoded by alr4641 to be a typical 2-Cys-Prx containing the conserved VCP motif. The 612 bp long alr4641 ORF encoded a 23 kD (203 amino acid) protein with the AhpC/TSA domain extending from the 13 th amino acid to the 146 th amino acid. Analysis of the Alr4641 protein sequence showed the presence of GGVG and YF motifs that are typical of eukaryotic 2-Cys-Prx ( Figure 3A). Based on homology with other peroxiredoxins, cysteines at position 56 (Cys-56) and 178 (Cys-178) of Alr4641 were speculated to be the putative peroxidatic and resolving cysteine residues respectively ( Figure 3A).
For functional characterization, the 2-Cys peroxiredoxin protein (Alr4641) from Anabaena was over-expressed in E. coli with N-terminal His-tag and purified near to homogeneity by affinity chromoatography ( Figure 3B). The putative peroxidatic (Cys-56) and resolving (Cys-178) cysteines of Alr4641 were individually mutated to serine by sitespecific mutagenesis and the corresponding proteins (Alr4641C56S and Alr4641C178S) were purified to near homogeneity. Gel filtration analysis revealed Alr4641 to elute in a fraction corresponding to decamer/dodecamer ( Figure 3C). Native PAGE analysis showed the wild-type Alr4641 as well as the mutants to be present as higher oligomers ( Figure 3D). These results suggest that peroxidatic and resolving cysteine residues are not involved in oligomer formation. On SDS-PAGE, the wild-type Alr4641 protein migrated as a monomer under reducing conditions (in presence of DTT), while in absence of DTT, a 50 kD protein, corresponding to its dimeric form was observed, indicating formation of inter subunit disulfide bond. Electrophoretic separation showed both Alr4641C56S and Alr4641C178S to be present as monomers irrespective of the presence or absence of reducing agent (DTT) on SDS PAGE ( Figure 3E). Tryptophan fluorescence spectra of the wild-type Alr4641, Alr4641C56S and Alr4641C178S proteins showed no shift in peak position at 340 nm suggesting that the absence of Cys residues does not alter the compactness of their structure (Additional file 2). Reduction of the wild-type Alr4641 did not alter the oligomeric state of the protein, but on treatment with H 2 O 2 , few smaller oligomers along with the major higher oligomeric form were observed on native PAGE ( Figure 3F). As the oligomeric state of Alr4641 remained unchanged, it was of particular interest to analyze the chaperone/peroxidase function of Alr4641 after exposure to oxidizing or reducing agents. Results pertaining to these activities are described in the next two sections.

Alr4641 protein loses its chaperone function on reduction
The Alr4641 protein was assessed for its capability to function as a molecular chaperone employing the malate dehydrogenase (MDH) aggregation assay. At 55°C, the MDH protein showed substantial aggregation after 10 min whereas the purified Alr4641 protein by itself did not form any aggregates. When purified Alr4641 was added to MDH, a marked decrease in the scattering of light was observed indicating reduced aggregation of MDH. Chaperone activity of Alr4641 was increased with increasing concentration of the protein (Alr4641) indicating that this protein did indeed function as a molecular chaperone ( Figure 4A). Alr4641C56S and Alr4641C178S both showed chaperone activity similar to the wild-type Alr4641 ( Figure 4B). Alr4641 treated with H 2 O 2 retained chaperone activity, but interestingly, the Alr4641 protein on reduction with dithiothretol (DTT) failed to show this activity ( Figure 4C). However, when the DTT-reduced Alr4641 was treated with H 2 O 2 , it regained its chaperone activity ( Figure 4C). CD spectropolarimetric analysis showed significant differences in the secondary structure of the reduced and the non-reduced wild-type Alr4641 suggesting that the oxidized and reduced forms were inherently different from each other ( Figure 4D).

Alr4641 protects plasmid DNA from oxidative damage and shows Trx/NTRC-dependent peroxidase activity
Metal catalyzed oxidation (MCO) was performed to verify if the purified Alr4641 protein could function as an antioxidant protein. The plasmid DNA was completely degraded when subjected to MCO assay in the absence of Alr4641. However, addition of the Alr4641 protein protected the plasmid DNA from degradation ( Figure 5A). The ability of Alr4641 to scavenge hydrogen peroxide with different electron donor systems [DTT, reduced glutathione (GSH) or thioredoxin A (TrxA)] was evaluated. The Alr4641 protein could use TrxA and DTT but not GSH to detoxify H 2 O 2 ( Figure 5B). The purified Alr4641 protein showed TrxA-dependent activity whereas both Alr4641C56S and Alr4641C178S failed to do so ( Figure 5C).
The NTRC protein from Anabaena was over-expressed in E. coli, purified by affinity chromatography ( Figure 5D). Surface Plasmon Resonance (SPR) was employed to study interaction of Alr4641 with NTRC. The Alr4641 protein was immobilized on a bare gold sensor chip while NTRC was used in the mobile phase. The interaction between the two proteins was confirmed by a concentrationdependent increase in the SPR signal ( Figure 5E). Equilibrium analysis showed a good Lorentz fit with the experimental values (Additional file 3) and the equilibrium constant (K D ) was observed to be 1.037x10 −6 ± 4.76x10 −8 M. NTRC was also employed to evaluate the peroxidase activity of Alr4641 in the presence of different peroxidase substrates. Among the three substrates tested, best activity was observed with H 2 O 2 followed by t-butyl hydroperoxide and cumeme hydroperoxide (Additional file 4). With increasing concentrations of H 2 O 2 , a reduction in the peroxidase activity was observed, indicating that excess H 2 O 2 inactivated the Alr4641 protein ( Figure 5F).

Alr4641 forms over-oxidized monomer in vivo under conditions of oxidative stress
The peroxidatic cysteine of 2-Cys-Prxs, on treatment with excess of oxidizing agents (e. g. H 2 O 2 ), becomes overoxidized and is unable to form disulphide bridges. Hence, the over-oxidized 2-Cys-Prx shows up as a monomer on non-reducing SDS-polyacrylamide gels [10]. To analyze the formation of over-oxidized monomers in vivo in Anabaena during oxidative stress, cells were treated with different oxidizing agents and analyzed ( Figure 6). Treatment with H 2 O 2 but not methyl viologen produced detectable Alr4641 monomers, whereas at the concentration of t-butyl hydroperoxide (t-Bx) employed, partial overoxidation of Alr4641 occurred and both monomeric as well as dimeric forms of the protein were observed ( Figure 6A). Exposure of Anabaena to 6 kGy dose of gamma radiation also resulted in the formation of the Alr4641 monomers ( Figure 6B). However, the overoxidized form disappeared during recovery and 24 h after irradiation, only the dimeric form of Alr4641 was observed ( Figure 6C).
Over-expression of Alr4641, but not Alr4641C56S, causes reduction in intracellular ROS generation on exposure to H 2 O 2 To assess the in vivo role of catalytic cysteine (C56), the wild-type alr4641 or alr4641C56S were individually cloned between the strong light inducible psbA promoter (P psbA ) and the gfp (green fluorescent protein) gene in pAM1956 (denoted as pAM4641 and pAM4641C56S respectively). Both these constructs were separately transferred to Anabaena PCC7120. Under fluorescence microscope, the filaments of An4641 + (Anabaena expressing Alr4641) and AnC56S + (Anabaena over-expressing Alr4641C56S) appeared green indicating the presence of pAM4641 or pAM4641C56S ( Figure 7A, B). When probed with the anti-Alr4641 antiserum, abundant production of the Alr4641 or Alr4641C56S protein was observed in the cell-free extract of An4641 + or AnC56S + respectively ( Figure 7C). When analyzed on non-reducing SDS-PAGE, the wild-type Alr4641 was mostly present in its dimeric form whereas Alr4641C56S remained largely monomeric ( Figure 7D). Native PAGE followed by Western blot analysis with cell free extracts of An4641 + /AnC56S + revealed the occurrence of higher oligomeric form in vivo in both the cases ( Figure 7E) as also observed with the purified proteins ( Figure 3D).
Earlier, the NTRC protein was shown to physically interact with the purified Alr4641 protein ( Figure 5E). In addition, capability of NTRC to associate with the Alr4641 protein from An4641 + cells free extracts was assessed by pull down experiments. As shown in Figure 7F, substantial amount of Alr4641 was bound when NTRC was immobilized on NiNTA agarose. In the absence of NTRC, hardly any Alr4641 bound to the empty resin ( Figure 7F). Exponential phase cultures of Anabaena PCC7120 (3.0 μg chlorophyll a ml −1 ) were exposed to methyl viologen, (MV), hydrogen peroxide, (H 2 O 2 ) or t-butyl hydroperoxide, (t-Bx) for 30 min. Cell free extracts (25 μg protein per lane) were resolved on non-reducing SDSpolyacrylamide gel, electroblotted onto a nitrocellulose membrane and probed with the Alr4641 antiserum. The dimeric (non-overoxidized) form and the monomeric (oxidized) form are indicated in the figure. (B) Over-oxidation of Alr4641 in response to gamma (γ) radiation. Exponential phase cultures of Anabaena PCC7120 (6.0 μg chlorophyll a ml −1 ) were exposed to different doses of γ-radiation as indicated in the figure. The Alr4641 protein was detected immediately after irradiation as described in A. (C) After exposure to 6 kGy dose of γ-radiation, Anabaena cells were incubated in BG11N+ medium for recovery from radiation stress. Cells were removed at time points indicated and the Alr4641 protein was detected as before.
The intracellular levels of ROS in the wild-type Anabaena, An4641 + or AnC56S + cells exposed to H 2 O 2 for 1 h were assessed with the fluorogenic probe DCHFDA. Under control conditions, ROS levels were very low in all types of cells. However, on exposure to 1 mM H 2 O 2 , substantially higher levels of ROS were observed in the wild-type Anabaena PCC7120 and AnC56S + cells as compared to the An4641 + cells ( Figure 7G).
Over-production of Alr4641 protects the photosynthetic machinery and enhances survival in response to oxidative stress in Anabaena Treatment with 1 mM H 2 O 2 for 24 h resulted in pronounced bleaching caused by a sharp reduction in the chlorophyll a content in the wild-type Anabaena PCC7120 but not in An4641 + cells ( Figure 8A and B). A substantial decline was observed in F v /F m of H 2 O 2 -stressed wild-type Anabaena cells, while An4641 + showed F v /F m comparable to the unstressed control cells (Table 1). Light curves (LC) of electron transport rate (ETR) with the wild-type Anabaena or An4641 + were carried out to analyze electron transport rate in PSII in response to H 2 O 2 . The ETR (II) of An4641 + on treatment with H 2 O 2 was similar to that of control cells. In contrast, a severe decrease in ETR (II) was observed when the wild-type Anabaena was treated with H 2 O 2 ( Figure 8C). Rate of CO 2 fixation decreased marginally in the An4641 + treated with H 2 O 2 as compared to a 20-fold reduction observed in the similarly treated wild- type Anabaena PCC7120 ( Figure 8D). The wild-type Anabaena PCC7120 treated with H 2 O 2 failed to grow on BG-11 plates indicating loss in viability. On the other hand, similarly treated An4641 + grew on plates like the unstressed control cells ( Figure 8E).

Discussion
Prxs form a phylogenetically ancient group of enzymes with a major role in detoxification of peroxides [2]. Generally, Prxs show a moderate catalytic activity, but their high cellular content seems to compensate for their reduced efficiency in decomposing peroxides [33]. It is believed that the antioxidant system in chloroplasts, organelle with highest content of Prxs in a plant cell, has evolved from cyanobacteria. Anabaena bears a resemblance to plant chloroplasts in being equipped with an oxidation sensitive 2-Cys-Prx (i.e. Alr4641) along with its reducing partner NTRC [32] and showing a low catalase activity [8,25].
The presence of the 0.9-knt alr4641 transcript (Figure 1) indicates that in spite of their adjacent location, the  alr4642 ORF (642-bp, located 191-bp downstream of alr4641) and alr4641 are not co-transcribed, signifying that alr4641 forms a monocistronic operon. The promoter sequence found immediately upstream of this start site showed the presence of FurA (a transcriptional repressor) binding site ( Figure 2) and the purified FurA protein from Anabaena bound the DNA fragment containing this sequence (Additional file 1). Gonzalez et al. have shown production of the Alr4641 protein to be reduced in the FurA-overexpressing Anabaena PCC7120. All these results imply that FurA regulates transcription of alr4641 in Anabaena [34]. In response to different abiotic stresses, the 2-Cys-prx gene transcript was enhanced in Synechococcus PCC7942 but not Synechocystis PCC6803 suggesting that transcriptional induction of 2-Cys-prx differs among cyanobacteria [35]. In Anabaena, along with methyl viologen and H 2 O 2 , gamma radiation (a physical agent that causes oxidative stress) could also enhance production of the alr4641 transcript or the Alr4641 protein ( Figure 1) [27]. Interestingly, salinity as well as osmotic stress also increased production of the Alr4641 protein (Figure 1), indicating that Alr4641 may be a multiple stress induced protein. This is not unusual as several environmental stresses (salinity, drought, heavy metals, heat shock etc.) generate ROS [12], which in turn may ultimately enhance production of the Alr4641 protein.
Employing pull down assay and SPR analysis, NTRC was shown to physically interact with Alr4641 ( Figures 5E,  7F) suggesting that NTRC is likely to be the physiological reductant of Alr4641 in Anabaena. In vivo, on treatment with H 2 O 2 , the recombinant AnC56S + strain (that overexpresses Alr4641C56S) showed higher ROS levels compared to the An4641 + strain (that over-expresses the wild-type Alr4641) ( Figure 7G). This underscores the importance of peroxidatic cysteine of Alr4641 for detoxification of H 2 O 2 in vivo in Anabaena.
In general, the purified 2-Cys-Prx isolated from different organisms co-exists in various forms i.e. dimeric, decameric and high molecular wt. complexes [36]. In contrast, in its native form, Alr4641 as well as its cysteine mutants appeared as decamers in vitro, (Figure 3) or in vivo ( Figure 7E). Moreover, irrespective of the redox state (i.e. whether oxidized or reduced), Alr4641 appeared as decamer (Figure 3) indicating that the disulfide bonds are not involved in oligomerization.
Generally, along with conformational change, the oligomeric state of 2-Cys Prx has also been linked to its dynamic redox state, which in turn determines its function [36]. Chaperone activity of 2-Cys-Prx has been generally linked to their oligomerization state [20]. The higher molecular weight complex shows chaperone function, the dimeric form mostly functions as a peroxidase, whereas the decameric form shows both these activities [37]. Although, reduction of Alr4641 with DTT did not change its oligomeric nature, its chaperone activity was severely reduced (Figure 4). Loss of chaperone function was observed on reducing Alr4641C56S and Alr4641C178S too (data not shown), suggesting that reduction in chaperone activity was not due to disruption of disulphide bonds. In contrast, treatment with H 2 O 2 did not affect the chaperone activity of Alr4641, whereas a substantial loss in peroxidase activity was observed ( Figure 5F). Apparently, chaperone/ peroxidase activity of Alr4641 does not depend on its oligomeric status, but is decided by the redox state of the protein i.e. the reduced form is more likely to function as a peroxidase while the oxidized form is more liable to function as a chaperone. A model depicting the above phenomena is described in the Figure 9. Although, thought to be a specific disulphide bond reducing agent, DTT is known to affect function of proteins not containing any cysteine residues [38], and it is proposed that DTT may act as a general reducing agent that causes changes in the global structure of proteins [39]. Reduction of 2-Cys-Prx from Arabidopsis with DTT also resulted in altered secondary structure [37]. In this study too, a distinct difference in the CD spectra of reduced and non-reduced Alr4641 was observed (Figure 4), indicating that treatment with DTT causes a change in the secondary structure.
Excess H 2 O 2 over-oxidizes the peroxidatic cysteine, rendering Alr4641 incapable of peroxidase activity [8]. Interestingly, high dose of γ-radiation could also over-oxidize the 2-Cys-Prx ( Figure 6B) preventing the formation of disulfide bond. Post irradiation, on SDS PAGE, the monomeric form of Alr4641 disappeared and only the dimeric form could be seen after 24 h, indicating the reversion of the over-oxidised Alr4641protein to its normal form ( Figure 6C). It is suggested that the recovery of the overoxidized Alr4641 is facilitated by the sulfiredoxin (Srx) protein, which reverses the over-oxidation in vivo [40].
In Anabaena, depletion of combined nitrogen from medium leads to formation of heterocysts, the specialized cells that fix nitrogen [41]. It should be noted that in spite of lowered O 2 content, ROS are generated by photosystem I (PSI) and respiratory electron transport in heterocysts [42]. Also, when the ratio of nitrogenase reductase to O 2 is greater than 4, nitrogenase reductase reduces oxygen to H 2 O 2 without being inactivated by oxygen [43]. Thus the H 2 O 2 produced in heterocysts has to be removed promptly. Prxs are known to be differentially distributed among the vegetative cells and heterocysts [29] and among the four PrxQ-like proteins (Alr3183, Alr2503, Alr2375 and Alr2556) from Anabaena, only Alr2375 was detected in heterocysts [44]. In our study, promoter activity (P alr4641 -GFP fluorescence) as well the Alr4641 protein was observed in heterocysts as well as vegetative cells (Figure 2), indicating that it may play a role in detoxifying peroxides in vegetative cells and heterocysts.
Hydrogen peroxide (H 2 O 2 ) is a commonly occurring reactive oxygen species (ROS) in biological systems and cyanobacteria have been shown to be generally more sensitive to H 2 O 2 than other phototrophs [45]. As Anabaena PCC7120 does not show good catalase activity [8,27], it is suggested that Prxs may be the principal components that detoxify H 2 O 2 in this organism. H 2 O 2 damages photosynthetic apparatus and severely affects F v /F m in several cyanobacteria [46]. In the cyanobacterium Microcystis aeruginosa, treatment with H 2 O 2 enhanced reactive oxygen species (ROS) accumulation, which caused destruction of pigment synthesis and led to cell death [47]. Treatment of the wild-type Anabaena PCC7120 with H 2 O 2 caused (a) enhanced levels of ROS (b) decrease in photosynthetic activities and (c) loss in viability ( Figure 8). However, all the above-mentioned deleterious effects were alleviated in An4641 + strain, indicating that Alr4641 can protect Anabaena from oxidative stress.

Conclusions
The present study has identified Alr4641 as an abiotic stress induced protein that plays an important role in protecting Anabaena from oxidative stress. The Alr4641 protein was found to be unique from the other reported 2-Cys-Prxs i.e. the redox state and not its oligomerization status dictated the functional switch between the peroxidase or chaperone activity of this protein. Key attributes of Alr4641 like dual function, inherent transcriptional/translational induction under different stresses, localization in both vegetative cells and heterocysts, ability to use various reducing agents for detoxifying peroxides, reflect the versatile role played by the protein in Anabaena. The recombinant Anabaena strain over expressing Alr4641 exhibited higher tolerance to oxidative stress, thus establishing its potential to serve as stress-tolerant biofertilizers in paddy fields.

Organism and growth conditions
Anabaena PCC7120 cultures were grown in BG-11 liquid medium, pH 7.0 with combined nitrogen (17 mM NaNO 3 ) under continuous illumination (30 μE m −2 s −1 ), with shaking (100 rpm) or without shaking (as still culture) at 27°C ± 2°C. Growth was assessed by monitoring the content of chlorophyll a mL −1 of culture volume [48]. E. coli cells were grown in Luria-Bertani (LB) medium in the presence of appropriate antibiotics at 37°C with shaking at 150 rpm. The antibiotics used were 10 μg neomycin mL −1 (Nm 10 ) in BG-11 liquid media and 25 μg neomycin mL −1 (Nm 25 ) in BG-11 agar plates for recombinant Anabaena PCC 7120; and 34 μg chloramphenicol mL −1 (Cm 34 ), 50 μg kanamycin mL −1 (Kan 50 ) or 100 μg carbenicillin mL −1 (Cb 100 ) for E. coli. The E. coli and Anabaena strains and plasmids used in the study are indicated in Additional file 5.
Cloning of alr4641, alr4641C56S alr4641C178S, furA and ntrc into pET16b The alr4641 ORF was PCR amplified using genespecific primers, alr4641fwd and alr4641rev, from Anabaena PCC7120 chromosomal DNA (Additional file 6). The PCR product (612-bp) obtained was digested with NdeI and BamHI and cloned into similarly digested pET16b (Additional file 5) to obtain plasmid pET4641. The pET4641 insert was sequenced to confirm the nucleotide sequence integrity of the cloned gene. A point mutation, leading to substitution of the Cys codon at positions 56 or 178 to Ser codon was introduced into the alr4641 ORF by PCR directed site-specific mutagenesis using overlapping PCR as described earlier [25]. The PCR products (alr4641C56S and alr4641C178) containing the desired mutation were cloned into pET16b vector between the NdeI and BamHI restriction enzyme sites for over-expression in E. coli and named pET4641C56S and pET4641C178S respectively. The furA (all1691) or the ntrc (all0737) ORF was amplified with specific primers (described in Additional file 6) employing Anabaena PCC7120 genomic DNA as template. Restriction enzyme sites for NcoI and BamHI were incorporated in the forward and the reverse primers respectively. The reverse primer also had six His codons (shown in bold) followed by a stop codon. PCR product was purified, digested, and ligated to the NcoI-BamHI digested pET16b vector to give rise to pETFurA and pETNTRC respectively. All the resultant clones were confirmed by DNA sequencing.

Over-production and purification of recombinant proteins
Over-production of the His-tagged Alr4641, Alr4641C56S, Alr4641C178S, FurA and NTRC proteins in E. coli BL21pLysS and their subsequent purification was performed by affinity chromatography using Ni-NTA matrix as described earlier [49]. The purified Alr4641 protein was also used to immunize rabbits for generating specific antiserum. The primary and booster immunizations and collection of the antiserum were performed at a commercial facility (Merck, India).

Chaperone activity
The chaperone activity of purified proteins was measured by using 1 μM malate dehydrogenase (MDH) as substrate in 50 mM HEPES-NaOH (pH 8.0) buffer at 55°C with various Prx concentrations (4:1, 2:1, 1:1, 1:2 MDH:Prx molar ratio). Turbidity (A 360 ) due to substrate aggregation at 55°C was monitored in a spectrophotometer (JASCO, Japan) equipped with a thermostatic cell holder. When desired, the purified Alr4641/Alr4641C56S/Alr4641C178S proteins were individually treated with DTT (5 mM) or H 2 O 2 (10 mM) for 10 min, passed through a desalting column and employed for the chaperone assay as described above. Assays were performed at least 4 times and representative curves are shown in the figure.

Peroxidase activity assay
For DTT dependent peroxidase assay, reaction mixture (1 ml) containing HEPES-NaOH (50 mM, pH 7.0) and desired concentrations of Prx proteins were pre-incubated with DTT (3 mM) for 10 min at 37°C, followed by the addition of H 2 O 2 (200 μM). The reaction was stopped after 10 min by addition of TCA (10%, v/v). Subsequently, 0.2 volume of ferrous ammonium sulfate (10 mM) and 0.1 volume of potassium thiocyanate (2.5 M) were added. Absorbance of the red colored complex was spectrophotometrically measured at 480 nm. The amount of residual H 2 O 2 remaining in the reaction was calculated from a standard calibration curve prepared by using known concentrations of H 2 O 2 . Trx-dependent peroxidase reactions were performed in a 50 μl reaction mixture containing HEPES-NaOH (50 mM, pH 7.0), E. coli thioredoxin A (TrxA, 5 μM), E. coli thioredoxin reductase (TR, 0.5 μM), NADPH (0.25 mM), Prx Protein or its mutant variants (0.05-1 μg), and H 2 O 2 (200 μM). For GSH-dependent peroxidase activity, the typical reaction mixture contained HEPES/NaOH (50 mM, pH 7.0), NADPH (0.25 mM), glutathione reductase (GR, 0.2 μM), Prx protein (1 μg) and reduced glutathione (GSH, 5 mM). The reaction was started by addition of 100 μM peroxide substrate. The residual amount of peroxide was determined by ferrithiocyanate system as mentioned above. NTRCdependent peroxidase activity of Alr4641 with different peroxide substrates was determined as described by Pascual et al. (2011) [32].

Protein electrophoresis, Western blotting and immunodetection
Purified Alr4641, Alr4641C56S and Alr4641C178S were resolved electrophoretically by 12% SDS-PAGE with or without DTT (10 mM). These three proteins were also resolved by native PAGE and stained with CBB. Total cellular proteins from Anabaena cultures were extracted using Laemmli's buffer [50] and electrophoretically separated by 12% SDS-PAGE. The gel was electroblotted on to a nitrocellulose membrane as described earlier [51]. In case of native PAGE, for efficient transfer, the gel was immersed in 1X SDS-PAGE running buffer, incubated at 70°C for 30 min and electroblotted on to the nitrocellulose membrane. Immunodetection was carried out with the Alr4641 antiserum.

Pull down assay
In the pull-down experiment, His-tagged NTRC (500 μg) was allowed to bind to Ni-NTA agarose slurry (100 μl) in assay buffer (50 mM Tris, 200 mM NaCl, 5 mM immidazole) for 2 h at 4°C, followed by washing with same buffer to remove the unbound NTRC. Cytosolic extract of An4641 + (800 μg protein) was incubated with NTRCbound Ni-NTA agarose overnight at 4°C with constant rocking. In the control experiment, only Ni-NTA agarose was incubated with cytosolic fraction of An4641 + . In both the cases, agarose was centrifuged at 5000 g for 5 min at 4°C, washed thrice with the assay buffer, boiled with cracking buffer and resolved on 12.5% SDS-PAGE. The gel was transferred on to a nitrocellulose membrane and probed with anti-Alr4641 antibody.

Co-Immuno-precipitation
For co-immuno-precipitation, the His-tagged NTRC (50 μg) was allowed to incubate with His-tagged Alr4641 (50 μg) in co-immunoprecipitation buffer (50 mM Tris-Cl pH 7.5, 15 mM EDTA, 100 mM NaCl, 0.1% Triton X-100 and protease inhibitor cocktail obtained from Sigma) at 4°C in duplicate. To one vial, Alr4641 antiserum was added and the components were allowed to interact for 6 h at 4°C with constant shaking. No antibody was added to the other vial (negative control). After that, a slurry of protein-G agarose beads (50 μl) was added to both the vials and these were kept shaking overnight at 4°C. Next day, beads were precipitated by centrifuging at 1200 g for 5 min at 4°C and washed thrice with the co-immuno-precipitation buffer. Subsequently, sample buffer was added to beads and the proteins extracted by boiling. The extracted proteins were separated on SDS-polyacrylamide (12.5%) gels, and visualized by staining.
Surface plasmon resonance (SPR) analysis Autolab Esprit SPR system was used for surface plasmon resonance analysis with bare gold sensor chip. At 20°C, about 250 response units of Alr4641 was loaded onto the bare gold chip employing the EDC-NHS chemistry (Autolab ESPIRIT User manual SPR) followed by extensive washing with buffer H (10 mM HEPES, 100 mM NaCl, pH 7.5). Different concentrations (4.33, 8.66, 10.39 and 12.99 μM) of the NTRC protein were injected onto the Alr4641-bound sensor chip at 33.3 μL min −1 flow rate in independent experiments. The NTRC was allowed to interact with the immobilized Alr4641 for 300 s before washing off with buffer H. The data were processed and equilibrium constant (K D ) was calculated using Autolab kinetic evaluation software (V5.4) provided with the instrument.

Gel retardation assays (GRA)
Primers 4641Prom_GRAFwd and 4641Prom_GRARev were annealed to form a 39-bp dsDNA (i.e. alr4641 promoter), which was used for the gel shift assays with the purified FurA protein. The end labeling of DNA fragments with digoxygenin (DIG) and the subsequent GRA, in the presence of the non-specific competitor poly (dI-dC), was performed as described by the manufacturer (Roche).

Metal catalyzed oxidation (MCO) assay for antioxidant activity
The plasmid DNA (pBluescript, 1 μg) was subjected to MCO by incubating FeCl 3 (20 μM) and DTT (5 mM) at room temperature for 30 min. Purified proteins (2-20 μg) were added to the reaction mixture and further incubated for 4 h. Subsequently, DNA integrity was assessed by electrophoresis of reaction samples on agarose (0.8%, TBE, pH 7) gels.

Oxidation and reduction of the Alr4641 protein
The purified Alr4641 protein was oxidized with H 2 O 2 (10 mM) for 30 min or reduced by addition of DTT (5 mM). The samples were analyzed for chaperone activity as described earlier or resolved on Native PAGE and visualized by CBB staining.

Northern blotting-hybridization and dot blot analysis
Isolation of Anabaena PCC7120 total RNA and subsequent Dot blot or Northern blotting-hybridization analysis with the alr4641 DIG-labeled DNA probe was performed as described earlier [52].

Rapid amplification of cDNA ends (RACE)
The total RNA isolated from the wild-type Anabaena PCC7120 cells stressed with H 2 O 2 , for 1 h was treated with DNase I and re-purified using commercial spin columns (Nucleospin RNA clean-up XS, Macherey Nagel). The reverse primer EXTERN-4641RACE-Rev (Additional file 6) was employed for cDNA synthesis. Tailing of cDNA using dATP and terminal transferase, the subsequent PCR with oligo dT-anchor primer and an internal gene-specific primer (INTER-4641RACE-Rev) was performed exactly as described (5'/3' RACE kit, 2 nd Generation, Roche).

Construction of GFP promoter
A 600-bp DNA fragment (upstream of the alr4641 gene) that contained the alr4641 promoter was amplified with suitable primers and cloned just upstream of gfp (reporter gene) in pAM1956 employing the restriction enzymes KpnI and SacI (construct named as pAM4641prom). This construct was conjugated into Anabaena PCC7120 and exconjugants (An4641 prom) were selected on BG-11/N + plates containing neomycin (25 μg ml −1 ) and subjected to microscopic analysis.

Heterocyst isolation
Anabaena PCC7120 was grown aerobically in nitrogenfree BG-11 liquid medium. Heterocysts were isolated from whole filaments using modified protocol as described by Cha et al., 2007 [44]. Anabaena culture was harvested and subjected to several freeze-thaw cycles in Tris-buffer (20 mM Tris, 1 mM EDTA, pH 7.4). After centrifugation for 5 min at 1000 g, the sedimented cells were suspended in the same buffer, glass beads (600 μM) were added and the suspension was vortexed for 2 min. Subsequently, the suspension was centrifuged at 150 g for 5 min to obtain heterocysts in the supernatant. Enrichment of greenish yellow heterocysts was achieved by repeatedly washing (7-8 times) and centrifuging (150 g, 5 min) the heterocyst pellet.

CO 2 fixation
The wild-type Anabaena PCC7120 and the recombinant An4641 + cells were subjected to 1 mM H 2 O 2 treatment for 1 day. Culture aliquot (200 μl) of the above-mentioned Anabaena cells (5-6 μg ml −1 chlorophyll a) was incubated in white fluorescent light (24 W m −2 ) for 5 min and followed by addition of NaH 14 CO 3 (20 mM, specific activity 0.5 mCi mmol −1 ). The reaction was stopped after 10 min by addition of 400 μl of 6 N acetic acid to the reaction mixture. The acid stable product was counted in a liquid scintillation counter with 0.4% BBOT [2, 5-bis (5tert-butylbenzoxazole-2-yl) thiophen] dissolved in a solution containing toluene and absolute ethanol (v/v, 65:35). The experiment was performed twice with three replicate samples each time.

DCHFDA assay
The content of the reactive oxygen species (ROS) in Anabaena strains treated with H 2 O 2 for 1 day and in respective controls cells was measured with Dichlorodihydrofluorescein diacetate (DCHFDA) [56]. Briefly, DCHFDA (10 μM final concentration) was added to cells suspended in BG-11 medium (3 μg chlorophyll a ml −1 ). Cells were incubated for 20 min in dark at 25°C. Fluorescence emission (λ ex = 490 nm and λ em = 520 nm) of the control or H 2 O 2 (1 mM)-treated cells was measured immediately afterwards. Experiments were repeated thrice and average values are reported.

Determination of oxidative stress tolerance of An4641 + strain
Three-day-old Anabaena cultures of the wild-type Anabaena PCC7120 (WT) as well as An4641 + (in triplicates) were inoculated in a fresh growth medium at a chlorophyll a density of 3 μg ml −1 and subjected to H 2 O 2 (1 mM) stress in tubes (without shaking) under illumination for 2 days. Growth was monitored in liquid cultures by determination of chlorophyll a content [48].

Additional files
Additional file 1: Purification of FurA and its binding with FurA binding sequence of Alr4641 promoter. (A)The FurA protein from Anabaena PCC7120 was over-expressed in E. coli and purified by affinity chromatography as described in the Methods section. After electrophoresis proteins were visualized by staining with CBB. Lane 1, mol. mass marker and lane 2, purified FurA protein (5 μg). (B) Gel shift assays with FurA. The DNA fragment corresponding to the FurA binding site ( Figure 2B) was