Open Access Highly Accessed Research article

The crystal structure of superoxide dismutase from Plasmodium falciparum

Ian W Boucher1, Andrzej M Brzozowski1, James A Brannigan1*, Claudia Schnick1, Derek J Smith13, Sue A Kyes2 and Anthony J Wilkinson1

Author Affiliations

1 Structural Biology Laboratory, Department of Chemistry, University of York, York YO10 5YW, UK

2 Molecular Parasitology Group, Weatherall Institute of Molecular Medicine, John Radcliffe Hospital, Headington, Oxford OX3 9DS, UK

3 Bioinformatics Institute, 30 Biopolis St., Singapore 138671, Singapore

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BMC Structural Biology 2006, 6:20  doi:10.1186/1472-6807-6-20


The electronic version of this article is the complete one and can be found online at: http://www.biomedcentral.com/1472-6807/6/20


Received:8 June 2006
Accepted:4 October 2006
Published:4 October 2006

© 2006 Boucher et al; licensee BioMed Central Ltd.

This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Background

Superoxide dismutases (SODs) are important enzymes in defence against oxidative stress. In Plasmodium falciparum, they may be expected to have special significance since part of the parasite life cycle is spent in red blood cells where the formation of reactive oxygen species is likely to be promoted by the products of haemoglobin breakdown. Thus, inhibitors of P. falciparum SODs have potential as anti-malarial compounds. As a step towards their development we have determined the crystal structure of the parasite's cytosolic iron superoxide dismutase.

Results

The cytosolic iron superoxide dismutase from P. falciparum (PfFeSOD) has been overexpressed in E. coli in a catalytically active form. Its crystal structure has been solved by molecular replacement and refined against data extending to 2.5 Å resolution. The structure reveals a two-domain organisation and an iron centre in which the metal is coordinated by three histidines, an aspartate and a solvent molecule. Consistent with ultracentrifugation analysis the enzyme is a dimer in which a hydrogen bonding lattice links the two active centres.

Conclusion

The tertiary structure of PfFeSOD is very similar to those of a number of other iron-and manganese-dependent superoxide dismutases, moreover the active site residues are conserved suggesting a common mechanism of action. Comparison of the dimer interfaces of PfFeSOD with the human manganese-dependent superoxide dismutase reveals a number of differences, which may underpin the design of parasite-selective superoxide dismutase inhibitors.

Background

Superoxide dismutases (SODs) are crucial enzymes in both eukaryotes and prokaryotes. They catalyse the dismutation of the superoxide radical to hydrogen peroxide and dioxygen according to the two-step reaction as follows:

M3+ + O2 .- → M2+ + O2

M2+ + O2 .- + 2H+ → M3+ + H2O2

where M denotes a metal ion which interconverts between oxidised and reduced states. The superoxide radical O2 .- is formed in cells as a result of both enzymatic and spontaneous oxidation reactions. The superoxide radical is toxic to living cells as it oxidises and degrades biological molecules such as lipids and proteins [1].

For many years it was thought that malaria parasites had no requirement for an endogenous superoxide dismutase and merely exploited the activity of the host's enzyme in the red blood cell [2]. However, in 1996 a Plasmodium falciparum iron-dependent SOD (PfFeSOD) was identified in parasites isolated from infected blood cells [3]. Malaria parasites are particularly prone to oxidative damage in the intra-erythrocytic stage of their lifecycle. This is because an important source of amino acids for the parasite is red blood cell haemoglobin. Haemoglobin degradation produces free haem groups leading to oxidation of the iron from the ferrous (Fe2+) to the ferric (Fe3+) state. This oxidation liberates electrons, which promote the formation of reactive oxygen intermediates, including superoxide. The PfFeSOD gene is expressed at its highest level during this stage of the parasite life cycle [4].

SODs are classified according to their metal cofactors. Eukaryotic cells are generally served by a cytosolic Cu/ZnSOD and an evolutionarily unrelated mitochondrial MnSOD. Some eukaryotes also contain a SOD containing a single Fe atom. Bacterial cells feature single metal-centred SODs in which the metal can be either manganese or iron. The FeSODs and the MnSODs exhibit recognisable similarities in their sequences, they have a common α/β tertiary structure and they use the same residues to coordinate the metal [5]. These are quite distinct from the two-metal Cu/ZnSODs, which have a Greek key β-barrel fold [6]. The MnSODs of eukaryotic origin are distinguishable from those of prokaryotic sources on the basis of their quaternary structure; the former are tetramers while the latter are dimers. Small sequence differences distinguish the Mn- and FeSODs [7]. Biochemically, FeSODs are more sensitive to inhibition by azide [8] and have a greater susceptibility to inactivation by hydrogen peroxide, than MnSODs. Iron and manganese superoxide dismutases can bind either metal cofactor. However, most are only functional with their cognate metal co-factor bound. Some enzymes however, maintain activity with either Fe or Mn bound and are termed cambialistic [9].

In 2002, an electron paramagnetic resonance and modelling study of SOD from P. falciparum showed it was, as expected, an iron-dependent dimer [10]. The fact that it is an FeSOD and distinct from human tetrameric Mn and Cu/ZnSODs raises the possibility of its exploitation as an anti-malarial drug target [11] and indeed inhibitors of PfFeSOD have been identified [12]. This study presents an X-ray crystal structure of P. falciparum FeSOD solved at a resolution of 2.5 Å.

Results

Protein characterization

Purified PfFeSOD was resolved by electrophoresis for 3 hours at 100 V in a 10% native polyacrylamide gel. The gel was soaked in riboflavin and NADPH to generate superoxide radicals, and stained by Nitro Blue Tetrazolium (NBT) dye. NBT reacts with superoxide to form a blue precipitate when fixed in a gel. Any regions on the gel that exhibit SOD activity will therefore be white against a blue background. A clear white band coincident with the PfFeSOD protein indicated that the protein was active. Analytical ultracentrifugation (AUC) sedimentation equilibrium experiments estimated the molecular weight of the protein to be 47,400 ± 700 Da. Since the calculated molecular weight of the monomer is 23,799 Da, this indicates that PfFeSOD is a dimer, consistent with previously characterised FeSODs, which are either dimers or tetramers.

Overall structure

The crystal structure of PfFeSOD has been solved and refined against data extending to 2.5 Å spacing. The refined model consists of two polypeptide chains, A and B, which are related by a non-crystallographic two-fold axis of symmetry, together with two iron ions and 140 solvent water molecules. The electron density maps are contiguous from residue 1 to residue 197 of both chains. The C-terminal PfFeSOD residue (Lys198), together with the eight residues of the C-terminal tag are not observed in the electron density maps. Details of the refinement statistics are given in Table 1. There is a solitary outlier in the Ramachandran plot at residue Lys43 in the B chain, which occurs in a partially ordered surface loop. The Ser15-Pro16 peptide bond in both chains is in the cis conformation.

Table 1. Data collection and refinement statistics

The overall structure is similar to those of previously solved iron superoxide dismutases, consisting of an amino terminal α-helical domain linked to a carboxy terminal α/β domain. The first eleven residues have an extended structure and are involved in crystal packing. The next 70 residues form two long anti-parallel α-helices (α1 and α3) connected by a meandering loop containing a third helix, α2. In both subunits, helix α1 has a noticeable kink at the conserved Lys29 residue, a feature that has been noted before [13]. This domain is connected via an extended loop to the α/β domain (Figure 2A), which comprises a three-stranded anti-parallel β-pleated sheet (strand order β3-β1-β2) surrounded by four α-helices. Superposition of equivalent Cα atoms of chain A and chain B of PfFeSOD gives a positional root mean squared deviation (rmsΔ) of 0.3 Å. The PfFeSOD structure superposes onto the molecular replacement model, E. coli FeSOD, with an rmsΔ of 0.55 Å over all equivalent Cα atoms.

thumbnailFigure 1. Sequence alignment of FeSOD from P. falciparum and E.coli and MnSOD from the human mitochondrion. Identical residues are highlighted with a red background and similar residues are boxed. PfFeSOD (top) and MnSOD (PDB code 1n0j [36] bottom) secondary structure elements are indicated. Residues predicted to be specific to MnSOD sequences [37] are marked with a triangle. Note the similarity of secondary structure between the two types of SOD. The longer helices in the N-terminal domain of MnSOD contribute to tetramer formation. The figure was made using ESPript [38].

thumbnailFigure 2. A) Ribbon representation of PfFeSOD polypeptide chain with colour ramping from the amino terminus in red to the carboxyl terminus in magenta. The iron is shown as a red sphere and its coordinating residues His26, His73, Asp157 and His161 are shown in cylinder representation. B) The PfFeSOD dimer coloured by subunit with the Fe atoms as mauve spheres and their coordinating residues in cylinder representation. The figures were made using CCP4 mg [39].

Structural comparisons and dimer interface

The tertiary structure is very similar to that of a number of other Fe- or Mn-dependent SOD enzymes. Of particular interest is comparison with the tetrameric MnSOD found in human mitochondria. Subtle differences in the structures may allow the design of inhibitors to block the activity of FeSOD selectively without affecting the MnSOD. The arrangement of the active site residues is well conserved between the Fe and MnSODs; the only significant difference in main chain conformation arises in the loop connecting α1 and α3, which is remote from the active site and the dimer interface.

As is typical of SOD proteins, only a relatively small accessible surface area (9.7 %) becomes buried in the dimer interface. The main contributions to the dimer interface arise from helix α1, the loop that connects α5 to β1 and the loop connecting β3 to α6. 41% of the atoms forming the dimer interface are polar, while 59% are non-polar. There are five bridging water molecules within the dimer interface. There is an interesting pair of adjacent charge-charge interactions between the carboxylates of the Asp140 residues and the side chain imidazoles of His139. Perhaps associated with this, the dihedral angles of residue Asp140 appear in a generously allowed location on the Ramachandran plot. These residues lie on what would be a classical β-turn were it not for the fact that residue 141 is an alanine rather than a glycine. All of the dimer stabilising interactions in the E. coli enzyme are conserved in PfFeSOD. Such high conservation of the dimer interface reflects the importance of dimerisation to the activity of dismutases.

Active site of P. falciparum FeSOD

The metal ion in both subunits of the enzyme is five-coordinate. Three bonds arise from coordination with histidine Nε2 atoms of residues His26 (mean Fe-Nε2 distance 2.2 Å), His73 (2.1 Å) and His161 (2.0 Å). A further bond is between the metal and the Oδ2 atom of Asp157 (mean Fe-Oδ2 distance 1.9 Å). The fifth coordination position is an oxygen atom from either a water molecule or a hydroxide species (mean Fe-O distance 2.1 Å). The coordination geometry is trigonal bipyramidal, with His73, His161 and Asp157 providing the equatorial ligands and with His26 and the hydroxide or water oxygen atom forming the axial ligands.

The area around the active site is fairly hydrophobic with two tryptophan residues (122 and 159) 5.4 Å and 6.1 Å from the metal, respectively. Trp122 forms a hydrogen bond to Gln69, which in turn forms a hydrogen bond with the hydroxyl group of Tyr34. Tyr34 is also hydrogen bonded via a water molecule to His30, which is bonded to Tyr134 from the other subunit. This classical hydrogen-bonding network in superoxide dismutases may allow communication between the two metal sites [13]. In the B chain however, we note that the Gln69 Nδ to Tyr34 -OH distance is longer (3.6 Å), perhaps due to coordinate error at this resolution. The spatial arrangement of the residues in the active site is otherwise identical to those of other Fe-dependent superoxide dismutases whose structures are known, consistent with the notion that structure and mechanism are highly conserved in this enzyme class.

A second line of communication between the active sites is afforded by the intermolecular ionic/hydrogen bonding interaction between the Fe-coordinating His161 and the carboxylate of Glu160. The latter is situated in a loop that links two Fe-coordinating residues (Asp157 and His161) in the opposing subunit. The relevance, if any, of structural communication between the active sites to the kinetics and mechanism of these enzymes is not established.

Modelling of the P. falciparum mitochondrially targeted FeSOD

The sequence of the major FeSOD is highly conserved in different Plasmodia species (see 2) and is encoded by a gene on chromosome 8 (PlasmoDB code PF08_0071 [14]) consisting of a single exon. Another gene product (PfFeSOD2) with significant sequence homology is located on chromosome 6. This PfFeSOD2 gene is interrupted with multiple introns. The original gene model (MAL6P1.194 [14]) was revised by a bioinformatic analysis to maximise primary sequence homology to PfFeSOD, leading to a gene predicted to consist of nine exons, separated by eight introns with consensus splice donor/acceptor sites (see 3). Evidence supporting the model was found by Plasmodium interspecies conservation of the intron-exon structure, which is a good predictor for small exons [15] and subsequently confirmed by cDNA cloning [16]. A striking feature of the PfFeSOD2 gene is that it encodes an N-terminal sequence typical of proteins that are targeted to sub-cellular organelles. The first two exons coincide precisely with elements of the bipartite signal (see 4) namely a signal sequence and a transit peptide. A GFP-fusion with the signal is directed to the mitochondrion, despite predictions from the sequence that it would be delivered to the apicoplast [16]. However, the gene structure not only hints at its evolution by exon shuffling, but provides the opportunity for alternatively spliced forms [17].

thumbnailAdditional File 1. Model of the P. falciparum mitochondrially targeted FeSOD2. Data file PfSOD2_model.pdb.

Format: PDB Size: 256KB Download fileOpen Data

Additional File 2. Sequence alignment of Plasmodia FeSOD sequences. FeSOD is one the most highly conserved proteins across different Plasmodium species [40]. Identical residues are highlighted with a red background and similar residues are boxed. PfFeSOD secondary structure elements are superposed. Codes: Pf, P. falciparum; Pr, P. reichenowi; Po, P. ovalae; Pm, P. malariae; Pv, P. vivax; Pk, P. knowlesi; Py, P. yeolii; Pb, P. berghei; Pc, P. chabaudi; Pg, P. gallinaceum. The figure was made using ESPript [38].

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Additional File 3. Gene model of PfFeSOD2. A region of DNA sequence from P. falciparum chromosome 6 is shown, with predicted introns highlighted in yellow, and the protein product of the exon sequences in red.

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Additional File 4. Sequence alignment of predicted PfFeSOD2 proteins from Plasmodium species. Identical residues are highlighted with a red background and similar residues are boxed. PfFeSOD2 predicted secondary structure elements are superposed and exon boundaries are marked with a triangle. Note that the first two exons coincide with the putative signal sequence and transit peptide. Sequence data were gleaned from PlasmoDB [14]. Although not shown, the incomplete sequence data from P. chabaudi (missing region around exons 4 & 5) and P. gallinaceum (missing region encompassing 6 & 7) also show the same conserved pattern of putative intron boundaries. Codes: Pf, P. falciparum; Pr, P. reichenowi; Pv, P. vivax; Pk, P. knowlesi; Pb, P. berghei; Py, P. yeolii.

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A homology model (see 1) of the mitochondrially targeted PfFeSOD2 was derived using the cytosolic PfFeSOD structure solved here. The cytosolic PfFeSOD is the closest in sequence of any dismutase to the mitochondrial PfFeSOD and hence provides the most suitable coordinate set from which to construct a homology model. The model generated has an rmsΔ on all Cα atoms of 0.36 Å for the 388 matched residues. Unsurprisingly the secondary structure is predicted to be identical to that of the cytosolic FeSOD of Plasmodium. It appears that the active site and dimer interface are also well conserved. This is consistent across the Fe/MnSOD enzyme family, which is a highly conserved enzyme class. It remains to be seen if the two superoxide dismutases from Plasmodium are indeed structurally and biochemically equivalent, or whether the mitochondrially targeted SOD has a different turnover/stability that is required for function within a specific environment in the cell.

Discussion

Superoxide dismutases play a crucial role in the chemical protection strategies many cells adopt to counter the considerable threat posed by the superoxide anion radical. Iron-containing superoxide dismutases are essentially confined to prokaryotes, algae, higher plants and certain protozoa [12]. In contrast, the human superoxide dismutases are either Mn- or Cu/Zn-dependent. Thus, selective inhibitors of FeSODs have potential uses in therapy against diseases caused by pathogens. At first sight it would appear difficult to inhibit PfFeSOD using classical 'active-site directed' approaches. The substrate-binding site is small, it needs to accommodate just two atoms and the design of selective inhibitors may be hampered by the structural similarity that the iron-containing superoxide dismutases share with the manganese-dependent enzymes. Superoxide is attracted to the active site of dismutases through a funnel, which comprises residues from both subunits in the dimer. The funnel lies at the top of the dimer interface near to the metal sites. It is thought that potential inhibitors could bind here and block access to the active site for the superoxide substrate [13].

An alternative approach is to target inhibitors towards the subunit interface so as to disrupt the quaternary structure. A possible explanation of the widely accepted "ping-pong" kinetics observed for FeSODs would be if superoxide binding in one active site is accompanied by oxidation to oxygen in the other, with the iron atoms in the respective subunits maintaining opposing oxidation states as they alternate between the +2 and +3 forms. If so, dimerisation would likely be important to the mechanism of FeSOD, and monomeric FeSODs are not found in Nature [13]. However, evidence from Cu/ZnSODs suggests that monomeric forms are active which may mean that dimerisation is not crucial for the function of all superoxide dismutases [18]. Despite this, it is clear that the dimer interface in Fe and MnSODs is important in the SOD reaction with dimer interface mutants of human MnSOD exhibiting reduced steady-state catalytic constants [19,20]. Other evidence points to the importance of dimerisation for functional SOD activity, as dimer destabilising mutations of Cu/Zn SOD have been linked to motor neuron disease [21]. Although the mechanism is unclear, the destabilised mutants may be more prone to aggregation, which is commonly associated with the disease.

There are a number of significant differences between the dimer interfaces in PfFeSOD and HuMnSOD that may be exploited in the design of parasite selective inhibitors. Residue Phe118, which contributes 15 % of the accessible surface area buried in the interface in PfFeSOD is replaced with glutamine in the human enzyme. The intermolecular polar/salt-bridging residue pair of His139 and Asp140 in PfFeSOD is substituted by Cys and Pro, respectively in HuMnSOD, similarly the Glu21-Arg168 ion pair in PfFeSOD appears as Ala and Lys respectively in the human enzyme. These differences ought to be exploitable in the selective design of dimer-disrupting mutants.

Inhibitors of PfFeSOD have already been identified from a random screening of a chemical library of compounds [12]. A subset of these uncharged polyaromatic compounds, with molecular weights in the range 200–700 Da, have in vitro anti-malarial activity, with IC50 values in the micromolar range. Their mechanism of action and their selectivity was not determined so it remains to be seen whether they interfere with dimer formation. A number of small molecule inhibitors of protein-protein interactions with biomedical significance have been reported recently [22]. For Trypanosoma cruzi, a parasite-selective inhibitor of triosephosphate isomerase has been identified and shown to act by blocking dimerisation [23], so it appears that the strategy could be useful, particularly as the percentage of accessible protein surface that becomes buried in a SOD dimer is at the lower limit of the range normally seen in protein multimers in Nature.

Conclusion

The X-ray structure of P. falciparum SOD provides the detailed template on which comparisons with human enzyme can be made, and for the design of potential parasite-specific inhibitors. In particular, the biochemical properties of the SOD enzyme (and differences to the human SOD protein) suggest that a possible mode of inhibition would be to disrupt the dimer interface that may be important to its function and stability. The intra-erythocytic stages of the parasite are in an environment that is known to be rich in antioxidant defences (both chemical and enzymatic) that might compensate an inhibitory effect. However, the selective delivery of inhibitors to the parasite organellar system may prove to be a useful route to new therapeutics.

Methods

Cloning and expression of P. falciparum FeSOD

The cytosolic FeSOD coding sequence was amplified from P. falciparum (3D7) genomic DNA using Vent™ polymerase (New England Biolabs) and the oligonucleotide primers:

5'-CATGCCATGGTTATTACATTGCCCAAATTAAAG-3'

5'-CCGCTCGAGCTTTTGCATAGCTTTTTTTAAGTT-3'.

The 597 base pair PCR product was digested with NcoI and XhoI and ligated to similarly cut pET28a (Novagen). This places the coding sequence for PfFeSOD upstream of that for a non-cleavable, C-terminal His6 tag. The expected expression product therefore comprises residues 1–198 of PfFeSOD with a C-terminal LEHHHHHH tag. The ligation products were introduced into competent E. coli NovaBlue™ cells (Novagen). Kanamycin-resistant transformants harbouring pET28-PfFeSOD were identified and isolated. Plasmid DNA from these cells was purified and subsequently introduced into the expression strain E. coli BL21-CodonPlus (Stratagene). An overnight culture of E. coli BL21/pET28-PfFeSOD was used to inoculate 1 litre of Luria-Bertani medium supplemented with 30μg ml-1 kanamycin and cells were grown with shaking at 37°C to an OD600 of 0.6 at which point expression of recombinant protein was induced by the addition of isopropyl-β, D-thiogalactopyranoside to a final concentration of 1 mM. After a further 4 hours incubation at 30°C, cells were harvested by centrifugation.

Purification, characterisation and crystallisation

The harvested cell pellet was resuspended in 50 mM Tris-HCl buffer pH 7.5 containing 300 mM NaCl (Buffer A). The cells were lysed by sonication and clarified by centrifugation. The supernatant was mixed with 2 ml Ni-NTA agarose resin (Qiagen) at 4°C for 1 hour with gentle shaking. The resin was then washed with Buffer A containing 20 mM imidazole and protein was eluted with Buffer A containing 100 mM imidazole. Fractions were examined by Coomassie staining following SDS-polyacrylamide gel electrophoresis and those containing proteins of approximately 23 kDa corresponding to FeSOD were pooled and further fractionated by size exclusion chromatography on a Superdex 75 (Pharmacia) column run in 50 mM Tris-HCl pH 7.5 containing 100 mM NaCl. Typically 10 – 15 mg of protein was obtained per litre of cell culture.

Sedimentation equilibrium experiments were conducted on a Beckman Optima XL/I analytical ultracentrifuge, in an AN-50Ti rotor. The buffer density (300 mM NaCl, 50 mM Tris-HCl, pH 7.5) and the partial specific volume of the protein were estimated to be 1.012 g.ml-1 and 0.7302 respectively, using the program SEDNTERP [24]. Protein homogeneity was examined on an 8.75 % native polyacrylamide gel. Enzyme activity was confirmed using a gel-based Nitro blue tetrazolium assay [25].

Crystallisation experiments were carried out by the hanging-drop vapour-diffusion method. Drops contained a 1:1 volume ratio of PfSOD at 10 mg ml-1 in 50 mM Tris-HCl pH 7.5, 100 mM NaCl and a range of precipitants. Rod shaped crystals appeared within a week at 18°C from reservoir solutions that contained 0.1 M Tris-HCl pH 7.5 and 30–40% (w/v) polyethylene glycol (PEG) 600.

Data collection

Crystals were mounted in a fine rayon loop and transferred into a solution containing 0.1 M Tris-HCl (pH 7.5) and 40 % PEG 600 which acts as a cryoprotectant. They were then flash-cooled in liquid nitrogen. Preliminary in-house X-ray analysis of these crystals showed that they belong to the space group P212121 with unit cell dimensions a = 55.5 Å, b = 78.4 Å, c = 89.3 Å. A complete X-ray diffraction data set was collected at 100 K, using synchrotron radiation at a wavelength of 0.976 Å, on beamline ID-29 at the ESRF, Grenoble, using an ADSC Quantum4 CCD detector. The data were processed using the programs DENZO and SCALEPACK [26].

Structure determination and refinement

Calculations were performed using the CCP4 suite of programs [27]. Molecular replacement was performed with AMoRe [28] and refinement conducted with REFMAC [29]. The structure was determined by the molecular replacement method using the Escherichia coli FeSOD coordinate set (PDB entry code 1ISC) as a search model. EcSOD and PfSOD share 51% sequence identity. Molecular replacement calculations produced two clear solutions related by a non-crystallographic 2-fold symmetry axis, and giving an R-factor of 40.4 % after rigid body refinement. Model building was performed using the X-AUTOFIT routines [30] implemented in the molecular graphics programme QUANTA (Accelrys, San Diego). During refinement, tight non-crystallographic symmetry restraints were imposed on the main chain atoms and medium restraints on the side chains of the two molecules in the dimer.

Modelling the targeted SOD

A homology model of the mitochondrial FeSOD (PfFeSOD2) was generated on the basis of 52% sequence identity over 188 residues to the known structure of the cytosolic PfFeSOD. All structural visualisation/manipulation was performed using QUANTA. The sequences of PfFeSOD2 and the PfFeSOD template structure were aligned using CLUSTALX [31], and manually corrected for certain regions, based on interrogation of the known structure.

Homology modelling was performed using MODELLER6 [32]. Ten initial models were generated, and the model with the lowest objective function chosen as the representative PfFeSOD2 structure. After manual checking of backbone and side chain positions, energy minimization was performed using CHARMM [33,34] to relax steric clashes within the model. Stereochemical evaluation was then performed using PROCHECK [35]. The model possesses good stereochemical quality, with 88.4 % of residues in the most favoured regions of the Ramachandran map, and 10.4 % in additional allowed regions. There are four residues in generously allowed or unfavourable regions, which accurately reflect those in the template structure.

Authors' contributions

JAB and IB conceived the study and together with AJW, who coordinated the project, drafted the manuscript; SK provided genomic DNA and advice on cloning; IB expressed the protein with JAB and purified the protein together with CS; IB carried out the crystallographic analysis under the guidance of AMB; DJS carried out the homology modelling work. All authors have approved the final manuscript.

thumbnailFigure 3. The active site from one subunit of the FeSOD dimer. The metal is shown as a grey sphere and the water molecule that acts as an axial ligand to the metal is coloured red. The 2Fo-Fc electron density map, contoured at the one sigma level, is represented as a mesh.

Acknowledgements

This work was funded by the Wellcome Trust (Malaria Functional Genomics Initiative, grant no. 066742/F/01/Z). I.W.B. was funded by a BBSRC PhD studentship. The authors wish to thank Andrew Leech (University of York) for AUC analysis, Matt Berriman (Sanger Centre) for bioinformatic insights, and the ESRF, Grenoble for providing excellent data collection facilities.

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