The crystal structure of an eukaryotic iron superoxide dismutase suggests intersubunit cooperation during catalysis

Superoxide dismutases (SODs) are a family of metalloenzymes that catalyze the dismutation of superoxide anion radicals into molecular oxygen and hydrogen peroxide. Iron superoxide dismutases (FeSODs) are only expressed in some prokaryotes and plants. A new and highly active FeSOD with an unusual subcellular localization has recently been isolated from the plant Vigna unguiculata (cowpea). This protein functions as a homodimer and, in contrast to the other members of the SOD family, is localized to the cytosol. The crystal structure of the recombinant enzyme has been solved and the model refined to 1.97 A resolution. The superoxide anion binding site is located in a cleft close to the dimer interface. The coordination geometry of the Fe site is a distorted trigonal bipyramidal arrangement, whose axial ligands are His43 and a solvent molecule, and whose in-plane ligands are His95, Asp195, and His199. A comparison of the structural features of cowpea FeSOD with those of homologous SODs reveals subtle differences in regard to the metal-protein interactions, and confirms the existence of two regions that may control the traffic of substrate and product: one located near the Fe binding site, and another in the dimer interface. The evolutionary conservation of reciprocal interactions of both monomers in neighboring active sites suggests possible subunit cooperation during catalysis.     

Characterization of the product-inhibited complex in catalysis by human manganese superoxide dismutase.

The reduction with excess H(2)O(2) of human Mn(III) superoxide dismutase (SOD) and the active-site mutant Y34F Mn(III)SOD was measured by scanning stopped-flow spectrophotometry and revealed the presence of an intermediate in the reduction of the manganese. The visible absorption spectrum of this intermediate closely resembled that of the enzyme in the inhibited, zero-order phase of the catalyzed disproportionation of superoxide. The decay of the visible spectrum of this intermediate was 2-fold faster for the wild-type compared with the mutant Y34F Mn-SOD. This correlates with the enhanced product inhibition of Y34F during the catalysis of O-(2) dismutation. The visible spectrum of the product-inhibited complex resembles that of the azide-Mn-SOD complex, suggesting that the inhibited complex has expanded geometry about the metal to octahedral. This study shows that the inhibited complex responsible for the zero-order phase in the catalysis by Mn-SOD of superoxide dismutation can be reached through both the forward (O-(2)) and reverse (H(2)O(2)) reactions, supporting a mechanism in which the zero-order phase results from product inhibition.     

Role of tryptophan 161 in catalysis by human manganese superoxide dismutase.

Tryptophan 161 is a highly conserved residue that forms a hydrophobic side of the active site cavity of manganese superoxide dismutase (MnSOD), with its indole ring adjacent to and about 5 A from the manganese. We have made a mutant containing the conservative replacement Trp 161 --> Phe in human MnSOD (W161F MnSOD), determined its crystal structure, and measured the catalysis of the resulting mutant using pulse radiolysis to produce O(2)(*)(-). In the structure of W161F MnSOD the phenyl side chain of Phe 161 superimposes on the indole ring of Trp 161 in the wild type. However, in the mutant, the hydroxyl side chain of Tyr 34 is 3.9 A from the manganese, closer by 1.2 A than in the wild type. The tryptophan in MnSOD is not essential for the half-cycle of catalytic activity involving reduction of the manganese; the mutant W161F MnSOD had k(cat)/K(m) at 2.5 x 10(8) M(-)(1) s(-)(1), reduced only 3-fold compared with wild type. However, this mutant exhibited a strong product inhibition with a zero-order region of superoxide decay slower by 10-fold compared with wild type. The visible absorption spectrum of W161F MnSOD in the inhibited state was very similar to that observed for the inhibited wild-type enzyme. The appearance of the inhibited form required reaction of 2 molar equiv of O(2)(*)(-) with W161F Mn(III)SOD, one to form the reduced state of the metal and the second to form the inhibited complex, confirming that the inhibited complex requires reaction of O(2)(*)(-) with the reduced form of the enzyme. This work suggests that a significant role of Trp 161 in the active site is to promote the dissociation of product peroxide, perhaps in part through its effect on the orientation of Tyr 34.     

The iron content of iron superoxide dismutase: determination by anomalous scattering

The number of iron atoms in the dimeric iron-containing superoxide dismutase from Pseudomonas ovalis and their atomic positions have been determined directly from anomalous scattering measurements on crystals of the native enzyme. To resolve the long-standing question of the total amount of iron per molecule for this class of dismutase, the occupancy of each site was refined against the measured Bijvoet differences. The enzyme is a symmetrical dimer with one iron site in each subunit. The iron position is 9 A from the intersubunit interface. The total iron content of the dimer is 1.2 +/- 0.2 moles per mole of protein. This is divided between the subunits in the ratio 0.65:0.55; the difference between them is probably not significant. Since each subunit contains, on average, slightly more than half an iron atom we conclude that the normal state of this enzyme is two iron atoms per dimer but that some of the metal is lost during purification of the protein. Although the crystals are obviously a mixture of holo- and apo-enzymes, the 2.9 A electron density map is uniformly clean, even at the iron site. We conclude that the three-dimensional structures of the iron-bound enzyme and the apo-enzyme are identical.     

Purification and characterization of iron superoxide dismutase and copper-zinc superoxide dismutase from Acanthamoeba castellanii

Two superoxide dismutases (SOD I and SOD II) were purified from Acanthamoeba castellanii and characterized for several biochemical properties. Analysis of the primary structure and inhibition studies revealed that SOD I is iron SOD (Fe-SOD), with a molecular mass of 50 kDa, and SOD II is copper-zinc SOD (Cu,Zn-SOD), with a molecular mass of 38 kDa. Both enzymes have a homodimeric structure consisting of 2 identical subunits, each with a molecular mass of 26 and 19 kDa for SOD I and SOD II, respectively. The isoelectric points of SOD I and SOD II were 6.4 and 3.5, respectively, and there were no isoenzyme forms detected. Both enzymes show a broad optimal pH of 7.0-11.0. Because no differences were observed in the apparent molecular weight of SOD I after addition of the reducing agent 2-mercaptoethanol, the subunits do not appear to be linked covalently by disulfide bonds. However, the subunits of SOD II were covalently linked by intra- and interdisulfide bonds. Western blot analyses showed that the 2 enzymes have different antigenicity. Both enzymes occur as cytoplasmic and detergent-extractable fractions. These enzymes may be potential virulence factors of A. castellanii by acting both as antioxidants and antiinflammatory agents. These enzymes may be attractive targets for chemotherapy and immunodiagnosis of acanthamoebiasis.     

A tetrameric iron superoxide dismutase from the eucaryote Tetrahymena pyriformis

An iron-containing superoxide dismutase has been purified from the protozoan Tetrahymena pyriformis. It has a molecular weight of 85,000 and is composed of four subunits of equal size. The tetramer contains 2.5 g atoms of ferric iron. Visible absorption and electron spin resonance spectra closely resemble those of other iron-containing superoxide dismutases. The amino acid sequence of the iron superoxide dismutase was determined. Each subunit is made up of 196 residues, corresponding to a molecular weight of 22,711. Comparison of the primary structure with the known sequences of other iron-containing superoxide dismutases reveals a relatively low degree of identity (33-34%). However, a higher percentage identity is found with mammalian manganese-containing superoxide dismutases (41-42%). The amino acid sequence is discussed in consideration of residues that may distinguish iron from manganese or dimeric from tetrameric superoxide dismutases.     

Induction of the manganese-containing superoxide dismutase in Escherichia coli by nalidixic acid and by iron chelators

Abstract Nalidixic acid caused a significant increase in the Mn-containing superoxide dismutase (MnSOD) of Escherichia coli . The maximum stimulatory effect of nalidixic acid on MnSOD biosynthesis was observed at 0.1 mM. The stimulatory effect of nalidixic acid was not due to increases in the intracellular flux of O⁻₂, but rather to its ability to chelate Fe²⁺. Furthermore, 2,2'-dipyridyl and 1,10-phenanthroline were shown to cause a 7- to 20-fold increase in the MnSOD of E. coli . It is proposed that the repressor for MnSOD is an iron-containing protein.     

Manganese superoxide dismutase induction by iron is impaired in Friedreich ataxia cells.

Iron-mediated oxidative stress has been implicated in the pathology of the neurodegenerative disease Friedreich ataxia (FRDA). Here, we show that normal upregulation of the stress defense protein manganese superoxide dismutase (MnSOD) fails to occur in FRDA fibroblasts exposed to iron. This impaired induction was observed at iron levels in which increased activation of the redox-sensitive factor NF-kappaB was absent. Furthermore, MnSOD induction could only be partially suppressed by antioxidants. We conclude that an NF-kappaB-independent pathway that may not require free radical signaling is responsible for the reduction of MnSOD induction. This impairment could constitute both a novel defense mechanism against iron-mediated oxidative stress in cells with mitochondrial iron overload and conversely, an alternative source of free radicals that could contribute to the disease pathology.     

Buffer enhancement of proton transfer in catalysis by human carbonic anhydrase III

Among the isozymes of carbonic anhydrase, isozyme III is the least efficient in the catalysis of the hydration of CO2 and was previously thought to be unaffected by proton transfer from buffers to the active site. We report that buffers of small size, especially imidazole, increase the rate of catalysis by human carbonic anhydrase III (HCA III) of (1) 18O exchange between HCO3- and water measured by membrane-inlet mass spectrometry and (2) the dehydration of HCO3- measured by stopped-flow spectrophotometry. Imidazole enhanced the rate of release of 18O-labeled water from the active site of wild-type carbonic anhydrase III and caused a much greater enhancement, up to 20-fold, for the K64H, R67H, and R67N mutants of this isozyme. Imidazole had no effect on the rate of interconversion of CO2 and HCO3- at chemical equilibrium. Steady-state measurements showed that the addition of imidazole resulted in increases in the turnover number (kcat) for the hydration of CO2 catalyzed by HCA III and for the dehydration of HCO3- catalyzed by R67N HCA III. These results are consistent with the transfer of a proton from the imidazolium cation to the zinc-bound hydroxide at the active site, a step required to regenerate the active form of enzyme in the catalytic cycle. Like isozyme II of carbonic anhydrase, isozyme III can be enhanced in catalytic rate by the presence of small molecule buffers in solution.     

Identification of excreted iron superoxide dismutase for the diagnosis of Phtytomonas

An excreted iron superoxide dismutase (FeSODe) of pI 3.6 with a molecular weight of 28-30 kDa was detected in the in vitro culture of Phytomonas isolated from Euphorbia characias (SODeCHA) and from Lycopersicon esculentum (SODeTOM), in Grace's medium without serum. These FeSODe excreted into the medium had immunogenic capacity: the positivity of the anti-SODeCHA serum persisted to a dilution of 1/30,000, and for the anti-SODeTOM to 1/10,000 by Western blot. In addition, cross reaction was detected between the anti-SODe serum of Phytomonas isolated from E. characias against SODeTOM, and the anti-SODe serum from L. esculentum with SODeCHA. This characteristic offers the possibility of its use to diagnose plant trypanosomatids. The validation of the test was confirmed by experimental inoculation of tomato fruits with Phytomonas isolated from L. esculentum. At 7, 10, 15, and 21 days post infection, it was possible to detect the presence of the parasites with the anti-SODe serum of Phytomonas isolated from L. esculentum at a dilution of 1/250. These serological results were confirmed by visualization of the parasites by optical microscopy. The data of this study confirm that the SOD is sufficient to identify a trypanosomatid isolated from plants as belonging to the genus Phytomonas.     

Phytomonas iron superoxide dismutase: a possible molecular marker

We have isolated and biochemically characterized two iron superoxide dismutases activities (SODI and SODII) from a plant trypanosomatid isolated from Euphorbia characias. The isoenzyme FeSODII has immunogenic capacity, and the positivity of the anti-SODII serum persists to a dilution of 1/40,000, by Western blot. In addition, Western blot has been used to test the positivity of the anti-SODII serum against antigen fractions (SOD) from 17 isolates belonging to the family Trypanosomatidae and for which we had previously determined the isoenzymatic profile. The reaction proved positive only with those plant isolates considered to belong to the genus Phytomonas, whereas there was no reaction of the anti-SODII serum, against the antigen fractions from the species Trypanosoma cruzi, Leishmania donovani, Herpetomonas samuelpessoai, Herpetomonas davidi, Crithidia luciliae and Leptomonas collosoma. FeSODII is located mainly over the entire surface of the parasite, as well as in the nucleus, glycosomes and membranes. The above makes FeSODII promising as a molecular tool for diagnosis and identification, and as a potential chemotherapeutic target for designing drugs aimed at controlling not only of the diseases caused by Phytomonas species, but also for the great metabolic similarity to other trypanosomatids of animals and humans, it may be possible for these results to be extrapolated. Moreover, the sequencing of the amino-terminal end of the FeSODII enables the design of primers that in the near future will make it possible to sequence the gene of this isoenzyme.     

Effect of iron on expression of superoxide dismutase by Aeromonas salmonicida and associated resistance to superoxide anion

Abstract Superoxide dismutase activity was detected in Aeromonas salmonicida under iron-replete and iron-limited culture conditions. Under iron-replete conditions an iron superoxide dismutase, molecular mass 50,400 Da, was identified based on inhibition by hydrogen peroxide but not by millimolar concentrations of cyanide. When the available iron in the culture medium was limited by addition of the non-assimilable iron chelator 2,2-dipyridyl, a manganese superoxide dismutase, molecular mass 45,600 Da, was identified, which was resistant to inhibition by either hydrogen peroxide or cyanide. The change in enzyme production would appear to be iron dependent, as addition of FeCl₃ in excess to iron-limited broths resulted in only the iron superoxide dismutase being synthesised. Examination of the location of the superoxide dismutase enzymes revealed that the manganese superoxide dismutase expressed under iron limitation is located in the periplasm, while the iron superoxide dismutase has a cytoplasmic location. The periplasmic manganese superoxide dismutase was able to protect A. salmonicida against extracellular riboflavin-generated superoxide, with A. salmonicida grown under iron-limited conditions exhibiting a 32-fold increase in minimum bactericidal concentration of riboflavin compared to cells cultured under iron-replete conditions. Furthermore, in a time-course study of bactericidal activity of exogenously generated superoxide against A. salmonicida , bacteria grown under iron-replete conditions and expressing cytoplasmic iron superoxide dismutase were rapidly killed, whilst those grown under iron limitation expressing periplasmic manganese superoxide dismutase survived for the duration of the experiment.     

Activation of superoxide dismutase molecules under the effect of ultraviolet radiation]

The effect of UV light (240-390 nm) with dose range 1.51-30.2 x 10(2) J/m2 on the functional properties of superoxide dismutase was investigated at various pH values. Photoactivation was shown to be maximum at pH values extreme for the display of superoxide dismutase activity.     

Glutathionylation of the iron superoxide dismutase from the psychrophilic eubacterium Pseudoalteromonas haloplanktis

Our previous work showed that the adduct between beta-mercaptoethanol and the single cysteine residue (Cys57) in superoxide dismutase from the psychrophilic eubacterium Pseudoalteromonas haloplanktis (PhSOD) reduces the enzyme inactivation by peroxynitrite. In this work, immunoblotting experiments prove that peroxynitrite inactivation of PhSOD involves formation of nitrotyrosine residue(s). In order to study the role of Cys57 as a redox-sensor residue modifiable by cellular thiols, a recombinant PhSOD and two Cys57 mutants were produced and characterized. Recombinant and mutant enzymes share similar activity and peroxynitrite inactivation, but different reactivity towards three glutathione forms. Indeed, oxidized glutathione and S-nitrosoglutathione, but reduced glutathione, lead to S-glutathionylation of recombinant PhSOD. This new covalent modification for a Fe-SOD does not occur in both Cys57 mutants, thus indicating that its target is Cys57. Moreover, mass spectrometry analysis confirmed that S-glutathionylation of Cys57 takes place also with endogenous PhSOD. Formation of this mixed disulfide in PhSOD protects the enzyme from tyrosine nitration and peroxynitrite inactivation. PhSOD undergoes S-glutathionylation during its overproduction in E. coli cells and in a growing culture of P. haloplanktis. In both cases the extent of glutathionylated PhSOD is enhanced upon cell exposure to oxidative agents. We suggest that S-glutathionylation of PhSOD could represent a further cold-adaptation strategy to improve the antioxidant cellular defence mechanism.     

Biological protection by superoxide dismutase

Diol dehydrase from $\text{Aerobacter aerogenes}$ was dissociated into two different protein components or subunits, designated Components F and S, by chromatography on DEAE-cellulose. Neither component alone possessed any appreciable catalytic activity. Diol dehydrase activity was restored when the two components were combined. Both components were also required for inactivation of coenzyme B₁₂ by oxygen when incubation was carried out in the absence of substrate aerobically. The more acidic component, Component S, was a sulfhydryl protein sensitive to an alkylating agent, iodoacetamide. Coenzyme B₁₂ was not bound by the individual components, F or S, both of which were necessary for the cobamide binding. The presence of substrate, 1,2-propanediol, in eluting buffer retarded the dissociation of the enzyme.