Heterodimeric structure of superoxide dismutase in complex with its metallochaperone

The copper chaperone for superoxide dismutase (CCS) activates the eukaryotic antioxidant enzyme copper, zinc superoxide dismutase (SOD1). The 2.9 A resolution structure of yeast SOD1 complexed with yeast CCS (yCCS) reveals that SOD1 interacts with its metallochaperone to form a complex comprising one monomer of each protein. The heterodimer interface is remarkably similar to the SOD1 and yCCS homodimer interfaces. Striking conformational rearrangements are observed in both the chaperone and target enzyme upon complex formation, and the functionally essential C-terminal domain of yCCS is well positioned to play a key role in the metal ion transfer mechanism. This domain is linked to SOD1 by an intermolecular disulfide bond that may facilitate or regulate copper delivery.     

Molecular Dynamics Simulation of Substrate-Enzyme Interactions in the Active Site Channel of Superoxide Dismutase

Abstract

Molecular dynamics simulations of the diffusion of superoxide ion down the active site channel of the enzyme superoxide dismutase were performed with a parallelized version of GROMOS on the Intel iPSC/860. Our model consisted of a spherical assembly of 6968 atoms centered at a copper ion in the enzyme. Trajectory analysis revealed that the anion is directed toward the copper ion through the cooperative motions of several active site residues. Other mechanistic and structural motifs recurring through five full trajectories are examined. In addition to these qualitative results, an upper bound has been calculated for the rate constant for displacement by substrate of the water molecule that is coordinated to the copper. This required an analysis of the dynamics of crossing a free energy barrier that has been characterized in previous work. Strong frictional effects due to Coulombic interactions lead to a rather small rate constant; the transmission coefficient is less than 0.01. The mechanism of the enzyme therefore may involve diffusion of substrate up to the bound water followed by electron transfer mediated by this water, rather than displacement of the water by substrate with subsequent electron transfer.     

Mechanism of Cu,Zn-superoxide dismutase activation by the human metallochaperone hCCS

The mechanism for copper loading of the antioxidant enzyme copper, zinc superoxide dismutase (SOD1) by its partner metallochaperone protein is not well understood. Here we show the human copper chaperone for Cu,Zn-SOD1 (hCCS) activates either human or yeast enzymes in vitro by direct protein to protein transfer of the copper cofactor. Interestingly, when denatured with organic solvents, the apo-form of human SOD1 cannot be reactivated by added copper ion alone, suggesting an additional function of hCCS such as facilitation of an active folded state of the enzyme. While hCCS can bind several copper ions, metal binding studies in the presence of excess copper scavengers that mimic the intracellular chelation capacity indicate a limiting stoichiometry of one copper and one zinc per hCCS monomer. This protein is active and unlike the yeast protein, is a homodimer regardless of copper occupancy. Matrix-assisted laser desorption ionization-mass spectrometry and metal binding studies suggest that Cu(I) is bound by residues from the first and third domains and no bound copper is detected for the second domain of hCCS in either the full-length or truncated forms of the protein. Copper-induced conformational changes in the essential C-terminal peptide of hCCS are consistent with a "pivot, insert, and release" mechanism that is similar to one proposed for the well characterized metal handling enzyme, mercuric ion reductase.     

Structural Evidence for a Copper-Bound Carbonate Intermediate in the Peroxidase and Dismutase Activities of Superoxide Dismutase

Copper-zinc superoxide dismutase (SOD) is of fundamental importance to our understanding of oxidative damage. Its primary function is catalysing the dismutation of superoxide to O₂ and H₂O₂. SOD also reacts with H₂O₂, leading to the formation of a strong copper-bound oxidant species that can either inactivate the enzyme or oxidise other substrates. In the presence of bicarbonate (or CO₂) and H₂O₂, this peroxidase activity is enhanced and produces the carbonate radical. This freely diffusible reactive oxygen species is proposed as the agent for oxidation of large substrates that are too bulky to enter the active site. Here, we provide direct structural evidence, from a 2.15 Å resolution crystal structure, of (bi)carbonate captured at the active site of reduced SOD, consistent with the view that a bound carbonate intermediate could be formed, producing a diffusible carbonate radical upon reoxidation of copper. The bound carbonate blocks direct access of substrates to Cu(I), suggesting that an adjunct to the accepted mechanism of SOD catalysed dismutation of superoxide operates, with Cu(I) oxidation by superoxide being driven via a proton-coupled electron transfer mechanism involving the bound carbonate rather than the solvent. Carbonate is captured in a different site when SOD is oxidised, being located in the active site channel adjacent to the catalytically important Arg143. This is the probable route of diffusion from the active site following reoxidation of the copper. In this position, the carbonate is poised for re-entry into the active site and binding to the reduced copper.     

1H and 31P NMR studies of the binding of low-affinity anions to Cu,Zn superoxide dismutase

Anions that do not coordinate to the catalytically active copper ion of Cu,Zn superoxide dismutase, but still affect the activity of the enzyme by weaker interactions with the protein moiety surrounding the active site (low affinity anions), uniformly perturbed the 1H NMR line of the NH group of the copper ligand His 46. This effect was detected on the enzyme having Co(II) substituted for the native Zn(II), in which the resonances of residues bound to the copper are detected because of the antiferromagnetic coupling between Cu(II) and Co(II). The interaction with the enzyme of phosphate, a good representative of low-affinity anions, was also studied by 31P NMR of the native enzyme and of enzyme samples covalently modified at all lysines or at the Arg 141, which is 5 A away from the copper. The results obtained indicate that Arg 141 is a likely candidate for binding of low-affinity anions in the vicinity of the copper and that the 1H NMR line of His 46 NH is diagnostic for such an interaction.     

Electron transfer facilitated by superoxide dismutase: a model for membrane redox systems?

Membranes, which are an amalgam of proteins and lipids, effect electron transfer through largely unknown mechanisms. Using albumin with bound fatty acids as a model, we have investigated the possible role of these two membrane constituents in electron transfer. In the presence of albumin: fatty acid, there is substantial enhancement of the reduction of ferricytochrome C by ferrous iron. To assess the possible role of free superoxide in cytochrome C reduction, we added mammalian copper/zinc containing superoxide dismutase (Cu/Zn SOD), which catalyzes the transfer of electrons between superoxide anion radicals, forming oxygen and hydrogen peroxide. Surprisingly, in the presence of either albumin or fatty acid free albumin, Cu/Zn SOD actually accelerates electron transfer from ferrous iron to ferricytochrome C. By contrast, neither inactive Cu/Zn SOD nor active manganese SOD facilitates the ferrous iron-dependent reduction of cytochrome C. These results suggest that, in some circumstances, Cu/Zn SOD may transfer electrons to alternative acceptors and that such transfer depends upon the unique reduction/oxidation reaction mechanism of Cu/Zn SOD. If so, this ubiquitous enzyme could be involved in regulating cellular electron transfer reactions as well as acting as a superoxide 'detoxify-ing' agent.     

Unique features of the sodC-encoded superoxide dismutase from Mycobacterium tuberculosis, a fully functional copper-containing enzyme lacking zinc in the active site

The sodC-encoded Mycobacterium tuberculosis superoxide dismutase (SOD) shows high sequence homology to other members of the copper/zinc-containing SOD family. Its three-dimensional structure is reported here, solved by x-ray crystallography at 1.63-A resolution. Metal analyses of the recombinant protein indicate that the native form of the enzyme lacks the zinc ion, which has a very important structural and functional role in all other known enzymes of this class. The absence of zinc within the active site is due to significant rearrangements in the zinc subloop, including deletion or mutation of the metal ligands His115 and His123. Nonetheless, the enzyme has a catalytic rate close to the diffusion limit; and unlike all other copper/zinc-containing SODs devoid of zinc, the geometry of the copper site is pH-independent. The protein shows a novel dimer interface characterized by a long and rigid loop, which confers structural stability to the enzyme. As the survival of bacterial pathogens within their host critically depends on their ability to recruit zinc in highly competitive environments, we propose that the observed structural rearrangements are required to build up a zinc-independent but fully active and stable copper-containing SOD.     

The effects of pH and various salts upon the activity of a series of superoxide dismutases.

The CuZn superoxide dismutases (SODs) from ox, sheep, pig and yeast were investigated by pulse radiolysis in order to evaluate the role of electrostatic interactions between O2.- and SOD proteins in the mechanism of action of the SOD enzymes. The protein net charge in this series varies, as evaluated by the protein pI values spanning over a large range of pH: 8.0 (sheep), 6.5 (pig), 5.2 (ox) and 4.6 (yeast). The amino acid sequences are largely conserved, with the three mammalian proteins being highly homologous and the yeast protein having some distinct variations in the region surrounding the active site. At pH 8.0 the activities of the SODs from various sources are similar, though the minor differences observed suggest that in the highly homologous mammalian series the most acidic protein is the most enzymically efficient one. The pH-dependences of the various activities in the pH range 7-12 are similar, and the related curves are best fitted by two pK values, which are approx. 9.2 and 11.0 for the mammalian enzymes and 9.1 and 11.4 for the yeast enzyme. The activities of the proteins at I 0.1 are decreased by approx. 20% when compared with the activity at I 0.02 at pH 8.5, whereas at pH above 10 the pH-dependence of the activity approaches that determined at I 0.02 and at pH 11.9 the activity is essentially independent of ionic strength. The dependence upon ionic strength also depends on the salt used, with perchlorate being more effective than phosphate or borate or Mops and still effective at pH above 10.5, where the effect of other salts becomes negligible. The dual and concerted dependence of the activities of different SODs on pH and salt concentration is explained with the encounter of O2.- with the active-site copper being governed by the protonation of two positively charged groups in the vicinity of the active site. The gradient between these localized charges and the rest of the protein may explain the different activities of the mammalian proteins at lower pH. On the basis of the sequence variation of the SODs examined it is not possible to definitely identify these groups. Likely candidates are conserved basic amino acid side chains in the vicinity (less than or equal to 1.2 nm) of the active site, i.e. Lys-134 and Arg-141, but co-ordination of OH- in the first copper co-ordination sphere may be an additional factor accounting for the higher pK.(ABSTRACT TRUNCATED AT 400 WORDS)     

The mechanism of superoxide dismutase functioning: a multicenter model

A new model of superoxide dismutase (SOD) functioning has been proposed on the basis of recent data. This model takes into account both experimental data and results of quantum mechanics calculations. One substrate molecule (superoxide radical) binds copper ion in active center of SOD, and the second superoxide radical interacts with a peripheral region of the enzyme. Uncoupled electron from the active center is transferred to the peripheral superoxide anion. This results in formation of oxygen molecule in the active center, and of hydrogen peroxide molecule in the peripheral region.     

Phosphate is an inhibitor of copper-zinc superoxide dismutase

The superoxide dismutase (SOD) activity of bovine copper-zinc superoxide dismutase (Cu,Zn-SOD) in 50 mM Hepes [4-(2-hydroxyethyl)-1- piperazineethanesulfonic acid], pH 7.4, was decreased by approximately 50% when the solution was made 10 mM in phosphate, in spite of the fact that the ionic strength of both solutions was adjusted to be equal. A similar experiment was carried out with bovine Cu,Zn-SOD chemically modified at Arg-141 with phenylglyoxal, which consequently had approximately 20% of the activity of the unmodified protein. (This activity was shown not to be due to residual unmodified protein.) Addition of 10 mM phosphate to solutions of the modified protein caused only a small decrease (less than 5%) in the SOD activity. The presence of phosphate also caused the affinity of Cu,Zn-SOD for binding azide or cyanide anions to be reduced; this effect of phosphate was also much less for the arginine-modified protein. We conclude that the inhibitory effect of phosphate on bovine Cu,Zn-SOD is due primarily to the neutralization of the positive charge on the side chain of Arg-141. The effect of increasing ionic strength on the activities of the native and arginine-modified proteins was also investigated. We found that at high concentrations of phosphate (greater than or equal to 10 mM), the SOD activities of native and arginine-modified Cu,Zn-SOD were inhibited comparably when the ionic strength was increased. This effect is presumably due to the lysine residues near the active site.(ABSTRACT TRUNCATED AT 250 WORDS)     

Toward delineating the structure and function of the particulate methane monooxygenase from methanotrophic bacteria

The particulate methane monooxygenase (pMMO) is a complex membrane protein complex that has been difficult to isolate and purify for biochemical and biophysical characterization because of its instability in detergents used to solubilize the enzyme. In this perspective, we summarize the progress recently made toward obtaining a purified pMMO-detergent complex and characterizing the enzyme in pMMO-enriched membranes. The purified pMMO is a multi-copper protein, with ca. 15 copper ions sequestered into five trinuclear copper clusters: two for dioxygen chemistry and alkane hydroxylation (catalytic or C-clusters) and three to provide a buffer of reducing equivalents to re-reduce the C-clusters following turnover (electron transfer or E-clusters). The enzyme is functional when all the copper ions are reduced. When the protein is purified under ambient aerobic conditions in the absence of a hydrocarbon substrate, only the C-clusters are oxidized; there is an apparent kinetic barrier for electron transfer from the E-cluster copper ions to the C-clusters under these conditions. Evidence is provided in support of both C-clusters participating in the dioxygen chemistry, but only one C-cluster supporting alkane hydroxylation. Acetylene modification of the latter C-cluster in the hydrophobic pocket of the active site lowers or removes the kinetic barrier for electron transfer from the E-clusters to the C-clusters so that all the copper ions could be fully oxidized by dioxygen. A model for the hydroxylation chemistry when a hydrocarbon substrate is bound to the active site of the hydroxylation C-cluster is presented. Unlike soluble methane monooxygenase (sMMO), pMMO exhibits limited substrate specificity, but the hydroxylation chemistry is highly regioselective and stereoselective. In addition, the hydroxylation occurs with total retention of configuration of the carbon center that is oxidized. These results are consistent with a concerted mechanism involving direct side-on insertion of an active singlet "oxene" from the activated copper cluster across the "C-H" bond in the active site. Finally, in our hands, both the purified pMMO-detergent complex and pMMO-enriched membranes exhibit high NADH-sensitive as well as duroquinol-sensitive specific activity. A possible role for the two reductants in the turnover of the enzyme is proposed.     

Conservation of local electric fields in the evolution of Cu,Zn superoxide dismutase

The trend of the electric field and the value of the electric field flux, sensed by the superoxide substrate in the proximity of the active site, were found to be constant in three highly homologous Cu,Zn superoxide dismutases from ox, pig and sheep, which display large differences in net protein charge and distribution of electrically charged surface residues but very similar catalytic rate constants. The spatial relationship of charges on the protein surface apparently has been conserved during the evolution of this enzyme to create electrostatic facilitation of catalysis.     

Crystal structure of the second domain of the human copper chaperone for superoxide dismutase

The human copper chaperone for superoxide dismutase (hCCS) delivers the essential copper ion cofactor to copper,zinc superoxide dismutase (SOD1), a key enzyme in antioxidant defense. Mutations in SOD1 are linked to familial amyotrophic lateral sclerosis (FALS), a fatal neurodegenerative disorder. The molecular mechanisms by which SOD1 is recognized and activated by hCCS are not understood. To better understand this biochemical pathway, we have determined the X-ray structure of the largest domain of hCCS (hCCS Domain II) to 2. 75 A resolution. The overall structure is closely related to that of its target enzyme SOD1, consisting of an eight-stranded beta-barrel and a zinc-binding site formed by two extended loops. The first of these loops provides the ligands to a bound zinc ion, and is analogous to the zinc subloop in SOD1. The second structurally resembles the SOD1 electrostatic channel loop, but lacks many of the residues important for catalysis. Like SOD1 and yCCS, hCCS forms a dimer using a highly conserved interface. In contrast to SOD1, however, the hCCS structure does not contain a copper ion bound in the catalytic site. Notably, the structure reveals a single loop proximal to the dimer interface which is unique to the CCS chaperones.     

变性过程中铜锌超氧化物歧化酶的活性通道

在酶的盐酸胍变性和热变性过程中,尝试采用电荷传递反应分析方法和电子自旋共振方法考察了酶活性部位的构象变化。酶活力与构象的变化行为表明,酶的活性部位通道先于酶分子的整体构象而发生变化,它是与酶的失活同时发生的。尽管酶活性部位中的金属离子保证了酶较高的稳定性,但酶的活性部位,特别是活性通道仍然是相对脆弱的。     

超氧化物歧化酶活性中心中铜离子的氧化还原研究

用电子顺磁共振EPR技术研究铜锌超氧化物歧化酶(Cu·Zn-SOD)与底物(O_2~(·-)反应达到平衡态时铜离子的EPR波谱表明,在平衡态时的铜离子处于还原态。用还原剂H_2O_2、NaBH_4处理Cu·Zn-SOD后,酶活力变化不同,电泳行为也不同。用NaBH_4处理SOD其活性及电泳行为接近天然酶,但经H_2O_2还原后的酶活性损失严重,电泳后出现多条色带。     

The contribution of adjacent subunits to the active sites of D-3-phosphoglycerate dehydrogenase

D-3-Phosphoglycerate dehydrogenase (PGDH) from Escherichia coli is allosterically inhibited by L-serine, the end product of its metabolic pathway. Previous results have shown that inhibition by serine has a large effect on Vmax and only a small or negligible effect on Km. PGDH is thus classified as a V-type allosteric enzyme. In this study, the active site of PGDH has been studied by site-directed mutagenesis to assess the role of certain residues in substrate binding and catalysis. These consist of a group of cationic residues (Arg-240, Arg-60, Arg-62, Lys-39, and Lys-141') that potentially form an electrostatic environment for the binding of the negatively charged substrate, as well as the only tryptophan residue found in PGDH and which fits into a hydrophobic pocket immediately adjacent to the active site histidine residue. Interestingly, Trp-139' and Lys-141' are part of the polypeptide chain of the subunit that is adjacent to the active site. The results of mutating these residues show that Arg-240, Arg-60, Arg-62, and Lys-141' play distinct roles in the binding of the substrate to the active site. Mutants of Trp-139' show that this residue may play a role in stabilizing the catalytic center of the enzyme. Furthermore, these mutants appear to have a significant effect on the cooperativity of serine inhibition and suggest a possible role for Trp-139' in the cooperative interactions between subunits.     

Involvement of the Copper in the Inhibition of Cu,Zn Superoxide Dismutase Activity at high pH

The alkaline spectroscopic transition of the copper at the active site of Cu, Zn superoxide dismutase has been reexamined by room temperature EPR. in order to correlate it with the inhibition of the enzyme activity at high pH. The EPR transition is governed by a single prototropic equilibrium, with pK values of 11.3 and 11.1 for ox and shark superoxide dismutase. respectively. This result suggests possible contributions of changes of the copper environment to the higher pK of the activity/pH curve.

When Arg141 was cheniically modified by phenylglyoxal treatment of the ox protein. a lower pK value (10.8) was obtained, indicating that Arg141 is involved in the observed modifications of the EPR spectra.     

Copper stabilizes a heterodimer of the yCCS metallochaperone and its target superoxide dismutase

The copper chaperone for superoxide dismutase (CCS) activates the antioxidant enzyme Cu,Zn-SOD (SOD1) by directly inserting the copper cofactor into the apo form of SOD1. Neither the mechanism of protein-protein recognition nor of metal transfer is clear. The metal transfer step has been proposed to occur within a transient copper donor/acceptor complex that is either a heterodimer or heterotetramer (i.e. a dimer of dimers). To determine the nature of this intermediate, we generated a mutant form of SOD1 by replacing a copper binding residue His-48 with phenylalanine. This protein cannot accept copper from CCS but does form a stable complex with apo- and Cu-CCS, as observed by immunoprecipitation and native gel electrophoresis. Fluorescence anisotropy measurements corroborate the formation of this species and further indicate that copper enhances the stability of the dimer by an order of magnitude. The copper form of the heterodimer was isolated by gel filtration chromatography and contains one copper and one zinc atom per heterodimer. These results support a mechanism for copper transfer in which CCS and SOD1 dock via their highly conserved dimer interfaces in a manner that precisely orients the Cys-rich copper donor sites of CCS and the His-rich acceptor sites of SOD1 to form a copper-bridged intermediate.     

Mechanism and Atomic Structure of Superoxide Dismutase

The active site Cu ion in Cu,Zn superoxide dismutase is alternately oxidized and reduced during the enzymatic dismutation of superoxide to hydrogen peroxide and molecular oxygen. For oxidized Cu,Zn superoxide dismutase, an atomic structure has been determined for the human enzyme at 2.5 A resolution. The resolution of the bovine enzyme structure has been extended to 1.8 A. Atomic resolution data has been, collected for reduced and inhibitor-bound Cu,Zn superoxide dismutases. and the interpretation of the' electron density difference maps is in progress. The geometry and molecular surfaces of the active sites in these structures, together with biochemical data, suggest a specific model for the enzyme mechanism. Similarities in the active site geometry of the Mn and Fe superoxide dismutases with the Cu.Zn enzyme suggest that dismutation in these enzymes may follow a similar mechanism.     

Chemical modification of the CuA center in cytochrome c oxidase by sodium p-(hydroxymercuri)benzoate

Cytochrome c oxidase contains a copper ion electron-transfer site, CuA, which has previously been found to be unreactive with externally added reagents under conditions in which the protein remains structurally intact. We have studied the reaction of cytochrome oxidase with sodium p-(hydroxymercuri) benzoate (pHMB) and found that the reaction proceeds, under appropriate conditions, to give an excellent yield of a particular derivative of the CuA center that has electron paramagnetic resonance and near-infrared absorption spectroscopic properties which are distinctly different from those of the unmodified center. Spectroscopic and chemical characterization of the other metal ion sites of the enzyme reveals little or no effect of the pHMB modification on the structures of and reactions at those sites. Of particular interest is the observation that the modified enzyme still displays a substantial fraction of the native steady-state activity of electron transfer from ferrocytochrome c to O2. Although the modified copper center retains the ability to receive electrons from the powerful reductant Na2S2O4 and to transfer electrons to O2, it is not significantly reduced when the enzyme is treated with milder (higher potential) reductants such as NADH/phenazine methosulfate or the physiological substrate ferrocytochrome c. CuA exhibits many spectroscopic and chemical properties which make it highly atypical of cuproprotein active sites; the singular nature of this site has prompted speculation about the importance of the structural peculiarities of this metal ion center in the catalytic cycle of the enzyme. In this work, we demonstrate that the unusual features of this site are not prerequisites for competent catalysis of electron transfer and O2 reduction by the enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)