Zinc(II) binding to apo-(bovine erythrocyte superoxide dismutase).

The binding of zinc(II) ions to apo-(bovine erythrocytes superoxide dismutase) was studied by 1H n.m.r. spectroscopy. Two zinc(II) ions bind to each subunit of the apoenzyme, and the first has a binding constant at least an order of magnitude larger than the second. The nature of the spectral changes that occur on binding the first zinc(II) ion are interpreted in terms of a change in the structure of the protein around the active site to one very similar to that of the holoenzyme, thus pre-forming the second zinc(II) binding site. The binding of the second zinc(II) ion effects changes in the environment of only those residues involved in its co-ordination.     

Metal binding sites in proteins: identification and characterization by paramagnetic NMR relaxation

A method is presented that allows the identification and quantitative characterization of metal binding sites in proteins using paramagnetic nuclear magnetic resonance spectroscopy. The method relies on the nonselective longitudinal relaxation rates of the amide protons and their dependence on the paramagnetic metal ion concentration and the pH, and on the three-dimensional structure of the protein. The method is demonstrated using Escherichia coli thioredoxin as a model protein and Ni(2+) as the paramagnetic metal ion. Through a least-squares analysis of the relaxation rates, it is found that Ni(2+) binds to a series of specific sites on the surface of thioredoxin. The strongest binding site is found near the N-terminus of the protein, where the metal ion is coordinated to the free NH(2) group of the N-terminal serine residue and the side chain carboxylate group of the aspartic acid residue in position 2. In addition, Ni(2+) binds specifically but more weakly to the surface-exposed side chain carboxylate groups of residues D10, D20, D47, and E85.     

Characterization of the redox and metal binding activity of BsSco, a protein implicated in the assembly of cytochrome c oxidase

Members of the Sco protein family are implicated in the assembly of the respiratory complex cytochrome c oxidase. Several possible roles have been proposed for Sco: a copper delivery agent, a site-specific thiol reductase, and an indicator of cellular redox status. Two cysteine residues (C45 and C49) in the sequence CXXXCP and a histidine (H135) approximately 90 residues toward the C-terminus are conserved in Sco from bacteria, yeast, and humans. The soluble domain of Sco has a thioredoxin fold that is suggestive of redox activity for this protein. We have characterized the soluble domain of the Sco protein from Bacillus subtilis (i.e., sBsSco) for its redox reactivity and metal binding capacity. In oxidized sBsSco, the cysteines are present as an intramolecular disulfide. Oxidized sBsSco does not bind metal, but can be reduced in vitro to a metal-binding form. Reduction of the disulfide in sBsSco is accompanied by increased intrinsic fluorescence. The reducibility of the cystine is unchanged when the conserved histidine is mutated to alanine. Tight binding by reduced sBsSco is observed for Cu(II) by electronic absorption, intrinsic fluorescence, and EPR spectroscopies, and isothermal titration calorimetry with an observed stoichiometry of one Cu(II) ion per sBsSco and a KD of approximately 50 nM. Tight binding of Cu(I) and Ag(I) is observed by quenching of intrinsic tryptophan fluorescence. Cobalt(II) exhibits weak binding, whereas Ni(II) and Zn(II) do not appear to bind. The high-affinity binding of metals by BsSco is triggered by its redox state, and this property could be important for its function in vivo.     

A study of the kinetics of iron and copper binding to hen ovotransferrin.

The kinetics of iron and copper binding to hen's-egg apo-ovotransferrin were studied by using citrate chelates of these metals at pH9.3 in borate buffer in the presence of bicarbonate. The kinetics of the absorbance change associated with the formation of the final product show a fast process, which is pseudo-first-order, where the reagents are in excess with respect to the protein, and the citrate concentration is higher than 25mM. At lower citrate concentration, the progress curves are clearly biphasic. There is marked dependence of the rate of the reaction on bicarbonate concentration, which may be interpreted as a displacement reaction of the ligand-metal-protein ternary complex. The kinetics have been interpreted in the framework of a reaction scheme which involves bimolecular reaction of a metal chelate to the protein and subsequent colour development by displacement of the chelator by bicarbonate. The pH-dependence of this reaction supports the belief that tyrosine residues are involved in the process of iron-binding. The overall similarity of kinetics for iron and copper binding, notwithstanding their different co-ordination preferences, suggests that the process of metal-binding or chromophore development for the two metal complexes must be similar.     

A zinc-finger like metal binding site in the nucleosome

UV spectroscopy demonstrated that chicken mononucleosomes bind Co(II) and Zn(II) ions at submicromolar concentrations in a tetrahedral mode, at a conserved zinc finger-like site, composed of Cys110 and His113 residues of both H3 molecules. Neither of these metal ions substituted for another, indicating a limited binding reversibility. Molecular modeling indicated that the tetrahedral site is formed by unhindered rotations around Calpha-Cbeta bonds in the side chains of the zinc binding residues. The resulting local rearrangement of the protein structure shields the bound metal ion from the solvent, explaining the observed lack of reversibility of the binding. Consequences of these findings for zinc homeostasis, metal toxicology and nucleosomal regulation are discussed.     

19F NMR studies of the D-galactose chemosensory receptor. 2. Ca(II) binding yields a local structural change.

The Escherichia coli D-galactose and D-glucose receptor possesses a Ca(II)-binding site closely related in structure and metal-binding characteristics to the eukaryotic EF-hand sites. Only the structure of the Ca(II)-occupied site is known. To investigate the structural change triggered by Ca(II) and Sr(II) binding, we have used 19F NMR to probe five 5-fluorotryptophan (5F-Trp) and seven 3-fluorophenylalanine (3F-Phe) positions in the structure, extending the approach described in the preceding article. Of particular interest were two 5F-Trp residues near the N terminus of the Ca(II) site at positions 127 and 133. Substitution of the larger Sr(II) for Ca(II) triggered 19F NMR frequency shifts of the 5F-Trp127 and -133 resonances, indicating a detectable structural change in the Ca(II) site. In contrast, the three 5F-Trp resonances from distant regions of the structure exhibited no detectable frequency shifts. When the metal was removed from the Ca(II) site, the 5F-Trp127 and -133 frequencies shifted to a new value similar to that observed for free 5F-Trp in aqueous solvent, and this new frequency was a function of the H2O to D2O ratio, indicating that the residues had become solvent exposed. Metal removal yielded small or undetectable frequency shifts for the three distant 5F-Trp resonances and for four of the five resolved 3F-Phe resonances. The allosteric coupling of the metal and sugar binding sites was observed to be slight: depletion of metal ions was observed to reduce the D-galactose affinity of the receptor by 2-fold. Together the results indicate that the structural changes in the Ca(II) site are primarily localized in the region of the site. Removal of the metal ion from the site exposes the nearby 5F-Trp127 and -133 residues to the solvent, suggesting that the empty site has a more open structure.(ABSTRACT TRUNCATED AT 250 WORDS)     

Arabidopsis glyoxalase II contains a zinc/iron binuclear metal center that is essential for substrate binding and catalysis

Glyoxalase II participates in the cellular detoxification of cytotoxic and mutagenic 2-oxoaldehydes. Because of its role in chemical detoxification, glyoxalase II has been studied as a potential anti-cancer and/or anti-protozoal target; however, very little is known about the active site and reaction mechanism of this important enzyme. To characterize the active site and kinetic mechanism of the enzyme, a detailed mutational study of Arabidopsis glyoxalase II was conducted. Data presented here demonstrate for the first time that the cytoplasmic form of Arabidopsis glyoxalase II contains an iron-zinc binuclear metal center that is essential for activity. Both metals participate in substrate binding, transition state stabilization, and the hydrolysis reaction. Subtle alterations in the geometry and/or electrostatics of the binuclear center have profound effects on the activity of the enzyme. Additional residues important in substrate binding have also been identified. An overall reaction mechanism for glyoxalase II is proposed based on the mutational and kinetic data from this study and crystallographic data on human glyoxalase II. Information presented here provides new insights into the active site and reaction mechanism of glyoxalase II that can be used for the rational design of glyoxalase II inhibitors.     

Linear free-energy analysis of mercury(II) and cadmium(II) binding to three-stranded coiled coils

Investigators have studied how proteins enforce nonstandard geometries on metal centers to assess the question of how protein structures can define the coordination geometry and binding affinity of an active-site metal cofactor. We have shown that cysteine-substituted versions of the TRI peptide series [AcG-(LKALEEK)(4)G-NH(2)] bind Hg(II) and Cd(II) in geometries that are different from what is normally found with thiol ligands in aqueous solution. A fundamental question has been whether this structural perturbation is due to protein influence or a change in the metal geometry preference. To address this question, we have completed linear free-energy analyses that correlate the association of three-stranded coiled coils in the absence of a metal with the binding affinity of the peptides to the heavy metals, Hg(II) and Cd(II). In this paper, six new members of this family have been synthesized, replacing core leucine residues with smaller and less hydrophobic residues, consequently leading to varying degrees of self-association affinities. At the same time, studies with some smaller and longer sequenced peptides have also been examined. All of these peptides are seen to sequester Hg(II) and Cd(II) in an uncommon trigonal environment. For both metals, the binding is strong with micromolar dissociation constants. For binding of Hg(II) to the peptides, the dissociation constants range from 2.4 x 10(-)(5) M for Baby L12C to 2.5 x 10(-)(9) M for Grand L9C for binding of the third thiolate to a linear Hg(II)(pep)(2) species. The binding of Hg(II) to the peptide Grand L9C is similar in energetics for metal binding in the metalloregulatory protein, mercury responsive (merR), displaying approximately 50% trigonal Hg(II) formation at nanomolar metal concentrations. Approximately, 11 kcal/mol of the Hg(II)(Grand L9C)(3)(-) stability is due to peptide interactions, whereas only 1-4 kcal/mol stabilization results from Hg(II)(RS)(2) binding the third thiolate ligand. This further validates the hypothesis that the favorable tertiary interactions in protein systems such as merR go a long way in stabilizing nonnatural coordination environments in biological systems. Similarly, for the binding of Cd(II) to the TRI family, the dissociation constants range from 1.3 x 10(-)(6) M for Baby L9C to 8.3 x 10(-)(9) M for TRI L9C, showing a similar nature of stable aggregate formation.     

Metal binding activity of the Escherichia coli hydrogenase maturation factor HypB

The formation of the [NiFe] metallocenter of Escherichia coli hydrogenase 3 requires the participation of proteins encoded by the hydrogenase pleiotropy operon hypABCDEF. The insertion of Ni(II) into the precursor enzyme follows the incorporation of the iron center and is the function of HypA, a Zn(II)-binding protein, and HypB, a GTPase. The Ni(II) donor and the mechanism of transfer of Ni(II) into the hydrogenase precursor protein are not known. In this study, we demonstrate that HypB is a nickel-binding protein capable of binding 1 equiv of Ni(II) with a K(d) in the sub-picomolar range. In addition, HypB has a weaker metal-binding site that is not specific for Ni(II) over Zn(II). Examination of the isolated C-terminal GTPase domain revealed that the high-affinity metal binding capability was severely abrogated but the low-affinity site was intact. By mutating conserved cysteine and histidine residues in E. coli HypB, we have localized the high-affinity Ni(II)-binding site to an N-terminal CXXCGC motif and the low-affinity metal-binding site to the GTPase domain. A model for the function of HypB during the Ni(II) loading of hydrogenase is proposed.     

Robust recognition of zinc binding sites in proteins

Metals play a variety of roles in biological processes, and hence their presence in a protein structure can yield vital functional information. Because the residues that coordinate a metal often undergo conformational changes upon binding, detection of binding sites based on simple geometric criteria in proteins without bound metal is difficult. However, aspects of the physicochemical environment around a metal binding site are often conserved even when this structural rearrangement occurs. We have developed a Bayesian classifier using known zinc binding sites as positive training examples and nonmetal binding regions that nonetheless contain residues frequently observed in zinc sites as negative training examples. In order to allow variation in the exact positions of atoms, we average a variety of biochemical and biophysical properties in six concentric spherical shells around the site of interest. At a specificity of 99.8%, this method achieves 75.5% sensitivity in unbound proteins at a positive predictive value of 73.6%. We also test its accuracy on predicted protein structures obtained by homology modeling using templates with 30%-50% sequence identity to the target sequences. At a specificity of 99.8%, we correctly identify at least one zinc binding site in 65.5% of modeled proteins. Thus, in many cases, our model is accurate enough to identify metal binding sites in proteins of unknown structure for which no high sequence identity homologs of known structure exist. Both the source code and a Web interface are available to the public at http://feature.stanford.edu/metals.     

Identification of metal binding residues for the binuclear zinc phosphodiesterase reveals identical coordination as glyoxalase II

Zinc phosphodiesterase (ZiPD) is a member of the metallo-beta-lactamase family with a binuclear zinc binding site. As an experimental attempt to identify the metal ligands of Escherichia coli ZiPD and to investigate their function in catalysis, we mutationally exchanged candidate metal coordinating residues and performed kinetic and X-ray absorption spectroscopic analysis of the mutant proteins. All mutants (H66E, H69A, H141A, D212A, D212C, H231A, H248A, and H270A) show significantly lower catalytic rates toward the substrate bis(p-nitrophenyl)phosphate. Substrate binding, represented by the kinetic value K', remains unchanged for six mutants, whereas it is increased 3-4-fold for H231A and H270A. Accordingly, these two residues are supposed to be involved in substrate binding, whereas the others are more important for catalytic turnover and thus are assumed to be involved in zinc ligation. Structural insight into the metal binding of D212 was gained by zinc K-edge extended X-ray absorption fine structure (EXAFS). The sulfur coordination number of the cysteine mutant was found to be 1, demonstrating binding to both zinc metals in a bridging mode. Taken together with two residues from a strictly conserved sequence region within the metallo-beta-lactamase family, the metal site of ZiPD is proposed with H64, H66, and H141 coordinating ZnA, D68, H69, and H248 coordinating ZnB, and D212 bridging both metals. Surprisingly, the same coordination sphere is found in glyoxalase II. This is further substantiated by comparable EXAFS spectra of both native enzymes. This is the first example of the same metal site in two members of the metallo-beta-lactamase domain proteins catalyzing different reactions. The kinetic analysis of mutants provides unexpected insights into the reaction mechanism of ZiPD.     

Real-time kinetics of discontinuous and highly conformational metal-ion binding sites of prion protein

The prion protein (PrP) is a metalloprotein with an unstructured region covering residues 60–91 that bind two to six Cu(II) ions cooperatively. Cu can bind to PrP regions C-terminally to the octarepeat region involving residues His111 and/or His96. In addition to Cu(II), PrP binds Zn(II), Mn(II) and Ni(II) with binding constants several orders of magnitudes lower than those determined for Cu. We used for the first time surface plasmon resonance (SPR) analysis to dissect metal binding to specific sites of PrP domains and to determine binding kinetics in real time. A biosensor assay was established to measure the binding of PrP-derived synthetic peptides and recombinant PrP to nitrilotriacetic acid chelated divalent metal ions. We have identified two separate binding regions for binding of Cu to PrP by SPR, one in the octarepeat region and the second provided by His96 and His111, of which His96 is more essential for Cu coordination. The octarepeat region at the N-terminus of PrP increases the affinity for Cu of the full-length protein by a factor of 2, indicating a cooperative effect. Since none of the synthetic peptides covering the octarepeat region bound to Mn and recombinant PrP lacking this sequence were able to bind Mn, we propose a conformational binding site for Mn involving residues 91–230. A novel low-affinity binding site for Co(II) was discovered between PrP residues 104 and 114, with residue His111 being the key amino acid for coordinating Co(II). His111 is essential for Co(II) binding, whereas His96 is more important than His111 for binding of Cu(II).     

Using directed evolution to improve the solubility of the C-terminal domain of Escherichia coli aminopeptidase P. Implications for metal binding and protein stability

There have been many approaches to solving problems associated with protein solubility. This article describes the application of directed evolution to improving the solubility of the C-terminal metal-binding domain of aminopeptidase P from Escherichia coli. During the course of experiments, the domain boundary and sequence were allowed to vary. It was found that extending the domain boundary resulted in aggregation with little improvement in solubility, whereas two changes to the sequence of the domain resulted in dramatic improvements in solubility. These latter changes occurred in the active site and abolished the ability of the protein to bind metals and hence catalyze its physiological reaction. The evidence presented here has led to the proposal that metals bind to the intact protein after it has folded and that the N-terminal domain is necessary to stabilize the structure of the protein so that it is capable of binding metals. The acid residues responsible for binding metals tend to repel one another - in the absence of the N-terminal domain, the C-terminal domain does not fold properly and forms inclusion bodies. Evolution of the C-terminal domain has removed the destabilizing effects of the metal ligands, but in so doing it has reduced the capacity of the domain to bind metals. In this case, directed evolution has identified active site residues that destabilize the domain structure.     

A reassessment of copper(II) binding in the full-length prion protein

It has been shown previously that the unfolded N-terminal domain of the prion protein can bind up to six Cu2+ ions in vitro. This domain contains four tandem repeats of the octapeptide sequence PHGGGWGQ, which, alongside the two histidine residues at positions 96 and 111, contribute to its Cu2+ binding properties. At the maximum metal-ion occupancy each Cu2+ is co-ordinated by a single imidazole and deprotonated backbone amide groups. However two recent studies of peptides representing the octapeptide repeat region of the protein have shown, that at low Cu2+ availability, an alternative mode of co-ordination occurs where the metal ion is bound by multiple histidine imidazole groups. Both modes of binding are readily populated at pH 7.4, while mild acidification to pH 5.5 selects in favour of the low occupancy, multiple imidazole binding mode. We have used NMR to resolve how Cu2+ binds to the full-length prion protein under mildly acidic conditions where multiple histidine co-ordination is dominant. We show that at pH 5.5 the protein binds two Cu2+ ions, and that all six histidine residues of the unfolded N-terminal domain and the N-terminal amine act as ligands. These two sites are of sufficient affinity to be maintained in the presence of millimolar concentrations of competing exogenous histidine. A previously unknown interaction between the N-terminal domain and a site on the C-terminal domain becomes apparent when the protein is loaded with Cu2+. Furthermore, the data reveal that sub-stoichiometric quantities of Cu2+ will cause self-association of the prion protein in vitro, suggesting that Cu2+ may play a role in controlling oligomerization in vivo.     

Metal binding specificity in carbonic anhydrase is influenced by conserved hydrophobic core residues.

The role of highly conserved aromatic residues surrounding the zinc binding site of human carbonic anhydrase II (CAII) in determining the metal ion binding specificity of this enzyme has been examined by mutagenesis. Residues F93, F95, and W97 are located along a beta-strand containing two residues that coordinate zinc, H94 and H96, and these aromatic amino acids contribute to the high zinc affinity and slow zinc dissociation rate constant of CAII [Hunt, J. A., and Fierke, C. A. (1997) J. Biol. Chem. 272, 20364-20372]. Substitutions of these aromatic amino acids with smaller side chains enhance the copper affinity (up to 100-fold) while decreasing the affinity of both cobalt and zinc, thereby altering the metal binding specificity up to 10(4)-fold. Furthermore, the free energy of the stability of native CAII, determined by solvent-induced denaturation, correlates positively with increased hydrophobicity of the amino acids at positions 93, 95, and 97 as well as with cobalt and zinc affinity. Conversely, increased copper affinity correlates with decreased protein stability. Zinc specificity is therefore enhanced by formation of the native enzyme structure. These data suggest that the hydrophobic cluster in CAII is important for orienting the histidine residues to stabilize metals bound with a distorted tetrahedral geometry and to destabilize the trigonal bipyramidal geometry of bound copper. Knowledge of the structural factors that lead to high metal ion specificity will aid in the design of metal ion biosensors and de novo catalytic sites.     

Imprint of evolutionary conservation and protein structure variation on the binding function of protein tyrosine kinases

MOTIVATION: According to the models of divergent molecular evolution, the evolvability of new protein function may depend on the induction of new phenotypic traits by a small number of mutations of the binding site residues. Evolutionary relationships between protein kinases are often employed to infer inhibitor binding profiles from sequence analysis. However, protein kinases binding profiles may display inhibitor selectivity within a given kinase subfamily, while exhibiting cross-activity between kinases that are phylogenetically remote from the prime target. The emerging insights into kinase function and evolution combined with a rapidly growing number of publically available crystal structures of protein kinases complexes have motivated structural bioinformatics analysis of sequence-structure relationships in determining the binding function of protein tyrosine kinases. RESULTS: In silico profiling of Imatinib mesylate and PD-173955 kinase inhibitors with protein tyrosine kinases is conducted on kinome scale by using evolutionary analysis and fingerprinting inhibitor-protein interactions with the panel of all publically available protein tyrosine kinases crystal structures. We have found that sequence plasticity of the binding site residues alone may not be sufficient to enable protein tyrosine kinases to readily evolve novel binding activities with inhibitors. While evolutionary signal derived solely from the tyrosine kinase sequence conservation can not be readily translated into the ligand binding phenotype, the proposed structural bioinformatics analysis can discriminate a functionally relevant kinase binding signal from a simple phylogenetic relationship. The results of this work reveal that protein conformational diversity is intimately linked with sequence plasticity of the binding site residues in achieving functional adaptability of protein kinases towards specific drug binding. This study offers a plausible molecular rationale to the experimental binding profiles of the studied kinase inhibitors and provides a theoretical basis for constructing functionally relevant kinase binding trees.     

Insights into the role of the metal binding site in methionine-R-sulfoxide reductases B

Methionine sulfoxide reductases B (MsrBs) catalyze the reduction of methionine-R-sulfoxide via a three-step chemical mechanism including a reductase step, formation of an intradisulfide bond followed by a thioredoxin recycling process. Fifty percent of the MsrBs, including the Escherichia coli enzyme, possess a metal binding site composed of two CXXC motifs of unknown function. It is located on the opposite side of the active site. The overexpressed E. coli MsrB tightly binds one atom of zinc/iron. Substitution of the cysteines of E. coli MsrB results in complete loss of bound metal and reductase activity, and leads to a low-structured conformation of the protein as shown by CD, fluorescence, and DSC experiments. Introduction of the two CXXC motifs in Neisseria meningitidis MsrB domain leads to a MsrB that tightly binds one atom of zinc/iron, shows a strongly increased thermal stability and displays a reductase activity similar to that of the wild-type but lacking thioredoxin recycling activity. These results demonstrate the stabilizing effect of the metal and the existence of a preformed metal binding site in the nonbound metal MsrB. The data also indicate that metal binding to N. meningitidis MsrB induces subtle structural modifications, which prevent formation of a competent binary complex between oxidized MsrB and reduced thioredoxin but not between reduced MsrB and substrate. The fact that the E. coli and the N. meningitidis MsrBs exhibit a similar thermal stability suggests the existence of other structural factors in the nonbound metal MsrBs that compensate the metal bound stabilizing effect.