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.     

An insight to conserved water molecular dynamics of catalytic and structural Zn(+2) ions in matrix metalloproteinase 13 of human

Matrix Metalloproteinase (MMP)--13 or Collagenase--3 plays a significant role in the formation and remodeling of bone, tumor invasion and causes osteoarthritis. Water molecular dynamic studies of the five (1XUC, 1XUD, 1XUR, 456C, 830C) PDB and solvated structures of MMP-13 in human have been carried out upto 5 ns on assigning the differential charges (+2, +1, +0.5 e) to both the Zinc ions. The MM and MD-studies have revealed the coordination of three water molecules (W(H), W(I) and W(S)) to Zn(c) and one water to Zn(s). The transition of geometry around the Znc from tetrahedral to octahedral via trigonal bipyramidal, and for Zn(s) from tetrahedral to trigonal bipyramidal are seem interesting. Recognition of two zinc ions through water molecular bridging (Zn(c) - W(H) (W(1))...W(2)....W(3)....H(187) Zn(s)) and the stabilization of variable coordination geometries around metal ions may indicate the possible involvement of Zn(c) ...Zn(s) coupled mechanism in the catalytic process. So the hydrophilic topology and stereochemistry of water mediated coupling between Zn-ions may provide some plausible hope towards the design of some bidentate/polydentate bridging ligands or inhibitors for MMP-13.     

Probing determinants of the metal ion selectivity in carbonic anhydrase using mutagenesis

Few studies measuring thermodynamic metal ion selectivity of metalloproteins have been performed, and the major determinants of metal ion selectivity in proteins are not yet well understood. Several features of metal ion binding sites and metal coordination have been hypothesized to alter the transition metal selectivity of chelators, including (1) the polarizability of the coordinating atom, (2) the relative sizes of the binding site and the metal ion, and (3) the metal ion binding site geometry. To test these hypotheses, we have measured the metal ion affinity and selectivity of a prototypical zinc enzyme, human carbonic anhydrase II (CAII), and a number of active site variants where one of the coordinating ligands is substituted by another side chain capable of coordinating metal. CAII and almost all of the variants follow the inherent metal ion affinity trend suggested by the Irving-Williams series, demonstrating that this trend operates within proteins as well as within small molecule chelators and may be a dominant factor in metal ion selectivity in biology. Neither the polarizability of the liganding side chains nor the size of the metal ion binding site correlates strongly with metal ion specificity; instead, changes in metal ion specificity in the variants correlate with the preferred coordination number and geometry of the metal ion. This correlation suggests that a primary feature driving deviations from the inherent ligand affinity trend is the positioning of active site groups such that a given metal ion can adopt a preferred coordination number/geometry.     

A tetrahedral coordination of Zinc during transmembrane transport by P-type Zn(2+)-ATPases

Zn(2+) is an essential transition metal required in trace amounts by all living organisms. However, metal excess is cytotoxic and leads to cell damage. Cells rely on transmembrane transporters, with the assistance of other proteins, to establish and maintain Zn(2+) homeostasis. Metal coordination during transport is key to specific transport and unidirectional translocation without the backward release of free metal. The coordination details of Zn(2+) at the transmembrane metal binding site responsible for transport have now been established. Escherichia coli ZntA is a well-characterized Zn(2+)-ATPase responsible for intracellular Zn(2+) efflux. A truncated form of the protein lacking regulatory metal sites and retaining the transport site was constructed. Metrical parameters of the metal-ligand coordination geometry for the zinc bound isolated form were characterized using x-ray absorption spectroscopy (XAS). Our data support a nearest neighbor ligand environment of (O/N)(2)S(2) that is compatible with the proposed invariant metal coordinating residues present in the transmembrane region. This ligand identification and the calculated bond lengths support a tetrahedral coordination geometry for Zn(2+) bound to the TM-MBS of P-type ATPase transporters.     

Zinc coordination geometry and ligand binding affinity: the structural and kinetic analysis of the second-shell serine 228 residue and the methionine 180 residue of the aminopeptidase from Vibrio proteolyticus

The chemical properties of zinc make it an ideal metal to study the role of coordination strain in enzymatic rate enhancement. The zinc ion and the protein residues that are bound directly to the zinc ion represent a functional charge/dipole complex, and polarization of this complex, which translates to coordination distortion, may tune electrophilicity, and hence, reactivity. Conserved protein residues outside of the charge/dipole complex, such as second-shell residues, may play a role in supporting the electronic strain produced as a consequence of functional polarization. To test the correlation between charge/dipole polarity and ligand binding affinity, structure-function studies were carried out on the dizinc aminopeptidase from Vibrio proteolyticus. Alanine substitutions of S228 and M180 resulted in catalytically diminished enzymes whose crystal structures show very little change in the positions of the metal ions and the protein residues. However, more detailed inspections of the crystal structures show small positional changes that account for differences in the zinc ion coordination geometry. Measurements of the binding affinity of leucine phosphonic acid, a transition state analogue, and leucine, a product, show a correlation between coordination geometry and ligand binding affinity. These results suggest that the coordination number and polarity may tune the electrophilicity of zinc. This may have provided the evolving enzyme with the ability to discriminate between reaction coordinate species.     

Individual metal ligands play distinct functional roles in the zinc sensor Staphylococcus aureus CzrA

Recent studies on metalloregulatory proteins suggest that coordination number/geometry and metal ion availability in a host cytosol are key determinants for biological specificity. Here, we investigate the contribution that individual metal ligands of the alpha5 sensing site of Staphylococcus aureus CzrA (Asp84, His86, His97', and His100') make to in vitro metal ion binding affinity, coordination geometry, and allosteric negative regulation of DNA operator/promoter region binding. All ligand substitution mutants exhibit significantly reduced metal ion binding affinity (K(Me)) by > or =10(3) M(-1). Substitutions of Asp84 and His97 give rise to non-native coordination geometries upon metal binding and are non-functional in allosteric coupling of metal and DNA binding (DeltaG(coupling) approximately 0 kcal mol(-1)). In contrast, His86 and His100 could be readily substituted with potentially liganding (Asp, Glu) and poorly liganding (Asn, Gln) residues with significant native-like tetrahedral metal coordination geometry retained in these mutants, leading to strong functional coupling (DeltaG(coupling) > or = +3.0 kcal mol(-1)). 1H-(15)N heteronuclear single quantum coherence (HSQC) spectra of wild-type and mutant CzrAs reveal that all H86 and H100 substitution mutants undergo 4 degrees structural switching on binding Zn(II), while D84N, H97N and H97D CzrAs do not. Thus, only those variant CzrAs that retain some tetrahedral coordination geometry characteristic of wild-type CzrA upon metal binding are capable of driving 4 degrees structural conformational changes linked to allosteric regulation of DNA binding in vitro, irrespective of the magnitude of K(Me).     

Can a hydroxide ligand trigger a change in the coordination number of magnesium ions in biological systems?

Density functional (B3LYP) calculations indicate that a hydroxide ligand is capable of triggering a reduction in the coordination number of Mg(2+) ions from 6 to 5. Since this could be quite relevant in the mode of action of magnesium-containing enzymes (especially hydrolases in which a metal-bound hydroxide species is believed to play a crucial role), we have performed a systematic deprotonation study of biologically relevant magnesium complexes. We explicitly calculated the preferred coordination number of [MgL(1)(x)L(2)(y)L(3)(z)](2)(-)(n) species at the B3LYP/aug-cc-pVTZ level of theory. L(1), L(2), and L(3) represent combinations of water, hydroxide, carboxylate (models Glu and Asp), ammonia ligands (models Lys and His residues), and fluoride ions. As expected, Mg(2+) exclusively prefers an octahedral coordination geometry with H(2)O, HCO(2)(-), or NH(3). Surprisingly, one hydroxide ligand triggers a change to a trigonal bipyramidal geometry. The isoelectronic fluoride ion behaves similarly. When two OH(-) are present, a tetrahedral coordination geometry is preferred. We postulate that a hydroxide (in addition to its role as an active nucleophile) could be employed by magnesium-containing enzymes to trigger a differential coordination behavior.     

Enzymatically inactive, exchange-inert Co(III)-carboxypeptidase A: role of inner sphere coordination in peptide and ester catalysis.

Catalytically inactive, exchange-inert Co(III)-carboxypeptidase A has been prepared by reaction of Co(II)-carboxypeptidase A with the active-site-directed oxidizing agent m-chloroperbenzoic acid. Co(III)-carboxypeptidase A, isolated by affinity gel filtration chromatography, has the same amino acid composition and molecular weight as the starting material and contains 0.95 g-atom/mol of cobalt and 0.01 g-atom/mol of zinc. Its electron paramagnetic resonance, circular dichroic, magnetic circular dichroic, and visible absorption spectra are consistent with those of octahedral Co(III) model complexes. Co(III)-caboxypeptidase A is essentially devoid of catalytic activity toward both peptide and ester substrates of the native enzyme, and stopped-flow fluorescence studies with dansylated substrates show that it binds peptides, but not esters. Furthermore, the protein does not react with either type of substrate to yield a single turnover. The implications of these findings to the mechanism of action of carboxypeptidase A are discussed in the light of the "metal-carbonyl" and "metal-hydroxide" hypotheses. Since Co(III)-carboxypeptidase A does not bind esters, inner-sphere coordination to the metal appears to be necessary for ester binding. All attempts to prepare Co(III)-carboxypeptidase A by treatment of Co(II)-carboxypeptidase A with hydrogen peroxide according to previously published procedures (Kang, E.P., Storm, C.B., & Carson, F.W. (1975) J. Am. Chem. Soc. 97, 6723) have been unsuccessful, and the present results do not confirm earlier reports that Co(III)-carboxypeptidase A exhibits esterase activity or that its activity is dependent on the method of preparation of the precursor Co(II)-carboxypeptidase A (Jones, M.M., Hunt, J.B., Storm, C.B., Evans, P.S., Carson, F.W. & Pauli, W.J. (1977) Biochem. Biophys. Res. Commun. 75, 253). These findings call for a reexamination of mechanistic conclusions based on the assumption that Co(III)-carboxypeptidase A is an active esterase.     

An interactive computer graphics study of thermolysin-catalyzed peptide cleavage and inhibition by N-carboxymethyl dipeptides

Interactive computer graphics was used as a tool in studying the cleavage mechanism of the model substrate Z-Phe-Phe-Leu-Trp by the zinc endopeptidase thermolysin. Two Michaelis complexes and three binding orientations of the tetrahedral intermediate to the crystal structure of thermolysin were investigated. Our results indicate that a Michaelis complex, which does not involve coordination of the scissile peptide to the zinc, is consistent with available experimental data and the most plausible of the two complexes. A tetrahedral intermediate complex wherein the two oxygens of the hydrated scissile peptide straddle the zinc in a bidentate fashion results in the most favorable interactions with the active site. The preferred tetrahedral intermediate and Michaelis complex provide a rationalization for the published substrate data. A trajectory for proceeding from the Michaelis complex to the tetrahedral intermediate is proposed. This trajectory involves a simultaneous activation of the zinc-bound water molecule concurrent with attack on the scissile peptide. A detailed ordered product release mechanism is also presented. These studies suggest some modifications and a number of extensions to the mechanism proposed earlier [Kester, W. R., & Matthews, B. W. (1977) Biochemistry 16, 2506; Holmes, M. A., & Matthews, B. W. (1981) Biochemistry 20, 6912]. The binding mode of the thermolysin inhibitor N-(1-carboxy-3-phenylpropyl)-L-leucyl-L-tryptophan [Monzingo, A. F., & Matthews, B. W. (1984) Biochemistry (preceding paper in this issue)] is compared with that of the preferred tetrahedral intermediate, providing insight into this inhibitor design.     

Structural studies of metal ions in family II pyrophosphatases: the requirement for a Janus ion

Family II inorganic pyrophosphatases (PPases) constitute a new evolutionary group of PPases, with a different fold and mechanism than the common family I enzyme; they are related to the "DHH" family of phosphoesterases. Biochemical studies have shown that Mn(2+) and Co(2+) preferentially activate family II PPases; Mg(2+) partially activates; and Zn(2+) can either activate or inhibit (Zyryanov et al., Biochemistry, 43, 14395-14402, accompanying paper in this issue). The three solved family II PPase structures did not explain the differences between the PPase families nor the metal ion differences described above. We therefore solved three new family II PPase structures: Bacillus subtilis PPase (Bs-PPase) dimer core bound to Mn(2+) at 1.3 A resolution, and, at 2.05 A resolution, metal-free Bs-PPase and Streptococcus gordonii (Sg-PPase) containing sulfate and Zn(2+). Comparison of the new and old structures of various family II PPases demonstrates why the family II enzyme prefers Mn(2+) or Co(2+), as an activator rather than Mg(2+). Both M1 and M2 undergo significant changes upon substrate binding, changing from five-coordinate to octahedral geometry. Mn(2+) and Co(2+), which readily adopt different coordination states and geometries, are thus favored. Combining our structures with biochemical data, we identified M2 as the high-affinity metal site. Zn(2+) activates in the M1 site, where octahedral geometry is not essential for catalysis, but inhibits in the M2 site, because it is unable to assume octahedral geometry but remains trigonal bipyramidal. Finally, we propose that Lys205-Gln81-Gln80 form a hydrophilic channel to speed product release from the active site.     

Bis-bidentate bridging ligands containing two N,O-chelating pyrazolyl-phenolate units; double helical complexes with Co(II), Cu(II) and Zn(II)

Two ligands have been prepared in which N,O-bidentate chelating pyrazolyl-phenolate units, based on 3-(2-hydroxyphenyl)pyrazole, are connected via methylene linkages to aromatic (1,4-phenylene or 3,3′-biphenylene) spacers. In each case the two N,O-donor units are too far apart to chelate to a single metal ion. Complexes of both ligands with Co(II), Cu(II) and Zn(II) were prepared and structurally characterised; in all cases the complexes are dinuclear double helicates M₂L₂, with each four-coordinate metal ion bound by a chelating unit from each of the two ligands in the complex. For Co(II) and Zn(II) the two M(NO) planes at each metal are close to perpendicular, indicative of a geometry which may be described as approximately distorted tetrahedral; for the Cu(II) complexes the angle between the two Cu(NO) planes is less, indicative of a distortion towards a more planar coordination geometry.     

Iron coordination structures of oxygen sensor FixL characterized by Fe K-edge extended x-ray absorption fine structure and resonance raman spectroscopy.

FixL is a heme-based O(2) sensor protein involved in a two-component system of a symbiotic bacterium. In the present study, the iron coordination structure in the heme domain of Rhizobium meliloti FixLT (RmFixLT, a soluble truncated FixL) was examined using Fe K-edge extended x-ray absorption fine structure (EXAFS) and resonance Raman spectroscopic techniques. In the EXAFS analyses, the interatomic distances and angles of the Fe-ligand bond and the iron displacement from the heme plane were obtained for RmFixLT in the Fe(2+), Fe(2+)O(2), Fe(2+)CO, Fe(3+), Fe(3+)F(-), and Fe(3+)CN(-) states. An apparent correlation was found between the heme-nitrogen (proximal His-194) distance in the heme domain and the phosphorylation activity of the histidine kinase domain. Comparison of the Fe-CO coordination geometry between RmFixLT and RmFixLH (heme domain of RmFixL), based on the EXAFS and Raman results, has suggested that the kinase domain directly or indirectly influences steric interaction between the iron-bound ligand and the heme pocket. Referring to the crystal structure of the heme domain of Bradyrhizobium japonicum FixL (Gong, W., Hao, B., Mansy, S. S., Gonzalez, G., Gilles-Gonzalez, M. A., and Chan, M. K. (1998) Proc. Natl. Acad. Sci. U. S. A. 95, 15177-15182), we discussed details of the iron coordination structure of RmFixLT and RmFixLH in relation to an intramolecular signal transduction mechanism in its O(2) sensing.     

Spectroscopic evidence for an intermediate in the T6 to R6 allosteric transition of the Co(II)-substituted insulin hexamer.

The phenol-induced conformational transition in the insulin hexamer is known to involve a large change in structure wherein residues 1-8 of the insulin B-chain are transformed from an extended coil (T-state) to a helix (R-state). This change in protein conformation both exposes a cryptic protein pocket on each subunit to which phenol binds and forces the HisB10 zinc sites to undergo a change in coordination geometry from octahedral to tetrahedral [Derewenda, U., Derewenda, Z., Dodson, E. J., Dodson, G. G., Reynolds, C. D., Smith, G. D., Sparks, C., & Swensen, D. (1989) Nature 338, 593-596]. Substitution of Co(II) for Zn(II) at the HisB10 sites introduces a sensitive chromophoric probe of the structural and chemical events that occur during this allosteric transition [Roy, M., Brader, M. L., Lee, R. W.-K., Kaarsholm, N. C., Hansen, J. F., & Dunn, M. F. (1989) J. Biol. Chem. 264, 19081-19085]. In this study, using rapid-scannig stopped-flow (RSSF) UV-visible spectroscopic studies, we demonstrate that a transient chemical intermediate is formed during the phenol-induced conversion of Co(II)-substituted hexamer from the T-state to the R-state. Decomposition of the RSSF spectra gave a spectrum for the intermediate with d-d transitions consistent with the assignment of the intermediate as either a distorted tetrahedral or a 5-coordinate Co(II) species. Possible structures for the intermediate and the implications of these findings to the allosteric mechanism are considered.     

Metal specificity is correlated with two crucial active site residues in Escherichia coli alkaline phosphatase

Escherichia coli alkaline phosphatase exhibits maximal activity when Zn(2+) fills the M1 and M2 metal sites and Mg(2+) fills the M3 metal site. When other metals replace the zinc and magnesium, the catalytic efficiency is reduced by more than 5000-fold. Alkaline phosphatases from organisms such as Thermotoga maritima and Bacillus subtilis require cobalt for maximal activity and function poorly with zinc and magnesium. Previous studies have shown that the D153H alkaline phosphatase exhibited very little activity in the presence of cobalt, while the K328W and especially the D153H/K328W mutant enzymes can use cobalt for catalysis. To understand the structural basis for the altered metal specificity and the ability of the D153H/K328W enzyme to utilize cobalt for catalysis, we determined the structures of the inactive wild-type E. coli enzyme with cobalt (WT_Co) and the structure of the active D153H/K328W enzyme with cobalt (HW_Co). The structural data reveal differences in the metal coordination and in the strength of the interaction with the product phosphate (P(i)). Since release of P(i) is the slow step in the mechanism at alkaline pH, the enhanced binding of P(i) in the WT_Co structure explains the observed decrease in activity, while the weakened binding of P(i) in the HW_Co structure explains the observed increase in activity. These alterations in P(i) affinity are directly related to alterations in the coordination of the metals in the active site of the enzyme.     

Evidence for a metal-thiolate intermediate in alkyl group transfer from epoxypropane to coenzyme M and cooperative metal ion binding in epoxyalkane:CoM transferase

Epoxyalkane:coenzyme M transferase (EaCoMT) catalyzes the nucleophilic addition of coenzyme M (CoM, 2-mercaptoethanesulfonic acid) to epoxypropane forming 2-hydroxypropyl-CoM. The biochemical properties of EaCoMT suggest that the enzyme belongs to the family of alkyltransferase enzymes for which Zn plays a role in activating an organic thiol substrate for nucleophilic attack on an alkyl-donating substrate. The enzyme has a hexameric (alpha(6)) structure with one zinc atom per subunit. In the present work M(2+) binding and the role of Zn(2+) in EaCoMT have been established through a combination of biochemical, calorimetric, and spectroscopic techniques. A variety of metal ions, including Zn(2+), Co(2+), Cd(2+), and Ni(2+), were capable of activating a Zn-deficient "apo" form of EaCoMT, affording enzymes with various levels of activity. Titration of Co(2+) into apo-EaCoMT resulted in UV-visible spectroscopic changes consistent with the formation of a tetrahedral Co(2+) binding site, with coordination of bound Co(2+) to two thiolate ligands. Quantification of UV-visible spectral changes upon Co(2+) titration into apo-EaCoMT demonstrated that EaCoMT binds Co(2+) cooperatively at six interacting sites. Isothermal titration calorimetric studies of Co(2+) and Zn(2+) binding to EaCoMT also showed cooperativity for metal ion binding among six sites. The addition of CoM to Co(2+)-substituted EaCoMT resulted in UV-visible spectral changes indicative of formation of a new thiol-Co(2+) bond. Co(2+)-substituted EaCoMT exhibited a unique Co(2+) EPR spectrum, and this spectrum was perturbed significantly upon addition of CoM. The presence of a divalent metal ion was required for the release of protons from CoM upon binding to EaCoMT, with Zn(2+), Co(2+), and Cd(2+) each facilitating proton release. The divalent metal ion of EaCoMT is proposed to play a key role in the coordination and deprotonation of CoM, possibly through formation of a metal-thiolate that is activated for attack on the epoxide substrate.     

Zn2+ selectively stabilizes FdU-substituted DNA through a unique major groove binding motif

We report, based on semi-empirical calculations, that Zn(2+) binds duplex DNA containing consecutive FdU-dA base pairs in the major groove with distorted trigonal bipyramidal geometry. In this previously uncharacterized binding motif, O4 and F5 on consecutive FdU are axial ligands while three water molecules complete the coordination sphere. NMR spectroscopy confirmed Zn(2+) complexation occurred with maintenance of base pairing while a slight hypsochromic shift in circular dichroism (CD) spectra indicated moderate structural distortion relative to B-form DNA. Zn(2+) complexation inhibited ethidium bromide (EtBr) intercalation and stabilized FdU-substituted duplex DNA (ΔT(m) > 15 °C). Mg(2+) neither inhibited EtBr complexation nor had as strong of a stabilizing effect. DNA sequences that did not contain consecutive FdU were not stabilized by Zn(2+). A lipofectamine preparation of the Zn(2+)-DNA complex displayed enhanced cytotoxicity toward prostate cancer cells relative to the individual components prepared as lipofectamine complexes indicating the potential utility of Zn(2+)-DNA complexes for cancer treatment.     

The second-shell metal ligands of human arginase affect coordination of the nucleophile and substrate

The active sites of eukaryotic arginase enzymes are strictly conserved, especially the first- and second-shell ligands that coordinate the two divalent metal cations that generate a hydroxide molecule for nucleophilic attack on the guanidinium carbon of l-arginine and the subsequent production of urea and l-ornithine. Here by using comprehensive pairwise saturation mutagenesis of the first- and second-shell metal ligands in human arginase I, we demonstrate that several metal binding ligands are actually quite tolerant to amino acid substitutions. Of >2800 double mutants of first- and second-shell residues analyzed, we found more than 80 unique amino acid substitutions, of which four were in first-shell residues. Remarkably, certain second-shell mutations could modulate the binding of both the nucleophilic water/hydroxide molecule and substrate or product ligands, resulting in activity greater than that of the wild-type enzyme. The data presented here constitute the first comprehensive saturation mutagenesis analysis of a metallohydrolase active site and reveal that the strict conservation of the second-shell metal binding residues in eukaryotic arginases does not reflect kinetic optimization of the enzyme during the course of evolution.     

Structural variation in bacterial glyoxalase I enzymes: investigation of the metalloenzyme glyoxalase I from Clostridium acetobutylicum

The glyoxalase system catalyzes the conversion of toxic, metabolically produced α-ketoaldehydes, such as methylglyoxal, into their corresponding nontoxic 2-hydroxycarboxylic acids, leading to detoxification of these cellular metabolites. Previous studies on the first enzyme in the glyoxalase system, glyoxalase I (GlxI), from yeast, protozoa, animals, humans, plants, and Gram-negative bacteria, have suggested two metal activation classes, Zn(2+) and non-Zn(2+) activation. Here, we report a biochemical and structural investigation of the GlxI from Clostridium acetobutylicum, which is the first GlxI enzyme from Gram-positive bacteria that has been fully characterized as to its three-dimensional structure and its detailed metal specificity. It is a Ni(2+)/Co(2+)-activated enzyme, in which the active site geometry forms an octahedral coordination with one metal atom, two water molecules, and four metal-binding ligands, although its inactive Zn(2+)-bound form possesses a trigonal bipyramidal geometry with only one water molecule liganded to the metal center. This enzyme also possesses a unique dimeric molecular structure. Unlike other small homodimeric GlxI where two active sites are located at the dimeric interface, the C. acetobutylicum dimeric GlxI enzyme also forms two active sites but each within single subunits. Interestingly, even though this enzyme possesses a different dimeric structure from previously studied GlxI, its metal activation characteristics are consistent with properties of other GlxI. These findings indicate that metal activation profiles in this class of enzyme hold true across diverse quaternary structure arrangements.     

High resolution X-ray structures of different metal-substituted forms of phosphotriesterase from Pseudomonas diminuta

Phosphotriesterase, isolated from the soil-dwelling bacterium Pseudomonas diminuta, catalyzes the detoxification of organophosphate-based insecticides and chemical warfare agents. The enzyme has attracted significant research attention in light of its possible employment as a bioremediation tool. As naturally isolated, the enzyme is dimeric. Each subunit contains a binuclear zinc center that is situated at the C-terminal portion of a "TIM" barrel motif. The two zincs are separated by approximately 3.4 A and coordinated to the protein via the side chains of His 55, His 57, His 201, His 230, Asp 301, and a carboxylated Lys 169. Both Lys 169 and a water molecule (or hydroxide ion) serve to bridge the two zinc ions together. Interestingly, these metals can be replaced with cadmium or manganese ions without loss of enzymatic activity. Here we describe the three-dimensional structures of the Zn(2+)/Zn(2+)-, Zn(2+)/Cd(2+)-, Cd(2+)/Cd(2+)-, and Mn(2+)/Mn(2+)-substituted forms of phosphotriesterase determined and refined to a nominal resolution of 1.3 A. In each case, the more buried metal ion, referred to as the alpha-metal, is surrounded by ligands in a trigonal bipyramidal ligation sphere. For the more solvent-exposed or beta-metal ion, however, the observed coordination spheres are either octahedral (in the Cd(2+)/Cd(2+)-, Mn(2+)/Mn(2+)-, and the mixed Zn(2+)/Cd(2+)-species) or trigonal bipyramidal (in the Zn(2+)/Zn(2+)-protein). By measuring the anomalous X-ray data from crystals of the Zn(2+)/Cd(2+)-species, it has been possible to determine that the alpha-metal ion is zinc and the beta-site is occupied by cadmium.     

Zinc-thiolate intermediate in catalysis of methyl group transfer in Methanosarcina barkeri.

Methyl group transfer reactions are essential in methane-forming pathways in all methanogens. The involvement of zinc in catalysis of methyl group transfer was studied for the methyltransferase enzyme MT2-A important for methanogenesis in Methanosarcina barkeri growing on methylamines. Zinc was shown to be required for MT2-A activity and was tightly bound by the enzyme with an apparent stability constant of 10(13.7) at pH 7.2. Oxidation was a factor influencing activity and metal stoichiometry of purified MT2-A preparations. Methods were developed to produce inactive apo MT2-A and to restore full activity with stoichiometric reincorporation of Zn(2+). Reconstitution with Co(2+) yielded an enzyme with 16-fold higher specific activity. Cysteine thiolate coordination in Co(2+)-MT2-A was indicated by high absorptivity in the 300-400 nm charge transfer region, consistent with more than one thiolate ligand at the metal center. Approximate tetrahedral geometry was indicated by strong d-d transition absorbance centered at 622 nm. EXAFS analyses of Zn(2+)-MT2-A revealed 2S + 2N/O coordination with evidence for involvement of histidine. Interaction with the substrate CoM (2-mercaptoethanesulfonic acid) resulted in replacement of the second N/O group with S, indicating direct coordination of the CoM thiolate. UV-visible spectroscopy of Co(2+)-MT2-A in the presence of CoM also showed formation of an additional metal-thiolate bond. Binding of CoM over the range of pH 6.2-7.7 obeyed a model in which metal-thiolate formation occurs separately from H(+) release from the enzyme-substrate complex. Proton release to the solvent takes place from a group with apparent pK(a) of 6.4, and no evidence for metal-thiolate protonation was found. It was determined that substrate metal-thiolate bond formation occurs with a Delta G degrees ' of -6.7 kcal/mol and is a major thermodynamic driving force in the overall process of methyl group transfer.