Carbonic anhydrase inhibitors: X-ray crystallographic structure of the adduct of human isozyme II with EMATE, a dual inhibitor of carbonic anhydrases and steroid sulfatase

The X-ray crystal structure for the adduct of human carbonic anhydrase II (hCA II) with estrone-3-O-sulfamate (EMATE), an antiendocrine agent showing both CA and estrone sulfatase inhibitory properties, has been resolved at a resolution of 1.5A. Its binding to the enzyme is similar to that of other sulfamates/sulfonamides, considering the interactions of the zinc anchoring group, but differs considerably when the steroidal scaffold of the inhibitor is analyzed. This part of the inhibitor interacts only within the hydrophobic half of the CA active site, interacting with residues Val 121, Phe 131, Val 135 and Pro 202, and leaving the hydrophilic half able to accommodate several water molecules not present in the uncomplexed enzyme. In addition, a very short bond of 1.78A between the zinc ion and the coordinated nitrogen atom of the sulfamate moiety is observed, which may explain the high affinity of this inhibitor for hCA II (K(i) of 10nM).     

Rapid sodium cyanide depletion in cell culture media: outgassing of hydrogen cyanide at physiological pH

During the course of in vitro studies on cyanide exposure with SH-SY5Y human neuroblastoma cells, we found that sodium cyanide (NaCN) up to a concentration of 10 mM had no significant toxic effect under our culture conditions. Further investigation of this apparent cyanide resistance revealed that the sodium cyanide was being rapidly depleted from the cell culture medium. Cyanide was interacting with constituents of the cell culture medium and was somehow being detoxified or removed from solution. The reaction of cyanide with cell culture media in 96-well culture plates reduced cyanide concentrations rapidly (80-90% in 2 h at 37 degrees C). Running the same reaction in capped tubes significantly reduced cyanide loss from solution. Incubation of cyanide with individual constituents of the cell culture medium in solution showed that glucose, phenol red, and amino acids all acted to detoxify or remove cyanide from solution. When amino acids or buffers were incubated with sodium cyanide in aqueous solution at pH 7.4, hydrogen cyanide (HCN) was found to degas from the solutions. We compared HCN outgassing over a range of pH values. As expected, HCN remained very soluble at high pH, but as the pH was reduced to 7.0, the rate of HCN formation and outgassing increased dramatically. Acid-base reactions involving cyanide and proton donors, such as amino acids and other cell culture media constituents, at physiological pH result in rapid HCN outgassing from solution at 37 degrees C. These results indicate that previous in vitro cyanide toxicity studies done in standard culture media with prolonged incubation times using gas-exchanging culture containers might have to be reevaluated in light of the fact that the effective cyanide concentrations in the culture media were significantly lower than reported.     

Chloride binding to alkaline phosphatase. 113Cd and 35Cl NMR

Chloride binding to alkaline phosphatase from Escherichia coli has been monitored by 35Cl NMR for the native zinc enzyme and by 113Cd NMR for two Cd(II)-substituted species, phosphorylated Cd(II)6 alkaline phosphatase and unphosphorylated Cd(II)2 alkaline phosphatase. Of the three metal binding sites per enzyme monomer, A, B, and C, only the NMR signal of 113Cd(II) at the A sites shows sensitivity to the presence of Cl-, suggesting that Cl- coordination occurs at the A site metal ion. From the differences in the chemical shift changes produced in the A site 113Cd resonance for the covalent (E-P) form of the enzyme versus the noncovalent (E . P) form of the enzyme, it is concluded that the A site metal ion can assume a five-coordinate form. The E-P form of the enzyme has three histidyl nitrogens as ligands from the protein to the A site metal ion plus either two water molecules or two Cl- ions as additional monodentate ligands. In the E . P form, there is a phosphate oxygen as a monodentate ligand and either a water molecule or a Cl- ion as the additional monodentate ligand. The shifts of the 113Cd NMR signals of the unphosphorylated Cd(II)2 enzyme induced by Cl- are very similar to those induced in the E-P derivative of the same enzyme, supporting the conclusion that the phosphoseryl residue is not directly coordinated to any of the metal ions. Specific broadening of the 35Cl resonance from bulk Cl- is induced by Zn(II)4 alkaline phosphatase, while Zn(II)2 alkaline phosphatase is even more effective, suggesting an influence by occupancy of the B site on the interaction of monodentate ligands at the A site. A reduction in this quadrupolar broadening is observed upon phosphate binding at pH values where E . P is formed, but not at pH values where E-P is the major species, confirming a specific interaction of Cl- at the A site, the site to which phosphate is bound in E . P, but not in E-P. For the zinc enzyme, a significant decrease in phosphate binding affinity can be shown to occur at pH 8 where one monomer has a higher affinity than the other.     

Organization of an efficient carbonic anhydrase: implications for the mechanism based on structure-function studies of a T199P/C206S mutant

Substitution of Pro for Thr199 in the active site of human carbonic anhydrase II (HCA II)(1) reduces its catalytic efficiency about 3000-fold. X-ray crystallographic structures of the T199P/C206S variant have been determined in complex with the substrate bicarbonate and with the inhibitors thiocyanate and beta-mercaptoethanol. The latter molecule is normally not an inhibitor of wild-type HCA II. All three ligands display novel binding interactions to the T199P/C206S mutant. The beta-mercaptoethanol molecule binds in the active site area with its sulfur atom tetrahedrally coordinated to the zinc ion. Thiocyanate binds tetrahedrally coordinated to the zinc ion in T199P/C206S, in contrast to its pentacoordinated binding to the zinc ion in wild-type HCA II. Bicarbonate binds to the mutant with two of its oxygens at the positions of the zinc water (Wat263) and Wat318 in wild-type HCA II. The environment of this area is more hydrophilic than the normal bicarbonate-binding site of HCA II situated in the hydrophobic part of the cavity normally occupied by the so-called deep water (Wat338). The observation of a new binding site for bicarbonate has implications for understanding the mechanism by which the main-chain amino group of Thr199 acquired an important role for orientation of the substrate during the evolution of the enzyme.     

3D structure of Sulfolobus solfataricus carboxypeptidase developed by molecular modeling is confirmed by site-directed mutagenesis and small angle X-ray scattering

Sulfolobus solfataricus carboxypeptidase (CPSso) is a thermostable zinc-metalloenzyme with a M(r) of 43,000. Taking into account the experimentally determined zinc content of one ion per subunit, we developed two alternative 3D models, starting from the available structures of Thermoactinomyces vulgaris carboxypeptidase (Model A) and Pseudomonas carboxypeptidase G2 (Model B). The former enzyme is monomeric and has one metal ion in the active site, while the latter is dimeric and has two bound zinc ions. The two models were computed by exploiting the structural alignment of the one zinc- with the two zinc-containing active sites of the two templates, and with a threading procedure. Both computed structures resembled the respective template, with only one bound zinc with tetrahedric coordination in the active site. With these models, two different quaternary structures can be modeled: one using Model A with a hexameric symmetry, the other from Model B with a tetrameric symmetry. Mutagenesis experiments directed toward the residues putatively involved in metal chelation in either of the models disproved Model A and supported Model B, in which the metal-binding site comprises His(108), Asp(109), and His(168). We also identified Glu(142) as the acidic residue interacting with the water molecule occupying the fourth chelation site. Furthermore, the overall fold and the oligomeric structure of the molecule was validated by small angle x-ray scattering (SAXS). An ab initio original approach was used to reconstruct the shape of the CPSso in solution from the experimental curves. The results clearly support a tetrameric structure. The Monte Carlo method was then used to compare the crystallographic coordinates of the possible quaternary structures for CPSso with the SAXS profiles. The fitting procedure showed that only the model built using the Pseudomonas carboxypeptidase G2 structure as a template fitted the experimental data.     

Binding of ligands to the catalytic zinc ion in horse liver alcohol dehydrogenase

The affinity of nitrogen and sulfur ligands for the catalytic zinc ion in horse liver alcohol dehydrogenase has been investigated by their influence on the affinity labeling reaction with iodoacetate. All the nitrogen compounds including ammonia, a primary and a secondary amine, and heterocycles containing a pyridine-type nitrogen with the exception of 2,2-dipyridyl were found to activate the affinity labeling reaction. Activation results from inner-sphere ligand coordination to the catalytic zinc ion. Closely related pyridine compounds gave a regular increase in affinity for the enzyme with increasing basicity, as expected for coordination to a metal ion. The sulfur compounds penicillamine and mercaptoethanol also activated the affinity labeling reaction, but dimercaptopropanol bound very tightly as a bidentate inhibited the reaction. The anions hydrosulfide, diethyldithiocarbamate, and cyanide coordinated to the catalytic zinc ion, whereas azide, thiocyanate, tetrazole, and iodide complexed the anion-binding site. The anionic metal ligands increased the rate of inactivation of the enzyme with iodoacetamide by binding to the catalytic zinc ion, while the binding of iodoacetate to the anion-binding site was prevented.     

Crystallographic studies of inhibitor binding sites in human carbonic anhydrase II: a pentacoordinated binding of the SCN- ion to the zinc at high pH

The binding of four inhibitors--mercuric ion, 3-acetoxymercuri-4-aminobenzenesulfonamide (AMS), acetazolamide (Diamox), and thiocyanate ion--to human carbonic anhydrase II (HCA II) has been studied with X-ray crystallography. The binding of mercury to HCA II at pH 7.0 has been investigated at 3.1 A resolution. Mercuric ions are observed at both nitrogens in the His-64 ring. One of these sites is pointing toward the zinc ion. The only other binding site for mercury is at Cys-206. The binding of the two sulfonamide inhibitors AMS and Diamox, has been reinvestigated at 2.0 and 3.0 A, respectively. Only the nitrogen of the sulfonamide group binds to the zinc ion replacing the hydroxyl ion. The sulfonamide oxygen closest to the zinc ion is 3.1 A away. Thus the tetrahedral geometry of the zinc is retained, refuting earlier models of a pentacoordinated zinc. The structure of the thiocyanate complex has been investigated at pH 8.5 and the structure has been refined at 1.9 A resolution using the least-squares refinement program PROLSQ. The crystallographic R factor is 17.6%. The zinc ion is pentacoordinated with the anion as well as a water molecule bound in addition to the three histidine residues. The nitrogen atom of the SCN- ion is 1.9 A from the zinc ion but shifted 1.3 A with respect to the hydroxyl ion in the native structure and at van der Waals' distance from the O gamma l atom of Thr-199. This is due to the inability of the O gamma l atom of Thr-199 to serve as a hydrogen bond donor, thus repelling the nonprotonated nitrogen. The SCN- molecule reaches into the deep end of the active site cavity where the sulfur atom has displaced the so-called "deep" water molecule of the native enzyme. The zinc-bound water molecule is 2.2 A from the zinc ion and 2.4 A from the SCN- nitrogen. In addition, this water is hydrogen bonded to the O gamma l atom of Thr-199 and to another water molecule. We have observed that solvent and inhibitor molecules have three possible binding sites on the zinc ion and their significance for the catalysis and inhibition of HCA II will be discussed. All available crystallographic data are consistent with a proposed catalytic mechanism in which both the OH moiety and one oxygen of the substrate HCO3- ion are ligated to the zinc ion.     

Metal poison inhibition of carbonic anhydrase

Carbonic anhydrase is inhibited by the “metal poison” cyanide. Several spectroscopic investigations of carbonic anhydrase where the natural zinc ion has been replaced by cobalt have further strengthened the view that cyanide and cyanate bind directly to the metal. We have determined the structure of human carbonic anhydrase II inhibited by cyanide and cyanate, respectively, by X-ray crystallography. It is shown that the inhibitors replace a molecule of water, which forms a hydrogen bond to the peptide nitrogen of Thr-199 in the native structure. The coordination of the zinc ion is hereby left unaltered compared to the native crystal structure, so that the zinc coordinates three histidines and one molecule of water or hydroxyl ion in a tetrahedral fashion. The binding site of the two inhibitors is identical to what earlier has been suggested to be the position of the substrate (CO₂) when attacked by the zinc bound hydroxyl ion. The peptide chain undergoes no significant alterations upon binding of either inhibitor. © 1993 Wiley-Liss, Inc.     

Biosorption of iron(III)–cyanide complex anions to Rhizopus arrhizus: application of adsorption isotherms

The biosorption of iron(III)–cyanide complex anions to Rhizopus arrhizus was investigated. The iron(III)–cyanide complex ion binding capacity of the biosorbent was a function of initial pH, initial iron(III)–cyanide complex ion and biosorbent concentration. These results indicated that a significant reduction of iron(III)–cyanide complex ions was achieved at pH 13, a highly alkaline condition. The maximum loading capacity of biosorbent was 612·2 mg g⁻¹ at 1996·2 mg litre⁻¹ initial iron(III)–cyanide complex ion concentration at this pH. The Freundlich, Langmuir and Redlich–Peterson adsorption models were fitted to the equilibrium data at pH 3·0, 7·0 and 13·0. The equilibrium data could be best fitted to by all the adsorption models over the entire concentration range (50–2000 mg litre⁻¹) at pH 13.     

pH Dependence of heme iron coordination, hydrogen peroxide reactivity, and cyanide binding in cytochrome c peroxidase(H52K)

Replacement of the distal histidine, His-52, in cytochrome c peroxidase (CcP) with a lysine residue produces a mutant cytochrome c peroxidase, CcP(H52K), with spectral and kinetic properties significantly altered compared to those of the wild-type enzyme. Three spectroscopically distinct forms of the enzyme are observed between pH 4.0 and 8.0 with two additional forms, thought to be partially denatured forms, making contributions to the observed spectra at the pH extremes. CcP(H52K) exists in at least three, slowly interconverting conformational states over most of the pH range that was investigated. The side chain epsilon-amino group of Lys-52 has an apparent pK(a) of 6.4 +/- 0.2, and the protonation state of Lys-52 affects the spectral properties of the enzyme and the reactions with both hydrogen peroxide and HCN. In its unprotonated form, Lys-52 acts as a base catalyst facilitating the reactions of both hydrogen peroxide and HCN with CcP(H52K). The major form of CcP(H52K) reacts with hydrogen peroxide with a rate approximately 50 times slower than that of wild-type CcP but reacts with HCN approximately 3 times faster than does the wild-type enzyme. The major form of the mutant enzyme has a higher affinity for HCN than does native CcP.     

Crystal structure of a zinc-activated variant of human carbonic anhydrase I,CA I Michigan 1: evidence for a second zinc binding site involving arginine coordination

The human genetic variant carbonic anhydrase I (CA I) Michigan 1 results from a single point mutation that changes His 67 to Arg in a critical region of the active site. This variant of the zinc metalloenzyme appears to be unique in that it possesses an esterase activity that is specifically enhanced by added free zinc ions. We have determined the three-dimensional structure of human CA I Michigan 1 by X-ray crystallography to a resolution of 2.6 A. In the absence of added zinc ions, the mutated residue, Arg 67, points out of the active site, hydrogen bonding with the carboxylate of Asn 69. This contrasts with the orientation of His 67, in the native isozyme, which points into the active site. The orientations of His 94, His 96, and His 119, that coordinate the catalytic zinc ion, and of the catalytically critical Thr 199-Glu 106 hydrogen bonding system, are largely unchanged in the mutant. The structure of an enzyme adduct with a second zinc bound was determined to a resolution of 2.0 A. The second zinc ion is coordinated to His 64, His 200, and Arg 67. This arginine residue reverses its orientation on zinc binding and turns into the active site. The residues at these three positions have been implicated in determining the specific kinetic properties of native CA I. This is, to our knowledge, the first example of a zinc ion coordinating with an arginine residue in a Zn(II) enzyme.     

Binding of thiocyanate and cyanide to manganese(III)-reconstituted horseradish peroxidase: a 15N nuclear magnetic resonance study

Binding of thiocyanate and cyanide ions to Mn(III) protoporphyrin-apohorseradish peroxidase complex [Mn(III)HRP] was investigated by relaxation rate measurements (at 50.68 MHz) of 15N resonance of SC15N- and C15N-. At pH = 4.0 the apparent dissociation constant (KD) for thiocyanate and cyanide binding to Mn(III)HRP was deduced to be 156 and 42 mM, respectively. The pH dependence of the 15N line width as well as apparent dissociation constant for thiocyanate and cyanide binding were quantitatively analyzed on the basis of a reaction scheme in which thiocyanate and cyanide in deprotonated form bind to the enzyme in a protonated form. The binding of thiocyanate and cyanide to Mn(III)HRP was found to be facilitated by protonation of an ionizable group on the enzyme [Mn(III)HRP] with a pKa = 4.0. From competitive binding studies it was shown that iodide, thiocyanate and cyanide bind to Mn(III)HRP at the same site; however, the binding site for resorcinol is different. The apparent dissociation constant for iodide binding deduced from competitive binding studies was found to be 117 mM, which agrees very well with the iodide binding to ferric HRP. The binding of thiocyanate and cyanide was shown to be away from the metal center and the distance of the 15N of thiocyanate and cyanide from the paramagnetic manganese ion in Mn(III)HRP was found to be 6.9 and 6.6 A, respectively. Except for cyanide binding, these observations parallel with the iodide and thiocyanate ion binding to native Fe(III)HRP. Water proton relaxivity measurements showed the presence of a coordinated water molecule to Mn(III)HRP with the distance of Mn-H2O being calculated to be 2.6 A. The slow reactivity of H2O2 towards Mn(III)HRP could be attributed to the presence of water at the sixth coordination position of the manganese ion.     

A nuclear magnetic resonance study of cobalt II alcohol dehydrogenase: Substrate analog-metal interactions

Two models for the active site of liver alcohol dehydrogenase (EC 1.1.1.1) have been proposed. Results of X-ray diffraction studies (B.V. Plapp, H. Eklund, and C.-I. Brändén, 1978, J. Mol. Biol.122, 23–32) on the native enzyme indicate that substrates are directly coordinated to the active site zinc ion, while NMR studies (D. L. Sloan, J. M. Young, and A. S. Mildvan, Biochemistry14, 1998–2008) on the Co II enzyme indicate that substrates are not bound directly to the metal. It was unclear whether the basis for this difference was structural or technical. Therefore, this NMR study has been done with wellcharacterized zinc and cobalt enzymes, and to facilitate comparison with X-ray diffraction data, the substrate analogs chosen were dimethyl sulfoxide and trifluoroethanol. Binding of either analog to the zinc enzyme in the presence of the appropriate cofactor produced unique changes in the T₁ and T₂ relaxation rates of the ${}^1\text{H}$ and ${}^{19}\text{F}$ nuclei. Similar results were obtained when cobalt enzyme was used for T₁ measurements, but relaxation was more rapid due to the presence of the paramagnetic ion. From these data, the distances between the analog nuclei and the catalytic site cobalt ion were calculated to be 8.9 ± 0.9 and 10.5 ± 1.2 Å for the cobalt enzyme-NADH-dimethyl sulfoxide and the cobalt enzyme-NAD⁺-F₃CCH₂OH complexes, respectively. The distances are comparable and the magnitudes indicate that the functional groups are not directly coordinated to the active site cobalt ion. These values are in good agreement with those previously reported by Sloan et al. (1975) for the cobalt enzyme-NADH-isobutyramide complex, and are consistent with their model in which a metal water ligand forms a bridge between the substrate and the metal. Therefore, there must be a structural basis for the differences observed in magnetic resonance versus X-ray diffraction studies.     

A study of ligand binding to spleen myeloperoxidase

The ligand binding properties of spleen myeloperoxidase, a peroxidase formerly called "the spleen green hemeprotein", were studied as functions of temperature and pH, using chloride and cyanide as exogenous ligands. Ligand binding is influenced by a proton dissociable group with a pKa of 4. The protonated, uncharged form of cyanide binds to the unprotonated form of the enzyme, while chloride ion binds to the enzyme when this group is protonated. In both cyanide and chloride binding, the pH-dependent change in the apparent ligand affinity is due to a change in the apparent association rate with pH. The proton dissociable group on the enzyme involved in ligand binding has a delta H value of about 8 kcal . mol-1. The present results suggest that this ionizable group is the imidazole group of a histidine residue located near the ligand binding site.     

Exploring the role and the binding affinity of a second zinc equivalent in B. cereus metallo-beta-lactamase

Metallo-beta-lactamases are a newly characterized family of zinc enzymes present in several pathogenic strains that represent an emerging clinical threat. Enzymes from different organisms exhibit an outstanding functional diversity, particularly in the metal ion requirements for activity. We have investigated the effect of the second zinc(II) equivalent in the enzyme betaLII from Bacillus cereus, naturally active in the mono-zinc(II) form. The enzyme is reversibly inactivated at low pH, due to dissociation of the two zinc(II) equivalents. The pH profile indicates that zinc-bound water in the mono-zinc(II) enzyme possesses a pK(a) below 4.9, indicating that a second zinc(II) equivalent is not needed for nucleophile activation. Instead, the second zinc(II) may contribute to properly anchor Asp120, that ultimately orients the attacking nucleophile in binuclear enzymes. This role may be fulfilled by Arg121 in mono-zinc enzymes, as suggested by the kinetic study of the R121C mutant in betaLII. In addition, it is demonstrated that Arg121 is not responsible for the low binding affinity of betaLII toward a second zinc(II) equivalent.     

Unique cyanide nitrogen-15 nuclear magnetic resonance chemical shift values for cyano-peroxidase complexes. Relevance to the heme active-site structure and mechanism of peroxide activation

Cyanide ion has been utilized to probe the heme environment of the ferric states of horseradish peroxidase, lactoperoxidase and chloroperoxidase. The 15N-NMR signal for cyanide bound to these enzymes is located in the downfield region from 578 to 412 ppm (with respect to the nitrate ion reference). The corresponding signal for met-forms of hemoglobin, myoglobin and cytochrome c is much further downfield in the 1047-847 ppm region. The signal position for peroxidases is quite invariant with pH in the physiological ranges. The upfield bias for peroxidase chemical shifts must reflect unique trans iron(III) ligand types and/or proximal-group hydrogen bonding or steric effects. Model compound studies reveal a significant upfield cyanide 15N shift with addition of agents capable of hydrogen-bonding to the coordinated cyanide ion. An even more striking upfield shift of 277 ppm is associated with deprotonation of a trans imidazole residue. The distinctive chemical shifts observed for the cyano ligand in peroxidases support the hypothesis that a distal hydrogen-bonding network and perhaps a polar, basic trans ligand are essential for O-O bond activation by peroxidases.     

Coordinate repression of cholesterol biosynthesis and cytoplasmic 3-hydroxy-3-methylglutaryl coenzyme A synthase by glucocorticoids in HeLa cells.

The stability constants for the calcium and magnesium complexes of rhodanese are >10⁵m^?1 at both high and low substrate concentrations. The stoichiometry of alkaline earth metal ion binding totals close to 1 per 18,500 molecular weight. The usual assay reagents contain sufficient amounts of these metal ions to maintain added enzyme in its metal-complexed form. When reaction mixtures are treated with oxalate to remove calcium ions, inhibition of rhodanese activity is virtually complete under circumstances such that the contribution of magnesium ion is low.Zinc and a number of transition metal ions are inhibitors of rhodanese activity. Studies of the concentration dependence of these effects with zinc, copper, and nickel showed that: 1) Some cyanide complexes of these metals are competitive with the donor substrate, thiosulfate ion. The binding of the copper and zinc complexes is mutually competitive. 2) Another cyanide species of copper appears to combine with the free enzyme to form a functionally active complex. 3) The zinc cyanide species with a net positive charge is an inhibitor competitive with the acceptor substrate, cyanide ion.All of these observations are consistent with a model in which metal ions serve as the electrophilic site of rhodanese.     

Magnetic resonance studies on the copper site of dopamine beta-monooxygenase in the presence of cyanide and azide anions

In order to elucidate the coordination state of water molecules in the Cu(II) site of dopamine [( 3,4-dihydroxyphenyl)ethylamine] beta-monooxygenase, measurements of the paramagnetic 1H nuclear magnetic relaxation rate of solvent water in the enzyme solution containing cyanide or azide as an exogenous ligand were carried out to obtain the values of intrinsic paramagnetic relaxation rate decrements Rp1 and Rp2 for the ligand-enzyme 1:1 and 2:1 complexes, respectively. Rp1 (percent) values were 53 (pH 5.5) and 52 (pH 7.0) for cyanide and 38 (pH 5.5) and 32 (pH 7.0) for azide, while Rp2 (percent) values were 98 (pH 5.5) and 96 (pH 7.0) for azide. Although no Rp2 values for cyanide were obtained because of its reducing power at the Cu(II) site, the Rp1 and Rp2 values obtained above prove that the Cu(II) center has two coordinated water molecules that are exchangeable for exogenous ligands at either pH. Supporting evidence was provided by electron paramagnetic resonance (EPR) titration, in which the enzyme solution containing cyanide-enzyme (1:1) complex in an equal proportion to uncomplexed enzyme gave an observed paramagnetic relaxation rate decrement, Rp, of 23%. Another characteristic of the Rp1 and Rp2 values was their invariability with respect to pH, indicating that the three-dimensional structure of the Cu(II) site is pH-invariant within the range examined. Binding constants of ligand to enzyme Kb1 and Kb2 for 1:1 and 2:1 complex formation, respectively, were also determined through an analysis of the Rp values; it was found that Kb1 was larger than Kb2 irrespective of pH. (ABSTRACT TRUNCATED AT 250 WORDS)     

Kinetics of cyanide binding to Chromatium vinosum ferricytochrome c'

The kinetics of the reversible binding of cyanide by the ferric cytochrome c' from Chromatium vinosum have been studied over the pH range 6.9-9.6. The reaction is extremely slow at neutral pH compared to the reactions of other high-spin ferric heme proteins with cyanide. The observed bimolecular rate constant at pH 7.0 is 2.25 X 10(-3) M-1 s-1, which is approximately 10(7)-fold slower than that for peroxidases, approximately 10(5)-fold slower than those for hemoglobin and myoglobin, and approximately 10(2)-fold to approximately 10(3)-fold slower than that recently reported for the Glycera dibranchiata hemoglobin, which has anomalously slow cyanide rate constants of 4.91 X 10(-1), 3.02 X 10(-1), and 1.82 M-1 s-1 for components II, III, and IV, respectively [Mintorovitch, J., & Satterlee, J. D. (1988) Biochemistry 27, 8045-8050; Mintorovitch, J., Van Pelt, D., & Satterlee, J. D. (1989) Biochemistry 28, 6099-6104]. The unusual ligand binding property of this cytochrome c' is proposed to be associated with a severely hindered heme coordination site. Cyanide binding is also characterized by a nonlinear cyanide concentration dependence of the observed rate constant at higher pH values, which is interpreted as involving a change in the rate-determining step associated with the formation of an intermediate complex between the cytochrome c' and cyanide prior to coordination. The pH dependence of both the binding constant for the formation of the intermediate complex and the association rate constant for the subsequent coordination to the heme can be attributed to the ionization of HCN, where cyanide ion binding is the predominant process.(ABSTRACT TRUNCATED AT 250 WORDS)