Reduction of methemerythrin by dithionite ion

The reduction of methemerythrin (Hr⁺) by dithionite produces deoxyhemerythrin (Hr^o) in multi, possibly three, stages. The kinetics were examined at pH 8·2 and 25 °C. The first stage is reduction of methemerythrin to an intermediate A by SO₂^- (k = 1.3 × 10⁵m^?1s^?1). The much slower second and third stages have rates independent of dithionite concentrations. Reaction is completed after about 10 h. The kinetics of reactions of A with N₃^-, H₂O₂, and O₂ were examined, as well as the conversion of A to intermediate B (k = 4·4 × 10^?4s^?1). It is concluded that A is an (Fe(II)Fe(III))₈ species, and that in B the unit (Fe(II)Fe(II))₈ is well developed, judging by its unreactivity towards N₃^?, its reaction with H₂O₂, and its reversible uptake of O₂ (85–90% of the final product). There is little effect of adjusting the pH to 6·3 on the rates of the processes examined.     

Reduction of methemerythrin-anion adducts by dithionite ion

The reduction by dithionite ion (in excess) of methemerythrin-anion adducts, Hr+X-, to deoxyhemerythrin, Hr degree, has been examined at 25 degrees and pH 6.3 and 8.2. The results accord with the scheme: S2O42- in equilibrium 2SO2- rapid Hr+X- in equilibrium Hr++X- k-1, k1 Hr++SO2- leads to PRODUCT k2 with X- = Br-, HCO2-, CNO-, and F-, k2[SO2-] greater than k1[X-], and the pseudo first-order rate constant, kobs (= k-1), is independent of [X-] and [S2O42-]. Only with X- = NCS- is k2[SO2-] approximately k1[X-] and kobs = a[S2O42-]1/2 (b[NCS-] + [S2OR2-]1/2)-1. Values at pH 6.3 of k-1 (sec-1) and k1 (M-1 sec-1), obtained by anation and anion displacement reactions, are 2.3 x 10(-3), 1.6 x 10(-2) (Br-); 1.5 x 10(-3), 1.2 x 10(-2) (HCO2-); 1.3 x 10(-4), 0.52 (CNO-) and approximately 2 x 10(-4), 3.3 x 10(-3) (CN-, pH 7.0). Values of k-1 from reduction and displacement methods are in good agreement with each other. The value of k2 (1.6 x 10(5) M-1 sec-1, pH 6.3) in somewhat smaller than that for reduction of the met form of hemoproteins. There is only a small effect of pH on rates. Direct reduction of Hr+CN- does not occur, in contrast with Mb+CN-.     

Reduction of mercuric ion in vitro by superoxide anion

The reduction rate of mercuric ion to metallic mercury by a superoxide anion produced by a xanthine-xanthine oxidase system increased with an increased concentration of xanthine oxidase in the presence of enough xanthine. The reduction rate of mercuric ion by a superoxide anion in the presence of nitroblue tetrazolium (NBT) was proportional to the concentration of NBT. The result suggests that NBT was reduced to diformazan by a superoxide anion produced by a xanthine-xanthine oxidase system and that mercuric ion will be reduced to metallic mercury by diformazan. The reduction rate of mercuric ion was also indicative that a superoxide anion produced by an NADH-phenazine methosulfate (PMS) system increased with an increased concentration of PMS.     

Reduction by dithionite ion of adducts of metmyoglobin with imidazole, pyridine, and derivatives

The rate and equilibrium constants for the information of a number of metmyoglobin species Mb+X (X = imidazole, imidazole-H-, 1-methylimidazole, 2-methylimidazole, 4-nitroimidazole, 2-methyl-5-nitroimidazole, pyridine, 2-, 3-, and 4-picoline) and the rates of their reduction by dithionite have been measured at 25 degrees. Several different kinds of kinetic behavior for the reduction were observed. In all cases, a rate constant for direct reaction of Mb+X with SO2- can be assessed. The data strongly support attack of SO2- on the ligand, followed by electron transfer through the pi system to the metal ion.     

The lactoperoxidase system links anion transport to host defense in cystic fibrosis

Chronic respiratory infections in cystic fibrosis result from CFTR channel mutations but how these impair antibacterial defense is less clear. Airway host defense depends on lactoperoxidase (LPO) that requires thiocyanate (SCN-) to function and epithelia use CFTR to concentrate SCN- at the apical surface. To test whether CFTR mutations result in impaired LPO-mediated host defense, CF epithelial SCN- transport was measured. CF epithelia had significantly lower transport rates and did not accumulate SCN- in the apical compartment. The lower CF [SCN-] did not support LPO antibacterial activity. Modeling of airway LPO activity suggested that reduced transport impairs LPO-mediated defense and cannot be compensated by LPO or H2O2 upregulation.     

The transformation of chlorophenols by lactoperoxidase

The lactoperoxidase-catalyzed transformations of penta-, 2,3,4,6,-tetra-, 2,4,6,-tri, 2,4,-di- and 4-monochlorophenol were followed spectrophotometrically. Apparent stoichiometries of chlorophenol: H₂O₂ ranged from 1:1 for the tri- and tetrachlorophenol at pH 7 to 5:2 for pentachlorophenol at pH 4. The initial velocity (ν₀) was only slightly influenced by changes in [H₂O₂] ? 5 μM. ν₀ responded to [chlorophenol] according to the empirical expression ν₀ = [lactoperoxidase]·(k₁[chlorphenol] + k₂[chlorophenol]²). The constant k₁ was found to be 5.8 · 10⁵, 1.8 · 10⁶, 1.9 · 10⁶ M^?1 · s^?1 for the protonated forms of penta-, tetra- and trichlorophenol, respectively, at pH 7. With the di- and monochlorophenol the solution soon became opaque, and the reaction ceased. The results show that more than one reaction occurs. Some comparisons were also made with horseradish peroxidase A and C. Cetyltrimethylammonium bromide prevented opaqueness, but was shown to be a substrate for lactoperoxidase. Assuming an average concentration of 0.1 μM for H₂O₂ and pentachlorophenol in man, the metabolic rate becomes 30 ng/h per g peroxidase-containing tissue, possibly with deposition of the products.     

Mechanism of nitrite-stimulated catalysis by lactoperoxidase.

The reactions of lactoperoxidase (LPO) intermediates compound I, compound II and compound III, with nitrite (NO2(-)) were investigated. Reduction of compound I by NO2(-) was rapid (k2 = 2.3 x 10(7) M(-1) x s(-1); pH = 7.2) and compound II was not an intermediate, indicating that NO2* radicals are not produced when NO2(-) reacts with compound I. The second-order rate constant for the reaction of compound II with NO2(-) at pH = 7.2 was 3.5 x 10(5) M(-1) x s(-1). The reaction of compound III with NO2(-) exhibited saturation behaviour when the observed pseudo first-order rate constants were plotted against NO2(-) concentrations and could be quantitatively explained by the formation of a 1 : 1 ratio compound III/NO2(-) complex. The Km of compound III for NO2(-) was 1.7 x 10(-4) M and the first-order decay constant of the compound III/ NO2(-) complex was 12.5 +/- 0.6 s(-1). The second-order rate constant for the reaction of the complex with NO2(-) was 3.3 x 10(3) M(-1) x s(-1). Rate enhancement by NO2(-) does not require NO2* as a redox intermediate. NO2(-) accelerates the overall rate of catalysis by reducing compound II to the ferric state. With increasing levels of H2O2, there is an increased tendency for the catalytically dead-end intermediate compound III to form. Under these conditions, the 'rescue' reaction of NO2(-) with compound III to form compound II will maintain the peroxidatic cycle of the enzyme.     

Enzymatic radioiodination of phospholipids catalyzed by lactoperoxidase

Phospholipids were iodinated with iodide by a lactoperoxidase-catalyzed reaction in the presence of controlled amounts of H₂O₂ which were continuously supplied by glucose oxidase + glucose. Different molecular and ionic species of inorganic iodine present in the reaction mixture (i.e., I^?, I₂, I₃^?) were eliminated by thiosulfate reduction to I^? followed by gel filtration on Sephadex LH-20 which separated I^? from the phospholipids completely. Final separation and identification of individual phospholipids were done on a column of silica gel H using a single solvent mixture consisting of CHCl₃:CH₃OH:CH₃COOH:H₂O (25:15:4:2, by volume). Application of phospholipases A₂ and D or transesterification provided evidence to indicate a covalent iodination of the fatty acid moiety of the lipids by the enzymatic process, which apparently is substitution but could also proceed by addition to the double bonds, when present.     

Mechanism-based inhibition of lactoperoxidase by thiocarbamide goitrogens

The irreversible inactivation of bovine lactoperoxidase by thiocarbamide goitrogens was measured, and the kinetics were consistent with a mechanism-based (suicide) mode. Sulfide ion inactivated, 2-mercaptobenzimidazole-inactivated, and 1-methyl-2-mercaptoimidazole-inactivated lactoperoxidases have different visible spectra, suggesting different products were formed. The results support a mechanism in which reactive intermediates are formed by S-oxygenation reactions catalyzed by lactoperoxidase compound II. It is proposed that the reaction of electron-deficient intermediates with the heme prosthetic group is responsible for the observed spectral changes and inactivation by thiocarbamides.     

Kinetics of the oxidation of ferrocyanide by lactoperoxidase compound II

The kinetics of the oxidation of ferrocyanide by lactoperoxidase compound II has been studied over the pH range 5.2-9.9 at 25 degrees C and an ionic strength of 0.11 M. For all pH values, exponential decay curves are obtained for the reaction of compound II in the presence of ferrocyanide which yielded pseudo-first-order rate constants kobs. The spontaneous decay of compound II in the absence of ferrocyanide occurs at an appreciable rate which was measured independently and used in the data analysis. At all pH values two striking effects were observed when the rate of the decay reaction in the presence of ferrocyanide, kobs, was plotted against ferrocyanide concentration: a saturation effect and positive intercepts which are attributable to the spontaneous decay. The plots of kobs versus ferrocyanide concentration were analyzed in terms of the following parameters: a first-order rate constant k3,obs, a Michaelis constant Km,obs and a spontaneous-decay rate constant k4. The parameters k3,obs and Km,obs describe the reaction of compound II with ferrocyanide, independently of the spontaneous decay. The parameter k4 has only a small pH dependence, whereas plots of the logs of k3,obs and Km,obs versus pH have slopes of -1 at high pH. The major part of the pH dependence can be explained by the influence of a single heme-linked acid group in the LPO-compound-II-ferrocyanide complex.