Characterization of hog thyroid peroxidase

Structural stability and heme binding potential of the truncated human dual oxidase 2 (DUOX2) peroxidase domain

The essential role of human dual oxidase 2 (hDUOX2) in thyroid hormone biosynthesis defines this member of the NOX/DUOX family, whose absence due to mutation has been directly related to disease, specifically hypothyroidism. Both human DUOX isoforms, hDUOX1 and hDUOX2, are expressed in thyroid tissue; however, hDUOX1 cannot compensate for inactivation of hDUOX2, suggesting that each enzyme is differentially regulated and/or functions in a unique manner. In efforts to uncover relevant structural and functional differences we have expressed and purified the peroxidase domain of hDUOX2(1-599) for direct comparison with the previously studied hDUOX1(1-593). As was shown for hDUOX1, the truncated hDUOX2 domain purifies without a bound heme co-factor and displays no peroxidase activity. However, hDUOX2(1-599) displays greater stability than hDUOX1(1-593). Surprisingly, upon titration with heme, both isoforms bind heme with a low micromolar affinity, demonstrating that they retain a heme binding site. A conformational difference in the full-length protein and/or a protein-protein interaction may be required to increase the heme binding affinity.

Caenorhabditis elegans and human dual oxidase 1 (DUOX1) "peroxidase" domains: insights into heme binding and catalytic activity

The seven members of the NOX/DUOX family are responsible for generation of the superoxide and H(2)O(2) required for a variety of host defense and cell signaling functions in nonphagocytic cells. Two members, the dual oxidase isozymes DUOX1 and DUOX2, share a structurally unique feature: an N-terminal peroxidase-like domain. Despite sequence similarity to the mammalian peroxidases, the absence of key active site residues makes their binding of heme and their catalytic function uncertain. To explore this domain we have expressed in a baculovirus system and purified the Caenorhabditis elegans (CeDUOX1(1-589)) and human (hDUOX1(1-593)) DUOX1 "peroxidase" domains. Evaluation of these proteins demonstrated that the isolated hDUOX1(1-593) does not bind heme and has no intrinsic peroxidase activity. In contrast, CeDUOX1(1-589) binds heme covalently, exhibits a modest peroxidase activity, but does not oxidize bromide ion. Surprisingly, the heme appears to have two covalent links to the protein despite the absence of a second conserved carboxyl group in the active site. Although the N-terminal dual oxidase motif has been proposed to directly convert superoxide to H(2)O(2), neither DUOX1 domain demonstrated significant superoxide dismutase activity. These results strengthen the in vivo conclusion that the CeDUOX1 protein supports controlled peroxidative polymerization of tyrosine residues and indicate that the hDUOX1 protein either has a unique function or must interact with other protein factors to express its catalytic activity.

Characterization of the heme environment in Arabidopsis thaliana fatty acid alpha-dioxygenase-1

Plant alpha-dioxygenases (PADOX) are hemoproteins in the myeloperoxidase family. We have used a variety of spectroscopic, mutagenic, and kinetic approaches to characterize the heme environment in Arabidopsis thaliana PADOX-1. Recombinant PADOX-1 purified to homogeneity contained 1 mol of heme bound tightly but noncovalently per protein monomer. Electronic absorbance, electron paramagnetic resonance, and magnetic circular dichroism spectra showed a high spin ferric heme that could be reduced to the ferrous state by dithionite. Cyanide bound relatively weakly in the ferric PADOX-1 heme vicinity (K(d) approximately 10 mm) but did not shift the heme to the low spin state. Cyanide was a very strong inhibitor of the fatty acid oxygenase activity (K(i) approximately 5 microm) and increased the K(m) value for oxygen but not that for fatty acid. Spectroscopic analyses indicated that carbon monoxide, azide, imidazole, and a variety of substituted imidazoles did not bind appreciably in the ferric PADOX-1 heme vicinity. Substitution of His-163 and His-389 with cysteine, glutamine, tyrosine, or methionine resulted in variable degrees of perturbation of the heme absorbance spectrum and oxygenase activity, consistent with His-389 serving as the proximal heme ligand and indicating that the heme has a functional role in catalysis. Overall, A. thaliana PADOX-1 resembles a b-type cytochrome, although with much more restricted access to the distal face of the heme than seen in most other myeloperoxidase family members, explaining the previously puzzling lack of peroxidase activity in the plant protein. PADOX-1 is unusual in that it has a high affinity, inhibitory cyanide-binding site distinct from the distal heme face and the fatty acid site.

Role of heme in intracellular trafficking of thyroperoxidase and involvement of H2O2 generated at the apical surface of thyroid cells in autocatalytic covalent heme binding

Thyroperoxidase (TPO) is a glycosylated hemoprotein that plays a key role in thyroid hormone synthesis. We previously showed that in CHO cells expressing human TPO (hTPO) only 2% of synthesized hTPO reaches the cell surface. Herein, we investigated the role of heme moiety insertion in the exit of hTPO from the endoplasmic reticulum. Peroxidase activity at the cell surface and cell surface expression of hTPO were decreased by approximately 30 and approximately 80%, respectively, with succinyl acetone, an inhibitor of heme biosynthesis, and were increased by 20% with holotransferrin and aminolevulinic acid, precursors of heme biosynthesis. Results were similar with holotransferrin plus aminolevulinic acid or hemin, but hemin increased cell surface activity more efficiently (+120%) relative to the control. It had been suggested (DePillis, G., Ozaki, S., Kuo, J. M., Maltby, D. A., and Ortiz de Montellano, P. R. (1997) J. Biol. Chem. 272, 8857-8960) that covalent attachment of heme to mammalian peroxidases could be an H2O2-dependent autocatalytic processing. In our study, heme associated intracellularly with hTPO, and we hypothesized that there was insufficient exposure to H2O2 in Chinese hamster ovary cells before hTPO reached the cell surface. After a 10-min incubation, 10 microM H2O2 led to a 65% increase in cell surface activity. In contrast, in thyroid cells, H2O2 was synthesized at the apical cell surface and allowed covalent attachment of heme. Two-day incubation of primocultures of thyroid cells with catalase led to a 30% decrease in TPO activity at the cell surface. In conclusion, we provide compelling evidence for an essential role of 1) heme incorporation in the intracellular trafficking of hTPO and of 2) H2O2 generated at the apical pole of thyroid cells in the autocatalytic covalent heme binding to the TPO molecule.

Isolation of thyroid peroxidase from patients with Graves' disease and comparison with animal peroxidases

1. Human thyroid peroxidase (TPO) was isolated from 280-640 g of pooled thyroid tissue resected from patients with Graves' disease. 2. Isolation was performed by an improved and simplified method. 3. The Reinheit Zahl (A412/A280) of the final preparations was in the range of 0.16-0.32. 4. The spectroscopic and enzymatic properties of Graves' TPO were compared with those of porcine TPO and bovine LPO, revealing closer resemblance to the former. 5. Graves' TPO may provide a useful substitute for normal TPO, which is very difficult to isolate.

An extended X-ray absorption fine structure investigation of the structure of the active site of lactoperoxidase

Native lactoperoxidase, compound III, and the reduced forms (at pH 6 and 9) were studied using X-ray absorption spectroscopy (XAS). Native lactoperoxidase has four pyrrole nitrogen ligands at an average distance of 2.04 +/- 0.01 A, a proximal ligand at 1.91 +/- 0.02 A, and a sixth (distal) ligand at 2.16 +/- 0.03 A. Lactoperoxidase native enzyme has a first coordination shell structure that is similar to that of native lignin peroxidase [Sinclair, R., Yamazaki, I., Bumpus, J., Brock, B., Chang, C.-S., Albo, A., & Powers, L. (1992) Biochemistry 31, 4892-4900] and different from that of horseradish peroxidase [Chance, B., Powers, L., Ching, Y., Poulos, T., Schonbaum, G., Yamazaki, I., & Paul, K. (1984) Arch. Biochem. Biophys. 235, 596-611]. Similarly, lactoperoxidase compound III resembles lignin peroxidase compound III. The five-coordinated ferrous form was stable at pH 9, but at pH 6 it was rapidly converted to the six-coordinated form with a distal ligand at 2.18 +/- 0.03 A. No evidence typical of changes in spin state was obtained at the different pH values.

The chloroperoxidase from the fungus Curvularia inaequalis; a novel vanadium enzyme

The presence of vanadium-containing bromoperoxidases in various types of seaweed is well-documented. We now report that the terrestrial fungus Curvularia inaequalis excretes a novel chloroperoxidase which also contains vanadium as a prosthetic group. The chloroperoxidase is excreted in the medium as the only protein and is, therefore, almost purely obtained. Atomic absorption spectroscopy measurements showed that the chloroperoxidase contained vanadium, which was essential for enzymatic activity, in a stoichiometry of 1 mol vanadium per mol of enzyme. When the fungus was grown in media containing low concentrations of vanadate (VO4(3-)) or when vanadate was absent, the enzyme was excreted in an apoform. Addition of vanadate to the apoenzyme purified from the medium, dialyzed holo-enzyme or growth medium led to incorporation of the metal and to a subsequent increase in specific activity from 0.7 to about 7.5 units/mg. The reduced enzyme showed an axially symmetric EPR spectrum (g(o) = 1.971, Ao = 91.7 x 10(-4) cm-1) with 16 hyperfine lines that is essentially the same as the EPR spectrum of the vanadium-containing bromoperoxidase of the seaweed Ascophyllum nodosum. This demonstrates that the active sites in the two enzymes are very similar. The chlorinating and brominating activities of the chloroperoxidase from C. inaequalis were also studied and compared to those of the vanadium bromoperoxidase from A. nodosum. The chlorinating reaction catalyzed by the chloroperoxidase had a pH optimum around 5.5 and the Km for Cl- was small (0.25 mM at pH 4.5), but the logarithm of its value increased linearly with increasing pH. At high bromide concentrations, the pH optima of chloroperoxidase and bromoperoxidase in the brominating reaction were about the same (5.5). However, at low bromide concentrations the pH optimum of the chloroperoxidase was at higher pH values than that of the bromoperoxidase.

Inhibition of veratryl alcohol oxidase activity of lignin peroxidase H2 by 3-amino-1,2,4-triazole

The oxidation of veratryl alcohol (3,4-dimethoxybenzyl alcohol) by lignin peroxidase H2 from Phanerochaete chrysosporium and H2O2 was inhibited by 3-amino-1,2,4-triazole (AT). Inhibition was found to be competitive with respect to veratryl alcohol (K1 = 18 microM) and noncompetitive with respect to H2O2. Unlike bovine lactoperoxidase, catalase, and thyroid peroxidase, AT was not a suicide (mechanism based) inhibitor for lignin peroxidase H2. Binding studies revealed that lignin peroxidase H2 catalyzed insignificant binding of [14C]AT to the enzyme. Apparently AT is a poor substrate for lignin peroxidase H2 and is only slowly oxidized to form a yellow product in the presence of H2O2. The formation of the yellow product was shown to increase with increasing concentrations of veratryl alcohol, suggesting that an intermediate in the oxidation of veratryl alcohol is able to mediate the oxidation of AT. Extensive metabolism of AT to CO2 by the white rot fungus Phanerochaete chrysosporium (approximately 60% in 30 days) was also demonstrated.

3-Aminotriazole is a substrate for lactoperoxidase but not for catalase

Rapid scan spectrophotometry has been applied to investigate the reaction of 3-aminotriazole with mammalian heme enzymes, represented by lactoperoxidase and bovine liver catalase. The results clearly indicate that 3-aminotriazole is a substrate for lactoperoxidase compounds I, II and III, but it does not convert catalase compound I to II under conditions favoring peroxidatic activity of the enzyme. The possible physiological significance of these findings is discussed.

Oxidation of the substituted catechols dihydroxyphenylalanine methyl ester and trihydroxyphenylalanine by lactoperoxidase and its compounds

The reactions of native lactoperoxidase and its compound II with two substituted catechols have been investigated by ESR spin stabilization and spin trapping and by rapid scan and conventional spectrophotometric techniques. The catechols are Dopa methyl ester (dihydroxyphenylalanine methyl ester) and 6-hydroxy-Dopa (trihydroxyphenylalanine). o-Semiquinone radicals are formed in the anaerobic reaction of Dopa methyl ester with hydrogen peroxide catalyzed by native lactoperoxidase. The comparable anaerobic reaction of 6-hydroxy-Dopa appears to produce hydroxyl radicals in an unusual reaction. Compound II is reduced back to native lactoperoxidase by both catechols. The reaction between Dopa methyl ester and compound II undergoes an oscillation. The results on the overall lactoperoxidase cycle indicate two successive one-electron reductions of the peroxidase intermediates back to the native enzyme. The resulting free radical formation of o- and p-semiquinones and subsequent formation of stable quinones and Dopachromes is dependent upon the stereochemical arrangement of the catechol hydroxyl groups.

cDNA-directed expression of human thyroid peroxidase

A human thyroid peroxidase cDNA, hTPO-1 [(1987) Proc. Natl. Acad. Sci. USA 84, 5555-5559], was expressed in human Hep G2 cells using a vaccinia virus cDNA-expression system. When examined by immunoblot analysis, the level of hTPO-1 protein expression reached a maximum approx. 24 h after infection and remained at a similar level up to 72 h post-infection. The expressed protein was enzymatically active as measured by guaiacol oxidation. Monoclonal antibody-assisted immunoaffinity column chromatography was used for partial purification of vaccinia-expressed hTPO-1, resulting in more than 300-fold higher specific activity and a measurable difference spectrum of the hTPO-1 (Fe3+)-CN complex.

Evidence for a peroxidatic oxidation of norepinephrine, a catecholamine, by lactoperoxidase

The electron spin resonance-spin stabilization technique has been applied to identify the o-semiquinone intermediate produced during the lactoperoxidase-catalyzed oxidation of the catecholamine norepinephrine. The results of a rapid scan and spectrophotometric investigation of the reaction clearly indicate a normal peroxidatic pathway of catecholamine degradation.

Vanadate activation of bromoperoxidase from Corallina officinalis

A nonheme bromoperoxidase has been purified to homogeneity from the red seaweed Corallina officinalis. Like the corresponding enzyme previously reported from C. pilulifera, this bromoperoxidase contains a significant amount of nonheme iron. However, it is vanadate ion and not iron that activates the enzyme, and maximal activity is achieved with stoichiometric vanadium incorporation. The absence of competition between vanadium and iron suggests that they occupy distinct binding sites in the protein. A correlation between vanadium content and catalytic activity indicates that less than 12 percent of the maximal activity of the enzyme can be derived from metals other than vanadium.

Investigations into lactoperoxidase-catalysed bromination of tyrosine and thyroglobulin

Thyroid peroxidase and lactoperoxidase are capable of producing oxidized bromine species. Thus investigations into bromination reactions with tyrosine and thyroglobulin were undertaken in order to gain insight into possible formation of brominated thyroid hormone analogues. A reversed-phase high-performance liquid chromatographic method was developed for the separation of bromine/iodine-substituted tyrosines and used as a basis for these investigations combined with ultraviolet absorption and electrochemical detection. The results indicate that in vivo bromination of tyrosyl residues in thyroglobulin might be of some importance in cases of either iodine deficiency or excessive bromide intake.

Hydroperoxide-dependent metabolism of goitrogenic thiocarbamides by lactoperoxidase

1. Inhibition of lactoperoxidase by thiocarbamides is consistent with a suicide mechanism whereby enzyme-catalysed S-oxygenation produces reactive intermediates which covalently modify the active site haem. 2. The reaction of thiocarbamide goitrogens with lactoperoxidase in the presence of hydroperoxides results in time-dependent and irreversible enzyme inactivation and an altered visible spectrum of the haem prosthetic group of the inactivated enzyme. 3. A mechanism of S-oxygenation for the inactivation is suggested by lactoperoxidase-catalysed formation of stable S-oxides from thioamide and organosulphur functional groups, and by a common dependence of substrate and inhibitor binding constants on their electrochemical oxidation potentials. 4. Hydroperoxide-dependent inactivation of lactoperoxidase by benzimidazoline-2-thiones occurs concomitantly to the covalent binding of stoichiometric amounts of 14C- or 35S-labelled inhibitors per mole of enzyme, and the formation of turnover products derived from the hydroperoxide cosubstrate and inhibitor.

Spectral studies with lactoperoxidase and thyroid peroxidase: interconversions between native enzyme, compound II, and compound III

Spectral scans in both the visible (650-450 nm) and the Soret (450-380 nm) regions were recorded for the native enzyme, Compound II, and Compound III of lactoperoxidase and thyroid peroxidase. Compound II for each enzyme (1.7 microM) was prepared by adding a slight excess of H2O2 (6 microM), whereas Compound III was prepared by adding a large excess of H2O2 (200 microM). After these compounds had been formed it was observed that they were slowly reconverted to the native enzyme in the absence of exogenous donors. The pathway of Compound III back to the native enzyme involved Compound II as an intermediate. Reconversion of Compound III to native enzyme was accompanied by the disappearance of H2O2 and generation of O2, with approximately 1 mol of O2 formed for each 2 mol of H2O2 that disappeared. A scheme is proposed to explain these observations, involving intermediate formation of the ferrous enzyme. According to the scheme, Compound III participates in a reaction cycle that effectively converts H2O2 to O2. Iodide markedly affected the interconversions between native enzyme, Compound II, and Compound III for lactoperoxidase and thyroid peroxidase. A low concentration of iodide (4 microM) completely blocked the formation of Compound II when lactoperoxidase or thyroid peroxidase was treated with 6 microM H2O2. When the enzymes were treated with 200 microM H2O2, the same low concentration of iodide completely blocked the formation of Compound III and largely prevented the enzyme degradation that otherwise occurred in the absence of iodide. These effects of iodide are readily explained by (i) the two-electron oxidation of iodide to hypoiodite by Compound I, which bypasses Compound II as an intermediate, and (ii) the rapid oxidation of H2O2 to O2 by the hypoiodite formed in the reaction between Compound I and iodide.

Electron paramagnetic resonance spectroscopy of thyroid peroxidase

Thyroid peroxidase was isolated from porcine thyroids by two methods. Limited trypsin proteolysis was employed to obtain a cleaved enzyme, and affinity chromatography was used to isolate intact thyroid peroxidase. Enzyme isolated by both methods was used in the examination of the heme site of native thyroid peroxidase and its complexes by EPR spectroscopy. Intact thyroid peroxidase showed a homogeneous high-spin EPR signal with axial symmetry, in contrast to the rhombic EPR signal of native lactoperoxidase. Reaction of cyanide or azide ion with native thyroid peroxidase resulted in the loss of the axial EPR signal within several hours. The EPR spectroscopy of the nitrosyl adduct of ferrous thyroid peroxidase exhibited a three-line hyperfine splitting pattern and indicated that the heme-ligand structure of thyroid peroxidase is significantly different from that of lactoperoxidase.

Human myeloperoxidase and thyroid peroxidase, two enzymes with separate and distinct physiological functions, are evolutionarily related members of the same gene family

Human myeloperoxidase and human thyroid peroxidase nucleotide and amino acid sequences were compared. The global similarities of the nucleotide and amino acid sequences are 46% and 44%, respectively. These similarities are most evident within the coding sequence, especially that encoding the myeloperoxidase functional subunits. These results clearly indicate that myeloperoxidase and thyroid peroxidase are members of the same gene family and diverged from a common ancestral gene. The residues at 416 in myeloperoxidase and 407 in thyroid peroxidase were estimated as possible candidates for the proximal histidine residues that link to the iron centers of the enzymes. The primary structures around these histidine residues were compared with those of other known peroxidases. The similarity in this region between the two animal peroxidases (amino acid 396-418 in thyroid peroxidase and 405-427 in myeloperoxidase) is 74%; however, those between the animal peroxidases and other yeast and plant peroxidases are not significantly high, although several conserved features have been observed. The possible location of the distal histidine residues in myeloperoxidase and thyroid peroxidase amino acid sequences are also discussed.

Irreversible inactivation of lactoperoxidase in the course of iodide oxidation

In the course of lactoperoxidase-catalysed I- oxidation, which is a model for the initial step of thyroid hormone biosynthesis, irreversible enzyme inactivation can occur if free molecular iodine (I2) or other oxidized iodine species accumulate. Evidence is presented that the breakdown of the catalytic activity is the result of the iodination of the peroxidase-apoprotein. This kind of enzyme inactivation, which can be prevented by iodine acceptors' such as thyroglobulin or high concentrations of I-, may well play a role in the regulation of the synthesis of thyroid hormones in vivo.

Direct electron spin resonance detection of free radical intermediates during the peroxidase catalyzed oxidation of phenacetin metabolites

The oxidation of the phenacetin metabolites p-phenetidine and acetaminophen by peroxidases was investigated. Free radical intermediates from both metabolites were detected using fast-flow ESR spectroscopy. Oxidation of acetaminophen with either lactoperoxidase and hydrogen peroxide or horseradish peroxidase and hydrogen peroxide resulted in the formation of the N-acetyl-4-aminophenoxyl free radical. Totally resolved spectra were obtained and completely analyzed. The radical concentration was dependent on the square root of the enzyme concentration, indicating second-order decay of the radical, as is consistent with its dimerization or disproportionation. The horseradish peroxidase/hydrogen peroxide-catalyzed oxidation of p-phenetidine (4-ethoxyaniline) at pH 7.5-8.5 resulted in the one-electron oxidation products, the 4-ethoxyaniline cation free radical. The ESR spectra were well resolved and could be unambiguously assigned. Again, the enzyme dependence of the radical concentration indicated a second-order decay. The ESR spectrum of the conjugate base of the 4-ethoxyaniline cation radical, the neutral 4-ethoxyphenazyl free radical, was obtained at pH 11-12 by the oxidation of p-phenetidine with potassium permanganate.

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.

The role of compound III in reversible and irreversible inactivation of lactoperoxidase

In the presence of iodide (I-, 10 mM) and hydrogen peroxide in a large excess (H2O2, 0.1-10 mM) catalytic amounts of lactoperoxidase (2 nM) are very rapidly irreversibly inactivated without forming compound III (cpd III). In contrast, in the absence of I- cpd III is formed and inactivation proceeds very slowly. Increasing the enzyme concentration up to the micromolar range significantly accelerates the rate of inactivation. The present data reveal that irreversible inactivation of the enzyme involves cleavage of the prosthetic group and liberation of heme iron. The rate of enzyme destruction is well correlated with the production of molecular oxygen (O2), which originates from the oxidation of excess H2O2. Since H2O2 and O2 per se do not affect the heme moiety of the peroxidase, we suggest that the damaging species may be a primary intermediate of the H2O2 oxidation, such as oxygen in its excited singlet state (1 delta gO2), superoxide radicals (O-.2), or consequently formed hydroxyl radicals (OH.).

One- and two-electron oxidation of reduced glutathione by peroxidases

The oxidation of glutathione by horseradish peroxidase or lactoperoxidase forms a thiyl free radical, as demonstrated with the spin-trapping ESR technique. Reactions of this thiyl free radical result in oxygen consumption, which is inhibited by the radical trap 5,5-dimethyl-1-pyrroline-N-oxide. In contrast to L-cysteine oxidation, glutathione oxidation is highly hydrogen peroxide-dependent. The oxidation of glutathione by glutathione peroxidase forms GSSG without forming a thiyl radical intermediate except in the presence of the thiyl radical-generating horseradish peroxidase.

Detection of a catalytic intermediate of peroxidase in hog thyroid microsomes

A catalytic intermediate, Compound II of peroxidase was detected spectrophotometrically in thyroid microsomes. From comparison with the spectral data on purified thyroid peroxidase, the content of the peroxidase was estimated to be 0.019 nmol per mg of the microsomal protein, being about one-eighth of the amount of cytochrome b5. It was concluded that thyroid peroxidase exhibits the same peroxidase activity for guaiacol or ascorbate in the free and the microsome-bound forms.