Singlet oxygen production from the peroxidase-catalyzed oxidation of indole-3-acetic acid

The aerobic oxidation of indole-3-acetic acid catalyzed by horseradish peroxidase produces 1268 nm emission characteristic of singlet oxygen. Lactoperoxidase also oxidizes indole-3-acetic acid to produce singlet oxygen, but in contrast to horseradish peroxidase, this enzyme system requires hydrogen peroxide. In both of these systems, the intensity of the 1268 nm emission is small due to quenching of the singlet oxygen by indole-3-acetic acid and by reaction products derived from indole-3-acetic acid. The biomolecular reaction of peroxyl radicals via a Russell mechanism is a plausible mechanism for the singlet oxygen generation in these systems. Under typical conditions of p2H 4.0, 1 microM horseradish peroxidase, 1 mM indole-3-acetic acid, and 240 microM oxygen, the singlet oxygen yield was 15 +/- 1 microM or 13% of the amount predicted by the Russell mechanism.     

A sensitive, convenient radioimmunoassay procedure which demonstrates that serum hTSH is suppressed below the normal range in thyrotoxic patients

A highly sensitive radioimmunoassay procedures for the measurement of serum hTSH is described which permits delineation of the entire range of values in normal subjects (0.5-4.5 microU/ml). The procedure involves the concentration of hTSH from serum by adsorption to concanavalin A covalently bound to 4B Sepharose, Lactoperoxidase iodination of hTSH, and disequilibrium assay conditions. This method utilizes commonly available radioimmunoassay materials and is convenient to perform. Our results with this assay show that patients with thyrotoxicosis of a variety of etiologies have serum hTSH levels suppressed well below the normal range.     

Macrophage recognition of immune complexes: development and application of novel cell surface labeling procedures

A fluorescein- and lactoperoxidase-conjugated ferritin-anti-ferritin immune complex has been prepared for cell surface labeling experiments on immune recognition and effector function. Lactoperoxidase (LPO) has been covalently coupled to affinity-purified anti-ferritin antibodies with p-benzoquinone by a modified version of the method of Ternynck and Avrameas [Ternynck, T., & Avrameas, S. (1976) Ann. Immunol. (Paris) 127C, 197]. The conjugate is a heterodimer of Mr230 000 with linkages to either or both of the heavy and light chains of the antibody, as judged by two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) in the absence and presence of 2-mercaptoethanol. The conjugate retains antibody-binding activity as measured by a quantitative precipitin assay. When incorporated into immune complexes, the modified antibody also retains Fc receptor recognition ability as determined by erythrocyte-antibody rosette inhibition assays. Electron microscopy demonstrated that the antigen, ferritin, was monodisperse with complete apoprotein sheaths surrounding the core. Ferritin-anti-ferritin-LPO complexes were formed in 4-fold antigen excess. Complexes were verified by fluorescence and electron microscopy. Immune complexes were masked with "cold" iodine by use of the endogenous LPO activity. The complexes bound to cells at 4 degrees C as shown by electron microscopy and fluorescence video/intensification microscopy. The LPO delivered to the cell surface in this fashion can be utilized to iodinate the surface with 125I. Under saturation conditions, the labeling with local LPO delivery followed by SDS-PAGE and autoradiography is identical with labeling with free LPO. Labeling has also been conducted under conditions of substrate deficit.(ABSTRACT TRUNCATED AT 250 WORDS)     

Rapid cell surface appearance of endocytic membrane proteins in Chinese hamster ovary cells.

Lactoperoxidase was used to selectively radiolabel endocytic membrane. CHO cells were incubated with enzyme at 37 degrees C for 10 min to permit lactoperoxidase internalization. Radioiodination was done at 4 degrees C. About 90% of the radioiodinated products pelleted at 100,000 X g. From 12 to 15 different electrophoretic species were detected by one-dimensional gel electrophoresis. When cells labeled by internalized lactoperoxidase were warmed to 37 degrees C, the incorporated radioactivity was lost in a biphasic manner with an overall t1/2 of approximately 20 h. Upon warming cells to 37 degrees C, the labeled species became sensitive to pronase or trypsin digestion. The increase in protease sensitivity was progressive over a 10- to 20-min period. Maximally 45% of the initially intracellular radiolabel could be released. A digest of exterior-radioiodinated cells released 50% of the incorporated radioiodine. These observations strongly suggest a rapid shuttling of approximately 90% of the radioiodinated membrane species initially present within the cell to the cell surface.     

A rat liver system that catalyses a pyridoxal phosphate-independent αβ-elimination

1. A method is described for the trace iodination of immunoglobulins and other serum proteins by a system consisting of lactoperoxidase, hydrogen peroxide and iodide. 2. gammaG immunoglobulin that had been labelled to a specific radioactivity of 5muc/mug. by use of carrier-free [(125)I]iodide gave no evidence of denaturation when analysed by electrophoresis and density-gradient ultracentrifugation. 3. Tryptic hydrolysis and peptide ;mapping' of a completely characterized peptide radioiodinated by this method showed that the [(125)I]iodide was bound to tyrosyl residues. 4. Proteins differ in their susceptibility to iodination by this method. Human gammaG immunoglobulin, for example, is iodinated more than ten times as readily as is human alpha(2)-macroglobulin under the same conditions. 5. Lactoperoxidase catalyses the iodination of proteins much more readily than does horseradish peroxidase.     

Effect of urate on the lactoperoxidase catalyzed oxidation of adrenaline

Lactoperoxidase is an iron containing enzyme, which is an essential component of the defense system of mammalian secretary fluids. The enzyme readily oxidizes adrenaline and other catecholamines to coloured aminochrome products. A K_m-value of 1.21 mM and a catalytic constant (k = V_\max/[Enz]) of 15.5 × 10³ min^–1 characterized the reaction between lactoperoxidase and adrenaline at pH 7.4. Urate was found to activate the enzyme catalyzed oxidation of adrenaline in a competitive manner, the effect decreasing with increasing adrenaline concentration. Lactoperoxidase was able to catalyze the oxidation of urate. However, urate was a much poorer substrate than adrenaline, and it seems unlikely that urate activates by functioning as a free, redox cycling intermediate between enzyme and adrenaline. The activation mechanism probably involves an urate-lactoperoxidase complex.     

Identification, purification, and characterization of a non-heme lactoperoxidase in bovine milk

A purification procedure for a protein related to lactoperoxidase devoid of the heme prosthetic group under conditions also yielding enzymatically active lactoperoxidase is described. These two forms were separated from bovine milk according to their respective behaviors on cation exchange. Lactoperoxidase and non-heme lactoperoxidase had the same apparent molecular weight in the denatured (sodium dodecyl sulfate-polyacrylamide gel electrophoresis) and native form (velocity sedimentation on sucrose gradient) about 85,000; but unlike lactoperoxidase, non-heme lactoperoxidase was devoid of light absorption properties in the Soret region and of enzyme activity. Lactoperoxidase and non-heme lactoperoxidase contained a similar amount of carbohydrate and gave very similar peptide maps after limited proteolysis by subtilisin or trypsin. The two forms appeared to be immunologically related since they gave a single line in immunodiffusion using anti-lactoperoxidase antibodies and since 125I-labeled non-heme lactoperoxidase and 125I-labeled lactoperoxidase reacted with anti-lactoperoxidase antibodies in radioimmunoassay. Lactoperoxidase and nonheme lactoperoxidase were compared in their ability to interact with diiodotyrosine and tubulin (Rousset, B., and Wolff, J. (1980) J. Biol. Chem. 255, 2514-2523). 125I-labeled diiodotyrosine bound specifically to lactoperoxidase. No detectable binding has been observed with nonheme lactoperoxidase. In contrast, lactoperoxidase and non-heme lactoperoxidase coupled to an insoluble matrix were able to bind rat brain tubulin, indicating that both forms of lactoperoxidase can be used for an affinity chromatography purification procedure of brain tubulin. Non-heme lactoperoxidase was found in milk from several origins, cow, goat, sheep, and human. In bovine milk, lactoperoxidase and non-heme lactoperoxidase were found in comparable amounts.     

On the three visual pigments in the retina of the firefly squid,Watasenia scintillans

Summary The deep-sea bioluminescent squid, Watasenia scintillans, has three visual pigments: The major one (A1 pigment) is based on retinal and has _max = 484 nm, the second one (A2 pigment) is based on 3-dehydroretinal and has _max = 500 nm, and the third one (A4 pigment) is based on 4-hydroxyretinal and has _max = 470 nm. The distribution of these 3 visual pigments in the retina was studied by HPLC analysis of the retinals in retina slices obtained by microdissection. It was found that A1 pigment was not located in the specific region of the ventral retina receiving the down-welling light which contains very long photoreceptor cells, forming two strata. A2 and A4 pigment were found exclusively in the proximal pinkish stratum and in the distal yellowish stratum. The role of these pigments in the retina is hypothesized to involve spectral discrimination. The extraction and analysis of retinoids to determine the origin of 3-dehydroretinal and 4-hydroxyretinal in the mature squid showed only a trace amount of 4-hydroxyretinol in the eggs. Similar analysis of other cephalopods collected near Japan showed the absence of A2 or A4 pigment in their eyes.Abbreviations HPLC high-performance liquid chromatography - IS inner segment - OS outer segment     

Peroxidase catalyzed reactions of iodide at low pH

Lactoperoxidase (LP) and horseradish peroxidase (HRP) catalyze the rapid oxidation of iodide to iodine at pH 3.6. One mole of peroxide reacts with 2 moles of iodide, producing 1 mole of iodine. Neither enzyme catalyzes the further oxidation of iodine. The turnover numbers for LP and HRP are 1.4 × 10⁵ and 2.2 × 10⁴ I₂ moles produced/min/enzyme mole, respectively.     

Highly efficient labeling of DNA polymerases by a binary system of photoaffinity reagents

A binary system of photoaffinity reagents was proposed earlier for highly efficient labeling of DNA polymerases by 5"-[³²P]DNA primers. In the present study we demonstrate the feasibility of this approach to increase the efficiency of DNA polymerase labeling. A photoactive 2,3,5,6-tetrafluoro-4-azidobenzoyl (FAB) group was incorporated at the 3"-end of 5"-[³²P]DNA primers synthesized by DNA polymerase or Tte in the presence of one of the dTTP analogs—FAB-4-dUTP, FAB-9-dUTP, or FAB-4-ddUTP. The reaction mixture was irradiated by light with wavelength of 334-365 nm (direct labeling) or 365-450 nm in the presence of photosensitizer, one of dTTP analogs containing a pyrene moiety, Pyr-6-dUTP or Pyr-8-dUTP. In the case of the binary system of photoaffinity reagents, a FAB group is activated by energy transfer from sensitizer localized in the dNTP-binding site of DNA polymerase in the triple complex, comprised by reagent, DNA polymerase, and Pyr-6(8)-dUTP. Direct activation of the FAB group under these conditions is negligible. The most efficient photolabeling of DNA polymerases was observed with a primer containing a FAB-4-dUMP group at the 3"-end, and Pyr-6-dUTP as a photosensitizer. Using 10-fold molar excess of photoreagent to DNA polymerase , the labeling efficiency was shown to achieve 60%, which is 2-fold higher than the efficiency of the direct DNA polymerase labeling under harsher conditions (334-365 nm).     

The specificity of the chemical modification of N6-delta 2-(isopentenyl)adenosine in purified yeast tRNA Ser.

The specific modification of N6-delta 2-(isopentenyl)adenosine in purified tRNA Ser yeast by mild treatment with KMnO4 and I2 was studied. N6-delta 2-(isopentenyl)adenosine in tRNA SER is specifically modified by iodination, providing us with a suitable method for the quantitative determination of N6-delta 2-(isopentenyl)adenosine in tRNA was found to contain 114 +/- 8 pmol/A260nm unit of N6-delta 2-(isopentenyl)adenosine and gave three labelled fractions on an RPC-5 column. The product obtained after KMnO4 treatment of tRNA Ser was not homogeneous. The enzymatic "reisopentenylation" of KMnO4-treated tRNA Ser resulted in the regeneration of only traces of the original molecule(s). Most of them had been damaged either by the KMnO4 treatment or in the incubation mixture used for "reisopentenylation".     

Excitation energy transfer pathways in Lhca4

EET in reconstituted Lhca4, a peripheral light-harvesting complex from Photosystem I of Arabidopsis thaliana, containing 10 chlorophylls and 2 carotenoids, was studied at room temperature by femtosecond transient absorption spectroscopy. Two spectral forms of Lut were observed in the sites L1 and L2, characterized by significantly different interactions with nearby chlorophyll a molecules. A favorable interpretation of these differences is that the efficiency of EET to Chls is about two times lower from the "blue" Lut in the site L1 than from the "red" Lut in the site L2 due to fast IC in the former case. A major part of the energy absorbed by the "red" Lut, approximately 60%-70%, is transferred to Chls on a sub-100-fs timescale from the state S(2) but, in addition, minor EET from the hot S(1) state within 400-500 fs is also observed. EET from the S(1) state to chlorophylls occurs also within 2-3 ps and is ascribed to Vio and/or "blue" Lut. EET from Chl b to Chl a is biphasic and characterized by time constants of approximately 300 fs and 3.0 ps. These rates are ascribed to EET from Chl b spectral forms absorbing at approximately 644 nm and approximately 650 nm, respectively. About 25% of the excited Chls a decays very fast-within approximately 15 ps. This decay is proposed to be related to the presence of the interacting Chls A5 and B5 located next to the carotenoid in the site L2 and may imply some photoprotective role for Lhca4 in the photosystem I super-complex.     

Regulation of the distribution of excitation energy in Ochromonas danica,an organism containing a chlorophyll-A/C/carotenoid light harvesting antenna

A chlorophyll a, c-fucoxanthin pigment-protein complex8 functions as the major light harvesting antenna in the Chrysophyte Ochromonas danica. The regulated distribution of excitation energy between the two photosystems was investigated in these organisms and was shown to be strongly wavelength dependent. A light state transition was induced by pre-illumination of cells using light 2 (640 nm) and light 1 (700 nm) of equal absorbed intensity, and detected by reversible changes in the 77 K chlorophyll fluorescence emission spectra. Peaks at 690 nm and 720 nm in the low temperature spectra are most likely associated with PS2 and PS1 respectively. A room temperature fluorescence emission at 680 nm induced by modulated light 2 (500 nm) was strongly quenched in the presence of background light 1 (720 nm). Removal of light 1 led to an increase in fluorescence followed by a slow quenching. The room temperature fluorescence changes were directly correlated with changes in the 77 K emission spectra that indicated a change in the distribution of excitation energy between the two photosystems. It was established that DCMU (1 mol) prevented the state 2. The conversion to state 1 followed a simple photochemical dose dependence and had a half-time of 20 s-1.5 min at 6 W m^-2. In contrast, the conversion to state 2 was independent of light intensity. These data indicate that O. danica undergoes a light state transition in response to the preferential excitation of PS2 or PS1.Abbreviations PS2 photosystem 2 - PS1 photosystem 1 - LHC light harvesting chlorophyll a/b protein - fx fucoxanthin - PQ plastoquinone - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethyl urea     

The metabolic pathway catalyzed by the tyrosinase of Agaricus bisporus

N-t-Butyloxycarbonyl-gamma-L-glutaminyl-2-bromo-4-hydroxybenzene alpha-benzyl ester was synthesized as a precursor to gamma-L-glutaminyl-4-hydroxy[2-3H]benzene. With this labeled compound and the previously synthesized gamma-L-glutaminyl-4-hydroxy[3,5-3H]benzene, the stoichiometry of ring substitution was determined for the tyrosinase-catalyzed metabolic pathway of Agaricus bisporus. In this pathway, gamma-L-glutaminyl-4-hydroxybenzene is hydroxylated to gamma-L-glutaminyl-3,4-dihydroxybenzene which is oxidized to gamma-L-glutaminyl-3,4-benzoquinone and a compound of previously unknown structure, "490." The results indicated that the "490" quinone was derived from gamma-L-glutaminyl-3,4-benzoquinone without further ring substitution. A base-catalyzed, nonenzymatic reaction of gamma-L-glutaminyl-3,4-benzoquinone was observed which yielded a compound with a 490 nm chromophore. gamma-Glutamyl transpeptidase cleavage of gamma-L-glutaminyl-3,4-dihydroxybenzene led to the release of 4-aminocatechol which air-oxidized to a compound with identical spectral properties to "490." The structure of "490" was thus determined to be 2-hydroxy-4-imino-2,5-cyclohexadiene-1-one(2-hydroxy-4-iminoquinone). The tyrosinase-catalyzed hydroxylation of gamma-L-glutaminyl-4-hydroxybenzene was found to be optimal at pH 8.0, while the enzymatic oxidation of gamma-L-glutaminyl-3,4-dihydroxybenzene was optimal at pH 6.0.     

Monomers,dimers, and tetramers of 4-n-propyl-5-ethyl farnesyl bacteriochlorophyll c in dichloromethane and carbon tetrachloride

Absorption (ABS) and circular dichroism (CD) spectra were recorded for 6 concentrations (2.0–290 M) of bacteriochlorophyll (BChl) c in each solvent. Monomer spectra were obtained by adding methanol (1:200) to each sample. The monomer showed an ABS peak and a CD trough at 664 nm in CH₂Cl₂ (ABS peak at 665 nm in CCl₄). Dimer-plus-monomer spectra were obtained by subtracting high concentration (e.g., 290 M) spectra appropriately scaled from lower concentration (e.g., 26 M) spectra. Pure dimer spectra were then obtained by subtracting monomer spectra appropriately scaled from dimer-plus-monomer spectra. The dimer showed an ABS peak at 679 nm in both CH₂Cl₂ and CCl₄ and a CD trough at ca. 670 nm in CH₂Cl₂. The optical properties of the dimer do not agree with the model for bacteriochlorophyllide d [Smith KM, Bobe FW, Goff DA and Abraham RJ (1986) J Am Chem Soc 108: 1111–1120]. Higher aggregate spectra were obtained by subtracting appropriately scaled monomer and dimer spectra from high concentration (e.g., 290 M) spectra. The aggregate showed ABS shoulders at ca. 636 and 678 nm with a peak at 702 nm in CH₂Cl₂ and at 708 nm in CCl₄; the CD spectrum in either solvent showed peaks at 638 and 679 nm with troughs at 658 and ca. 710 nm. These spectra are consistent with an excitonic interaction between 4 chromophores in the aggregate. Each of the 12 original ABS spectra was deconvoluted in terms of the appropriate monomer, dimer and aggregate spectra, and the concentrations of each component were determined. Plots of log aggregate concentration vs. log dimer concentration lay on or near a line of slope 1.9 for CH₂Cl₂ and on or near a line of slope 2.1 for CCl₄. The aggregate was thus shown to be a tetramer. The theoretical relationship between dimers and monomers (slope 2.0) was not observed in all cases.Abbreviations ABS absorbance - BChl bacteriochlorophyll - CD circular dichroism - Chl chlorophyll - DNS data not shown - PEF 4-n-propyl-5-ethyl farnesyl     

Extracellular protein fibrils in Chrysochromulina breviturrita (Prymnesiophyceae) and their serological relationship to fungal fimbriae

An extensive network of extracellular fibrils was revealed by negative staining in the greenish gold algal flagellate, Chrysochromulina breviturrita. These fibrils were of uniform diameter (4–5 nm), sometimes exceeding 5 m in length. In addition there were short, narrower fibrils (2–3 nm) on the surface of the flagella. Six protein bands were isolated from spent culture medium by SDS-PAGE and one of 80,000 Da was found to polymerize after dialysis into 4–5 nm fibrils identical to those found on the cell surface. Two other proteins of 58,000 Da and 65,000 Da also formed 4–5 nm fibrils but these were either rare or of a shorter length and different appearance. An antiserum directed against the surface 7 nm fibrils (fimbriae) of fungi agglutinated cells of C. breviturrita and some other Prymnesiophyceae and Chrysophyceae, but did not agglutinate cells of algal species in other groups. Immunofluorescence and protein A gold labelling confirmed that antigens related to fungal fimbriae were present on the surface of cells of C. breviturrita. Only the 80,000 and 58,000 Da proteins labelled heavily following protein A gold labelling. Some individual 4–5 nm fibrils labelled with gold were observed in the material prepared from the 80,000 Da band. These results therefore establish that C. breviturrita produces a surface network of fibrils that are serologically related to the fimbriae of fungi, and suggest a previously unrecognized relationship between members of the Prymnesiophyceae, Chrysophyceae and fungal groups.     

Hypochlorous acid-induced heme degradation from lactoperoxidase as a novel mechanism of free iron release and tissue injury in inflammatory diseases

Lactoperoxidase (LPO) is the major consumer of hydrogen peroxide (H(2)O(2)) in the airways through its ability to oxidize thiocyanate (SCN(-)) to produce hypothiocyanous acid, an antimicrobial agent. In nasal inflammatory diseases, such as cystic fibrosis, both LPO and myeloperoxidase (MPO), another mammalian peroxidase secreted by neutrophils, are known to co-localize. The aim of this study was to assess the interaction of LPO and hypochlorous acid (HOCl), the final product of MPO. Our rapid kinetic measurements revealed that HOCl binds rapidly and reversibly to LPO-Fe(III) to form the LPO-Fe(III)-OCl complex, which in turn decayed irreversibly to LPO Compound II through the formation of Compound I. The decay rate constant of Compound II decreased with increasing HOCl concentration with an inflection point at 100 μM HOCl, after which the decay rate increased. This point of inflection is the critical concentration of HOCl beyond which HOCl switches its role, from mediating destabilization of LPO Compound II to LPO heme destruction. Lactoperoxidase heme destruction was associated with protein aggregation, free iron release, and formation of a number of fluorescent heme degradation products. Similar results were obtained when LPO-Fe(II)-O(2), Compound III, was exposed to HOCl. Heme destruction can be partially or completely prevented in the presence of SCN(-). On the basis of the present results we concluded that a complex bi-directional relationship exists between LPO activity and HOCl levels at sites of inflammation; LPO serve as a catalytic sink for HOCl, while HOCl serves to modulate LPO catalytic activity, bioavailability, and function.     

An immobilized two-enzyme system for the activation of the lactoperoxidase antibacterial system in milk

Lactoperoxidase catalyzes the oxidation of thiocyanate by hydrogen peroxide and an intermediary product is formed with antibacterial properties. The components of this system, with the exception of hydrogen peroxide, are present in milk. H₂O₂ may be introduced by means of enzymatic, generation and thus make the system complete. A two-enzyme system consisting of β–galactosidase and glucose oxidase has been developed for this purpose. The coupled enzyme reaction is shown to work with high efficiency at the neutral pH of milk although the enzymes as such, particularly lactases suitable for immobilization, have optimal activities at much lower pH values. The results indicate that the lactoperoxidase system may in this way be employed to inactivate bacteria present in milk.     

The inhibition of streptococci by lactoperoxidase, thiocyanate and hydrogen peroxide. The oxidation of thiocyanate and the nature of the inhibitory compound

1. The growth of the lactoperoxidase-sensitive Streptococcus cremoris 972 in a synthetic medium was inhibited by lactoperoxidase and thiocyanate. The glycolysis and oxygen uptake of suspensions of Strep. cremoris 972 in glucose or lactose were also inhibited. The lactoperoxidase-resistant Strep. cremoris 803 was not inhibited under these conditions but was inhibited in the absence of a source of energy. 2. Lactoperoxidase (EC 1.11.1.7), thiocyanate and hydrogen peroxide completely inhibited the hexokinases of non-metabolizing suspensions of both strains. The inhibition was reversible, hexokinase and glycolytic activities of Strep. cremoris 972 being restored by washing the cells free from inhibitor. The aldolase and 6-phosphogluconate-dehydrogenase activities of Strep. cremoris 972 were partially inhibited but several other enzymes were unaffected. 3. The resistance of Strep. cremoris 803 to inhibition was not due to the lack of hydrogen peroxide formation, to the destruction of peroxide, to the inactivation of lactoperoxidase or to the operation of alternative pathways of carbohydrate metabolism. 4. A ;reversal factor', which was partially purified from extracts of Strep. cremoris 803, reversed the inhibition of glycolysis of Strep. cremoris 972. The ;reversal factor' also catalysed the oxidation of NADH(2) in the presence of an intermediate oxidation product of thiocyanate and was therefore termed the NADH(2)-oxidizing enzyme. 5. The NADH(2)-oxidizing enzyme was present in lactoperoxidase-resistant streptococci but was absent from lactoperoxidase-sensitive streptococci.