Excitation of indole analogs by phagocytosing leukocytes

The system suspended with phagocytosing leukocytes and related system produce weak light which could be greatly amplified by indole analogs with plain fatty acids at 3 position. Main emitting species in indole-3-acetic acid or indole-3-propionic acid-sensitized system was analyzed spectrometrically in the dark and ascribed to the transition of an excited indole compound in triplet state to its ground state. Such an excited species would be generated by the oxidative way of the indole analogs but not through the dioxetane structure of 2 and 3 positions on indole ring.     

Light-driven periodic changes in urocanase activity of a heterotrophic bacterium

Summary Urocanase activity in Pseudomonas putida cells showed periodic changes corresponding to a light-dark cycle. Apparent interconversion of the active and inactive forms of urocanase was accomplished by photoactivation by nearultraviolet light and by dark thermal inactivation. The purified enzyme exhibited similar behavior. This system suggests a possible molecular basis for an hour-glass timer. Photoinactivation by light of 290 nm alternated with photoactivation at 340 nm also generated regular changes in urocanase activity.     

Identification of the prosthetic group of urocanase. The mode of its reaction with sodium borohydride and of its photochemical reactivation.

Urocanase from Pseudomonas putida and from beef liver were isolated by modifying described procedures. Both enzymes were inactivated and labeled on treatment with tritiated sodium borohydride and gave, upon subsequent hydrolysis, a radioactive acid. The previously reported identity of this acid as 2-hydroxybutanoic acid was disproved by several criteria. Other hydroxy acids were also proved to be different from the radioactive acid derived from urocanase. A large portion of the radioactive material from P. putida was found to be nicotinic acid by 1H NMR spectroscopy, gas-liquid chromatography of its methyl ester, and co-crystallization with authentic reference compounds both as the acid and as the hydrazide. A significant portion of the radioactive material derived from beef liver urocanase also co-crystallized with nicotinic acid. Sodium borohydride-treated inactive urocanase was partially reactivated by light. The action spectrum of the photoreactivation showed a maximum at 330 nm. Treatment of urocanase with sodium borodeuteride followed by hydrolysis afforded a sample of nicotinic acid which carried deuterium mainly in position 6. Both the reversible reducibility of urocanase and its action spectrum of photoreactivation suggest that urocanase contains an enzyme-bound nicotinamide nucleotide molecule which is essential for enzymic activity.     

A possible mechanism of the generation of singlet molecular oxygen in nadph-dependent microsomal lipid peroxidation.

A simplified system, consisting of NADPH, Fe3+-ADP, EDTA, liposomes, NADPH-cytochrome c reductase and Tris - HCl buffer (pH 6.8), has been employed in studies of the generation of singlet oxygen in NADPH-dependent microsomal lipid peroxidation. The light emitted by the system involves 1deltag type molecular oxygen identifiable by its characteristic emission spectrum and its behavior with beta-carotene. The generation of another excited species (a compound in the triplet state) could be demonstrated in this system by changes of light intensity and emission spectra which arise from photosensitizer (9,10-dibromoanthracene sulfonate, eosin, Rose-Bengal)-mediated energy transfers. Chemiluminescence in the visible region was markedly quenched by various radical trappers and by an inhibitor of NADPH-cytochrome c reductase, but not by superoxide dismutase. During the early stage of lipid peroxidation, the intensity of chemiluminescence was proportional to the square of the concentration of lipid peroxide. These characteristics suggest that singlet oxygen and a compound in the triplet state (probably a carbonyl compound) are generated by a self-reaction of lipid peroxy radicals.     

Glucuronidation of oxygenated benzo(a)pyrene derivatives by UDP-glucuronyl transferase of nuclear envelope

The variation of the spectra and its reactivity towards 2-methylpropanal, indole-3-acetic acid and malonaldehyde of solutions of horseradish peroxidase in dimethyl sulfoxide-water mixtures has been studied. A broad pattern of changes was observed in the CD spectra of peroxidase, especially in the 400 nm region. These variations influenced strongly the excited triplet acetone emission from the 2-methylpropanal system which is generated in the active site of the enzyme protected from external quenching. This means that presumably the active site is more uncovered in the presence of dimethyl sulfoxide than the native form. Energy transfer parameters indicate that in fact there is a conformational effect produced by dimethyl sulfoxide in the horseradish peroxide active site. Dimethyl sulfoxide appears to be an important conformational probe in biochemistry.     

A method for the detection of urocanase on polyacrylamide gels and its use with crude cell extracts of Pseudomonas.

A method is described for the specific detection of urocanase activity on polyacrylamide gels. It is dependent upon the reduction of nitro blue tetrazolium by the product of the urocanase reaction using phenazine methosulphate as a coupling agent. The method has been characterized using crude cell extracts of Pseudomonas testosteroni and Pseudomonas putida. After growth of the organisms in histidine-succinate medium each extract shows only one band of urocanase activity. The enzymes from the two species have significantly different electrophoretic mobilities.     

Thioglycolate, competitive inhibitor of urocanase.

Urocanase was inhibited by thioglycolate, 2-mercaptoethanol, dithioerythritol, and 3-mercaptopropionate. Thioglycolate inhibited competitively at low concentrations (K_i, 0.1 mM) and protected the active site from modification by sulfite. The inhibited enzyme was reactivated by dialysis. A difference spectrum peak of 328 nm for the thioglycolate-urocanase complex compared to the 327 nm absorption maximum of the NAD-thioglycolate adduct. Several nucleophiles are known to inhibit urocanase. We conclude that thioglycolate, as a nucleophilic agent, inhibits by forming an adduct with the tightly bound NAD of urocanase. These results provide indirect evidence that NAD may be the locus of substrate binding in urocanase.     

Substrate-mediated inactivation of urocanase from Pseudomonas putida. Evidence for an essential sulfhydryl group

Incubation of urocanase from Pseudomonas putida with either its substrate, urocanic acid, or product, 4'(5')-imidazolone-5'(4')-propionic acid, resulted in an oxygen-dependent inhibition of enzyme activity. Coincident with the inactivation was the stoichiometric incorporation of radioactivity from [14C]urocanate into the protein. NAD+ which is required for activity or urocanase was not directly involved in the inactivation process. The inactivation of urocanase was irreversible, could be partially blocked by the competitive inhibitor imidazolepropionate, and involved the modification of a single active-site thiol. The inhibition resulted from oxidative decomposition of 4'(5')-imidazolone-5'(4')-propionate but was not due to the formation of the major degradative product, 4-ketoglutaramate, since this compound was not an irreversible inactivator of urocanase although it did produce some inhibition at high concentrations. A mechanism is presented in which a reactive imine intermediate in the decomposition scheme is subject to nucleophilic attack by an active-site thiol, thereby generating a covalent enzyme--thioaminal adduct. These results emphasize the importance of a catalytic center sulfhydryl group for urocanase activity.     

The stoichiometry of the tightly bound NAD+ in urocanase. Separation and characterization of fully active and inhibited forms of the enzyme

1. Urocanase, purified by classical methods [Keul, V., Kaeppeli, F., Ghosh, C., Krebs, T., Robinson, J. A. and Rétey, J. (1979) J. Biol. Chem. 254, 843-851] from Pseudomonas putida was submitted to high-performance liquid chromatography on a TSK-DEAE column. The enzyme was eluted in three resolved peaks (A, B and C) exhibiting specific activities of 3.4 U/mg, 1.85 U/mg and 0.4 U/mg, respectively. 2. The difference spectra of peaks B and A as well as of C and A showed maxima at 330 nm. 3. Irradiation of peaks B and C at 320 nm resulted in an increase of urocanase activity by 45% and 400%, respectively. Peak A could not be photoactivated. Rechromatography of the photoactivated peaks B and C on the TSK-DEAE column confirmed their partial transformation into peak A. 4. Spectroscopic methods for quantitative protein determination were adapted to urocanase. The stoichiometry of bound NAD+/urocanase (form A) was determined to be 1.75 by enzymic analysis of the free NAD+ released upon acid denaturation of the holoenzyme. A similar stoichiometry (1.8-1.9) was found for all three forms (A, B and C) by biosynthetic incorporation of [7-14C]nicotinate into urocanase using a nicotinate auxotrophic mutant of P. putida. 5. Form A of urocanase showed, after treatment with NaBH4 up to 50% inhibition, an elution pattern (TSK-DEAE column) similar to a mixture of forms A, B and C in the approximate ratio of 1:2:1. None of these forms could be photoactivated. 6. We conclude that form A of the urocanase dimer contains two intact NAD+ molecules. In form B one of the two subunits contains an NAD+-nucleophile adduct which is present in both subunits of form C. Full urocanase activity requires intact NAD+ in both subunits. Intact NAD+ can be regenerated from the adduct but not from the reduced form by photolysis. The two subunits of urocanase are independent both in their catalytic activity and in modification reactions.     

Vitamin B2-sensitised photooxidation of the ophthalmic drugs Timolol and Pindolol: kinetics and mechanism

The kinetics and mechanistic aspects of the riboflavin-photosensitised oxidation of the topically administrable ophthalmic drugs Timolol (Tim) and Pindolol (Pin) were investigated in water-MeOH (9:1, v/v) solution employing light of wavelength > 400 nm. riboflavin, belonging to the vitamin B(2) complex, is a known human endogenous photosensitiser. The irradiation of riboflavin in the presence of ophthalmic drugs triggers a complex picture of competitive reactions which produces the photodegradation of both the drugs and the pigment itself. The mechanism was elucidated employing stationary photolysis, polarographic detection of dissolved oxygen, stationary and time-resolved fluorescence spectroscopy, and laser flash photolysis. Ophthalmic drugs quench riboflavin-excited singlet and triplet states. From the quenching of excited triplet riboflavin, the semireduced form of the pigment is generated, through an electron transfer process from the drug, with the subsequent production of superoxide anion radical (O(2)(*-)) by reaction with dissolved molecular oxygen. Through the interaction of dissolved oxygen with excited triplet riboflavin, the species singlet oxygen (O(2)((1)Delta(g))) is also generated to a lesser extent. Both O(2)(*-) and O(2)((1)Delta(g)) induce photodegradation of ophthalmic drugs, Tim being approximately 3-fold more easily photooxidisable than Pin, as estimated by oxygen consumption experiments.     

A possible mechanism of the generation of singlet molecular oxygen in NADPH-dependent microsomal lipid peroxidation

A simplified system, consisting of NADPH, Fe³⁺-ADP, EDTA, liposomes, NADPH-cytochrome c reductase and Tris · HCl buffer (pH 6.8), has been employed in studies of the generation of singlet oxygen in NADPH-dependent microsomal lipid peroxidation.The light emitted by the system involves ¹Δg type molecular oxygen identifiable by its characteristic emission spectrum and its behavior with β-carotene. The generation of another excited species (a compound in the triplet state) could be demonstrated in this system by changes of light intensity and emission spectra which arise from photosensitizer (9, 10-dibromoanthracene sulfonate, eosin, Rose-Bengal)-mediated energy transfers.Chemiluminescence in the visible region was markedly quenched by various radical trappers and by an inhibitor of NADPH-cytochrome c reductase, but not by superoxide dismutase. During the early stage of lipid peroxidation, the intensity of chemiluminescence was proportional to the square of the concentration of lipid peroxide.These characteristics suggest that singlet oxygen and a compound in the triplet state (probably a carbonyl compound) are generated by a self-reaction of lipid peroxy radicals.     

Catabolism of indole-3-acetic acid in chloroplast fractions from light-grown Pisum sativum L. seedlings

Abstract The catabolism of indole-3-acetic acid was investigated in chloroplast preparations and a crude enzyme fraction derived from chloroplasts of Pisum sativum seedlings. Data obtained with both systems indicate that indole-3-acetic acid undergoes decarboxylative oxidation in pea chloroplast preparations. An enhanced rate of decarboxylation of [1′-¹C]indole-3-acetic acid was obtained when chloroplast preparations were incubated in the light rather than in darkness. Results from control experiments discounted the possibility of this being due to light-induced breakdown of indole-3-acetic acid. High performance liquid chromatography analysis of [2′-¹⁴C]indole-3-acetic acid-fed incubates showed that indole-3-methanol was the major catabolite in both the chloroplast and the crude enzyme preparations. The identification of this reaction product was confirmed by gas chromatography-mass spectrometry when [²H₅]indole-3-methanol was detected in a purified extract derived from the incubation of an enzyme preparation with ³²H₅]indole-3-acetic acid.     

Involvement of Threonine Dehydratase in Biosynthesis of the α-Ketobutyrate Prosthetic Group of Urocanase

Seventeen mutants of Pseudomonas putida that were unable to grow on threonine as nitrogen source owing to a lack of threonine dehydratase were isolated, and all were found to be unable to synthesize active urocanase. Spontaneous revertants selected for urocanase production concomitantly regained threonine dehydratase. Mutants that were unable to utilize urocanate as carbon source were also isolated, and these were defective in urocanase formation but were normal in threonine dehydratase levels. Since alpha-ketobutyrate is the prosthetic group for urocanase, these results are consistent with the proposal that threonine dehydratase is necessary for urocanase prosthetic group biosynthesis. However, the lack of urocanase activity in threonine dehydratase-negative mutants was shown not to be the result of reduced levels of endogenous free alpha-ketobutyrate, nor to the participation of threonine dehydratase in the initiation of urocanase biosynthesis through the conversion of threonyl-tRNA(Thr) to alpha-ketobutyryl-tRNA(Thr). Other alternatives for the participation of threonine dehydratase in urocanase biosynthesis are discussed.     

Reconstitution of an electrogenic auxin transport activity mediated by Arabidopsis thaliana plasma membrane proteins

Plasma membrane proteins from Arabidopsis thaliana leaves were reconstituted into proteoliposomes and a K+ diffusion potential was generated. The resulting ionic fluxes, determined in the presence of the plant hormone auxin (indole-3 acetic acid), showed an additional electrogenic and saturable component, with a K(M) of 6 microM. This flux was neither detected in liposomes in the presence of indole-3 acetic acid, nor in proteoliposomes in the presence of an inactive auxin analog and was completely inhibited by 3 microM naphtylphthalamic acid, a specific inhibitor of the auxin efflux carrier. The efficiency of the reconstituted carrier and the mechanism of its regulation by naphtylphthalamic acid are discussed.     

Isolation and Characterization of Esters of Indole-3-Acetic Acid from the Liquid Endosperm of the Horse Chestnut (Aesculus species)

Esters of indole-3-acetic acid were extracted and purified from the liquid endosperm of immature fruits of various species of the horse chestnut (Aesculus parviflora, A. baumanni, A.pavia rubra, and A. pavia humulis). The liquid endosperm contained, at least 12 chromatographically distinct esters. One of these compounds was purified and characterized as an ester of indole-3-acetic acid and myo-inositol. A second compound was found to be an ester of indole-3-acetic acid and the disaccharide rutinose (glucosyl-rhamnose). A third compound was partially characterized as an ester of indole-3-acetic acid and a desoxyaminohexose.     

Excitation of indole-3-acetic acid (an auxin) in a linoleate-lipoxygenase system.

The weak luminescence that accompanies the linoleate-lipoxygenase reaction was greatly enhanced by the addition of indole analogues, and especially indole acetic acid. The main emitting species in the indole acetic acid-linoleate-lipoxygenase system was analysed spectrophotometrically in the visible region and ascribed to the transition of excited indole acetate in triplet state to its ground state. Such an excited indole acetate could be generated by transfer of energy from the excited CO2 and excited carbonyl (generated by the linoleate-lipoxygenase reaction) to indole acetate in the ground state, but not by cleavage of the dioxetane analog (positions 2 and 3 on the indole ring).     

O-methylhydroxylamine as a reagent for NAD+ modification in urocanase.

The inhibition of urocanase from Pseudomonas putida by O-methylhydroxylamine has been characterized as being due to the formation of an adduct between CH₃ONH₂ and NAD⁺, the latter of which has been recently shown to be a tightly bound coenzyme for this urocanase. Inhibition is maximal at pH 8.5 and is blocked by the presence of the substrate analog imidazole propionate. Loss of catalytic activity corresponds directly with the binding of 1 mol of ¹⁴CH₃ONH₂ per mole of enzyme, and partial reversibility of the modification, achieved by dialysis at pH 7.5, is accompanied by concomitant restoration of enzymatic activity. No incorporation of ¹⁴CH₃ONH₂ into urocanase is seen when enzyme-bound NAD⁺ is first converted to NADH or when NAD⁺ is removed by prior treatment of urocanase with 8 m urea. Stability and spectral properties of the CH₃ONH · NAD adduct are consistent with previous data reported for the product of the hydroxylamine reaction with NAD⁺. It is concluded that other urocanases which exhibit inhibition by hydroxylamine may likewise contain NAD⁺ as an essential coenzyme and that the use of ¹⁴CH₃ONH₂ as a reversible modification reagent for NAD⁺ should prove helpful for studies on the role of NAD⁺ in the urocanase catalytic process.     

Reaction center triplet states in photosystem I and photosystem II

A photosystem I (PS I) particle has been prepared by lithium dodecyl sulfate digestion which lacks the acceptor X, and iron-sulfur centers B and A. Illumination of these particles at liquid helium temperature results in the appearance of a light-induced spin-polarized triplet signal observed by EPR. This signal is attributed to the triplet state of P-700, the primary donor, formed by recombination of the light induced radical pair P-700+ A1- (where A1 is the intermediate acceptor). Formation of the triplet does not occur if P-700 is oxidized or if A1 is reduced, prior to the illumination. A comparison of the P-700 triplet with that of P-680, the primary donor of Photosystem II, shows several differences. (1) The P-680 triplet is 1.5 mT (15 G) wider than the P-700 triplet. This is reflected by the zero-field splitting parameters, which indicate that P-700 is a slightly larger species than P-680. The zero-field splitting parameters do not indicate that either P-700 or P-680 are dimeric. (2) The P-700 triplet is induced by red and far-red light, while the P-680 triplet is induced only by red light. (3) The temperature dependences of the P-700 triplet and the P-680 triplet are different.     

Xanthophyll cycle--a mechanism protecting plants against oxidative stress

Six different xanthophyll cycles have been described in photosynthetic organisms. All of them protect the photosynthetic apparatus from photodamage caused by light-induced oxidative stress. Overexcitation conditions lead, in the chloroplast, to the over-reduction of the NADP pool and production of superoxide, which can subsequently be metabolized to hydrogen peroxide or a hydroxyl radical, other reactive oxygen species (ROS). On the other hand, overexcitation of photosystems leads to an increased lifetime of the chlorophyll excited state, increasing the probability of chlorophyll triplet formation which reacts with triplet oxygen forming single oxygen, another ROS. The products of the light-dependent phase of xanthophyll cycles play an important role in the protection against oxidative stress generated not only by an excess of light but also by other ROS-generating factors such as drought, chilling, heat, senescence, or salinity stress. Four, mainly hypothetical, mechanisms explaining the protective role of xanthophyll cycles in oxidative stress are presented. One of them is the direct quenching of overexcitation by products of the light phase of xanthophyll cycles and three others are based on the indirect participation of xanthophyll cycle carotenoids in the process of photoprotection. They include: (1) indirect quenching of overexcitation by aggregation-dependent light-harvesting complexes (LHCII) quenching; (2) light-driven mechanisms in LHCII; and (3) a model based on charge transfer quenching between Chl a and Zx. Moreover, results of the studies on the antioxidant properties of xanthophyll cycle pigments in model systems are also presented.     

Photoactivation of Urocanase in Pseudomonas putida: Possible Role in Photoregulation of Histidine Metabolism

Irradiation by near-ultraviolet light of cells or extracts of Pseudomonas putida increased the urocanase activity. Irradiated cells exhibited enhanced catabolic activity on histidine and urocanate.