Arylglycerol-gamma-Formyl Ester as an Aromatic Ring Cleavage Product of Nonphenolic beta-O-4 Lignin Substructure Model Compounds Degraded by Coriolus versicolor

4-Ethoxy-3-methoxyphenylglycerol-gamma-formyl ester (compound IV) was identified as a degradation product of both 4-ethoxy-3-methoxyphenylglycerol-beta-syringaldehyde ether (compound I) and 4-ethoxy-3-methoxyphenylglycerol-beta-2,6-dimethoxyphenyl ether (compound II) by a ligninolytic culture of Coriolus versicolor. An isotopic experiment with a C-labeled compound (compound II') indicated that the formyl group of compound IV was derived from the beta-phenoxyl group of beta-O-4 dimer as an aromatic ring cleavage fragment. However, compound IV was not formed from 4-ethoxy-3-methoxyphenylglycerol-beta-guaiacyl ether (compound III). gamma-Formyl arylglycerol (compound IV) could be a precursor of 4-ethoxy-3-methoxyphenylglycerol (compound VI), because 3-(4-ethoxy-3-methoxyphenyl)-1-formyloxy propane (compound VII) was cleaved to give 3-(4-ethoxy-3-methoxyphenyl)-1-propanol (compound VIII) by C. versicolor. 4-Ethoxy-3-methoxyphenylglycerol-beta,gamma-cyclic carbonate (compound V), previously found as a degradation product of compound III by Phanerochaete chrysosporium (T. Umezawa, and T. Higuchi, FEBS Lett., 25:123-126, 1985), was also identified from the cultures with compound I, II, and III and degraded to give the arylglycerol (compound VI). An isotopic experiment with C-labeled compounds II' and III' indicated that the carbonate carbon of compound V was derived from the beta-phenoxyl groups of beta-O-4 substructure.     

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.     

微生物复合菌剂的制备

【背景】微生物复合菌剂比单一菌剂更能够在土壤中高效、稳定发挥作用促进作物生长,是微生物菌剂发展的趋势,但是目前对构建微生物复合菌剂的研究不够深入。【目的】研制可显著促进水稻生长的微生物复合菌剂,并构建微生物复合菌剂的数学模型。【方法】将解淀粉芽孢杆菌(Bacillus amyloliquefaciens) FH-1与7株植物促生细菌按照生物量1:1的比例复配成微生物复合菌剂,利用水稻盆栽实验筛选高效复合微生物菌剂。利用生化方法对各个菌株的促生特性进行测定。分析植物特征和菌株促生特性间的相关性关系,并据此利用一般线性方程构建复合菌剂的数学模型。【结果】与空白对照CK相比,复合菌剂FN显著提升水稻的苗长20.79%、根长26.67%和鲜重74.84%(P0.05),是7种微生物复合菌剂中综合效果最佳的微生物复合菌剂。偏相关分析结果表明解无机磷能力、产铁载体能力和产ACC脱氨酶能力在促进植物生长过程中可能发挥着更重要的作用。根据菌剂促生特性与植物特征的偏相关性结果,构建了微生物复合菌剂数学模型,预测准确率可达97%以上。【结论】成功研制了高效促进水稻生长的微生物复合菌剂,并构建了微生物复合菌剂的数学模型,可为微生物复合菌剂的研制提供一定的科学指导。     

Microbial transformation of 8-chloro-10,11-dihydrodibenz(b,f)(1,4)oxazepine by fungi.

The microbial transformation of 8-chloro-10,11-dihydrodibenz(b,f)(1,4)oxazepine (compound I) was undertaken to obtain new derivatives. Compound I was transformed by Hormodendrum sp. (NRRL 8133) to 8-chloro-10,11-dihydrodibenz(b,f)(1,4)oxazepine-11-one (compound II) and 2-(2-amino-4-chlorophenoxy)benzyl alcohol (compound IV). Microbial cleavage of the nonaromatic ring to form compound IV was accomplished by several other fungi. Compound I was transformed to 8-chlorodibenz(b,f)(1,4)oxazepine (compound III) by Hormodendrum cladosporioides (NRRL 8132).     

Dibutyl phthalate, the bioactive compound produced by Streptomyces albidoflavus 321.2

It was found that the bioactive compound, dibutyl phthalate, was produced by a new soil isolate Streptomyces albidoflavus 321.2. Once this active compound was recovered by ethyl acetate from the fermented broth, being possible to isolate 13.4 mg/l, it was purified by paper, silica gel column, thin layer and gas chromatography. Structure was determined by analysing UV, IR and GC-MS spectra. During analysis, such active compound showed strong activity against gram-positive and gram-negative bacteria, as well as unicellular and filamentous fungi. The antimicrobial activity of the compound was reversed by the amino acid proline. No acute toxicity was observed.     

Reactions of prostaglandin endoperoxide synthase with hydroperoxide and reducing substrates under single turnover conditions

The peroxidase reaction of prostaglandin endoperoxide synthase was investigated by transient state kinetics using stoichiometric amounts of substrates. The rate constants for the conversion of compound I to intermediate II determined with a stoichiometric amount of hydroperoxide were found to be lower by an order of magnitude than when an excess of hydroperoxide was used. The difference was attributed to ability of the compound I of prostaglandin endoperoxide synthase to be reduced by the excess of hydroperoxide. This suggests that the true rate constant of unimolecular conversion compound I to intermediate II at 3 degrees C is 5-10 s-1 instead of 50-200 s-1 as reported before. The latter value rather characterizes the combined process of spontaneous and hydroperoxide-dependent transformation of compound I. Stoichiometric amounts of reducing substrates significantly stimulated transformation of compound I. This effect could not be entirely explained by their reducing action, which was measured by following the oxidation kinetics. The results of the global fit of the experimental data suggest that reducing substrates, in addition to their direct action in reducing compound I to compound II, indirectly stimulate transformation of compound I to the tyrosyl radical form of intermediate II, thereby stimulating the cyclooxygenase reaction.     

Reaction of human myeloperoxidase with hydrogen peroxide and its true catalase activity

The instability of human myeloperoxidase [EC 1.11.1.7] compound I, which was spontaneously reduced to compound II, and the abnormal stoichiometry of the reaction of myeloperoxidase with H2O2 were investigated. As to the former, a pretreatment of myeloperoxidase with H2O2 did not stabilize compound I, and no difference in its stability was observed between native (alpha 2 beta 2) and hemi (alpha beta) myeloperoxidase. From these results, it was thought that the instability of compound I was caused by neither the presence of endogenous donors nor the intramolecular reduction of compound I to compound II by the other heme in the native enzyme molecule. As for the latter, true catalase activity of myeloperoxidase was demonstrated by monitoring O2 evolution after the injection of H2O2 into the enzyme solution. Myeloperoxidase compound I reacted with H2O2 and returned to the ferric state with concomitant evolution of an O2 molecule. Accordingly, the abnormal stoichiometry of the reaction with H2O2 and a part of the instability of compound I can probably be ascribed to this true catalase activity.     

Arylglycerol-γ-Formyl Ester as an Aromatic Ring Cleavage Product of Nonphenolic β-O-4 Lignin Substructure Model Compounds Degraded by Coriolus versicolor

4-Ethoxy-3-methoxyphenylglycerol-γ-formyl ester (compound IV) was identified as a degradation product of both 4-ethoxy-3-methoxyphenylglycerol-β-syringaldehyde ether (compound I) and 4-ethoxy-3-methoxyphenylglycerol-β-2,6-dimethoxyphenyl ether (compound II) by a ligninolytic culture of Coriolus versicolor. An isotopic experiment with a ¹³C-labeled compound (compound II′) indicated that the formyl group of compound IV was derived from the β-phenoxyl group of β-O-4 dimer as an aromatic ring cleavage fragment. However, compound IV was not formed from 4-ethoxy-3-methoxyphenylglycerol-β-guaiacyl ether (compound III). γ-Formyl arylglycerol (compound IV) could be a precursor of 4-ethoxy-3-methoxyphenylglycerol (compound VI), because 3-(4-ethoxy-3-methoxyphenyl)-1-formyloxy propane (compound VII) was cleaved to give 3-(4-ethoxy-3-methoxyphenyl)-1-propanol (compound VIII) by C. versicolor. 4-Ethoxy-3-methoxyphenylglycerol-β,γ-cyclic carbonate (compound V), previously found as a degradation product of compound III by Phanerochaete chrysosporium (T. Umezawa, and T. Higuchi, FEBS Lett., 25:123-126, 1985), was also identified from the cultures with compound I, II, and III and degraded to give the arylglycerol (compound VI). An isotopic experiment with ¹³C-labeled compounds II′ and III′ indicated that the carbonate carbon of compound V was derived from the β-phenoxyl groups of β-O-4 substructure.     

Isolation of an iron-binding compound from Pseudomonas aeruginosa.

An iron-binding compound was isolated from ethyl acetate extracts of culture supernatant fluids of Pseudomonas aeruginosa and was purified by successive paper and thin-layer chromatographic procedures. The purified compound was characterized by UV, visible, infrared, and fluorescence spectroscopy. The compound possesses phenolic characteristics, with little or no similarity to dihydroxybenzoates and no indication of a hydroxamate group. P. aeruginosa synthesized the compound during active growth in culture media containing less than 5 X 10(-6) M added FeCl3. When added to iron-poor cultures of P. aeruginosa, the compound promoted the growth of the bacterium and also reversed growth inhibition by the iron chelator ethylenediamine-di-(o-hydroxyphenylacetic acid).     

The effect of adrenal and gonadal hormones on vascular permeability in rat skin

The effect of adrenal and gonadal hormones on vascular permeability induced by intradermal injection of prostaglandins (PGs) E1, F2alfa, arachidonic acid and compound 48/80 have been examined in the rate. PGE1, arachidonic acid and compound 48/80 produced an increase in local vascular permeability. PGF2alfa decreased the action of these vasoactive agents, when it was injected in a mixture intradermally with PGE1, arachidonic acid and compound 48/80. Vasoactive response induced by PGE1, arachidonic acid and compound 48/80 was inhibited by the removal of adrenals and testes, and it was restored to normal by injection either of cortisol, deoxycorticosterone (DOC) or testosterone. In adrenalectomized rats, no change was observed in the inhibition of vascular permeability elicited by PGF2alfa response to compound 48/80. The blocking effect of PGF2alfa on vascular permeability evoked by PGE1 and arachidonic acid showed a considerable decrease. After orchidectomy the inhibitory effect of PGF2alfa on the vascular permeability induced by arachidonic acid and compound 48/80 was completely blocked, while in the case of PGE1 the inhibition was partial. Testosterone treatment restored the anti-inflammatory effect of PGF2alfa against compound 48/80. Ovariectomy was without any effect on vascular response.     

Superoxide modulates the activity of myeloperoxidase and optimizes the production of hypochlorous acid.

Myeloperoxidase catalyses the conversion of H2O2 and Cl- to hypochlorous acid (HOCl). It also reacts with O2- to form the oxy adduct (compound III). To determine how O2- affects the formation of HOCl, chlorination of monochlorodimedon by myeloperoxidase was investigated using xanthine oxidase and hypoxanthine as a source of O2- and H2O2. Myeloperoxidase was mostly converted to compound III, and H2O2 was essential for chlorination. At pH 5.4, superoxide dismutase (SOD) enhanced chlorination and prevented formation of compound III. However, at pH 7.8, SOD inhibited chlorination and promoted formation of the ferrous peroxide adduct (compound II) instead of compound III. We present spectral evidence for a direct reaction between compound III and H2O2 to form compound II, and for the reduction of compound II by O2- to regenerate native myeloperoxidase. These reactions enable compound III and compound II to participate in the chlorination reaction. Myeloperoxidase catalytically inhibited O2- -dependent reduction of Nitro Blue Tetrazolium. This inhibition is explained by myeloperoxidase undergoing a cycle of reactions with O2-, H2O2 and O2-, with compounds III and II as intermediates, i.e., by myeloperoxidase acting as a combined SOD/catalase enzyme. By preventing the accumulation of inactive compound II, O2- enhances the activity of myeloperoxidase. We propose that, under physiological conditions, this optimizes the production of HOCl and may potentiate oxidant damage by stimulated neutrophils.     

Biotransformation of 4-Hydroxybenzen Derivatives by Hairy Root Cultures of Polygonum multiflorum Thunb.

The biotransformation of four 4-hydroxybenzen derivatives （1,4-benzenediol （compound 1）, 4-hydroxybenzaldehyde （compound 2）, 4-hydroxybenzyl alcohol （compound 3） and 4-hydroxybenzoic acid （compound 4）） by the hairy root cultures of Polygonum multiflorum Thunb. as a new biocatalyst was investigated. It was found that the substrates were transformed to their corresponding glucosides, 4-hydroxyphenyl β-D-glucopyranoside （arbutin, compound la）, 4-hydroxymethylphenyl β-D-glucopyranoside （gastrodin, compounds 2a, 3a） and 4-carboxyphenyl α-D- glucopyranoside （compound 4a）, respectively. In the meantime, the hairy roots of P. multiflorum were able to stereoselectively and regioselectively glucosylate phenolic hydroxyl groups of compounds 1-4, but the cultures could not glucosylate the aldehyde group of compound 2 or the benzyllc hydroxyl group of compound 3, and no glucosyl esterification of carboxyl groups of compound 4 was detected. On the other hand, the result also showed that the hairy roots of P. multiflorum were able to reduce the 4-hydroxybenzaldehyde to its corresponding alcohol. This is the first report that substrate 4 has been converted into its α-D-glucopyranoside by a plant biotransformα- tion system.     

Metabolism of 2,4,4′-Trichlorobiphenyl by Acinetobacter sp. P6

Metabolism of 2,4,4′-trichlorobiphenyl by Acinetobacter sp. strain P6 has been studied. When the incubation was carried out without shaking at 15°C, two isomeric monohydroxy compounds, a dihydrodiol compound, a dihydroxy compound, a meta-cleaved yellow compound and a dichlorobenzoic acid were detected by combined gas liquid chromatograph-mass spectrometry. As an additional metabolite, dichlorodihydroxy biphenyl, a dechlorinationhydroxylation product, was also detected. When the incubation mixture was shaken at 30°C, a meta-cleaved yellow compound was readily produced and predominantly accumulated in the reaction mixture upon further incubation. The major pathway of 2,4,4′-trichlorobiphenyl by Acinetobacter sp. P6 was considered to proceed oxidatively via 2.′3′-dihydro-2′,3′-diol compound, concomitant dehydrogenated 2′,3′-dihydroxy compound and then the 1′,2′-meta-cleaved yellow compound, i.e., 3-chloro-2-hydroxy-6-oxo-6(2,4-dichlorophenyl)hexa-2,4-dienoic acid.     

Siderophore containing 2,3-dihydroxybenzoic acid and threonine formed by Rhizobium trifolli

An iron-binding compound was isolated from ethyl acetate extract of culture supernatant fluid of Rhizobium trifolii AR6 and was purified by iron-exchange chromatography. The compound was characterized by UV and IR. It contained 2,3-dihydroxy-benzoic acid and threonine and was accumulated during stationary phase of growth in iron-deficient media. Synthesis of the siderophore was repressed by FeCl3. In iron limited medium the compound promoted growth of R. trifolii strains.     

Redox properties of the couples compound I/compound II and compound II/native enzyme of human myeloperoxidase

Myeloperoxidase (MPO) is an important component of the neutrophil's antimicrobial armory and has been implicated in promoting tissue damage in numerous inflammatory diseases. For the first time the standard reduction potential of the redox couple compound II/native enzyme has been determined to be (0.97+/-0.01)V at pH 7.0 and 25 degrees C. This was achieved by rapid mixing of preformed compound II with either tyrosine or nitrite by using the sequential-mixing stopped-flow technique and measuring spectrophotometrically the concentrations of the reacting species and products at equilibrium. Using the recently determined standard reduction potential for the couple compound I/native enzyme (1.16 V), the reduction potential of the couple compound I/compound II was calculated to be 1.35 V at pH 7 and 25 degrees C. These data reveal substantial differences between the two known heme peroxidase superfamilies and reflect the dramatic differences observed in the oxidisability of substrates by the MPO redox intermediates compound I and compound II.     

Transformation of hemoglobin a into methemoglobin by sesamol

Sesamol (3,4-methylenedioxyphenol), a monophenolic antioxidant in sesame iol, produced methemoglobin from hemoglobin A (oxyhemoglobin and deoxyhemoglobin) and from red cells. The activity of the compound was more extensive than the polyphenolic compounds. The profiles of the methemoglobin formation by the compound were compared with those by nitrite and hydroxylamine. The formation of methemoglobin from oxyhemoglobin by the compound was rather slowly progressed, but the amount of methemoglobin formed was proportional to the concentration of oxyhemoglobin even when the concentration of the compound was low. The sesamol-induced methemoglobin formation was influenced by inositol hexaphosphate, an allosteric effector of hemoglobin. Thus, the phosphate enhanced the transformation of oxyhemoglobin and inhibited the transformation of deoxyhemoglobin.     

Effect of compound D-600 (methoxyverapamil) on gluconeogenesis and on acceleration of the process by alpha-adrenergic stimuli in rat kidney tubules.

1. Tubule fragments were isolated from renal cortex of fed rats and glucose formation was measured after incubation with 5 mM-sodium lactate. 20 Compound D-600 (10-100 microM) decreased gluconeogenesis from lactate. This inhibition of the process by compound D-600 increased with increasing extracellular Ca2+ concentration, was overridden by noradrenaline and diminished by starvation for 24 h. 3. Inhibition of lactate-supported gluconeogenesis by compound D-600 was not prevented by the alpha 1-adrenoceptor antagonist thymoxamine. 4. Compound D-600 had little effect on gluconeogenesis from 2-oxoglutarate and increased gluconeogenesis from succinate. 5. Compound D-600 opposed stimulation of gluconeogenesis by noradrenaline or oxymetazoline (a selective alpha-adrenoceptor agonist) in a manner suggesting that compound D-600 is an alpha-adrenoceptor blocker. Oxymetazoline was more sensitive than noradrenaline to blockade by both compound D-600 and by the conventional alpha-adrenoceptor antagonist phentolamine. Noradrenaline became more sensitive to blockade by compound D-600 when extracellular Ca2+ was decreased. 6. Compound D-600 did not block stimulation of gluconeogenesis by angiotensin or cyclic AMP.     

Effects of a Dictamnus dasycarpus T. extract on allergic models in mice

The anti-allergic effect of a 70% ethanol extract from Dictamnus dasycarpus Turcz (DDT) was studied in mice. DDT at doses of 200 and 500 mg/kg inhibited the systemic anaphylactic shock induced by compound 48/80 in a dose-dependent manner. It also inhibited dose-dependently the scratching behavior induced by compound 48/80, histamine and serotonin. An increase in the vascular permeability induced by compound 48/80, histamine and serotonin was also inhibited by DDT. In an in vitro study, DDT inhibited the histamine released from rat peritoneal mast cells induced by compound 48/80. It seems likely from these findings that DDT was effective in antagonizing certain pharmacological effects induced by compound 48/80 that occurred via both histamine and serotonin released from mast cells. In conclusion, DDT may be effective in the relief of symptoms of allergic atopic dermatitis and other allergy-related diseases.     

Ring hydroxylation of di-t-butylhydroxytoluene by rat liver microsomal preparations

3,5-Di-t-butylhydroxytoluene (compound I) was converted into 4-hydroperoxy-4-methyl-2,6-di-t-butylcyclohexa-2,5-dienone (compound II), 4-hydroxy-4-methyl-2,6-di-t-butylcyclohexa-2,5-dienone (compound III) and 2,6-di-t-butyl-4-hydroxymethylphenol (compound IV) by rat liver microsomal preparations in the presence of NADPH and air. The oxidation of compound (I) by m-chloroperbenzoic acid also produced the same compounds. These results suggest that hydroperoxide can be an intermediate in aromatic hydroxylation and that biological oxygenations resemble per-acid reactions.     

Structure of the Ring Cleavage Product of 1-Hydroxy-2-Naphthoate, an Intermediate of the Phenanthrene-Degradative Pathway of Nocardioides sp. Strain KP7

1-Hydroxy-2-naphthoate (compound I) is a metabolite of the phenanthrene-degradative pathway in Nocardioides sp. strain KP7. This singly hydroxylated aromatic compound is cleaved by 1-hydroxy-2-naphthoate dioxygenase. In this study, the structure of the ring cleavage product generated by the action of homogeneous 1-hydroxy-2-naphthoate dioxygenase was determined upon separation by high-performance liquid chromatography at pH 2.5 by using nuclear magnetic resonance (NMR) and mass spectroscopic techniques. The ring cleavage product at this pH existed in equilibrium between two forms, 2-oxo-3-(3-oxo-1,3-dihydro-1-isobenzofuranyl)propanoate (compound III) and 2,2-dihydroxy-3-(3-oxo-1,3-dihydro-1-isobenzofuranyl)propanoate (compound IV). After the pH of the solution was raised to 7.5, the structure of the major species became (E)-4-(2-carboxylatophenyl)-2-oxo-3-butenoate (compound II; common name, trans-2′-carboxybenzalpyruvate), which was in equilibrium with compound III. Direct monitoring of the enzymatic formation of the ring cleavage product by ¹H-NMR in a deuterated potassium phosphate buffer (pH 7.5) detected only compound II as a product, and the proton on carbon 3 of compound II was not exchanged with deuterium. Thus, compound II is likely to be the first stable product of dioxygenation of 1-hydroxy-2-naphthoate.