In vitro anti- and pro-oxidative effects of natural polyphenols

The anti- and pro-oxidative effects of phenolic compounds and antioxidants were studied in two different in vitro model systems utilizing ethyl linoleate and 2′-deoxyguanosine (2′-dG) as oxidative substrates, and a Fenton reaction (H₂O₂, Fe²⁺) to initiate oxidation. Oxidation of the biomolecules in both model systems exhibited dose dependency. In the 2′-dG assay, oxidation was closely related to H₂O₂ generation, which occurred during autoxidation of the phenolics. Hydroxylating activity was greatly enhanced by Mn²⁺ and Cu²⁺, but not by Zn²⁺ or Co²⁺. Ethyl linoleate peroxidation was inhibited by low concentrations of catechol, quercitin, and instant coffee. However, peroxidation was promoted by high concentrations of the same compounds, probably by recycling of chelated inactive Fe³⁺ to the active Fe²⁺ state.     

Cometabolic turnover of aniline,phenol and some of their monochlorinated derivatives by the Rhodococcus mutant strain AM 144

One-step conversion of aniline, phenol and some of their monochlorinated derivatives into the corresponding catechols by resting pre-adapted cells of the Rhodococcus mutant strain AM 144 (defective in synthesis of catechol 1,2-dioxygenase) was shown to depend on the availability of an additional metabolizable carbon substrate, e.g. glucose or acetate. A stoichiometric relation existed between the amount of the latter compounds added and the amount of aniline (or phenol, respectively) converted into catechol suggesting that the primary function of the cosubstrates was to provide reducing power to the oxygenative transformation reaction. The observed cosubstrate-dependence generally parallels that seen in previous studies on turnover of different monochloroaromatic non-growth substrates by aromatics-utilizing Rhodococcus wildtype-strains. Cell cultures of strain AM 144 growing at the expense of acetate also proved able to convert aniline into catechol. Typically, growth of the cells was retarded during the phase of aniline transformation as compared to the respective control cultures. Based on the results of these model experiments, it was concluded that (i) in natural microbial communities cometabolically active bacteria would hardly enrich under cometabolic conditions over fast-growing non-cometabolizing bacteria if the latter organisms will tolerate the particular non-growth substrate, and (ii) cometabolizing bacteria would have a selective advantage only if the non-growth substrate to be transformed is a toxic one or if it can serve as a potential nutrient source (e.g., of nitrogen or sulfur).Abbreviations MCA monochloroaniline - MCP monochlorophenol - MCC monochlorocatechol - TLC thin-layer chromatography - MS mass spectrometry - GLC gas-liquid chromatography - UV ultraviolet (range of the spectrum)     

Catechols involved in sclerotization of cuticle and egg pods of the grasshopper,Melanoplus sanguinipes,and their interactions with cuticular proteins

N‐Acetyldopamine (NADA) is the major catechol in the hemolymph of nymphal and adult grasshoppers, Melanoplus sanguinipes (F.), and mainly occurs as an acid‐labile conjugate indicated to be a sulfate ester. Its concentration increases in last instar nymphs and peaks during adult cuticle sclerotization. Dopamine (DA), the precursor of NADA and melanic pigments, is about 10 times lower in concentration than NADA, but shows a similar pattern of accumulation. NADA also predominates in cuticle, but its concentration is lowest during the active period of sclerotization, reflecting its role as a precursor for quinonoid tanning agents. Two other catechols, 3,4‐dihydroxybenzoic acid (DOBA) and 3,4‐dihydroxyphenylethanol (DOPET), also occur in hemolymph and cuticle, and their profiles suggest a role in cuticle stabilization. Solid‐state NMR analysis of sclerotized grasshopper cuticle (fifth instar exuviae) estimated the relative abundances of organic components to be 59% protein, 33% chitin, 6% catechols, and 2% lipid. About 99% of the catechols are covalently bound in the cuticle, and therefore are involved in sclerotization of the protein‐chitin matrix. To determine the types of catechol covalent interactions in the exocuticle, samples of powdered exuviae were heated in Hcl under different hydrolytic conditions to release adducts and cross‐linked products. 3,4‐Dihydroxyphenylketoethanol (DOPKET) and 3,4‐dihydroxyphenylketoethylamine (arterenone) are the major hydrolysis products in weak and strong acid, respectively, and primarily represent NADA oligomers that apparently serve as cross‐links and filler material in sclerotized cuticle. Intermediate amounts of norepinephrine (NE) are released, which represent N‐acetylnorepinephrine (NANE), a hydrolysis product of NADA bonded by the b‐carbon to cuticular proteins and possibly chitin. Small quantities of histidyl‐DA and histidyl‐DOPET ring and side‐chain C‐N adducts are released by strong acid hydrolysis. Therefore, grasshopper cuticle appears to be sclerotized by both o‐quinones and p‐quinone methides of NADA and dehydro‐NADA, which results in a variety of C‐O and C‐N covalent bonds linked primarily through the side‐chain carbons of the catechol moiety to amino acid residues in cuticular proteins. The primary catechol extracted from both the female accessory glands/calyx and the proteinaceous frothy material of the egg pod is DOBA, which also commonly occurs in cockroach accessory glands and oothecae, presumably as a tanning agent precursor. 3,4‐Dihydroxyphenylalanine (DOPA) was also detected in extracts of the accessory glands/calyx of grasshoppers, and may serve as a precursor for DOBA synthesis. Arch. Insect Biochem. Physiol. 40:119–128, 1999. © 1999 Wiley‐Liss, Inc.     

An urushiol derivative from poison sumac

GC analysis of the ethanolic extract of poison sumac (Toxicodendron vernix) showed five urushiol components four of which were identical with those     

Bioconversion of bi- and tri-cyclic monophenols by alginate-entrapped cells of Mucuna pruriens L. and by the partially purified Mucuna-phenoloxidase

Although alginate-entrapped cells of Mucuna pruriens L. possess a low substrate specificity, only para-substituted monocyclic phenols have been ortho-hydroxylated into catechols so far. In this study, compounds with more complex chemical structures were found to be substrates using entrapped cells of M. pruriens as well as the partially purified Mucuna-phenoloxidase. Thus, 5-, 6- and 7-hydroxylated 2-aminotetralins and a tricyclic compound, 9-hydroxy N-n-propyl hexahydronaphthoxazine, were converted into catechols. After isolation using preparative HPLC, the identity of the products was confirmed by MS. In general, for the entrapped cells and the enzyme preparation identical substrate specificities were found.This publication is dedicated to the memory of Prof. Alan S. Horn, Ph.D., who deceased at January 2, 1990     

Plant catechols prevent lipid peroxidation in human plasma and erythrocytes

The antioxidant activity of several plant catechol derivatives was tested in buffer, plasma, and human erythrocytes. In buffer, chlorogenic acid (CGA), caffeic acid (CA), and dihydrocaffeic acid (DCA) reduced ferric iron equally well in the ferric reducing antioxidant power (FRAP) assay. Low concentrations of the polyphenols enhanced the ability of plasma to reduce ferric iron by about 10%. In plasma, lipid hydroperoxide and F₂-isoprostane formation induced by a water-soluble free radical initiator were reduced by CGA at concentrations as low as 20 M. During incubation at 37°C, human erythrocytes took up DCA, but not CGA, and intracellular DCA enhanced the ability of erythrocytes to reduce extracellular ferricyanide. When intact erythrocytes were exposed to oxidant stress generated by liposomes containing small amounts of lipid hydroperoxides, extracellular CGA at a concentration of 5 M decreased both lipid peroxidation in the liposomes, and spared -tocopherol in erythrocyte membranes. These results suggest that the catechol structure of these compounds convey the antioxidant effect in plasma and in erythrocytes.     

用钴卟啉修饰电极催化测定多巴胺等神经递质

将5, 10, 15, 20－四－（3－甲氧基－4－羟基苯基）卟啉钴（CoTMHPP）修饰在玻碳电极表面,制备成对多巴胶等神经递质有高灵敏度响应的CoTMHPP修饰电极．电极具有灵敏度高、响应快、稳定性好等特点．电极响应时间小于10s,儿茶酚类化合物的检测浓度为10^-6mol／L．     

Cyclodextrins as a useful tool for bioconversions in plant cell biotechnology

The application of cyclodextrins as precursor solubilizers in biotechnological processes, in which plant cells are involved, is new. In this paper the possibilities for cyclodextrin facilitated bioconversions by freely suspended and/or immobilized plant cells or plant enzymes are demonstrated. After complexation with -cyclodextrin, the phenolic steroid 17-estradiol could be ortho-hydroxylated into a catechol, mainly 4-hydroxyestradiol, by a phenoloxidase from in vitro grown cells of Mucuna pruriens. By complexation with -cyclodextrin the solubility of the steroid increased from almost insoluble to 660 M. In addition, by complexation with -cyclodextrin, a solution of 3 mM coniferyl alcohol could be fed to cell cultures of Podophyllum hexandrum in order to enhance the accumulation of podophyllotoxin. Finally, the glucosylation of podophyllotoxin by cell cultures derived from Linum flavum was investigated. Four cyclodextrins: -cyclodextrin, -cyclodextrin, hydroxypropyl--cyclodextrin and dimethyl--cyclodextrin were used to improve the solubility of podophyllotoxin. Dimethyl--cyclodextrin met our needs the best and the solubility of podophyllotoxin could be enhanced from 0.15 to 1.92 mM. Podophyllotoxin--d-glucoside was formed at a rate of 0.51 mmol l^-1 suspension per day by the L. flavum cells growing in the presence of 1.35 mM podophyllotoxin, complexed with dimethyl--cyclodextrin.Abbreviations DW dry weight - E2 17-estradiol - FW fresh weight - PCV packed cell volume     

Effect of the o-methyl catechols apocynin,curcumin and vanillin on the cytotoxicity activity of tamoxifen

Apocynin (APO), curcumin (CUR) and vanillin (VAN) are o-methyl catechols widely studied due their antioxidant and antitumour properties. The effect of treatment with these o-methyl catechols on tamoxifen (TAM)-induced cytotoxicity in normal and tumour cells was studied. The cytotoxicity of TAM on red blood cells (RBC) was performed by haemoglobin or K⁺release and on polymorphonuclear leukocytes (PMNs) by trypan blue dye exclusion method. Cytotoxic activity was assessed in human chronic myeloid leukemia (K562) cell line by (3-[4,5-dimethylthiazol-2-yl]-2,5-diphenyltetrazolium bromide). According the release of haemoglobin and K⁺, the CUR showed a decrease in TAM cytotoxicity on RBC; however, in PMN, APO, CUR and VAN showed increased of these cells viability. VAN presented the highest cytotoxicity on K562 cells, followed by APO and CUR. These results point the potential therapeutic value of these o-methyl catechols with TAM, particularly of CUR, which potentiates the cytotoxic effects of TAM on K562 cells and also decreases TAM-associated cytotoxicity on RBC and PMN.     

Continuous production of the pharmaceutical 7,8-dihydroxy N-di-n-propyl 2-aminotetralin using a phenoloxidase from cell cultures of Mucuna pruriens

Alginate-entrapped cells of Mucuna pruriens as well as the phenoloxidase isolated from the cell cultures, are able to ortho-hydroxylate several mono-, bi- and tri-cyclic monophenols. In this study, 7,8-dihydroxy N-di-n-propyl 2-aminotetralin, a catechol of pharmaceutical interest and difficult to prepare chemically, could be produced in considerable quantities by bioconversion of the precursor 7-hydroxy N-di-n-propyl 2-aminotetralin. A continuous flow system on a laboratory scale was used, which consisted of a phenoloxidase suspension in dialysis tubing as the biocatalysator in an airlift fermentor coupled with an aluminium oxide column for selective product isolation. Product formation continued for at least 50 h, resulting in ca. 130 mg product per liter, this being a bioconversion percentage of 25%. When the enzyme preparation was reused, 85% of the original activity was measured.Alan S. Horn deceased at January 2nd, 1990