Reactivity of ubiquinones and ubiquinols with free radicals

The reactivity of quinones 1–4 and of the corresponding quinols 5–8 towards carbon- and oxygen-centred radicals were studied. All quinones bearing at least one nuclear position free, readily react with alkyl and phenyl radicals to afford the alkylated quinones 12–24; however, quinones 1 and 3 reacted with 2-cyano-2-propyl radical to yield products (the mono- and di-ethers 9–11) derived from the attack on the carbonylic oxygen. The reactions carried out on quinones with the benzoyloxy radical led to no reaction products and in the case of Q₁₀, the isoprenic chain also remained unchanged. Quinols 5–8 reacted only with oxygencentred radicals (benzoyloxy and 2-cyano-2-propylperoxy radicals) to give the corresponding quinones. The isoprenic chain of Q₁₀ did not undergo attack even with peroxy radicals. Carbon-centred radicals resulted unable to abstract hydrogen from the studied quinols.     

Spin Trapping by Use of N-Tert-Butylhydroxylamine. Involvement of Fenton Reactions

Spin trapping of short-lived R. radicals is done by use of N-tert-butylhydroxylamine (1) and H²O². The hydroxylamine is oxidized to the radical t-BuN(O)H (2) which is converted into the spin trap 2-methyl-2-nitrosopropane (3). Simultaneously, hydroxyl radicals. OH are formed from H²O². The latter radical species abstracts hydrogen atoms from suitable molecules HR to give R. radicals, which are trapped with the formation of aminooxyl radicals, i. e., t-BuN(O)R (4) detectable by EPR spectroscopy. The reaction is enhanced by the presence of iron ions. The cleavage of H²O² into. OH radicals is considered to involve both a radical-driven (t-BuN(O)H 2) and an iron-driven Fenton reaction.     

Regioselective acylation of several polyhydroxylated natural compounds by Candida antarctica lipase B

Regioselective acylation of four polyhydroxylated natural compounds, deacetyl asperulosidic acid (1), asperulosidic acid (2), puerarin (3) and resveratrol (4) by Candida antarctica Lipase B in the presence of various acyl donors (vinyl acetate, vinyl decanoate or vinyl cinnamoate) was studied. Compounds 1, 2 and 4 were regioselectively acetylated with vinyl acetate to afford products, 3'-O-acetyl-10-O-deacetylasperulosidic acid (1a), 3',6'-O-diacetyl-10-O-deacetylasperulosidic acid (1b), 3'-O-acetylasperulosidic acid (2a), 3',6'-O-diacetylasperulosidic acid (2b), 4'-O-acetylresveratrol (4a), respectively, with yields of 22 to 50%, while reactions with vinyl decanoate and vinyl cinnamoate were slow with lower yields. Compound 3 was readily acylated with all three acyl donors and quantitatively converted to products 6'-O-acetylpuerarin (3a), 6'-O-decanoylpuerarin (3b), 6'-O-cinnamoylpuerarin (3c), respectively. The structures of these acylated products were determined by spectroscopic methods (MS and NMR).     

Mechanism of O2 generation in reduction and oxidation cycle of ubiquinones in a model of mitochondrial electron transport systems

O⁻₂ generation in mitochondrial electron transport systems, especially the NADPH-coenzyme Q₁₀ oxidoreductase system, was examined using a model system, NADPH-coenzyme Q₁-NADPH-dependent cytochrome P-450 reductase. One electron reduction of coenzyme Q₁ produces coenzyme Q₁ and O⁻₂ during enzyme-catalyzed reduction and O₂ + coenzyme Q₁ are in equilibrium with O⁻₂ + coenzyme Q₁ in the presence of enough O₂. The coenzyme Q₁ produced can be completely eliminated by superoxide dismutase, identical to bound coenzyme Q₁₀ radical produced in a succinate/fumarate couple-KCN-submitochondrial system in the presence of O₂. Superoxide dismutase promotes electron transfer from reduced enzyme to coenzyme Q₁ by the rapid dismutation of O₂⁻ generated, thereby preventing the reduction of coenzyme Q₁ by O⁻₂. The enzymatic reduction of coenzyme Q₁ to coenzyme Q₁H₂ via coenzyme Q₁ is smoothly achieved under anaerobic conditions. The rate of coenzyme Q₁H₂ autoxidation is extremely slow, i.e., second-order constant for [O₂][coenzyme Q₁H₂] = 1.5 M⁻¹ · s⁻¹ at 258 μM O₂, pH 7.5 and 25°C.     

Biotransformation of γ-terpinene using Stemphylium botryosum (Wallroth) yields p-mentha-1,4-dien-9-ol, a novel odorous monoterpenol

A wild strain of Stemphylium botryosum, when grown submerged in the presence of γ-terpinene (1), yielded the novel highly odour active terpene alcohol (2), whose structure was established by spectroscopic means as p-mentha-1,4-dien-9-ol. During cultivation (2) was further oxidized, predominantly to the corresponding aromatic alcohol p-cymene-9-ol (5). The enantioselective enzymatic introduction of the hydroxyl group at the non-activated C9 of (1) resulted in an enantiomeric excess (ee) of 74% for (2) and 70% for (5), respectively.     

An Efficient Chemoenzymatic Synthesis of S-(-)-Fenpropimorph

First enantioselective synthesis of S-(-)-1-[3-(4-tert-butylphenyl)-2-methyl]propyl-cis-3,5-dimethylmorpholine (6), biologically active enantiomer of the systematic fungicide fenpropimorph, is reported. It comprises reacting 4-tert-butylbenzylbromide with methyldiethylmalonate, decarbethoxylation of 2 into racemic 3-(4-tert-butylphenyl)-2-methylpropionic acid ethylester (3) in DMSO in the presence of alkali, then Pseudomonas sp. lipase catalyzed kinetic resolution of racemic 3 into S-(+)-acid (4), base-catalyzed racemization and recycling of the R-(-)-ester 3, acylation of cis-3,5-dimethylmorpholine, and final reduction of the intermediary amide 5 to provide enantiomerically pure S-(-)-6.     

Radical-Induced Damage to Proteins: E.S.R. Spin-Trapping Studies

The reactions of hydroxyl radicals generated from Fe¹¹/H₂O₂ and Cu¹¹/H₂O₂ redox couples with a variety of proteins (BSA, histones, cytochrome c, lysozyme and protamine) have been investigated by e.s.r. spin trapping. The signals obtained, which are generally anisotropic in nature, characterize the formation of partially-immobilized spin-adducts resulting from attack of the HO- radicals on the protein and subsequent reaction of the protein-derived radicals with the spin trap. Similar spin adducts are observed on incubation of two haem-proteins (haemoglobin and myoglobin) with H₂O₂ in the absence of added metal ions implying a reaction at the haem centre followed by internal electron transfer reactions.

Two strategies have been employed to obtain information about the site(s) of radical damage in these proteins. The first involves the use of a variety of spin traps and in particular DMPO: with this particular trap the broad spectra from largely immobilized radicals show characteristic a(β-H) values which enable carbon-, oxygen- and sulphur-centred radicals to be distinguished. The second involves the use of enzymatic cleavage of first-formed adducts to release smaller nitroxides, with isotropic spectra, which allow the recognition of β-proton splittings and hence information about the sites of radical damage to be obtained. These results, which allows backbone and side-chain attack to be distinguished, are in agreement with random attack of the HO^. radical on the protein and are in accord with studies carried out on model peptides. In contrast the use of less reactive attacking radicals [N₃·, ·CH(CH₃)OH] and oxidising agents (Ce⁴⁺) provides evidence for selective attack on these proteins at particular residues.     

Transformations of arylpropane lignin model compounds by a lignin peroxidase of the white-rot fungus Phanerochaete chrysosporium

Various lignin model compounds of the O-arylpropane type were oxidized with purified lignin peroxidase from the white-rot fungus Phanerochaete chrysosporium, and oxidation products were identified by gas-chromatography/mass-spectroscopy procedures. Our results are in accord with the theory that lignin peroxidase catalyzes one-electron oxidations of its substrates with formation of cation radicals, and that these radicals undergo degradative reactions that are predictable from a knowledge of cation radical and oxygen chemistry. Cation radicals formed from O-arylpropane model compounds appeared to undergo the following types of degradative transformations: addition of water to ring-centered radicals, followed by proton loss yielding quinones and alcohols; nucleophilic attack by hydroxy functions on propanoid moieties giving cyclic ketals as intermediates which decompose to yield side chain migration products; transfer of the charge of a radical from a ring to the associated alkyl moiety through an ether bond, with loss of a proton from the latter, forming a new carbon-centered radical. The new alkyl-centered radicals apparently were able to abduct dioxygen to form peroxyl radicals which decomposed giving a variety of oxidation products and probably superoxide anion. Specific examples of the above transformations are presented, and their relevance to lignin degradation is discussed.     

Book Review

LEGGETT, W. F. Ancient and Medieval Dyes. 5 × 8 in. 96 pp. Cloth. Chemical Publishing Co., Brooklyn, N. Y. 1944. $2.25.

Microtechnic In General. McCARTNEY, J. E. A new immersion oil “polyric”. J. Path. & Bact., 56, 265-6. 1944.

NICKERSON, MARK. A dry ice freezing unit for rotary microtomes. Science, 100, 177-8. 1944.

Dyes And Thedx Biological Uses. BERGEIM, FRANK H., and BRAKER, WILLIAM. Homosulfanilamides. J. Amer. Chem. Soc., 66, 1459. 1944.

CALDWELL, W. T., TYSON, F. T., and LAUER, LOTHAR. Substituted 2-sulfonamido-5-aminopyridines. II. J. Amer. Chem. Soc., 66, 1479. 1944.

JOHNS, C. K. Dye concentration in resazurin tablets. Amer. J. Pub. Health, 34, 955-8. 1944.

SMITH, WINSLOW WHITNEY. Relative sensitivity of different phases of growth curve of Bact. salmonicida to alkaline acriflavine. Proc. Soc. Exp. Biol. & Med., 56, 240-2. 1844.

VAN ARENDONK, A. M., and SHOULE, H. A. Dialkylaminoalkyl derivatives of substituted quinolines and quinaldines. J. Amer. Chem. Soc., 66, 1284. 1944.

WHEELER, KEITH, and DEGERING, E. F. Preparation and properties of certain derivatives of sulfamide. J. Amer. Chem. Soc., 66, 1242. 1944.

Animal Microtechnic. BOARDMAN, EDWARD T. Methods for collecting ticks for study and delineation. J. Parasitology, 30, 57-9. 1944.

DICKIE, MARGARET M. A new differential stain for mouse pituitary. Science, 100, 297-8. 1944.

GOVAN, A. D. TELFORD. Fat staining by Sudan dyes suspended in watery media. J. Path. & Bact., 56, 262-4. 1944.

LILLIE, R. D., and ASHBURN, L. L. Supersaturated solutions of fat stains in dilute isopropanol for demonstration of acute fatty degenerations not shown by Herxheimer technic. Arch. Path., 36, 432. 1943.

MULLEN, J. P. A convenient and rapid method for staining glycogen in paraffin sections with Best's carmine stain. Amer. J. Clin. Path., Tech. Sect., 8, 9-10. 1944.

NYKA, W. A method for staining the rickettsiae of typhns in histological sections. J. Path. & Bact., 56, 264. 1944.

POPPER, HANS, GYORGY, PAUL, and GOLDBLATT, H. Fluorescent material (ceroid) in experimental nutritional cirrhosis. Arch. Path., 37, 161. 1944.

SMALL, C. S., and SCHULTZ, M. A. Sustaining faded tissue sections. Amer. J. Clin. Path., Tech. Sect., 7, 66-7. 1943.

YOFFEY, J. M., and PARNELL, J. The lymphocyte content of rabbit bone marrow. J. Anat., 78, 109-12. 1944.

ZIEGLER, E. E. Hematoxylin-eosin tissue stain. An improved, rapid, and uniform technic. Arch. Path., 37, 68. 1044.

Plant Microtechnic. HAASIS, FERDINAND W. Staining rubber in ground or milled plant tissues. Ind. and Eng. Chem., Anal. Ed., 16, 480. 1944.

PARRIS, G. K. A simple nuclear stain and staining technique for Helminthosporia. Phytopathology, 34, 700. 1944.

Microorganisms. DARZINS, E. Rickettsienstudien. Zentbl. Bakl., Abt. I, Orig., 151, 18-20. 1943.

GOHAR, M. A. A staining method for Corynebacterium diphtheriae. J. Bact., 47, 575. 1944.

GRAY, P. H. H. Two-stain method for direct bacteria count. J. Milk Techn., 6, 76. 1943.     

Synthesis of plastoquinone-9 and phytylplastoquinone from homogentisate in lettuce chloroplasts

Chloroform-soluble extracts of unpurified chloroplast preparations of lettuce, pea and spinach and of class I lettuce chloroplasts that have been incubated in the light with [methylene-³H]homogentisate contain ³H-labelled plastoquinones-9 and -8 (minor homologue), 2-demethylplastoquinones-9 and -8 (minor homologue), pytylplastoquinone and 2-demethylphytylplastoquinone.. The absence of demethylquinols, the presumed precursors of the dimethylquinones, from the extracts to the fact that no precautions were taken in the extraction procedure to present their oxidation to the corresponding quinones.In unpurified lettuce chloroplasts the synthesis of these compounds from [methylene-³H]homogentisate is Mg²⁺-dependent and it is stimulated by light. The addition of isopentenyl pyrophosphate to the incubation mixtures increases the amounts of both groups of quinones (polyprenyl quinones and phytyl quinones) synthesised in the light and the amounts of polyprenyl quinones synthesised in the dark. Replacement of isopentenyl pyrophosphate with a source of preformed polyrenyl pyrophosphates brings about a marked rise in the amounts of polyprenyl quinones synthesized. This rise in polyprenyl quinone synthesis is further increased if the chloroplats are subjects to osmotic shock. The presence of S-adenosylmethionine increases the amounts of dimethylquinones synthesized at the expense of the demethylquinones. The implied precursor-product relationships between 2-demethylphytylplastoquinone (quinol?) and phytylplastoquinone and between the 2-demethylplastoquinones (quinols) and plastoquinones were verified in a pulse-labelling experiment. Confirmation that these quinones, or their corresponding quinols, are synthesized.     

The One-Electron Reduction Potential of 3-Amino-1, 2, 4-benzotriazine 1, 4-dioxide (Tirapazamine): A Hypoxia-Selective Bioreductive Drug

The one-electron reduction potential of 3-amino-l, 2, 4-benzotriazine 1, 4-dioxide, tirapazamine (SR 4233) in aqueous solution has been determined by pulse radiol-ysis. Reversible electron transfer was achieved between radiolytically-generated one-electron reduced radicals of tirapazamine (T), and quinones or benzyl viologen as redox standards. The reduction potential E_m7(T/T^±) was -0.45 ± 0.01 V vs. NHE at pH 7. From the pH dependence of the reduction potential, pK_a = 5.6 ± 0.2 was estimated for the tirapazamine radical, a value similar to the pK_a determined by other methods.     

2-substituted-3H-indol-3-one-1-oxides: preparation and radical trapping properties

A series of 2-alkyl and 2-aryl substituted-3H-indol-3-one-1-oxides was prepared and evaluated for its radical trapping properties. Spin trapping and electron paramagnetic resonance experiments demonstrate the ability of these indolone-1-oxides to trap hetero- and carbon-centered radicals. The most stable spin adducts (lifetime of several hours) are obtained with 2-alkyl substituted nitrones, the 2-ethyl-5,6-dioxolo-3H-indolone-1-oxide, 5e and the 2-secbutyl-3H-indolone-1-oxide, 5f. These two nitrones are also sensitive to redox reactions in solution. Therefore this indolone-1-oxide series lacking a β-hydrogen atom gives rise to highly stable adducts with free radicals.     

Reactions of captopril and epicaptopril with transition metal ions and hydroxyl radicals: An EPR spectroscopy study

In the present study, using the technique of EPR spin trapping with DMPO a spin trap, we demonstrated formation of thiyl radicals from thiol-containing angiotensin converting enzyme (ACE) inhibitor captopril (CAP) and from its stereoisomer epicaptopril (EPICAP), a non-ACE inhibitor, in the process of ^.OH radical scavenging. Splitting constants of DMPO/thiyl radical adducts were identical for both thiols and were a_N = 15.3 G, and a_H = 16.2 G. Bimolecular rate constants for the reaction of CAP and EPICAP with ^.OH radicals were close to a diffusion-controlled rate (≈ 2 × 10¹⁰ M⁻¹s⁻¹). Our data also show that both CAP and EPICAP reduce Fe(III) ions and that their respective thiyl radicals are formed in this reaction. In the presence of Fe(III), H₂O₂, and CAP, or EPICAP, ^.OH radicals were produced by a thiol-driven Fenton mechanism. Copper(II) ions were also reduced by these thiols, but no thiyl radicals could be detected in these reactions, and no ^.OH or other Fenton oxidants were observed in the presence of H₂O₂. Our data show direct evidence that thiol groups of CAP and EPICAP are involved in scavenging of ^.OH radicals. The direct ^.OH radical scavenging, together with the reductive “repair” of other sites of ^.OH radical attack, may contribute to the known protective effect of CAP against ischemia/reperfusion-induced arrhythmias. The formation of reactive thiyl radicals in the reactions of the studied compounds with ^.OH radicals and with Fe(III) ions may play a role in some of the known adverse effects of CAP.     

A Hydrogen-Donating Monohydroxamate Scavenges Ferryl Myoglobin Radicals

The addition of 25μM hydrogen peroxide to 20μM metmyoglobin produces ferryl (Fe^IV = O) myoglobin. Optical spectroscopy shows that the ferryl species reaches a maximum concentration (60-70% of total haem) after 10 minutes and decays slowly (hours). Low temperature EPR spectroscopy of the high spin metmyoglobin (g = 6) signal is consistent with these findings. At this low peroxide concentration there is no evidence for iron release from the haem. At least two free radicals are detectable by EPR immediately after H₂O₂ addition, but decay completely after ten minutes. However, a longer-lived radical is observed at lower concentrations that is still present after 90 minutes. The monohydroxamate N-methylbutyro-hydroxamic acid (NMBH) increases the rate of decay of the fenyl species. In the presence of NMBH, none of the protein-bound free radicals are detectable; instead nitroxide radicals produced by oxidation of the hydroxamate group are observed. Similar results are observed with the trihydroxamate, desferoxamine. “Ferryl myoglobin” is still able to initiate lipid peroxidation even after the short-lived protein free radicals are no longer detectable (E.S.R. Newman, C.A. Rice-Evans and M.J. Davies (1991) Biochemical and Biophysical Research Communications 179, 1414-1419). It is suggested that the longer-lived protein radicals described here may be partly responsible for this effect. The mechanism of inhibition of initiation of lipid peroxidation by hydroxamate drugs, such as NMBH, may therefore be due to reduction of the protein-derived radicals, rather than reduction of ferryl haem.     

Identification of free radical species derived from caffeic acid and related polyphenols

Polyphenols are widely distributed in various fruits, vegetables and seasonings. It is well known that they have several physiological effects due to their antioxidative activities. Their activities depend on structural characteristics that favour the formation of their corresponding stable radicals. During the examination at which pH values, the polyphenol radicals are stabilized, we confirmed that polyphenol radicals were stabilized in NaHCO₃/Na₂CO₃ buffer (pH 10) rather than in physiological pH region. Then, we measured electron spin resonance (ESR) spectra at pH 10 to examine the characteristics of free radical species derived from caffeic acid (CA) with an unsaturated side chain, dihydrocaffeic acid (DCA) with a saturated side chain, chlorogenic acid (ChA) and rosmarinic acid (RA). In analyzing the radical structures, ESR simulation, determinations of macroscopic and microscopic acid dissociation constants and molecular orbital (MO) calculation were performed. In CA, the monophenolate forms were assumed to participate in the formation of free radical species, while in DCA, the diphenol form and the monophenolate forms were presumed to contribute to the formation of free radical species. On the basis of the results, we propose the possible structures of the free radical species formed from polyphenols under alkaline conditions.     

Twenty-Four-Hour Variations in the Sensitivity of Rat Aorta to Vasoactive Agents

The presence of time-dependent variations in the in vitro sensitivity of aorta preparations to either vasoconstricting or relaxing agents was investigated in rats maintained in light from 08: 00 to 20: 00 and in darkness from 20: 00 to 08: 00. Rat thoracic aorta rings were obtained from animals sacrificed at four different times of the day. The rat aorta was found to be more sensitive to the constricting effect of phenylephrine at 15: 00, and of 5-hydroxytryptamine at 21: 00. On the other hand, both endothelium-dependent and -independent relaxations were more remarkable at 03: 00 than at other times of the day. These variations represented significant circadian rhythms when analyzed by analysis of variance. Different in vitro responsiveness to these agents might reflect changes in the sensitivity and/or number of related receptors in vascular preparations. In conclusion, the circadian time of animal sacrifice to obtain vascular preparations constitutes an important aspect of the research method and a key determinant of findings. (Chronobiology International, 13(6), 465-475, 1996)     

Quinone formation from carcinogenic benzo[a]pyrene mediated by lipid peroxidation in phosphatidylcholine liposomes

The behavior of benzo[a]pyrene (B[a]P) during peroxidation of phosphatidylcholine (PC) liposomes initiated by an azo compound was investigated to examine the mechanism of quinone formation from carcinogenic B[a]P mediated by nonenzymatic lipid peroxidation occurring in vivo. B[a]P had a retarding effect on the peroxidation of polyunsaturated fatty acid moiety of PC. The major oxidation products which accumulated in the peroxidized liposomes were B[a]P 1,6-, 3,6-, and 6,12-quinone. Antioxidants acting as scavengers of chain-propagating lipid peroxy radicals effectively prevented not only lipid peroxidation but also B[a]P oxidation in the liposomal suspension. PC hydroperoxides, the primary products of PC oxidation, did not react with B[a]P in the absence of the azo compound, indicating that lipid peroxy radicals, not lipid hydroperoxides, are responsible for the formation of these quinones. The experiments using 18O2 gas and 18O-labeled methyl linoleate hydroperoxides demonstrated that B[a]P quinones are formed by incorporating molecular oxygen and their origin is partly due to the lipid peroxy radical. The mechanism proposed for the formation of B[a]P quinones mediated by peroxidation of membrane lipids involves a direct attack of the lipid peroxy radical on B[a]P and subsequent autocatalytic oxidation. Weak carcinogenic and noncarcinogenic pentacyclic aromatic hydrocarbons showed little reactivity to the lipid peroxy radical in the liposomes. Thus, the facility of the peroxidative attack on B[a]P may be related to the powerful carcinogenic activity of this substance.     

Lipase Catalyzed Resolution of (±)-2-Substituted 1-Propanol Derivatives Possessing an Aromatic Ring

For the purpose of the chiral synthesis of natural products, lipase-catalyzed kinetic resolutions of three types of 2-substituted 1-propanol derivatives (each having an aromatic ring) was investigated. In every case, chiral recognition of the primary alcohol unit took place to provide the corresponding alcohols and the acetates in high optical purity. The (2S,3S)-5-aryl-2-methyl-3-hydroxy-4E-pentenol 5 was formally converted into the antibiotic, (-)-oudemansin X.     

Laboratory Hints from the Literature

Microscope and Other Apparatus: Bernard, J. E. The principles of fluorescence microscopy. J. Royal Micro. Soc., 57, 256-9. 1937.

Wrighton, H. A new light source for microscopy. J. Royal Micro. Soc., 57, 260-1. 1938.

Microtechhic in general: Comandon, J. and De Fonbrune, P. La chambre $aG huile. Ses avantages pour l'$eGtude des microorganisms vivants, la culture des tissus et la micromanipulation. Ann. Inst. Pasteur, 60, 113-41. 1938.