Degradation of trilinolein by laccase enzymes

Laccase enzymes were investigated for their potential to catalyze the oxidation of trilinolein and methyl linoleate. This study demonstrates that laccase enzymes can oxidize unsaturated fatty acid esters and their associated lipids. The reaction products resulting from laccase-catalyzed reactions with trilinolein were analyzed using combined reversed-phase high-performance liquid chromatography and mass spectrometry via an atmospheric pressure chemical ionization source. The dominant oxidation products detected were monohydroperoxides, bishydroperoxides, and epoxides. This paper presents the first detailed investigation into the interaction between laccase enzymes and lipids containing unsaturated fatty acids.     

Inhibition of arachidonic acid incorporation into erythrocyte phospholipids by peracetic acid and other peroxides. Role of arachidonoyl-CoA: 1-palmitoyl-sn-glycero-3-phosphocholine acyl transferase

To explore possible mechanisms of the arachidonic acid deficiency of the red blood cell membrane in alcoholics, we compared the effect of ethanol and its oxidized products, acetaldehyde and peracetic acid, with other peroxides on the accumulation of [14C]arachidonate into RBC membrane lipids in vitro. Incubation of erythrocytes with 50 mM ethanol or 3 mM acetaldehyde had no effect on arachidonate incorporation. Pretreatment of erythrocytes with 10 mM hydrogen peroxide, 0.1 mM cumene hydroperoxide or 0.1 mM t-butyl hydroperoxide had little effect on [14C]arachidonate incorporation in the absence of azide. However, pretreatment of cells with N-ethylmaleimide, 0.1 mM peracetic acid or performic acid, with or without azide, inhibited arachidonate incorporation into phospholipids but not neutral lipids. In chase experiments, peracetate also inhibited transfer of arachidonate from neutral lipids to phospholipids. To investigate a possible site of this inhibition of arachidonate transfer into phospholipids by percarboxylic acids, we assayed a repair enzyme, arachidonoyl CoA: 1-palmitoyl-sn-glycero-3-phosphocholine acyl transferase (EC 2.3.1.23). As in intact cells, phospholipid biosynthesis was inhibited more by N-ethylmalemide and peracetic acid than by hydrogen peroxide, cumene hydroperoxide, and t-butyl hydroperoxide. Peracetic acid was the only active inhibitor among ethanol and its oxidized products studied and may deserve further examination in ethanol toxicity.     

Reactions of aldehydes with unsaturated fatty acids during histological fixation

Synopsis Formaldehyde reacts with unsaturated fatty acids in tissues during histological fixation. For example, the reaction of formaldehyde with oleic acid gives rise to compounds with the structures shown below. The structures of the major reaction products have been confirmed, but those of the minor products have not been conclusively demonstrated. Esterified unsaturated fatty acids react more slowly, but the reaction is otherwise similar. Acrolein has been found to react in a similar fashion, but the reaction is far more complex.The occurrence of such compounds in tissues partly explains the loss of lipids during fixation, and raises some interesting possibilities regarding new fixatives and new histochemical reactions. The experimental work described in this paper was performed in the Departments of Pathology and Applied Biology, University of Cambridge.     

The reactions of hypochlorous acid, the reactive oxygen species produced by myeloperoxidase, with lipids

Myeloperoxidase (MPO), an abundant enzyme in phagocytes, has been implicated in the pathogenesis of various inflammatory diseases including atherosclerosis. The major oxidant produced by MPO, hypochlorous acid (HOCl), is able to modify a great variety of biomolecules by chlorination and/or oxidation. In this paper the reactions of lipids (preferentially unsaturated fatty acids and cholesterol) with either reagent HOCl or HOCl generated by the MPO-hydrogen peroxide-chloride system are reviewed. One of the major issues has been whether the reaction of HOCl with lipids of low density lipoprotein (LDL) yields predominantly chlorohydrins or lipid hydroperoxides. Electrospray mass spectrometry provided direct evidence that chlorohydrins rather than peroxides are the major products of HOCl- or MPO-treated LDL phosphatidylcholines. Nevertheless lipid peroxidation is a possible alternative reaction of HOCl with polyunsaturated fatty acids if an additional radical source such as pre-formed lipid hydroperoxides is available. In phospholipids carrying a primary amino group such as phosphatidylethanolamine chloramines are the preferred products compared to chlorohydrins. Cholesterol can be converted by HOCl to great variety of oxysterols besides three isomers of chlorohydrins. For the situation in vivo it appears that the type of reaction occurring between HOCl and lipids would very much depend on the circumstances, e.g. the pH and the presence of radical initiators. The biological effects of lipid chlorohydrins are not yet well understood. It has been shown that chlorohydrins of both unsaturated fatty acids as well as of cholesterol may cause lysis of target cells, possibly by disruption of membrane structures.     

Oxidative degradation of model lipids representative for main paper pulp lipophilic extractives by the laccase–mediator system

Different model lipids-alkanes, fatty alcohols, fatty acids, resin acids, free sterols, sterol esters, and triglycerides-were treated with Pycnoporus cinnabarinus laccase in the presence of 1-hydroxybenzotriazole as mediator, and the products were analyzed by gas chromatography. The laccase alone decreased the concentration of some unsaturated lipids. However, the most extensive lipid modification was obtained with the laccase-mediator system. Unsaturated lipids were largely oxidized and the dominant products detected were epoxy and hydroxy fatty acids from fatty acids and free and esterified 7-ketosterols and steroid ketones from sterols and sterol esters. The former compounds suggested unsaturated lipid attack via the corresponding hydroperoxides. The enzymatic reaction on sterol esters largely depended on the nature of the fatty acyl moiety, i.e., oxidation of saturated fatty acid esters started at the sterol moiety, whereas the initial attack of unsaturated fatty acid esters was produced on the fatty acid double bonds. In contrast, saturated lipids were not modified, although some of them decreased when the laccase-mediator reactions were carried out in the presence of unsaturated lipids suggesting participation of lipid peroxidation radicals. These results are discussed in the context of enzymatic control of pitch to explain the removal of lipid mixtures during laccase-mediator treatment of different pulp types.     

Histochemical demonstration of unsaturated hydrophilic lipids with palladium chloride.

Compounds in which olefinic linkages are accessible to aqueous reagents reduce the chloropalladite ion [PdCl4]2-, to metallic palladium. This reaction is used in a histochemical method whereby hydrophilic unsaturated lipids are stained dark brown or black. The specificity of the new method has been confirmed by means of solvent-extraction and chemical blocking procedures and by comparison with other histochemical techniques. Yellow staining of collagen, keratin and cytoplasm is probably due to attachment of the chloropalladite anion to proteins. The yellow background can be largely decolorized by treating the sections with aqueous pyridine, which forms colorless complexes with divalent palladium. A standard technique for staining with palladium is presented and the method is discussed in relation to other histochemical procedures that demonstrate unsaturated lipids.     

Studies in lipid histochemistry

Summary The effect of bromination (carried out especially with potassium tribromide and with bromine water) on various chemical groups in lipids and nonlipidic substances in tissue sections and in spot tests was investigated. Bromination blocks rapidly and effectively the reaction of double bonds with osmium tetroxide in unsaturated fatty acids, in phosphoglycerides, and nonpolar lipids, whereas in sphingolipids some residual staining persists even when the blocking period is prolonged. Similar results were obtained in the case of the UV-Schiff reaction. The vinylether bond in plasmalogens is blocked completely but not so rapidly.Besides double bonds bromination blocks the pseudoplasmal reaction in unsaturated lipids and the reaction of higher fatty aldehydes with Schiffs reagent and with dinitrophenyl hydrazine. Moreover it oxidizes the hydroxy group of cholesterol to a ketoderivative and in the case of ceramide mono- and dihexosides increases the intensity of the PAS reaction.The influence of bromination on various protein groups and the extraction of some loosely bound mucosubstances were demonstrated. The practical implication of these observations in applied lipid histochemistry is discussed.     

Reaction mechanism of the Co2+-activated multifunctional bromoperoxidase-esterase from Pseudomonas putida IF-3.

The reaction mechanism of the Co2+-activated bromoperoxidase-esterase of Pseudomonas putida IF-3 was studied. Site-directed mutagenesis suggested that the serine residue of the catalytic triad conserved in serine hydrolases participates in the bromination and ester hydrolysis reactions. The enzyme released a trace amount of free peracetic acid depending on the concentration of H2O2, which had been considered the intermediate in the reaction of nonmetal haloperoxidases to oxidize halide ions to hypohalous acid. However, the formation of free peracetic acid could not explain the enzyme activation effect by Co2+ ions which completely depleted the free peracetic acid. In addition, the kcat value of the enzymatic bromination was 900-fold higher than the rate constant of free peracetic acid-mediated bromination. Those results strongly suggested that the peracetic acid-like intermediate formed at the catalytic site is the true intermediate and that the formation of free peracetic acid is only a minor reaction involving the enzyme. We propose the possible reaction mechanism of this multifunctional enzyme based on these findings.     

Increased digestibility of cedar by pretreatment with peracetic acid and steam explosion

A type of steam explosion method combined with chemical pretreatment was studied. Peracetic acid was an effective reagent to assist the steam explosion reaction and greatly improved the enzymatic saccharification of cedar compared with single steam explosion. The extent of saccharification was directly proportional to the amount of peracetic acid absorbed in the chips, and the function of peracetic acid was revealed as an acid catalyst and as a radical initiator in the steam explosion reaction.     

Tissue fixation by osmium tetroxide. A possible role for proteins.

The osmiophilia, under the conditions of normal tissue fixation, of the histidine, lysine, tryptophan, cysteine and methionine side chain of proteins is suggested by in vitro studies on blocked amino acids representative of such protein side chains, and the chemical nature of the reaction products elucidated. The chemical feasibility of inter- or intramolecular cross-linking of protein by OsO4 at these and other sites is demonstrated, as in the cross-linking of protein with unsaturated lipids such as methyl oleate, methyl linoleate and linolenate, and cholesteryl acetate. The relevance of these results to the process of tissue fixation by OsO4 is discussed.     

Fractionation and lipase-catalyzed conversion of microalgal lipids to biodiesel

This study was conducted to evaluate the lipid fractionation and purification procedures of lipase-catalyzed conversion of neutral lipids to microalgal biodiesel. Microalgae lipids were efficiently recovered and purified by a combined extraction method and crude lipid extracts were separated into neutral lipids, glycolipids, and phospholipids by solid-phase extraction. The high purity of the neutral lipids fraction was confirmed by its low concentration of phosphorous (< 2.0 ppm). Transesterification was catalyzed by immobilized Candida antarctica lipase for 72 h with stepwise addition of methanol. The reaction displayed Michaelis–Menten kinetics and produced high yields of microalgal biodiesel (91.2% in the case of Dunaliella salina) with a high content of unsaturated fatty acids (81.5%). Neutral lipids were converted to biodiesel by three-step transesterification, while the removal of polar lipids maintained the activity of the immobilized lipase by reducing both reaction mixture viscosity and contamination risk.     

Complex hydrogenation/oxidation reactions of the water-soluble hydrogenation catalyst palladium di (sodium alizarinmonosulfonate) and details of homogeneous hydrogenation of lipids in isolated biomembranes and living cells.

Palladium di (sodium alizarinmonosulfonate) is a highly efficient catalyst for the hydrogenation of unsaturated fatty acids esterified in lipids of model or biological membranes, enabling the study of the relationship between function and the physical state of membranes. However, the catalyst shows a complex behavior in the action of molecular hydrogen and oxygen, giving rise to the formation of at least four products. Two of these are free radicals. Owing to this complexity, precise control of the reaction requires pretreatment of the catalyst. When partial hydrogenation of the palladium complex is followed by air oxidation, a catalyst solution is produced which is stable on air and maintains catalytic hydrogenation activity for several days. This form of the catalyst induces hydrogenation of unsaturated lipids with no induction period making a strict timing of the procedure possible. Of the several other factors affecting the outcome of membrane hydrogenations, one of the most important is the accessibility to the catalyst of particular membrane regions or lipid pools. Differences in accessibility may arise as a consequence of different local microviscosities or their change during hydrogenation, of the appearance of distinct liquid crystalline phases, and of strong protein-lipid interactions. Obviously, in case of whole-cell hydrogenations, the accessibility is influenced by the spatial separation of the organelles, as well.     

Free radical grafting onto cellulose in homogeneous conditions 1. Modified cellulose–acrylonitrile system

Synthesis of cellulose–polyacrylonitrile copolymers has been studied in a homogeneous solution of N,N-dimethylacetamide/LiCl. The method is based on the preliminary reaction of a portion of OH cellulosic groups with acryloyl chloride to give cellulose with a certain number of pendant double bonds. Successively, acrylonitrile is grafted onto the unsaturated groups by free radical polymerization using azobisisobutyronitrile as initiator. The optimum grafting conditions are evaluated by changing reaction temperature, as well as monomer/initiator and monomer/unsaturated group molar ratios. The products are characterized by size exclusion chromatography, i.r. and ¹³C n.m.r. spectroscopy and a possible reaction mechanism is deduced.     

Lipid oxidation in the skin

Abstract

Skin is the largest organ of the body and exerts several physiological functions such as a protective barrier against moisture loss and noxious agents including ultraviolet irradiation. Oxidation of skin may impair such functions and induce skin disorders including photoaging and skin cancer. Skin surface lipids, a mixture of sebaceous and epidermal lipids, have unique species and fatty acid profile. The major unsaturated lipids are squalene, sebaleic aicd, linoleic acid, and cholesterol. Singlet oxygen and ozone as well as free radicals and enzymes are important oxidants for skin lipids. Squalene is the major target for singlet oxygen, giving rise to twelve regio-isomeric squalene hydroperoxides. Ultraviolet radiation activates lipoxygenase and cyclooxygenase, inducing specific enzymatic oxidation of lipids. Free radical mediated lipid peroxidation gives multiple oxidation products. Lipid oxidation products produced by these mechanisms are observed in human skin and induce various skin diseases, but in contrast to plasma and other tissues, identification and quantitative measurement of lipid oxidation products in skin are scarce and should be the subjects of future studies.     

The Effect of Formaldehyde on Tissue Lipids and on Histochemical Reactions for Carbonyl Groups

Histcchemical and chemical evidence indicates that formaldehyde combines with unsaturated lipids at the double bond. The resulting complex contains a free carbonyl group which probably originates from the formaldehyde. The reaction occurs over a wide pH range, and takes place in the absence of oxygen or moisture. The reaction product is visualized by the Schiff reagent, and by the Ashbel-Seligman procedure. In the plasmal procedure, when performed on formalin-treated material, the reaction has the same significance as the pseudo-plasmal reaction, i.e. it denotes the presence of double bonds. The Ashbel-Seligman technic seems to be more sensitive to this complex than the Schiff reagent and shows it more markedly than it does the true plasmals and the atmospherically oxidized unsaturated compounds.     

Unsaturated diether phospholipids in the Antartic methanogen Methanococcoides burtonii

Abstract The Antarctic methanogen Methanococcoides burtonii contained only diether phospholipids. These membrane components were analysed by gas chromatography and gas chromatography mass spectrometry. Of particular interest was the occurrence of unsaturated diether lipids in M. burtonii ; unsaturated ether lipids accounted for 57% of the diether phospholipids. To our knowledge, unsaturated ether lipids have not been previously reported in a methanogen. The presence of the unsaturated ether lipids in M. burtonii is probably the result of temperature adaptation by the bacterium. It may be possible to use these components as a chemical signature for methanogens in Antarctic and Southern Ocean environments.     

The Effect of Formaldehyde on Tissue Lipids and on Histochemical Reactions for Carbonyl Groups

Histcchemical and chemical evidence indicates that formaldehyde combines with unsaturated lipids at the double bond. The resulting complex contains a free carbonyl group which probably originates from the formaldehyde. The reaction occurs over a wide pH range, and takes place in the absence of oxygen or moisture. The reaction product is visualized by the Schiff reagent, and by the Ashbel-Seligman procedure. In the plasmal procedure, when performed on formalin-treated material, the reaction has the same significance as the pseudo-plasmal reaction, i.e. it denotes the presence of double bonds. The Ashbel-Seligman technic seems to be more sensitive to this complex than the Schiff reagent and shows it more markedly than it does the true plasmals and the atmospherically oxidized unsaturated compounds.     

Formation of superoxide in the reaction of photolytically altered nifedipine--a nitroso compound--with unsaturated membrane lipids.

Nifedipine, which is unstable at light, is photolytically converted to the corresponding 4-[2'-nitrosophenyl]-pyridine (NTP). We reported earlier that NTP react with unsaturated lipids in a pseudo Diels-Alder reaction, thus forming stable nitroxide radicals. In this paper we report that superoxide is being generated in the latter reaction. Superoxide formation was evidenced by SOD-inhibitable cytochrome c reduction in the reaction of NTP with egg phosphatidylcholine at molar ratio 1:1, and 1:3. In this reaction an ESR-observable nitroxide radical was formed. Maximum nitroxide formation was observed after 90 min; the addition of SOD (93 units/ml) increased the concentration of nitroxide. This effect of SOD was reversed by catalase, indicating involvement of hydrogen peroxide in this effect. The nitroxide radical formation appears to be metal-independent, since neither iron salts, nor an iron chelator, desferal, influenced the nitroxide formation. Although production of superoxide in our system was only observed at high concentrations of NTP and of unsaturated lipids, this reaction may be of potential cytotoxic significance due to redox cycling of the nitroxide/hydroxylamine couple in cellular systems.     

Improved pretreatment of lignocellulosic biomass using enzymatically-generated peracetic acid

Release of sugars from lignocellulosic biomass is inefficient because lignin, an aromatic polymer, blocks access of enzymes to the sugar polymers. Pretreatments remove lignin and disrupt its structure, thereby enhancing sugar release. In previous work, enzymatically generated peracetic acid was used to pretreat aspen wood. This pretreatment removed 45% of the lignin and the subsequent saccharification released 97% of the sugars remaining after pretreatment. In this paper, the amount of enzyme needed is reduced tenfold using first, an improved enzyme variant that makes twice as much peracetic acid and second, a two-phase reaction to generate the peracetic acid, which allows enzyme reuse. In addition, the eight pretreatment cycles are reduced to only one by increasing the volume of peracetic acid solution and increasing the temperature to 60 °C and the reaction time to 6 h. For the pretreatment step, the weight ratio of peracetic acid to wood determines the amount of lignin removed.     

Identification of the missing trans-acting enoyl reductase required for phthiocerol dimycocerosate and phenolglycolipid biosynthesis in Mycobacterium tuberculosis

Phthiocerol dimycocerosates (DIM) and phenolglycolipids (PGL) are functionally important surface-exposed lipids of Mycobacterium tuberculosis. Their biosynthesis involves the products of several genes clustered in a 70-kb region of the M. tuberculosis chromosome. Among these products is PpsD, one of the modular type I polyketide synthases responsible for the synthesis of the lipid core common to DIM and PGL. Bioinformatic analyses have suggested that this protein lacks a functional enoyl reductase activity domain required for the synthesis of these lipids. We have identified a gene, Rv2953, that putatively encodes an enoyl reductase. Mutation in Rv2953 prevents conventional DIM formation and leads to the accumulation of a novel DIM-like product. This product is unsaturated between C-4 and C-5 of phthiocerol. Consistently, complementation of the mutant with a functional pks15/1 gene from Mycobacterium bovis BCG resulted in the accumulation of an unsaturated PGL-like substance. When an intact Rv2953 gene was reintroduced into the mutant strain, the phenotype reverted to the wild type. These findings indicate that Rv2953 encodes a trans-acting enoyl reductase that acts with PpsD in phthiocerol and phenolphthiocerol biosynthesis.