Lipoxygenase isoforms in elicitor-treated parsley cell suspension cultures.

Treatment of parsley cell cultures with a fungal elicitor triggered the induction of a lipoxygenase isoform which may be involved in the de novo synthesis of defence-response inducers, such as jasmonic acid or 12-oxo-phytodienoic acid.

Visualization of a covalent intermediate between microsomal epoxide hydrolase, but not cholesterol epoxide hydrolase, and their substrates.

Mammalian soluble and microsomal epoxide hydrolases have been proposed to belong to the family of alpha/beta-hydrolase-fold enzymes. These enzymes hydrolyse their substrates by a catalytic triad, with the first step of the enzymatic reaction being the formation of a covalent enzyme-substrate ester. In the present paper, we describe the direct visualization of the ester formation between rat microsomal epoxide hydrolase and its substrate. Microsomal epoxide hydrolase was precipitated with acetone after brief incubation with [1-(14)C]epoxystearic acid. After denaturing SDS gel electrophoresis the protein-bound radioactivity was detected by fluorography. Pure epoxide hydrolase and crude microsomes showed a single radioactive signal of the expected molecular mass that could be suppressed by inclusion of the competitive inhibitor 1,1,1-trichloropropene oxide in the incubation mixture. In a similar manner, 4-fluorochalcone-oxide-sensitive binding of epoxystearic acid to rat soluble epoxide hydrolase could be demonstrated in rat liver cytosol. Under similar conditions, no covalent binding of [26-(14)C]cholesterol-5alpha,6alpha-epoxide to microsomal proteins or solubilized fractions tenfold enriched in cholesterol epoxide hydrolase activity could be observed. Our data provide definitive proof for the formation of an enzyme-substrate-ester intermediate formed in the course of epoxide hydrolysis by microsomal epoxide hydrolase, show no formation of a covalent intermediate between cholesterol epoxide hydrolase and its substrate under the same conditions as those under which an intermediate was shown for both microsomal and soluble epoxide hydrolases and therefore indicate that the cholesterol epoxide hydrolase apparently does not act by a similar mechanism and is probably not structurally related to microsomal and soluble epoxide hydrolases.

Influence of fluid absorption time on cell recovery in cytocentrifugation.

OBJECTIVE: To determine the absorption time required to give complete cell recovery in cytocentrifugation. STUDY DESIGN: A simplified model for cell recovery was outlined that relates cell recovery to the relative magnitude of cell sedimentation velocity (SV) and fluid velocity (FV) during cytocentrifugation. The recovery of blood leukocytes was measured at various relative values of the SV/FV ratio and plotted to provide an indication of the effect of the ratio on recovery and to identify the conditions necessary to yield complete cell recovery. RESULTS: As SV/FV approaches zero, cell recovery also approaches zero. As the SV/FV ratio increases, recovery increases toward a maximum of 100%. The fluid absorption time is a key factor in the SV/FV ratio, which also includes centrifugal force and sample volume. A preliminary evaluation of commercial equipment yielded a wide range of absorption characteristics. In addition, fluid flow can be slowed and the SV/FV ratio increased by adding macromolecules--e.g., bovine serum albumin--to the sample fluid. CONCLUSION: Cytocentrifugation has the capability of nearly complete cell recovery if conditions are selected that yield a high SV/FV ratio. Such recovery usually requires slowing the fluid flow rate beyond what is normally obtained in most commercial equipment.

Envelope Membranes from Spinach Chloroplasts Are a Site of Metabolism of Fatty Acid Hydroperoxides.

Enzymes in envelope membranes from spinach (Spinacia oleracea L.) chloroplasts were found to catalyze the rapid breakdown of fatty acid hydroperoxides. In contrast, no such activities were detected in the stroma or in thylakoids. In preparations of envelope membranes, 9S-hydroperoxy-10(E),12(Z)-octadecadienoic acid, 13S-hydroperoxy-9(Z),11(E)-octadecadienoic acid, or 13S-hydroperoxy-9(Z),11(E),15(Z)-octadecatrienoic acid were transformed at almost the same rates (1-2 [mu]mol min-1 mg-1 protein). The products formed were separated by reversed-phase high-pressure liquid chromatography and further characterized by gas chromatography-mass spectrometry. Fatty acid hydroperoxides were cleaved (a) into aldehydes and oxoacid fragments, corresponding to the functioning of a hydroperoxide lyase, (b) into ketols that were spontaneously formed from allene oxide synthesized by a hydroperoxide dehydratase, (c) into hydroxy compounds synthesized enzymatically by a system that has not yet been characterized, and (d) into oxoenes resulting from the hydroperoxidase activity of a lipoxygenase. Chloroplast envelope membranes therefore contain a whole set of enzymes that catalyze the synthesis of a variety of fatty acid derivatives, some of which may act as regulatory molecules. The results presented demonstrate a new role for the plastid envelope within the plant cell.

Stereocontrolled hydrolysis of the linoleic acid monoepoxide regioisomers catalyzed by soybean epoxide hydrolase.

Soybean fatty acid epoxide hydrolase (EC 3.3.2.3) was found to possess remarkable and unique stereochemical features. After complete hydrolysis, this enzyme converts racemic or enantiomerically enriched cis-9,10-epoxy-12(Z)-octadecenoic and cis-12,13-epoxyocta-9(Z)-decenoic acids, i.e. the two regioisomers of linoleic acid monoepoxides, into their corresponding 9R, 10R- and 12R, 13R-dihydrodiols with a high enantiomeric excess (> 90%). A straightforward chiral-phase HPLC technique was developed that gives an easy access to the stereochemistry of these reaction products. These results are discussed in terms of a possible model for the substrate binding site of this enzyme.

Effect of sample volume on cell recovery in cytocentrifugation.

The purpose of this study was to improve cell recovery and distribution in cytocentrifugation by optimizing sample volume. The experimental design used equal cell numbers in different diluent volumes from 25 to 500 microL. As the diluent volume increased, the fractional recovery of cells also increased, from 10% to a virtual 100%, even though the number of cells per sample remained constant. Optimal cell recovery was achieved with sample volumes between 200 and 500 microL. The importance of using a 200-microL volume with samples of high cellularity as well as those of low cellularity, such as cerebrospinal fluid, is discussed.

Regio- and stereoselectivity of cytochrome P-450 and peroxygenase-dependent formation of cis-12,13-epoxy-9(Z)-octadecenoic acid (vernolic acid) in Euphorbia lagascae.

Two oxygenases associated with microsomes prepared from Euphorbia lagascae developing seeds were found to convert linoleic acid into cis-12,13-epoxy-9(Z)-octadecenoic acid (vernolate): a cytochrome P-450 and a peroxygenase. The cytochrome P-450 dependent epoxidation is characterized by a remarkable regio- and enantioselectivity, i.e. only the 12(S),13(R)-enantiomer is formed in the endosperm. In germinating seeds, peroxygenase was active but no cytochrome P-450 epoxidase could be detected. Moreover, because of the very high enantioselectivity of the fatty acid epoxide hydrolase, which is also found in these tissues and which preferentially hydrates the 12(R),13(S)-epoxide enantiomer, 12(S),13(R)-epoxy-9(Z)-octadecenoic acid is the only isomer which can accumulate in E. lagascae.

Mechanism of reaction of fatty acid hydroperoxides with soybean peroxygenase.

13(S)-Hydroperoxyoctadeca-9(Z),11(E),15(Z)-trienoic acid (13-HPOT) was used to probe the mechanism of the hydroperoxide O-O bond cleavage catalyzed by solubilized and partially purified soybean peroxygenase. When reacted with this ferrihemoprotein, it was converted to 13(S)-hydroxyoctadeca-9(Z),11(E), 15(Z)-trienoic acid (13-HOT) and a single epoxide regio-isomer, i.e. 15,16-cis-epoxy-13(S)-hydroxyoctadeca-9(Z),11(E)-dienoic acid (15,16-EHOD). In the absence of co-oxidizable substrates, such as oleic acid or thiobenzamide, this latter compound accounted for about two-thirds of the reaction products. 13-HOT and 15,16-EHOD are products of heterolytic scission of the O-O bond of 13-HPOT; no products arising by homolytic scission could be detected. Therefore, soybean peroxygenase catalyzes hydroperoxide reduction exclusively by a heterolytic mechanism leading to a ferryl-oxo complex analogous to peroxidase compound I. In similar experiments, 13(S)-hydroperoxyoctadeca-9(Z),11(E)-dienoic acid gave 13(S)-hydroxyoctadeca-9(Z),11(E)-dienoic acid and 9,10 epoxy-13(S)-hydroxyoctadec-11(E)-enoic acid. Experiments with 18O-labeled 13-HPOT indicated that about 83% of the oxygen atom incorporated into the epoxide group of 15,16-EHOD, originated from the hydroperoxide group. Moreover, using mixtures of unlabeled and 18O-labeled 13-HPOT, it was established that this transfer takes place predominantly (about 3:1) by an intramolecular process. In the intermolecular reaction 13-HOT, formed after reduction of the hydroperoxide, diffuses from the active site and, after reassociation, is epoxidized at the 15,16-double bond. A unifying mechanistic scheme, which takes into account all of the reactions catalyzed by the peroxygenase, is proposed.

Enantioselectivity of the hydrolysis of linoleic acid monoepoxides catalyzed by soybean fatty acid epoxide hydrolase.

Soybean epoxide hydrolase efficiently catalyzes the hydration of the two positional isomers of linoleic acid monoepoxides into their corresponding vic-diols. Kinetic analysis of the progress curves, obtained at low substrate concentrations (i.e. [So] much less than Km), and analysis of the residual substrates by chiral-phase HPLC, indicate that the hydrolase is highly enantioselective, i.e. cis-9R,10S-epoxy-12(Z)-octadecenoic and cis-12R,13S-epoxy-9(Z)-octadecenoic acids are preferentially hydrolyzed (the enantioselectivity ratios are 15 and 28, respectively). Importantly, these two enantiomers are the one formed preponderantly by epoxidation of linoleic acid by peroxygenase, a hydroperoxide-dependent oxidase we have previously described in soybean (Blée, E., and Schuber, F., Biochem. Biophys. Res. Commun. (1990) 173, 1354-1360).

Regio- and enantioselectivity of soybean fatty acid epoxide hydrolase.

Soluble epoxide hydrolase purified from soybean catalyzes trans-addition of water across the oxirane ring of cis-9,10-epoxystearic acid with inversion of configuration at the attacked carbon, yielding threo-9,10-dihydroxystearic acid. Kinetic analyses of the progress curves, obtained at low substrate concentrations (i.e. [S] much less than Km), and determination of the enantiomeric excess of the residual substrate by chiral-phase high-performance liquid chromatography at different reaction times, indicate that the epoxide hydrolase hydrates preferentially cis-9R, 10S-epoxystearic acid (V/Km ratio, approximately 20). Interestingly, this enantiomer is obtained by epoxidation of oleic acid catalyzed by peroxygenase, a hydroperoxide-dependent oxidase, we have previously described in soybean (Blée, E., and Schuber, F. (1990) J.Biol. Chem. 265, 12887-12894). For the epoxide hydrolase to show high enantioselectivity there must be a free carboxylic acid functionality on the substrate which probably influences its positioning within the active site. This selectivity, which in principle can be used for kinetic resolution of the cis-9,10-epoxystearic acid enantiomers, is much reduced with methyl cis-9,10-epoxystearate. 18O-Labeling experiments indicate that water attacks both cis-9,10-epoxystearic acid enantiomers on the oxirane carbon which has the S-chirality. Results show that soybean epoxide hydrolase produces exclusively threo-9R,10R-dihydroxystearic acid, i.e. a naturally occurring metabolite in higher plants. cis-9,10-Epoxy-18-hydroxystearic acid, a cutin monomer, was a poorer substrate of the epoxide hydrolase than 9,10-epoxystearic acid (V/Km ratio for the preferred enantiomers, approximately 19). From a physiological point of view, peroxygenase and this newly described epoxide hydrolase could be responsible, in vivo, for the biosynthesis of a class of oxygenated fatty acid compounds known to be involved in cutin monomers production and in plant defense mechanisms.

Occurrence of fatty acid epoxide hydrolases in soybean (Glycine max). Purification and characterization of the soluble form.

Epoxide hydrolases catalysing the hydration of cis-9,10-epoxystearate into threo-9,10-dihydroxystearate have been detected in soybean (Glycine max) seedlings. The major activity was found in the cytosol, a minor fraction being strongly associated with microsomes. The soluble enzyme, which was purified to apparent homogeneity by (NH4)2SO4 fractionation, hydrophobic, DEAE- and gel-filtration chromatographies, has a molecular mass of 64 kDa and a pI of 5.4.

Stereochemistry of the epoxidation of fatty acids catalyzed by soybean peroxygenase.

The stereochemistry of C18 unsaturated fatty acids epoxidation catalyzed by detergent-solubilized and partially purified soybean peroxygenase was determined by chiral phase HPLC. Linoleic acid was oxidized into 9, 10- and 12,13-cis-epoxyoctadecenoic acids with a high enantiofacial selectivity. A 5.2:1 and 2.3:1 ratio respectively in favor of the 9(R), 10(S)- and 12(R), 13(S)-epoxy enantiomers was observed. These epoxy-derivatives of linoleic acid have the chirality of metabolites known to be involved in plant defense against fungi. This finding is of importance in establishing a physiological role for the peroxygenase.

Efficient epoxidation of unsaturated fatty acids by a hydroperoxide-dependent oxygenase.

Detergent-solubilized and partially purified soybean peroxygenase was shown to actively catalyze, in the presence of alkylhydroperoxides as co-substrates, the epoxidation of mono- and polyunsaturated fatty acids such as oleic and linoleic acids. Octadecenoic acids were found to be better substrates than shorter mono-unsaturated fatty acids (C16:1 or C14:1), but the position of their double bond (at positions 6, 9, or 11) had little effect on the rates of epoxidation. The peroxygenase exhibits a strong stereospecificity since octadecenoic acids with double bonds in trans-configuration were not epoxidized at detectable rates. Oxidation of linoleic acid yielded the two positional monoepoxide isomers and, as the minor product, the diepoxide. An important regioselectivity was, however, observed in this case; i.e. the unsaturation at position 9,10 was epoxidized preferentially to that at 12, 13. Oxidation of oleic acid in the presence of 18O-labeled hydroperoxy-linoleic acid revealed an incorporation of about 80% of the label into the epoxide ring. Products similar to those formed by the peroxygenase by epoxidation of unsaturated free fatty acids such as linoleic acid have been described as important metabolites (leukotoxins) in the defense of plants, e.g. in fungal agressions. This aspect underlines the physiological relevance of this new and potent catalytic activity of the peroxygenase.

Characterization of elemental sulfur in isolated intact spinach chloroplasts.

Incubation of intact spinach (Spinacia oleracea L.) chloroplasts in the presence of (35)SO(4) (2-) resulted in the light-dependent formation of a chloroform-soluble sulfur-containing compound distinct from sulfolipid. We have identified this compound as the most stable form (S(8)) of elemental sulfur (S(0), valence state for S = O) by mass spectrometry. It is possible that elemental sulfur (S(0)) was formed by oxidation of bound sulfide, i.e. after the photoreduction of sulfate to sulfide by intact chloroplasts, and released as S(8) under the experimental conditions used for analysis.

Hydroperoxide-dependent sulfoxidation catalyzed by soybean microsomes.

The sulfoxidation of methiocarb, an aromatic-alkyl sulfide pesticide, catalyzed by soybean microsomes was found to be strongly stimulated in the presence of cumene and linoleic acid hydroperoxides. We have shown that this S-oxidation, which does not require cofactors such as NAD(P)H, is an hydroperoxide-dependent reaction: 18O2-labeling experiments demonstrated that the oxygen atom incorporated into the sulfoxide originated from hydroperoxides rather than from molecular oxygen. In the absence of exogenous hydroperoxides, soybean microsomes catalyzed methiocarb sulfoxide formation at a basal rate dependent on their endogenous hydroperoxides, especially those derived from free fatty acids. The nature of the sulfoxidase is discussed. Our results seem to rule out the participation of cytochrome P-450 in this oxidation, whereas the studied sulfoxidase presents some similarities to plant peroxygenase.

Oxidation of an organosulfur xenobiotic by microsomes from soybean cotyledons.

Methiocarb, an aromatic-alkyl sulfide insecticide was enzymatically oxidized into its sulfoxide by microsomes from soybean cotyledons. No further oxidation into sulfone was detected. Distribution of the sulfoxidase activity was studied in soybean seedlings and found maximal in cotyledons. Subcellular fractionation of cotyledons homogenates indicated that the activity was almost entirely associated with the microsomal fraction. Sulfoxidation of methiocarb did not require cofactors such as NAD(P)H. Nevertheless, the sulfoxidase did not act as a peroxidase.

Comparative role of polyamines in division and plastid differentiation of Euglena gracilis.

Regulation of polyamine biosynthesis during growth and differentiation of Euglena gracilis was investigated. Increased activity of L-ornithine decarboxylase (EC 4.1.1.17), the enzyme which catalyzes the initial step in polyamine synthesis in Euglena, and accumulation of polyamines were observed prior to DNA replication in synchronous cultures of heterotrophically or photoautotrophically grown cells. In photoautotrophic cells three maxima of polyamine synthesis were observed during the light period of the cell cycle. The transition form quiescence to active growth was accompanied in heterotrophic Euglena by a very large stimulation of ornithine decarboxylase activity and polyamine synthesis; the decrease in growth potential of these cells was correlated with a decrease in polyamine levels. In contrast, differentiation of Euglena i.e. a shift from heterotrophic to photoautotrophic mode of living in the absence of division, led only to a minor stimulation of polyamine biosynthesis. Alpha-Methylornithine, an inhibitor of ornithine decarboxylase, blocked the growth of heterotrophic Euglena, and depletion of intracellular polyamines decreased the differentiation rate. Both events could be reversed by addition of putrescine to the growth medium. This study suggests that Euglena requires a minimal intracellular level of polyamines to grow and differentiate under optimal conditions. This requirement seems to be more stringent for cell division.