Soybean leaves contain multiple lipoxygenases

Chromatofocusing of soybean (Glycine max L.) leaf lipoxygenases revealed three distinct peaks of activity. Based on their isoelectric points (pls), pH optima, and mutant analysis it appears that the leaf isozymes are different from those described from mature soybean seed. At least one leaf lipoxygenase appears to differ from those found in hypocotyls. The pls of the main bands of the three leaf lipoxygenase peaks are 6.67, 5.91, and 5.67. The pH optima curves of three active fractions exhibit peaks at pH 6.2, 5.5, and 8.5, respectively. One of the fractions has two polypeptides with slightly different molecular weights, both of which react to soybean seed lipoxygenase antibodies. The other two fractions contain a polypeptide of unit molecular weight reacting with the lipoxygenase antibodies.     

Enzyme inhibition activities of the extracts from rhizomes of Gloriosa superba Linn (Colchicaceae)

An alcoholic extract obtained from the rhizomes of Gloriosa superba Linn (Colchicaceae) was screened for enzyme inhibition activities. The crude extract and its subsequent fractions including chloroform, ethyl acetate, n-butanol and aqueous were screened against lipoxygenase, actylcholinesterase, butyrylcholinesterase and urease. An outstanding inhibition on lipoxygenase was observed. The highest enzyme inhibition potency was expressed by the chloroform fraction (90%) among the tested fractions on lipoxygenase. Overall 67– 90% inhibition was found for lipoxygenase, 46-69% for acetylcholinesterase and 10–33% for butyrylcholinesterase, while urease was not inhibited.     

Enzyme inhibition activities of the extracts from rhizomes of Gloriosa superba Linn (Colchicaceae)

An alcoholic extract obtained from the rhizomes of Gloriosa superba Linn (Colchicaceae) was screened for enzyme inhibition activities. The crude extract and its subsequent fractions including chloroform, ethyl acetate, n-butanol and aqueous were screened against lipoxygenase, actylcholinesterase, butyrylcholinesterase and urease. An outstanding inhibition on lipoxygenase was observed. The highest enzyme inhibition potency was expressed by the chloroform fraction (90%) among the tested fractions on lipoxygenase. Overall 67-90% inhibition was found for lipoxygenase, 46-69% for acetylcholinesterase and 10-33% for butyrylcholinesterase, while urease was not inhibited.     

Co-oxidation of carotenes requires one soybean lipoxygenase isoenzyme.

The type II lipoxygenase (optimum pH 6.5) from soybeans was purified and separated into two fractions either by chromatography on DEAE-Sephadex or by isoelectric focusing. In the presence of linoleic acid and oxygen both fractions co-oxidise canthaxanthine or beta-carotene as effectively as a combination of these fractions. Oxygenation of linoleic acid and co-oxidation of canthaxanthine by type II lipoxygenase is stimulated by 13-hydroperoxy-cis-9,trans-11-octadecadienoic acid but not by 13-hydroxy-cis-9,trans-11-octadecadienoic acid or 9-hydroperoxy-trans-10,cis-12-octadecadienoic acid.     

Lipoxygenase mRNA in rabbit reticulocytes. Its isolation, characterization and translational repression

The synthesis of the erythroid lipoxygenase, an enzyme which is of importance for the degradation of mitochondria during the maturation of reticulocytes to erythrocytes, was studied in reticulocytes from bone marrow and in density-separated fractions from peripheral blood of anemic rabbits. Lipoxygenase mRNA was enriched to about 75% by digestion of polysomes with protease K, poly(U)-Sepharose chromatography and repeated sucrose gradient centrifugation. From sucrose gradient centrifugation, electrophoresis and electron microscopy a molecular weight of about 10(6) was calculated. Synthesis of lipoxygenase is absent in erythroblasts, in very young reticulocytes obtained from bone marrow, or in the lightest fractions of reticulocytes from the peripheral blood. More mature blood reticulocytes show a considerable synthesis of the enzyme. The induction of the synthesis of the lipoxygenase seems to be initiated when reticulocytes have reached the peripheral blood. It is shown that lipoxygenase mRNA is present in reticulocytes as a translationally inactive free cytoplasmic messenger ribonucleoprotein (mRNP) particle. After deproteinization isolated mRNA obtained from masked mRNP codes for authentic lipoxygenase in a cell-free protein-synthesizing system of reticulocytes.     

Subcellular localization and some properties of lipoxygenase activity in human blood platelets.

Lipoxygenase activity was measured in human platelet subcellular fractions. From a sonicated platelet preparation, a granule fraction, mixed membranes (surface and intracellular) and cytosol fractions were separated by differential centrifugation. With respect to activities in the sonicated preparation, the lipoxygenase was slightly enriched in both the cytosol and mixed-membrane fractions and consistently de-enriched in the granule fractions. Approx. 65% and 20% of the total cell enzyme activity were found in the cytosol and mixed membranes respectively, with only 8% present in the granule fraction. Additionally we measured the lipoxygenase activity in purified surface- and intracellular-membrane subfractions prepared from the mixed membranes by free-flow electrophoresis. There was a slight enrichment in activity in the intracellular membrane fraction compared with that in the mixed membranes, and a depletion of activity in the surface membranes. Characterization of the enzyme activity, i.e. time course, pH-dependence, Ca2+-dependence, Vmax. and Km for arachidonic acid, and the carbon-position specificity for this acid, failed to reveal any significant differences between the membrane-bound and soluble forms of the lipoxygenase. These findings suggest that in human platelets the same lipoxygenase is associated with the membranes as in the cytosol and that the membrane-bound activity predominates in intracellular membrane elements.     

Membrane-Associated and Soluble Lipoxygenase Isoforms in Tomato Pericarp (Characterization and Involvement in Membrane Alterations)

Membrane-associated and soluble lipoxygenases from green tomato (Lycopersicon esculentum Mill. cv Ailsa Craig) fruit have been identified. Microsomal lipoxygenase was localized partly in the plasma membrane and tonoplast fractions. The possibilities of glycosyl-phosphatidylinositol or transmembrane polypeptide anchors in the membrane were ruled out by differential solubilization and temperature-induced phase separation in Triton X-114. High performance liquid chromatography of reaction products combined with polarography showed that tomato lipoxygenase is capable of specific oxygenation of fatty acids esterified in phospholipids. This possibility of direct action on membrane phospholipids strengthened the hypothesis of a role for lipoxygenase in plant senescence and membrane turnover. Membrane-associated lipoxygenase is polymorphic, with two forms differing by their isoelectric points (pls) (around 4.2 and 5.1). The pl of the soluble lipoxygenase corresponds to the minor microsomal enzyme, with a pl of 5.1. The charge-differing isoforms were separated and analyzed by western blotting using anti-soybean lipoxygenase antibodies. A single polypeptide with an apparent molecular weight of 92,000 was identified in each case for the soluble and microsomal enzymes. It is suggested that a charge modification of the soluble lipoxygenase allows its association with the membrane.     

Enzyme inhibition activities of Teucrium royleanum

The crude methanolic extract and chloroform, ethyl acetate and n-butanol fractions of Teucrium royleanum were examined as inhibitors of actylcholinesterase, butyrylcholinesterase, lipoxygenase and urease. A significant enzyme inhibition activity (52-83%) was shown by the crude methanolic extract and its fractions against acetylcholinesterase, while low to outstanding enzyme inhibitory activity was shown (19-93%) against butyrylcholinesterase. The crude methanolic extract and its various fractions demonstrated low activity against lipoxygenase and inactive against urease.     

Lipoxygenase activities of human platelets and their subcellular fractions: Comparison between lipoxygenase-deficient platelets and normal platelets

Lipoxygenase activities were estimated in washed platelets (intact platelets) and their subcellular fractions obtained from 7 patients with deficient platelet lipoxygenase activities and 9 normal subjects. From sonicated platelet preparations, 12,000 g supernatant (F-I), cytosol (F-II) and microsomal fractions (F-III) were prepared by differential centrifugation. When 12-hydroxyeicosatetraenoic acid (12-HETE) produced by the incubation of arachidonic acid with intact platelets or each of their subcellular fractions from normal subjects was measured by reversed-phase high-performance liquid chromatography analysis, the lipoxygenase activities of F-I, F-II and F-III were 87%, 31% and 17%, respectively, of the enzyme activity of intact platelets. One of the patients showed no detectable lipoxygenase activity in any preparation, while the other patients showed reduced enzyme activities in all preparations. The addition of CaCl2 significantly increased 12-HETE synthesis solely by F-I from these patients. In most of these patients, contrary to normal subjects, it appeared that the lipoxygenase activity was not fully expressed in intact platelets, since the F-I produced more 12-HETE than the intact platelets.     

Enzyme inhibition activities of Andrachne cardifolia Muell

The crude methanolic extract and various fractions of Andrachne cardifolia Muell, including chloroform, ethyl acetate and n-butanol fractions were subjected to in vitro enzyme inhibition activity against acetylcholinesterase, butyrylcholinesterase, lipoxygenase and urease enzymes. A significant enzyme inhibition activity (40-89%) was shown by the crude methanolic extract and its fractions against lipoxygenase, while low to significant activity (40-71%) against butyrylcholinesterase. The crude methanolic extract and its various fractions demonstrated poor to significant activity (25-73%) against acetylcholinesterase and no activity against urease.     

Enzyme inhibition activities of teucrium royleanum

The crude methanolic extract and chloroform, ethyl acetate and n-butanol fractions of Teucrium royleanum were examined as inhibitors of actylcholinesterase, butyrylcholinesterase, lipoxygenase and urease. A significant enzyme inhibition activity (52–83%) was shown by the crude methanolic extract and its fractions against acetylcholinesterase, while low to outstanding enzyme inhibitory activity was shown (19–93%) against butyrylcholinesterase. The crude methanolic extract and its various fractions demonstrated low activity against lipoxygenase and inactive against urease.     

Role of lipoxygenase in the O2-dependent activation of soluble guanylate cyclase from rat lung.

Guanylate cyclase activity in rat lung supernatant fractions is stimulated 3-4 fold by aerobic incubation at 30 degrees C for approx. 30 min ('O2-dependent activation'). This stimulation was blocked by 20 microM-eicosa-5,8,11,14-tetraynoic acid (ETYA), an inhibitor of lipoxygenase and cyclo-oxygenase, but not by aspirin or indomethacin, which are cyclo-oxygenase inhibitors. The enzyme activator(s) is presumed to be the fatty acid hydroperoxide(s) formed by lipoxygenase. Removal of lipoxygenase from the supernatant fraction by chromatography on Amberlite XAD-4 also prevented activation, which was restored by the addition of soya-bean lipoxygenase. Bovine serum albumin prevented O2-dependent activation or activation by soya-bean lipoxygenase, through its ability to bind the unsaturated fatty acid substrate of lipoxygenase. The lipoxygenase in the supernatant fraction is inhibited by endogenous glutathione peroxidase plus reduced glutathione (GSH); removal of GSH de-inhibits lipoxygenase and activates guanylate cyclase. This was effected by autoxidation, by cumene hydroperoxide (with GSH peroxidase) and by titration with N-ethylmaleimide (NEM). Activation by NEM was inhibited by serum albumin or ETYA, as was activation by low concentrations (less than 50 microM) of cumene hydroperoxide. Activation by higher concentrations was not so inhibited; therefore, cumene hydroperoxide can also activate by a direct effect on guanylate cyclase. A hypothesis for physiological activation is proposed.     

Inhibition activities of Colchicum luteum baker on lipoxygenase and other enzymes

In vitro enzymes inhibition activities of the crude methanolic extract and various fractions of Colchicum luteum Baker (Liliaceae) including chloroform, ethyl acetate, n-butanol and aqueous were carried out against actylcholinesterase, butyrylcholinesterase, lipoxygenase and urease enzymes. A significant enzyme inhibition activity (89%) is shown by the crude methanolic extract and its fractions against lipoxygenase, while low to significant activity (32-75%) was evident against butyrylcholinesterase. The crude methanolic extract and its various fractions demonstrated low activity (29-61%) against acetylcholinesterase and no activity against urease.     

Inhibition activities of colchicum luteum baker on lipoxygenase and other enzymes

In vitro enzymes inhibition activities of the crude methanolic extract and various fractions of Colchicum luteum Baker (Liliaceae) including chloroform, ethyl acetate, n-butanol and aqueous were carried out against actylcholinesterase, butyrylcholinesterase, lipoxygenase and urease enzymes. A significant enzyme inhibition activity (89%) is shown by the crude methanolic extract and its fractions against lipoxygenase, while low to significant activity (32–75%) was evident against butyrylcholinesterase. The crude methanolic extract and its various fractions demonstrated low activity (29–61%) against acetylcholinesterase and no activity against urease.     

Identification and characterization of lipoxygenase isoforms in senescing carnation petals

A membrane-associated lipoxygenase and a soluble lipoxygenase have been identified in carnation (Dianthus caryophyllus L. cv Rêve) petals. Treatments of microsomal membranes by nonionic or zwitterionic detergents indicated that lipoxygenase is tightly bound to the membranes. By phase separation in Triton X-114, microsomal lipoxygenase can be identified in part as an integral membrane protein. Soluble lipoxygenase had an optimum pH range of 4.9 to 5.8, whereas microsomal lipoxygenase exhibited maximum activity at pH 6.1. Both soluble and membrane-associated lipoxygenases produced carbonyl compounds and hydroperoxides simultaneously, in the presence of oxygen. The membranous enzyme was fully inhibited by 0.1 millimolar n-propyl gallate, nordihydroguaiaretic acid, or salicylhydroxamic acid, but the effect of the three inhibitors on the soluble enzyme was much lower. The soluble lipoxygenase is polymorphic and three isoforms greatly differing by their isoelectric points were identified. Lipoxygenase activity in flowers was maximal at the beginning of withering, both in the microsomal and the soluble fractions. Substantial variations in the ratio of the two forms of lipoxygenase were noted at different sampling dates. Our results allowed us to formulate the hypothesis of a strong association of one soluble form with defined membrane constituents.     

Soybean Lipoxygenase L-4, a Component of the 94-kilodalton Storage Protein in Vegetative Tissues: Expression and Accumulation in Leaves Induced by Pod Removal and by Methyl Jasmonate

A lipoxygenase L-4 gene was isolated from a soybean genomiclibrary. The amino acid sequence of lipoxygenase L-4 is highlyhomologous with the partial amino acid sequence of the 94-kDavegetative storage protein, vsp94, found in paraveinal mesophyllcells in the leaves of depodded soybean plants. No L-4 expressionwas observed in maturing seeds. The L-4 gene is highly expressedin the vegetative tissues of young seedlings, including cotyledons,hypocotyls, roots and primary leaves. L-4 expression followedthe same pattern as lipoxygenase activity in cotyledons peaking3 to 5 days after germination, and returning to a basal levelby 9 days after germination. L-4 gene expression was low inthe roots, stems and leaves of 10-week-old plants. Exposureof 4-week-old plants to atmospheric methyl jasmonate increasedL-4 mRNA in leaves. Continuous pod removal from 7-week-old plantsover a 2 week period resulted in dramatic accumulation of L-4mRNA in leaves. Accumulation of the L-4 protein and three otherlipoxygenase fractions in the leaves of depodded plants wasdemonstrated by ion exchange chromatography. These results indicatethat lipoxygenase L-4 is a component of vsp94. (Received May 31, 1993; Accepted August 9, 1993)     

绿茶、乌龙茶、红茶中的主要组分和酚类化合物抑制脂肪氧合酶活性和抗油脂自动氧化特性的研究

绿茶、乌龙茶和红茶中含有多种抑制脂肪氧合酶及抗油脂自动氧化的有效成分。实验结果表明,其中以表没食子儿茶素没食子酸酯(EGCG)的抗氧化活性最强,延缓猪油自动氧化诱导期为55.5小时,比无添加抗氧化成分的延长11倍,抑制脂肪氧合酶活性的IC_(50)值为10.0μmol/L。茶黄素单酯-2B(TFM-2B)和茶黄素双酯(TFD)比EGCG抑制脂肪氧合酶活性的效果更强,其IC_(60)值分别为0.57和0.23μmol/L。在三种茶叶的四种溶剂萃取物中,以乙酸乙酯萃取物的抗氧化活性最强。本文还研究了茶叶中主要生物活性物质的分离与纯化方法,以及抗氧化活性与结构的关系。     

Role of the mitochondria in the conversion of 1-aminocyclopropane 1-carboxylic acid to ethylene in plant tissues

Intact plant mitochondria, isolated from climacteric (Lycopersicon esculentum, Mill., tomato) or non-climacteric (Solanum tuberosum, L., potato) tissues, and purified on Percoll density gradients, were unable to convert 1-aminocyclopropane 1-carboxylic acid (ACC) to ethylene. Energization or sonication did not enhance ethylene production. For both tissues, the low activity of ACC conversion found in crude mitochondrial fractions from both tissues was increased by sonication. After mitochondrial purification, this activity was located on top of the gradient together with the microsomal membrane fraction containing a high lipoxygenase activity. Addition of exogenous lipoxygenase and linoleic acid to isolated tomato or potato mitochondria greatly enhanced ACC conversion (to approx. 300 pmol h⁻¹ mg⁻¹ protein). Direct measurements of ACC uptake by mitochondria indicated that ACC uptake is not dependent on energization.     

Isolation of lipoxygenase isoforms from Glycine max embryo axes based on apparent cross-reactivity with anti-myosin antibodies

Three lipoxygenase isoforms were isolated from Glycine max embryo axes. A number of proteins around 97 kDa cross-reacted with several anti-actin and anti-myosin antibodies and these were used to follow their purification through gel filtration, hydroxyapatite and anion exchange columns. The 97-kDa cross-reactive material eluted in the unbound fractions of the last anion exchange column, and displayed two components of pI's 6.2 and 6.3. Further phase partition of this fraction in TX-114 yielded a hydrophobic 97 kDa protein. Additionally, a 95-kDa protein was retained and eluted from this last column. Partial peptide sequences indicated that the 95 kDa protein was soybean lipoxygenase-1, the first 97 kDa protein was lypoxygenase-3, and the hydrophobic 97 kDa protein was lipoxygenase-2. Several possible reasons for the cross-reactivity with the antibodies are discussed. To our knowledge, this is the first example of individual lipoxygenase isoforms isolated from soybean embryo axes.     

Lipoxygenase in dark-grown Pisum sativum

Lipid oxidizing activity has been detected in acetone powders from both dark- and light-grown dwarf pea seedlings. This activity has been shown by several methods to be due to lipoxygenase. The enzyme from dark-grown seedlings has been purified 5·7-fold by ammonium sulphate precipitation and gel filtration. CM-cel-lulose chromatography of the purified enzyme yielded four active fractions. The properties of the four lipoxy-genase isoenzymes are described.