Steady-state kinetics of the anaerobic reaction of soybean lipoxygenase-1 with linoleic acid and 13-L-hydroperoxylinoleic acid.

The steady-state kinetics of the anaerobic reaction of soybean lipoxygenase-1 with linoleic acid and 13-L-hydroperoxylinoleic acid were studied. Initial rates of the formation of oxodienoic acids**, absorbing at 285 nm, were measured at pH 10. About 50% of the consumed 13-L-hydroperoxylinoleic acid was converted into oxodienoic acids regardless of the initial ratio of the two substrates. A linear inhibition by both linoleic acid and 13-L-hydroperoxylinoleic acid was observed in the concentration range studied, which is on the upper side limited by the concentrations at which micelle- or acid-soap formation starts. A kinetic scheme is proposed based on one active site in lipoxygenase-1 which alternately binds the two substrates. Values for the kinetic constants were calculated by fitting simultaneously the complete set of data to the appropriate rate equation.     

Micelle and acid-soap formation of linoleic acid and 13-L-hydroperoxylinoleic acid being substrates of lipoxygenase-1.

Surface tension measurements of linoleic acid solutions in 0.1 M sodiumborate buffer pH 10 at 23 degrees C showed that at increasing the linoleic acid concentration a sharp transition from monomers to micelles occurs at 167 micrometer. At pH 9 and 8 formation of acid-soap dimers from monomers starts at 60 micrometer and 21 micrometer respectively. The concentration range at which only monomers exist is therefore markedly reduced. For 13-L-hydroperoxylinoleic acid at pH 10 acid-soap formation still takes place, starting at approx. 220 micrometer. The total lipid concentration at which acid-soap or micelle formation starts in mixtures of linoleic acid and 13-L-hydroperoxylinoleic acid has been determined in relation to the molar ratio of both acids.     

Irreversible inhibition of soybean lipoxygenase-1 by hydroperoxy acids as substrates

Soybean lipoxygenase-1 was irreversibly inactivated by various peroxy acids containing a cis,cis-1,4-pentadiene group. Among these compounds, 15(S)-hydroperoxyeicosatetraenoic acid (15(S)-HPETE)2 was found to be the most effective in the inactivation of lipoxygenase. Although the prior exposure of 15(S)-HPETE to hemoglobin abolished the inhibitory effect of 15(S)-HPETE, the simultaneous inclusion of hemoglobin potentiated the inactivation of lipoxygenase by 15(S)-HPETE alone. Interestingly, the potentiating effect of hemoglobin was observed only in the incubations with peroxy acids possessing the cis,cis-1,4-pentadiene. In either the presence or the absence of hemoglobin, it was commonly observed that the enzyme inactivation, which was maximal at pH 10, was significantly protected by tocopherol, but neither by mannitol nor ethanol, and that the inclusion of arachidonic acid or linoleic acid prevented the enzyme inactivation. Based on these results, it is suggested that the selective inactivation of lipoxygenase by these peroxy acids may be due to unstable intermediates produced from hydroperoxy acids bound to the active site of lipoxygenase.     

Inhibition of soybean lipoxygenase-1 by n-alcohols and n-alkylthiols.

A series of n-alcohols and n-alkylthiols with carbon chains from 2 to 12 were examined for the inhibition of soybean lipoxygenase-1 (L-1). The alcohol produces a competitive inhibition, the extent of which increases with an increase in the carbon number of alkyl chain up to 8. Whereas the inhibition of the alkylthiol is noncompetitive, the extent of which is almost independent from the carbon number. From the behavior of pKi dependence on the carbon number of the alcohol, the decyl group appears to be optimum to bind to L-1. The thermodynamic analysis for the inhibition based upon van 't Hoff equation indicates positive enthalpy and entropy changes for the binding of the alcohol to the enzyme and negative enthalpy and positive to negative entropy changes for that of the alkylthiol. These observations suggest that the alcohol inhibits L-1 by binding of the hydrophobic alkyl tail to the catalytic site of the enzyme by a hydrophobic interaction. The alkylthiol inhibits by binding of the nucleophilic sulfhydryl head to a polarizable region of the enzyme and the alkyl tail to a hydrophobic region of the enzyme free from the steric hindrance as an anchor.     

Cationic substrates of soybean lipoxygenase-1

Soybean lipoxygenase-1 (SBLO-1) catalyzes the oxygenation of 1,4-dienes to produce conjugated diene hydroperoxides. The best substrates are anions of fatty acids; for example, linoleate is converted to 13(S)-hydroperoxy-9(Z),11(E)-octadecadienoate. The manner in which SBLO-1 binds substrates is uncertain. In the present work, it was found that SBLO-1 will oxygenate linoleyltrimethylammonium ion (LTMA) to give primarily13(S)-hydroperoxy-9(Z),11(E)-octadecadienyltrimethylammonium ion. The rate of this process is about the same at pH 7 and pH 9 and is about 30% of the rate observed with linoleate at pH 9. At pH 7, SBLO-1 oxygenates linoleyldimethylamine (LDMA) to give primarily 13(S)-hydroperoxy-9(Z),11(E)-octadecadienyldimethylamine. The oxygenation of LDMA occurs at about the same rate as LTMA at pH 7, but more slowly at pH 9. The results demonstrate that SBLO-1 will readily oxygenate substrates in which the carboxylate of linoleate is replaced with a cationic group, and the products of these reactions have the same stereo- and regiochemistry as the products obtained from fatty acid substrates.     

Oxidation of furan fatty acids by soybean lipoxygenase-1 in the presence of linoleic acid

The interaction of furan fatty acids (F-acids) with lipoxygenase was investigated by incubation experiments of a synthetic dialkyl-substituted F-acid with soybean lipoxygenase-1. Originally the oxidation of furan fatty acids was assumed to be directly effected by lipoxygenase. It is now demonstrated that this reaction is a two-step process that requires the presence of lipoxygenase substrates, e.g. linoleic acid. In the first step linoleic acid is converted by the enzyme to the corresponding hydroperoxide. This attacks, probably in a radical reaction, the furan fatty acid to produce a dioxoene compound that can be detected unequivocally by gas chromatography-mass spectrometry.     

厌氧条件下微生物将磷还原为磷化氢

【目的】磷化氢为磷的气态形式,将污水中磷通过转化为磷化氢的方式去除,为污水除磷提供新思路。【方法】采用厌氧持续培养的方式,以经过磷化氢处理和没有处理的水稻土分别作为接种物,在氧化还原电位(ORP)≤-300 m V、恒温35°C,避光持续培养160 d。【结果】培养器1出水总磷的去除率稳定达到25%,最高去除率为26.78%,气体磷化氢的产量达到130 ng/L以上。培养器2出水总磷去除达到23%,气体磷化氢的产量达到126 ng/L。【结论】对水稻土进行厌氧条件下连续培养,可以形成稳定的厌氧产磷化氢微生物体系,提高磷化氢的释放量。     

Irreversible inactivation of soybean lipoxygenase-1 by hydrophobic thiols

Soybean lipoxygenase-1 is inactivated by micromolar concentrations of the following hydrophobic thiols: 1-octanethiol, 12(S)-mercapto-9(Z)-octadecenoic acid (S-12-HSODE), 12(R)-mercapto-9(Z)-octadecenoic acid (R-12-HSODE), and 12-mercaptooctadecanoic acid (12-HSODA). In each case, inactivation is time-dependent and not reversed by dilution or dialysis. Inactivation requires 13-hydroperoxy-9(Z),11(E)-octadecadienoic acid (13-HPOD), which suggests that it is specific for the ferric form of the enzyme. Lipoxygenase catalyzes an oxygenation reaction on each of the aforementioned thiols, as judged by the consumption of O(2). These reactions also require 13-HPOD. 1-Octanethiol is converted to 1-octanesulfonic acid, which was identified by GC/MS of its methyl ester. The rates of oxygen uptake for R- and S-12-HODE are about 5- and 2.5-fold higher than the rate with 1-octanethiol. The stoichiometries of inactivation imply that inactivation occurs on approximately 1 in 18 turnovers for 12-HSODA, 1 in 48 turnovers for 1-octanethiol, 1 in 63 turnovers for S-12-HSODE, and 1 in 240 turnovers for R-12-HSODE. These data imply that close resemblance to lipoxygenase substrates is not a crucial requirement for either oxidation or inactivation. Under the conditions of our experiments, inactivation was not observed with several more polar thiols: mercaptoethanol, dithiothreitol, L-cysteine, glutathione, N-acetylcysteamine, and captopril. The results imply that hydrophobic thiols irreversibly inactivate soybean lipoxygenase by a mechanism that involves oxidation at sulfur.     

Oxygenation of monounsaturated fatty acids by soybean lipoxygenase-1: evidence for transient hydroperoxide formation

Soybean lipoxygenase-1 (SBLO-1) catalyzes the oxygenation of polyunsaturated fatty acids to produce conjugated diene hydroperoxides. Previous work from our laboratories has demonstrated that SBLO-1 will also catalyze the oxygenation of monounsaturated acids (Clapp, C. H., Senchak, S. E., Stover, T. J., Potter, T. C., Findeis, P. M., and Novak, M. J. (2001) Soybean Lipoxygenase-Mediated Oxygenation of Monounsaturated Fatty Acids to Enones, J. Am. Chem. Soc. 123, 747-748). Interestingly, the products are alpha,beta-unsaturated ketones rather than the expected allylic hydroperoxides. In the present work, we provide evidence that the monoolefin substrates are initially converted to allylic hydroperoxides, which are subsequently converted to the enone products. The hydroperoxide intermediates can be trapped by reduction to the corresponding allylic alcohols with glutathione peroxidase plus glutathione or with SnCl2. Under some conditions, the hydroperoxide intermediates accumulate and can be detected by HPLC and peroxide assays. Kinetics measurements at low concentrations of [1-14C]-9(Z)-octadecenoic acid indicate that oxygenation of this substrate at 25 degrees C, pH 9.0 occurs with kcat/Km = 1.6 (+/-0.1) x 10(2) M-1 s-1, which is about 105 lower than kcat/Km for oxygenation of 9(Z),12(Z)-octadecadienoic acid (linoleic acid). Comparison of the activities of 9(Z)-octadecenoic acid and 12(Z)-octadecenoic acid implies that the two double bonds of linoleic acid contribute almost equally to the C-H bond-breaking step in the normal lipoxygenase reaction. The results are consistent with the notion that SBLO-1 functionalizes substrates by a radical mechanism.     

Inhibition of soybean lipoxygenase-1 by 10-butyryl substituted 1,8-dihydroxy-9-anthrone (butantrone)

10-Butyryl substituted 1,8-dihydroxyanthrone (butantrone) inhibited soybean lipoxygenase-1 irreversibly and more efficiently than its parent compound 1,8-dihydroxyanthrone (dithranol, anthralin) (IC50 values 0.090 mM and 1.1 mM, respectively). Intact butantrone rather than its hydrolysis product was the primary effector and the 10-butyryl moiety its site specific probe, probably directing the inhibitor to the proximity of the binding site of the lipid substrate/product.     

The interaction of nitric oxide with soybean lipoxygenase-1.

The interaction of nitric oxide with the non-heme iron dioxygenase lipoxygenase is reported. This apparently resulted in a novel type of complex where an electron is donated to the NO molecule. In addition a new position for an EPR transition from iron was discovered which, it is suggested results from high spin ferric iron in a field of axial symmetry characterised by a very low value for D.     

Effect of endocannabinoids on soybean lipoxygenase-1 activity

Endocannabinoids appear to be involved in a variety of physiological processes. Lipoxygenase activity has been known to be affected by unsaturated fatty acids or phenolic compounds. In this study, we examined whether endocannabinoids containing both N-acyl group and phenolic group can affect the activity of soybean lipoxygenase (LOX)-1, similar to mammalian 15-lipoxygenase in physicochemical properties. First, N-arachidonoyl dopamine and N-oleoyl dopamine were found to inhibit soybean LOX-1-catalyzed oxygenation of linoleic acid in a non-competitive manner with a K_i value of 3.7 μM and 6.2 μM, respectively. Meanwhile, other endocannabinoids failed to show a remarkable inhibition of soybean LOX-1. Separately, N-arachidonoyl dopamine and N-arachidonoyl serotonin were observed to inactivate soybean LOX-1 with K_in value of 27 μM and 24 μM, respectively, and k₃ value of 0.12 min⁻¹ and 0.35 min⁻¹, respectively. Furthermore, such an inactivation was enhanced by ascorbic acid, but suppressed by 13(S)-hydroperoxy-9,11-octadecadienoic acid. Taken together, it is proposed that endocannabinoids containing polyunsaturated acyl moiety and phenolic group may be efficient for the inhibition as well as inactivation of 15-lipoxygenase.     

Demonstration by EPR spectroscopy of the functional role of iron in soybean lipoxygenase-1.

1. The EPR spectrum at 15 degrees K of soybean lipoxygenase-1 in borate buffer pH 9.0 has been studied in relation to the presence of substrate (linoleic acid), product (13-L-hydroperoxylinoleic acid) and oxygen. 2. The addition of 13-L-hydroperoxylinoleic acid to lipoxygenase-1 at pH 9.0 gives rise to the appearance of EPR lines at g equals 7.5, 6.2, 5.9 and 2.0, and an increased signal at g equals 4.3. 3. In view of the effect of the end product on both the kinetic lag period of the aerobic reaction and the fluorescence of the enzyme, it is concluded that 13-L-hydroperoxylinoleic acid is required for the activation of soybean lipoxygenase-1. Thus it is proposed that the enzyme with iron in the ferric state is the active species. 4. A reaction scheme is presented in which the enzyme alternatingly exists in the ferric and ferrous states for both the aerobic and anaerobic reaction.     

Structural and functional characterization of second-coordination sphere mutants of soybean lipoxygenase-1.

Lipoxygenases are an important class of non-heme iron enzymes that catalyze the hydroperoxidation of unsaturated fatty acids. The details of the enzymatic mechanism of lipoxygenases are still not well understood. This study utilizes a combination of kinetic and structural probes to relate the lipoxygenase mechanism of action with structural modifications of the iron's second coordination sphere. The second coordination sphere consists of Gln(495) and Gln(697), which form a hydrogen bond network between the substrate cavity and the first coordination sphere (Asn(694)). In this investigation, we compared the kinetic and structural properties of four mutants (Q495E, Q495A, Q697N, and Q697E) with those of wild-type soybean lipoxygenase-1 and determined that changes in the second coordination sphere affected the enzymatic activity by hydrogen bond rearrangement and substrate positioning through interaction with Gln(495). The nature of the C-H bond cleavage event remained unchanged, which demonstrates that the mutations have not affected the mechanism of hydrogen atom tunneling. The unusual and dramatic inverse solvent isotope effect (SIE) observed for the Q697E mutant indicated that an Fe(III)-OH(-) is the active site base. A new transition state model for hydrogen atom abstraction is proposed.     

Isolation of soybean lipoxygenase-2 by affinity chromatography

Isoenzyme lipoxygenase-2 from soybean was isolated by affinity chromatography. Gel electrophoresis showed it to be a single protein. Its pH optimum of 6.5, range of 5.0–8.0 and activity which increased when Ca²⁺ was added identified the isolated enzyme as lipoxygenase-2.     

Effect of denaturants on the structural properties of soybean lipoxygenase-1.

The effect of chemical (urea) and physical (temperature and high pressure) denaturation on the structural properties of soybean lipoxygenase-1 (LOX1) was analyzed through dynamic fluorescence spectroscopy and circular dichroism. We show that the fluorescence decay of the native protein could be fitted by two lorentzian distributions of lifetimes, centered at 1 and 4 ns. The analysis of the urea-denatured protein suggested that the shorter distribution is mostly due to the tryptophan residues located in the N-terminal domain of LOX1. We also show that a pressure of 2400 bar and a temperature of 55 degrees C brought LOX-1 to a state similar to a recently described stable intermediate "I." Analysis of circular dichroism spectra indicated a substantial decrease of alpha-helix compared with beta-structure under denaturing conditions, suggesting a higher stability of the N-terminal compared with the C-terminal domain in the denaturation process.     

Kinetic studies of oxygen reactivity in soybean lipoxygenase-1

The reactivity of O(2) with soybean lipoxygenase-1 (SLO) has been examined using a range of kinetic probes. We are able to rule out diffusional encounter of O(2) with protein, an outer-sphere electron transfer to O(2), and proton transfer as rate-limiting steps in k(cat)/K(M)(O(2)) for wild-type enzyme (WT SLO); this restricts the rate-limiting step to either the combination of O(2) with L(*) or a subsequent conformational change. In the Ile(553) --> Phe mutant, which constricts the putative O(2) binding channel [Knapp et al. (2001) J. Am. Chem. Soc. 123, 2931-2932], k(cat)/K(M)(O(2)) decreases by over a factor of 20; yet, this mutant appears to have the same rate-limiting step as WT SLO. It is argued that the slow step on k(cat)/K(M)(O(2)) is the combination of O(2) with L(*), with proximal protein effects determining the rate of reaction. The available data for SLO support the view that enzymes can affect O(2) reactivity without a direct involvement of metal cofactors. The primary role of the Fe(3+) cofactor is to generate an enzyme-bound radical, while the protein is concluded to control the stereo- and regiochemistry of O(2) encounter with this radical.     

Analysis of a specific oxygenation reaction of soybean lipoxygenase-1 with fatty acids esterified in phospholipids

Soybean lipoxygenase was reacted with phosphatidylcholine (at pH 9, with 10 mM deoxycholate), and the oxygenation products were analyzed by high-pressure liquid chromatography, UV, gas chromatography-mass spectrometry (GC-MS), and NMR. The structures of the intact glycerolipid products were established by GC-MS of diglycerides recovered by phospholipase C hydrolysis and by proton NMR of the intact phosphatidylcholine. These analyses, together with analyses of the transesterified fatty acids, indicated that arachidonyl and linoleoyl moieties in the phosphatidylcholine were converted exclusively to the 15(S)-hydroperoxy-5(Z),8(Z),11(Z),13(E)-eicosatetraenoate and 13(S)-hydroperoxy-9(Z),11(E)-octadecadienoate analogues, respectively. Control experiments proved that the intact phospholipid (and not hydrolyzed/reesterified fatty acid) was the true substrate of the oxygenation reaction. Phosphatidylethanolamine and phosphatidylinositol lipids were also substrates for specific oxygenation by the soybean lipoxygenase. The results provide concrete evidence that fatty acids esterified in phospholipid can be subject to highly specific oxygenation by a lipoxygenase enzyme.