A novel chiral stationary phase HPLC-MS/MS method to discriminate between enzymatic oxidation and auto-oxidation of phosphatidylcholine.

To elucidate the role of enzymatic lipid peroxidation in disease pathogenesis and in food deterioration, we recently achieved stereoselective analysis of phosphatidylcholine hydroperoxide (PCOOH) possessing 13S-hydroperoxy-9Z,11E-octadecadienoic acid (13(S)-9Z,11E-HPODE) using HPLC-MS/MS with a CHIRALPAK OP (+) column. Because enzymatic oxidation progresses concurrently with auto-oxidation, we need to distinguish them further. Here, we attempted such an analysis. First, we used lipoxygenase, linoleic acid, and lysophosphatidylcholine (LPC) to synthesize the enzymatic oxidation product 13(S)-9Z,11E-HPODE PC, and the auto-oxidation products 13(RS)-9Z,11E-HPODE PC and 13(RS)-9E,11E-HPODE PC, which were used as standards to test the ability of various columns to separate the enzymatic oxidation product from auto-oxidation products. Separation was achieved by connecting in series two columns with different properties: CHIRALPAK OP (+) and CHIRALPAK IB-3. The CHIRALPAK OP (+) column separated 13(R)-9Z,11E-HPODE PC and 13(S)-9Z,11E-HPODE PC, whereas CHIRALPAK IB-3 enabled separation of 13(S)-9Z,11E-HPODE PC and 13(RS)-9E,11E-HPODE PC. The results for the analysis of both enzymatically oxidized and auto-oxidized lecithin (an important phospholipid mixture in vivo and in food) indicate that our method would be useful for distinguishing enzymatic oxidation and auto-oxidation reactions. Such information will be invaluable for elucidating the involvement of PCOOH in disease pathogenesis and in food deterioration.

Standard operation protocol for analysis of lipid hydroperoxides in human serum using a fully automated method based on solid-phase extraction and liquid chromatography-mass spectrometry in selected reaction monitoring.

Standard operating procedures (SOPs) are of paramount importance in the analytical field to ensure the reproducibility of the results obtained among laboratories. SOPs gain special interest when the aim is the analysis of potentially unstable compounds. An SOP for analysis of lipid hydroperoxides (HpETEs) is here reported after optimization of the critical steps to be considered in their analysis in human serum from sampling to final analysis. The method is based on automated hyphenation between solid-phase extraction (SPE) and liquid chromatography-mass spectrometry (LC-MS). The developed research involves: (i) optimization of the SPE and LC-MS steps with a proper synchronization; (ii) validation of the method-viz. accuracy study (estimated as 86.4% as minimum value), evaluation of sensitivity and precision, which ranged from 2.5 to 7.0 ng/mL (0.25-0.70 ng on column) as quantification limit and precision below 13.2%), and robustness study (reusability of the cartridge for 5 times without affecting the accuracy and precision of the method); (iii) stability study, involving freeze-thaw stability, short-term and long-term stability and stock solution stability tests. The results thus obtained allow minimizing both random and systematic variation of the metabolic profiles of the target compounds by correct application of the established protocol.

Efficient and specific conversion of 9-lipoxygenase hydroperoxides in the beetroot. Formation of pinellic acid.

The linoleate 9-lipoxygenase product 9(S)-hydroperoxy-10(E),12(Z)-octadecadienoic acid was stirred with a crude enzyme preparation from the beetroot (Beta vulgaris ssp. vulgaris var. vulgaris) to afford a product consisting of 95% of 9(S),12(S),13(S)-trihydroxy-10(E)-octadecenoic acid (pinellic acid). The linolenic acid-derived hydroperoxide 9(S)-hydroperoxy-10(E),12(Z),15(Z)-octadecatrienoic acid was converted in an analogous way into 9(S),12(S),13(S)-trihydroxy-10(E),15(Z)-octadecadienoic acid (fulgidic acid). On the other hand, the 13-lipoxygenase-generated hydroperoxides of linoleic or linolenic acids failed to produce significant amounts of trihydroxy acids. Short-time incubation of 9(S)-hydroperoxy-10(E),12(Z)-octadecadienoic acid afforded the epoxy alcohol 12(R),13(S)-epoxy-9(S)-hydroxy-10(E)-octadecenoic acid as the main product indicating the sequence 9-hydroperoxide → epoxy alcohol → trihydroxy acid catalyzed by epoxy alcohol synthase and epoxide hydrolase activities, respectively. The high capacity of the enzyme system detected in beetroot combined with a simple isolation protocol made possible by the low amounts of endogenous lipids in the enzyme preparation offered an easy access to pinellic and fulgidic acids for use in biological and medical studies.

Preparation of pure lipid hydroperoxides.

Increasing evidence of lipid peroxidation in food deterioration and pathophysiology of diseases have revealed the need for a pure lipid hydroperoxide (LOOH) reference as an authentic standard for quantification and as a compound for biological studies in this field. Generally, LOOH is prepared from photo- or enzymatically oxidized lipids; however, separating LOOH from other oxidation products and preparing pure LOOH is difficult. Early studies showed the usability of reaction between hydroperoxide and vinyl ether for preparation of pure LOOH. Because the reactivity of vinyl ether with LOOHs other than fatty acid hydroperoxides has never been reported, here, we employed the reaction for preparation of a wide variety of pure LOOHs. Phospholipid, cholesteryl ester, triacylglycerol, or fatty acid was photo- or enzymatically oxidized; the resultant crude sample containing hydroperoxide was allowed to react with a vinyl ether [2-methoxypropene (MxP)]. Liquid chromatography (LC) and mass spectrometry confirmed that MxP selectively reacts with LOOH, yielding a stable MxP adduct (perketal). The lipophilic perketal was eluted at a position away from that of intact LOOH and identified and isolated by LC. Upon treatment with acid, perketal released the original LOOH, which was finally purified by LC. Using our optimized purification procedures, for instance, we produced 75 mg of pure phosphatidylcholine hydroperoxide (>99%) from 100 mg of phosphatidylcholine. Our developed method expands the concept of the perketal method, which provides pure LOOH references. The LOOHs prepared by the perketal method would be used as "gold standards" in LOOH methodology.

NMR properties of conjugated linoleic acid (CLA) methyl ester hydroperoxides.

NMR data on lipid hydroperoxides is scarce. In this study, hydroperoxides were produced from methyl 9-cis,11-trans-octadecadienoate and from methyl 10-trans,12-cis-octadecadienoate by autoxidation in the presence of 20% of alpha-tocopherol. Ten different hydroperoxides were isolated from the autoxidation mixtures of the two conjugated linoleic acid (CLA) methyl esters by SPE and HPLC. The assignment of the 1H and 13C NMR spectra of these hydroperoxides was accomplished by 2D NMR experiments and by spectral simulations. Substitution of a hydroperoxyl group at the allylic position in CLA methyl esters induced a 53.93 ppm downfield shift on the hydroperoxyl-bearing carbon resonance. The effects on the olefinic alpha, beta, gamma, and delta carbon resonances were -3.45, +4.96, -1.22, and +4.42 ppm, respectively. Furthermore, the solvent effects of deuterochloroform, deuteroacetone, and deuterobenzene on the 13C resonances of the hydroperoxides suggest that deuterochloroform is the appropriate solvent for 13C NMR studies on mixtures of lipid hydroperoxides.

Elimination of lipid peroxide during hemodialysis.

BACKGROUND/AIMS: This study is aimed to show the antioxidative effect of hemodialysis (HD) by demonstrating the elimination of toxic lipid peroxides. METHODS: Blood samples were obtained from patients on regular maintenance HD before and 15, 30, 60, 120 and 240 min after the start of each HD session. Plasma cholesteryl ester hydroperoxide (CE-OOH), phosphatidylcholine hydroperoxide (PC-OOH), and eliminators of lipid peroxides (LOOH) such as apolipoprotein A-I (apoA-I) and lecithin:cholesterol acyltransferase (LCAT) were investigated. The hydroxyl radical scavenging activity was measured for the evaluation of the pro-oxidative side. RESULTS: CE-OOH and PC-OOH were elevated in patients with chronic kidney disease both on and not on HD, while these values were much higher in HD patients. CE-OOH quickly dropped during the first 30 min of HD, then gradually decreased until 240 min. CE-OOH concentrations were related to those of apoA-I. In contrast, PC-OOH showed an increase 30 min after the start of HD, a change which resembled that of LCAT and was the reverse of the hydroxyl radical scavenging activity. CONCLUSION: These results demonstrate the antioxidative action through CE-OOH elimination involving apoA-I. The pro- and antioxidative effects of HD on LOOH are not uniform but PC-OOH is mainly influenced prooxidatively.

Duración mínima del tratamiento balneario con aguas bicarbonatadas sulfatadas para conseguir un efecto antioxidante en personas mayores de 65 años / Minimum duration of spa treatment with bicarbonated-sulfated waters to obtain an antioxidant effect in persons aged more than 65 years

Introducción: desde que se utilizan los tratamientos balnearios, siempre ha habido la duda sobre el tiempo mínimo necesario para que dicho tratamiento fuera eficaz y efectivo. Forma parte de la tradición balnearia realizar la llamada "la novena", que se corresponde con la duración mínima de 9 días continuados de tratamiento y estancia balnearia para conseguir los efectos beneficiosos de la cura balnearia, hechos que han sido observados durante años. Objetivo: estudiar y evaluar el tiempo mínimo de tratamiento cenoterápico con aguas bicarbonatadas sulfatadas necesario para obtener una disminución estadísticamente significativa de la eliminación de sustancias reactivas al ácido tiobarbitúrico (TBARS) en una población balnearia mayor de 65 años. Pacientes y método: estudio clínico prospectivo realizado en el balneario de aguas bicarbonatadas sulfatadas de Jaraba-Sicilia (Zaragoza) en 3 estaciones climatológicas diferentes del mismo año, con 120 voluntarios del Programa de Termalismo Social del IMSERSO, 60 varones y 60 mujeres (edad media 70,9 ñ 0,5 años); no había diferencias estadísticamente significativas entre la edad de ambos grupos, homogéneos en su conjunto y de muestras pareadas dependientes e igual tamaño. Se obtuvieron muestras de orina para determinar la concentración de TBARS mediante espectrofotometría a la llegada al balneario, a los 9 y a los 14 días de tratamiento; se les realizó una historia clínica completa y se valoraron diferentes variables médicas tras aplicar crenoterapia por vía tópica (baños de 37,5-39 0 C durante 15 min) y/o hidropínica. Las muestras urinarias se analizaron siguiendo una modificación de la técnica descrita en 1978 por Mihara et al. Resultados: la producción urinaria de peroxidación lipídica (TBARS) en orina, principalmente malondialdehído, fue, a la llegada, de 0,368 ñ 0,0095 nM/ml, a los 9 días de tratamiento de 0,352 ñ 0,0088 nM/ml y al finalizar el mismo, tras 14 días de crenoterapia, de 0,337 ñ 0,0083 nM/ml; el beneficio poscrenoterápico obtenido en su estado oxidativo (efecto crenoterápico terapéutico) fue de -0,016 ñ 0,0019 (4,35 por ciento) a los 9 días, el cual se duplicó a los 14 días, con cifras de -0,031 ñ 0,0017 (8,4 por ciento). Esta disminución de los valores de oxidación obtenidos presentó diferencias estadísticamente significativas (p < 0,001) en toda la población estudiada. Conclusión: a partir del noveno día de tratamiento con aguas bicarbonatadas sulfatadas hay evidencias de que el efecto crenoterápico antioxidante comienza a ser eficaz y estadísticamente significativo en la población estudiada, lo que coincide con la mejoría física obtenida. Este efecto crenoterápico se potencia al doble si se prolonga el tratamiento hasta 14 días (AU)

Measurement of lipid peroxidation.

There is currently considerable interest in what is termed "oxidative stress," or the oxidation of biological macromolecules, with emphasis on its involvement in various diseases and toxicities and methods to limit either its occurrence or effects. This unit describes traditional methods to measure the extent or rate of lipid peroxidations, including assays for conjugated dienes, lipid hydroperoxides, the polyunsaturated lipid breakdown product malondialdehyde, and hemolysis, along with discussion of alternative methods.

Separation of representative lipid compounds of biological membranes and lipid derivatives from peroxidized polyunsaturated fatty acids by reversed phase high-performance liquid chromatography.

A complex mixture of different lipid compounds, including phosphatidylcholine, phosphatidylserine, all trans-retinol, 15(S)-hydroperoxyeicosatetraenoic acid, D-alpha-tocopherol, saturated and unsaturated fatty acids can be separated by reversed phase HPLC by using a C-18, 120 mm x 4 mm, 3 microns particle size column and a step gradient from acetonitrile/water (1:1; v:v) to 100% acetonitrile at a flow rate of 0.8 ml/min. By applying this elution condition, separation of various groups of lipid hydroperoxides and lipid derivatives, each one originating from a different in vitro peroxidized polyunsaturated fatty acid, can be obtained. Simultaneous detection is carried out by a diode array detector at a wavelength accumulation range set up between 195 and 400 nm. The possibility of simultaneously having such a large number of measurements renders this chromatographic method particularly suitable in studies concerning lipid peroxidation where, in addition to the detection of free radical-induced lipid hydroperoxides, data on some key antioxidant molecules, i.e. vitamin A and E, as well as that of structural compounds of biological membranes, i.e. phosphatidylcholine and phosphatidylserine, can be achieved.

The selenoenzyme phospholipid hydroperoxide glutathione peroxidase controls the activity of the 15-lipoxygenase with complex substrates and preserves the specificity of the oxygenation products.

Mammalian 15-lipoxygenases have been suggested to be involved in cell differentiation and atherogenesis because of their capability of oxygenating polyenoic fatty acids esterified to biomembranes and lipoproteins. We investigated the interaction of the lipid-peroxidizing 15-lipoxygenase and the hydroperoxy lipid-reducing phospholipid hydroperoxide glutathione peroxidase during their reaction with biomembranes and lipoproteins and obtained the following results. 1) Lipoxygenase treatment of submitochondrial membranes led to the formation of hydroperoxyphosphatidylethanolamine and hydroperoxyphosphatidylcholine as indicated by high performance liquid chromatography with chemiluminescence detection. In 15-lipoxygenase-treated low density lipoprotein cholesteryl hydroperoxylinoleate was the major oxygenation product. 2) Phospholipid hydroperoxide glutathione peroxidase was capable of reducing the hydroperoxy lipids formed by the 15-lipoxygenase to their corresponding alcohols. 3) Preincubation of low density lipoprotein and submitochondrial membranes with the phospholipid hydroperoxide glutathione peroxidase completely prevented the lipoxygenase reaction. However, addition of exogenous hydroperoxy lipids restored the oxygenase activity. 4) Short-term incubations of the complex substrates with the 15-lipoxygenase led to a specific pattern of oxidation products which was rendered more unspecific at long-term incubation or at high substrate concentrations. If the phosholipid hydroperoxide glutathione peroxidase was present during the reaction, the specific product pattern was preserved. These data indicate that the phospholipid hydroperoxide glutathione peroxidase is capable of reducing hydroperoxy ester lipids formed by a 15-lipoxygenase, and that it may down-regulate the 15-lipoxygenase pathways in mammalian cells. The specificity of 15-lipoxygenase-derived hydroperoxy lipids depends on their immediate reduction to the corresponding alcohols preventing postcatalytic isomerization.

An enzymatic formation of 13-oxo-trideca-9,11-dienoic acid from 13-hydroperoxylinolenic acid by a homolytic hydroperoxide lyase in elicitor-treated soybean cotyledons.

An activity of homolytic hydroperoxide lyase (HPLS) catalyzing the specific cleavage of 13-hydroperoxylinolenic acid to form a volatile compound and 13-oxo acid was found in the enzyme extract from soybean cotyledons. 2-Penten-1-ol was characterized as a volatile metabolite by gas chromatography-mass spectrometry analysis. The methyl ester derivatives of reaction products were separated and isolated by a normal-phase high-performance liquid chromatography, and identified to be 13-oxo-trideca-9(Z),11(E)-dienoic acid methyl ester and its geometric isomer possessed 9(E),11(E) moiety by the analyses of high resolution mass spectrometry and nuclear magnetic resonance spectrometry. An activity of homolytic HPLS found in soybean cotyledons was evidently enhanced by elicitation. The products of 13-oxo-tridecadienoic acid with alpha, beta, gamma, delta-unsaturation were shown to be antifungal substances by a chromatographic bioassay. The metabolites via lipoxygenase and HPLS pathways may have physiological roles in the resistant action of host plants.

Apparent antibacterial activity of catalase: role of lipid hydroperoxide contamination.

Escherichia coli was killed by catalase in dose-, time-, and pH-dependent manners. Dialyzed catalase had bactericidal activity, but enzyme which had been heat-denatured or inactivated by pretreatment with 3-aminotriazole plus hydrogen peroxide did not. Cytochrome c and hemoglobin also had bactericidal activity. Thiobarbituric acid-reactive substances were detected in commercial hemoproteins except for horseradish peroxidase and the relationship between the contents of these substances and bactericidal activity was demonstrated. Without the addition of hydroperoxide, hemoproteins except for horseradish peroxidase initiated the oxidation of 2,2'-azino-bis(3-ethylbenzthiazoline-6-sulfonic acid) (ABTS) and catalase caused the peroxidation of linoleic acid. The pH patterns of bactericidal activity, lipid peroxidation, and the oxidation of ABTS were similar. The results indicate that hemoprotein preparations are contaminated with lipid hydroperoxides and it is the decomposition of these contaminants catalyzed by the hemoprotein into alkoxyl/peroxyl radicals that causes bacterial killing.

Biliary glutathione promotes the mucosal metabolism of luminal peroxidized lipids by rat small intestine in vivo.

We previously found that exogenous GSH enhances mucosal GSH and promotes lipid hydroperoxide metabolism by rat small intestine (AW, T. Y., and M. W. WIlliams, 1992. Am. J. Physiol. 263:G665-G672). In this study, we have developed an in vivo bile and lymph fistula rat model to test the hypothesis that biliary GSH is an important luminal source of GSH. Peroxidized fish oil was infused into the proximal intestine, and hydroperoxide accumulation in lumen, mucosa, and lymph was determined. Diversion of bile decreased mucosal GSH and increased hydroperoxide accumulation in all fractions. Supplementation with GSH, but not with GSSG, increased tissue GSH and attenuated hydroperoxide accumulation (50-60%), consistent with enhancement of hydroperoxide removal by exogenous GSH. Addition of native bile deficient in GSH, but not cysteine, cystine, or GSSG, decreased luminal and lymph hydroperoxide levels by 20-30%. Amino acid supplementation concurrently attenuated hydroperoxide recoveries in these fractions by 30-40% and increased mucosal GSH by 40%, indicating a role for biliary amino acids in hydroperoxide elimination. The effect of amino acids was abolished by buthionine sulfoximine, confirming their role in GSH biosynthesis. Collectively, the results demonstrate that bile is a rich source of reductant for maintaining mucosal GSH to promote intestinal metabolism of luminal peroxidized lipids.

Characterization of lipid hydroperoxides generated by photodynamic treatment of leukemia cells.

A new technique, high-performance liquid chromatography with reductive mode electrochemical detection on a mercury drop (HPLC-EC), has been used for analyzing lipid hydroperoxide (LOOH) formation in photooxidatively stressed L1210 leukemia cells. Highly specific and sensitive for peroxides (detection limits < 0.5 pmol for cholesterol hydroperoxides and < 50 pmol for phospholipid hydroperoxides), this approach allows different classes of LOOH to be separated and determined in minimally damaged cells. L1210 cells in serum-containing growth medium were irradiated in the presence of merocyanine 540 (MC540), a lipophilic photosensitizing dye. Lipid extracts from cells exposed to a light fluence of 0.11 J/cm2 (which reduced clonally assessed survival by 30%) showed 12-15 well-defined peaks in HPLC-EC. None of these peaks was observed when cells were irradiated without MC540 or when dye/light-treated samples were reduced with triphenylphosphine prior to analysis. Three peaks of relatively low retention time (< 12 min) were assigned to the following species by virtue of comigration with authentic standards: 3 beta-hydroxy-5 alpha-cholest-6-ene-5-hydroperoxide (5 alpha-OOH), 3 beta-hydroxycholest-4-ene-6 beta-hydroperoxide (6 beta-OOH), and 3 beta-hydroxycholest-5-ene-7 alpha/7 beta-hydroperoxide (7 alpha/7 beta-OOH). Formation of 5 alpha-OOH and 6 beta-OOH (single oxygen adducts) was confirmed by subjecting [14C]cholesterol-labeled cells to relatively high levels of photooxidation and analyzing extracted lipids by HPLC with radiochemical detection. Material represented in a major peak at 18-22 min on HPLC-EC was isolated in relatively large amounts by semipreparative HPLC and shown to contain phospholipid hydroperoxides (predominantly phosphatidylcholine species, PCOOH) according to the following criteria: (i) decay of 18-22 min peak during Ca2+/phospholipase A2 treatment, with reciprocal appearance of fatty acid hydroperoxides; (ii) reduction of peroxide during treatment with reduced glutathione and phospholipid hydroperoxide glutathione peroxidase, but not glutathione peroxidase; and (iii) comigration with PCOOH standards in thin-layer chromatography. HPLC-EC analysis revealed quantifiable amounts of PCOOH and ChOOH at a light fluence that clonally inactivated < 10% of the cells, which allows for the possibility that photoperoxidative damage plays a causal role in cell killing.

Chromatographic separation and electrochemical determination of cholesterol hydroperoxides generated by photodynamic action.

Reverse-phase HPLC with electrochemical detection (HPLC-EC) was used to separate and quantitate photochemically generated cholesterol hydroperoxides. The EC measurements were performed in the reduction mode under anaerobic conditions. When cholesterol-containing liposomes were irradiated in the presence of a phthalocyanine dye, at least four major oxidation products of cholesterol were detected by HPLC-EC:5 alpha-hydroperoxide (5 alpha-OOH), 6 beta-hydroperoxide (6 beta-OOH), 7 alpha-hydroperoxide (7 alpha-OOH), and 7 beta-hydroperoxide (7 beta-OOH). The detection limit for each compound was found to be approximately 25 pmol. Product identification was based on matching HPLC and TLC behavior of standards and on physical indicators (melting points and NMR chemical shifts). The cholesterol hydroperoxides were barely separated from EC-silent diol derivatives, which could be detected by 210 nm absorbance after reduction of the hydroperoxides with triphenylphosphine. Irradiation of a dye-sensitized natural membrane, the human erythrocyte ghost, also resulted in formation of 5 alpha-OOH, 6-OOH, and 7-OOH, as evidenced by HPLC-EC. Under the chromatographic conditions used, these species were well separated not only from one another but also from a family of at least six phospholipid hydroperoxides. These results illustrate the strengths of HPLC-EC as a relatively convenient, sensitive, and selective means of analyzing cholesterol hydroperoxides in biological samples.