Peroxynitrite and protein tyrosine nitration of prostacyclin synthase

When working on the regulation of prostacyclin synthase (PGIS), we found that PGIS was selectively inhibited by peroxynitrite (ONOO-), a potent oxidant formed by the combination of superoxide anion and nitric oxide (NO) at a rate of diffusion-controlled. None of the cellular antioxidants studied (i.e. GSH, Vitamins C and E, and others) prevented the inhibition of ONOO- on PGIS. This unexpected behavior was explained by a catalytic reaction of the iron-thiolate center of PGIS with ONOO- anion. In contrast, ONOO- activated both thromboxane A2-synthase and cyclooxygenases. In addition, we demonstrated that sub-micromolar levels of ONOO- inhibited PGI2-dependent vasorelaxation and triggered a PGH2-dependent vasospasm, indicating that ONOO- increased PGH2 formation as a consequence of PGIS nitration. We have subsequently demonstrated that endogenous ONOO- caused PGIS nitration and TxA2 activation in several diseased conditions such as atherosclerotic vessels, hypoxia-reperfusion injury, cytokines-treated cells, diabetes, as well as hypertension. Since NO is produced physiologically it seems that excessive formation of superoxide not only eliminates the vasodilatory, growth-inhibiting, anti-thrombotic and anti-adhesive effects of NO and PGI2 but also allows and promotes an action of the potent vasoconstrictor, prothrombotic agent, growth promoter, and leukocyte adherer, PGH2. We conclude that the nitration of PGIS nitration might be a new pathogenic mechanism for superoxide-induced endothelium dysfunction often observed in vascular diseases such as atherosclerosis, hypertension, ischemia, endotoxic shock, and diabetes.     

Peroxynitrite mild nitration of albumin and LDL-albumin complex naturally present in plasma and tyrosine nitration rate-albumin impairs LDL nitration

In blood, peroxynitrite (ONOO- ) and CO2 react to form NO2* and CO3* through the short-lived adduct ONOOCO2-, leading to protein-bound tyrosine nitration. ONOO(-) -modified LDL is atherogenic. Oxidatively modified LDL generally appears in the vessel wall surrounded by antioxidants. Human serum albumin (HSA) is one of them, partly associated to LDL as a LDL-albumin complex (LAC). The purpose was to study the effect of a mild nitration on LAC and whether albumin may interfere with LDL nitration. To do so, SIN-1 was used as ONOO- generator in the presence or absence of 25 mM HCO3-. The human serum albumin (HSA)-bound tyrosine nitration rate was found to be 4.4 x 10(-3) mol/mol in the presence of HCO3-. HSA decreased the LAC-tyrosine nitration rate from 2.5 x 10(-3) to 0.6 x 10(-3) mol/mol. It was concluded that HSA impaired the apoB-bound tyrosine nitration. These findings raise the question of the patho-physiological significance of these nitrations and their interactions which may potentially prevent both atheromatous plaque formation and endothelium dysfunction in particular and appear to be beneficial in terms of atherogenic risk.     

Peroxynitrite generation and tyrosine nitration in defense responses in tobacco BY-2 cells

Peroxynitrite (ONOO(-)) is a compound formed by reaction of superoxide (O(2) (-)) with nitric oxide (NO) and is expected to possess characteristics of both O(2) (-) reactivity and NO mobility in order to function as a signal molecule. Although there are several reports that describe the role of ONOO(-) in defense responses in plants, it has been very difficult to detect ONOO(-) in bioimaging due to its short half-life or paucity of methods for ONOO(-)-specific detection among reactive oxygen species or free radicals. Aminophenyl fluorescein (APF), a recently developed novel fluorophore for direct detection of ONOO(-) in bioimaging, was used for intracellular ONOO(-) detection. ONOO(-) generation in tobacco BY-2 cells treated with INF1, the major elicitin secreted by the late blight pathogen Phytophthora infestans, occurred within 1 h and reached a maximum level at 6-12 h after INF1 treatment. Urate, a ONOO(-) scavenger, abolished INF1-induced ONOO(-) generation. It is well known that ONOO(-) reacts with tyrosine residues in proteins to form nitrotyrosine in a nitration reaction as an ONOO(-)-specific reaction. Western blot analysis using anti-nitrotyrosine antibodies recognized nitrotyrosine-containing proteins in 20 and 50 kDa bands in BY-2 protein extract containing SIN-1 [3-(4-morpholinyl) sydnonimine hydrochloride; an ONOO(-) donor]. These bands were also recognized in INF1-treated BY-2 cells and were found to be slightly suppressed by urate. Our study is the first to report ONOO(-) detection and tyrosine nitration in defense responses in plants.     

Peroxynitrite flux-mediated LDL oxidation is inhibited by manganese porphyrins in the presence of uric acid

We have studied the role of three Mn(III)porphyrins differing in charge, alkyl substituent length and reactivity, on LDL exposed to low fluxes of peroxynitrite (PN) in the presence of uric acid. Mn(III)porphyrins (5 microM, MnTE-2-PyP(5+), MnTnOct-2-PyP(5+), and MnTCPP(3-)) plus uric acid (300 microM) inhibited cholesteryl ester hydroperoxide formation, changes in REM as well as spared alpha- and gamma-tocopherol. MnTnOct-2-PyP(5+), the more lipophilic compound, was the most effective in protecting LDL lipids, while MnTCPP(3-) exerted the lesser protection. Mn(III)porphyrins react fast with PN ( approximately 10(5)-10(7) M(-1) s(-1)) to yield a O=Mn(IV) complex. The stoichiometry of uric acid consumption was approximately 1.7 moles per mol of PN, in agreement with reactions with both the O=Mn(IV) complex and nitrogen dioxide. A shift from an anti- to a pro-oxidant action of the Mn(III)porphyrin was observed after uric acid was significantly consumed, supporting competition reactions between LDL targets and uric acid for the O=Mn(IV) complex. Overall, the data is consistent with the catalytic reduction of PN in a cycle that involves a one electron oxidation of Mn(III) to Mn(IV) by PN followed by the reduction back to Mn(III) by uric acid. These antioxidant effects should predominate under in vivo conditions having plasma uric acid concentration range between 150 and 500 microM.     

Peroxynitrite affects exocytosis and SNARE complex formation and induces tyrosine nitration of synaptic proteins

The reactive species peroxynitrite, formed via the near diffusion-limited reaction of nitric oxide and superoxide anion, is a potent oxidant that contributes to tissue damage in neurodegenerative disorders. Peroxynitrite readily nitrates tyrosine residues in proteins, producing a permanent modification that can be immunologically detected. We have previously demonstrated that in the nerve terminal, nitrotyrosine immunoreactivity is primarily associated with synaptophysin. Here we identify two other presynaptic proteins nitrated by peroxynitrite, Munc-18 and SNAP25, both of which are involved in sequential steps leading to vesicle exocytosis. To investigate whether peroxynitrite affects vesicle exocytosis, we used the fluorescent dye FM1-43 to label a recycling population of secretory vesicles within the synaptosomes. Bolus addition of peroxynitrite stimulated exocytosis and glutamate release. Notably, these effects were strongly reduced in the presence of NaHCO(3), indicating that peroxynitrite acts mainly intracellularly. Furthermore, peroxynitrite enhanced the formation of the sodium dodecyl sulfate-resistant SNARE complex in a dose-dependent manner (100-1000 microm) and induced the formation of 3-nitrotyrosine in proteins of SNARE complex. These data suggest that modification(s) of synaptic vesicle proteins induced by peroxynitrite may affect protein-protein interactions in the docking/fusion steps, thus promoting exocytosis, and that, under excessive production of superoxide and nitric oxide, neurons may up-regulate neuronal signaling.     

Lack of tyrosine nitration by hypochlorous acid in the presence of physiological concentrations of nitrite. Implications for the role of nitryl chloride in tyrosine nitration in vivo

Elevated levels of reactive nitrogen species (RNS) such as peroxynitrite have been implicated in over 50 diverse human diseases as measured by the formation of the RNS biomarker 3-nitrotyrosine. Recently, an additional RNS was postulated to contribute to 3-nitrotyrosine formation in vivo; nitryl chloride formed from the reaction of nitrite and neutrophil myeloperoxidase-derived hypochlorous acid (HOCl). Whether nitryl chloride nitrates intracellular protein is unknown. Therefore, we exposed intact human HepG2 and SW1353 cells or cell lysates to HOCl and nitrite and examined each for 3-nitrotyrosine formation by: 1) Western blotting, 2) using a commercial 3-nitrotyrosine enzyme-linked immunosorbent assay kit, 3) flow cytometric analysis, and 4) confocal microscopic analysis. With each approach, no significant 3-nitrotyrosine formation was observed in either whole cells or cell lysates. However, substantial 3-nitrotyrosine was observed when peroxynitrite (100 microm) was added to cells or cell lysates. These data suggest that nitryl chloride formed from the reaction of nitrite with HOCl does not contribute to the elevated levels of 3-nitrotyrosine observed in human diseases.     

Mechanistic insight into the catalytic inhibition by nitroxides of tyrosine oxidation and nitration

BackgroundNitroxide antioxidants (RNO^•) protect from injuries associated with oxidative stress. Tyrosine residues in proteins are major targets for oxidizing species giving rise to irreversible cross-linking and protein nitration, but the mechanisms underlying the protective activity of RNO^• on these processes are not sufficiently clear.MethodsTyrosine oxidation by the oxoammonium cation (RN⁺=O) was studied by following the kinetics of RNO^• formation using EPR spectroscopy. Tyrosine oxidation and nitration were investigated using the peroxidase/H₂O₂ system without and with nitrite. The inhibitory effect of RNO^• on these processes was studied by following the kinetics of the evolved O₂ and accumulation of tyrosine oxidation and nitration products.ResultsTyrosine ion is readily oxidized by RN⁺=O, and the equilibrium constant of this reaction depends on RNO^• structure and reduction potential. RNO^• catalytically inhibits tyrosine oxidation and nitration since it scavenges both tyrosyl and ^•NO₂ radicals while recycling through RN⁺=O reduction by H₂O₂, tyrosine and nitrite. The inhibitory effect of nitroxide on tyrosine oxidation and nitration increases as its reduction potential decreases where the 6-membered ring nitroxides are better catalysts than the 5-membered ones.ConclusionsNitroxides catalytically inhibit tyrosine oxidation and nitration. The proposed reaction mechanism adequately fits the results explaining the dependence of the nitroxide inhibitory effect on its reduction potential and on the concentrations of the reducing species present in the system.General significanceNitroxides protect against both oxidative and nitrative damage. The proposed reaction mechanism further emphasizes the role of the reducing environment to the efficacy of these catalysts.     

Lactobacillus growth and membrane composition in the presence of linoleic or conjugated linoleic acid

Five Lactobacillus strains of intestinal and food origins were grown in MRS broth or milk containing various concentrations of linoleic acid or conjugated linoleic acid (CLA). The fatty acids had bacteriostatic, bacteriocidal, or no effect depending on bacterial strain, fatty acid concentration, fatty acid type, and growth medium. Both fatty acids displayed dose-dependent inhibition. All strains were inhibited to a greater extent by the fatty acids in broth than in milk. The CLA isomer mixture was less inhibitory than linoleic acid. Lactobacillus reuteri ATCC 55739, a strain capable of isomerizing linoleic acid to CLA, was the most inhibited strain by the presence of linoleic acid in broth or milk. In contrast, a member of the same species, L. reuteri ATCC 23272, was the least inhibited strain by linoleic acid and CLA. All strains increased membrane linoleic acid or CLA levels when grown with exogenous fatty acid. Lactobacillus reuteri ATCC 55739 had substantial CLA in the membrane when the growth medium was supplemented with linoleic acid. No association between level of fatty acid incorporation into the membrane and inhibition by that fatty acid was observed.     

Post-translational tyrosine nitration of eosinophil granule toxins mediated by eosinophil peroxidase

Nitration of tyrosine residues has been observed during various acute and chronic inflammatory diseases. However, the mechanism of tyrosine nitration and the nature of the proteins that become tyrosine nitrated during inflammation remain unclear. Here we show that eosinophils but not other cell types including neutrophils contain nitrotyrosine-positive proteins in specific granules. Furthermore, we demonstrate that the human eosinophil toxins, eosinophil peroxidase (EPO), major basic protein, eosinophil-derived neurotoxin (EDN) and eosinophil cationic protein (ECP), and the respective murine toxins, are post-translationally modified by nitration at tyrosine residues during cell maturation. High resolution affinity-mass spectrometry identified specific single nitration sites at Tyr349 in EPO and Tyr33 in both ECP and EDN. ECP and EDN crystal structures revealed and EPO structure modeling suggested that the nitrated tyrosine residues in the toxins are surface exposed. Studies in EPO(-/-), gp91phox(-/-), and NOS(-/-) mice revealed that tyrosine nitration of these toxins is mediated by EPO in the presence of hydrogen peroxide and minute amounts of NOx. Tyrosine nitration of eosinophil granule toxins occurs during maturation of eosinophils, independent of inflammation. These results provide evidence that post-translational tyrosine nitration is unique to eosinophils.     

Characterization of linoleic acid nitration in human blood plasma by mass spectrometry

Nitric oxide (*NO) is a pervasive free radical species that concentrates in lipophilic compartments to serve as a potent inhibitor of lipid and low-density lipoprotein oxidation processes. In this study, we synthesized, characterized, and detected nitrated derivatives of linoleic acid (18:2) in human blood plasma using high-pressure liquid chromatography coupled with electrospray ionization tandem mass spectrometry. While the reaction of nitronium tetrafluoroborate with 18:2 presented ions with a mass/charge (m/z) ratio of 324 in the negative ion mode, characteristic of nitrolinoleate (LNO(2)), the reaction of nitrite (NO(2)(-)) with linoleic acid hydroperoxide yielded nitrohydroxylinoleate (LNO(2)OH, m/z 340). Further analysis by MS/MS gave a major fragment at m/z 46, characteristic of a nitro group (-NO(2)) present in the parent ion. This was confirmed by using [(15)N]O(2), which gave products of m/z 325 and 341, that after fragmentation yielded a daughter ion at m/z 47. Moreover, a C-NO(2) structure was also demonstrated in LNO(2)OH by nuclear magnetic resonance spectroscopy ((15)N NMR, delta 375.9), as well as by infrared analysis in both LNO(2)OH (nu(max) = 3427, 1553, and 1374 cm(-1)) and LNO(2) (nu(max) = 1552 and 1373 cm(-1)). Stable products with m/z of 324 and 340, which possessed the same chromatographic characteristics and fragmentation pattern as synthesized standards, were found in human plasma of normolipidemic and hyperlipidemic donors. The presence of these novel nitrogen-containing oxidized lipid adducts in human plasma could represent "footprints" of the antioxidant action of *NO on lipid oxidation and/or a pro-oxidant and nitrating action of *NO-derived species.     

Chlorophyll destruction in the presence of bisulfite and linoleic acid hydroperoxide

Chlorophyll was rapidly destroyed in the presence of bisulfite and linoleic acid hydroperoxide. Both bisulfite and linoleic acid hydroperoxide were required for chlorophyll destruction and both were consumed in the reaction; however, there was no oxygen requirement. Chlorophyll destruction occurred most readily in the slightly acidic pH region with little destruction occurring above pH 8. The free radical scavengers, hydroquinone and α-tocopherol, were very effective at inhibiting chlorophyll destruction, but the singlet oxygen quenchers, β-carotene, 2,5-dimethylfuran and 1,3-diphenylisobenzofuran, were only slightly effective. The addition of metal chelators indicated that metals were not participating in the reaction. The evidence indicates that chlorophyll was destroyed by a free radical mechanism. Based on the present results and that of others, it is suggested that chlorophyll was destroyed via oxidation by the alkoxy radical which was produced during the decomposition of linoleic acid hydroperoxide by bisulfite.     

Paraoxonase-1 and linoleic acid oxidation in familial hypercholesterolemia

Serum paraoxonase-1 (PON1) is a high-density lipoprotein-associated enzyme that can inhibit low-density lipoprotein (LDL) oxidation in vitro. The role of PON1 in vivo still remains to be clarified. We investigated the effect of PON1 genotype (-107C > T and 192Q > R), concentration, paraoxonase activity, and arylesterase activity on the early phase of lipid peroxidation in plasma samples of 110 patients with heterozygous familial hypercholesterolemia. The degree of lipid oxidation was assessed by quantitation of oxidized-linoleic acid (the most abundant fatty acid present in LDL) using high performance liquid chromatography. We found a significant inverse correlation between paraoxonase activity and the oxidized-linoleic acid concentration (r = -0.22, P = 0.03), independent of baseline linoleic acid levels. These findings support an anti-oxidative role for PON1 in patients with FH, and thus may give insight into the functioning of PON1 in vivo.     

Peroxynitrite mediates TNF-alpha-induced endothelial barrier dysfunction and nitration of actin

We tested the hypothesis that tumor necrosis factor (TNF)-alpha induces a peroxynitrite (ONOO(-))-dependent increase in permeability of pulmonary microvessel endothelial monolayers (PMEM) that is associated with generation of nitrated beta-actin (NO(2)-beta-actin). The permeability of PMEM was assessed by the clearance rate of Evans blue-labeled albumin. beta-Actin was extracted from PMEM lysate with a DNase-Sepharose column. The extracted beta-actin was quantified in terms of its nitrotyrosine/beta-actin ratio with anti-nitrotyrosine and anti-beta-actin antibodies, sequentially, by dot-blot assays. The cellular compartmentalization of NO(2)-beta-actin was displayed by showing confocal localization of nitrotyrosine-immunofluorescence with beta-actin-immunofluorescence but not with F-actin fluorescence. Incubation of PMEM with TNF (100 ng/ml) for 0.5 and 4.0 h resulted in increases in permeability to albumin. There was an increase in the nitrotyrosine/beta-actin ratio at 0.5 h with minimal association of the NO(2)-beta-actin with F-actin polymers. The TNF-induced increase in the nitrotyrosine/beta-actin ratio and permeability were prevented by the anti-ONOO(-) agent Urate. The data indicate that TNF induces an ONOO(-)-dependent barrier dysfunction, which is associated with the generation of NO(2)-beta-actin.     

Peroxynitrite signaling in human erythrocytes: synergistic role of hemoglobin oxidation and band 3 tyrosine phosphorylation

Peroxynitrite crosses the red blood cell (RBC) membrane and reacts with hemoglobin (Hb) producing mainly metHb, which is reduced back to ferrousHb by NADH- and NADPH-dependent reductases. Peroxynitrite also induces band 3 (B3) tyrosine phosphorylation, a signaling pathway believed to activate glucose metabolism. This study was aimed to decipher the relationship between these two peroxynitrite-dependent processes. Peroxynitrite induced a burst of the hexose monophosphate shunt (HMS), revealed by NMR studies, and a burst of the glycolytic pathway, measured by lactate production. The HMS plays a prominent role in membrane signaling, as demonstrated by B3 phosphotyrosine inhibition by the glycolytic pathway inhibitor 2-deoxy-glucose (2DG) and activation by dehydroepiandrosterone (DHEA), an inhibitor of HMS. Peroxynitrite-induced B3 tyrosine phosphorylation was paralleled by the inhibition of membrane-associated phosphotyrosine phosphatase (PTP) activity, which was protected by 2DG but not DHEA. Interestingly, heme poisoning with CO inhibited peroxynitrite-dependent Hb oxidation and lactate production but did not affect PTP down regulation. These results suggest two distinct and concurrent effects of peroxynitrite: one mediated by Hb which, likely in its oxidized state, binds more strongly to B3, and another mediated by PTP-dependent B3 phosphorylation. Both effects are directed towards a surge in glucose utilization.     

Nitration and oxidation of a hydrophobic tyrosine probe by peroxynitrite in membranes: comparison with nitration and oxidation of tyrosine by peroxynitrite in aqueous solution.

It has been reported that peroxynitrite will initiate both oxidation and nitration of tyrosine, forming dityrosine and nitrotyrosine, respectively. We compared peroxynitrite-dependent oxidation and nitration of a hydrophobic tyrosine analogue in membranes and tyrosine in aqueous solution. Reactions were carried out in the presence of either bolus addition or slow infusion of peroxynitrite, and also using the simultaneous generation of superoxide and nitric oxide. Results indicate that the level of nitration of the hydrophobic tyrosyl probe located in a lipid bilayer was significantly greater than its level of oxidation to the corresponding dimer. During slow infusion of peroxynitrite, the level of nitration of the membrane-incorporated tyrosyl probe was greater than that of tyrosine in aqueous solution. Evidence for hydroxyl radical formation from decomposition of peroxynitrite in a dimethylformamide/water mixture was obtained by electron spin resonance spin trapping. Mechanisms for nitration of the tyrosyl probe in the membrane are discussed. We conclude that nitration but not oxidation of a tyrosyl probe by peroxynitrite is a predominant reaction in the membrane. Thus, the local environment of target tyrosine residues is an important factor governing its propensity to undergo nitration in the presence of peroxynitrite. This work provides a new perspective on selective nitration of membrane-incorporated tyrosine analogues.     

Protein tyrosine nitration in the cell cycle

Nitration of tyrosine residues in proteins is associated with cell response to oxidative/nitrosative stress. Tyrosine nitration is relatively low abundant post-translational modification that may affect protein functions. Little is known about the extent of protein tyrosine nitration in cells during progression through the cell cycle. Here we report identification of proteins enriched for tyrosine nitration in cells synchronized in G0/G1, S or G2/M phases of the cell cycle. We identified 27 proteins in cells synchronized in G0/G1 phase, 37 proteins in S phase synchronized cells, and 12 proteins related to G2/M phase. Nineteen of the identified proteins were previously described as regulators of cell proliferation. Thus, our data indicate which tyrosine nitrated proteins may affect regulation of the cell cycle.     

Exploring the molecular basis of human manganese superoxide dismutase inactivation mediated by tyrosine 34 nitration

Manganese Superoxide Dismutase (MnSOD) is an essential mitochondrial antioxidant enzyme that protects organisms against oxidative damage, dismutating superoxide radical () into H₂O₂ and O₂. The active site of the protein presents a Mn ion in a distorted trigonal–bipyramidal environment, coordinated by H26, H74, H163, D159 and one ⁻OH ion or H₂O molecule. The catalytic cycle of the enzyme is a “ping-pong” mechanism involving Mn³⁺/Mn²⁺. It is known that nitration of Y34 is responsible for enzyme inactivation, and that this protein oxidative modification is found in tissues undergoing inflammatory and degenerative processes. However, the molecular basis about MnSOD tyrosine nitration affects the protein catalytic function is mostly unknown.In this work we strongly suggest, using computer simulation tools, that Y34 nitration affects protein function by restricting ligand access to the active site. In particular, deprotonation of 3-nitrotyrosine increases drastically the energetic barrier for ligand entry due to the absence of the proton.Our results for the WT and selected mutant proteins confirm that the phenolic moiety of Y34 plays a key role in assisting superoxide migration.     

Calcium-translocating and cardiotonic properties of oxidation products of linoleic acid

Calcium-translocating activity of linoleic acid and its lipoxygenase (linoleate: oxygen oxidoreductase; EC 1.13.11.12) metabolites or autoxidation products was determined in vitro by estimation of 45Ca transport from a bulk aqueous to a bulk organic phase. Fresh commercial linoleic acid, tested immediately after removal from a sealed vial, stimulated calcium translocation only at concentrations greater than 1 mM. In contrast, 45Ca translocation by linoleic acid exposed to air was detectable at 10 microM. Oxidation products of linoleic acid obtained either by incubation with lipoxygenase or by autoxidation were much less potent than the calcium ionophore A23187. The products obtained by enzymic oxidation of linoleic acid enhanced contractility in the Langendorff-perfused guinea pig heart up to 45% over control (at 3 X 10(-8) M). The inotropic response was transient with rapid onset and not affected by the beta-adrenergic antagonist, propranolol. The autoxidation products of linoleic acid increased cardiac contractility up to 43% at 10(-6) M. In contrast, fresh linoleic acid caused only a negative inotropic effect at 10(-8) to 3 X 10(-7) M, progressing to contracture at 10(-6) M. These findings suggest that conflicting reports on the cardiostimulant effect of linoleic acid may be due to varying levels of the autoxidation products. Linoleic acid metabolites in vivo may have a physiological role in myocardial function related to their Ca2+-ionophoric activity.     

Isomerization increases the postprandial oxidation of linoleic acid but not alpha-linolenic acid in men

Human lipid intake contains various amounts of trans fatty acids. Refined vegetable and frying oils, rich in linoleic acid and/or alpha-linolenic acid, are the main dietary sources of trans-18:2 and trans-18:3 fatty acids. The aim of the present study was to compare the oxidation of linoleic acid, alpha-linolenic acid, and their major trans isomers in human volunteers. For that purpose, TG, each containing two molecules of [1-(13)C]linoleic acid, alpha-[1-(13)C]linolenic acid, [1-(13)C]-9cis,12trans-18:2, or [1-(13)C]-9cis,12cis,15trans-18:3, were synthesized. Eight healthy young men ingested labeled TG mixed with 30 g of olive oil. Total CO(2) production and (13)CO(2) excretion were determined over 48 h. The pattern of oxidation was similar for the four fatty acids, with a peak at 8 h and a return to baseline at 24 h. Cumulative oxidation over 8 h of linoleic acid, 9cis,12trans-18:2, alpha-linolenic acid, and 9cis,12cis,15trans-18:3 were, respectively, 14.0 +/- 4.1%, 24.7 +/- 6.7%, 23.6 +/- 3.3%, and 23.4 +/- 3.7% of the oral load, showing that isomerization increases the postprandial oxidation of linoleic acid but not alpha-linolenic acid in men.