The mechanism of oleic acid nitration by *NO(2).

Fatty acid nitration is a recently discovered process that generates biologically active nitro lipids; however, its mechanism has not been fully characterized. For example, some structural details such as vinyl and allyl isomers of the nitro fatty acids have not been established. To characterize lipids that originated from a biomimetic reaction of *NO(2) with oleic acid, we synthesized several isomers of nitro oleic acids and studied their chromatography and mass spectra by various techniques of mass spectrometry. LC/MS analysis performed on a high resolution micro column detected molecular carboxylic anions of various oleic acid nitro isomers (NO(2)OA). Esterification of NO(2)OA with pentafluorobenzyl bromide and diisopropylethylamine as a catalyst produced a unique isoxazole ester derivative exclusively from allyl NO(2)OA isomers via dehydration of the nitro group at ambient temperatures. This new analytical procedure revealed that *NO(2) generated two vinyl and two allyl isomers of NO(2)OA. The vinyl isomers showed high regioselectivity with the 1.8:1 preference for the 10-NO(2)OA isomer that was absent among allylic isomers. The nitration also generated elaidic acid via cis-trans isomerization and diatereoisomers of vicinal nitro hydroxy, nitro keto and alpha-nitro epoxy stearic acids with high stereo and regioselectivity. Nitration of small unilamelar phospholipid vesicles resulted in several phospholipids containing nitro lipids and elaidic acid amenable to hydrolysis by phospholipase A(2).

Cytochrome P450/NADPH-dependent biosynthesis of 5,6-trans-epoxyeicosatrienoic acid from 5,6-trans-arachidonic acid.

5,6-trans-AA (5,6-TAA, where TAA stands for trans-arachidonic acid) is a recently identified trans fatty acid that originates from the cis-trans isomerization of AA initiated by the NO2 radical. This trans fatty acid has been detected in blood circulation and we suggested that it functions as a lipid mediator of the toxic effects of NO2. To understand its role as a lipid mediator, we studied the metabolism of 5,6-TAA by liver microsomes stimulated with NADPH. Profiling of metabolites by liquid chromatography/MS revealed a complex mixture of oxidized products among which were four epoxides, their respective hydrolysis products (dihydroxyeicosatrienoic acids), and several HETEs (hydroxyeicosatetraenoic acids) resulting from allylic, bis-allylic and (omega-1)/(omega-2) hydroxylations. We found that the C5-C6 trans bond competed with the three cis bonds for oxidative metabolism mediated by CYP (cytochrome P450) epoxygenase and hydroxylase. This was evidenced by the detection of 5,6-trans-EET (where EET stands for epoxyeicosatrienoic acid), 5,6-erythro-dihydroxyeicosatrienoic acid and an isomer of 5-HETE. A standard of 5,6-trans-EET obtained by iodolactonization of 5,6-TAA was used for the unequivocal identification of the unique microsomal epoxide in which the oxirane ring was of trans configuration. Additional lipid products originated from the metabolism involving the cis bonds and thus these metabolites had the trans C5-C6 bond. The 5,6-trans-isomers of 18- and 19-HETE were likely to be products of the CYP2E1, because a neutralizing antibody partially inhibited their formation without having an effect on the formation of the epoxides. Our study revealed a novel pathway of microsomal oxidative metabolism of a trans fatty acid in which both cis and trans bonds participated. Of particular significance is the detection of the trans-epoxide of AA, which may be involved in the metabolic activation of such trans fatty acids and probably contribute to their biological activity. Unlike its cis-isomer, 5,6-trans-EET was significantly more stable and resisted microsomal hydrolysis and conjugation with glutathione catalysed by hepatic glutathione S-transferase.

5E, 8Z, 11Z, 14Z-eicosatetraenoic acid, a novel trans isomer of arachidonic acid, causes G1 phase arrest and induces apoptosis of HL-60 cells.

Trans arachidonic acid isomers (trans-AA) constitute a new group of trans fatty acids (trans-FA) generated in vivo via endogenous cis-trans isomerization stimulated by the NO2 radical. Because both NO2 and trans-FA have been implicated as causative factors in cancer, we studied the effect of the trans-AA isomers on proliferation and viability of human promyelocytic (HL-60) cells. The four trans arachidonic (trans-AA) acid isomers synthesized by us have been presently tested with respect to their competence to affect the proliferation and viability of human promyeolocytic HL-60 cells in culture. The data demonstrate that one of the isomers, 5,6-trans-AA, showed distinct activity by targeting cell progression through the cell cycle and inducing apoptosis. The effects were time- and concentration-dependent: the cytostatic effect of 5E-AA was observed at 10 microM following 72 h of treatment. This effect was manifested as a perturbation of cell progression through G1 phase, indicating the 'on' activation of the G1 checkpoint as evidenced by the flow- and laser scanning-cytometry techniques. Apoptotic cells were identified by comparison of their morphology, DNA fragmentation, caspase activation and collapse of mitochondrial potential with control cells. These observations suggested that 5E-AA induced a mitochondrial pathway of apoptosis. There was no evidence of cell-cycle phase specificity in induction of apoptosis by 5E-AA, as the cells showing highly fragmented DNA or caspase-3 activation were distributed in all phases of the cycle. The data suggest that 5E-AA may have at least two targets: one that is cell-cycle specific and associated with the observed arrest in the G1 phase and another, unrelated to the cell cycle, which is responsible for triggering apoptosis indiscriminately, regardless of cycle phase I.

Stereospecific synthesis and mass spectrometry of 5,6-trans-epoxy-8Z,11Z,14Z-eicosatrienoic acid.

A novel, facile synthesis of 5,6-trans-epoxyeicosatrienoic acid (5,6-trans-EET) from 5,6-trans-arachidonic acid by iodolactonization and alkaline de-iodation is described along with characterization by mass spectrometry (LC-MS, negative ions) and NMR and comparison with 5,6-cis-EET.

Cytochrome P450/NADPH-dependent formation of trans epoxides from trans-arachidonic acids.

Trans-arachidonic acids (trans-AA) are products of cis-trans isomerization of arachidonic acid by nitrogen dioxide radical (NO(2)), and occur in vivo, but their metabolism is unknown. We found that hepatic microsomes oxidized trans-AA via cytochrome P450/NADPH system to epoxides, which were hydrolyzed by epoxide hydrolase to diols (DiHETEs). 14,15-trans-AA produced one erythro diol and three threo diols each having one trans double bond.