4-hydroxy-2-nonenal and ethyl-linoleate

In these studies, we demonstrate that N(2),3-ethenoguanine (N(2), 3-epsilonGua) is formed from lipid peroxidation as well as other oxidative reactions. Ethyl linoleate (EtLA) or 4-hydroxy-2-nonenal (HNE) was reacted with dGuo in the presence of tert-butyl hydroperoxide (t-BuOOH) for 72 h at 50 degrees C. The resulting N(2), 3-epsilonGua was characterized by liquid chromatography/electrospray mass spectroscopy and by gas chromatography/high-resolution mass spectral (GC/HRMS) analysis of its pentafluorobenzyl derivative following immunoaffinity chromatography purification. The amounts of N(2),3-epsilonGua formed were 825 +/- 20 and 1720 +/- 50 N(2), 3-epsilonGua adducts/10(6) normal dGuo bases for EtLA and HNE, respectively, corresponding to 38- and 82-fold increases in the amount of N(2),3-epsilonGua compared to controls containing only t-BuOOH. Controls containing t-BuOOH but no lipid resulted in a >1000-fold increase in the level of N(2),3-epsilonGua over dGuo that was not subjected to incubation. EtLA and HNE, in the presence of t-BuOOH, were reacted with calf thymus DNA at 37 degrees C for 89 h. The amounts of N(2),3-epsilonGua formed in intact ctDNA were 114 +/- 32 and 52.9 +/- 16.7 N(2),3-epsilonGua adducts/10(6) normal dGuo bases for EtLA and HNE, respectively. These compared to 2.02 +/- 0. 17 and 2.05 +/- 0.47 N(2),3-epsilonGua adducts/10(6) normal dGuo bases in control DNA incubated with t-BuOOH, but no lipid. [(13)C(18)]EtLA was reacted with dGuo to determine the extent of direct alkylation by lipid peroxidation byproducts. These reactions resulted in a 89-93% level of incorporation of the (13)C label into N(2),3-epsilonGua when EtLA and dGuo were in equimolar concentrations, when EtLA was in 10-fold molar excess, and when deoxyribose (thymidine) was in 10-fold molar excess. Similar reactions with ctDNA resulted in an 86% level of incorporation of the (13)C label. These data demonstrate that N(2),3-epsilonGua is formed from EtLA and HNE under peroxidizing conditions by direct alkylation. The data also suggest, however, that N(2),3-epsilonGua is also formed by an alternative mechanism that involves some other oxidative reaction which remains unclear.

Topics: Aldehydes; Animals; Cattle; Chromatography, High Pressure Liquid; DNA Adducts; Gas Chromatography-Mass Spectrometry; Guanosine; Linoleic Acids; Lipid Peroxidation; Mutagens

Ethyl linoleate, ethyl linolenate, ethyl arachidonate and cod liver oil were oxidized with Fenton's reagent. Acrolein, malonaldehyde and 4-hydroxynonenal formed were derivatized to N-methylpyrazoline, N-methylpyrazole and 5-(1'-hydroxyhexyl)-1-methyl-2-pyrazoline with N-methylhydrazine, respectively. The derivatives were simultaneously analysed by gas chromatograph equipped with a fused silica capillary column and a nitrogen-phosphorus detector. The maximum amounts of acrolein (9.7 +/- 2.11 nmol/ml) and malonaldehyde (61.18 +/- 6.51 nmol/ml) were formed from cod liver oil. The highest amount of 4-hydroxynonenal (6.83 +/- 0.53 nmol/ml) was produced from ethyl arathidonate.

Topics: Acrolein; Aldehydes; Arachidonic Acids; Chromatography, Gas; Cod Liver Oil; Cross-Linking Reagents; Hydrogen Peroxide; Iron; Linoleic Acids; Linolenic Acids; Lipid Peroxidation; Malondialdehyde; Oxidation-Reduction; Reference Standards