Quantitation of Hydroxyl Radicals Produced by Radiation and Copper-Linked Oxidation of Ascorbate by 2-Deoxy-d-Ribose Method

We have established controlled conditions for studying the reaction of chemically and radiolytically produced hydroxyl radical (radical dotOH) with 2-deoxy-D-ribose (2-DR). Ascorbate (ASC) or dithiothreitol (DTT) and cuprous or cupric ions were used to generate the OH-radical. The OH-radical was detected using the classical method of measuring the amount of thiobarbituric acid reactive products (TBARP) formed by radical dotOH-mediated 2-DR degradation, but using sensitive fluorescent detection of the TBARP production to quantify the OH-radical. All experiments were performed with adequate O2 concentrations. The copper reaction with ASC consumes O2 in a manner that is strongly dependent on copper concentration, and less dependent on ascorbate concentration. For an independent check of the Cu2+ catalyzed ASC oxidation kinetics, the decay of ASC absorbency at 265 nm, as well as the increase of H2O2 absorbency at not, vert, similar240 nm, were also monitored. These spectral changes agree well with the O2 consumption data. TBARP production from 2-DR incubated with a Cu2+–ASC mixture or γ-irradiated were also compared. γ-Irradiation of 2-DR solutions shows a dose and 2-DR concentration dependent increase of TBARP generation. Other electron donors, such as DTT, are more complicated in their mechanism of OH-radical production. Incubation of 2-DR with Cu2+-DTT mixtures shows a delay (not, vert, similar50 min) before OH-radical generation is detected. Our results suggest that the Cu2+-ASC reaction can be used to mimic the effects of ionizing radiation with respect to OH-radical generation. The good reproducibility and relative simplicity of the 2-DR method with fluorescence detection indicates its usefulness for the quantitation of the OH-radical generated radiolytically or chemically in carefully controlled model systems. © 1997 Elsevier Science Inc.