Abstract

Time-resolved reductions in the light-scattering intensity (LSI) of aqueous oxic and anoxic solutions of poly-C and poly-U at pH 7.8, following pulse-irradiation, have been studied as indices of strand break formation. With doses of 3-24 Gy per pulse, a number of kinetically distinct strand breakage components have been detected. A comparison of the LSI responses obtained from irradiations conducted under N2O with those conducted under air or O2 show no marked difference in the overall extent of LSI change. However, the immediate and fast (t 1/2 less than or equal to 50 microseconds) reduction in LSI, accounting for about 18-19% of the pyrimidine polynucleotide's total LSI response in oxic solution, is reduced in the absence of oxygen, to about 12% of the total LSI response found with poly-C and to about 9% for poly-U. For poly-C there is a five-fold enhancement in the rate of major strand breakage under anoxia [k1(N2O) = 7.9s-1] whereas for poly-U a more modest enhancement (about two-fold) is observed. These enhanced rates are mirrored by those for the losses of the principal optical anoxic absorptions (observed pulse radiolytically) that are assigned to the pyrimidine 6-yl base radicals. Such findings support a proposal that the rate-limiting step of major strand breakage for pyrimidine polynucleotides is a base radical mediated hydrogen atom abstraction reaction (Lemaire et al. 1987, Hildenbrand and Schulte-Frohlinde 1989). Irradiation of poly-C and poly-U in N2O/O2 (4:1, v/v) saturated solutions yields LSI changes much larger than those noted under N2O and air (or O2), which are in turn approximately double the responses observed under N2. This indicates that the major strand breaking species of water radiolysis is the OH-radical and that there is an oxygen enhancement of single strand breakage of about 1.9 for poly-C and 1.6 for poly-U.

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