Background:. Deoxyribonucleotide radicals resulting from formal C1'-hydrogen atom abstraction are important reactive intermediates in a variety of DNA-damage processes. The reactivity of these radicals can be affected by the agents that generate them and the environment in which they are produced. As an initial step in determining the factors that control the reactivity of these important radical species, we developed a mild method for their generation at a defined site within a biopolymer. Results:. Irradiation of oligonucleotides containing a photolabile nucleotide produced C1'-DNA radicals. In the absence of potential reactants other than O2, approximately 90% of the damage events involve formation of alkaline-labile lesions, with the remainder resulting in direct strand breaks. The ratio of alkaline-labile lesions to direct strand breaks ( approximately 9:1) is independent of whether the radical is generated in single-stranded DNA or double-stranded DNA. Strand damage is almost completely quenched under anaerobic conditions in the presence of low thiol concentrations. Competition studies with O2 indicate that the trapping rate of C1'-DNA radicals by beta-mercaptoethanol is approximately 1.1 x 10(7) M-1 s-1. Conclusions:. The mild generation of the C1'-DNA radical in the absence of exogenous oxidants makes it possible to examine their intrinsic reactivity. In the absence of other reactants, the formation of direct strand breaks from C1'-radicals is, at most, a minor pathway. Competition studies between beta-mercaptoethanol and O2 indicate that significantly higher thiol concentrations than those in vivo or some means of increasing the effective thiol concentration near DNA are needed for these reagents to prevent the formation of DNA lesions arising from the C1'-radical under aerobic conditions.
5,6-Dihydrothymid-5-yl (4) is generated via Norrish
type I cleavage of isopropyl ketone 7. Ketone 7
was
site specifically incorporated into chemically synthesized
polythymidylates and an oligonucleotide containing all
four native deoxyribonucleotides. No damage is induced in
oligonucleotides containing 7 upon photolysis
under
anaerobic conditions. In the presence of O2, strand
breaks and alkaline labile lesions are formed at the original
site
of 7, and at nucleotides adjacent to the 5‘-phosphate of
7. Kinetic isotope effect experiments reveal that
direct
strand scission at the thymidine adjacent to the 5‘-phosphate of
4 arises from C1‘ hydrogen atom abstraction.
The
observed KIE (∼3.9) is attributed to hydrogen atom abstraction from
C1‘ by the peroxyl radical 35 derived from
4.
Enzymatic end group analysis and measurement of free base release
are consistent with a process involving C1‘
hydrogen atom abstraction. Cleavage experiments carried out in the
presence of t-BuOH (1.05 M) and NaN3
(10
mM) indicate that damage does not result from hydroxyl radical, but
that 1O2 is responsible for a significant
amount
of the observed strand damage.
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