An ESR investigation of the individual DNA base radicals produced by gamma-irradiation of frozen solutions of the nucleotides TMP, dCMP, dGMP and dAMP and their reactions with cysteamine upon annealing is reported. The results show that water radicals in bulk ice do not lead to the formation of DNA or cysteamine radicals. Radicals from the oxidation pathway which include the DNA base one electron oxidized radicals and their successors, G(C8)OH., A(C8)OH. and thymine dimers (.Tdi) and/or T(C6)OH; readily react with cysteamine to form RS. and ultimately RSSR-. Reactions of dGMP and dCMP radicals from the oxidation pathway with cysteamine occur at lower temperatures than those of dAMP and TMP, suggesting hole migration. Both T(C6)H. and C(N3)H. react with cysteamine to form RS. and diamagnetic products, but G(C8)H. and A(C8)H. do not. Subtraction of the anion radical T-. and its proton adduct T(C6)H. from the total radical yield of TMP (with or without cysteamine) suggests that somewhat less than half of the total TMP radicals found are a result of the oxidative pathway. Similar results are found in the other nucleotides. The total spectral intensity derived from the radicals from the oxidative pathway such as G(C8)OH., A(C8)OH. and .Tdi/T(C6)OH. are somewhat less than that for the protonated anion radicals. Only one non-base radical is identified, a sugar radical at the C(1)' site on the deoxyribose portion of dAMP. This species, S(A)., is also found to react with cysteamine or its disulfide radical anion. Analyses performed in the presence and absence of a thiol are found to allow for a clear separation of oxidative and reductive pathways.