Mononuclear phagocytes play a central role in the pathogenesis of chronic inflammatory diseases. It is therefore important to define chemotherapeutically exploitable metabolic pathways that distinguish monocytes from other cell types. Blood monocytes do not synthesize deoxynucleotides de novo, and their transformation to macrophages occurs without cell division. Whether or not monocytes can repair DNA damage, and whether or not DNA repair is necessary for their survival, is unknown. The present experiments demonstrate that normal human monocytes, unlike neutrophils, rapidly repair DNA strand breaks induced by gamma-irradiation. Monocyte extracts contain functional immunoreactive DNA polymerase-alpha. DNA repair synthesis in normal monocytes is blocked by aphidicolin, an inhibitor of DNA polymerase-alpha with respect to dCTP. Aphidicolin is also directly toxic to normal monocytes, but has no effect on nondividing lymphocytes or fibroblasts. Compared to most other cell types, monocytes and macrophages have very low dCTP pools, but abundant deoxycytidine kinase activity. This suggests that dCTP derived from salvage pathways is important for DNA repair in these cells. Consistent with this notion, exogenous deoxycytidine could partially protect monocytes from aphidicolin killing. The unexpected toxicity of aphidicolin toward normal human monocytes may be attributable to their high rate of spontaneous DNA strand break formation, to the importance of DNA polymerase-alpha for DNA repair in these cells, and to their minute dCTP pools.