Some of the properties of cellular iron species which react with H 2 O 2 to cause DNA single-strand breaks in HL-60 cells were characterized in control cells and in cells made deficient of iron using 4,7-phenylsulfonyl-1,10-phenanthroline (bathophenanthroline disulfonic acid or BPS) and ascorbate. Single-strand breaks were measured using alkaline elution of DNA of cells treated at 4 o to minimize repair during treatment. Strand breakage in the presence of 10% serum was only 40% of that in the absence of serum. This effect was traced to reaction of H 2 O 2 with metals, most likely iron, in serum. Dimethyl sulfoxide (Me 2 SO) inhibited a maximum of 65% of breaks in control cells. The diffusion distance from the site of generation of hydroxyl radicals to the site of reaction with DNA for the Me 2 SO-inhibitable fraction was 6.9 nm. There was no significant alteration in the fraction of Me 2 SO-inhibitable strand breaks or in diffusion distance in iron-deficient cells, though total strand breaks decreased by 70%. When the effect of extracellular iron in serum was taken into account, 60 μM orthophenanthroline (OP) inhibited a maximum of 85% of strand breaks. In cells pretreated with 60 μM OP, the Me 2 SO-inhibitable fraction of the remaining strand breaks decreased to 32%, while the diffusion distance decreased to 4.1 nm. These data indicate the existence of a number of different iron species, as characterized by overlapping but not coincidental inhibition by OP and Me 2 SO, and by differing diffusion distances.