Enzymatic superoxide-dismutase activity is believed to be important in defense against the toxic effects of superoxide. Although superoxide dismutases are among the best studied proteins, numerous questions remain concerning the specific biological roles of the various superoxide-dismutase types. In part, this is because the proposed damaging effects of superoxide are manifold, ranging from inactivation of certain metabolic enzymes to DNA damage. Studies with superoxide-deficient mutants have proven valuable, but surprisingly few such studies have been reported. We have constructed and characterized Neurospora crassa mutants that are null for sod-1, the gene that encodes copper-zinc superoxide dismutase. Mutant strains are sensitive to paraquat and elevated oxygen concentrations, and they exhibit an increased spontaneous mutation rate. They appear to have near wild-type sensitive to near- and far-UV, heat shock and gamma-irradiation. Unlike the equivalent Saccharomyces cerevisiae mutant and the sodA sodB double mutant of Escherichia coli, they do not exhibit aerobic auxotrophy. These results are discussed in the context of an attempt to identify consensus phenotypes among superoxide dismutase-deficient mutants. N. crassa sod-1 null mutant strains were also employed in genetic and subcellular fractionation studies. Results support the hypothesis that a single gene (sod-1), located between Fsr-12 and leu-3 on linkage group I, is responsible for most or all CuZn superoxide dismutase activity in this organism.