Because radon and its progeny (referred to collectively here as radon) emit alpha particles with a wide range of energies, as well as beta particles and gamma-rays, it is important to quantitate the relationship between initial damage induced by radon and that by acute low-LET radiation. We have evaluated dose-response relationships for induction of micronuclei both in vivo and in vitro following exposure to radon or 60Co. To determine if isolation procedures altered the cells' responsiveness to 60Co gamma-ray exposures, animals were exposed before cell isolation, or cells were isolated and then exposed. The data were described by linear dose-response functions and were not significantly different when the radiation exposure was in vivo or in vitro (respectively micronuclei/1000 binucleated cells = 1.6 +/- 6.5 + 62 +/- 2.7 D; micronuclei/1000 binucleated cells = 15.4 +/- 26.0 + 54.6 +/- 11.4 D, where D is in Gy). Primary rat lung fibroblasts (RLF) or Chinese hamster ovary (CHO-K1) cells were exposed in vitro to either radon or 60Co gamma-rays. Radon was 10.9 +/- 2.6 and 12.5 +/- 2.4 times as effective per Gy of radiation dose in producing micronuclei as was 60Co in RLF and CHO-K1 cells respectively. To determine the relative biological effectiveness of in vivo radon exposure, animals were exposed to either radon or 60Co, and lung fibroblasts were isolated and evaluated for radiation-induced micronuclei. In vivo radon exposure was 10.6 +/- 1.0 times as effective as acute whole-body 60Co exposure in producing micronuclei in lung fibroblasts. Different cell lines and exposure conditions resulted in similar effectiveness factors. Such ratios help evaluate the biological damage, hazard and risk associated with radon inhalation.