The biological effectiveness of radon-progeny alpha particles. IV. Morphological transformation of Syrian hamster embryo cells at low doses.

Primary explants of Syrian hamster embryo (SHE) cells were exposed to either low-LET 250 kVp X rays or graded single doses of defined high-LET alpha particles (90, 100, 120, 150, 180 and 200 keV/microns), simulating those produced by radon progeny, and monitored for cell inactivation and oncogenic transformation. For the alpha particles the doses delivered ranged from 1 cGy to 1 Gy with an emphasis on doses less than 20 cGy, while for the X rays the doses ranged from 20 cGy to 4 Gy. The dose-response curves for cell killing by alpha particles approximated an exponential function of dose, whereas the X rays produced a curve with a shoulder characteristic of linear-quadratic relationships seen for low-LET radiations. The RBE at 10% survival varied between 3.6-7.0 depending on the LET of the alpha particles, with the RBEm ranging between 7-12. The most effective alpha particles were those with an LET of 120 keV/microns. All radiations produced initial increases in the frequency of morphological transformants, as a function of dose, with a rise to a maximum followed by a plateau in the response which was relatively constant at approximately 2-6 x 10(-3) transformants frequency, expressed per initial cell at risk, had a tendency to decline to parallel the cell survival response. Both the dose at which the maximum frequency of transformants was expressed and the initial slope of the dose-response relationship differed substantially between the different radiation qualities. Maximal transformation per initial cell at risk occurred at doses as low as 1-4 cGy for the 90 and 100 keV/microns particles with the maximum occurring at higher doses (to 16 cGy) as the LET increased toward 200 keV/microns. In contrast, the maximal transformation for 250 kVp X rays was at 50 cGy. The 90 and 100 keV/microns particles, with an RBEm of 60 and 37, respectively, based on the ratios of the initial slopes of the dose-response curves, were the most effective LETs in terms of the ability to induce morphological transformation of SHE cells. When expressed in terms of particle fluence, it appears that in the LET range of radon progeny approximately two to four particle traversals per nucleus are required per killing event, whereas it is at doses corresponding to less than one particle per nucleus that maximal oncogenic transformation is expressed.(ABSTRACT TRUNCATED AT 400 WORDS)