The Bystander Effect in Radiation Oncogenesis: I. Transformation in C3H 10T½ Cells In Vitro can be Initiated in the Unirradiated Neighbors of Irradiated Cells (original) (raw)

Sawant, S. G., Randers-Pehrson, G., Geard, C. R., Brenner, D. J. and Hall, E. J. The Bystander Effect in Radiation Oncogenesis: I. Transformation in C3H 10T½ Cells In Vitro can be Initiated in the Unirradiated Neighbors of Irradiated Cells.

It has long been accepted that radiation-induced genetic effects require that DNA be hit and damaged directly by the radiation. Recently, evidence has accumulated that in cell populations exposed to low doses of α particles, biological effects occur in a larger proportion of cells than are estimated to have been traversed by α particles. The end points observed include chromosome aberrations, mutations and gene expression. The development of a fast single-cell microbeam now makes it possible to expose a precisely known proportion of cells in a population to exactly defined numbers of α particles, and to assay for oncogenic transformation. The single-cell microbeam delivered no, one, two, four or eight α particles through the nuclei of all or just 10% of C3H 10T½ cells. We show that (a) more cells can be inactivated than were actually traversed by α particles and (b) when 10% of the cells on a dish are exposed to α particles, the resulting frequency of induced transformation is not less than that observed when every cell on the dish is exposed to the same number of α particles. These observations constitute evidence suggesting a bystander effect, i.e., that unirradiated cells are responding to damage induced in irradiated cells. This bystander effect in a biological system of relevance to carcinogenesis could have significant implications for risk estimation for low-dose radiation.