Interphase death of cells occurs physiologically in healthy animal tissues as well as in tissues pathologically injured by radiation or drugs. An active self-destruction process has been found to play a major role in the interphase death of highly radiosensitive cells. However, the mechanism of this radiation-induced interphase death in human lymphoma has not yet been studied in detail. In the present study, we examined a lymphoma derived from a child lymphoblastic lymphoma bearing CD1, CD4, and CD8 antigens and established in nude mice. Low-dose x-irradiation of this lymphoma induced interphase cell death with characteristic morphological and biological changes of an active self-destruction process, i.e., changes in cell surface appearance seen using scanning electron microscopy and nuclear fragmentation accompanied with an increase in free DNA. The process was proved to require protein synthesis. It was concluded that the radiosensitivity of this T-cell lymphoma of common thymic type is mainly due to the occurrence of the active self-destruction process.