Cellular and tissue responses to heavy ions: Basic considerations

Summary Responses of the S/S variant of the L5178Y murine leukemic lymphoblast, the photoreceptor cell of the rabbit retina and the lenticular epithelium of the rabbit to heavy ions (²⁰Ne,²⁸Si,⁴⁰Ar and⁵⁶Fe) are described and discussed primarily from the standpoint of the need for a comprehensive theory of cellular radiosensitivity from which a general theory of tissue radiosensitivity can be constructed.The radiation responses of the very radiosensitive, repair-deficient S/S variant during the G₁- and early S phases of the cell cycle were found to be unlike those of normally radioresistant cells in culture: the relative biological effectiveness (RBE) did not increase with the linear energy transfer (LET) of the incident radiation. Such behavior could be anticipated for a cell which is lacking the repair system that operates in other (normal) cells when they are exposed to ionizing radiations in the G₁ phase of the cell cycle. The S/S variant does exhibit a peak of radioresistance to X-photons mid-G₁ + 8 h into the cell cycle, however, and as the LET was increased, the repair capacity responsible for that radioresistance was reduced progressively.Sensory cells (photoreceptors) in the retina of the New Zealand white (NZW) rabbit are very radioresistant to ionizing radiations, and several years elapsed after localized exposure (e.g., 5–10 Gy) to heavy ions (²⁰Ne,⁴⁰Ar) before photoreceptor cells were lost from the retina. During the first few weeks after such irradiations, damage to DNA in the photoreceptor cells was repaired to a point where it could not be demonstrated by reorienting gradient sedimentation under alkaline conditions, a technique that can detect DNA damage produced by <0.1 Gy of X-photons. Restitution of DNA structure was not permanent, however, and months or years later, butbefore loss of photoreceptor cells from the retina could be detected, progressive deterioration of the DNA structure began.