Inhibition of potential lethal damage repair and related gene expression after carbon-ion beam irradiation to human lung cancer grown in nude mice.

Using cultured and nude mouse tumor cells (IA) derived from a human lung cancer, we previously demonstrated their radiosensitivity by focusing attention on the dynamics of tumor clonogens and the early and rapid survival recovery (potential lethal damage repair: PLD repair) occurring after X-ray irradiation. To the authors' knowledge, this is the first study demonstrating gene expression in association with PLD repair after carbon-ion beam or X-ray irradiation to cancer cells. In this study we tried to detect the mechanism of DNA damage and repair of the clonogens after X-ray or carbon-ion beam irradiation.

Gene expression profile changes correlating with radioresistance in human cell lines.

Purpose: To identify gene expression profiles specific to radioresistance of human cells.

Methods And Materials: Global gene expression profiles of a total of 15 tumor and normal fibroblast cell lines were analyzed using DNA microarrays and statistical clustering methods. Initially, six of the cell lines were categorized into radioresistant (RG) or nonradioresistant (NRG) groups according to the radiation dose required to reduce their survival to 10% (D10).

Radiosensitivity of hypoxic and proliferating clonogen in a human lung cancer grown in nude mice.

Using cultured and nude mouse tumor cells (IA) derived from a human lung cancer, we studied their radiosensitivity by focusing attention on the dynamics of tumor clonogens. The movement of clonogens in the regrowing IA tumor after irradiation can be divided into three phases: first, the early and rapid survival recovery (PLD repair) phase; second, the delay phase involving a certain lag in survival change; and third, the repopulation phase consisting of two stages: the anoxic repopulation before angiogenesis and the hypoxic repopulation in the presence of a poorly developed vascular network. Clonogens in a regrowing tumor after irradiation were found to actively proliferate even in an anoxic environment before angiogenesis and under the hypoxic conditions prevailing after the formation of a tumor with a poorly developed vascular system.

Potential in a single cancer cell to produce heterogeneous morphology, radiosensitivity and gene expression.

Morphologically heterogeneous colonies were formed from a cultured cell line (KYSE70) established from one human esophageal carcinoma tissue. Two subclones were separated from a single clone (clone13) of KYSE70 cells. One subclone (clone13-3G) formed mainly mounding colonies and the other (clone 13-6G) formed flat, diffusive colonies.