The Efficiency of DNA Strand-Break Repair in Two Fibrosarcoma Tumors and in Normal Tissues of Mice Irradiated in Vivo with X Rays

We have used alkaline elution to study the repair of X-ray-induced DNA strand breaks in vivo in two fibrosarcoma tumors and in several normal mouse tissues after whole-body irradiation of mice with 10-12.5 Gy of X rays. Both tumors were found to repair damage significantly faster and to a greater ex...

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Bibliographic Details
Published in:Radiation research 1984-10, Vol.100 (1), p.171-181
Main Authors: Murray, David, Jenkins, W. Timothy, Meyn, Raymond E.
Format: Article
Language:English
Subjects:
Animals
Biological and medical sciences
Biological effects of radiation
Cellular differentiation
CHO cells
DNA - radiation effects
DNA damage
DNA Repair
DNA, Neoplasm - radiation effects
Dose-Response Relationship, Radiation
Fibrosarcoma - genetics
Fibrosarcoma - radiotherapy
Fundamental and applied biological sciences. Psychology
Glutathione - physiology
Ionizing radiations
Irradiation
Kinetics
Lesions
Mice
Mice, Inbred C3H
Neoplasm Transplantation
Neurons
Radiation damage
Time Factors
Tissue repair
Tissues, organs and organisms biophysics
Tumors
Whole-Body Irradiation
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Summary:We have used alkaline elution to study the repair of X-ray-induced DNA strand breaks in vivo in two fibrosarcoma tumors and in several normal mouse tissues after whole-body irradiation of mice with 10-12.5 Gy of X rays. Both tumors were found to repair damage significantly faster and to a greater extent than any of the normal tissues, so that by 2 hr after irradiation the level of damage in both tumors was indistinguishable from unirradiated control values. Of the normal tissues studied, liver repaired the fastest. The kinetics for the other normal tissues were essentially the same, showing an appreciable level (7-16%) of unrepaired lesions still evident after 2 hr. Even as late as 12 hr there was a significant amount of residual damage in some tissues, with testes and spleen showing the greatest level (ca. 15%). The repair kinetics for each tissue were not appropriately described by a sum of two exponentials. In contrast, previously reported data for many homogeneous mammalian cell systems in vitro and for some tissues in vivo have shown biphasic repair kinetics. This difference may be related to heterogeneity of both cell type and environment within the tissue populations used in the investigation. The faster repair of DNA strand breaks by tumor cells relative to cells from normal tissues was not readily explainable in terms of such radiobiological parameters as overall tissue oxygenation or sulfhydryl content. Rather, it appears that the degree of differentiation of the cells within the tissue population may be a major determinant of repair proficiency. Based on a model incorporating a competition between repair and fixation of sublethal lesions, these data are consistent with the idea that tumor cells may have a repair, and hence survival, advantage over normal cells in response to ionizing radiation.
ISSN:0033-7587
1938-5404
DOI:10.2307/3576531