Is repair of DNA strand break damage from ionizing radiation second-order rather than first-order? A simpler explanation of apparently multiexponential repair.

The purpose of this paper is to suggest the hypothesis that repair of radiation damage might be largely a second-order process (binary), as well as or instead of first-order (monoexponential). Second-order means that the rate of repair is proportional to n(2) instead of to n, where n is the number of repairable breaks. Integrating this equation gives a linear plot of the reciprocal proportion of unrepaired lesions, n(0)/n(t), as a function of repair time. This is in contrast to mono- or biexponential processes which give rise to reciprocal plots not consistent with such linearity, except with specially selected distributions with multiple T((1/2))'s. There is the advantage of only one parameter (the first half-time) instead of (2n - 1) parameters for n components. At times greater than 2tau of the longest exponential component, a larger proportion of damage would be incompletely repaired than in a mono- or biexponential model of repair. Data on DNA repair from published laboratory experiments were reanalyzed. Results are presented as graphs of the reciprocal of the proportion of damage remaining as a function of time after irradiation of DNA. If the second-order process is correct, these graphs should be straight lines, even though traditional semilog plots of the same data are markedly concave upward, showing the well-noted slowing down of repair with time after irradiation. All the data sets found in the literature showed a good fit to a straight line representing reciprocal repair. Repair of single-strand breaks in DNA fitted very well, from 1.0 down to 1/40 of the initial damage remaining, with tau values of 5-10 min. Repair of DSBs fitted almost as well. One set of data showed a strong dependence on temperature in the range 10-37 degrees C, with each curve fitting the straight reciprocal plot. The tau values for DSBs were 10-100 min, of similar magnitude to those for repair of animal tissues. The second-order process with a single time parameter could explain the data showing "apparently slowing down" repair previously analyzed by multiexponential formulae requiring more parameters. It appears that second-order repair may play a larger part in repair processes than has usually been assumed. It is suggested that analysis of data on repair of radiation-induced damage could test the second-order (one-parameter reciprocal) analysis, as well as using bi-or multiexponential analyses. If repair in DNA is relevant to recovery in mammalian tissues, there may be serious clinical implications, to be discussed elsewhere.

[1]  M. Joiner,et al.  Recovery kinetics of X-ray damage in mouse skin: the influence of dose per fraction. , 1991, International journal of radiation biology.

[2]  G. Iliakis,et al.  Effect of arabinofuranosyladenine on radiation-induced chromosome damage in plateau-phase CHO cells measured by premature chromosome condensation: implications for repair and fixation of alpha-PLD. , 1988, Radiation research.

[3]  M. Löbrich,et al.  Repair of x-ray-induced DNA double-strand breaks in specific Not I restriction fragments in human fibroblasts: joining of correct and incorrect ends. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[4]  Repair kinetics in mouse lung after multiple X-ray fractions per day. , 1988, International journal of radiation biology.

[5]  G. Iliakis,et al.  Kinetics of DNA double-strand break repair throughout the cell cycle as assayed by pulsed field gel electrophoresis in CHO cells. , 1991, International journal of radiation biology.

[6]  J. Dahm-Daphi,et al.  Comparison between the alkaline unwinding technique and neutral filter elution using CHO, V79 and EAT cells. , 1995, International journal of radiation biology.

[7]  J. Hopewell,et al.  The kinetics of repair for sublethal radiation-induced damage in the pig epidermis: an interpretation based on a fast and a slow component of repair. , 1992, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[8]  A. Ruifrok,et al.  Repair capacity and kinetics for human mucosa and epithelial tumors in the head and neck: clinical data on the effect of changing the time interval between multiple fractions per day in radiotherapy. , 1996, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[9]  R K Sachs,et al.  The link between low-LET dose-response relations and the underlying kinetics of damage production/repair/misrepair. , 1997, International journal of radiation biology.

[10]  K. Sax An Analysis of X-Ray Induced Chromosomal Aberrations in Tradescantia. , 1940, Genetics.

[11]  George Lliakis,et al.  The role of DNA double strand breaks in lonizing radiation‐induced killing of eukaryotic cells , 1991 .

[12]  E. Dikomey,et al.  DNA repair kinetics after exposure to X-irradiation and to internalβ-rays in CHO cells , 1986, Radiation and environmental biophysics.

[13]  Y. Ung,et al.  DNA double-strand break induction and rejoining as determinants of human tumour cell radiosensitivity. A pulsed-field gel electrophoresis study. , 1995, International journal of radiation biology.

[14]  S B Curtis,et al.  Lethal and potentially lethal lesions induced by radiation--a unified repair model. , 1986, Radiation research.

[15]  P. Deschavanne,et al.  A benchmark of cell survival models using survival curves for human cells after completion of repair of potentially lethal damage. , 1994, Radiation research.

[16]  H. Thames,et al.  Is the experience with CHART compatible with experimental data? A new model of repair kinetics and computer simulations. , 1992, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[17]  H. Thames,et al.  Recovery from radiation damage in mouse lung: interpretation in terms of two rates of repair. , 1993, Radiation research.

[18]  P. Lambin,et al.  Hypersensitivity to very-low single radiation doses: its relationship to the adaptive response and induced radioresistance. , 1996, Mutation research.

[19]  W. Hittelman,et al.  The relationship of DNA and chromosome damage to survival of synchronized X-irradiated L5178Y cells. II. Repair. , 1988, Radiation research.

[20]  E. Dikomey,et al.  Effect of heat on induction and repair of DNA strand breaks in X-irradiated CHO cells. , 1992, International journal of radiation biology.

[21]  H. Thames Repair kinetics in tissues: alternative models. , 1989, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[22]  H D Thames,et al.  Impact of spinal cord repair kinetics on the practice of altered fractionation schedules. , 1992, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[23]  A. J. van der Kogel,et al.  Biological equivalance of low dose rate to multifractionated high dose rate irradiations: investigations in mouse lip mucosa. , 1997, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[24]  K. Baverstock,et al.  Long-range energy transfer in DNA , 1988 .

[25]  J. Fowler,et al.  Kinetics of repair in the spinal cord of the rat. , 1997, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[26]  D. Frankenberg,et al.  Half-life values for DNA double-strand break rejoining in yeast can vary by more than an order of magnitude depending on the irradiation conditions. , 1994, International journal of radiation biology.

[27]  T. Kron,et al.  Acute reaction parameters for human oropharyngeal mucosa. , 1995, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[28]  H D Thames,et al.  Repair capacity and kinetics of human skin during fractionated radiotherapy: erythema, desquamation, and telangiectasia after 3 and 5 year's follow-up. , 1989, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[29]  M. Frankenberg-Schwager Review of repair kinetics for DNA damage induced in eukaryotic cells in vitro by ionizing radiation. , 1989, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[30]  H D Thames,et al.  An 'incomplete-repair' model for survival after fractionated and continuous irradiations. , 1985, International journal of radiation biology and related studies in physics, chemistry, and medicine.

[31]  C. A. Tobias,et al.  The repair-misrepair model of cell survival , 1980 .

[32]  R. Sachs,et al.  Misrejoining of double-strand breaks after X irradiation: relating moderate to very high doses by a Markov model. , 1998, Radiation research.

[33]  E. Dikomey,et al.  Saturated and unsaturated repair of DNA strand breaks in CHO cells after X-irradiation with doses ranging from 3 to 90 Gy. , 1993, International journal of radiation biology.

[34]  J. Fowler,et al.  A new incomplete-repair model based on a 'reciprocal-time' pattern of sublethal damage repair. , 1999, Acta oncologica.

[35]  P. Bryant,et al.  DNA repair kinetics after low doses of X-rays. A comparison of results obtained by the unwinding and nucleoid sedimentation methods. , 1984, Mutation research.

[36]  B. Fertil,et al.  A new model describing the curves for repair of both DNA double-strand breaks and chromosome damage. , 1996, Radiation research.

[37]  P. Hahnfeldt,et al.  Recent data obtained by pulsed-field gel electrophoresis suggest two types of double-strand breaks. , 1998, Radiation research.

[38]  H. Thames,et al.  The kinetics of repair in mouse lung after fractionated irradiation. , 1987, International journal of radiation biology and related studies in physics, chemistry, and medicine.

[39]  M. Stuschke,et al.  Repair of ionizing radiation induced DNA double-strand breaks (dsb) at the c-myc locus in comparison to the overall genome. , 1998, International journal of radiation biology.

[40]  J. Hopewell,et al.  Repair kinetics in pig epidermis: an analysis based on two separate rates of repair. , 1996, International journal of radiation biology.

[41]  G. Steel Recovery kinetics deduced from continuous low dose-rate experiments. , 1989, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[42]  J. Hopewell,et al.  Repair, repopulation and cell cycle redistribution in rat foot skin. , 1998, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[43]  J. Fowler X-ray induced conductivity in insulating materials , 1956, Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences.

[44]  D. Goodhead Saturable repair models of radiation action in mammalian cells. , 1985 .

[45]  E. Fielden,et al.  The effect of 5-bromouracil on energy transfer in DNA and related model systems: DNA with incorporated 5-BUdR. , 1971, Radiation research.

[46]  I. Radford Evidence for a general relationship between the induced level of DNA double-strand breakage and cell-killing after X-irradiation of mammalian cells. , 1986, International journal of radiation biology and related studies in physics, chemistry, and medicine.