The effect of 125I decay at different stages of S-phase on survival, expression of micronuclei and chromosome aberrations in CHO cells

References

• BARENDSEN, G. W., 1994, The relationship between RBE and LET for different types of lethal damage in mamma-lian cell: Biophysical and molecular mechanisms. Radiation Research, 139, 257–270.
   PubMed Web of Science ®Google Scholar
• BILL, C. A., GROCHAN, B. M., VRDOLJAK, E., MENDOZA, E. A., and TOFILON, P. J., 1992, Decreased repair of radiation-induced DNA double-strand breaks with cellular differentiation. Radiation Research, 132, 254–258.
   PubMed Web of Science ®Google Scholar
• BREWEN, J. G., and STETKA, D. G., 1982, Cytogenetic events in vivo. In: Mutagenecity: New Horizons in Genetic Toxicology. Edited by: J. A. Heddle (New York: Academic Press, Inc.), pp. 351–384.
   Google Scholar
• BRYANT, P. E., 1984, Enzymatic restriction of mammalian cell DNA using Rvu II and BamH1: Evidence for the double-strand break origin of chromosomal aberrations. International Journal of Radiation Biology, 46, 57–65.
   Web of Science ®Google Scholar
• CHADWICK, K. H., and LEENHOUTS, H. P., 1978, The rejoining of DNA double-strand breaks and a model for the forma-tion of the chromosomal rearrangements. International Journal of Radiation Biology, 33, 517–529.
   Web of Science ®Google Scholar
• CHADWICK, K. H., and LEENHOHTS, H. P., 1981, The Molecular Theory of Radiation Biology. (Berlin, Heidelberg, New York: Springer-Verlag).
   Google Scholar
• CHARLTON, D. E., 1986, The range of high LET effects from 1251 decays. Radiation Research, 107, 163–171.
   PubMed Web of Science ®Google Scholar
• CHARLTON, D. E., and Humm, J. L., 1988, A method of calcu-lating DNA strand breakage following the decay of incorporated 1251. International Journal of Radiation Biology, 53, 353–365.
   Web of Science ®Google Scholar
• COOK, P. R., 1994, RNA polymerase, structural determinant of the chromatin loop and the chromosome. BioEssays, 16, 425–430.
   PubMedGoogle Scholar
• DENEKAMP, J., WITHMORE, G. F., and JEGGO, P., 1989, Biphasic survival curves for XRS radiosensitive cells: subpopula-tions or transient expression of repair competence. International Journal of Radiation Biology, 55, 605–617.
   PubMed Web of Science ®Google Scholar
• DOWNES, C. S., and WILKINS, A. S., 1994, Cell cycle checkpoints, DNA repair and DNA replication strategies. BioEssays, 16, 75–79.
   PubMedGoogle Scholar
• ELIA, M. C., and BRADLEY, M. 0., 1992, Influence of chromatin structure on the induction of DNA double strand breaks by ionizing radiation. Cancer Research, 52, 1580–1586.
   Google Scholar
• EVANS, H. J., 1962, Chromosome aberrations induced by ionizing radiations. International Review of Cytology, 13, 221–321.
   Web of Science ®Google Scholar
• GOODHEAD, D. T., 1994, Initial events in the cellular effects of ionizing radiations: clustered damage in DNA. Inter-national Journal of Radiation Biology, 65, 7–17.
   PubMed Web of Science ®Google Scholar
• GRIFFIN, C. S., HARVEY, A. N., and SAVAGE, J. R. K., 1994, Chromatid damage induced by 238PU a-particles in G2 and S phase Chinese hamster V79 cells. International Journal of Radiation Biology, 66, 85–98.
   PubMed Web of Science ®Google Scholar
• HARTLEIN, M. W., and PRESTON, R. J., 1985, An explanation of interspesific differences to X-ray-induced chromosome aberrations and a consideration of dose-response curves. Mutation Research, 150, 299–305.
   PubMedGoogle Scholar
• HOFER, K. G., VAN LOON, N., SCHNEIDERMAN, M. H., and CHARLTON, D. E., 1991, High and low-LET cytocidal effects of DNA-associated iodine-125. In: Biophysical Aspects of Auger Processes. Edited by: R. W. Howell, V. R. Narra, K. S. R. Sastry and D. V. Rao, American Association of Physicists in Medicine, Symposium Pro-ceedings No. 8 (Woodbury: American Institute of Physics, Inc., Woodbury), pp. 227–248.
   Google Scholar
• HOFER, K. R., VAN LOON, N., SCHNEIDERMAN, M. H., and CHARLTON, D. E., 1992, The paradoxical nature of DNA damage and cell death induced by 1251 decay. Radiation Research, 131, 121–124.
   Google Scholar
• HOFER, K. G., VAN LOON, N., SCHNEIDERMAN, M. H., and DALRYMPLE, G. V., 1993, Targets for radiation-induced cell death: target replication during the cell cycle evaluated in cells exposed to X-rays or 1251 decays. International Journal of Radiation Biology, 64, 205–216.
   PubMed Web of Science ®Google Scholar
• HOFER, K. G., and BAO, S. P., 1995, Low-LET and high-LET radiation action of 1251 decays in DNA: Effect of cysteamine on micronucleus formation and cell killing. Radiation Research, 141, 183–192.
   PubMed Web of Science ®Google Scholar
• HOWELL, R. W., RAO, D. V., Hou, D.-Y, NARRA, V. R., and SASTRY, K. S. R., 1991, The question of relative biological effectiveness and quality factor for Auger emitters incorporated in proliferating mammalian cells. Radia-tion Research, 128, 282–292.
   Google Scholar
• Rums, G., and CHUVASH, R., 1990, Radiosensitivity throughout the cell cycle and repair of potentially lethal damage and DNA double-strand breaks in an X-ray-sensitive CHO mutant. International Journal of Radiation Biology, 57, 1195–1211.
   PubMedGoogle Scholar
• RIAKIS, G., PANTELIAS, G. E., ORAYASU, R., and SEANE RR., 1987, 125IdUrd-induced chromosome fragments, assayed by premature chromosome condensation, and DNA double-strand breaks have similar repair kinetics in GI-phase CHO cells. International Journal of Radiation Biology, 52, 705–722.
   Google Scholar
• JOHNSTON, P. J., and BRYANT, P. E., 1994, A component of DNA double-strand break is dependent on the spatial orien-tation of the lesions within the higher-order structures of chromatin. International Journal of Radiation Biology, 66, 531–536.
   PubMed Web of Science ®Google Scholar
• KASSIS, A. I., FAD, F., KINSEY, B. M., SASTRY, K. S. R., TAUBE, R. A., and ADELSTEIN, S. J., 1987a, Radiotoxicity of 1251 in mammalian cells. Radiation Research, 111, 305–318.
   PubMed Web of Science ®Google Scholar
• KASSIS, A. I., SASTRY, K. S. R., and ADELSTEIN, S. J., 1987b, Kinetics of uptake, retention, and radiotoxicity of 125IUdR in mammalian cells: implications of localized energy deposition by Auger processes. Radiation Research, 109, 78–89.
   PubMed Web of Science ®Google Scholar
• LEA, D. E., 1955, Actions of Radiations on Living Cells (Cam-bridge: Cambridge University Press).
   Google Scholar
• LEMOTTE, P. K., and LITTLE, J. B., 1984, DNA damage induced in human diploid cells by decay of incorporated radionuclides. Cancer Research, 44, 1337–1342.
   PubMed Web of Science ®Google Scholar
• LuDwiKów, G., LuDwmów, F., and JOHANSON, K. J., 1992, Kinetics of micronucleus induction by 125I-labelled thyroid hormone in hormone-responsive cells. International Journal of Radiation Biology, 61, 639–653.
   PubMed Web of Science ®Google Scholar
• LuDwiKów, G., LuDwiKów, F., and JOHANSON, K. J., 1994, Kinetics of micronuclei induced by 125IdU in cells of two lines. Radiation Research, 138, 70–78.
   PubMedGoogle Scholar
• MAErv, A., MCKENNA, W. G., and MUSCHEL, R. J., 1994, The molecular basis for cell cycle delays following ionizing radiation: a review. Radiotherapy and Oncology, 31, 1–13.
   PubMedGoogle Scholar
• MAKRIGIORGOS, G. M., ADELSTEIN, S. J., and KASSIS, A. I., 1990, Auger electron emitters: Insights gained from in vitro experiments. Radiation and Environmental Biophysics, 29, 75–91.
   PubMed Web of Science ®Google Scholar
• MANDERS, E. M. M., STAP, J., BRAKENHOFF, G. J., VAN DRIEL, R., and ATEN, J. A., 1992, Dynamics of three-dimensional repli-cation patterns during the S-phase, analysed by double labelling of DNA and confocal microscopy. Journal of Cell Science, 103, 857–862.
   Google Scholar
• MARPLES, B., JOINER, M. C., and SEov, K. A., 1994, The effect of oxygen on low-dose hypersensitivity and increased radioresistance in Chinese hamster V79-379A cells. Radiation Research, 138, S17—S20.
   Google Scholar
• MARTIN, R. F., and HASELTINE, W. A., 1981, Range of radio-chemical damage to DNA with decay of iodine-125. Science, 213, 896–898.
   PubMed Web of Science ®Google Scholar
• MURRA) V., and MARTIN, R. F., 1988, Sequence specificity of 125I-labelled Hoechst 33258 damage in six closely related DNA sequences. Journal of Molecular Biology, 203, 63–73.
   PubMedGoogle Scholar
• NATARAJAN, A. T., 1990, Chromosomal aberrations from radia-tion-induced DNA lesions. In: Trends in Chromosome Research. Edited by: T. Sharma (Berlin: Springer-Verlag, Norosa Publishing House), pp. 119–124.
   Google Scholar
• OLEINICK, N. L., and CHIU, S.-M., 1992, Chromatin and nuclear structural factors which modify the radiosensitivity of DNA. In: Radiation Research: A Twentieth-Century Perspec-tive. Vol. II. Congress Proceedings. Edited by: W. C. Dewey, M. Edington, R.J. M. Fry, E. J. Hall and G. F. Whitmore (San Diego, New York, Boston, London, Sydney, Tokyo, Toronto: Academic Press Inc., Harcourt Brace Jovano-vich Publishers), pp. 149–154.
   Google Scholar
• OLIVE, P. L., 1992, DNA organization affects cellular radio- sensitivity and detection of initial DNA strand breaks. International Journal of Radiation Biology, 62, 389-396. PRISE, K. M., 1994, Use of radiation quality as a probe for DNA lesion complexity. International Journal of Radiation Biology, 65, 43–48.
   Google Scholar
• RADFORD, I. R. and HODGSON, G. S. 1985, 125I-induced DNA double-strand breaks: Use in the calibration of the filter elution technique and comparison with x-ray induced breaks. International Journal of Radiation Biology, 48, 555–566.
   Web of Science ®Google Scholar
• RESNICK, M. A., 1976, The repair of double-strand breaks in DNA: A model involving recombination. Journal of Theoretical Biology, 59, 97–106.
   PubMed Web of Science ®Google Scholar
• RESNICK, M. A., BENNET, C., PERKINS, E., PORTER, G., and PRIEBE, S. D., 1995, Double-strand breaks and recombinational repair: The role of processing, signalling and DNA homology. In: The Yeasts. Vol. 6, Yeast Genetics, 2nd edition. Edited by: A. E. Wheals, A. H. Rose and J. S. Harrison (London, San Diego, New York, Boston, Sydney, Tokyo, Toronto: Academic Press Ltd, Har-Court Brace 8c Company Publishers), pp. 357–410.
   Google Scholar
• REVELL, S. H., 1983, Relationships between chromosome damage and cell death. In: Radiation-Induced Chromo-some Damage in Man. Edited by: T. Ishihara and M. S. Sasaki (New York: Alan R. Liss, Inc.), pp. 215–233.
   Google Scholar
• SACHS, R. K., and BRENNER, D. J., 1993, Effect of LET on chromosomal aberration yields. I. Do long-lived, exchange-prone double strand breaks play a role? International Journal of Radiation Biology, 64, 677–688.
   Google Scholar
• SAVAGE, J. R. K., 1988, The production of chromosome structural changes by radiation: an update of Lea (1946), Chapter VI. British Journal of Radiology, 62, 507–520.
   Google Scholar
• SAVAGE, J. R. K., CAWOOD, A. H., and PAPWORTH, D. G., 1983, The disparity between homologous chromosomes during DNA replication. Journal of Theoretical Biology, 100, 631 — 643.
   Google Scholar
• SCHNEIDERMAN, M. H., and HOFER, K. G., 1980, The target for radiation-induced cell cycle delay. Radiation Research, 84, 462–476.
   PubMed Web of Science ®Google Scholar
• SCHNEIDERMAN, M. H., HOFER, K. G., and SCHNEIDERMAN, G. S., 1988, Cell cycle progression after selective irradiation of DNA during the cell cycle. Radiation Research, 116, 283–291.
   PubMed Web of Science ®Google Scholar
• SHINOHARA, A., and OGAWA, T., 1995, Homologous recombina-tion and the role of double-strand breaks. Trends in Biochemical Sciences, 20, 387–391.
   PubMed Web of Science ®Google Scholar
• SKARSGARD, L. D., SKWARCHUK, M. W., and WOUTERS, B. G., 1994, The survival of asynchronous V79 cells at low radiation doses: modeling the response of mixed cell populations. Radiation Research, 138, S72 —S75.
   Google Scholar
• SKWARCHUK, M. W., WOUTERS, B. G., and SKARSGARD, L. D., 1993, Substructure in the radiation survival response at low dose: asynchronous and partially synchronised V79-WRNE cells. International Journal of Radiation Biology, 64, 601–612.
   PubMed Web of Science ®Google Scholar
• STACKHOUSE, M. A., and BEDFORD, J. S., 1994, An ionizing radiation-sensitive mutant of CHO cells: irs-20. III. Chromosome aberrations, DNA breaks and mitotic delay. International Journal of Radiation Biology, 65, 571–582.
   PubMed Web of Science ®Google Scholar
• SZOSTAK, W. J., ORR-WEAVER, T. L., and ROTHSTEIN, R. J., 1983, The double-strand-break repair model for recombination. Cell, 33, 25–35.
   Google Scholar
• VOGELSTEIN, B., PARDOLL, D. M., and COFFEY, D. S., 1980, Super-coiled loops and eucaryotic DNA replication. Cell, 22, 79–85.
   PubMed Web of Science ®Google Scholar
• WARTERS, R. L., 1993, Persistence of radiation-induced double- strand breaks in the DNA of heated CHO cells. Inter-national Journal of Radiation Biology, 64, 669–676.
   PubMed Web of Science ®Google Scholar
• WARTERS, R. L., and Roll Komi L., 1982, Hyperthermia and the cell nucleus. Radiation Research, 92, 458–462.
   Google Scholar
• WOLF, S., 1968, Chromosome aberrations and the cell cycle. Radiation Research, 33, 609–619.
   PubMedGoogle Scholar
• WONG, R. S. L., and DEWEY W. C., 1982, Molecular studies on the hyperthermic inhibition of DNA synthesis in Chinese hamster ovary cells. Radiation Research, 92, 370–395.
   Google Scholar
• WOUTERS, B. G., and SKARSGARD, L. D., 1994, The response of a human tumor cell line to low radiation doses: evidence of enhanced sensitivity. Radiation Research, 138, S76—S80.
   Google Scholar
• XUE, L.-Y, FRIEDMAN, N. L., CHEINICK, N. L., and CHIU, S.-M., 1994, Induction of DNA damage in y-irradiated nuclei stripped of nuclear protein classes: differential mod-ulation of double-strand break and DNA-protein cross-link formation. International Journal of Radiation Biology, 66, 11–21.
   PubMed Web of Science ®Google Scholar
• YAsui, L. S., FINK, T. J., and ENRIQUE, A. M., 1994, Nuclear scaffold organization in the X-ray sensitive Chinese hamster mutant cell line, xrs-5. International Journal of Radiation Biology, 65, 185–192.
   PubMed Web of Science ®Google Scholar
• YAsui, L. S., PASCHOA, A. S., WARTERS, R. L., and HOFER, K. G., 1988, Cytotoxicity of 1251 decay produced lesions in chromatin. In: DNA Damage by Auger Emitters. Edited by: K. F. Baverstock and D. E. Charlton (London, New York, Philadelphia: Taylor 8c Francis), pp. 181–189.
   Google Scholar