Antony M. Hooker

The Linear No-Threshold Model does not Hold for Low-Dose Ionizing Radiation

Abstract Hooker, A. M., Bhat, M., Day, T. K., Lane, J. M., Swinburne, S. J., Morley, A. A. and Sykes, P. J. The Linear No-Threshold Model does not Hold for Low-Dose Ionizing Radiation. Radiat. Res. 162, 447–452 (2004). Almost all of the data on the biological effects of ionizing radiation come from studies of high doses. However, the human population is unlikely to be exposed to such doses. Regulatory limits for radiation exposure are based on the linear no-threshold model, which predicts that the relationship between biological effects and radiation dose is linear, and that any dose has some effect. Chromosomal changes are an important effect of ionizing radiation because of their role in carcinogenesis. Here we exposed pKZ1 mice to single whole-body X-radiation doses as low as 1 μGy. We observed three different phases of response: (1) an induction of inversions at ultra-low doses, (2) a reduction below endogenous inversion frequency at low doses, and (3) an induction of inversions again at higher doses. These results do not fit a linear no-threshold model, and they may have implications for the way in which regulatory standards are presently set and for understanding radiation effects.

Adaptive response for chromosomal inversions in pKZ1 mouse prostate induced by low doses of X radiation delivered after a high dose

Abstract Day, T. K., Zeng, G., Hooker, A. M., Bhat, M., Scott, B. R., Turner, D. R. and Sykes, P. J. Adaptive Response for Chromosomal Inversions in pKZ1 Mouse Prostate Induced by Low Doses of X Radiation Delivered after a High Dose. Radiat. Res. 167, 682–692 (2007). Adaptive responses are induced by stress such as X radiation and result in a lower than expected biological response. Two-dose adaptive response experiments typically involve a low priming dose followed by a subsequent high radiation dose. Here, we used a sensitive in vivo chromosomal inversion assay to demonstrate for the first time an adaptive response when a low dose (0.01–1 mGy) was given several hours after a high 1000-mGy radiation dose. The adaptive responses in this study were of similar magnitude to the two-dose adaptive responses previously observed in this test system when the low dose was given first. A chromosomal inversion adaptive response was also induced by two 1000-mGy doses and when a 1-mGy dose was preceded or followed by a dose of 0.01 mGy, but not by two 4000-mGy doses. This is also the first example of an adaptive response when both doses are low. Our data agree with previous reports of an on-off mechanism of adaptive response. The induction of an adaptive response by a low dose after a high damaging dose provides evidence that the mechanisms underlying radiation adaptive responses are not due to prevention of damage induced by the high dose but to modulation of the cellular response to this damage.

Extremely Low Priming Doses of X Radiation Induce an Adaptive Response for Chromosomal Inversions in pKZ1 Mouse Prostate

Abstract Day, T. K., Zeng, G., Hooker, A. M., Bhat, M., Scott, B. R., Turner, D. R. and Sykes, P. J. Extremely Low Priming Doses of X Radiation Induce an Adaptive Response for Chromosomal Inversions in pKZ1 Mouse Prostate. Radiat. Res. 166, 757– 766 (2006). An adaptive response is a response to a stress such as radiation exposure that results in a lower than expected biological response. We describe an adaptive response to X radiation in mouse prostate using the pKZ1 chromosomal inversion assay. pKZ1 mice were treated with a priming dose of 0.001, 0.01, 1 or 10 mGy followed 4 h later by a 1000-mGy challenge dose. All priming doses caused a similar reduction in inversions compared to the 1000-mGy group, supporting the hypothesis that the adaptive response is the result of an on/off mechanism. The adaptive response was induced by a priming dose of 0.001 mGy, which is three orders of magnitude lower than has been reported previously. The adaptive responses completely protected against the inversions that would have been induced by a single 1000-mGy dose as well as against a proportion of spontaneous background inversions. The distribution of inversions across prostate gland cross sections after priming plus challenge irradiation suggested that adaptive responses were predominantly due to reduced low-dose radiation-induced inversions rather than to reduced high-dose radiation-induced inversions. This study used radiation doses relevant to human exposure.

Effect of exposure to 900 MHz radiofrequency radiation on intrachromosomal recombination in pKZ1 mice

Abstract Sykes, P. J., McCallum, B. D., Bangay, M. J., Hooker, A. M. and Morley, A. A. Effect of Exposure to 900 MHz Radiofrequency Radiation on Intrachromosomal Recombination in pKZ1 Mice. Radiat. Res. 156, 495–502 (2001). Radiofrequency (RF) radiation emitted from mobile phones is not considered to be directly genotoxic, but it may have downstream effects on cellular DNA. We studied the effect of 4 W/kg pulsed 900 MHz RF radiation on somatic intrachromosomal recombination in the spleen in the pKZ1 recombination mutagenesis model. Somatic intrachromosomal recombination inversion events were detected in spleen tissue of pKZ1 mice by histochemical staining for E. coli β-galactosidase protein in cells in which the lacZ transgene has undergone an inversion event. pKZ1 mice were exposed daily for 30 min to plane-wave fields of 900 MHz with a pulse repetition frequency of 217 Hz and a pulse width of 0.6 ms for 1, 5 or 25 days. Three days after the last exposure, spleen sections were screened for DNA inversion events. There was no significant difference between the control and treated groups in the 1- and 5-day exposure groups, but there was a significant reduction in inversions below the spontaneous frequency in the 25-day exposure group. This observation suggests that exposure to RF radiation can lead to a perturbation in recombination frequency which may have implications for recombination repair of DNA. The biological significance of a reduction below the spontaneous frequency is not known. The number of mice in each treatment group in this study was small (n = 10 or n = 20). Therefore, repetition of this study with a larger number of animals is required to confirm these observations.

Induction of somatic intrachromosomal recombination inversion events by cyclophosphamide in a transgenic mouse model

Somatic intrachromosomal recombination (SICR) can result in chromosomal inversion and deletion, mechanisms which are important in carcinogenesis. We have utilised a transgenic mouse model to study SICR inversion events in spleen cells. The transgenic construct is designed so that expression of an Escherichia coli lacZ transgene only occurs in a cell when an SICR inversion event occurs in the region of the transgene. The inversion events can then be detected by histochemical staining of frozen spleen sections for transgene expression and by polymerase chain reaction across the inversion breakpoints. The spontaneous inversion frequency in spleen rose 2-fold from 1.54 +/- 0.24 x 10(-4) (mean +/- SE) in 4-month-old transgenic mice to 3.12 +/- 0.67 x 10(-4) in 22-month-old mice. Four- or 8-month-old mice were treated with a single intraperitoneal injection of cyclophosphamide, with doses ranging from 0.01 to 100 mg/kg. The animals were killed 3 days after treatment. A significant induction of SICR inversions was detected at all doses with a 3.2-fold maximum induction of inversions detected at 10 mg/kg. These results suggest that the transgenic mouse model used here may be a sensitive model for studying the role of SICR in mutation and in studying risk assessment of environmental DNA-damaging agents.

Inversion due to intrachromosomal recombination produced by carcinogens in a transgenic mouse model

Somatic intrachromosomal recombination (SICR) can result in inversions and deletions in the DNA. pKZ1 mice possess an Escherichia coli (E. coli) lacZ transgene which is only expressed after a DNA inversion involving the transgene occurs. The E. coli beta-galactosidase protein can then be detected in frozen tissue sections using a chromogenic substrate. Therefore, pKZ1 mice can be used to detect SICR inversion events in vivo in different tissues. We have tested the pKZ1 mouse for its potential as a general mutagenesis model for detecting SICR in spleen in response to carcinogens which have widely different mechanisms of genotoxicity. Animals were given a single exposure of carcinogen and spleen cells were examined 3 days later for inversion events by histochemical staining of tissue sections. Mitomycin C, X-irradiation, etoposide and methylene chloride caused significant induction of inversion events in spleen tissue, ranging from 1.6- to 4.2-fold induction with the doses used here. This is the first time that inversion events induced by these carcinogens have been specifically studied in vivo in a mouse model and the findings expand the repertoire of mutation events known to be caused by these agents. We suggest that the pKZ1 mouse can be used as a general mutagenesis model for detection of SICR events and is likely to be a useful model for studying the mechanism of SICR in response to DNA damaging agents.

Dose-dependent increase or decrease of somatic intrachromosomal recombination produced by etoposide

Chromosomal inversions and deletions can occur via somatic intrachromosomal recombination (SICR), a mechanism known to be important in mutagenesis and carcinogenesis. Here, we demonstrate a dose-dependent increase or decrease in SICR inversion frequency both in vivo and in vitro after treatment with etoposide, using the pKZ1 mouse mutagenesis model. pKZ1 mice received a single intraperitoneal injection of etoposide dose ranging from 0.0005 to 50mg/kg. Animals were sacrificed 3 days after treatment and the spleen was analysed for SICR. A significant 1.4-3.1-fold induction of SICR inversion events was detected in pKZ1 mice after treatment with etoposide doses ranging from 0.05 to 50 mg/kg etoposide. However, inversion frequencies after treatment with 0.0005 and 0.005 mg/kg etoposide decreased significantly to 0.67 and 0.43 of the levels observed in control animals, respectively. A pKZ1 mouse hybridoma cell line was exposed to etoposide (1-1000 nM) and a similar pattern of SICR response to that detected in vivo was observed. A significant 2.3-4.6-fold induction of SICR inversions was observed in pKZ1 cells treated with 100 and 1000 nM etoposide. Inversion frequencies after treatment with 1 and 10nM etoposide decreased significantly to 0.31 and 0.5 of the level observed in control cell lines. Our in vitro studies complement our in vivo studies and exclude a kinetic phenomenon as the responsible mechanism of reduction in SICR in response to low dose etoposide. Determination of the exact mechanism and significance of recombination suppression at low doses of etoposide treatment requires further investigation.

Low dose X-radiation adaptive response in spleen and prostate of Atm knockout heterozygous mice.

Purpose: To investigate the effect of being heterozygous for a knockout mutation in the ataxia telangiectasia (Atm) gene on radiation adaptive response. Materials and methods: DNA recombination, as measured by pKZ1 inversion frequency, was quantified by histochemistry in Atm knockout heterozygous prostate and spleen 3 days after treatment with a priming dose of 0.01 or 10 mGy X-radiation 4 h prior to a challenge dose of 1000 mGy. Results: In spleen and prostate, a single dose of 0.01 mGy caused an induction in inversion frequency but a dose of 10 mGy prevented the induction of a proportion of endogenous inversions. Both doses induced an adaptive response, of similar magnitude, to a subsequent high challenge dose for chromosomal inversions in both spleen and prostate. The adaptive response completely prevented the induction of inversions from a 1000 mGy challenge dose and also a proportion of endogenous inversions. The adaptive responses and distribution of inversions across gland cross-sections observed here in Atm knockout heterozygote prostate were similar to those induced in Atm wild-type prostate in a previous study. Conclusions: Being heterozygous for a knockout mutation in the Atm gene does not affect the endogenous pKZ1 inversion frequency, the inversion response to single low radiation doses used here, or the induction of a radiation adaptive response for inversions in pKZ1 mouse spleen or prostate.

Extremely Low Doses of X-Radiation Can Induce Adaptive Responses in Mouse Prostate

The pKZ1 mouse chromosomal inversion assay is the only assay that has detected modulation of a mutagenic endpoint after single whole body X-irradiation with doses lower than 1 mGy. A non-linear dose response for chromosomal inversion has been observed in spleen and prostate between 0.001 mGy and 10 mGy, with doses between 0.005–0.01 mGy causing an increase in inversions and doses between 1–10 mGy causing a reduction below spontaneous inversion frequency. An adaptive response is a decreased biological effect induced by a low radiation dose. Adaptive responses contradict the linear-no-threshold model of risk estimation. We demonstrated that very low (0.001 mGy, 0.01 mGy, 1 mGy and 10 mGy) doses of X-radiation induced a chromosomal inversion adaptive response as measured by a reduction in the frequency of subsequent high dose (1000 mGy) induced inversions in prostate. These are the lowest X-radiation doses reported to induce an adaptive response for any endpoint. Adaptive response experiments were also performed where the high dose was administered four hours prior to a low dose of 0.01 mGy or 10 mGy. In both cases an adaptive response was observed. Identification of the modifying factors involved in the adaptive response may provide candidates for radioprotection.

The PKZ1 Recombination Mutation Assay: A Sensitive Assay for Low Dose Studies

The majority of mutation studies are performed at high doses of DNA damaging agents due to the insensitivity of most mutation assays. Extrapolation using a linear no-threshold (LNT) dose response model is then used to estimate the extent of possible DNA damage at lower doses. There is increasing evidence to suggest that the LNT model may not be correct at low doses of at least some DNA damaging agents. The pKZ1 in vivo and in vitro recombination assays have proven to be very sensitive for detection of changes in chromosomal inversion in lymphoid tissue in response to low doses of DNA damaging agents. Non-linear dose response curves for chromosomal inversion as an end-point have been identified at low doses of DNA damaging agents using this assay. Here, we review the inversion results obtained to date with the pKZ1 assays and discuss their suitability for low dose studies.