Abstract
This paper reviews our current knowledge of the mechanisms underlying the induction of bystander effects by low dose, low-LET ionizing radiation and discusses how they may be related to observed adaptive responses or other protective effects of low dose exposures. Bystander effects appear to be the result of a generalized stress response in tissues or cells. The signals may be produced by all exposed cells, but the response appears to require a quorum in order to be expressed. The major response involving low LET radiation exposure discussed in the existing literature is a death response. This has many characteristics of apoptosis but is p53 independent. While a death response might appear to be adverse, the position is argued in this paper that it is in fact protective and removes damaged cells from the population. Since many cell populations carry damaged cells without being exposed to radiation, so called “background damage”, it is possible that low doses exposures cause removal of cells damaged by agents other than the test dose of radiation. This mechanism would lead to the production of “U-shaped” dose response curves. In this scenario, the level of “adaptive” or beneficial response will be related to the background damage carried by the cell population. This model may be important when attempting to predict the consequences of mixed exposures involving radiation and other environmental stressors.
I. INTRODUCTION
Radiation-induced bystander signals appear to coordinate cellular responses even in cells not directly exposed or traversed by radiation. This work has led to a paradigm shift in radiobiology over the last 5–10 years1–4. Prior to this, it was held that DNA double strand breaks and cellular survival/damage were inextricably linked and that radiation damage could be defined as a function of DNA double strand breaks. This is now being challenged because of an increasing number of studies that demonstrate indirect (i.e., non-DNA related) effects and coordinated tissue responses5. These appear to saturate at low doses and lead to a breakdown of the dose response relationship that dominates at high doses6, 7. The low dose mechanisms may mitigate or exacerbate the direct effects of the dose and dominate the results at doses below 0.5 Gy7, 8. Signal production has been detected at doses as low as 5 mGy, although at these doses the recipient cell may transduce the signal in a different way9. Current conventional models of radiation dose response do not accommodate these new findings and as long as the mechanisms remain unclear, modelling low dose effects is difficult and uncertainty is high.
While there is obvious interest in general in this field, the key applications are likely to be in radiation protection and biotechnology. A novel mechanism for coordination of tissue responses is clearly being induced by radiation and probably by other substances. This offers new avenues for development of drugs aimed not at cell destruction but at restoring the tissues own control and coordination of response following DNA damage.
II. BYSTANDER EFFECTS AND ADAPTIVE RESPONSES
Many of the newly recognized effects are similar to systemic stress or innate immune responses, in that there is no simple relationship between exposure and effect, and the outcome is not obviously dependent on dose or number of cells hit by radiation10–13. Mitochondria and reactive oxygen species appear to be important to the coordination and regulation of these effects14–17. So far, research by our group and by others has suggested that radiation causes hit cells to produce signals, which can be received by cells close to or distant from the targeted cell18–23. The recipient cells transduce the signals and appear to coordinate an appropriate (by definition ADAPTIVE) response. Responses recorded to date include initiation of apoptosis, differentiation or proliferation13, 24–26. These coordinated responses can be protective as, for example, an apoptotic response can remove an abnormal cell from the population, but the response can also involve fixation of mutations, induction of genomic instability or cellular transformation as pre-malignant responses. Which response predominates appears to depend on genetic and environmental influences and not to be related to dose27, 28.
III. WHAT ARE THE SIGNALING MECHANISMS?
The nature of the signal(s) is (are) unknown, although the properties are becoming clearer. Much of the phenomenological data are suggestive of a very small (less than 1000 dalton) (lipo) peptide molecule or biogenic amine, but it is also possible to argue for long-lived radicals leading to peroxide or aldehyde release from cells22, 29–31. The mechanisms by which the cells coordinate their responses are also unknown, but signaling which leads to persistently increased ROS and modulation of biochemical pathways in mitochondria (particularly HMP shunt) have been demonstrated15, 32–34.
IV. MODELS TO STUDY BYSTANDER EFFECTS
Many in vitro models to study these effects have been developed. These can involve irradiation using low doses of high or low LET radiation using microbeams or low fluences of alpha particles, where not all cells in the field are hit by a radiation traversal. Effects are looked for in “un-hit” cells35–40. A simple medium transfer protocol, which enables low dose, low LET radiation effects to be studied, has also been published by our own group41–42. This work has shown that medium from irradiated cells and from the distant progeny of irradiated cells contains a factor or factors, which can significantly alter survival of cells that were never irradiated and were never in contact with irradiated cells. Inhibitors of the production of the factor (or response to it) include the MAO inhibitor L-deprenyl and lactate15, 43. A major feature of current research in the field is aimed at dissecting out the relative importance of signal production and cellular response. Results to date suggest that these are independently modulated and that cell lines, which do not produce a signal, may respond to one. This clearly implicates a genetic component in the mechanism which is further indicated by the in vivo work available44, 45.
V. BYSTANDER EFFECTS AND GENOMIC INSTABILITY
One of the most interesting areas in this field is the link between bystander effects and the induction and perpetuation of genomic instability1–4. Radiation-induced genomic instability is characterized by the appearance, in cell populations, of progeny with higher than normal levels of NON-CLONAL cytogenetic abnormalities and cell death. The instability is persistent, but effects occur at a stable rate in the post-irradiation survivors for many generations. Affected progeny populations do not either die out or dominate—an apparent paradox, which is difficult to reconcile with the current “world view” of competitive natural selection of favourable genes. The mechanism of perpetuation is now thought to be epigenetic and to involve an excess generation of reactive oxygen species (ROS). This is “signaled” to neighbours and perpetuated in progeny via mechanisms similar to the bystander mechanisms discussed earlier. The transmissible factors are very likely to be related to “bystander factors”.
While knowledge about radiation-induced genomic instability and bystander effects has been growing in the radiation field for over 15 years, it has only recently become apparent that chemicals in the natural environment can also induce the state of genomic instability in cells and hence low dose chemical toxicity probably also involves bystander effects46–47. This widens the relevance of these indirect damage mechanisms to include environmental toxins other than radiation and makes it important to understand the mechanisms involved as they may contribute to mixed exposure responses in biota.
VI. RELEVANCE OF BYSTANDER EFFECTS IN THE ADAPTIVE RESPONSE FIELD
Evidence, which suggests that bystander mechanisms may be involved in adaptive responses, comes from published data and also from deductive reasoning. The published data show that signals produced by irradiated cells can induce protection against a real dose of ionizing radiation48,49. These authors have also shown that intracellular calcium fluxes precede the induction of responses in bystander cells exposed to signals from irradiated cells24, 50–52. While the response that generally follows exposure to these bystander signals is cell death, this can be protective if it eliminates damaged cells from the population. Following low dose exposure, where few cells will have damage, it seems appropriate to remove them. At higher doses, where many cells are damaged and tissue integrity is at risk of collapse, such a bystander effect would be an added problem for an already compromised population. It is interesting to note here that repair deficient cells have larger death-inducing bystander effects than the corresponding repair proficient parent lines53, 54. This would be expected if the damaged cell couldn't be repaired, if the bystander effect is assumed to be protective. Many cell lines and most tumour explants do not produce death-inducing signals after exposure to radiation, and no calcium pulse is seen55–57. It is not known whether they produce no signals or whether different signals, not transduced through the calcium pulse-apoptotic death pathway, are involved.
VII. MODELS AND RELEVANCE TO RADIATION PROTECTION
If we accept that bystander effects are the result of a generalized stress response in tissues or cells, what are the implications for radiation protection? Does the effect alter the acceptability of the Linear-No-Threshold hypothesis, upon which all radiation protection legislation is based? How can dose be used as a measure of effect or harm, if low doses (which are those experienced in the workplace) do not produce any type of linear dose-effect curve? There is clearly some very complex biology involved because the signals may be produced by all exposed cells, but the response appears to require a quorum in order to be expressed18, 58–60. The major response involving low LET radiation exposure discussed in the existing literature is a death response. This has many characteristics of apoptosis, but is p53 independent? While a death response might appear to be adverse, the position is argued in this paper that it is in fact protective and removes damaged cells from the population. Since many cell populations carry damaged cells without being exposed to radiation, so called “background damage”, it is possible that low dose exposures cause removal of cells damaged by agents other than the test dose of radiation. This mechanism could lead to the production of U-shaped dose response curves so common in toxicology61–63. In this scenario, the level of “adaptive” or beneficial response will be related to the level of background damage carried by the cell population. These considerations may be important when attempting to predict the consequences of mixed exposures involving radiation and other environmental stressors.
VIII. CONCLUSION
To conclude, it is clear that adaptive responses, bystander effects and genomic instability belong to a suite of effects that predominately modulate the low dose response to radiation. These mechanisms are part of the cellular homeostatic response and, while we can detect low dose effects, there is little evidence that these translate into harm. It is likely that for many genotypes there is an operational threshold for harmful radiation damage that probably occurs at a point where the functional activity of the tissue is being compromised by the level of (protective) cell death. For genotypes where the bystander response, if there is one, does not involve coordinated cell death, it is likely that there is no operational threshold and that stochastic effects such as carcinogenesis have some very small probability of occurring at low doses. What this probability is, though, is not easy to determine. It is unlikely to be definable by extrapolation from high dose data because the underlying mechanisms are so different. Many of the current research efforts in this field are aimed at modulating the bystander effect using chemicals. This approach should, perhaps, not only look at preventing the bystander effect but also at causing or simulating it in tissues and cells which do not have the capacity to mount this response.
ACKNOWLEDGMENTS
We acknowledge support from the Science Foundation of Ireland and Saint Luke's Institute of Cancer Research.
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