Background radiation and cancer risks: A major intellectual confrontation within the domain of radiation genetics with multiple converging biological disciplines.

This paper assesses the judgments of leading radiation geneticists and cancer risk assessment scientists from the mid-1950s to mid-1970s that background radiation has a significant effect on human genetic disease and cancer incidence. This assumption was adopted by the National Academy of Sciences (NAS) Biological Effects of Atomic Radiation (BEAR) I Genetics Panel for genetic diseases and subsequently applied to cancer risk assessment by other leading individuals/advisory groups (e.g., International Commission on Radiation Protection-ICRP). These recommendations assumed that a sizeable proportion of human mutations originated from background radiation due to cumulative exposure over prolonged reproductive periods and the linear nature of the dose-response. This paper shows that the assumption that background radiation is a significant cause of spontaneous mutation, genetic diseases, and cancer incidence is not supported by experimental and epidemiological findings, and discredits erroneous risk assessments that improperly influenced the recommendations of national and international advisory committees, risk assessment policies, and beliefs worldwide.

Experimental evolution of extremophile resistance to ionizing radiation.

A growing number of known species possess a remarkable characteristic - extreme resistance to the effects of ionizing radiation (IR). This review examines our current understanding of how organisms can adapt to and survive exposure to IR, one of the most toxic stressors known. The study of natural extremophiles such as Deinococcus radiodurans has revealed much. However, the evolution of Deinococcus was not driven by IR. Another approach, pioneered by Evelyn Witkin in 1946, is to utilize experimental evolution. Contributions to the IR-resistance phenotype affect multiple aspects of cell physiology, including DNA repair, removal of reactive oxygen species, the structure and packaging of DNA and the cell itself, and repair of iron-sulfur centers. Based on progress to date, we overview the diversity of mechanisms that can contribute to biological IR resistance arising as a result of either natural or experimental evolution.

A high-throughput alpha particle irradiation system for monitoring DNA damage repair, genome instability and screening in human cell and yeast model systems.

Ionizing radiation (IR) is environmentally prevalent and, depending on dose and linear energy transfer (LET), can elicit serious health effects by damaging DNA. Relative to low LET photon radiation (X-rays, gamma rays), higher LET particle radiation produces more disease causing, complex DNA damage that is substantially more challenging to resolve quickly or accurately. Despite the majority of human lifetime IR exposure involving long-term, repetitive, low doses of high LET alpha particles (e.g. radon gas inhalation), technological limitations to deliver alpha particles in the laboratory conveniently, repeatedly, over a prolonged period, in low doses and in an affordable, high-throughput manner have constrained DNA damage and repair research on this topic. To resolve this, we developed an inexpensive, high capacity, 96-well plate-compatible alpha particle irradiator capable of delivering adjustable, low mGy/s particle radiation doses in multiple model systems and on the benchtop of a standard laboratory. The system enables monitoring alpha particle effects on DNA damage repair and signalling, genome stability pathways, oxidative stress, cell cycle phase distribution, cell viability and clonogenic survival using numerous microscopy-based and physical techniques. Most importantly, this method is foundational for high-throughput genetic screening and small molecule testing in mammalian and yeast cells.

Why toxicologists resisted and radiation geneticists supported EPA'S adoption of LNT for cancer risk assessment.

The linear non-threshold (LNT) dose response model for cancer risk assessment has been a controversial concept since its initial proposal during the 1930s. It was long advocated by the radiation genetics community in the 1950s, some two decades prior to being generally adopted within the chemical toxicology community. This paper explores possible reasons for such major differences in the acceptance of LNT for cancer risk assessment by these two key groups of scientists.

Inclusion of dosimetric data as covariates in toxicity-related radiogenomic studies : A systematic review.

PURPOSE: This systematic review evaluates the completeness of dosimetric features and their inclusion as covariates in genetic-toxicity association studies. MATERIALS AND METHODS: Original research studies associating genetic features and normal tissue complications following radiotherapy were identified from PubMed. The use of dosimetric data was determined by mining the statement of prescription dose, dose fractionation, target volume selection or arrangement and dose distribution. The consideration of the dosimetric data as covariates was based on the statement mentioned in the statistical analysis section. The significance of these covariates was extracted from the results section. Descriptive analyses were performed to determine their completeness and inclusion as covariates. RESULTS: A total of 174 studies were found to satisfy the inclusion criteria. Studies published ≥2010 showed increased use of dose distribution information (p = 0.07). 33% of studies did not include any dose features in the analysis of gene-toxicity associations. Only 29% included dose distribution features as covariates and reported the results. 59% of studies which included dose distribution features found significant associations to toxicity. CONCLUSION: A large proportion of studies on the correlation of genetic markers with radiotherapy-related side effects considered no dosimetric parameters. Significance of dose distribution features was found in more than half of the studies including these features, emphasizing their importance. Completeness of radiation-specific clinical data may have increased in recent years which may improve gene-toxicity association studies.

A glance into how the cold war and governmental loyalty investigations came to affect a leading U.S. radiation geneticist: Lewis J. Stadler's nightmare.

This paper describes an episode in the life of the prominent plant radiation geneticist, Lewis J. Stadler (1897-1954) during which he became a target of the Federal Bureau of Investigation (FBI) concerning loyalty to the United States due to possible associations with the communist party. The research is based on considerable private correspondence of Dr. Stadler, the FBI interrogatory questions and Dr. Stadler's answers and letters of support for Dr. Stadler by leading scientists such as, Hermann J. Muller.

[Tremendous Human, Social, and Economic Losses Caused by Obstinate Application of the Failed Linear No-threshold Model].

The linear no-threshold model (LNT) was recommended in 1956, with abandonment of the traditional threshold dose-response for genetic risk assessment. Adoption of LNT by the International Commission on Radiological Protection (ICRP) became the standard for radiation regulation worldwide. The ICRP recommends a dose limit of 1 mSv/year for the public, which is too low and which terrorizes innocent people. Indeed, LNT arose mainly from the lifespan survivor study (LSS) of atomic bomb survivors. The LSS, which asserts linear dose-response and no threshold, is challenged mainly on three points. 1) Radiation doses were underestimated by half because of disregard for major residual radiation, resulting in cancer risk overestimation. 2) The dose and dose-rate effectiveness factor (DDREF) of 2 is used, but the actual DDREF is estimated as 16, resulting in cancer risk overestimation by several times. 3) Adaptive response (hormesis) is observed in leukemia and solid cancer cases, consistently contradicting the linearity of LNT. Drastic reduction of cancer risk moves the dose-response curve close to the control line, allowing the setting of a threshold. Living organisms have been evolving for 3.8 billion years under radiation exposure, naturally acquiring various defense mechanisms such as DNA repair mechanisms, apoptosis, and immune response. The failure of LNT lies in the neglect of carcinogenesis and these biological mechanisms. Obstinate application of LNT continues to cause tremendous human, social, and economic losses. The 60-year-old LNT must be rejected to establish a new scientific knowledge-based system.

James V. Neel and Yuri E. Dubrova: Cold War debates and the genetic effects of low-dose radiation.

This article traces disagreements about the genetic effects of low-dose radiation exposure as waged by James Neel (1915-2000), a central figure in radiation studies of Japanese populations after World War II, and Yuri Dubrova (1955-), who analyzed the 1986 Chernobyl nuclear power plant accident. In a 1996 article in Nature, Dubrova reported a statistically significant increase in the minisatellite (junk) DNA mutation rate in the children of parents who received a high dose of radiation from the Chernobyl accident, contradicting studies that found no significant inherited genetic effects among offspring of Japanese A-bomb survivors. Neel's subsequent defense of his large-scale longitudinal studies of the genetic effects of ionizing radiation consolidated current scientific understandings of low-dose ionizing radiation. The article seeks to explain how the Hiroshima/Nagasaki data remain hegemonic in radiation studies, contextualizing the debate with attention to the perceived inferiority of Soviet genetic science during the Cold War.

Multigenerational effects of whole body exposure to 2.14 GHz W-CDMA cellular phone signals on brain function in rats.

The present experimental study was carried out with rats to evaluate the effects of whole body exposure to 2.14 GHz band code division multiple access (W-CDMA) signals for 20 h a day, over three generations. The average specific absorption rate (SAR, in unit of W/kg) for dams was designed at three levels: high (<0.24 W/kg), low (<0.08 W/kg), and 0 (sham exposure). Pregnant mothers (4 rats/group) were exposed from gestational day (GD) 7 to weaning and then their offspring (F1 generation, 4 males and 4 females/dam, respectively) were continuously exposed until 6 weeks of age. The F1 females were mated with F1 males at 11 weeks old, and then starting from GD 7, they were exposed continuously to the electromagnetic field (EMF; one half of the F1 offspring was used for mating, that is, two of each sex per dam and 8 males and 8 females/group, except for all offspring for the functional development tests). This protocol was repeated in the same manner on pregnant F2 females and F3 pups; the latter were killed at 10 weeks of age. No abnormalities were observed in the mother rats (F0 , F1 , and F2 ) and in the offspring (F1 , F2 , and F3 ) in any biological parameters, including neurobehavioral function. Thus, it was concluded that under the experimental conditions applied, multigenerational whole body exposure to 2.14 GHz W-CDMA signals for 20 h/day did not cause any adverse effects on the F1 , F2 , and F3 offspring.

Danos causados pelas radiações ionizantes sobre órgãos e sistemas vitais de fetos e crianças pequenas / Damage caused by ionizing radiation on organs and vital systems of fetuses and young children

Entrevista feita por jornalistas irlandeses, por ocasião da conferência de imprensa de Ady Roche (Chernobyl Children's Project (http://www.chernobylinternational.com), Minsk, abril de 2000.Tradução de Paulo Neves e revisão de Emico Okuno e Joaquim Francisco de Carvalho. O original em francês encontra-se à disposição do leitor para eventual consulta.

H.J. Muller's contributions to mutation research.

H. J. Muller is best known for his Nobel Prize work on the induction of mutations by ionizing radiation. Geneticists are less familiar with his contributions to mutation and how he related the process of mutagenesis to the gene and distinguished gene mutations from other genetic and epigenetic events such as polyploidy, chromosome rearrangements, and position effects. The hallmark of Muller's contributions is his design of genetic stocks to solve genetic problems and allow experimentation to reveal new phenomena. In this review I relate Muller's personality to his teaching and research and present a history of Muller's ideas on mutation from his first days in Morgan's fly lab to his final thoughts on what became called "Muller's ratchet", a term he did not get to enjoy because it was coined seven years after his death.

Evolutionary branching in a finite population: deterministic branching vs. stochastic branching.

Adaptive dynamics formalism demonstrates that, in a constant environment, a continuous trait may first converge to a singular point followed by spontaneous transition from a unimodal trait distribution into a bimodal one, which is called "evolutionary branching." Most previous analyses of evolutionary branching have been conducted in an infinitely large population. Here, we study the effect of stochasticity caused by the finiteness of the population size on evolutionary branching. By analyzing the dynamics of trait variance, we obtain the condition for evolutionary branching as the one under which trait variance explodes. Genetic drift reduces the trait variance and causes stochastic fluctuation. In a very small population, evolutionary branching does not occur. In larger populations, evolutionary branching may occur, but it occurs in two different manners: in deterministic branching, branching occurs quickly when the population reaches the singular point, while in stochastic branching, the population stays at singularity for a period before branching out. The conditions for these cases and the mean branching-out times are calculated in terms of population size, mutational effects, and selection intensity and are confirmed by direct computer simulations of the individual-based model.

[Somatic chromosome mutagenesis in residents of Ukraine exposed to ionizing radiation in different periods after the Chernobyl accident].

The authors summarize results of 25-year selective cytogenetic monitoring of the priority groups in different periods after the Chernobyl accident. The increase in intensity of somatic chromosome mutagenesis in exposed individuals as a result of both targeted and non-targeted radiation-induced cytogenetic effects has been confirmed including delayed, transmissible, hidden chromosome instability and the bystander effect.

Differential genetic responses to ionizing irradiation in individual families of Japanese medaka, Oryzias latipes.

Although no statistically significant hereditary effects have yet been detected in the children of survivors from the atomic bombings in Hiroshima and Nagasaki, recent animal studies have found that exposure to ionizing radiation can cause genomic and epigenomic instability in the exposed individuals, as well as their offspring, and therefore, may have much larger genetic effects than predicted by earlier studies. When individuals are exposed to various environmental insults, including radiation, individual sensitivity to the insults often varies. Variance in germ-line response to radiation among individuals has been widely recognized, but it is difficult to address due to the use of inbred strains and the limited number of offspring that can be produced by a pair of mice, the common model used to study genetic effects of radiation. Herein is the first study to examine individual family responses to ionizing radiation using a parent-pedigree approach in an outbred strain of a vertebrate model, the Japanese medaka fish. Changes in frequencies of radiation-induced germline mutations at nine microsatellite loci were examined in the same families before and after exposure to one of four acute doses of ionizing radiation (0.1, 0.5, 2.5, 5Gy, plus sham-exposed controls). Families varied significantly in pre-exposure mutation frequencies and responses to irradiation, but germline mutations were elevated in at least one family after 0.1, 0.5, and 5Gy exposures. Variance among individuals in sensitivity to radiation is well documented for many endpoints, and our work now extends these endpoints to include germ-line mutations. Further studies are needed to elucidate dose response, effects at varying stages of spermatogenesis, and the mechanisms underlying the variance in these individual responses to radiation.

Towards a unifying theory of late stochastic effects of ionizing radiation.

The traditionally accepted biological basis for the late stochastic effects of ionizing radiation (cancer and hereditary disease), i.e. target theory, has so far been unable to accommodate the more recent findings of non-cancer disease and the so-called non-targeted effects, genomic instability and bystander effect, thus creating uncertainty in radiation risk estimation. We propose that ionizing radiation can give rise to these effects through two distinct and independent routes, one essentially genetic, termed here type A, and the other essentially epigenetic, termed type B. Type B processes entail envisaging phenotype as represented by a dynamic attractor and radiation acting as an agent that stresses cellular processes leading to the adoption of a variant attractor/phenotype. Evidence from the literature indicates that type B processes can lead to the inheritance of variant cell attractors and mediate a category of trans-generational effects quite distinct from classical Mendelian inherited disease, which is type A. The causal relationships for radiation-induced somatic human health detriment, i.e., cancer and non-cancer (e.g., cardiovascular) disease, are discussed from the point of view of the proposed classification. This approach unifies at a fundamental level the heritable and late somatic effects of radiation into a single causal framework that has the potential to be extended to the effects of the other environmental agents damaging to health.

[Study of genetic control of radiosensitivity].

The results of radiation genetics studies are reviewed. The first series of studies concerned the role of heterogeneity of the human population for radiosensitivity of chromosomes in determining the pattern of dose-response relationships; correctness of extrapolation of averaged experimental data to low doses was demonstrated. In the second series of experiments, the radiation-induced adaptive response and the contribution of different factors, including genetic ones, to its formation in human cells were studied. A conclusion was made about impossibility of extrapolating data obtained for cell cultures to an organism as a whole or to a population. The third part of the study was of applied character: cytogenetic methods of biological dosimetry were used to estimate the doses of internal and external irradiation of children living on the territory of the Bryansk oblast contaminated after the Chernobyl accident. The results are discussed in the context of the present-day concepts of genetic control of sensitivity to environmental factors.

Functional cell-cycle chromatin conformation changes in the presence of DNA damage result into chromatid breaks: a new insight in the formation of radiation-induced chromosomal aberrations based on the direct observation of interphase chromatin.

Experiments were carried out to explore the correlation between chromatin conformation changes in the presence of DNA lesions and the formation of radiation-induced chromosomal aberrations. To modulate the onset and dynamics of chromatin conformation changes following irradiation, premature chromosome condensation (PCC) was induced by means of cell fusion. G2-check point abrogation by caffeine or elevated heat treatment was also applied. In addition, transfer of irradiated mitotic cells was employed either into depleted media to restrain them from proceeding through G1/S, or holding them further in colcemid to avoid M/G1 transition. To investigate the correlation between efficiency of chromosomal conformation changes and chromosomal breakage in irradiated G0 peripheral blood lymphocytes, cell fusion with different mitotic PCC-inducer cells was used. The experimental evidence supports the hypothesis that functional cell-cycle chromatin conformation changes in the presence of DNA damage are important determinants in the formation of radiation-induced chromosomal aberrations. Specifically, it is proposed here that following irradiation, chromatin structure may not be broken but instead it unfolds to a conformation that is more accessible to repair enzymes at the sites of DNA lesions. If subsequent chromosomal conformation changes occur while DNA is still being repaired, such changes will lead into an energetically unfavorable state, thus exerting mechanical stress on the unfolded chromatin at the damaged sites, which will in turn result into chromatid breaks that may not be able to restitute or mis-rejoin. Therefore, this biophysical conversion process of DNA damage into chromatid breaks as such is antagonistic to the DNA repair process. Alternatively, in the absence of chromosomal conformation changes, either DNA repair will take place efficiently or DNA misrepair will cause the formation of exchanges and chromosomal rearrangements. Consequently, the type and yield of radiation-induced chromosomal aberrations at a given cell cycle stage will be the combined effect of the interaction, at that particular stage, of the DNA repair process and the proposed conversion process of DNA lesions into chromatid breaks.