Human minisatellite mutation rate after the Chernobyl accident

Terminal branch haplotype analysis: a novel approach to investigate newly arisen variants of mitochondrial DNA in natural populations

The discrimination of recent mutational derivatives from ancestral variation is a critical antecedent to any effort which aims to identify the factors modulating the rates of origin and persistence of new mutants. We propose that newly arisen mtDNA variants, which we designate as terminal branch haplotypes (TBHs), can be recognized by joint sequencing and phylogenetic analysis. This study examined mtDNA diversity in natural populations of the brown bullhead (Ameiurus nebulosus) from four heavily contaminated sites and three relatively pristine locations. While sequence analysis of the mtDNA D-loop region revealed that TBHs were prevalent in these populations, contaminant exposure appeared to play a minor role in their generation. Instead, most TBHs likely arose due to spontaneous mutations with variation in their incidence among sites reflecting the impact of demographic factors.

Pathogenesis of non-AIDS-defining cancers: a review

As the AIDS epidemic advances, the number of HIV-infected subjects developing AIDS-related neoplasms is rapidly increasing, and the spectrum of malignancies encountered is expanding. Several non-AIDS-defining cancers are being reported at an increasing incidence in HIV-infected individuals, including anal, skin, oral mucosa, head and neck and lung carcinomas, testicular tumors, and pediatric soft-tissue sarcoma. There appears to be an emerging role for various concurrent viral infections in the HIV-infected host that are likely implicated in the pathogenesis of some nondefining-AIDS neoplasms. Our recent findings in HIV-associated lung cancers and in the precursor lesions of cervical carcinoma suggest that wide-spread genomic instability, as manifested by the development of increased numbers of microsatellite alterations (MAs), may occur frequently in HIV-associated tumors and they may play an important role in the pathogenesis of those neoplasms. Although the mechanism underlying the development of increased MAs is unknown, it may play a crucial role in the development of many HIV-associated tumors. It will be important to track the epidemiological and biological features of non-AIDS-defining cancers in HIV-infected patients, and compare them to those tumors in the general population. It is likely that further clues about malignant transformation and oncogenesis unraveled in the HIV setting will have broad clinical implications.

Current and future contributions of transgenic mice to the analysis of germline toxicology

Evermore sophisticated tests are need to study germline toxicology. The gene conversion-based systems developed in Leicester and in the USA are steps in the right direction, but a lot of validation both in vivo and in vitro is required. Transgenic technology can also be used to research the biology of testis, so that we know more how to make it more human-like. If you talk to toxicologists, they always complain: 'but it 's only a rat, it's only a mouse, it's not a man'. In future, once we understand more biology--it might be possible to make the toxicological response of a transgenic mouse more human-like. As we all know, the testis is a complex biological system and it is only when we get a better understanding of what is going on to the fundamental level are such developments possible. Indeed, it might be possible to do even more exciting things, such as taking mitotic human tissue culture cells and to inducing them to enter meiosis in vitro. Such a system would be a natural complement to the in vitro tests widely used in industry.

Nucleotide variation in the p53 tumor-suppressor gene of voles from Chernobyl, Ukraine

The 1986 Chernobyl disaster contaminated vast regions of Ukraine and Belarus with a variety of radioactive isotopes and heavy metals. While over 90% of the radioactive isotopes have decayed into stable compounds, radiation levels in contaminated areas are still extraordinarily high. In fact, some rodents living near the reactor have internal 134,137Cs concentrations approaching 80 000 Bq/g. Several recent genetic analyses of vertebrates have illustrated that mutation rates of organisms exposed to radiation from Chernobyl are higher than in control groups, but none have studied DNA sequences. Nucleotide sequences of rodent mitochondrial genes were originally reported to have been hypervariable, but those results were subsequently retracted. Herein, I report the results of a pilot study to determine the extent of nucleotide variation at the p53 gene in four species of rodents (voles) from Chernobyl and from control sites. I sequenced a 788 bp region (coding and non-coding) of p53 in 30 different mice comprising four different species of Microtus. Nucleotide variation at the population level was due to deletions and substitutions; both were limited to introns. There were no significant differences between the number of haplotypes in radioactive and control populations (p=0.60). Rare or private alleles might have arisen due to unique mutational pressures at Chernobyl. Alternatively, natural selection might have favored one allele over others (i.e., a selective sweep). Neither scenario is strongly supported by these data. Thus, no apparent genetic effects of the Chernobyl disaster on the p53 gene of resident voles were revealed; more extensive surveys will be necessary to determine if mutation rates are indeed elevated in mice from Chernobyl. However, two salient points emerge; the first involves the utility of introns as markers for mutations in coding regions and the second considers the relative merits of cloning in mutation detection studies.

Transgenic plants are sensitive bioindicators of nuclear pollution caused by the Chernobyl accident

To evaluate the genetic consequences of radioactive contamination originating from the nuclear reactor accident of Chernobyl on indigenous populations of plants and animals, it is essential to determine the rates of accumulating genetic changes in chronically irradiated populations. An increase in germline mutation rates in humans living close to the Chernobyl Nuclear Power Plant site, and a two- to tenfold increase in germline mutations in barn swallows breeding in Chernobyl have been reported. Little is known, however, about the effects of chronic irradiation on plant genomes. Ionizing radiation causes double-strand breaks in DNA, which are repaired via illegitimate or homologous recombination. We make use of Arabidopsis thaliana plants carrying a beta-glucuronidase marker gene as a recombination substrate to monitor genetic alterations in plant populations, which are caused by nuclear pollution of the environment around Chernobyl. A significant (p<0.05) increase in somatic intrachromosomal recombination frequencies was observed at nuclear pollution levels from 0.1-900 Ci/km2, consistent with an increase in chromosomal aberrations. This bioindicator may serve as a convenient and ethically acceptable alternative to animal systems.

Monitoring for induced heritable mutations in natural populations: application of minisatellite DNA screening

The need to understand the role that anthropogenic chemicals play in generating germline mutations is critical, both from an ecological and a human health perspective. Exposure to complex mixtures of urban and industrial chemicals is widespread and we have little understanding of the long-term implications to populations and gene pools. It has recently been suggested that minisatellite DNA mutations may be sensitive biomarkers for induced heritable mutations in populations exposed to radioactive and non-radioactive contamination in their environments. Minisatellite loci are attractive targets for mutational analyses because they undergo a rate of mutation much greater than unique sequence DNA and with DNA fingerprinting many loci can be scanned simultaneously. As a result, the technique is statistically powerful requiring relatively small sample sizes (compared to other in situ mutation assays) and is reasonably cost and time efficient. This paper will review the application of minisatellite mutation screening to the field of genetic toxicology.

Mutation rate in human microsatellites: influence of the structure and length of the tandem repeat

In 10,844 parent/child allelic transfers at nine short-tandem-repeat (STR) loci, 23 isolated STR mismatches were observed. The parenthood in each of these cases was highly validated (probability >99.97%). The event was always repeat related, owing to either a single-step mutation (n=22) or a double-step mutation (n=1). The mutation rate was between 0 and 7 x 10(-3) per locus per gamete per generation. No mutations were observed in three of the nine loci. Mutation events in the male germ line were five to six times more frequent than in the female germ line. A positive exponential correlation between the geometric mean of the number of uninterrupted repeats and the mutation rate was observed. Our data demonstrate that mutation rates of different loci can differ by several orders of magnitude and that different alleles at one locus exhibit different mutation rates.

Stage specificity, dose response, and doubling dose for mouse minisatellite germ-line mutation induced by acute radiation

Germ-line mutation induction at mouse minisatellite loci by acute irradiation with x-rays was studied at premeiotic and postmeiotic stages of spermatogenesis. An elevated paternal mutation rate was found after irradiation of premeiotic spermatogonia and stem cells, whereas the frequency of minisatellite mutation after postmeiotic irradiation of spermatids was similar to that in control litters. In contrast, paternal irradiation did not affect the maternal mutation rate. A linear dose-response curve for paternal mutation induced at premeiotic stages was found, with a doubling dose of 0.33 Gy, a value close to those obtained in mice after acute spermatogonia irradiation using other systems for mutation detection. High frequencies of spontaneous and induced mutations at minisatellite loci allow mutation induction to be evaluated at low doses of exposure in very small population samples, which currently makes minisatellite DNA the most powerful tool for monitoring radiation-induced germ-line mutation.

A novel unstable mouse VNTR family expanded from SINE B1 elements

Human hypervariable minisatellites provide highly informative loci for analyzing processes of tandem repeat turnover, but little is known about mechanisms of instability in other species. We have therefore screened the mouse genome for analogous VNTR loci. One of the probes we isolated, MMS10, detects a highly variable rodent-specific family of multiple loci derived by expansion of a common GGCAGA repeat unit from within a subset of B1 short interspersed elements. The mean germline mutation rate for loci detected by MMS10 was estimated at 1.7% per offspring band, though analysis of individual loci showed substantial variation in germinal instability apparently related to repeat array size. This MMS10 family of expanded hexanucleotide repeat loci provides a novel resource for investigating mechanisms of tandem repeat turnover in the mouse and an efficient means for monitoring germline mutations induced by external agents such as ionizing radiation.

Combination of genomic DNA fingerprinting into the medaka specific-locus test system for studying environmental germ-line mutagenesis

A specific-locus test (SLT) system has been established using the medaka fish (Oryzias latipes), where recessive visible mutations (at the b, lf or gu loci) detected during early embryonic stages (TM) or after hatching (VM), and dominant lethals (DL) can be examined in the same individual F1 progeny of treated parents. It was found that approximately 90% of the F1 embryos with gamma-ray-induced specific-locus mutations were concomitantly accompanied by dominant lethals irrespective of doses and germ-cell stages at the time of exposure, suggesting that DNA alterations in such mutants might include both the marker loci and region(s) responsible for dominant lethals. In contrast, embryonic lethality of the ENU (ethylnitorosourea)-induced specific-locus mutants considerably varied among ENU concentrations as well as germ-cell stages treated. Further, synergistic effect of combined treatments with gamma-rays and ENU on induction of mutations were suggested in postmeiotic male germ cells, while in spermatogonia no synergistic effect was found. DNA alterations at the 87 arbitrarily primed polymerase chain reaction (AP-PCR) markers spread over the genome were examined for individual dominant lethal embryos from 4.75 Gy-irradiated sperm or spermatids. It was found that, 14 out of 20 dominant lethal embryos lost more than one AP-PCR markers, including multiple markers located on the identical linkage group (average genetic distances, approximately 11 cM). Also found was that frequency of loss of the AP-PCR markers in the severely malformed dominant lethal embryos was higher (approximately 4.5%) than that in the slightly malformed lethal embryos (approximately 1.6%). Here, results of these studies, including previously unpublished work, are presented to illustrate the potential usefulness of the medaka SLT system for monitoring environmental mutagens.

The linear no-threshold dose-effect relation: is it relevant to radiation protection regulation?

Official radiogenic cancer risk estimates for low-dose, protracted exposure conditions have been based on linear, no-threshold downward extrapolation from medium and high-dose effects among a population of A-bomb survivors, with the application of a downward correction for an assumed reduced biological effectiveness at low doses and low dose rates (DDREF correction). Neither in the follow-up of populations exposed to the high-dose A-bomb flash, nor from epidemiological data after low-dose occupational or medical irradiation is there any convincing evidence for this DDREF hypothesis--even less for a zero-effect threshold dose. To the contrary, for external low-dose exposures of nuclear workers or general populations, cancer risks per unit dose have been found to be about 1 order of magnitude larger than those derived from the Japanese survivors, with larger discrepancies for persons above 50 years of age, and for x-rayed fetuses. This may be due to a dose and dose-rate effect exactly opposite from that postulated by the DDREF assumption, and a dose-dependent bias due to selection for exceptionally high immune competence among the > 5 years A-bomb survivor cohort. Excess cancer mortality following occupational exposures to ingested fission products and radiation-associated teratogenic, genetic, and cancer detriment among diverse populations who had ingested small amounts of radioactivity after the precipitation of fallout at great distances from the Chernobyl nuclear explosion, suggest discrepancies of as much as 2 orders of magnitude with official risk estimates. Contrary to widely publicized statements, claiming that current regulations of population exposures are far too restrictive, thus unnecessarily costly for the radiation industries, the aggregate of radiation epidemiological evidence suggests that current standards are inadequate to protect public health.

Genetic toxicities of human teratogens

Birth defects cause a myriad of societal problems and place tremendous anguish on the affected individual and his or her family. Current estimates categorize about 3% of all newborn infants as having some form of birth defect or congenital anomaly. As more precise means of detecting subtle anomalies become available this estimate, no doubt, will increase. Even though birth defects have been observed in newborns throughout history, our knowledge about the causes and mechanisms through which these defects are manifested is limited. For example, it has been estimated that around 20% of all birth defects are due to gene mutations, 5-10% to chromosomal abnormalities, and another 5-10% to exposure to a known teratogenic agent or maternal factor [D.A. Beckman, R.L. Brent, Mechanisms of teratogenesis. Ann. Rev. Pharmacol. Toxicol. 24 (1984) 483-500; K. Nelson, L.B. Holmes Malformations due to presumed spontaneous mutations in newborn infants, N. Engl. J. Med. 320 (1989) 19-23.]. Together, these percentages account for only 30-40%, leaving the etiology of more than half of all human birth defects unexplained. It has been speculated that environmental factors account for no more than one-tenth of all congenital anomalies [D.A. Beckman, R.L. Brent, Mechanisms of teratogenesis, Ann. Rev. Pharmacol. Toxicol. 24 (1984) 483-500]. Furthermore, since there is no evidence in humans that the exposure of an individual to any mutagen measurably increases the risk of congenital anomalies in his or her offspring' [J.F. Crow, C. Denniston, Mutation in human populations, Adv. Human Genet. 14 (1985) 59-121; J.M. Friedman, J.E. Polifka, Teratogenic Effects of Drugs: A Resource for Clinicians (TERIS). The John Hopkins University Press, Baltimore, 1994], the mutagenic activity of environmental agents and drugs as a factor in teratogenesis has been given very little attention. Epigenetic activity has also been given only limited consideration as a mechanism for teratogenesis. As new molecular methods are developed for assessing processes associated with teratogenesis, especially those with a genetic or an epigenetic basis, additional environmental factors may be identified. These are especially important because they are potentially preventable. This paper examines the relationships between chemicals identified as human teratogens (agents that cause birth defects) and their mutagenic activity as evaluated in one or more of the established short-term bioassays currently used to measure such damage. Those agents lacking mutagenic activity but with published evidence that they may otherwise alter the expressions or regulate interactions of the genetic material, i.e. exhibit epigenetic activity, have likewise been identified. The information used in making these comparisons comes from the published literature as well as from unpublished data of the U.S. National Toxicology Program (NTP).

The radiobiological basis of total body irradiation

Total body irradiation (TBI) is an all-pervasive systemic treatment modality which is well suited to the sterilization of small numbers of widely dispersed radiosensitive cells. This makes it attractive for the treatment of leukaemia or lymphoma in remission. It is unlikely that hypoxia or repopulation will be a problem in TBI treatment of leukaemia, and clonal resistance to radiation occurs less readily than to drugs. Leukaemic cells are often radiosensitive with poor repair capacities but considerable variation is seen in laboratory studies and leukaemias may be highly individual. It is possible that programmed cell death (apoptosis) contributes to leukaemic cell killing and variability of apoptosis may give rise to biological individuality. Molecular methodologies may now be used to monitor leukaemic cell populations and may enable semi-quantitative predictive assays of radiosensitivity. When the malignant cell population is not uniformly distributed throughout the body, as in lymphoma, non-uniform TBI is appropriate, e.g. by addition of local boosts or by the combination of TBI with radiolabelled antibody treatment. Major side-effects mostly relate to critical organs with late-responding characteristics (low alpha/beta ratio, high sensitivity to fraction size or dose rate). The radiobiological basis of developmental effects in children is not well understood. In future, improved selectivity of TBI may come from molecular biological strategies to sensitize malignant cells and to protect normal tissues.

Genetic disorders in house mouse germ cells after the Chernobyl catastrophe

Genetic effects were studied in house mice caught from 1986 to 1994 in regions polluted by radionuclides as a result of the Chernobyl disaster. The dose rates of gamma-radiation on the soil surface ranged from 0.0002 to 2 mGy/h. The frequency of reciprocal translocations in mouse spermatocytes was relatively low, but increased with the dose rate. Embryo mortality was increased only in the progeny of male mice in males caught in 1987 in the area with maximal contamination. The frequency of mice heterozygous for recessive lethal mutations decreased with time after the accident.

Fitness loss and germline mutations in barn swallows breeding in Chernobyl

The severe nuclear accident at Chernobyl in 1986 resulted in the worst reported accidental exposure of radioactive material to free-living organisms. Short-term effects on human populations inhabiting polluted areas include increased incidence of thyroid cancer, infant leukaemia, and congenital malformations in newborns. Two recent studies have reported, although with some controversy, that germline mutation rates were increased in humans and voles living close to Chernobyl, but little is known about the viability of the organisms affected. Here we report an increased frequency of partial albinism, a morphological aberration associated with a loss of fitness, among barn swallows, Hirundo rustica, breeding close to Chernobyl. Heritability estimates indicate that mutations causing albinism were at least partly of germline origin. Furthermore, evidence for an increased germline mutation rate was obtained from segregation analysis at two hypervariable microsatellite loci, indicating that mutation events in barn swallows from Chernobyl were two- to tenfold higher than in birds from control areas in Ukraine and Italy.

Risk of congenital anomalies in children of parents occupationally exposed to low level ionising radiation

OBJECTIVES

To evaluate the risk of having a child with a congenital anomaly in relation to occupational exposure to low level ionising radiation in the pre-conception period.

METHODS

A case-control study based on the Canadian congenital anomalies registry used record linkage techniques to identify congenital anomalies among male and female workers in Canada's largest electric company. Cases were defined as parents of a child with a congenital anomaly born between April 1979 and December 1986 who had a congenital anomaly diagnosed within the first year of life. Controls were an individually matched sample of parents of a liveborn child without an anomaly. Risk of congenital anomaly was assessed in relation to parental exposure to ionising radiation acquired through work within a nuclear generating station of an electric power company. Exposure was assessed according to employment, whether or not the worker was monitored for radiation exposure, and quantitative estimates of radiation dose.

RESULTS

Employment within the electric power industry was not associated with an increased risk of congenital anomalies in the offspring of mothers or fathers. Risk estimates for workers monitored (those who are likely to be exposed to ionising radiation) were 1.75 (95% confidence interval (95% CI) 0.86 to 3.55) for mothers and 0.84 (95% CI 0.68 to 1.05) for fathers. Exposure for fathers before conception, defined cumulatively and for six months before conception, was not associated with increased risk of anomalies in their offspring. There were no significant increases in risk found between type of anomaly and any measure of exposure, although the statistical power in these groups was limited. The study had insufficient numbers to evaluate the effects of ionising radiation in mothers as only three mothers had recorded doses > 0 mSv.

CONCLUSIONS

Overall, workers in a nuclear power industry, and specifically those exposed before conception to low levels of ionising radiation, do not appear to be at an increased risk of having a liveborn child with a congenital anomaly.

Proceedings of the 4th International DNA Fingerprinting Conference. Melbourne, Australia, December 2-7, 1996

Minisatellites provide not only the basis for DNA fingerprinting and DNA profiling but also extremely informative systems for analysing processes of tandem repeat turnover in the human genome. Minisatellite instability appears to involve distinct mutation processes in somatic and germline cells; in the germline, mutation is frequently dominated by inter-allelic conversion-like events most likely occurring at meiosis and apparently regulated by cis-acting mutation initiator elements. Attempts to define these initiators in transgenic mice have so far been thwarted by what appears to be a major human/mouse barrier to the inter-species transfer of repeat instability. Minisatellites not only show high frequency spontaneous mutation in the germline, but also appear to be very sensitive to mutation induction by ionizing radiation, both in experimentally irradiated mice and in human populations exposed following the Chernobyl disaster; the mechanisms of mutation induction by radiation remain enigmatic.

On simple repetitive DNA sequences and complex diseases

Simple repetitive DNA sequences are abundantly interspersed in eukaryote genomes and therefore useful in genome research and genetic fingerprinting in plants, fungi and animals, including man. Recently, simple repeats were also identified in some prokaryotic genomes. Hence the same probes can be applied for multilocus DNA fingerprinting in medically relevant bacteria. Simple repeats including composite dinucleotide microsatellites are differentially represented in different compartments of eukaryote genomes. Expanded triplet blocks in and around certain genes may, for example, cause so-called trinucleotide diseases in man. As a consequence, simple repetitive sequences should also be characterized with respect to their influences on the DNA structure, gene expression, genomic (in)stability and their development on an evolutionary time scale. Here three examples of microsatellites in the human major histocompatibility complex (HLA) are investigated, a (GT)n microsatellite situated 2 kb 5' off the lymphotoxin alpha (LTA) gene, a (GAA)n block in the 5' part of the HLA-F gene and a composite (GT)n(GA)m stretch in the second intron of HLA-DRBl genes. Grossly differing mutation rates are evident in these elements as well as varying linkage disequilibria. The unfolding of these simple repeats in distant human populations is covered including Caucasians, Bushmen and South American Indians. Furthermore, implications of simple repeat neighboring genes are discussed for the multifactorial diseases multiple sclerosis (MS), rheumatoid arthritis (RA) and early onset pauciarticular arthritis (EOPA). Polymorphisms of HLA-DRBl and T cell receptor beta variable (TCRBV) genes confer susceptibility for these autoimmune diseases as demonstrable by intronic simple repeat variability. Microsatellite polymorphisms within the TNF region reveal linkage disequilibria with HLA-DRBl and different promotor alleles of the TNFA gene. Disease associations with TNFA microsatellite alleles are, on the one hand, secondary to associations with HLA-DRBl genes (in MS) or they represent additional risk factors (in RA, EOPA) on the other hand. Evolutionary persistence, various structural conformations and the specific binding of nuclear proteins to several simple repeat sequences refute the preconceptions of biological insignificance for all of these ubiquitously interspersed elements.

Lessons from Chernobyl: the event, the aftermath fallout: radioactive, political, social

The accident at the Chernobyl nuclear power station on April 26, 1986, released about 300 MCi of radioactive substances, including about 40 MCi of 131I and 100 MCi of short-lived radioiodines. In the immediate surroundings there were 143 cases of acute radiation syndrome, 34 deaths, and hundreds of thousands of people displaced from their homes, many permanently. The social and psychologic stresses that followed have been enormous and long-lasting. This article focuses on the rising incidence of thyroid cancer in exposed children. Radiation-induced thyroid cancer following external radiation is well documented but there is little evidence in humans of thyroid cancer from internal radiation and the risk coefficient for radioiodine exposure is known. To achieve this, thyroid dose reconstruction and prospective follow-up of about 50,000 persons who were children in 1986 will be required. Thyroid cancer in children of southern Belarus began to increase in 1990 and there now are about 1,000 cases in Belarus and northern Ukraine. These aggressively growing tumors, almost all variants of papillary thyroid cancer, are typical for thyroid cancer in children not exposed to radiation, and a low mortality rate is to be expected. It also is expected, however, that malignant as well as benign thyroid neoplasms will continue to arise in these exposed children well into their adult life.

The natural somatic mutation frequency and human carcinogenesis

Much recent attention has been paid to the important role of the DNA mismatch repair system in controlling the accumulation of somatic mutations in human tissues and the association of mismatch repair deficiency with carcinogenesis. In the absence of an intact mismatch repair system, cells accumulate mutations at a rate some 1000 times faster than normal cells, and this mutator phenotype is easily measured by the detection of the formation of new variant alleles at microsatellite loci. However, the mismatch repair system is not 100% efficient, even when intact, and the pattern of microsatellite alterations in a wide variety of tumors is consistent with these being due to clonal amplification from tissues that are genetically heterogeneous at microsatellite loci rather than mismatch repair deficiency in the tumor itself. On this basis, it can be estimated that the mutation frequency of microsatellites in normal human tissues is approximately 10(-2) per locus per cell. Similarly, a frequency of mutation at minisatellite loci in normal tissues of around 10(-1) per locus per cell can be estimated. Such elevated levels of mutation are consistent with a recent study of the frequency of HPRT mutation in human kidneys that demonstrated these to be frequent (average 2.5 x 10(-4) in individuals of 70 years or more) and exponentially related to age. Taken as a whole, the data suggest that somatic mutation in human epithelial cells may be some 10-fold higher than in peripheral blood lymphocytes and that the underlying rate of spontaneous mutation is sufficient to account for a large proportion of human carcinogenesis without the need to evoke either stepwise alteration to a mutator phenotype of clonal expansion at all the mutation steps in carcinogenesis. The exponential increase in mutation frequency with age is predictable on the basis that the mutation rate is controlled at the level of repair and that mutation in genes that affect the efficiency of these processes will gradually increase the underlying rate. In addition, the age relatedness of mutation frequency strongly supports the concept that mutation is cell division dependent and that cellular proliferation per se is an important risk factor for cancer. Comparison of somatic mutations with those in the human germline mutation suggests common mechanistic origins and that the high levels of somatic mutation that occur are a direct reflection of the germline mutation rate selected over evolutionary time. Thus, the somatic accumulation of mutations can be seen as a natural process within the human body and cancer a normal part of the human life cycle. This point of view may explain why it has been so difficult to significantly reduce cancer incidence and suggests that, for this to be achieved, the means of altering the natural somatic mutation rate needs to be identified.

Multilocus DNA fingerprinting reveals high rate of heritable genetic mutation in herring gulls nesting in an industrialized urban site

Genotoxins, such as polycyclic aromatic compounds, are ubiquitous in urban and industrial environments. Our understanding of the role that these chemicals play in generating DNA sequence mutations is predominantly derived from laboratory studies with specific genotoxins or extracts of contaminants from environmental media. Most assays are not indicative of the germinal effects of exposure in situ to complex mixtures of common environmental mutagens. Using multilocus DNA fingerprinting, we found the mutation rate in herring gulls inhabiting a heavily industrialized urban harbor (Hamilton Harbour, Ontario) to be more than twice as high as three rural sites: Kent Island, Bay of Fundy; Chantry Island, Lake Huron; and Presqu'ile Provincial Park in Lake Ontario. Overall we found a mutation rate of 0.017 +/- 0.004 per offspring band in Hamilton, 0.006 +/- 0.002 at Kent Island, 0.002 +/- 0.002 from Chantry Island, and 0.004 +/- 0.002 from Presqu'ile Provincial Park. The mutation rate from the rural sites (pooled) was significantly lower than the rate observed in Hamilton Harbour (Fisher's exact test, two-tailed; P = 0.0006). These minisatellite DNA mutations may be important biomarkers for heritable genetic changes resulting from in situ exposure to environmental genotoxins in a free-living vertebrate species.