Tissue-specific time courses of spontaneous mutation frequency and deviations in mutation pattern are observed in middle to late adulthood in Big Blue mice

To better define the time course of spontaneous mutation frequency in middle to late adulthood of the mouse, measurements were made at 10, 14, 17, 23, 25, and 30 months of age in samples of adipose tissue, liver, cerebellum (90% neurons), and the male germline (95% germ cells). A total of 46 million plaque-forming units (pfus) were screened at the six time points and 1,450 circular blue plaques were harvested and sequenced. These data improve resolution and confirm the previously observed occurrence of at least two tissue-specific profiles of spontaneous mutation frequency (elevation with age in adipose tissue and liver, and constancy with age in neurons and male germ cells), a low mutation frequency in the male germline, and a mutation pattern unchanged with age within a tissue. These findings appear to extend to very old age (30 months). Additional findings include interanimal variation in spontaneous mutation frequency is larger in adipose tissues and liver compared with neurons and male germ cells, and subtle but significant differences in the mutation pattern among tissues, consistent with a minor effect of tissue-specific metabolism. The presumptive unaltered balance of DNA damage and repair with age in the male germline has evolutionary consequences. It is of particular interest given the controversy over whether or not increasing germline mutation frequency with paternal age underlies the reports associating older males with a higher incidence of some types of genetic disease. These most detailed measurements available to date regarding the time course of spontaneous mutation frequency and pattern in individual tissues help to constrain hypotheses regarding the role of mutational mechanisms in DNA repair and aging.

Spontaneous mutation in Big Blue mice from fetus to old age: tissue-specific time courses of mutation frequency but similar mutation types

Transgenic mouse mutation detection systems permit rapid determination of the frequency and type of mutations allowing direct examination of mutational markers for aging, neurodegeneration, and cancer. The Big Blue transgenic mouse mutation detection system was used to determine the frequency and nature of spontaneous mutations versus age in multiple tissue types. Nuclear DNA was extracted from whole fetus at 13.5 days postcoitus (dpc) and from six tissues postbirth (cerebellum, forebrain, thymus, liver, adipose tissue, and male germline) of Big Blue transgenic mice at four ages: 10 days and at 3, 10, and 25 months postbirth. Forty million total plaque-forming units (pfu) were screened. The time course of mutation frequency with age had a significantly different shape in different tissues (P < 10(-6)). By 13.5 dpc, the whole fetus mutation frequency had already started increasing from the theoretical zero at conception to a value that was about one-half the mid-adulthood (3-10 months) average. From 10 days to 3 months, mutation frequency increased significantly in liver (P = 0.007) and showed an increasing trend in cerebellum, forebrain, and thymus. From 3 to 10 months, there was no significant change in mutation frequency in any tissue examined. From 10 to 25 months, the mutation frequency increased significantly in liver (P < 10(-6)) and adipose tissue (P = 0.002), but not in the other tissues examined (cerebellum, forebrain, and male germline). It is of interest that the mutation frequency in the male germline is consistently the lowest, remaining essentially unchanged in old age. The spectrum of mutation types was unaltered with age, tissue type and gender, although, as previously reported, tandem GG-->TT mutations are tissue specific and show significant increases with age and certain hotspots (Buettner VL et al. [1999]: Environ Mol Mutagen 33:320-324; Hill KA et al. [2003]: Mutat Res 534:173-186). The spectrum of mutation types was generally the same for all tissue types, despite the tissue-specific increases in mutation frequency with age. These data provide a useful reference for future studies of endogenous and exogenous mutagenesis.

Mutation frequency is reduced in the cerebellum of Big Blue mice overexpressing a human wild type SOD1 gene

Amyotrophic lateral sclerosis (ALS) is a progressive paralytic disorder caused by motor neuron degeneration. A similar disease phenotype is observed in mice overexpressing a mutant human hSOD1 gene (G93A, 1Gurd(1)). Mice transgenic for lacI (Big Blue) and human mutant (1Gurd(1), Mut hSOD1) or wild type (2Gur, Wt hSOD1) SOD1 genes were used to examine spontaneous mutation, oxidative DNA damage, and neurodegeneration in vivo. The frequency and pattern of spontaneous mutation were determined for forebrain (90% glia), cerebellum (90% neurons) and thymus from 5-month-old male mice. Mutation frequency is not elevated significantly and mutation pattern is unaltered in Mut hSOD1 mice compared to control mice. Mutation frequency is reduced significantly in the cerebellum of Wt hSOD1 mice (1.6x10(-5); P=0.0093; Fisher's Exact Test) compared to mice without a human transgene (2.7x10(-5)). Mutation pattern is unaltered. This first report of an endogenous factor that can reduce in vivo, the frequency of spontaneous mutation suggests potential strategies for lowering mutagenesis related to aging, neurodegeneration, and carcinogenesis.

Spontaneous microdeletions and microinsertions in a transgenic mouse mutation detection system: analysis of age, tissue, and sequence specificity

A total of 3497 independent spontaneous mutations were examined using the Big Blue transgenic mouse mutation detection system. Base substitutions predominate, although 16% of somatic and germline mutations are microdeletions, microinsertions, or deletions combined with insertions. The pattern of microdeletions and microinsertions is similar in both the lacI transgene and the human p53 gene. Single-base deletions (D1) and insertions (I1) are evenly distributed in the lacI transgene, whereas microdeletions from 2 to 50 bp are clustered at two regions (bp 129-228 and 529-628). The pattern of microdeletions and microinsertions is similar between young (< or =3 months) and old (25 months) mice. Brain tissue has a paucity of deletions combined with insertions when compared with that of thymus and nine other tissues (P = 0.01). A 16-bp deletion at lacI base position 272 is a tissue-specific hotspot preferentially occurring in brain. Approximately 68 and 93% of D1 and I1, respectively, occur at mononucleotide repeats. The frequencies of D1 and I1 in mononucleotide repeats increase in an exponential manner with the length of the repeat. The lacI transgene shows similarity to the human p53 gene in the pattern of microdeletions and microinsertions and the size distribution of microdeletions.

The Big Blue(R) transgenic mouse mutation detection assay: the mutation pattern of sectored mutant plaques

There are mutational artifacts in the Big Blue(R) assay and it is important to characterize the source and nature of these mutations. Differences were reported in the mutation patterns of a small sample of 23 sectored and 91 circular mutant plaques derived from skin using the Big Blue(R) transgenic mouse mutation detection system [G. R. Stuart, N.J. Gorelick, J.L. Andrews, J.G. de Boer, B.W. Glickman, The genetic analysis of lacI mutations in sectored plaques from Big Blue transgenic mice, Environ. Mol. Mutagen 28 (1996) 385-392.]. We have extended these observations by analyzing 46 sectored and 224 circular mutant plaques derived from seven tissues. The frequency of sectored mutant plaques is estimated to be 16% with no significant variation with tissue type. However, the patterns of mutation for sectored mutants and mouse-derived mutations differed significantly (p=0.04). Base substitutions in sectored mutant plaques do not show the asymmetries found in circular mutants consistent with integration of a GC rich transgene into the AT rich mammalian genome. Sectored mutants have mutation patterns consistent with a mixture of mouse, in vitro and Escherichia coli-derived mutations. Data on the relative frequencies of different mutant plaque morphologies suggests that overlapped plaques are substantially contaminated by sectored plaques at recommended plating densities.

Spontaneous mutation frequency and pattern in Big Blue mice fed a vitamin E-supplemented diet

Endogenous oxidative DNA damage caused by normal cellular processes may play a vital role in carcinogenesis. To directly test the hypothesis that antioxidants will protect DNA from oxidative damage in vivo, Big Blue((R)) mice were fed either a control diet (66 IU vitamin E/kg diet) or a high-dose vitamin E diet containing 1000 IU vitamin E/kg diet of racemic d,l-alpha-tocopherol acetate from conception until 3 months of age. Using the standard Big Blue((R)) protocol, 15.5 million plaque forming units (pfu) were examined from five tissues (heart, liver, adipose tissue, thymus, and testis) of three control and three high-dose vitamin E supplemented male mice generating 433 mutants, which represented 373 independent mutations upon sequencing the lacI transgene. The alpha-tocopherol tissue concentration increased with high-dose vitamin E supplementation. In four of the tissues, individually or combined, mutation frequency changed little if any with vitamin E supplementation. In adipose tissue, which accumulated the highest levels of vitamin E, mutation frequency was significantly reduced with high-dose vitamin E supplementation (P = 0.047). Within the constraints of sample size, the pattern of mutation in adipose tissue was not altered significantly (P = 0.40). When data from all tissues were combined, a reduction in G:C --> T:A transversions was observed (P = 0.044). These results may have implications for cancer chemoprevention and provide insight into the efficacy of vitamin E supplementation in reducing spontaneous oxidative DNA damage in vivo. More dramatic alterations of mutation frequency and pattern may be observed with higher doses of vitamin E and substitution of the racemic supplement with d-alpha-tocopherol acetate.

Tandem-base mutations occur in mouse liver and adipose tissue preferentially as G:C to T:A transversions and accumulate with age

Tandem-base mutations (TBM) are associated with ultraviolet light and other mutagens. Herein, we report an age- and tissue-specific difference in the frequency of spontaneous TBM in Big Blue transgenic mice. A total of 390 mutants from liver and adipose tissue contained 17 and 4 TBM, respectively, while no TBM were detected in 683 mutants from six other tissues. There was a proportional increase in the frequency of TBM in liver with age (29 days postconception to 25 months of age). Nine TBM (43%) were GG to TT transversions that preferentially occurred at specific sites. The remaining 12 mutants contained at least one transversion mutation each. We speculate that the increase of TBM in liver and adipose tissue with age is due to chronic mutagen exposure, perhaps derived from fat in the diet.

Methylation of CpG dinucleotides in the lacI gene of the Big Blue transgenic mouse

Cytosine residues at CpG dinucleotides can be methylated by endogenous methyltransferases in mammalian cells. The resulting 5-methylcytosine base may undergo spontaneous deamination to form thymine causing G/C to A/T transition mutations. Methylated CpGs also can form preferential targets for environmental mutagens and carcinogens. The Big Blue(R) transgenic mouse has been used to investigate tissue and organ specificity of mutations and to deduce mutational mechanisms in a mammal in vivo. The transgenic mouse contains approximately 40 concatenated lambda-like shuttle vectors, each of which contains one copy of an Escherichia coli lacI gene as a mutational target. lacI mutations in lambda transgenic mice are characterized by a high frequency of spontaneous mutations targeted to CpG dinucleotides suggesting an important contribution from methylation-mediated events. To study the methylation status of CpGs in the lacI gene, we have mapped the distribution of 5-methylcytosines along the DNA-binding domain and flanking sequences of the lacI gene of transgenic mice. We analyzed genomic DNA from various tissues including thymus, liver, testis, and DNA derived from two thymic lymphomas. The mouse genomic DNAs and methylated and unmethylated control DNAs were chemically cleaved, then the positions of 5-methylcytosines were mapped by ligation-mediated PCR which can be used to distinguish methylated from unmethylated cytosines. Our data show that most CpG dinucleotides in the DNA binding domain of the lacI gene are methylated to a high extent (>98%) in all tissues tested; only a few sites are partially (70-90%) methylated. We conclude that tissue-specific methylation is unlikely to contribute significantly to tissue-specific mutational patterns, and that the occurrence of common mutation sites at specific CpGs in the lacI gene is not related to selective methylation of only these sequences. The data confirm previous suggestions that the high frequency of CpG mutations in lacI transgenes is related to the presence of 5-methylcytosine bases.