Germline mutations of tetranucleotide DNA repeats in families with normal children and reproductive pathology

We have previously reported a high rate of tetranucleotide DNA repeat mutations, including mutations of both germline and somatic origin, in spontaneous human abortuses. To analyze in more detail mutational microsatellite (MS) variability in meiosis and its possible association with disturbed embryonic development, we have conducted a comparative study of mutation rates of a complex of 15 autosomal tetranucleotide MSs in 55 families with healthy children and in 103 families that have had spontaneous abortuses with normal karyotypes. In the families with miscarriage, the gametic MS mutation rate was higher than in the families with normal reproductive function (4.36 x 10(-3) versus 2.32 x 10(-3) per locus per gamete per generation), but this difference was statistically nonsignificant (P = 0.25). No association of MS mutations with familiar miscarriage was found. Mutations at the MS loci studied were recorded almost 3 times as often in spermatogenesis as in oogenesis, which is likely to result from a greater number of DNA replication cycles in male germline cell precursors than in female ones. Mutations increasing and reducing the MS sequence length appeared at virtually the same rate. Changes in MS DNA sequence length per one repeated element, i.e., single-step mutations (93% of cases) exceeded all other events of allele length change. The highest number of mutations (81.2%) was found in longer alleles. This distribution of mutations by size, direction, and parental origin corresponds to the multistep mutation model of their emergence via mechanism of DNA strand slippage during replication.     

Germline Mutations of Tetranucleotide DNA Repeats in Families with Normal Children and Reproductive Pathology

We have previously reported a high rate of tetranucleotide DNA repeat mutations, including mutations of both germline and somatic origin, in spontaneous human abortions. To analyze in more detail mutational microsatellite (MS) variability in meiosis and its possible association with disturbed embryonic development, we have conducted a comparative study of mutation rates of a panel of 15 autosomal tetranucleotide MSs in 55 families with healthy children and in 103 families that have had spontaneous abortions with normal karyotypes. In the families with miscarriage, the gametic MS mutation rate was higher than in the families with normal reproductive function (4.36 × 10⁻³ versus 2.32 × 10⁻³ per locus per gamete per generation), but this difference was statistically nonsignificant (P = 0.25). No association of MS mutations with familiar miscarriage was found. Mutations at the MS loci studied were recorded almost 3 times as often in spermatogenesis as in oogenesis, which is likely to result from a greater number of DNA replication cycles in male germline cell precursors than in female ones. Mutations increasing and reducing the MS sequence length appeared at virtually the same rate. Changes in MS DNA sequence length per one repeated element, i.e., single-step mutations (93% of cases) exceeded all other events of allele length change. The highest number of mutations (81.2%) was found in longer alleles. This distribution of mutations by size, direction, and parental origin corresponds to the multistep mutation model of their emergence via mechanism of DNA strand slippage during replication.__________Translated from Genetika, Vol. 41, No. 7, 2005, pp. 943–953.Original Russian Text Copyright © 2005 by Nikitina, Lebedev, Sukhanova, Nazarenko.     

Multiple levels of single-strand slippage at cetacean tri- and tetranucleotide repeat microsatellite loci.

Between three and six tri- and tetranucleotide repeat microsatellite loci were analyzed in 3720 samples collected from four different species of baleen whales. Ten of the 18 species/locus combinations had imperfect allele arrays, i.e., some alleles differed in length by other than simple integer multiples of the basic repeat length. The estimate of the average number of alleles and heterozygosity was higher at loci with imperfect allele arrays relative to those with perfect allele arrays. Nucleotide sequences of 23 different alleles at one tetranucleotide repeat microsatellite locus in fin whales, Balaenoptera physalus, and humpback whales, Megaptera novaeangliae, revealed sequence changes including perfect repeats only, multiple repeats, and partial repeats. The relative rate of the latter two categories of mutation was estimated at 0.024 of the mutation rate involving perfect repeats only. It is hypothesized that single-strand slippage of partial repeats may provide a mechanism for counteracting the continuous expansion of microsatellite loci, which is the logical consequence of recent reports demonstrating directional mutations. Partial-repeat mutations introduce imperfections in the repeat array, which subsequently could reduce the rate of single-strand slippage. Limited computer simulations confirmed this predicted effect of partial-repeat mutations.     

The mutation rates of di-, tri- and tetranucleotide repeats in Drosophila melanogaster

In a recent study, we reported that the combined average mutation rate of 10 di-, 6 tri-, and 8 tetranucleotide repeats in Drosophila melanogaster was 6.3 x 10(-6) mutations per locus per generation, a rate substantially below that of microsatellite repeat units in mammals studied to date (range = 10(-2)-10(-5) per locus per generation). To obtain a more precise estimate of mutation rate for dinucleotide repeat motifs alone, we assayed 39 new dinucleotide repeat microsatellite loci in the mutation accumulation lines from our earlier study. Our estimate of mutation rate for a total of 49 dinucleotide repeats is 9.3 x 10(-6) per locus per generation, only slightly higher than the estimate from our earlier study. We also estimated the relative difference in microsatellite mutation rate among di-, tri-, and tetranucleotide repeats in the genome of D. melanogaster using a method based on population variation, and we found that tri- and tetranucleotide repeats mutate at rates 6.4 and 8.4 times slower than that of dinucleotide repeats, respectively. The slower mutation rates of tri- and tetranucleotide repeats appear to be associated with a relatively short repeat unit length of these repeat motifs in the genome of D. melanogaster. A positive correlation between repeat unit length and allelic variation suggests that mutation rate increases as the repeat unit lengths of microsatellites increase.      

Isolation and characterization of polymorphic microsatellites in European chestnut (Castanea sativa Mill.)

Thirteen polymorphic microsatellite loci were isolated from Castanea sativa (Mill.). Six contained dinucleotide repeats, six contained trinucleotide repeats, and one contained a compound microsatellite of a trinucleotide and a tetranucleotide repeat. The loci were characterized using C. sativa trees from three populations in the UK and the parents and six seedlings from a Turkish mapping population. The number of alleles revealed varied from two to 14 (mean = 5.15) per loci. Eight loci were found to be useful in the mapping family.     

Individual variation in microsatellite mutation rate in barn swallows

The hypermutable nature of some microsatellite loci implies realistic possibilities for the large-scale detection of germline mutations by pedigree analysis. We have developed a model system for mutation analysis by the characterisation of patterns of mutation at three hypervariable microsatellites (two tetranucleotide and one pentanucleotide repeat loci) in barn swallows, all three markers having mutation rates at the percentage level. Here, we study how the mutation rate varies between individual birds of a Spanish population of barn swallows. A total of 53 mutations were identified from 2920 germline transmissions in 90 families with a total of 694 offspring. Mutations were not randomly distributed among individuals (P = 0.020). Attempts to correlate mutation rate with allele size, degree of inbreeding, immunocompetence and male age only revealed a strong effect of allele size. The mean mutation rate differed between colonies of breeding swallows which was probably due to a corresponding variation in allele size between colonies. There was no difference in the mean mutation rate between the Spanish and an Italian population. These results corroborate earlier findings, at the population level, of an allele size effect on the microsatellite mutation rate.     

Heterogeneity in the rate and pattern of germline mutation at individual microsatellite loci

There is a lack of information on how individual microsatellite loci differ with respect to their mutation properties. Such variation will have an important bearing on our understanding of the ubiquitous occurrence of simple repeat sequences in eukaryotic genomes and on deriving proper mutation models that can be incorporated into genetic distance estimates. We genotyped ~100 families of the bird barn swallow (Hirundo rustica) for two hypervariable (heterozygosity >95%) microsatellite markers: HrU6, an (AAAG)_n tetranucleotide repeat, and HrU10, an (AAGAG)_n pentanucleotide repeat. A total of 27 germline mutation events were documented, corresponding to mutation rates of 0.57% (HrU6) and 1.56% (HrU10). The mutation rate increased with allele size, at ~0.1% per repeat unit over the observed range of allele sizes (~10–100 repeat units). Single repeat unit changes dominated, with 21/27 mutations representing the gain or loss of one repeat unit. There was no clear difference in the number of gains versus losses nor was there an effect of allele size on the magnitude or direction of mutation. Unexpectedly, the mutation rate of females (maternally transmitted mutations) was 2.5–5 times higher than that of males. Contrasting these observations with mutation data from other microsatellite loci reveals differences not only in the mutation rate, but also in the magnitude, direction and effect of sex on mutation. Thus, microsatellite mutation and evolution may be viewed as a dynamic and variable process.     

Extremely complex pattern of microsatellite mutation in the germline of wheat exposed to the post-Chernobyl radioactive contamination

The molecular structure of rare variants at 13 microsatellite loci found in a population of wheat plants grown for one generation in the heavily contaminated 30 km exclusion zone around the Chernobyl Nuclear Power Plant and in a control population was compared. Evidence for rare alterations (variants) was obtained for all 13 loci, including gain and loss of repeats, as well as the complete loss of microsatellite bands. The ratio between gains and losses among variants in the control group was similar to that in the exposed group. Sequencing of variants at six microsatellite loci found in the exposed population revealed extremely complex pattern of germline mutations, including complete deletions of loci, a bias towards mutations with gains and losses of multiple repeat units, and relatively frequent insertions of DNA of unknown origin. The occurrence of large deletions at two loci may be attributed to direct and inverted repeats sequences located just upstream and downstream of the array. The results of our study also suggest that the majority of mutations within the studied wheat microsatellite loci are represented by gains and losses of multiple repeat units, implying that a simple model of replication slippage cannot account for mutation events at these loci. Our data also support the conclusion that the spectra of spontaneous and radiation-induced mutation in wheat may be similar.     

Radiation-induced untargeted germline mutations in Japanese medaka

Radiation has been shown to increase mutation frequencies at tandem repeat loci by indirect interactions of radiation with DNA. We studied germline mutations in chronically exposed Japanese medaka (Oryzias latipes) using microsatellite loci. After screening 26 randomly selected loci among unirradiated parents and their 200 offspring, we selected seven highly mutable loci (0.5-1.0 x 10(-2) mutants per locus per gamete) and two bonus loci for further study. To determine if radiation exposure increases mutation frequencies in these loci, medaka were chronically irradiated from subadults through maturation at relatively low dose rates of 68 mGy/d. Total doses for males and females were 10.4 and 3 Gy, respectively. The mean number of mutations for the offspring of exposed families (0.149+/-0.044) was significantly higher (P=0.018) than for control families (0.080+/-0.028), indicating induction of germline mutations from chronic irradiation. This increase in the microsatellite mutation rate is greater than expected from direct interaction of radiation with DNA, suggesting indirect, untargeted mechanism(s) for mutations. This study identified microsatellite loci with a high mutational background in medaka, variation among loci and families as important variables, and demonstrated the usefulness of this fish model for studying radiation-induced germline mutations.     

High somatic instability of a microsatellite locus in a clonal tree,<Emphasis Type="Italic"> Robinia pseudoacacia</Emphasis>

Robinia pseudoacacia L. is a clonal tree species. To investigate a mutation within eight microsatellite loci of R. pseudoacacia, we analyzed DNA samples obtained from different leaf samples within each ramet, leaves from ramets within the genet, and seeds. Of the eight loci, locus Rops15 (AG motif) displayed hypermutability. The mutation rates of Rops15 within each ramet, among ramets within the genet, and offspring were 6.27% (ranging from 0 to 31.1%), 6.11% (from 0 to 25.0%) and 3.78% (from 0 to 10.9%), respectively. The mutation rate increased with allele size (13–71 repeat units). The mutation patterns observed in Rops15 were distinctive in two ways. First, there was a significant bias toward additions over deletions, and both addition and deletion of single repeats were dominant at alleles with lengths less than 232 bp (63 repeats). Second, for the longest allele of 248 bp (71 repeats), the number of losses was higher than the number of gains. These observations suggest that the mutation patterns of microsatellites in R. pseudoacacia may follow a generalized stepwise mutation model, and that the tendency of long alleles to mutate to shorter lengths acts to prevent infinite growth. Finally, the observation of somatic hypermutability at locus Rops15 highlights the need for caution when using highly polymorphic microsatellites for population genetic structure and paternity analysis in tree species.Communicated by H.F. Linskens     

Mini-and microsatellite mutations in children from Chernobyl accident cleanup workers

Knowledge about possible genotoxic effects of low-dose radiation on the human germline is limited and relies primarily on extrapolations from high-dose exposures. To test whether ionizing radiation can cause paternal genetic mutations that are transmitted to offspring, we enrolled families of 88 Chernobyl cleanup workers exposed to ionizing radiation. We analyzed DNA isolated from lymphocytes for mutations via DNA blotting with the multi-locus minisatellite probes 33.6 and 33.15 and via PCR in a panel of six tetranucleotide repeats. Children conceived before and children conceived after their father's exposure showed no statistically significant differences in mutation frequencies. We saw an increase in germline microsatellite mutations after radiation exposure that was not statistically significant. We found no dependence of mutation rate on increasing exposure. A novel finding was that the tetranucleotide marker D7S1482 demonstrated germline hypermutability. In conclusion, our results do not support an increased level of germline minisatellite mutations but suggest a modest increase in germline mutations in tetranucleotide repeats. Small sample size, however, limited statistical power.     

Analysis of somatic mutations at human minisatellite loci in tumors and cell lines

Hypervariable human minisatellite loci show a substantial level of germline instability, and spontaneous mutation rates to new length alleles have been measured directly by pedigree analysis. We now show that mutation events altering the number of minisatellite repeat units are not restricted to the germline, but also arise in other tissues. Mutant alleles can be detected at a very low frequency in lymphoblastoid cell lines and at much higher frequencies in clonal tumor cell populations, most particularly in gastrointestinal adenocarcinomas. Mutant alleles in these tumors are usually present at a dosage equal to or greater than that of the progenitor allele, indicating that most or all of the tumor cells carry the same clonally derived mutant allele. As with germline mutation, the incidence of somatic mutations in tumors varies from locus to locus, with the same locus showing the highest level of germline and somatic instability. Most length changes, as those in the germline, are of only a few repeat units; however, very large changes are also observed, implying that such mutations can occur in the absence of meiosis.     

Mutation rate variation at human dinucleotide microsatellites

Mutation is the ultimate source of genetic variation, and mutation rate is thus an important parameter governing the extent of genetic variation. Microsatellites are highly informative genetic markers that have been widely used in genetic studies. While previous studies showed that the mutation rate differs in di-, tri-, and tetranucleotide repeats, how mutation rate distributes within each class of repeat is poorly understood. This study first revealed the pattern of the mutation rate variation within the dinucleotide repeats. Two data sets were used. The first is the allele frequency data from 115 microsatellites with dinucleotide repeats distributed along the human genome in 10 worldwide populations. The second data set is much larger, consisting of the allele frequency of 5252 dinucleotide repeats from the Genome Database. Mutation rate for each locus is estimated through a new homozygosity-based estimator, which has been shown to be unbiased and highly efficient and is reasonably robust against deviations from the single-step model. The mutation rates among loci can be approximated well by a gamma distribution and its shape parameter can be accurately estimated with this approach. This result provides the basic guidelines for analyzing the large-scale genomic data from microsatellite loci.     

Microsatellite DNA markers in Populus tremuloides.

Markers for eight new microsatellite DNA or simple sequence repeat (SSR) loci were developed and characterized in trembling aspen (Populus tremuloides) from a partial genomic library. Informativeness of these microsatellite DNA markers was examined by determining polymorphisms in 38 P. tremuloides individuals. Inheritance of selected markers was tested in progenies of controlled crosses. Six characterized SSR loci were of dinucleotide repeats (two perfect and four imperfect), and one each of trinucleotide and tetranucleotide repeats. The monomorphic SSR locus (PTR15) was of a compound imperfect dinucleotide repeat. The primers of one highly polymorphic SSR locus (PTR7) amplified two loci, and alleles could not be assigned to a specific locus. At the other six polymorphic loci, 25 alleles were detected in 38 P. tremuloides individuals; the number of alleles ranged from 2 to 7, with an average of 4.2 alleles per locus, and the observed heterozygosity ranged from 0.05 to 0.61, with an average of 0.36 per locus. The two perfect dinucleotide and one trinucleotide microsatellite DNA loci were the most informative. Microsatellite DNA variants of four SSR loci characterized previously followed a single-locus Mendelian inheritance pattern, whereas those of PTR7 from the present study showed a two-locus Mendelian inheritance pattern in controlled crosses. The microsatellite DNA markers developed and reported here could be used for assisting various genetic, breeding, biotechnology, genome mapping, conservation, and sustainable forest management programs in poplars.     

Polymorphic microsatellite and cryptic simple repeat sequence markers in pineapples (Ananas comosus var. comosus)

A rapid method for isolating microsatellite loci in pineapples, based on the 5′‐anchored polymerase chain reaction technique, revealed 137 microsatellite loci (consisting of 62 dinucleotide, 24 trinucleotide, 49 tetranucleotide and 2 hexanucleotide repeats) and 16 cryptically simple repeat sequences. We report on the characterization of 19 polymorphic microsatellite loci and one cryptic simple repeat loci in pineapples. The number of alleles per locus ranged from two to four while the observed heterozygosity ranged from 0.1705 to 1. These markers are useful as tools for detecting levels of genetic variation in pineapple varieties for germplasm management and crossbreeding purposes.     

Hypermutable minisatellites,a human affair?

Minisatellites are a class of highly polymorphic GC-rich tandem repeats. They include some of the most variable loci in the human genome, with mutation rates ranging from 0.5% to >20% per generation. Structurally, they consist of 10- to 100-bp intermingled variant repeats, making them ideal tools for dissecting mechanisms of instability at tandem repeats. Distinct mutation processes generate rare intra-allelic somatic events and frequent complex conversion-like germline mutations in these repeats. Furthermore, turnover of repeats at human minisatellites is controlled by intense recombinational activity in DNA flanking the repeat array. Surprisingly, whereas other mammalian genomes possess minisatellite-like sequences, hypermutable loci have not been identified that suggest human-specific turnover processes at minisatellite arrays. Attempts to transfer minisatellite germline instability to the mouse have failed. However, yeast models are now revealing valuable information regarding the mechanisms regulating instability at these tandem repeats. Finally, minisatellites and tandem repeats provide exquisitely sensitive molecular tools to detect genomic insults such as ionizing radiation exposure. Surprisingly, by a mechanism that remains elusive, there are transgenerational increases in minisatellite instability.     

Nine polymorphic microsatellite loci for the northern leopard frog (Rana pipiens)

We describe the cloning and characterization of nine microsatellite loci from the northern leopard frog. Seven loci consist of tetranucleotide repeats, one locus consists of a dinucleotide repeat and one locus consists of a GT repeat juxtaposed with a GATA repeat. In a sample of 36 frogs from a natural population, polymorphism at these loci ranged from two to 13 alleles per locus with expected heterozygosities ranging from 0.5 to 0.91. These loci will be useful to researchers since this species is used for a broad range of studies.     

Mutation rates in the complex microsatellite MYCL1 and related simple repeats in cultured human cells

Microsatellite instability is a phenotype observed in tumors cells that have defects in DNA mismatch repair (MMR). Most markers used for detecting microsatellite instability are mono- and dinucleotide repeats, but one tetranucleotide repeat (MYCL1) has been reported to be useful for this purpose. The MYCL1 repeat is actually a complex repeat, made up of approximately 14 GAAA tetranucleotides plus various other GA-rich repeats. In order to determine the nature of the instability of the this sequence, we have used a frameshift-reversion assay in MMR-proficient and -deficient human cells to compare the mutation rates and the types of mutation of MYCL1 to those of the related simple repeats (GAAA)17, (GA)17, and (CA)17. We found that the complex repeat was the most stable of the repeats examined in cells deficient in MMR; the tetranucleotide was less stable, while the dinucleotides were the least stable. In MMR-proficient cells, the relative rates were reversed; the MYCL1 repeat was the least stable, the tetranucleotide was more stable, and the dinucleotides were the most stable. These results suggest that MYCL1 and the pure tetranucleotide have relatively low rates of errors during replication, but that the errors in these repeats are corrected less efficiently than those in the smaller repeats. Because of their high rate of instability in MMR-proficient cells, MYCL1 and other tetranucleotide repeats appear to lack specificity for detection of tumors with defective MMR.