Isolation and characterization of mouse minisatellites

A Fast and Specific Alignment Method for Minisatellite Maps

Background

Variable minisatellites count among the most polymorphic markers of eukaryotic and prokaryotic genomes. This variability can affect gene coding regions, like in the prion protein gene, or gene regulation regions, like for the cystatin B gene, and be associated or implicated in diseases: the Creutzfeld-Jakob disease and the myoclonus epilepsy type 1, for our examples. When it affects neutrally evolving regions, the polymorphism in length ( i.e., in number of copies) of minisatellites proved useful in population genetics.

Motivation

In these tandem repeat sequences, different mutational mechanisms let the number of copies, as well as the copies themselves, vary. Especially, the interspersion of events of tandem duplication/contraction and of punctual mutation makes the succession of variant repeats much more informative than the sole allele length. To exploit this information requires the ability to align minisatellite alleles by accounting for both punctual mutations and tandem duplications.

Results

We propose a minisatellite maps alignment program that improves on previous solutions. Our new program is faster, simpler, considers an extended evolutionary model, and is available to the community. We test it on the data set of 609 alleles of the MSY1 (DYF155S1) human minisatellite and confirm its ability to recover known evolutionary signals. Our experiments highlight that the informativeness of minisatellites resides in their length and composition polymorphisms. Exploiting both simultaneously is critical to unravel the implications of variable minisatellites in the control of gene expression and diseases.

Availability

Software is available at http://atgc.lirmm.fr/ms_align/

Species-wide distribution of highly polymorphic minisatellite markers suggests past and present genetic exchanges among house mouse subspecies

Global analysis of four minisatellite loci in House Mouse reveals unexpected long-range gene flow between populations and subspecies.

Background

Four hypervariable minisatellite loci were scored on a panel of 116 individuals of various geographical origins representing a large part of the diversity present in house mouse subspecies. Internal structures of alleles were determined by minisatellite variant repeat mapping PCR to produce maps of intermingled patterns of variant repeats along the repeat array. To reconstruct the genealogy of these arrays of variable length, the specifically designed software MS_Align was used to estimate molecular divergences, graphically represented as neighbor-joining trees.

Results

Given the high haplotypic diversity detected (mean H_e = 0.962), these minisatellite trees proved to be highly informative for tracing past and present genetic exchanges. Examples of identical or nearly identical alleles were found across subspecies and in geographically very distant locations, together with poor lineage sorting among subspecies except for the X-chromosome locus MMS30 in Mus mus musculus. Given the high mutation rate of mouse minisatellite loci, this picture cannot be interpreted only with simple splitting events followed by retention of polymorphism, but implies recurrent gene flow between already differentiated entities.

Conclusion

This strongly suggests that, at least for the chromosomal regions under scrutiny, wild house mouse subspecies constitute a set of interrelated gene pools still connected through long range gene flow or genetic exchanges occurring in the various contact zones existing nowadays or that have existed in the past. Identifying genomic regions that do not follow this pattern will be a challenging task for pinpointing genes important for speciation.

Assessing radiation-associated mutational risk to the germline: repetitive DNA sequences as mutational targets and biomarkers

This review assesses recent data on mutational risk to the germline after radiation exposure obtained by molecular analysis of tandemly repeated DNA loci (TRDLs): minisatellites in humans and expanded simple tandem repeats in mice. Some studies, particularly those including exposure to internal emitters, indicate that TRDL mutation can be used as a marker of human radiation exposure; most human studies, however, are negative. Although mouse studies have suggested that TRDL mutation analysis may be more widely applicable in biomonitoring, there are important differences between the structure of mouse and human TRDLs. Mutational mechanisms probably differ between the two species, and so care should be taken in predicting effects in humans from mouse data. In mice and humans, TRDL mutations are largely untargeted with only limited evidence of dose dependence. Transgenerational mutation has been observed in mice but not in humans, but the mechanisms driving such mutation transmission are unknown. Some minisatellite variants are associated with human diseases and may affect gene transcription, but causal relationships have not yet been established. It is concluded that at present the TRDL mutation data do not warrant a dramatic revision of germline or cancer risk estimates for radiation.

Expanded simple tandem repeat (ESTR) mutation induction in the male germline: lessons learned from lab mice

Expanded simple tandem repeat (ESTR) DNA loci that are unstable in the germline have provided the most sensitive tool ever developed for investigating low-dose heritable mutation induction in laboratory mice. Ionizing radiation exposures have shown that ESTR mutations occur mainly in pre-meiotic spermatogonia and stem cells. The average spermatogonial doubling dose is 0.62-0.69 Gy for low LET, and 0.18-0.34 Gy for high LET radiation. Chemical alkylating agents also cause significant ESTR mutation induction in pre-meiotic spermatogonia and stem cells, but are much less effective per unit dose than radiation. ESTR mutation induction efficiency is maximal at low doses of radiation or chemical mutagens, and may decrease at higher dose ranges. DNA repair deficient mice (SCID and PARP-1) with elevated levels of single and double-strand DNA breaks have spontaneously elevated ESTR mutation frequencies, and surprisingly do not show additional ESTR mutation induction following irradiation. In contrast, ESTR mutation induction in p53 knock-outs is indistinguishable from that of wild-type mice. Studies of sentinel mice exposed in situ to ambient air pollution showed elevated ESTR mutation frequencies in males exposed to high levels of particulate matter. These studies highlight the application of the ESTR assay for assessing environmental hazards under real-world conditions. All ESTR studies to date have shown untargeted mutations that occur at much higher frequencies than predicted. The mechanism of this untargeted mutation induction is unknown, and must be elucidated before we can fully understand the biological significance of ESTR mutations, or use these markers for formal risk assessment. Future studies should focus on the mechanism of ESTR mutation induction, refining dose responses, and developing ESTR markers for other animal species.

Sipa1 is a candidate for underlying the metastasis efficiency modifier locus Mtes1

We previously identified loci in the mouse genome that substantially influence the metastatic efficiency of mammary tumors. Here, we present data supporting the idea that the signal transduction molecule, Sipa1, is a candidate for underlying the metastasis efficiency modifier locus Mtes1. Analysis of candidate genes identified a nonsynonymous amino acid polymorphism in Sipa1 that affects the Sipa1 Rap-GAP function. Spontaneous metastasis assays using cells ectopically expressing Sipa1 or cells with knocked-down Sipa1 expression showed that metastatic capacity was correlated with cellular Sipa1 levels. We examined human expression data and found that they were consistent with the idea that Sipa1 concentration has a role in metastasis. Taken together, these data suggest that the Sipa1 polymorphism is one of the genetic polymorphisms underlying the Mtes1 locus. This report is also the first demonstration, to our knowledge, of a constitutional genetic polymorphism affecting tumor metastasis.

The individuality of mice

Mutant mice simulating human CNS disorders are used as models for therapeutic drug development. Drug evaluation requires a coherent correlation between behavioral phenotype and drug status. Variations in behavioral responses could mask such correlations, a problem highlighted by the three-site studies of Crabbe et al. (1999) and Wahlsten et al. (2003a). Factors contributing to variation are considered, focusing on differences between individual animals. Genetic differences due to minisatellite variation suggest that each mouse is genetically distinct. Effects during gestation, including maternal stress, influence later life behavior; while endocrine exchanges between fetus and parent, and between male and female fetuses dependent on intrauterine position, also contribute. Pre and perinatal nutrition and maternal attention also play a role. In adults, endocrine cyclicity in females is a recognized source of behavioral diversity. Notably, there is increasing recognition that groups of wild and laboratory mice have complex social structures, illustrated through consideration of Crowcroft (1966). Dominance status can markedly modify behavior in test paradigms addressing anxiety, locomotion and aggressiveness, to an extent comparable to mutation or drug status. Understanding how such effects amplify the behavioral spectrum displayed by otherwise identical animals will improve testing.

Advances in the application of germline tandem repeat instability for in situ monitoring

Alterations in tandem repetitive DNA sequences such as minisatellite DNA and expanded simple tandem repeats (ESTRs) may provide useful biomarkers of induced germline effects. In this review, I describe the differences between ESTRs and minisatellites with respect to their structure and mutational mechanisms, and discuss field applications measuring induced germline instability. It is evident that both types of loci have high rates of mutation that facilitate the measurement of induced mutation measured in relatively small numbers of samples following environmentally relevant exposures. Several research groups have used these loci to demonstrate a significant increase in germline mutation in humans and animals exposed to radioactive or chemical pollutants in their natural environment. Mutations are manifested as gains or losses in repeat units and are detected either by pedigree screening or by PCR amplification of sperm DNA. Mutations at both ESTRs and minisatellites appear to arise via indirect mechanisms rather than by direct damage to the repeat locus itself. Most interestingly, ESTR instability following radiation has been shown to be heritable and transmitted to subsequent generations. An understanding of the mechanisms involved in induced instability is required in order to begin to decipher the potential biological implications of increased germline tandem repeat mutation. Furthermore, relatively few studies have investigated the ability of different genotoxins to induce tandem repeat instability. Such laboratory-based experiments will be crucial in clarifying the particular environmental or occupational exposures that should be targeted for future studies and for isolating and subsequently identifying the putative mutagens in complex environmental matrices.

Sexual selection, germline mutation rate and sperm competition

BACKGROUND

An important component of sexual selection arises because females obtain viability benefits for their offspring from their mate choice. Females choosing extra-pair fertilization generally favor males with exaggerated secondary sexual characters, and extra-pair paternity increases the variance in male reproductive success. Furthermore, females are assumed to benefit from 'good genes' from extra-pair sires. How additive genetic variance in such viability genes is maintained despite strong directional selection remains an evolutionary enigma. We propose that sexual selection is associated with elevated mutation rates, changing the balance between mutation and selection, thereby increasing variance in fitness and hence the benefits to be obtained from good genes sexual selection. Two hypotheses may account for such elevated mutation: (1) Increased sperm production associated with sperm competition may increase mutation rate. (2) Mutator alleles increase mutation rates that are revealed by the expression of condition-dependent secondary sexual characters used by choosy females during their mate choice. M Petrie has independently developed the idea that mutator alleles may account for the maintenance of genetic variation in viability despite strong directional selection.

RESULTS

A comparative study of birds revealed a positive correlation between mutation rate at minisatellite loci and extra-pair paternity, but not between mutation rate and relative testes mass which is a measure of relative sperm production. Minisatellite mutation rates were not related to longevity, suggesting a meiotic rather than a mitotic origin of mutations.

CONCLUSION

We found evidence of increased mutation rate in species with more intense sexual selection. Increased mutation was not associated with increased sperm production, and we suggest that species with intense sexual selection may maintain elevated mutation rates because sexual selection continuously benefits viability alleles expressed in condition-dependent characters. Sexual selection may increase mutational input, which in turn feeds back on sexual selection because of increased variance in viability traits.

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.

Minisatellites show rare and simple intra-allelic instability in the mouse germ line

Minisatellites provide very informative systems for analyzing processes of tandem repeat DNA turnover in humans. The mouse genome also contains authentic minisatellites, but none has yet been found to show high levels of instability. Indirect evidence using minisatellite variant repeat mapping by PCR in Mus musculus subspecies suggested that mouse minisatellites mutate at a rate below 10(-3) per gamete and mainly by intra-allelic events. This is in sharp contrast to the complex interallelic mutations observed at high frequency at some human loci. To define more directly the turnover mechanisms and rates of instability at one of the most variable mouse minisatellites (MMS80), we used size-enrichment small-pool PCR (SESP-PCR) to recover de novo mutant alleles from sperm DNA from homozygous BALB/cJ mice and from strain DHA heterozygotes. The sperm mutation rate at MMS80 was extremely low, at or below 5 x 10(-6) per sperm. Comparison of progenitor and mutant allele structures showed that these rare mutants had arisen by simple and primarily, if not exclusively, intra-allelic mutation events. These results suggest a fundamental difference in turnover mechanisms at minisatellites between mice and human.

Ionising radiation and mutation induction at mouse minisatellite loci. The story of the two generations

The analysis of the effects of ionising radiation on germline mutations is limited by the number of offspring that need to be analysed following exposure to a dose, which is relevant to risk assessment in humans. We have developed a new experimental approach using hypervariable mouse expanded simple tandem repeat (ESTR) loci (minisatellites) which are both highly sensitive to ionising radiation and which permit changes in mutation rates to be detected in relatively small samples. Here, we review the progress made in validating the model, and the unexpected features it has revealed, including a novel form of radiation-induced genetic instability that can be transmitted from one generation to the next.

No correlation between germline mutation at repeat DNA and meiotic crossover in male mice exposed to X-rays or cisplatin

To test the hypothesis that mouse germline expanded simple tandem repeat (ESTR) mutations are associated with recombination events during spermatogenesis, crossover frequencies were compared with germline mutation rates at ESTR loci in male mice acutely exposed to 1Gy of X-rays or to 10mg/kg of the anticancer drug cisplatin. Ionising radiation resulted in a highly significant 2.7-3.6-fold increase in ESTR mutation rate in males mated 4, 5 and 6 weeks after exposure, but not 3 weeks after exposure. In contrast, irradiation had no effect on meiotic crossover frequencies assayed on six chromosomes using 25 polymorphic microsatellite loci spaced at approximately 20cM intervals and covering 421cM of the mouse genome. Paternal exposure to cisplatin did not affect either ESTR mutation rates or crossover frequencies, despite a report that cisplatin can increase crossover frequency in mice. Correlation analysis did not reveal any associations between the paternal ESTR mutation rate and crossover frequency in unexposed males and in those exposed to X-rays or cisplatin. This study does not, therefore, support the hypothesis that mutation induction at mouse ESTR loci results from a general genome-wide increase in meiotic recombination rate.

Minisatellites: mutability and genome architecture

Minisatellites have been found in association with important features of human genome biology such as gene regulation, chromosomal fragile sites, and imprinting. Our knowledge of minisatellite biology has greatly increased in the past 10 years owing to the identification and careful analysis of human hypermutable minisatellites, experimental models in yeast, and recent in vitro studies of minisatellite recombination properties. In parallel, minisatellites have been put forward as potential biomarkers for the monitoring of genotoxic agents such as ionizing radiation. We summarize and discuss recent observations on minisatellites. In addition we take advantage of recent whole chromosome sequence data releases to provide a unifying view which may facilitate the annotation of tandem repeat sequences.

Somatic versus germline mutation processes at minisatellite CEB1 (D2S90) in humans and transgenic mice

The most variable human minisatellites show extreme germline instability dominated by complex intra-allelic rearrangements plus a lower frequency of inter-allelic transfers of repeat units. In contrast, little is known about somatic instability at such loci. We have therefore used single-molecule PCR to analyze mutation at minisatellite CEB1 (D2S90) in human blood DNA. Somatic mutants were rare and involved only relatively simple intra-allelic events, with no bias toward expansions, in sharp contrast to the complex gain-biased rearrangements seen in sperm. Somatic and germline mutation processes were further analyzed in mice transgenic for a cosmid insert containing CEB1. Mutant molecules in transgenic sperm and blood were detected but only at the low frequencies seen in human blood and arose mainly by simple duplications and deletions as seen for somatic mutations in human. These data suggest distinct pathways for germline and somatic CEB1 mutations with germline instability involving recombination-based repair of meiotic double-strand breaks and somatic mutation arising by replication slippage or mitotic recombination. The problem of transferring germline-specific features of minisatellite instability from human to mouse suggests, with other recent observations, that long-range chromatin conformation may be required for the recombination-based mode of germline instability at human minisatellites.

Meiotic interallelic conversion at the human minisatellite MS32 in yeast triggers recombination in several chromatids

Tandem repetitive DNA sequences such as minisatellites include the most polymorphic loci yet identified in the human genome. The high mutation rates at many of these loci are driven by incompletely understood recombination-based mechanisms that operate in the germline. To analyse aspects of minisatellite mutation processes and general eukaryotic recombination in meiosis that cannot be studied in humans or other mammals, including crosstalk and interplay between all four chromatids, we have previously constructed a eukaryotic model system, enabling the analysis of all four products of meiosis. In this system we have integrated alleles of the human minisatellite MS32, flanked by synthetic markers, in the vicinity of a meiotic recombination hot spot in chromosome III of Saccharomyces cerevisiae. In the present study, tetrad analysis showed that gene conversion is the predominant and possibly the universal pathway leading to interallelic transfer of repeats, with or without exchange of flanking regions. The data also suggest a hyper-recombinogenic state, triggered by interallelic mutation processes which generate a cascade of mutant alleles in the same meiosis. A number of tetrads contained identical mutant alleles of meiotic origin. Several tetrads could not be explained by the current models for minisatellite mutation. Accordingly, we here present a modified model based on the successive repair of multiple double-strand breaks.

Direct analysis by small-pool PCR of MS205 minisatellite mutation rates in sperm after mutagenic therapies

We have used small-pool PCR to analyse mutation in samples of sperm taken from men after mutagenic therapy. Small-pool PCR uses direct analysis of germline DNA at a highly unstable tandem-repeated "minisatellite" locus to measure rates of length-change mutation in individual sperm samples. The advantages of this approach are that the normal mutation rate is extremely high (about 0.4% per gamete at the locus analysed here), so that relatively small increases in mutation rate can be detectable in individual samples. It is known from work on sperm from untreated individuals that different alleles at this locus have different mutation rates. For this reason, we have analysed the germline mutation rates in sperm samples from two men, in each case comparing a post-treatment sample with a pre-treatment sample from the same individual. We find no evidence for altered mutation in the post-treatment sample, suggesting that the repopulation of the germ-cell compartment after treatment may be subject to stringent mechanisms for the detection and elimination of germ-cell damage.

Cis-regulation of inter-allelic exchanges in mutation at human minisatellite MS205 in yeast

Tandemly repeated DNA is a major component of the human genome, and includes loci contributing to human disease. Minisatellites include the most variable human loci described to date, and the mechanisms by which this variation is generated in humans have been studied in detail. Integration of human minisatellites into yeast not only provides a model for further dissecting the molecular basis of length change mutation at these loci, but also more generally allows the study of complex recombinational events in yeast. We have used human minisatellite MS205 integrated into yeast to study the structural details of length change mutations. Apart from showing that mutation at this locus in yeast has features similar to those observed at some minisatellites in humans, including meiosis-specificity, and polarity, in which exchange events are localised to one extremity of the array, we here, for the first time, directly demonstrate that a flanking element in yeast regulates the mutation process. The results therefore support the hypothesis that flanking initiators are involved in minisatellite mutation in humans. Furthermore, mutant alleles showed more complex rearrangements in one orientation than the other. The data also suggest that the mutational pathway for deletions might be different from the pathway generating inter-allelic exchanges and duplications.