Two highly polymorphic minisatellites from the pseudoautosomal region of the human sex chromosomes.

Two pseudoautosomal loci DXYS15 and DXYS17 from the pairing region of the human sex chromosomes display a high variability with at least eight alleles each. The structural elements responsible for the polymorphisms have been isolated and sequenced. In both cases the variations result from DNA rearrangements occurring in tandemly repeated sequences (minisatellites) of 21-29 nucleotides for DXYS15 and 28-33 nucleotides for DXYS17. At reduced stringency, the DXYS15 minisatellite detects other hypervariable sequences located in other parts of the genome and hence represents a new family of minisatellites. In contrast to most other known hypervariable families, the DXYS15 hypervariable sequence displays a very high AT content.     

Conservation of intronic minisatellite polymorphisms in the SCK1/SHC2 gene of Hominidae

The neuronally expressed Shc adaptor homolog SCK1/SHC2 gene contains an unusually high number of minisatellites. In humans, twelve different minisatellite sequences are located in introns of SCK1/SHC2 and ten of them are highly polymorphic. Here we used primers developed for humans to screen ten intronic loci of SCK1/SHC2 in chimpanzee and gorilla, and undertook a comprehensive analysis of the genomic sequence to address the evolutionary events driving these variable repeats. All ten loci amplified in chimpanzee and gorilla contained hypervariable and low-variability minisatellites. The human polymorphic locus TR1 was monomorphic in chimpanzee and gorilla, but we detected polymorphic alleles in these apes for the human monomorphic TR7 locus. When we examined the repeat size among these hominoids, there was no consistent variation by length from humans to great apes. In spite of the inconsistent evolutionary dynamics in repeat length variation, exon 16 was highly conserved between humans and great apes. These results suggest that non-coding intronic minisatellites do not show a consistent evolutionary paradigm but evolved with different patterns among each minisatellite locus. These findings provide important insight for minisatellite conservation during hominoid evolution.     

Hypervariable minisatellite DNA sequences in the Indian peafowl Pavo cristatus.

We report here for the first time the large-scale isolation of hypervariable minisatellite DNA sequences from a non-human species, the Indian peafowl (Pavo cristatus). A size-selected genomic DNA fraction, rich in hypervariable minisatellites, was cloned into Charomid 9-36. This library was screened using two multilocus hypervariable probes, 33.6 and 33.15 and also, in a "probe-walking" approach, with five of the peafowl minisatellites initially isolated. Forty-eight positively hybridizing clones were characterized and found to originate from 30 different loci, 18 of which were polymorphic. Five of these variable minisatellite loci were studied further. They all showed Mendelian inheritance. The heterozygosities of these loci were relatively low (range 22-78%) in comparison with those of previously cloned human loci, as expected in view of inbreeding in our semicaptive study population. No new length allele mutations were observed in families and the mean mutation rate per locus is low (less than 0.004, 95% confidence maximum). These loci were also investigated by cross-species hybridization in related taxa. The ability of the probes to detect hypervariable sequences in other species within the same avian family was found to vary, from those probes that are species-specific to those that are apparently general to the family. We also illustrate the potential usefulness of these probes for paternity analysis in a study of sexual selection, and discuss the general application of specific hypervariable probes in behavioral and evolutionary studies.     

Cloning a selected fragment from a human DNA ''fingerprint'': isolation of an extremely polymorphic minisatellite.

A large hypervariable DNA fragment from a human DNA fingerprint was purified by preparative gel electrophoresis and molecular cloning. The cloned fragment contained a 6.3 kb long minisatellite consisting of multiple copies of a 37 bp repeat unit. Each repeat contained an 11 bp copy of the "core" sequences, a putative recombination signal in human DNA. The cloned minisatellite hybridized to a single locus in the human genome. This locus is extremely polymorphic, with at least 77 different alleles containing 14 to 525 repeat units per allele being resolved in a sample of 79 individuals. All alleles except the shortest are rare and the resulting heterozygosity is very high (approximately 97%). Cloned minisatellites should therefore provide a panel of extremely informative locus-specific probes ideal for linkage analysis in man.     

Mouse DNA ''fingerprints'': analysis of chromosome localization and germ-line stability of hypervariable loci in recombinant inbred strains.

Human minisatellite probes cross-hybridize to mouse DNA and detect multiple variable loci. The resulting DNA "fingerprints" vary substantially between inbred strains but relatively little within an inbred strain. By studying the segregation of variable DNA fragments in BXD recombinant inbred strains of mice, at least 13 hypervariable loci were defined, 8 of which could be regionally assigned to mouse chromosomes. The assigned loci are autosomal, dispersed and not preferentially associated with centromeres or telomeres. One of these minisatellites is complex, with alleles 90 kb or more long and with internal restriction endonuclease cleavage sites which produce a minisatellite "haplotype" of multiple cosegregating fragments. In addition, one locus shows extreme germ-line instability and should provide a useful system for studying more directly the rates and processes of allelic variation of minisatellites.     

Characterization of tomato DNA clones with sequence similarity to human minisatellites 33.6 and 33.15

A tomato lambda genomic library was screened with the human minisatellites 33.6 and 33.15. Similar tomato sequences are estimated to occur on average every 4000 kb. In thirteen hybridizing clones characterized, the size of minisatellite arrays varied between 100 bp and 3 kb. The structure of the repetitive elements is complex as the human core sequence is interspersed with other elements. In three cases, sequences similar to the human minisatellites were part of a higher-order tandem repeat. The chromosomal position of these sequences was established by ascertaining linkage to previously mapped RFLP markers. In contrast to the human genome, no clustering of minisatellite loci was observed in tomato. The fingerprints generated by hybridizing tomato minisatellites to genomic DNA of a set of cultivars were, in two cases, more variable than those obtained with 33.6 or 33.15. Two of the characterized probes detected 4–8 alleles of a single locus, which displayed 10–15 times more polymorphism than random RFLP clones. Some minisatellites contain di- and tri-nucleotide microsatellite repeated motifs which may account for the high level of polymorphism detected with these clones.     

Evolutionary transience of hypervariable minisatellites in man and the primates.

Using PCR, two minisatellite loci showing extreme repeat-unit copy-number variation in humans have been characterized in great apes and monkeys. In contrast to humans, minisatellite locus MS32 is monomorphic with only 3-4 diverged repeat units in great apes, Old World and New World monkeys, this organization presumably representing the relatively stable ancestral precursor state of the human hypervariable locus. Similarly, minisatellite MS1 shows extreme repeat-copy-number variability in man compared with low copy number and minimal variability in great apes. Analysis of variant repeat units shows that the 5' and 3' regions of MS1 are relatively stable in great apes and man, and that variability in man is confined to the central region of the minisatellite. In contrast to the great apes, MS1 is highly variable in Old World monkeys. These results, as well as computer simulations of minisatellite evolution based on known mutation rates, show that short minisatellites are stable within the genome, and that the degree of polymorphism at a given locus can change dramatically over a short period of evolutionary time. The ability of hypervariable minisatellites to detect highly informative loci by cross-species hybridization is therefore largely unpredictable.     

Tetrad analysis shows that gene conversion is the major mechanism involved in mutation at the human minisatellite MS1 integrated in Saccharomyces cerevisiae

Minisatellites are arrays of tandemly repeated DNA sequences which occur at thousands of locations in the human genome. They are frequently hypervariable with respect to allele length as a result of high rates of complex and incompletely understood recombination-based germline mutation events that alter the repeat copy number. MS1 is one of the most variable minisatellites so far isolated from the human genome. We have integrated MS1, flanked by synthetic markers, in the vicinity of a hot spot for meiotic double-strand breaks upstream of the LEU2 locus in chromosome III of Saccharomyces cerevisiae. Here we present the first tetrad analysis of mutations at a human minisatellite locus. The data showed that mutant alleles occur as single mutants in one of the spores in a tetrad, also when the mutant structure was the result of a combination of intra- and inter-allelic rearrangements. The conversional transfer of repeat units from one allele to the other was associated with flanking marker conversion which always involved the same flank of the minisatellite. The results demonstrate that conversion is the predominant mechanism by which minisatellite alleles mutate to new lengths, and also support the assumption that cis-acting elements are involved in the regulation of the mutational process in humans.     

A GGCAGG motif in minisatellites affecting their germline instability

Mouse and human genomes contain hypervariable DNA regions consisting of tandem repeats of a short sequence referred to as minisatellites. This variation is thought to arise through processes such as unequal crossover or replication slippage. A mo-1 minisatellite probe comprising a 14-base pair repeat sequence reveals many polymorphic fragments even in DNA of BALB/c sublines. Oligonucleotide probes with single base substitution in the mo-1 have been synthesized and used for assessing sequence involved in generation of polymorphisms. The results indicate that the loci containing mo-1 homologues with mutation in the GGCAGG sequence are monomorphic despite the other mutants showing polymorphism. Reciprocally, locus-specific polymorphic clones, Pc-1 and Pc-2, have been isolated with hybridization to mo-1, and both are shown to contain repeated sequence comprising the GGCAGG sequence. They reveal high mutation rates of 8.8% and 3.3% per gamete, respectively. These results strongly suggest that the motif contributes to the germline instability of minisatellites.     

No evidence of radiation effect on mutation rates at hypervariable minisatellite loci in the germ cells of atomic bomb survivors

Human minisatellites consist of tandem arrays of short repeat sequences, and some are highly polymorphic in numbers of repeats among individuals. Since these loci mutate much more frequently than coding sequences, they make attractive markers for screening populations for genetic effects of mutagenic agents. Here we report the results of our analysis of mutations at eight hypervariable minisatellite loci in the offspring (61 from exposed families in 60 of which only one parent was exposed, and 58 from unexposed parents) of atomic bomb survivors with mean doses of >1 Sv. We found 44 mutations in paternal alleles and eight mutations in maternal alleles with no indication that the high doses of acutely applied radiation had caused significant genetic effects. Our finding contrasts with those of some other studies in which much lower radiation doses, applied chronically, caused significantly increased mutation rates. Possible reasons for this discrepancy are discussed.     

Preparation of synthetic tandem-repetitive probes for DNA fingerprinting

DNA fingerprints are generated using probes that hybridize to hypervariable minisatellites, also known as variable number tandem repeat loci. Cloned minisatellites have served as the predominant source of DNA fingerprinting probes. A short segment within the repeat units of minisatellites, called the "core" sequence, is highly conserved within a family of related minisatellites, thereby allowing a single-cloned minisatellite to cross-hybridize to 20 to 40 other minisatellites. In this article, we describe a method for the synthetic preparation of polymeric core sequence probes for DNA fingerprinting. Unlike "monomeric" oligonucleotide probes, the polymeric probes mimic the tandem-repetitive structure of minisatellites, and thus each probe molecule can potentially form many sites of hybridization with a target minisatellite. The synthetic probes are cloned into plasmid DNA to provide a perpetual source of probe material.     

Amplification of human minisatellites by the polymerase chain reaction: towards DNA fingerprinting of single cells.

Hypervariable minisatellites can be amplified from human DNA by the polymerase chain reaction, using primers from DNA flanking the minisatellite to amplify the entire block of tandem repeat units. Minisatellite alleles up to 5-10 kb long can be faithfully amplified. At least six minisatellite loci can be co-amplified from the same DNA sample and simultaneously detected to provide a reproducible and highly variable DNA fingerprint which can be obtained from nanogram quantities of human DNA. The polymerase chain reaction can also be used to analyse single target minisatellite molecules and single human cells, despite the appearance of spurious PCR products from some hypervariable loci. DNA fingerprinting at the level of one or a few cells therefore appears possible.     

Characterization of minisatellites in Arabidopsis thaliana with sequence similarity to the human minisatellite core sequence.

A strategy based on random PCR amplification was used to isolate new repetitive elements of Arabidopsis thaliana. One of the random PCR product analyzed by this approach contained a tandem repetitive minisatellite sequence composed of 33 bp repeated units. The genomic locus corresponding to this PCR product was isolated by screening a lambda genomic library. New related loci were also isolated from the genomic library by screening with a 14 mer oligonucleotide representing a region conserved among the different repeated units. Alignment of the consensus sequence for each minisatellite locus allowed the definition of an Arabidopsis thaliana core sequence that shows strong sequence similarities with the human core sequence and with the generalized recombination signal Chi of Escherichia coli. The minisatellites were tested for their ability to detect polymorphism, and their chromosomal position was established.     

Identification of hypervariable single locus minisatellite DNA probes in the blue tit Parus caeruleus

We report the isolation of a set of hypervariable minisatellite DNA sequences from a blue tit Parus caeruleus genomic DNA library. In our strategy, we cloned a minisatellite-rich DNA fraction into a charomid vector. The resulting cosmid library was screened with the two minisatellite DNA probes 33.6 and 33.15 for recombinants containing a minisatellite DNA insert. A total of 233 positive clones were isolated. Of 37 clones that have been analysed, nine gave polymorphic signals and can be used as single locus probes (SLPs). Four of the SLPs were investigated in more detail. The number of alleles, the heterozygosity and the mutation rate were estimated. Linkage analysis revealed that two of these loci were linked. The SLPs are of value to studies of the mating system and reproductive success in the blue tit, and may also be useful in population genetic studies.     

Systematic cloning of human minisatellites from ordered array charomid libraries

We present a rapid and efficient method for the isolation of minisatellite loci from human DNA. The method combines cloning a size-selected fraction of human MboI DNA fragments in a charomid vector with hybridization screening of the library in ordered array. Size-selection of large MboI fragments enriches for the longer, more variable minisatellites and reduces the size of the library required. The library was screened with a series of multi-locus probes known to detect a large number of hypervariable loci in human DNA. The gridded library allowed both the rapid processing of positive clones and the comparative evaluation of the different multi-locus probes used, in terms of both the relative success in detecting hypervariable loci and the degree of overlap between the sets of loci detected. We report 23 new human minisatellite loci isolated by this method, which map to 14 autosomes and the sex chromosomes.     

Genome-wide prediction of human VNTRs

Polymorphic minisatellites, also known as variable number of tandem repeats (VNTRs), are tandem repeat regions that show variation in the number of repeat units among chromosomes in a population. Currently, there are no general methods for predicting which minisatellites have a high probability of being polymorphic, given their sequence characteristics. An earlier approach has focused on potentially highly polymorphic and hypervariable minisatellites, which make up only a small fraction of all minisatellites in the human genome. We have developed a model, based on available minisatellite and VNTR sequence data, that predicts the probability that a minisatellite (unit size > or = 6 bp) identified by the computer program Tandem Repeats Finder is polymorphic (VNTR). According to the model, minisatellites with high copy number and high degree of sequence similarity are most likely to be VNTRs. This approach was used to scan the draft sequence of the human genome for VNTRs. A total of 157,549 minisatellite repeats were found, of which 29,224 are predicted to be VNTRs. Contrary to previous results, VNTRs appear to be widespread and abundant throughout the human genome, with an estimated density of 9.1 VNTRs/Mb.     

A panel of VNTR markers in pigs

By cloning tandemly repeated sequences from the pig genome by use of non-porcine minisatellite probes for library screening, five novel polymorphic VNTR loci were isolated: three minisatellites and two satellite-like loci. Four of them could be mapped onto chromosomes by linkage analysis and/or in situ hybridization. They were assigned to Chromosomes (Chrs) 5, 6, 14, and 16. Physical mapping on both presumed satellites and on one of the minisatellites revealed that the former resided near or at the centromere and the latter towards the chromosome ends. The location of the minisatellite is of particular interest since, together with data on three other minisatellites previously isolated, it supports the idea that, as in humans, minisatellites may preferentially be subtelomeric also in pigs. Received: 23 August 1995 / Accepted: 5 March 1996     

Simultaneous genetic mapping of multiple human minisatellite sequences using DNA fingerprinting

We have used several DNA probes which simultaneously recognize multiple loci to follow the segregation of a large number of minisatellite loci through two large reference pedigrees. The segregation data were analyzed for linkage to previously characterized marker loci using RFLP mapping data for these pedigrees from a previous study and from the Centre d'Etude du Polymorphisme Humain data bank. In this way we have mapped 31 separate minisatellite alleles of a total of 146 studied. The results of these analyses suggest that the distribution of minisatellites in the human genome is skewed toward telomeres and is highly clustered in character. A group of at least five separate minisatellites was found at 7 qter, and smaller clusters are present in several other regions. We detected a smaller than expected number of linkages, perhaps because of the clustering of minisatellite loci. The 7qter minisatellite cluster is in a region of excess male meiotic recombination, and in this respect is similar to minisatellite clusters at 16pter and in the X-Y pseudoautosomal region.     

Comparison of minisatellites.

In the class of repeated sequences that occur in DNA, minisatellites have been found polymorphic and became useful tools in genetic mapping and forensic studies. They consist of a heterogeneous tandem array of a short repeat unit. The slightly different units along the array are called variants. Minisatellites evolve mainly through tandem duplications and tandem deletions of variants. Jeffreys et al. (1997) devised a method to obtain the sequence of variants along the array in a digital code and called such sequences maps. Minisatellite maps give access to the detail of mutation processes at work on such loci. In this paper, we design an algorithm to compare two maps under an evolutionary model that includes deletion, insertion, mutation, tandem duplication, and tandem deletion of a variant. Our method computes an optimal alignment in reasonable time; and the alignment score, i.e., the weighted sum of its elementary operations, is a distance metric between maps. The main difficulty is that the optimal sequence of operations depends on the order in which they are applied to the map. Taking the maps of the minisatellite MSY1 of 609 men, we computed all pairwise distances and reconstructed an evolutionary tree of these individuals. MSY1 (DYF155S1) is a hypervariable locus on the Y chromosome. In our tree, the populations of some haplogroups are monophyletic, showing that one can decipher a microevolutionary signal using minisatellite maps comparison.