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.     

Nucleotide sequence and genomic organization of bird minisatellites.

Two minisatellite loci from a Eurasian songbird, the willow warbler (Phylloscopus trochilus) were isolated, sequenced and used as probes to detect more than 20 related hypervariable loci. In addition, a sequence flanking one of the minisatellite loci was isolated, and used to study a VNTR locus. The bird minisatellites have a repeat unit of either 12 (AGGGAAGGGCTC) or 17 bp (GGGGACAGGGGACACCC), repeated in tandem 40-100 times per locus, and shows partial similarity to the sequence motifs of human minisatellites. These sequences are among the most variable minisatellites known, with the incidence per gamete of new length alleles estimated from family studies of warblers to about 5.6% per locus. The bird minisatellite alleles show mendelian inheritance and segregation analysis indicates that they are derived from families of sequences with members on several autosomal linkage groups. Some of the warbler core sequences cross-hybridize to hypervariable loci in other species of birds, mammals and fishes.     

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.     

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.     

"Major minisatellite loci" detected by minisatellite clones 33.6 and 33.15 correspond to the cognate loci D1S111 and D7S437

G. Chimini et al. (1989, Genomics 5: 316-324) have recently reported that the two multilocus DNA fingerprinting probes 33.6 and 33.15 each detect a single major site in the human genome, at 1q23 and 7q35-q36, respectively, and speculate that these sites represent particularly large loci homologous to these probes. However, the human minisatellite loci cloned in 33.6 and 33.15 can themselves be assigned by somatic cell hybrid analysis to 1cen-q24 and 7q31.3-qter, respectively, corresponding to the "major loci" of Chimini et al. Furthermore, under their hybridization conditions, both 33.6 and 33.15 act largely as locus-specific minisatellite probes. The "major minisatellite loci" postulated by Chimini et al. do not therefore appear to represent major localized clusters of minisatellites in the human genome, but rather the loci cloned in 33.6 and 33.15.     

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.     

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.     

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.     

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.     

Minisatellite DNA markers in the chicken genome

This paper reports the detailed characterization of multilocus minisatellite DNA fingerprints in the chicken. Results are presented of DNA fingerprint segregation analyses carried out in three chicken pedigrees, calculating the number of detected loci, testing for Mendelian inheritance, and cosegregation among fingerprint bands. Two pedigrees (families 1 and 2) were analysed using the Jeffreys probes 33.6 and 33.15 only, and one pedigree (family 3) was analysed using 33.6, 33.15. 3′α-globin HVR and M13 protein III gene repeat. Mean band transmission frequencies in families 1 and 2 were near to the Mendelian expectation of 0.5 and no mutations were observed. Family 3 showed transmission frequencies slightly exceeding 0.5. Linkage among bands was higher than observed in some other avian species, with each allele represented by a mean of 1.48 HaeIII fragments. Cosegregation of heterozygous parental fragments representing distinguishable loci followed the expected binomial distribution. The number of minisatellites detectable by the four probes was estimated to be 217. The pattern of cosegregation among those minisatellite loci was tested against that expected for different levels of recombination through the use of a simulation model. We conclude that most minisatellites are unlinked and probably widely dispersed in the chicken genome.     

A suite of falcon single-locus minisatellite probes: a powerful alternative to DNA fingerprinting

Nine falcon single-locus minisatellite probes have been cloned, characterized and shown to provide a powerful alternative to multilocus DNA fingerprinting for determining the parentage of broods of young. Eight clones derived from size-selected peregrine Falco peregrinus and merlin F. columbarius charomid libraries were found to detect single minisatellite loci in all tested members of the genus Falco . A further clone (c Fti 1) randomly selected from a kestrel F. tinnunculus library identified a single locus in other members of the genus and certain species of the Accipitridae. The nine loci display a mean heterozygosity of 88% and considerable allelic diversity in the peregrine and merlin. Pedigree analysis provides evidence consistent with the clustering of minisatellites in linkage groups that are conserved between species. Mutations were observed at five loci among families of peregrines and kestrels. Composite profiles produced with this suite of probes provide an excellent means of confirming identity and parentage. The use of profiling for investigating familial relationships, population dynamics and combating the illegal trade in wild falcons is discussed.     

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.     

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.     

The efficiency of multilocus DNA fingerprint probes for individualization and establishment of family relationships, determined from extensive casework.

The properties of human DNA fingerprints detected by multilocus minisatellite probes 33.6 and 33.15 have been investigated in 36 large sibships and in 1,702 Caucasian paternity cases involving the analysis of over 180,000 DNA fingerprint bands. The degree of overlap of minisatellite loci detected by these two probes is shown to be negligible (approximately 1%), and the resulting DNA fingerprints are therefore derived from independent sets of hypervariable loci. The level of allelism and linkage between different hypervariable DNA fragments scored with these probes is also low, implying substantial statistical independence of DNA fragments. Variation between the DNA fingerprints of different individuals indicates that the probability of chance identity is very low (much less than 10(-7) per probe). Empirical observations and theoretical considerations both indicate that genetic heterogeneity between subpopulations is unlikely to affect substantially the statistical evaluation of DNA fingerprints, at least among Caucasians. In paternity analysis, the proportion of nonmaternal DNA fragments in a child which cannot be attributed to the alleged father is shown to be an efficient statistic for distinguishing fathers from nonfathers, even in the presence of minisatellite mutation. Band-sharing estimates between a claimed parent and a child can also distinguish paternity from nonpaternity, though with less efficiency than comparison of a trio of mother, child, and alleged father.     

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     

Clustering of hypervariable minisatellites in the proterminal regions of human autosomes

Six of the human minisatellites detected by DNA fingerprint probes have been localized by in situ hybridization to human metaphase chromosomes. These hypervariable loci are not dispersed at random in the human genome, but show preferential, though not exclusive, localization to terminal G-bands of human autosomes. Two of the proterminal minisatellites are very closely linked to other variable loci. Sequence analysis of one of these additional minisatellites suggests that the two linked minisatellites arose by independent amplification of different repeat units. The proterminal regions of human autosomes may therefore be rich in minisatellites, analogous to the pseudoautosomal terminal pairing region of human sex chromosomes that is similarly abundant in hypervariable minisatellites.     

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.     

In situ hybridization and pulsed-field gel analysis define two major minisatellite loci: 1q23 for minisatellite 33.6 and 7q35-q36 for minisatellite 33.15

The two classical minisatellite probes, 33.6 and 33.15, were used for in situ hybridization to human metaphase chromosomes. Surprisingly, a single major hybridization peak was observed with each probe, respectively at 1q23 for 33.6 and 7q35-q36 for 33.15. Hybridization to human DNA cleaved with "rare-cutter" enzymes and fractionated on pulsed-field gels also showed a fairly simple, largely monomorphic pattern which allows chromosomal assignment using somatic cell hybrids. Differences in hybridization stringency and degree of resolution account for most of the discrepancy between these results and the accepted view of minisatellites, i.e., a large number of unlinked loci spread over the genome. Our results nevertheless indicate the existence of particularly large and homologous loci on a particular chromosome for each of these probes.     

On the use of DNA fingerprints for linkage studies in cattle

To find a marker for the bovine "muscular hypertrophy" gene and for the "roan" locus, we have typed six cattle pedigrees totaling 540 animals for nine blood group systems, for 12 biochemical markers, for RFLPs at four loci, and with five probes revealing multilocus DNA fingerprints. Segregation analysis of the fingerprint bands showed that, in cattle, a fingerprint probe will reveal a mean of 7.6 clearly resolvable bands, behaving as simple, highly informative Mendelian entities characterized by a mean mutation rate of +/- 1/4500 gametes. For one of the bands, we observed a "mutation burst" generating germline mosaicism. Because some of the fingerprint bands were allelic or corresponded to clustered minisatellites, a mean of only 5.7 independent loci is explored per probe. Fingerprint bands revealed by different probes also show a clear propensity for close linkage, pointing toward nonrandom distribution of minisatellite sequences or the existence of minisatellite clusters. Although this reduces the power of fingerprints for linkage analysis substantially, we were able to demonstrate genetic linkage between fingerprint bands and at least three of the classical markers, to exclude the roan locus from 4.5 Morgans of the bovine genome with the DNA fingerprints and for an additional 2.5 Morgans with the classical markers, and to identify a solid candidate marker for the bovine muscular hypertrophy gene, yielding a lod score greater than or equal to 2.84 without any obliged recombinant.