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.     

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.     

Restriction fragment length polymorphism in the mitochondrial DNA of cloned cattle

The clonal origin of 4 Holstein bulls was determined by hybridization experiments with 2 different minisatellite probes, and all 4 animals showed identical genomic DNA fingerprints, hence confirming monozygosity. Extra-chromosomal differences were observed among these 4 Holstein bulls. Mitochondrial DNA restriction fragment length polymorphisms with restriction endonucleases Avall and Hhal sites were found, and these polymorphisms can be explained by the loss of a single site for each of these 2 enzymes. Since mitochondrial DNA are maternally transmitted, all 4 bulls would produce genetically equivalent spermatozoa and offspring. The combination of embryo cloning and specific cytoplasmic markers would provide an ideal system for the study of maternal cytoplasmic effects on quantitative traits.     

How is it that microsatellites and random oligonucleotides uncover DNA fingerprint patterns?

Minisatellites, microsatellites, and short random oligonucleotides all uncover highly polymorphic DNA fingerprint patterns in Southern analysis of genomic DNA that has been digested with a restriction enzyme having a 4-bp specificity. The polymorphic nature of the fragments is attributed to tandem repeat number variation of embedded minisatellite sequences. This explains why DNA fingerprint fragments are uncovered by minisatellite probes, but does not explain how it is that they are also uncovered by microsatellite and random oligonucleotide probes. To clarify this phenomenon, we sequenced a large bovine genomic BamHI restriction fragment hybridizing to the Jeffreys 33.6 minisatellite probe and consisting of small and large Sau3A-resistant subfragments. The large Sau3A subfragment was found to have a complex architecture, consisting of two different minisatellites, flanked and separated by stretches of unique DNA. The three unique sequences were characterized by sequence simplicity, that is, a higher than chance occurrence of tandem or dispersed repetition of simple sequence motifs. This complex repetitive structure explains the absence of Sau3A restriction sites in the large Sau3A subfragment, yet provides this subfragment with the ability to hybridize to a variety of probe sequences. It is proposed that a large class of interspered tracts sharing this complex yet simplified sequence structure is found in the genome. Each such tract would have a broad ability to hybridize to a variety of probes, yet would exhibit a dearth of restriction sites. For each restriction enzyme having 4-bp specificity, a subclass of such tracts, completely lacking the corresponding restriction sites, will be present. On digestion with the given restriction enzyme, each such tract would form a large fragment. The largest fragments would be those that contained one or more long minisatellite tracts. Some of these large fragments would be highly polymorphic by virtue of the included minisatellite sequences; by virtue of their complex structure, all would be capable of hybridizing to a wide variety of probes, uncovering a DNA fingerprint pattern.     

DNA "fingerprints" and segregation analysis of multiple markers in human pedigrees

Tandem-repetitive DNA hybridization probes based on a putative human recombination signal detect multiple polymorphic minisatellite fragments in human DNA. The genetic complexity of the resulting individual-specific DNA "fingerprints" was investigated by studying a large sibship affected by neurofibromatosis and a more extensive pedigree segregating for two different hemoglobinopathies. The segregation of up to 41 different heterozygous DNA fragments from each parent could be analyzed in a single sibship, using two different repeat probes. Most of these variable DNA fragments could not be paired as alleles, to an extent which suggests that the DNA fingerprints are together derived from approximately 60 heterozygous loci (approximately 120 variable fragments), only a proportion of which can be scored in a given individual. Two or three of the DNA fragments detected by one probe showed tight linkage and may be derived from long minisatellite(s) that are cleaved to produce more than one polymorphic DNA fragment. Excluding allelic and linked DNA fragments, almost all remaining scorable fragments segregated independently, allowing up to 34 unlinked loci to be examined simultaneously. These loci are scattered over most or all of the human autosomes. Minisatellite probes are therefore suitable for rapid marker generation and can be applied to linkage analysis in human pedigrees.     

The use of synthetic tandem repeats to isolate new VNTR loci: cloning of a human hypermutable sequence.

Synthetic tandem repeats (STRs) of oligonucleotides have previously been shown to detect polymorphic loci in the human genome. Here, we report results from the use of three such probes to screen a human cosmid library. Nine of the 45 positive clones that were analyzed appear to contain highly polymorphic minisatellite or VNTR loci. The degree of enrichment for minisatellite sequences varied with the choice of STR: one provided a 15- to 20-fold enrichment (4 polymorphic loci among 10 clones), whereas 2 others gave a 3- to 5-fold enrichment (5 polymorphic probes in a total of 35 clones) compared to random screening. The 9 VNTR markers have been localized by linkage analysis in the CEPH panel and/or by in situ hybridization. Eight probes identify new loci, one of which maps to an interstitial region. One of the VNTR loci (identified by probe CEB1) was found to be hypermutable, with 52 mutation events identified among 310 children characterized in 40 CEPH families. The parental origin of the mutation could be identified in all instances, and only one mutation was found to be of maternal origin. The mutation rate in males was estimated to be approximately 15%. Segregation analysis of flanking markers suggests that mutations are not associated with crossing over. As the only previously described hypermutable minisatellite loci in humans have equal rates of male and female mutations, these observations establish that a second type of hypermutable minisatellite exists in the human genome. In neither case does the generation of new alleles appear to be associated with unequal crossing over.     

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.     

Gene organization of haplotypes expressing two different C4A allotypes

Summary The gene organization of C4 haplotypes expressing two different C4A allotypes with a C4B null allele (C4A3A2-BQ0 and C4A3A6BQO) was studied using Southern blot analysis with cDNA probes and restriction enzymes which give C4A and C4B locus-specific restriction fragments. These haplotypes were shown to have both a C4A and a C4B locus present, suggesting that the C4B locus expresses a C4A protein. The finding of a 21-OH A and a 21-OH B gene on the C4A3A6BQO haplotype further suggests that this haplotype has the common gene organization C4A, 21-OH A, C4B, 21-OH B. A model explaining C4 null alleles on haplotypes found to have two C4 loci is presented.     

Hypervariable single and multi-locus DNA polymorphisms for genetic typing of non-human primates

The series of hypervariable, “minisatellite” loci characterized byJeffreys and coworkers in the human myoglobin gene have proved to be DNA sequences highly conserved throughout the eukaryotic genome, and hence the methodology developed for human DNA “fingerprinting” has found immediate application in an ever expanding number of species. Primatologists have not been slow to profit from a method which predicts individual recognition to a very high degree of probability, and initial studies have focused on paternity allocation (rather than paternity exclusion, as designated by the classical biochemical markers), adaptive aspects of socio-sexual behaviour patterns and mating systems. A number of probes with sequences corresponding to the common minisatellite core sequences have been used for probing genomic DNA, and synthetic, G-rich oligonucleotides (15 – 37 bases), corresponding to the core sequence of the minisatellite repeat unit, or simply di-, tri-, or tetranucleotide repeats, appear to be equally discriminatory. The multiple banding patterns produced on hybridization of these probes to restriction enzyme digests of DNA provide an advantage in that the probability of two unrelated individuals sharing the same banding pattern will be low. However, the uncertainty of linkage of the multiple loci identified precludes genotyping and population genetic analyses based on allele frequencies. In contrast, single locus analysis allows DNA typing using variable number tandem repeat (VNTR) or restriction fragment length (RFLP) DNA polymorphisms, and the merits and drawbacks relative to DNA fingerprinting are discussed. For the behavioural primatologists dealing with defined, accessible troops of primates, the value of multilocus DNA fingerprinting, in terms of established methodology and availability of probes applicable to species as phylogenetically wide-ranging as apes and prosimians, may well outweigh the loss of genotypic and population structure data.     

A unique AT-rich hypervariable minisatellite 3' to the ApoB gene defines a high information restriction fragment length polymorphism

A DNA restriction fragment length polymorphism has been found immediately 3' to the human apoB gene. Digestion of many different human DNAs at sites flanking the region and Southern blotting analysis reveal that this region can vary in length by approximately 300 base pairs with five alleles readily distinguishable. The length polymorphism is due to a unique AT-rich minisatellite that consists primarily of a 30-base pair tandem repeat with two structurally related subunit sequences, x (ATAATTAAATATTTT) and y (ATAATTAAAATATTT). In general, the sequences repeat in an x-y order. The AT-rich region also contains variant x and y sequences that result from C or G for A substitution. Sequence analysis of one large allele revealed the expected increased number of xy repeats. In addition, similar analysis of three different smaller alleles with the same apparent size on Southern blotting analysis showed that all were of slightly different size due to minor differences in the number of xy repeats. The heterogeneity of this AT-rich minisatellite provides the basis for a highly informative restriction fragment length polymorphism of the apoB gene and should be very useful in association and linkage analysis studies of the contribution of this locus to atherosclerosis susceptibility.     

DNA fingerprinting analysis of Booroola pedigrees: a search for linkage to the Booroola gene

Seven minisatellite probes from a variety of sources were used to analyse 11 paternal half-sib families in which the Booroola gene was segregating. A total of 402 bands that showed segregation in the pedigrees were examined for linkage to the Booroola gene. None of the bands showed segregation with the Booroola gene. The most likely evidence for a linked band was produced by the HaRas HVR probe in Family 902 (=0.0; LOD 2.3). The conclusion, however, is that the minisatellite probes used in this study could not be used as markers for the Booroola gene. The study highlighted problems associated with the use of minisatellite probes in linkage studies in half-sib families. The complex banding patterns found on fingerprinting gels was a major source of scoring error. In a few cases both of the sire's alleles could be identified at a particular locus, but in most cases only one of the alleles could be identified. For the most part, the bands had to be treated as dominant alleles. The contribution of dam alleles to the banding pattern could only be estimated. There was an indication that minisatellite loci in sheep are clustered in particular regions of the sheep genome as the rate at which bands segregated with each other was higher than one would expect from loci randomly distributed throughout the genome.     

Identification, isolation and characterization of canine minisatellite sequences

A Charomid ordered-array library containing a 2–16 Kb size fraction of MbeoI-digested canine genomic DNA has been screened with the Jeffreys multilocus probes, 33-6 and 33-15, to identify and isolate canine minisatellite sequences. Of the 48 positive clones identified, 7 were found to contain polymorphic mini-satellites with heterozygosities in the range 20–88%. The majority of the remainder were either monomorphic or dimorphic in the animals tested. Analysis of intrabreed variation in Bedlington Terriers using two polymorphic minisatellites has shown that a significant reduction occurs in the number of alleles seen compared to an agglomerated population sample, correlating with the high level of inbreeding within this breed. Flanking DNA sequence and partial repeat sequence is presented for the most polymorphic minisatellite thus far identified, cCfaMP5. The variable region in this mini-satellite is similar to human minisatellites which show a distinct purine or pyrimidine strand bias.     

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.     

Isolation and characterization of DNA probes from a flow-sorted human chromosome 8 library that detect restriction fragment length polymorphism (RFLP).

We have used a recombinant DNA library constructed from flow-sorted human chromosome 8 as a source of single-copy human probes. These probes have been screened for restriction fragment length polymorphism (RFLP) by hybridization to Southern transfers of genomic DNA from five unrelated individuals. We have detected six RFLPs distributed among four probes after screening 741 base pairs for restriction site variation. These RFLPs all behave as codominant Mendelian alleles. Two of the probes detect rare variants, while the other two detect RFLPs with PIC values of .36 and .16. Informative probes will be useful for the construction of a linkage map for chromosome 8 and for the localization of mutant alleles to this chromosome.     

Detection and inheritance of RFLPs in Eucalyptus nitens

The level of polymorphism using genomic and cDNA probes with a number of restriction enzymes and the inheritance of the RFLP loci was investigated in E. nitens. The polymorphism detected with 366 genomic and cDNA probes and three to six restriction enzymes was analysed in three-generation outbred pedigrees. No difference in the level of polymorphism detected with genomic versus cDNA probes was observed. There was a difference in the efficiency of detection of polymorphism with six different restriction enzymes, with three of the enzymes (BglII, DraI and EcoRI) showing substantially more polymorphism than the others. There was no significant correlation between the size of the DNA fragments generated by the enzymes and the detection of polymorphism. Several cases of restriction-site mutations resulting in a polymorphism were observed. The inheritance of 69 loci was analysed in two pedigrees resulting from interpopulational crosses. The majority of the loci segregated according to expected ratios with distortion observed in only 3% of loci. Probes from the cDNA library detected a greater proportion of loci with more than two alleles than did probes from the genomic library. The high polymorphism, large number of alleles, and ease of interpretation of RFLPs in E. nitens means that they will be useful in a range of applications such as genetic linkage maps and paternity analysis.     

Isolation, characterization, and physical localization of 33 human X-chromosome RFLP markers

In a search for highly polymorphic X-specific loci, the X-chromosome DOE Ch35 phage library (LAOXNL01) was screened with three oligonucleotides representative of minisatellite consensus sequences. A total of 170 clones containing human inserts were isolated by hybridization to the oligonucleotide sequences; each was tested for polymorphism on five random female DNAs with six restriction enzymes. Among the 53 clones demonstrating a polymorphic pattern, 47 were of distinct origin. Twelve of the polymorphisms (23%) were determined to be autosomal. Polymorphisms for the remaining 35 clones were characterized, These polymorphisms represent 33 new X-chromosome RFLP loci, since two pairs of clones detected partially overlapping patterns. A pattern of similar length variation with multiple enzymes ("VNTR-type") was demonstrated in 6 (50%) of the 12 non-X-polymorphic clones. However, only 3 (9%) of the 33 X polymorphic loci showed VNTR-like patterns, suggesting a decreased amount of VNTR polymorphism on the X chromosome. The 33 polymorphic X loci were physically localized with a set of rodent x human somatic cell hybrid DNAs representing nine different X-chromosome breakpoints.     

Sheep linkage mapping: restriction fragment length polymorphism detection with heterologous cDNA probes

Summary. A selection of cattle, human and sheep cDNA probes were screened against sheep genomic DNA, cut with 10 different restriction enzymes, to assess the usefulness of these probes for restriction fragment length polymorphism (RFLP) linkage studies in sheep. Two-thirds of the cattle cDNA probes showed moderate to strong homology with sheep DNA samples, compared with less than half of the human cDNA probes at the final washing stringency chosen for the experiments. The set of probes tested detected a useful frequency of RFLPs. Fifty-seven per cent of probes showing moderate to strong homology identified RFLPs with one or more restriction enzymes. Restriction enzymes that detected RFLPs most frequently in sheep were Taq I and Msp I. The results show that sheep and cattle cDNA probes, including candidate genes for production traits, identified a high frequency of RFLPs suitable for genetic mapping in sheep.     

Detection of minisatellite sequences inPhaseolus vulgaris

An improved procedure for detecting minisatellite sequences inPhaseolus vulgaris is described. Both M13 protein III tandem repeat and the 33.15 human mini-satellite sequences revealed polymorphisms with a high number of sharp bands after digestion of genomic DNA withHae III,Hinf I, orTaq I. Improved resolution of the numerous restriction fragments detected by these probes is accomplished by one or more of the following: varying agarose concentration, using high SDS hybridization buffer, exposure of the autoradiograph without intensifying screens, and transfer of the autoradiograph to electrophoresis paper. Increased stability of the DNA-DNA hybridizations with these heterologous probes is obtained by reducing hybridization temperature. Labeling probes with the polymerase chain reaction can accentuate some restriction fragments depending upon the radiolabeled nucleotide used.