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.     

Identification of new minisatellites loci in Arabidopsis thaliana

In order to characterize new CG-rich minisatellites present in the Arabidopsis thaliana genome, a genomic library was screened at low stringency with a probe containing nine repeated-units of a minisatellite (CMs1) previously identified. Both minisatellites and minisatellite-like elements were identified. The minisatellites, with a tandemly-repeated structure, all contain the Arabidopsis thaliana-core sequence previously defined (Tourmente et al., 1994). Both minisatellite and minisatellite-like sequences occur in the Arabidopsis genome in low copy and are weakly polymorphic between ecotypes. The genetic mapping of these markers has shown that they are dispersed on the genome. YACs clones of the CIC library carrying these minisatellites and minisatellite-like sequences were identified.Key words: Arabidopsis thaliana, minisatellites, polymorphism      

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.     

Linkage of two distinct AT-rich minisatellites at multiple loci in the genome of Theileria parva

Minisatellite tandem repeat elements are well known components of vertebrate genomes, but have not yet been extensively characterized in lower eukaryotes. We describe two unusual, AT-rich minisatellites of the protozoan parasite Theileria parva whose sequences are unrelated to the G/C-rich `chi minisatellite superfamily' of vertebrate and plant genomes. The T. parva tandem repeats, one with a conserved sequence T_2-5ACACA (6–17 copies), and the other with a 6-bp core sequence of either ACTATA or TATACT associated with additional variable sequences in repeats of 10–17 bp (3–7 copies), were closely linked at more than 20 sites in the T. parva genome, separated by 390, 510 and 660 bp at three loci analysed in detail. Such linkage is without precedent in minisatellites so far analysed in other organisms. The minisatellite loci were widely dispersed on 13 out of 33 genomic SfiI fragments, on all four T. parva chromosomes and did not exhibit a telomeric bias in their distribution. Analysis of flanking sequences revealed no obvious conserved sequences between the five loci, or other multicopy repeat sequences outside the minisatellite regions. The T_2-5 ACACA minisatellite was highly effective as a multilocus fingerprinting probe for discrimination of T. parva isolates. Analysis of two individual minisatellite loci revealed variation between the genomic DNAs of two T. parva isolates in the copy number of the constituent repeats within the array, similar to that typical of vertebrate minisatellites.     

Minisatellite polymorphism as a tool to distinguish closely related Lactococcus lactis strains

Genome plasticity is considered as a means for bacteria to adapt to their environment. Plasticity in tandem repeat sequences on bacterial genomes has been recently exploited to trace the epidemiology of pathogens. Here, we examine the utility of minisatellite (i.e., a repeat unit of six nucleotides or more) typing in non-pathogenic food bacteria of the species Lactococcus lactis. Thirty-four minisatellites identified on the sequenced L. lactis ssp. lactis strain IL1403 genome were first analyzed in 10 closely related ssp. lactis strains, as determined by randomly amplified polymorphic DNA (RAPD). The selected tandem repeats varied in length, percent identity between repeats, and locations. We showed that: (i) the greatest polymorphism was in orfs encoding exported proteins or in intergenic regions; (ii) two thirds of minisatellites were little- or non-variable, despite as much as 90% identity between tandem repeats; and (iii) dendrograms based on either RAPD or minisatellite analyses were similar. Seven minisatellites identified in this study are potentially useful for lactococcal typing. We then asked whether tandem repeats in L. lactis were stable upon very long-term (up to two years) storage. Despite large rearrangements previously reported in derivative strains, just one of 10 minisatellites tested underwent an alteration, suggesting that tandem repeat rearrangements probably occur during active DNA replication. We conclude that multiple locus minisatellite analysis can be a valuable tool to follow lactococcal strain diversity.     

人体小卫星DNA探针的制备

根据人体小卫星DNA核心顺序,化学合成长23碱基寡核苷酸探针,筛选人体基因组文库,旨在获得能用作遗传分析探针的小卫星顺序。结果得到15个含小卫星的阳性重组子。随机取其一(C_(35.9))作探针,试做群体分析。所有个体均可检出多条杂交带。其中某些带具有多态性。在一定检测条件下,检出的DNA图谱在有限的个体内具有个体特异性。结果表明筛选文库得到的小卫星顺序可用于小卫星多态性的检测。其它小卫星探针的筛选和应用性研究正在进行。     

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     

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.     

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.     

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.     

A novel minisatellite repeat expansion identified at FRA16B in a Japanese carrier

Previously, the allelic expansion of a 33-bp AT-rich minisatellite repeat has been reported to cause FRA16B, a distamycin A-inducible fragile site. Here, we identified a novel 35-bp minisatellite repeat at FRA16B in a Japanese carrier. The nucleotide sequence of the 35-bp minisatellite was highly AT-rich and nearly identical to the 33-bp one but with insertion of two nucleotides, thymine and adenine. The copy number of the AT-rich minisatellite was 21 in total in the carrier, while only a few copies of the 33-bp minisatellite were present in a non-carrier Japanese subject. These results suggest that the molecular mechanism involved in the allelic expansion of the minisatellite repeat in FRA16B recognizes both minisatellites, the 33-bp one and the 35-bp one, as an amplicon. These observations were different from the ones at folate-sensitive fragile sites, where the CCG triplet repeat was commonly involved in the allelic expansion. Although a slight reduction in AT content (95% > 90%) in the region of minisatellite expansion in the carrier subject was observed, both AT-content and length of the highly AT-rich region seem to play important roles in the cytogenetic expression of the distamycin A-inducible fragile site. In another normal subject, without fragile site expression, allelic expansion involving the 33-bp minisatellite was observed, and the length of the AT-rich DNA region was increased up to approximately 1000 bp. Since the length of the AT-rich minisatellite region was increased up to approximately 1,100-bp in the carrier subject, the threshold length for the cytogenetic expression of the AT-rich DNA region may be between about 1,000-bp and 1,100-bp.     

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.     

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.     

A Drosophila minisatellite contains multiple Chi sequences

We demonstrate the existence of polymorphic DNA minisatellites in Drosophila mauritiana, a close relative of D. melanogaster. One of these sequences (minisatellite mD4.2) consists of 13 tandemly repeated monomers, 10 of which are 33 base pairs long. Each of the repeat monomers contains sequences identical or very similar to the Chi sequence (GCTGGTGG), a signal for recBCD-dependent recombination in Escherichia coli. Sequences hybridizing to the mD4.2 minisatellite are present in at least 20–25 genomic locations and exhibit substantial variability among different populations of three Drosophila species and two populations of the house fly, Musca domestica. Interpopulational variation is a result of length differences rather than restriction site polymorphisms and genetic crosses establish that the hybridizing restriction fragment patterns have an underlying genetic basis. The presence of these sequences in the genetically well known Drosophila species allows critical examination of processes that produce and maintain the remarkable variability associated with these genomic regions.     

Isolation and Characterization of Mouse Minisatellites

Minisatellites provide the most informative system for analyzing processes of tandem repeat turnover in humans. However, little is known about minisatellites and the mechanisms by which they mutate in other species. To this end, we have isolated and characterized 76 endogenous mouse VNTRs. Fifty-one loci have been localized on mouse chromosomes and, unlike in humans, show no clustering in proterminal regions. Sequence analysis of 25 loci revealed the majority to be authentic minisatellites with GC-rich repeat units ranging from 14 to 47 bp in length. We have further characterized 3 of the most polymorphic loci both inMus musculussubspecies and in inbred strains by using minisatellite variant repeat mapping (MVR) by PCR to gain insight into allelic diversity and turnover processes. MVR data suggest that mouse minisatellites mutate mainly by intra-allelic nonpolar events at a rate well below 10⁻³per gamete, in contrast to the high-frequency complex meiotic gene conversion-like events seen in humans. These results may indicate a fundamental difference in mechanisms of minisatellite mutation and genome turnover between mice and humans.     

Characterization of Novel Minisatellite Repeat Loci in Atlantic Salmon (Salmo salar) and Their Phylogenetic Distribution

We present here the sequence and characterization of various minisatellite-like tandem repeat loci isolated from the genome of Atlantic salmon (Salmo salar). Their diversity of sequence and lack of core motifs common to minisatellites of other species suggest the presence of numerous and previously unidentified simple sequence repeat families in this salmonid. Evidence for their ubiquity was provided by screening of a salmon genomic library. Southern blot analysis of the phylogenetic distribution of a subset of the minisatellites found one sequence to be pervasive among vertebrates, others present only in Salmoninae or Salmonidae species, and one amplified only in Atlantic salmon. There is evidence for the positioning of microsatellite and minisatellite arrays in close proximity at many loci. Furthermore, one tandem repeat appears to have been inserted into the transposase coding region of a copy of the Tc1 transposon-like element recently identified in salmonids. Received: 9 October 1996 / Accepted: 20 May 1997     

Minisatellite polymorphisms of the SLC6A19: susceptibility in hypertension

The SLC6A19 is a human homolog of B⁰AT1 that encodes a neutral amino acid transporter. We examined the distribution of VNTR (variable number of tandem repeats; minisatellites) and conducted polymorphic analysis of SCL6A19 isolated from the genomic DNA of controls and multi-generational families. The SLC6A19 was found to contain seven blocks of minisatellites, 3 of which (SLC6A19-MS1, -MS4, and -MS7) showed polymorphism and were found to be transmitted through meiosis following Mendelian inheritance in seven families. These minisatellite polymorphisms may be useful markers for paternity mapping and DNA fingerprinting. Furthermore, we conducted a case-control study in which genomic DNA from 400 controls and 205 cases with essential hypertension was compared. A statistically significant association was identified between rare SLC6A19-MS7 alleles and the occurrence of hypertension (odds ratio, 7.87; 95% confidence interval, 0.88-70.66; and p = 0.028). These findings suggest that the rare SLC6A19-MS7 allele may be a risk factor for hypertension.     

Genotype identification and assessment of genetic relationships in pearl millet [Pennisetum glaucum (L.) R. Br] using microsatellites and RAPDs

 The potential of DNA markers such as microsatellites, minisatellites and RAPDs was investigated in pearl millet [Pennisetum glaucum (L.) R. Br] with respect to their abundance and variability. Southern analysis, using 22 different di-, tri-, tetra- and penta-oligonucleotide probes and five minisatellite probes, identified (GATA)₄ as the most useful probe for the detection of multiple polymorphic fragments among pearl millet cultivars and landraces from India. The clustering patterns of pearl millet cultivars and landraces based on (GATA)₄ and RAPD (randomly amplified polymorphic DNA) markers differed. The landraces, representing eight states in India, could not be grouped based on their geographical distribution with the DNA markers. RAPD analysis revealed a high degree of genetic diversity among the cultivars and landraces employed in this study. The probability of an identical match by chance for any two genotypes using (GATA)₄ and RAPDs was 3.02×10^-20 for cultivars and 5.2×10^-9 for landraces. The microsatellite (GATA)₄ and RAPDs provide useful tools for genotype identification and for the assessment of genetic relationships in pearl millet. Received: 19 October 1997 / Accepted: 9 December 1997     

Genetic markers for the Booroola fecundity (Fec) gene in sheep

Animals from the Booroola line of Australian Merino sheep are characterized by a high ovulation rate that can be attributed to the presence of a codominant allele (Fec ^B).The specific function of the gene has not been identified. Effective use of the trait within the sheep breeding industry requires one or more genetic markers that can distinguish between alternative alleles at the locus Fec. With a combination of DNA minisatellite markers and polymorphic protein markers, a cluster of seven minisatellite fragments has been identified as being linked to the Fec gene and to the ovine A blood group locus. The minisatellite fragments have been derived from multilocus probes and hence cannot be used to define the chromosomal location of the Fec gene or to serve as diagnostic markers for Fec. The derivation of cloned single locus markers from the minisatellite fragments will enable finer scale mapping of the Fec and the A blood group locus in sheep.