De novo mutations and allelic diversity at minisatellite locus D7S22 investigated by allele-specific four-state MVR-PCR analysis

We have studied the allelic diversity and de novo mutations at the hypervariable minisatellite locus D7S22. A four-state minisatellite variant repeat unit mapping by PCR (MVR-PCR) method was developed for this purpose, and a substitution polymorphism close to the repeat array was used to design allele-specific flanking primers to study individual haplotypes in genomic DNA. A total of 150 alleles from different allele size groups and flanking haplotypes were mapped. On average, MVR-codes extending 65 repeats (2.4 kb) into the repeat array were obtained. The interspersion patterns of variant repeats were highly polymorphic. However, subgroups of alleles close in size and with identical flanking haplotype revealed common MVR-code characteristics indicating a close evolutionary relationship. Unlike the situation in many other hypervariable minisatellites, no polarized variability was revealed at this minisatellite locus. Fifty four small families with D7S22 de novo mutations were analysed by MVR-PCR. The sites where the length change occurred were revealed in 22 cases, while in 32 cases the mutation obviously occurred further into the repeat array. In agreement with a non-polar distribution of the allelic variation, there was no evidence for a hypermutable hot spot for mutation within the repeat array. Comparison of MVR-codes in the mutant and progenitor in gain mutations indicated that at least one, possibly four cases, reflected inter- allelic events. Together with evidence from DNA sequencing of alleles of <2 kb, this indicates that as many as half of the gain mutations might be inter-allelic events in D7S22. Based on these results, different factors which might affect the mutation rate are discussed.      

Mutation rate heterogeneity and the generation of allele diversity at the human minisatellite MS205 (D16S309)

Many tandemly repeated minisatellite loci display extreme levels of length variation as a consequence of high rates of spontaneous germline mutation altering repeat copy number. Direct screening for new allele lengths by small-pool PCR has shown that instability at the human minisatellite locus MS205 (D16S309) is largely germline specific and usually results in the gain or loss of just a few repeat units. Structural analysis of the order of variant repeats has shown that these events occur preferentially at one end of the tandem array and can result in complex rearrangements including the inter-allelic transfer of repeat units. In contrast, putative mutants recovered from somatic DNA occur at a substantially lower rate and are simple and non- polar in nature. Germline mutation rates vary considerably between alleles, consistent with regulation occurring in cis. Although examination of DNA sequence polymorphisms immediately flanking the minisatellite reveals no definitive associations with germline mutation rate variation, differences in rate may be paralleled by changes in mutation spectrum. These findings help to explain the diversity of MS205 allele structures in modern humans and suggest a common mutation pathway with some other minisatellites.      

Analysis of allelic structures at the D7S21 (MS31A) locus in the Japanese, using minisatellite variant repeat mapping by PCR (MVR-PCR)

To sample the diversity of allelic structures at the D7S21 (MS31A) locus in the Japanese, allele-specific minisatellite variant repeat mapping using polymerase chain reaction (MVR-PCR) was performed on genomic DNA from a number of Japanese individuals. Three polymorphic positions in the MS31A 5' flanking DNA were typed from 214 un-related Japanese, and the distribution of haplotypes was analysed. Allele-specific MVR-PCR, using primers that discriminate between different alleles at these polymorphic positions in heterozygous individuals, allows single alleles to be mapped from genomic DNA in approximately 80% of Japanese. 149 Japanese alleles have been mapped to date and all of them, except for two pairs of indistinguishable alleles, have different internal structures. More than half of the mapped alleles showed similar regions of internal structure to other alleles and were classified into groups on this basis.     

Allele-specific MVR-PCR analysis at minisatellite D1S8

Minisatelilte variant repeat mapping by the polymerase chainreaction (MVR-PCR) provides a digital approach to DNA typingof great potential use both in forensic medicine and, by mappingsingle alleles, for exploring allelic variability and mutationprocesses at minisateliltes. The MVR haplotypes of single allelescan be determined either from physically separated alleles orby pedigree analysis of digital diplold codes generated fromboth alleles simultaneously. We now show that single allelescan be rapidly mapped from total genomic DNA using allele-specificPCR primers directed to polymorphic sites in the DNA flankingthe minisatellite. This approach can also be used to dissectmixed DNA samples such as those often encountered in forensicDNA analysis.     

Allelic structures at hypervariable minisatellite B6.7 in Japanese show population specificity

Human minisatellite B6.7 shows extensive allele length and structural variability in north Europeans. We analysed this locus in the Japanese population. Allele size distributions showed that Japanese retain extensive allele length variability but have significantly smaller alleles compared with north Europeans. In contrast, there is very little variation in flanking DNA, with only one single-nucleotide polymorphism (SNP) near the minisatellite. Ninety-two Japanese alleles were further characterised by minisatellite variant repeat mapping by polymerase chain reaction (MVR-PCR). These alleles showed a wide variety of internal MVR structures, despite their relative shortness, with most alleles observed only once in the sample. The true heterozygosity is estimated at 99.95%, with well in excess of 2000 different alleles existing in the Japanese population. Dot matrix analysis showed that groups of related alleles sharing structural motifs could be identified within Japanese and in north Europeans, and that these groups are population specific with no examples of significant similarity between any Japanese and north European alleles. Minisatellite B6.7 therefore shows huge allele variability and fast repeat turnover in Japanese as well as north European populations, and provides novel lineage markers for exploring very recent events in human population history. Received: January 29, 2002 / Accepted: February 12, 2002     

Extremely complex repeat shuffling during germline mutation at human minisatellite B6.7

Human minisatellite B6.7 is a highly variable locus showing extensive heterozygosity with alleles ranging from six to >500 repeat units. Paternal and maternal mutation rates to new length alleles were estimated from pedigrees at 7.0 and 3.9% per gamete, respectively, indicating that B6.7 is one of the most unstable minisatellites isolated to date. Mutation at this locus was also analysed by small pool PCR of sperm and blood DNA. Male germline instability varied from <0.8 to 14% per allele and increased with tandem array size. In contrast, the frequency of mutants in somatic (blood) DNA was far lower (<0.5%), consistent with a meiotic origin of germline mutants. Sperm mutants were further characterized by minisatellite variant repeat mapping using four major polymorphic sites within the B6.7 repeats. This highly informative system revealed a wide variety of changes in allele structure, including simple intra-allelic duplications and deletions and more complicated inter- and intra-allelic transfers of repeat blocks, as seen at other human minisatellites. The main mode of sperm mutation, however, resulted in extremely complex allele reorganization with evidence of inter-allelic transfer plus the generation of novel repeats by rearrangement at the sub-repeat level, suggesting that recombinational instability at B6.7 is a complex multistep process.     

Hypervariable digital DNA codes for human paternal lineages: MVR-PCR at the Y-specific minisatellite, MSY1 (DYF155S1)

We describe the first haploid minisatellite, the human Y chromosome- specific locus, MSY1. It consists of an array of 48-114 AT-rich 25 bp repeats of at least five different variant types. A minisatellite variant repeat PCR (MVR-PCR) system gives Y-specific DNA codes, with a virtual heterozygosity of 99.9%, making MSY1 by far the single most variable locus on the Y. African populations contain the most diverged MSY1 structures. MSY1 is the only Y-chromosomal system where the characteristics of large numbers of mutations can be studied in detail: it provides a uniquely powerful tool both for the investigation of mutation in a haploid system, and for the dating of paternal lineages.      

Distribution of tandem repeat polymorphism within minisatellite MS621 (D5S110)

The minisatellite MS621 (D5S110) is a highly polymorphic tandem repeat locus which maps to the distal region of human chromosome 5p. Major repeat unit variants at D5S110 differ not by base substitutions but by differences in the repetition of an 11 bp sequence motif found within each repeat. The two major classes of repeat unit thus contain two (' dimeric '= D-type) or three (' trimeric '= T-type) copies of this short motif. Mapping the distribution of these D- and T-type repeat units within alleles has allowed the analysis of the structural basis of allelic variation and of one de novo mutation. In contrast to previous studies of some other highly polymorphic minisatellites, this analysis provided no clear evidence for polarized variability at D5S110.     

The plasticity of human telomeres demonstrated by a hypervariable telomere repeat array that is located on some copies of 16p and 16q.

Human telomeres are composed of tandem arrays of TTAGGG repeats with many variant repeats at the proximal ends. Comparison of the interspersion of variant and TTAGGG repeats between alleles can be used to study telomere instability, but the difficulty in identifying chromosome-specific sequences close to the start of autosomal telomeres has hampered such investigations. A chromosome end, including a telomere and adjacent sequence, that is polymorphic for its presence or absence in unrelated individuals has been identified. The telomere-adjacent DNA shows strong homology (92-99%) to sequences, including two expressed sequence tags, that are usually located in subterminal regions of human chromosomes but not adjacent to telomeres. Since this chromosome end arose, it has relocated at least once. In Caucasians, it forms the telomere of approximately 6% of 16q and 2% of 16p chromosome arms. The mechanism of relocation is unknown but must have involved the telomere-adjacent DNA rather than the telomere itself, as copies on 16p and 16q share the same telomere-adjacent sequence. The interspersion patterns of TTAGGG with TGAGGG, TTGGGG and non-amplifying repeat sequences revealed extensive allelic variation, such that 47 different alleles were observed among the 50 alleles mapped. Closely related alleles differ by small changes in copy number at blocks of adjacent like repeats, as seen at the Xp/Yp pseudoautosomal telomere. Such differences are compatible with a model in which the majority of mutations arise by intra-allelic mechanisms, in individuals hemizygous for a single copy of the chromosome end.     

河北汉族人群D1S8位点DNA结构多态性

目的 研究小卫星变异重复序列（ｍｉｎｉｓｔａｅｌｌｉｔｅ ｖａｒｉａｎｔ ｅｒｐｅａｔ,ＭＶＲ）位点Ｄ１Ｓ８的结构多态性,为ＤＮＡ指纹数据库的构建及法医学应用提供基础资料。方法 应用ＭＶＲ－聚合酶链反应和聚丙烯酰胺梯度凝胶电泳银染法,检测２４０名河北汉族针关个体Ｄ１Ｓ８位点重复序列的变异并进行数字编码。结果 每一个体得到约３０个数字编码,未发现任何两个无关个体编码相同,３０个编码完全相同的概率为３     

Analysis of the trinucleotide CAG repeat from the human mitochondrial DNA polymerase gene in healthy and diseased individuals

The human nuclear gene (POLG) for the catalytic subunit of mitochondrial DNA polymerase (DNA polymerase gamma) contains a trinucleotide CAG microsatellite repeat within the coding sequence. We have investigated the frequency of different repeat-length alleles in populations of diseased and healthy individuals. The predominant allele of 10 CAG repeats was found at a very similar frequency (approximately 88%) in both Finnish and ethnically mixed population samples, with homozygosity close to the equilibrium prediction. Other alleles of between 5 and 13 repeat units were detected, but no larger, expanded alleles were found. A series of 51 British myotonic dystrophy patients showed no significant variation from controls, indicating an absence of generalised CAG repeat instability. Patients with a variety of molecular lesions in mtDNA, including sporadic, clonal deletions, maternally inherited point mutations, autosomally transmitted mtDNA depletion and autosomal dominant multiple deletions showed no differences in POLG trinucleotide repeat-length distribution from controls. These findings rule out POLG repeat expansion as a common pathogenic mechanism in disorders characterised by mitochondrial genome instability.     

PCR amplification introduces errors into mononucleotide and dinucleotide repeat sequences.

The polymerase chain reaction (PCR) is used universally for accurate exponential amplification of DNA. We describe a high error rate at mononucleotide and dinucleotide repeat sequence motifs. Subcloning of PCR products allowed sequence analysis of individual DNA molecules from the product pool and revealed that: (1) monothymidine repeats longer than 11 bp are amplified with decreasing accuracy, (2) repeats generally contract during PCR because of the loss of repeat units, (3) Taq and proofreading polymerase Pfu generate similar errors at mononucleotide and dinucleotide repeats, and (4) unlike the parent PCR product pool, individual clones containing a single repeat length produce no "shadow bands". These data demonstrate that routine PCR amplification alters mononucleotide and dinucleotide repeat lengths. Such sequences are common components of genetic markers, disease genes, and intronic splicing motifs, and the amplification errors described here can be mistaken for polymorphisms or mutations.     

Evolution and population genetics of the H-ras minisatellite and cancer predisposition

Case-control studies have implicated rare length H-ras minisatellite alleles in cancer risk. In Europeans, this locus has four common alleles, and a larger number of rare alleles; possession of a rare allele has been identified as a risk factor responsible for 5-10% of some cancers. This unusual model of predisposition has been controversial in case-control studies, but also makes characteristic predictions about the population genetics of the locus, which we examine in this study. Using minisatellite variant repeat ("MVR") mapping, and compound haplotypes composed of the minisatellite and surrounding substitutional polymorphisms, we have reconstructed the main steps in the evolution of this locus in human populations. MVR-calibrated measurements of allele length yield rare allele frequencies significantly higher than most previous studies, and show that most other analyses have not distinguished two common alleles of 84 and 85 repeat units. Alleles classified as "rare" in European populations predominate (70%) in the African sample studied. Small-pool PCR (SP-PCR) analysis on common alleles in sperm DNA gives an estimate for the germline minisatellite mutation rate of about 0.05% (95% confidence upper limit 0.15%). Overall, our results do not reflect a locus subject to frequent mutation and strong selection, and are difficult to reconcile with the proposed cancer predisposition. Restricted variation at this locus is most simply explained by low mutation rate, and although definitive case-control studies can only be performed using methods capable of reproducibly distinguishing rare and common alleles, our work suggests that most studies to date have not resolved alleles adequately.     

Influence of allele lineage on the role of the insulin minisatellite in susceptibility to type 1 diabetes

The insulin minisatellite or variable number of tandem repeats locus (INS VNTR) is the best candidate for the type 1 diabetes mellitus (T1DM) susceptibility locus IDDM2. Small class I alleles associate with predisposition to T1DM, whereas large class III alleles associate with dominant protection. We have analysed variant repeat distribution within the minisatellite and combined this with flanking haplotypes to define five new ancestral allele lineages. Class III alleles divide into two highly diverged lineages, IIIA and IIIB, which correspond perfectly to the previously defined Protective (PH) and Very Protective (VPH) haplotypes, respectively. Class I alleles are divided into three newly defined lineages, IC+, ID+ and ID-, by a combination of variant repeat distributions and flanking haplotypes. All class I alleles are equally predisposing to T1DM except for ID- alleles which are protective when transmitted from ID-/III heterozygous fathers. Similar results have been previously reported for alleles of 42 repeats in length (allele 814) which represent a subset of the ID- lineage. Division of class ID- alleles into those of 42 repeats and those of other sizes suggested that this protective effect was a feature of all ID- alleles, irrespective of size. ID- alleles are only clearly distinguished from all other alleles by an MSPI(-) variant within IGF2 downstream of the minisatellite, suggesting that the apparent role of the minisatellite in susceptibility to T1DM may be modified by neighbouring haplotype and therefore that IDDM2 could have a multi-locus aetiology.     

Characterization of large CTG repeat expansions in myotonic dystrophy alleles using PCR

The CTG trinucleotide repeat expansions that are associated with myotonic dystrophy can be up to several thousand repeat units in length. We have developed a PCR protocol that has the potential to amplify mutant alleles with very large numbers of CTG repeats. The amplification uses the rTth DNA polymerase, XL system for long PCR targets together with primers which do not closely flank the repeat region and partial substitution of 7-deaza-dGTP for dGTP. Alleles containing up to approximately 800 CTG repeats were detected directly in agarose gels stained with ethidium bromide. Larger CTG repeat expansions required Southern blot transfer and detection with a repeat sequence probe; using this method, alleles containing up to approximately 2700 CTG repeats were detected. The PCR-based method described here was comparable to previous Southern blots of EcoRI-restriction digested genomic DNA in both the approximate size and heterogeneity of mutant alleles detected, but provided more precise sizes of the CTG repeat expansions than the restriction digest approach. This PCR protocol could potentially simplify current mutation detection protocols in the molecular diagnosis of myotonic dystrophy, and facilitate molecular studies of the disease. © 1996 Wiley-Liss, Inc.     

The effect of FMR1 CGG repeat interruptions on mutation frequency as measured by sperm typing.

Fragile X syndrome results from the unstable expansion of a CGG repeat within the FMR1 gene. Three classes of FMR1 alleles have been identified, normal alleles with 6-60 repeats, premutations with 60-200 repeats, and full mutations with > 230 repeats. Premutations are exquisitely unstable upon transmission. Normal alleles, while generally stable upon transmission, are thought to have different intrinsic mutation frequencies, such that some normal alleles may be predisposed towards expansion while others may be more resistant to such change. One variable that may account for this difference is the occurrence of one or more AGG triplets punctuating the normal CGG repeat. The AGG interruptions lead to alleles that have equivalent overall length but different lengths of perfect repeats. To test the influence of the length of perfect repeats on stability, we examined the CGG repeat of single sorted sperm from two males, each with 39 total repeats, but distinct AGG interruption patterns. Sorted sperm of each donor showed -15% variation in repeat length, consistent with previous studies of sorted sperm at other triplet repeat loci. However, when discounting the majority variation of +/-1 repeat, the male with 29 perfect repeats showed 3% expansion changes while the donor with only 19 perfect repeats had none (< 0.9%). Moreover, > 90% of all variant sperm, including all those observed with expansions, showed expansion or contraction of the 3' end of the repeat array. These data are consistent with the hypothesis that perfect repeat tracts influence the repeat stability and that changes of the FMR1 repeat exhibit polarity.     

Detection of inter-spread repeat sequence in genomic DNA sequence

Various types of periodic patterns in nucleotide sequences are known to be very abundant in a genomic DNA sequence, and to play important biological roles such as gene expression, genome structural stabilization, and recombination. We present a new method, named "STEPSTONE", to find a specific periodic pattern of repeat sequence, inter-spread repeat, in which the tandem repeats of the conserved and the not-conserved regions appear periodically. In our method, at first, the data on periods of short repeat sequences found in a target sequence are stored as a hash data, and then are selected by application of an auto-correlation test in time series analysis. Among the statistically selected sequences, the inter-spread repeats are obtained by usual alignment procedures through two steps. To test the performance of our method, we examined the inter-spread repeats in Mycobacterium tuberculosis and Zamia paucijuga genomic sequences. As a result, our method exactly detected the repeats in the two sequences, being useful for identifying systematically the inter-spread repeats in DNA sequence.     

Analysis of CAG repeat of the Machado-Joseph gene in human, chimpanzee and monkey populations: a variant nucleotide is associated with the number of CAG repeats

Machado-Joseph disease (MJD) is an autosomal dominant neurodegenerative disorder associated with an unstable and expanded CAG repeat. We analyzed this locus from various sources including MJD families, Acadian, African American, Caucasian, Greenland Inuit and Thai populations. The range of the CAG repeat size was 14-40 in the normal alleles while the MJD alleles contained 73-78 repeats in our studies. We found 25 different alleles on normal chromosomes with a heterozygosity of 0.86 in combined populations. The most common alleles were 23 (22.9%) and 14 (25.5%) repeats. We also examined 16 chimpanzees and various Old World monkeys: a pigtail macaque, a mangabey and 12 rhesus macaques. The DNA sequences surrounding the CAG repeat did not vary among species. The range of the number of the CAG repeats is 13-14 in macaques, 16 in mangabey and 14-20 in chimpanzees. Variant CAA or AAG triplets in the CAG repeat tracts were found in all 268 human, 28 monkey and 32 chimpanzee chromosomes. As reported in a previous study [Kawaguchi et al. (1994) Nature Genet. 8, 221-228] the common variant positions were the third (CAA), fourth (AAG) and sixth (CAA) positions. However, we found three human chromosomes containing CAG at the sixth position and the mangabey had AAG at the ninth position. In addition, we found CAG at the fourth position and AAG at the sixth position in all macaque chromosomes. The nucleotide following the CAG repeat tract was usually G in all species studied. However, we sometimes found C at this position in human and chimpanzee chromosomes. Interestingly, this variant C was found in all expanded chromosomes and in 54.5% of chromosomes with 27-40 CAG repeats but it was not found in any chromosomes with less than 20 CAG repeats. We hypothesize that the variant C may be associated with CAG repeat instability.      

Allelic diversity at minisatellite MS205 (D16S309): evidence for polarized variability

We have determined the allelic structures on 106 Caucasian chromosomesat the minisatellite locus MS205 (D16S309). In addition to theInternal structures deduced by minisatellite variant repeat(MVR) mapping, the genotypes at six flanking substitutionalpolymorphic sites have been analysed. The minisatellite structuresshow a polarity of variation at MS205, with most observed variationdue to differences at one extremity of the tandem repeat array.This locus, therefore, provides a further example of polarityof variation at human minisatellites. Analysis of haplotypesat flanking polymorphic sites suggests that there may be a higherfrequency of exchange near the highly unstable end of the minisatellite,and thus that exchanges of flanking polymorphisms may be dueto co-conversion or recombination events occurring during unequalexchanges between minisatellite alleles.