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.     

中国明对虾基因组小卫星重复序列分析

通过对中国明对虾基因组随机DNA片断的测序 ,我们获得了总长度约 6 4 10 0 0个碱基的基因组DNA序列 ,从中共找到 172 0个重复序列。其中 ,小卫星序列的数目为 398个 ,占重复序列总数目的 2 3 14 %。这些小卫星序列的重复单位长度为 7- 16 5个碱基 ,集中分布于 7- 2 1个碱基范围内 ,其中以重复单位长度为 12个碱基的重复序列数目最多 ,为 5 8个 ,占小卫星重复序列总数目的 14 5 7%。不同拷贝数目所对应的重复序列的数目情况为 :拷贝数目为 2的重复单位所组成的重复序列数目最多 ,为 137个 ;其次是拷贝数目为 3的重复序列 ,为12 2个 ,且随着拷贝数目的增加 ,由其所组成的重复序列的数目呈递减的趋势。其中一部分序列见GeneBank数据库 ,登录号为AY6 990 72 -AY6 990 76。 398个重复序列分别由 398种重复单位所组成 ,因而小卫星重复序列的类型很多 ,我们初步分成三类 :两种碱基组成类别、三种碱基组成类别和四种碱基组成类别 ,并进一步根据各个重复序列中所含有的碱基种类的数量从大到小排列这些碱基而分成若干小类。从这些分类中可以看出 ,中国明对虾基因组中的小卫星整体上是富含A T的重复序列 ,并具有一定的“等级制度” ,揭示了其与微卫星重复序列之间的关系 ,即一部分小卫星重复序列可能起源于微卫星     

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.     

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.     

Isolation and characterization of simple repeat sequences from the yellow fin sea bream Acanthopagrus latus (Sparidae)

We isolated DNA fragments containing various repetitive elements from the genome of a sea bream Acanthopagrus latus. Sequence analysis indicated that two fragments have particularly interesting features. Fragment AL87 contained a tetranucleotide repeat and a quasipalindromic sequence. Sequence comparison suggested that AL87 may be a part of a gene encoding a serine/threonine protein kinase, and that the quasipalindrome is situated at the junction of an intron and an exon. Moreover, the quasipalindrome is conserved in several other fishes, even though it has the potential to form a stem-loop structure at the splicing site. Fragment AL79 contained a minisatellite sequence made up of six 30-bp units in tandem. DNase I sensitivity assays and statistical analyses showed the repeat region to be flexible when subjected to bending stress. In addition, atomic force microscopic imaging of AL79 showed the presence of highly curved (kinked) segments flanking the repeat region. The structural features of these repetitive elements may be key factors facilitating the amplification of the repeats.     

Human identity testing with PCR-based systems

Large numbers of repetitive stretches of DNA are present within the human genome that are associated with human individuality due to their polymorphic character. Approximately one-third of these repeat sequences is arranged as microsatellites or short tandem repeats (STRs) whose valuable application as state-of-the-art technique in human identity testing will be briefly summarized in this review. Prerequisties for successful DNA typing using STRs amplified by polymerase chain reaction (PCR) are outlined and particular attention is paid to the molecular structure of STRs from autosomes as well as from the Y chromosome. A comprehensive overview about current and emerging methods of STR analysis is given as well.     

The human factor VII gene is polymorphic due to variation in repeat copy number in a minisatellite

The gene coding for human factor VII, a vitamin K-dependent coagulation factor, contains five minisatellite imperfect tandem repeats with monomer element lengths ranging from 14 to 37 bp, and copy numbers ranging from 6 to 52. Three of these repeats are entirely within introns, one is entirely in an untranslated portion of an exon, and one spans an exon-intron border and contains coding sequence. A consensus sequence derived from a comparison of the monomers is similar to a core sequence found in other minisatellites. All of the minisatellites display higher-order periodicities. At least one of these minisatellites is polymorphic. A variation in repeat copy number has been observed in a tandem-repeat region in the seventh factor-VII intron.     

Identification of repetitive, genome-specific probes in crucifer oilseed species.

Direct amplification of minisatellite DNA by PCR (DAMD PCR) was used to amplify and subsequently clone several fragments of DNA from crucifer species. The PCR-derived fragments of DNA were generated using known minisatellite core sequences as PCR primers. Southern hybridization of these putative minisatellite DNA fragments revealed that many were genome-specific; they hybridized with high affinity only to the genomic DNA of the species from which they were cloned. The DNA fragments were believed to be dispersed in the genome, based on smear-like hybridization signals on EcoRI-, BamHI-, and HindIII-digested genomic DNA. Genome-specific probes were specifically isolated from Brassica rapa (A genome), Brassica nigra (B genome), and Sinapis alba in addition to several other crucifer species. The sequence of a B. rapa specific probe (pBr17.1.3A) contained a minisatellite region that could be divided into three tandem repeats; each repeat contained between two and five subrepeats and each subrepeat shared a highly conserved core region of 29 bp. This minisatellite sequence also hybridized with high affinity to the A genome species B. napus and B. juncea. This research showed that dispersed, genome-specific probes can be isolated using DAMD PCR and that these probes could be used to detect and quantify alien DNA present in progeny from intergeneric or interspecific crosses.     

VNTRs in review

In the last decade the study of human genetic variation has made a quantum leap from the analysis of protein and antigen intermediaries to the investigation of DNA itself.¹ The DNA double helix codes genetic information as a sequence of four different nucleotides: adenine (A), guanine (G), cytosine (C), and thymine (T). Nucleotides are nitrogenous bases that bind the complementary strands of the double helix, giving rise to the use of base pairs (bp) as a unit of DNA length. So far so good. Within the human genome there are DNA sequences that do not code for proteins and that consist of short runs of nucleotides, say GTGGACAGG, repeated in tandem hundreds, or even thousands of times. This particular sequence, known as MS1 for minisatellite 1, is found on human chromosome 1 at a locus called D1S7. Although it is old news that there are a lot of repetitive DNAs in the human genome, it is new and very interesting to find that many repetitive DNA loci have arrays of different numbers of repeats in different individuals. These loci are referred to as VNTRs, shorthand for “variable numbers of tandem repeats” or, more flippantly for “very nasty types of repeat.” The finding of hundreds of VNTR loci distributed across all chromosomes exposes a richness of genetic diversity for anthropologists studying human evolutionary history.     

DNA fingerprinting in three species of neotropical primates

DNA fingerprinting allows the simultaneous detection of a large number of hypervariable loci consisting of highly polymorphic tandem repeat units that are extensively dispersed in the genome. With the 33.6 human minisatellite probe, hypervariable fragments were detected, for the first time, in the genome of three different species of wild-caught neotropical primates: Aotus infulatus, Aotus azarae, and Cebus apella. As in the human, these species were highly polymorphic, showing distinctive, individual-specific patterns. Estimates of relatedness within each group were calculated from interspecific comparisons based on the number of shared fragments between individuals. This work shows that the 33.6 human minisatellite probe can be very useful for increasing our understanding of population dynamics and behavior of these species in their natural habitat. © 1996 Wiley-Liss, Inc.     

Molecular evolution of minisatellites in hemiascomycetous yeasts

Minisatellites are DNA tandem repeats exhibiting size polymorphism among individuals of a population. This polymorphism is generated by two different mechanisms, both in human and yeast cells, "replication slippage" during S-phase DNA synthesis and "repair slippage" associated to meiotic gene conversion. The Saccharomyces cerevisiae genome contains numerous natural minisatellites. They are located on all chromosomes without any obvious distribution bias. Minisatellites found in protein-coding genes have longer repeat units and on the average more repeat units than minisatellites in noncoding regions. They show an excess of cytosines on the coding strand, as compared to guanines (negative GC skew). They are always multiples of three, encode serine- and threonine-rich amino acid repeats, and are found preferably within genes encoding cell wall proteins, suggesting that they are positively selected in this particular class of genes. Genome-wide, there is no statistically significant association between minisatellites and meiotic recombination hot spots. In addition, minisatellites that are located in the vicinity of a meiotic hot spot are not more polymorphic than minisatellites located far from any hot spot. This suggests that minisatellites, in S. cerevisiae, evolve probably by strand slippage during replication or mitotic recombination. Finally, evolution of minisatellites among hemiascomycetous yeasts shows that even though many minisatellite-containing genes are conserved, most of the time the minisatellite itself is not conserved. The diversity of minisatellite sequences found in orthologous genes of different species suggests that minisatellites are differentially acquired and lost during evolution of hemiascomycetous yeasts at a pace faster than the genes containing them.     

Human minisatellite alleles detectable only after PCR amplification.

We present evidence that a proportion of alleles at two human minisatellite loci is undetected by standard Southern blot hybridization. In each case the missing allele(s) can be identified after PCR amplification and correspond to tandem arrays too short to detect by hybridization. At one locus, there is only one undetected allele (population frequency 0.3), which contains just three repeat units. At the second locus, there are at least five undetected alleles (total population frequency 0.9) containing 60-120 repeats; they are not detected because these tandem repeats give very poor signals when used as a probe in standard Southern blot hybridization, and also cross-hybridize with other sequences in the genome. Under these circumstances only signals from the longest tandemly repeated alleles are detectable above the nonspecific background. The structures of these loci have been compared in human and primate DNA, and at one locus the short human allele containing three repeat units is shown to be an intermediate state in the expansion of a monomeric precursor allele in primates to high copy number in the longer human arrays. We discuss the implications of such loci for studies of human populations, minisatellite isolation by cloning, and the evolution of highly variable tandem arrays.     

Variable germline and embryonic instability of the human minisatellite MS32 (D1S8) in transgenic mice.

Tandem repeat loci such as minisatellites and trinucleotide repeats frequently show instability. We have investigated mutation at human minisatellite MS32 (locus D1S8) transferred to transgenic mice. Three lines of hemizygous transgenic mice were studied. A single-copy line (110D) was seen to be relatively stable, whilst two multicopy lines showed structural instability of the transgene in pedigrees (lines 109 and 110A). For both these lines, mutant structures were detected as a result of mutation events having occurred in the germline or early embryo. Structural changes seen included gain or loss of minisatellite repeat units (110A and 109), alteration of DNA flanking the minisatellite repeat array (109 only) or deletion of the entire transgene (109 only). This work demonstrates that tandem repeat transgenes can show instability and thus provide additional systems for the analysis of repetitive DNA structural change in mice.     

Simultaneous estimation of all the parameters of a stepwise mutation model.

Minisatellite and microsatellite are short tandemly repetitive sequences dispersed in eukaryotic genomes, many of which are highly polymorphic due to copy number variation of the repeats. Because mutation changes copy numbers of the repeat sequences in a generalized stepwise fashion, stepwise mutation models are widely used for studying the dynamics of these loci. We propose a minimum chi-square (MCS) method for simultaneous estimation of all the parameters in a stepwise mutation model and the ancestral allelic type of a sample. The MCS estimator requires knowing the mean number of alleles of a certain size in a sample, which can be estimated using Monte Carlo samples generated by a coalescent algorithm. The method is applied to samples of seven (CA)n repeat loci from eight human populations and one chimpanzee population. The estimated values of parameters suggest that there is a general tendency for microsatellite alleles to expand in size, because (1) each mutation has a slight tendency to cause size increase and (2) the mean size increase is larger than the mean size decrease for a mutation. Our estimates also suggest that most of these CA-repeat loci evolve according to multistep mutation models rather than single-step mutation models. We also introduced several quantities for measuring the quality of the estimation of ancestral allelic type, and it appears that the majority of the estimated ancestral allelic types are reasonably accurate. Implications of our analysis and potential extensions of the method are discussed.SINCE the discovery that a large number of loci with tandemly repeated sequences in human and many eukaryote species are highly polymorphic because of copy number variation of the repeats in different individuals (Jeffreys 1985; Litt and Luty 1989; Weber and May 1989), allele size data from such loci are rapidly becoming the dominant source of genetic markers for genome mapping, forensic testing, and population studies. Loci with repeat sequences longer than 5 bp are generally referred to as minisatellite or variable number tandem repeat loci, and those with repeat sequences between 2 to 5 bp are referred to as microsatellite or short tandem repeat loci (Tautz 1993). Because mutations change the copy number of such loci in a stepwise fashion, rapid accumulation of population samples from minisatellite and microsatellite loci has resurrected the interest of the stepwise mutation model (SMM), which was popular in the 1970s.     

Slipped-strand mispairing at noncontiguous repeats in Poecilia reticulata: a model for minisatellite birth

The standard slipped-strand mispairing (SSM) model for the formation of variable number tandem repeats (VNTRs) proposes that a few tandem repeats, produced by chance mutations, provide the "raw material" for VNTR expansion. However, this model is unlikely to explain the formation of VNTRs with long motifs (e.g., minisatellites), because the likelihood of a tandem repeat forming by chance decreases rapidly as the length of the repeat motif increases. Phylogenetic reconstruction of the birth of a mitochondrial (mt) DNA minisatellite in guppies suggests that VNTRs with long motifs can form as a consequence of SSM at noncontiguous repeats. VNTRs formed in this manner have motifs longer than the noncontiguous repeat originally formed by chance and are flanked by one unit of the original, noncontiguous repeat. SSM at noncontiguous repeats can therefore explain the birth of VNTRs with long motifs and the "imperfect" or "short direct" repeats frequently observed adjacent to both mtDNA and nuclear VNTRs.     

Mathematical Modelling of Mycobacterium tuberculosis VNTR Loci Estimates a Very Slow Mutation Rate for the Repeats

Minisatellites are highly variable tandem repeats used for over 20 years in humans for DNA fingerprinting. In prokaryotes fingerprinting techniques exploiting VNTR (variable number of tandem repeats) polymorphisms have become widely used recently in bacterial typing. However although many investigations into the mechanisms underlying minisatellite variation in humans have been performed, relatively little is known about the processes that mediate bacterial minisatellite polymorphism. An understanding of this is important since it will influence how the results from VNTR experiments are interpreted. The minisatellites of Mycobacterium tuberculosis are well characterized since they are some of the few polymorphic loci in what is otherwise a very homogeneous organism. Using VNTR results from a well-defined and characterized set of M. tuberculosis strains we show that the repeats at a locus are likely to evolve by stepwise contraction or expansion in the number of repeats. A stochastic continuous-time population mathematical model was developed to simulate the evolution of the repeats. This allowed estimation of the tendency of the repeats to increase or decrease and the rate at which they change. The majority of loci tend to lose rather than gain repeats. All of the loci mutate extremely slowly, with an average rate of 2.3 x 10(-8), which is 350 times slower than that of a set of VNTR repeats with similar diversity observed experimentally in Escherichia coli. This suggests that the VNTR profile of a strain of M. tuberculosis will be indicative of its clonal lineage and will be unlikely to vary in epidemiologically-related strains.     

Repeat instability at human minisatellites arising from meiotic recombination.

Little is known about the role of meiotic recombination processes such as unequal crossover in driving instability at tandem repeat DNA. Methods have therefore been developed to detect meiotic crossovers within two different GC-rich minisatellite repeat arrays in humans, both in families and in sperm DNA. Both loci normally mutate in the germline by complex conversion-like transfer of repeats between alleles. Analysis shows that inter-allelic unequal crossovers also occur at both loci, although at low frequency, to yield simple recombinant repeat arrays with exchange of flanking markers. Equal crossovers between aligned alleles, resulting in recombinant alleles but without change in repeat copy number, also occur in sperm at a similar frequency to unequal crossovers. Both crossover and conversion show polarity in the repeat array and are co-suppressed in an allele showing unusual germline stability. This provides evidence that minisatellite conversion and crossover arise by a common mechanism, perhaps by alternative processing of a meiotic recombination initiation complex, and implies that minisatellite instability is a by-product of meiotic recombination in repeat DNA. While minisatellite recombination is infrequent, crossover rates indicate that the unstable end of a human minisatellite can act as a recombination warm-spot, even between sequence-heterologous alleles.     

A variable tandem repeat locus mapped to chromosome band 10q26 is amplified and rearranged in leukocyte DNAs of two cancer patients.

A highly polymorphic locus associated with the variable tandem repetition of a 35 bp consensus sequence was mapped to chromosome 10, band q26. Examination of leukocyte DNA from a cancer patient revealed the twenty-fold amplification of one allelic fragment of this locus, while the other allelic fragment demonstrated a normal copy number. In another patient, Southern blotting of leukocyte DNA detected the deletion of the 3'-flanking region from one tandem repeat allele. These results indicate that variable tandem repeats may mark highly unstable regions of DNA in the human genome which can be altered by changes more extensive than simple tandem repeat variation.     

Effects of temperature, Mg2+ concentration and mismatches on triplet-repeat expansion during DNA replication in vitro.

The human genome contains many simple tandem repeats that are widely dispersed and highly polymorphic. At least one group of simple tandem repeats, the DNA trinucleotide repeats, can dramaticallyexpand in size during transmission from one generation to the next to cause disease by a process known as dynamic mutation. We investigated the ability of trinucleotide repeats AAT and CAG to expand in size during DNA replication using a minimal in vitro system composed of the repeat tract, with and without unique flanking sequences, and DNA polymerase. Varying Mg2+concentration and temperature gave dramatic expansions of repeat size during DNA replication in vitro. Expansions of up to 1000-fold were observed. Mismatches partially stabilized the repeat tracts against expansion. Expansions were only detected when the primer was complementary to the repeat tract rather than the flanking sequence. The results imply that cellular environment and whether the growing strand contains a nick or gap are important factors for the expansion process in vivo.