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.     

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.     

Stable minihairpin structures forming at minisatellite DNA isolated from yellow fin sea bream Acanthopagrus latus

The lengths of simple repeat sequences are generally unstable or polymorphic (highly variable with respect to the numbers of tandem repeats). Previously we have isolated a family of minisatellite DNA (GenBank accession AF422186) that appears specifically and abundantly in the genome of yellow fin sea bream Acanthopagrus latus but not in closely-related red sea bream Pagrus major, and found that the numbers of tandem arrays in the homologous loci are polymorphic. This means that the minisatellite sequence has appeared and propagated in A. latus genome after speciation. In order to understand what makes the minisatellite widespread within the A. latus genome and what causes the polymorphic nature of the number of tandem repeats, the structural features of single-stranded polynucleotides were analyzed by electrophoresis, chemical modification, circular dichroism (CD), differential scanning calorimetry (DSC) and electron microscopy. The results suggest that a portion of the repeat unit forms a stable minihairpin structure, and it can cause polymerase pausing within the minisatellite DNA.     

Genetic mapping through the use of synthetic tandem repeats in the mouse genome

Polymers of arbitrary oligonucleotides can be used to detect polymorphic loci in a wide range of vertebrate genomes. Using 60 such probes, we previously reported the selection of the most efficient STR probes for polymorphism detection in the set of genomes investigated. We now report the use of this selection for the mouse genome and its contribution to genetic mapping. Twenty-three synthetic tandem repeats (STRs) sequences were probed on a recombinant inbred panel C57B1/6 x DBA/2. The loci detected are distributed in 70 linkage groups; 42 of these groups, corresponding to about 100 different polymorphic loci, include reference markers. These linkage groups appear to be evenly distributed within all the 20 mouse chromosomes with apparently no bias of repartition towards telomeres or centromeres.     

Numerous Length Polymorphisms at Short Tandem Repeats in Human Cytomegalovirus

We show the presence of numerous short tandem repeats in the human cytomegalovirus (HCMV) genome and assess their usefulness as molecular markers. The genome is shown to contain at least 24 microsatellite regions that exhibit length polymorphisms. Insertion-deletion polymorphisms at these short tandem repeats are common (80% of repeats examined are polymorphic among two laboratory strains and 10 clinical isolates). This is the first report of widespread microsatellite length polymorphism in a viral genome. Some regions are highly polymorphic: one was revealed by DNA sequencing to contain length variants at five closely linked sites, which combined resulted in 10 variants for this region among the 12 strains and isolates examined. This study not only provides a new molecular marker system for this virus but also extends our understanding of microsatellite polymorphism in two important ways. First, variable-length repeats in HCMV can be considerably shorter than polymorphic repeats previously found in other organisms. Second, highly variable microsatellite repeats are not confined to prokaryotes and eukaryotes, as previously assumed. This variation provides a useful marker system for distinguishing viral isolates, and similar markers are also likely to be found in other large-genome DNA viruses.     

A collection of ordered tetranucleotide-repeat markers from the human genome. The Utah Marker Development Group.

A collection of 1,069 human PCR-based genetic markers has been developed, and their distribution over the 22 autosomes and the X chromosome has been determined. Each marker was developed around a short-tandem-repeat DNA sequence. The majority (85%) of the markers described here were selected to contain tetranucleotide repeats, because these repeats show better stability during PCR than do dinucleotide repeats. Linkage maps constructed from genotypes collected with these markers in four CEPH pedigrees (1331, 1332, 1362, and 884) covered 3,417 cM of the human genome. More than 600 of the loci revealed heterozygosities > .70. Overall, 444 loci were ordered, with odds > 100:1 against inversion of adjacent loci. The average distance between markers was 7.4 cM on the autosomes and 24.8 cM on the X chromosome. Likely locations (100:1 odds intervals) were assigned for the remaining 621 short-tandem-repeat polymorphisms, as well as for 160 other markers that are present on the framework maps published by the Cooperative Human Linkage Center. Four markers specific to the Y chromosome are also reported here. From our maps, 347 markers were chosen to define "index" maps for each of the 22 autosomes. The index markers detect loci with an average heterozygosity of .85 and cover 3,169 cM of the autosomes, with an average distance between markers of 9.2 cM. These polymorphic short tandem repeats will be highly useful as reagents for the ongoing genetic and physical mapping of the human genome and for characterization of genetic changes in cancer.     

Development of microsatellite genetic markers in Siberian stone pine (<Emphasis Type="Italic">Pinus sibirica</Emphasis> Du Tour) based on the <Emphasis Type="Italic">de novo</Emphasis> whole genome sequencing

Siberian stone pine, Pinus sibirica Du Tour is one of the most economically and environmentally important forest-forming species of conifers in Russia. To study these forests a large number of highly polymorphic molecular genetic markers, such as microsatellite loci, are required. Prior to the new high-throughput next generation sequencing (NGS) methods, discovery of microsatellite loci and development of micro-satellite markers were very time consuming and laborious. The recently developed draft assembly of the Siberian stone pine genome, sequenced using the NGS methods, allowed us to identify a large number of microsatellite loci in the Siberian stone pine genome and to develop species-specific PCR primers for amplification and genotyping of 70 microsatellite loci. The primers were designed using contigs containing short simple sequence tandem repeats from the Siberian stone pine whole genome draft assembly. Based on the testing of primers for 70 microsatellite loci with tri-, tetra- or pentanucleotide repeats, 18 most promising, reliable and polymorphic loci were selected that can be used further as molecular genetic markers in population genetic studies of Siberian stone pine.     

STR markers for detecting heterogeneity in Indian population

Short tandem repeats are highly polymorphic sequences of nucleotides, which are abundant in eukaryotic genome. They form approximately 3% of the total human genome and occur on average in every 10, 000 nucleotides. Due to their small dimension, low mutation, and high level of polymorphism, these markers are intensely used as important genetic markers for mapping studies, disease diagnosis, and human identity testing. In the present study allelic distribution of four autosomal short tandem repeat markers (D21S2055, D21S11, D21S1435 and D21S1411) has been analyzed in Indian population. For determination of heterogeneity and their allelic frequency QF-PCR analysis have been done. All the loci were found highly polymorphic. Marker D21S1411 was the most informative (93.6%) and D21S1435 (70.1%) was the least informative marker in Indian population.     

Genetic analysis of the hypervariable region flanking the human insulin gene.

In order to study the mechanisms for the generation of length diversity within the 5' flanking region of the human insulin gene, we have isolated and sequenced a previously uncharacterized allele. This allele, of a size intermediate between those three already described in the literature, encompasses 1,156 base pairs (bp) and contains 81 reiterated tandem oligonucleotides of 14-15 bp each. Population analysis on 298 independently sampled individuals by Southern blotting of genomic DNA demonstrates that the polymorphic portion of the insulin 5' flanking region varies from 400 to more than 8,000 nucleotides, being encoded by from 30 to over 540 oligomeric repeats. Length variability 5' to the insulin gene is a result primarily of unequal crossing over, which generates an expansion or contraction in the number of tandem repeat units per chromosome. A similar mechanism probably accounts for nondispersed reiterated sequences at other loci in the human genome.     

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.     

Identification of a CA repeat at the TCRA locus using yeast artificial chromosomes: a general method for generating highly polymorphic markers at chosen loci.

The creation of a comprehensive genetic map in human has been limited by the lack of highly polymorphic markers spaced evenly throughout the human genome. We have utilized yeast artificial chromosomes (YAC) containing large human DNA inserts to help identify highly polymorphic (CA)n repeats at a chosen locus. The DNA of a YAC containing the locus was subcloned in M13 vectors, and the recombinants were screened at high stringency to detect preferentially long (CA)n repeats (n greater than 20). These repeats, which are the most likely to be highly polymorphic, were then studied to confirm both the level of polymorphism and their precise genetic location. This strategy has permitted the identification of a new, highly polymorphic CA repeat (77% heterozygosity) at the T cell receptor alpha chain (TCRA) locus on chromosome 14q. It provides a powerful marker for assessing the role of this locus in the susceptibility to autoimmune and infectious diseases. This approach should permit the development of highly polymorphic markers at any targeted locus and rapidly improve the current human genetic map.     

Differentiation of strains of Xylella fastidiosa by a variable number of tandem repeat analysis

Short sequence repeats (SSRs) with a potential variable number of tandem repeat (VNTR) loci were identified in the genome of the citrus pathogen Xylella fastidiosa and used for typing studies. Although mono- and dinucleotide repeats were absent, we found several intermediate-length 7-, 8-, and 9-nucleotide repeats, which we examined for allelic polymorphisms using PCR. Five genuine VNTR loci were highly polymorphic within a set of 27 X. fastidiosa strains from different hosts. The highest average Nei's measure of genetic diversity (H) estimated for VNTR loci was 0.51, compared to 0.17 derived from randomly amplified polymorphic DNA (RAPD) analysis. For citrus X. fastidiosa strains, some specific VNTR loci had a H value of 0.83, while the maximum value given by specific RAPD loci was 0.12. Our approach using VNTR markers provides a high-resolution tool for epidemiological, genetic, and ecological analysis of citrus-specific X. fastidiosa strains.     

Repeat polymorphisms within gene regions: phenotypic and evolutionary implications

We have developed an algorithm that predicted 11,265 potentially polymorphic tandem repeats within transcribed sequences. We estimate that 22% (2,207/9,717) of the annotated clusters within UniGene contain at least one potentially polymorphic locus. Our predictions were tested by allelotyping a panel of approximately 30 individuals for 5% of these regions, confirming polymorphism for more than half the loci tested. Our study indicates that tandem-repeat polymorphisms in genes are more common than is generally believed. Approximately 8% of these loci are within coding sequences and, if polymorphic, would result in frameshifts. Our catalogue of putative polymorphic repeats within transcribed sequences comprises a large set of potentially phenotypic or disease-causing loci. In addition, from the anomalous character of the repetitive sequences within unannotated clusters, we also conclude that the UniGene cluster count substantially overestimates the number of genes in the human genome. We hypothesize that polymorphisms in repeated sequences occur with some baseline distribution, on the basis of repeat homogeneity, size, and sequence composition, and that deviations from that distribution are indicative of the nature of selection pressure at that locus. We find evidence of selective maintenance of the ability of some genes to respond very rapidly, perhaps even on intragenerational timescales, to fluctuating selective pressures.     

Genetic variation at five trimeric and tetrameric tandem repeat loci in four human population groups.

Trimeric and tetrameric short tandem repeats (STRs) represent a rich source of highly polymorphic markers in the human genome that may be studied with the polymerase chain reaction (PCR). We report the analysis of a multilocus genotype survey of 97-380 chromosomes in U.S. Black, White, Mexican-American, and Asian populations at five STR loci located on chromosomes 1, 4, 11, and X. The heterozygote frequencies of the loci ranged from 0.36 to 0.91 and the number of alleles from 6 to 20 for the 20 population and locus combinations. Relative allele frequencies exhibited differences between populations and unimodal, bimodal, and complex distributions. Although deviations were noted at some locus-population test combinations, genotype data from the loci were consistent overall with Hardy-Weinberg equilibrium by three tests. Population subheterogeneity within each ethnic group was not detected by two additional tests. No mutations were detected in a total of 860 meioses for two loci studied in the CEPH kindreds and five loci studied in other families. An indirect estimate of the mutation rates gave values from 2.3 x 10(-5) to 15.9 x 10(-5) for the five loci. Higher mutation rates appear to be associated with greater numbers of tandem repeats in the core motif. The most frequent genotype for all five loci combined appears to have a frequency of 7.59 x 10(-4). Together, these results suggest that trimeric and tetrameric STR loci are useful markers for the study of new mutations and genetic linkage analysis and for application to personal identification in the medical and forensic sciences.     

An exhaustive DNA micro-satellite map of the human genome using high performance computing

The current pace of the generation of sequence data requires the development of software tools that can rapidly provide full annotation of the data. We have developed a new method for rapid sequence comparison using the exact match algorithm without repeat masking. As a demonstration, we have identified all perfect simple tandem repeats (STR) within the draft sequence of the human genome. The STR elements (chromosome, position, length and repeat subunit) have been placed into a relational database. Repeat flanking sequence is also publicly accessible at http://grid.abcc.ncifcrf.gov. To illustrate the utility of this complete set of STR elements, we documented the increased density of potentially polymorphic markers throughout the genome. The new STR markers may be useful in disease association studies because so many STR elements manifest multiallelic polymorphism. Also, because triplet repeat expansions are important for human disease etiology, we identified trinucleotide repeats that exist within exons of known genes. This resulted in a list that includes all 14 genes known to undergo polynucleotide expansion, and 48 additional candidates. Several of these are non-polyglutamine triplet repeats. Other examinations of the STR database demonstrated repeats spanning splice junctions and identified SNPs within repeat elements.     

Alu repeats in the human genome

Highly repetitive DNA sequences account for more than 50% of the human genome. The L1 and Alu families harbor the most common mammalian long (LINEs) and short (SINEs) interspersed elements. Alu elements are each a dimer of similar, but not identical, fragments of total size about 300 bp, and originate from the 7SL RNA gene. Each element contains a bipartite promoter for RNA polymerase III, a poly(A) tract located between the monomers, a 3'-terminal poly(A) tract, and numerous CpG islands, and is flanked by short direct repeats. Alu repeats comprise more than 10% of the human genome and are capable of retroposition. Possibly, these elements played an important part in genome evolution. Insertion of an Alu element into a functionally important genome region or other Alu-dependent alterations of gene functions cause various hereditary disorders and are probably associated with carcinogenesis. In total, 14 Alu families differing in diagnostic mutations are known. Some of these, which are present in the human genome, are polymorphic and relatively recently inserted into new loci. Alu copies transposed during ethnic divergence of the human population are useful markers for evolutionary genetic studies.     

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.     

Characterization of microsatellites in Bambusa arundinacea and cross species amplification in other bamboos

Microsatellites, tandem repeats of short nucleotide (1-6 bp) sequences, are the DNA marker of choice because of their highly polymorphic, ubiquitous distribution within genome, ease of genotyping through polymerase chain reaction (PCR), selectively neutral, co-dominant and multi allelic nature. Six microsatellites, three polymorphic and three monomorphic, have been characterized for the first time in a bamboo species, Bambusa arudinacea belonging to the family Poaceae. The number of alleles per locus ranges form 2 to 13. Allelic diversity ranges from 0.041 to 0.870. Polymorphic information content (PIC) values for two loci were > 0.3, an indicator of polymorphic allele. Cross species amplification has been tested in other 18 bamboo species. Monomorphic simple sequence repeats (SSRs) have been found to be cross amplified in most of the tested species while polymorphic ones in only three to four species. The utility of the SSR loci in genetic diversity study of B. arundinacea and other cross amplified bamboo species have been discussed.     

Differentiation of Strains of Xylella fastidiosa by a Variable Number of Tandem Repeat Analysis

Short sequence repeats (SSRs) with a potential variable number of tandem repeat (VNTR) loci were identified in the genome of the citrus pathogen Xylella fastidiosa and used for typing studies. Although mono- and dinucleotide repeats were absent, we found several intermediate-length 7-, 8-, and 9-nucleotide repeats, which we examined for allelic polymorphisms using PCR. Five genuine VNTR loci were highly polymorphic within a set of 27 X. fastidiosa strains from different hosts. The highest average Nei's measure of genetic diversity (H) estimated for VNTR loci was 0.51, compared to 0.17 derived from randomly amplified polymorphic DNA (RAPD) analysis. For citrus X. fastidiosa strains, some specific VNTR loci had a H value of 0.83, while the maximum value given by specific RAPD loci was 0.12. Our approach using VNTR markers provides a high-resolution tool for epidemiological, genetic, and ecological analysis of citrus-specific X. fastidiosa strains.     

Design and implementation of degenerate microsatellite primers for the mammalian clade

Microsatellites are popular genetic markers in molecular ecology, genetic mapping and forensics. Unfortunately, despite recent advances, the isolation of de novo polymorphic microsatellite loci often requires expensive and intensive groundwork. Primers developed for a focal species are commonly tested in a related, non-focal species of interest for the amplification of orthologous polymorphic loci; when successful, this approach significantly reduces cost and time of microsatellite development. However, transferability of polymorphic microsatellite loci decreases rapidly with increasing evolutionary distance, and this approach has shown its limits. Whole genome sequences represent an under-exploited resource to develop cross-species primers for microsatellites. Here we describe a three-step method that combines a novel in silico pipeline that we use to (1) identify conserved microsatellite loci from a multiple genome alignments, (2) design degenerate primer pairs, with (3) a simple PCR protocol used to implement these primers across species. Using this approach we developed a set of primers for the mammalian clade. We found 126,306 human microsatellites conserved in mammalian aligned sequences, and isolated 5,596 loci using criteria based on wide conservation. From a random subset of ~1000 dinucleotide repeats, we designed degenerate primer pairs for 19 loci, of which five produced polymorphic fragments in up to 18 mammalian species, including the distinctly related marsupials and monotremes, groups that diverged from other mammals 120-160 million years ago. Using our method, many more cross-clade microsatellite loci can be harvested from the currently available genomic data, and this ability is set to improve exponentially as further genomes are sequenced.