Silene tatarica microsatellites are frequently located in repetitive DNA

The genomic distribution of microsatellites can be explained by DNA slippage, slippage like processes and base substitutions. Nevertheless, microsatellites are also frequently associated with repetitive DNA, raising the question of the relative contributions of these processes to microsatellite genesis. We show that in Silene tatarica about 50% of the microsatellites isolated by an enrichment cloning protocol are associated with repetitive DNA. Based on the flanking sequences, we distinguished seven different classes of repetitive DNA. PCR primers designed for the flanking sequences of an individual clone amplified a heterogeneous family of repetitive DNA. Despite considerable variation in the flanking sequence (pi = 0.108), the microsatellite repeats did not show any evidence for decay. Rather, we observed the emergence of a new repeat type that probably arose by mutation and was spread by replication slippage. In fact, a complete repeat type switch could be observed among the analysed clones. We propose that the analysis of microsatellite sequences embedded in repetitive DNA provides a hitherto largely unexplored tool to study microsatellite evolution.     

DNA polymerase-catalyzed elongation of repetitive hexanucleotide sequences: application to creation of repetitive DNA libraries

We demonstrate the elongation of various hexanucleotide sequences with thermophilic DNA polymerase, under isothermal or thermal cyclic reaction conditions. We prepared 10 types of double repeat hexanucleotide duplexes with various GC compositions containing between 0 and 6 GC nucleotides per repeat and incubated these duplexes with thermophilic Taq DNA polymerase and dNTPs at various temperatures. All of the model repetitive short duplexes were elongated under the isothermal incubation conditions, although there were some differences in the elongation efficiencies derived from the GC composition in the repetitive sequences. It was also found that all of the model repetitive duplexes were extended more effectively by a 3-step thermal cyclic reaction involving denaturation, annealing, and extension. On the basis of this technique, we prepared a glutamate-encoding short repetitive duplex and created long repetitive DNAs under isothermal and thermal cyclic reaction conditions. DNA sequencing analysis of the cloned repetitive DNA revealed that well-ordered long repetitive DNAs of various chain lengths were created by this DNA polymerase-catalyzed ligation method, and these were easily cloned into vectors by the TA-cloning method. This method could be useful for obtaining DNAs encoding arbitrary long repetitive amino acid sequences more effectively than the conventional T4 ligase-catalyzed ligation method.     

Elongation of repetitive DNA by DNA polymerase from a hyperthermophilic bacterium Thermus thermophilus

Short repetitive DNA sequences are believed to be one of the primordial genetic elements that served as a source of complex large DNA found in the genome of modern organisms. However, the mechanism of its expansion (increase in repeat number) during the course of evolution is unclear. We demonstrate that the DNA polymerase of the hyperthermophilic bacterium Thermus thermophilus can elongate oligoDNA with several tandem repeats to very long DNA in vitro. For instance, 48mer repetitive oligoDNA (TACATGTA)₆, which has 25% GC content and a palindromic sequence, can be elongated up to ~10 000 bases by DNA polymerase at 74°C without template DNA. OligoDNA having a different GC content or a quasi-palindromic sequence can also be elongated, but less efficiently. A spectroscopic thermal melting experiment with the oligoDNA showed that its hairpin–coil transition temperature was very close to the elongation reaction temperature (74°C), but was much higher than the temperature at which duplex oligoDNA can exist stably. Taken together, we conclude that repetitive oligoDNA with a palindromic or quasi-palindromic sequence is elongated extensively by a hyperthermophilic DNA polymerase through hairpin–coil transitions. We propose that such an elongation mechanism might have been a driving force to expand primordial short DNA.     

To slip or skip, visualizing frameshift mutation dynamics for error-prone DNA polymerases

Three models describing frameshift mutations are "classical" Streisinger slippage, proposed for repetitive DNA, and "misincorporatation misalignment" and "dNTP-stabilized misalignment," proposed for non-repetitive DNA. We distinguish between models using pre-steady state fluorescence kinetics to visualize transiently misaligned DNA intermediates and nucleotide incorporation products formed by DNA polymerases adept at making small frameshift mutations in vivo. Human polymerase (pol) mu catalyzes Streisinger slippage exclusively in repetitive DNA, requiring as little as a dinucleotide repeat. Escherichia coli pol IV uses dNTP-stabilized misalignment in identical repetitive DNA sequences, revealing that pol mu and pol IV use different mechanisms in repetitive DNA to achieve the same mutational end point. In non-repeat sequences, pol mu switches to dNTP-stabilized misalignment. pol beta generates -1 frameshifts in "long" repeats and base substitutions in "short" repeats. Thus, two polymerases can use two different frameshift mechanisms on identical sequences, whereas one polymerase can alternate between frameshift mechanisms to process different sequences.     

Microsatellite instability in yeast: dependence on repeat unit size and DNA mismatch repair genes.

We examined the stability of microsatellites of different repeat unit lengths in Saccharomyces cerevisiae strains deficient in DNA mismatch repair. The msh2 and msh3 mutations destabilized microsatellites with repeat units of 1, 2, 4, 5, and 8 bp; a poly(G) tract of 18 bp was destabilized several thousand-fold by the msh2 mutation and about 100-fold by msh3. The msh6 mutations destabilized microsatellites with repeat units of 1 and 2 bp but had no effect on microsatellites with larger repeats. These results argue that coding sequences containing repetitive DNA tracts will be preferred target sites for mutations in human tumors with mismatch repair defects. We find that the DNA mismatch repair genes destabilize microsatellites with repeat units from 1 to 13 bp but have no effect on the stability of minisatellites with repeat units of 16 or 20 bp. Our data also suggest that displaced loops on the nascent strand, resulting from DNA polymerase slippage, are repaired differently than loops on the template strand.     

Frequent non-reciprocal exchange in microsatellite-containing-DNA-regions of vertebrates

Microsatellites are DNA-fragments containing short repetitive motifs with 2–10 bp. They are highly variable in most species and distributed throughout the whole genome. It is broadly accepted that their high degree of variability is closely associated with mispairing of DNA-strands during the replication phase, termed slippage, although recombination is also observed. The aim of this study is to demonstrate evidence that non-reciprocal recombination processes changing the total genomic structure are common in microsatellites and flanking regions. We sequenced DNA fragments from birds in which microsatellites are located, and analyzed the structure of the microsatellites and their flanking regions. Additionally, other data and those from literature of three microsatellite regions of primates coding for the Ataxin-2, the Huntingtin and the TATA-box binding protein were analyzed. The structures of seven avian and three primate microsatellites support the hypothesis that non-reciprocal recombination is a common process that may also contribute considerably to the variation at microsatellite loci. We conclude that results of population genetic studies that are analyzed statistically with methods based on stepwise mutation models should be interpreted with caution if no detailed information on the allelic variation of microsatellites is available.     

DNA recombination during PCR.

PCR co-amplification of two distinct HIV1 tat gene sequences lead to the formation of recombinant DNA molecules. The frequency of such recombinants, up to 5.4% of all amplified molecules, could be decreased 2.7 fold by a 6 fold increase in Taq DNA polymerase elongation time. Crossover sites mapped essentially to three discrete regions suggesting specific Taq DNA polymerase pause or termination sites. PCR mediated recombination may be a problem when studying heterogeneous genetic material such as RNA viruses, multigene families, or repetitive sequences. This phenomenon can be exploited to create chimeric molecules from related sequences.     

Selection and slippage creating serine homopolymers

Highly repetitive sequence within proteins is an abundant feature yet is considered by some to be the protein equivalent of "junk DNA." Homopolymer sequences, the most highly repetitive of this group, are typically encoded by trinucleotide repeats at the DNA level. It is thought that many of these sequences are produced by a replicative slippage mechanism. Recent studies suggest that these highly mutable regions within proteins may allow for rapid morphological evolution emerging from the increased variability afforded by such coding structures. However, in a homopolymer, it is difficult to determine if the repeated amino acid is due to slippage at the DNA level or due to selection at the protein level. Here we develop and test a model to detect cases for which the homopolymer tract has clearly been selected for, with no evidence of slippage at the DNA level. The polyserine tract within the phosphatidylserine receptor protein is used as an excellent example of one such case.     

三核苷酸双链重复序列扩展合成特性及其机理

简单重复序列在各种生物基因组中广泛存在,同分子进化、遗传多样性、分子标记和某些遗传性疾病等密切相关．本文以全部32种18 bp三核苷酸双链重复序列作为研究对象,对它们在聚合酶作用下的扩展合成进行了系统研究．探讨了反应温度、序列本身等对扩展效率和产物长度的影响．结果显示,几乎所有的序列都能扩展变长．但序列对其扩展效率有很大影响：GC含量较多的短链,尤其是一条链中同时有G和C的短链扩展效率较高;全由AC和GT组成的双链也较易扩展．短链的最适扩展温度与短链GC组成呈一定的正相关关系．琼脂糖凝胶电泳和聚丙烯酰胺凝胶电泳分析发现,大部分产物单一性良好,且产物分子质量的大小随反应时间线性增加;随着反应温度升高,产物差异性增大．最后分析了双链重复序列的“复制滑移”扩展机理,有望为进一步研究重复序列的分子进化和基因检测中的非特异性扩增等奠定基础．     

Low-copy microsatellite recovery from a conifer genome

Microsatellite development has been stymied by highly repetitive DNA in the large, highly duplicated conifer genome and by so few genomic conifer sequences in public databases. Recovery of microsatellites from the low-copy component was tested as an efficient approach to marker development. Microsatellites were isolated from Pinus taeda L. via low-copy enrichment and filter-hybridization of tri- and tetra-nucleotide repeat motifs. Efficiency at three phases of marker development was compared for low-copy and total-genome control libraries. In the first phase, enrichment for microsatellites was slightly lower in the low-copy libraries. In the second phase, redundancy was higher in the low-copy libraries. In the third phase, low-copy libraries provided more polymorphic markers than total-genome libraries. Of 418 sequenced low-copy clones, 102 were unique sequences with repeat motifs. Of these unique sequences, twice as many were useful for marker development compared to the total-genome control. Difficulty in microsatellite marker development due to highly repetitive DNA can be abated by low-copy enrichment or circumvented by selecting for specific CG-rich trinucleotide repeat motifs. Sixteen new low-copy and genomic P. taeda microsatellites were given as an example. Received: 19 April 2000 / Accepted: 27 February 2001     

Characterization of equine microsatellites and microsatellite-linked repetitive elements (eMLREs) by efficient cloning and genotyping methods.

We performed efficient cloning and genotyping methods for isolation of a large number of polymorphic microsatellites. The methods contain the time-efficient cloning method of constructing microsatellite-enriched libraries and the economic genotyping method of fluorescent labeling of PCR products. Eighty novel equine microsatellites cloned were efficiently isolated from the enrichment library and analyzed for genotype polymorphism. Of these, 72 microsatellites were analyzed with a good resolution. The average heterozygosity of all loci was 0.52, and the number of alleles ranged from one to 9 with an average of 4.5 alleles. The other eight loci showed multiple bands of PCR products, suggesting the occurrence of microsatellites in a repetitive element, in which the number of microsatellite repeats varies among different members of the repetitive element. We found five homologous groups at flanking regions in comparison with the flanking regions of microsatellites from DNA databases. One of them showed homology to equine repetitive element-2. In the other four homologous groups, the two groups were named equine microsatellite-linked repetitive element-1 (eMLRE-1) and equine microsatellite-linked repetitive element-2 (eMLRE-2) as novel equine repetitive elements identified from equine genome. These data should help the analysis of equine DNA sequences and the design of equine genome markers.     

Characterization of rabbit DNA micros extracted from the EMBL nucleotide sequence database

Microsatellite polymorphisms are invaluable for mapping vertebrate genomes. In order to estimate the occurrence of microsatellites in the rabbit genome and to assess their feasibility as markers in rabbit genetics, a survey on the presence of all types of mononucleotide, dinucleotide, trinucleotide and tetranucleotide repeats, with a length of about 20 bp or more, was conducted by searching the published rabbit DNA sequences in the EMBL nucleotide database (version 32). A total of 181 rabbit microsatellites could be extracted from the present database. The estimated frequency of microsatellites in the rabbit genome was one microsatellite for every 2–3 kb of DNA. Dinucleotide repeats constituted the prevailing class of microsatellites, followed by trinucleotide, mononucleotide and tetranucleotide repeats, respectively. The average length of the microsatellites, as found in the database, was 26, 23, 23 and 22 bp for mono-, di-, tri- and tetranucleotide repeats, respectively. The most common repeat motif was AG, followed by A, AC, AGG and CCG. This group comprised about 70% of all extracted rabbit microsatellites. About 61% of the microsatellites were found in non-coding regions of genes, whereas 15% resided in (protein) coding regions. A significant fraction of rabbit microsatellites (about 22%) was found within interspersed repetitive DNA sequences.     

Survey of human and rat microsatellites

Length variations in simple sequence tandem repeats (microsatellite DNA polymorphisms) are finding increasing usage in mammalian genetics. Although every variety of short tandem repeat that has been tested has been shown to exhibit length polymorphisms, little information on the relative abundance of the different repeat motifs has been collected. In this report, summaries of GenBank searches for all possible human and rat microsatellites ranging from mononucleotide to tetranucleotide repeats are presented. In humans, the five most abundant microsatellites with total lengths for the runs of repeats of greater than or equal to 20 nucleotides contained repeat sequences of A, AC, AAAN, AAN, and AG, in order of decreasing abundance, where N is C, G, or T. These five groups comprised about 76% of all microsatellites. Many other human simple sequence repeats were found at low frequency. In the 745 kb of human genomic DNA surveyed, one microsatellite of greater than or equal to 20 nucleotides in length was found, on average, every 6 kb. Only 12% of the human microsatellites had total lengths greater than or equal to 40 nucleotides. Roughly 80% of the A, AAN, and AAAN microsatellites and 50% of the AT microsatellites, but few of the other human microsatellites, were found to be associated with interspersed, repetitive Alu elements. In rats, the five most abundant microsatellites contained AC, AG, A, AAAN, and AAGG sequences, respectively. Rat microsatellites were generally longer than human microsatellites, with 43% of the rat sequences greater than or equal to 40 nucleotides.     

Low abundance of Escherichia coli microsatellites is associated with an extremely low mutation rate

It is widely assumed that microsatellites are generated by replication slippage, a mutation process specific to repetitive DNA. Consistent with their high mutation rate, microsatellites are highly abundant in most eukaryotic genomes. In Escherichia coli, however, microsatellites are rare and short despite the fact that a high microsatellite mutation rate was described. We show that this high microsatellite instability depends on the presence of the F-plasmid. E. coli cells lacking the F-plasmid have extremely low microsatellite mutation rates. This result provides a possible explanation for the genome-wide low density of microsatellites in E. coli. Furthermore, we show that the F-plasmid induced microsatellite instability is independent of the mismatch repair pathway.     

Neurological proteins are not enriched for repetitive sequences

Proteins associated with disease and development of the nervous system are thought to contain repetitive, simple sequences. However, genome-wide surveys for simple sequences within proteins have revealed that repetitive peptide sequences are the most frequent shared peptide segments among eukaryotic proteins, including those of Saccharomyces cerevisiae, which has few to no specialized developmental and neurological proteins. It is therefore of interest to determine if these specialized proteins have an excess of simple sequences when compared to other sets of compositionally similar proteins. We have determined the relative abundance of simple sequences within neurological proteins and find no excess of repetitive simple sequence within this class. In fact, polyglutamine repeats that are associated with many neurodegenerative diseases are no more abundant within neurological specialized proteins than within nonneurological collections of proteins. We also examined the codon composition of serine homopolymers to determine what forces may play a role in the evolution of extended homopolymers. Codon type homogeneity tends to be favored, suggesting replicative slippage instead of selection as the main force responsible for producing these homopolymers.     

DNA polymerase kappa produces interrupted mutations and displays polar pausing within mononucleotide microsatellite sequences

Microsatellites are ubiquitously present in eukaryotic genomes and are implicated as positive factors in evolution. At the nucleotide level, microsatellites undergo slippage events that alter allele length and base changes that interrupt the repetitive tract. We examined DNA polymerase errors within a [T]₁₁ microsatellite using an in vitro assay that preferentially detects mutations other than unit changes. We observed that human DNA polymerase kappa (Pol κ) inserts dGMP and dCMP within the [T]₁₁ mononucleotide repeat, producing an interrupted 12-bp allele. Polymerase β produced such interruptions at a lower frequency. These data demonstrate that DNA polymerases are capable of directly producing base interruptions within microsatellites. At the molecular level, expanded microsatellites have been implicated in DNA replication fork stalling. Using an in vitro primer extension assay, we observed sequence-specific synthesis termination by DNA polymerases within mononucleotides. Quantitatively, intense, polar pausing was observed for both pol κ and polymerase α-primase within a [T]₁₁ allele. A mechanism is proposed in which pausing results from DNA bending within the duplex stem of the nascent DNA. Our data support the concept of a microsatellite life-cycle, and are consistent with the models in which DNA sequence or secondary structures contributes to non-uniform rates of replication fork progression.     

Organization and evolution of highly repeated satellite DNA sequences in plant chromosomes

A major component of the plant nuclear genome is constituted by different classes of repetitive DNA sequences. The structural, functional and evolutionary aspects of the satellite repetitive DNA families, and their organization in the chromosomes is reviewed. The tandem satellite DNA sequences exhibit characteristic chromosomal locations, usually at subtelomeric and centromeric regions. The repetitive DNA family(ies) may be widely distributed in a taxonomic family or a genus, or may be specific for a species, genome or even a chromosome. They may acquire large-scale variations in their sequence and copy number over an evolutionary time-scale. These features have formed the basis of extensive utilization of repetitive sequences for taxonomic and phylogenetic studies. Hybrid polyploids have especially proven to be excellent models for studying the evolution of repetitive DNA sequences. Recent studies explicitly show that some repetitive DNA families localized at the telomeres and centromeres have acquired important structural and functional significance. The repetitive elements are under different evolutionary constraints as compared to the genes. Satellite DNA families are thought to arise de novo as a consequence of molecular mechanisms such as unequal crossing over, rolling circle amplification, replication slippage and mutation that constitute "molecular drive".     

Encoded errors: mutations and rearrangements mediated by misalignment at repetitive DNA sequences

Mutations and rearrangements that occur by misalignment during DNA replication are frequent sources of genetic variation in bacteria. Dislocations between a replicating strand and its template at repetitive DNA sequences underlie the mechanism of these genetic events. Such misalignments can be transient or stable and can involve intramolecular or intermolecular DNA mispairing, even pairing across a replication fork. Paradoxically, these replication 'slippage' events both create and destroy repetitive sequences in bacterial genomes. This review catalogues several types of slippage errors, presents the cellular processes that act to limit them and discusses the consequences of this class of genetic events on the evolution of bacterial genomes and physiology.