An unusually low microsatellite mutation rate in Dictyostelium discoideum, an organism with unusually abundant microsatellites

The genome of the social amoeba Dictyostelium discoideum is known to have a very high density of microsatellite repeats, including thousands of triplet microsatellite repeats in coding regions that apparently code for long runs of single amino acids. We used a mutation accumulation study to see if unusually high microsatellite mutation rates contribute to this pattern. There was a modest bias toward mutations that increase repeat number, but because upward mutations were smaller than downward ones, this did not lead to a net average increase in size. Longer microsatellites had higher mutation rates than shorter ones, but did not show greater directional bias. The most striking finding is that the overall mutation rate is the lowest reported for microsatellites: approximately 1 x 10(-6) for 10 dinucleotide loci and 6 x 10(-6) for 52 trinucleotide loci (which were longer). High microsatellite mutation rates therefore do not explain the high incidence of microsatellites. The causal relation may in fact be reversed, with low mutation rates evolving to protect against deleterious fitness effects of mutation at the numerous microsatellites.     

Abundance and polymorphism of microsatellite markers in the tea tree (Melaleuca alternifolia, Myrtaceae)

 The sequencing of 831 clones from an enriched microsatellite library of Melaleuca alternifolia (Myrtaceae) yielded 715 inserts containing repeat motifs. The majority of these (98%) were dinucleotide repeats or trinucleotide repeats averaging 22 and 8 repeat motifs respectively. The AG/GA motif was the most common, accounting for 43% of all microsatellites. From a total of 139 primer pairs designed, 102 produced markers within the expected size range. The majority of these (93) were polymorphic. Primer pairs were tested on five selected M. alternifolia genotypes. Loci based on dinucleotide repeats detected on average a greater number of alleles (4.2) than those based on trinucleotide repeats (2.9). The loci described will provide a large pool of polymorphisms useful for population studies, genetic mapping, and possibly application in other Myrtaceae. Received: 28 July 1998 / Accepted: 8 October 1998     

Characterization and analysis of microsatellite loci in Elymus caninus (Triticeae: Poaceae)

 Microsatellites are highly variable DNA sequences that can be used as markers for the genetic analysis of plants. The potential of microsatellite markers for use in a genetic diversity study in Elymus species was evaluated. Genomic libraries of Elymus caninus were constructed. The libraries were screened with two dinucleotide, (GA)n and (GT)n, and two trinucleotide repeats, (TCT)n and (CAC)n. A total of 19 positive clones were found for the two dinucleotide repeats; no positive clone was found for the trinucleotide repeats. Positive clones were sequenced to confirm the presence of microsatellites and to generate polymerase chain reaction (PCR) primers based on the sequences flanking the microsatellite. All sequenced (GA)n clones have repeats of n>10; over half of the (GT)n microsatellites have n<10 repeats. Primer pairs were designed and evaluated for 8 selected microsatellites. PCR products were amplified from 15 Elymus caninus accessions. The number of alleles found for the eight loci varied from 1 for ECGA89 and ECGT35 to 13 for ECGA22, as determined by non-denaturing polyacrylamide electrophoresis. Six microsatellite loci were found to be polymorphic in E. caninus. The eight primer pairs were tested on three other species; seven were successful in amplifying DNA from Elymus alaskanus and E. mutabilis, and four amplified DNA from E. caucasicus. Based on these results, microsatellites appear to be useful markers in detecting variation in E. caninus. Received: 8 September 1997/Accepted: 6 October 1997     

Heterogeneous evolution of microsatellites revealed by reconstruction of recent mutation history in an invasive apomictic snail, Potamopyrgus antipodarum

Heterogeneous patterns of microsatellite evolution present a major challenge for the development of mutation models, and an improved understanding of the determinants of variation in mutation rates and patterns among loci, alleles and taxa is required. A 19th Century bottleneck associated with the introduction of clones of the snail Potamopyrgus antipodarum to Britain presented an opportunity to reconstruct recent microsatellite evolution within the most common apomictic lineage. There was significant variation in both the number and step size of mutations among the seven loci studied. Patterns of mutability were consistent with higher mutation rates for di- than trinucleotides and for longer alleles at a locus. Mutation size was influenced in a more complex way, decreasing with relative allele length much more strongly for tri-, than dinucleotides. We found support for this latter, highly novel result in the literature via reanalysis of data in a recent genome-scan study of human microsatellites, which showed a similarly disparate pattern of length-dependence between di- and trinucleotides. In spite of the apomictic form of reproduction and an unusually strong excess of microsatellite contractions in P. antipodarum, there were notable similarities with mutation processes of human microsatellites, supporting the wider taxonomic generality of such evolutionary mechanisms.     

Polymorphism of Microsatellite Markers in Papaya (<Emphasis Type="Italic">Carica papaya</Emphasis> L.)

A set of 81 new microsatellite markers for Carica papaya L. previously identified by data mining using freely available sequence information from Genbank were tested for polymorphism using 30 germplasm accessions from the Papaya Germplasm Bank (PGM) at Embrapa Mandioca e Fruticultura Tropical (CNPMF) and 18 landraces. The data were used to estimate pairwise genetic distances between the genotypes. A neighbor-joining based dendrogram was used to define clusters and infer possible genetic structuring of the collection. Most microsatellites were polymorphic (73%), with an observed number of alleles per locus ranging from one to eleven. The levels of observed and expected heterozygosity for 51 polymorphic loci varied from 0.00 to 0.85 and from 0.08 to 0.82, averaging 0.19 and 0.59, respectively. Forty-four percent of microsatellites showed polymorphism information content (PIC) higher than 0.50. The compound microsatellites seem to be more informative than dinucleotide and trinucleotide repeats in average alleles per locus and PIC. Among dinucleotides, AG/TC or GA/CT repeat motifs exhibited more informativeness than TA/AT, GT/CA and TG/AC repeat motifs. The neighbor-joining analysis based on shared allele distance could differentiate all the papaya accessions and landraces as well as differences in their genetic structure. This set of markers will be useful for examining parentage, inbreeding and population structure in papaya.     

鳞翅目昆虫基因组中微卫星DNA的特征以及对其分离的影响

本文根据我们对鳞翅目昆虫棉铃虫和松毛虫以及其它动物 (筏蜘蛛、朱、鳕鱼和飞蝗 )的微卫星富集性基因组DNA文库的筛选和分析结果 ,结合其它实验室已发表的资料 ,对鳞翅目昆虫基因组中微卫星DNA的丰度和结构特点进行了较为系统的分析。结果表明 :与其它类群相比 ,尽管鳞翅目昆虫物种间存在差异 ,但其基因组中存在明显偏多的侧翼序列重复的、以多拷贝形式存在的微卫星位点 ,且其中相当一部分以基因家族的形式存在。微卫星DNA家族通常可以在序列分析阶段被识别出来 ,但很多多拷贝位点只有通过一系列后续分析才能被检查出来。这应是鳞翅目昆虫中微卫星位点的优化率相对偏低的主要原因。棉铃虫和松毛虫基因组中三相重复微卫星丰度相对较高 ,从而从某种程度上补偿了这些物种微卫星分离过程中因丰度低、多拷贝位点比例高所带来的困难。棉铃虫微卫星DNA家族侧翼序列中多聚T/A序列的存在表明 ,逆转录转座或逆转录侵染可能是在基因组中形成多拷贝微卫星位点和微卫星DNA家族的重要机制之一     

Characterization of microsatellite loci in Anopheles flavirostris,the principal malaria vector in the Philippines

Microsatellites were isolated and characterized from Anopheles flavirostris, the principal malaria vector in the Philippines. Fifty of the 150 positive clones sequenced contained mostly dinucleotide microsatellites and only 16 had trinucleotide repeats. We designed primers from the unique sequences flanking 18 microsatellite loci. Of these, 11 loci produced successful amplification and revealed high levels of polymorphism; 86 alleles were detected with allele number ranging from 2 to 16 at each locus. The high allelic variability will make these microsatellite loci very useful for taxonomic and population genetic studies.     

Mutation rate variation at human dinucleotide microsatellites

Mutation is the ultimate source of genetic variation, and mutation rate is thus an important parameter governing the extent of genetic variation. Microsatellites are highly informative genetic markers that have been widely used in genetic studies. While previous studies showed that the mutation rate differs in di-, tri-, and tetranucleotide repeats, how mutation rate distributes within each class of repeat is poorly understood. This study first revealed the pattern of the mutation rate variation within the dinucleotide repeats. Two data sets were used. The first is the allele frequency data from 115 microsatellites with dinucleotide repeats distributed along the human genome in 10 worldwide populations. The second data set is much larger, consisting of the allele frequency of 5252 dinucleotide repeats from the Genome Database. Mutation rate for each locus is estimated through a new homozygosity-based estimator, which has been shown to be unbiased and highly efficient and is reasonably robust against deviations from the single-step model. The mutation rates among loci can be approximated well by a gamma distribution and its shape parameter can be accurately estimated with this approach. This result provides the basic guidelines for analyzing the large-scale genomic data from microsatellite loci.     

Simple sequence repeats for genetic studies of alpaca

Trace sequences from the 2X alpaca genome sequencing effort were examined to identify simple sequence repeats (microsatellites) for genetic studies. A total of 6,685 repeat-containing sequences were downloaded from GenBank, processed, and assembled into contigs representing an estimated 4,278 distinct sequences. This sequence set contained 2,290 sequences of length > 100 nucleotides that contained microsatellites of length > or = 14 dinucleotide or 10 trinucleotide repeats with purity equal to 100%. An additional 13 sequences contained a GC microsatellite of length > or = 12 repeats (purity = 100%) were also obtained. Primer pairs for amplification of 1,516 putative loci are presented. Amplification of genomic DNA from alpaca and llama by PCR was demonstrated for 14 primer sets including one from each of the microsatellite repeat types. Comparative chromosomal location for the alpaca markers was predicted in the bovine genome by BLAT searches against assembly 4.0 of the bovine whole genome sequence. A total of 634 markers (41.8%) returned BLAT hits with score > 100 and Identity > 85%, with the majority assignable to unique locations. We show that microsatellites are abundant and easily identified within the alpaca genome sequence. These markers will provide a valuable resource for further genetic studies of the alpaca and related species.     

Characterization of 17 polymorphic microsatellite loci in the Anise swallowtail,Papilio zelicaon (Lepidoptera: Papilionidae), and their amplification in related species

Fifteen polymorphic dinucleotide and two trinucleotide microsatellite loci were identified in the Anise swallowtail, Papilio zelicaon, from DNA genomic libraries enriched for simple sequence repeats. Allele numbers varied from eight to 29, with an excess of homozygotes observed for nine loci. This homozygosity is a feature of other lepidopteran microsatellites and is probably due to null alleles. Sixteen markers were amplified successfully in other representatives of Papilio with 11 loci retaining polymorphism in at least one species. These results suggest that the microsatellites reported here may be appropriate for measuring population genetic structure in a number of Papilio species.     

Mining functional microsatellites in legume unigenes

Highly polymorphic and transferable microsatellites (SSRs) are important for comparative genomics, genome analysis and phylogenetic studies. Development of novel species-specific microsatellite markers remains a costly and labor-intensive project. Therefore, interest has been shifted from genomic to genic markers owing to their high inter-species transferability as they are developed from conserved coding regions of the genome. This study concentrates on comparative analysis of genic microsatellites in nine important legume (Arachis hypogaea, Cajanus cajan, Cicer arietinum, Glycine max, Lotus japonicus, Medicago truncatula, Phaseolus vulgaris, Pisum sativum and Vigna unguiculata) and two model plant species (Oryza sativa and Arabidopsis thaliana). Screening of a total of 228090 putative unique sequences spanning 219610522 bp using a microsatellite search tool, MISA, identified 12.18% of the unigenes containing 36248 microsatellite motifs excluding mononucleotide repeats. Frequency of legume unigene-derived SSRs was one SSR in every 6.0 kb of analyzed sequences. The trinucleotide repeats were predominant in all the unigenes with the exception of C. cajan, which showed prevalence of dinucleotide repeats over trinucleotide repeats. Dinucleotide repeats along with trinucleotides counted for more than 90% of the total microsatellites. Among dinucleotide and trinucleotide repeats, AG and AAG motifs, respectively, were the most frequent. Microsatellite positive chickpea unigenes were assigned Gene Ontology (GO) terms to identify the possible role of unigenes in various molecular and biological functions. These unigene based microsatellite markers will prove valuable for recording allelic variance across germplasm collections, gene tagging and searching for putative candidate genes.     

Drosophila virilis has long and highly polymorphic microsatellites

Comparative genomics is a powerful approach to inference of the dynamics of genome evolution. Most information about the evolution of microsatellites in the genus Drosophila has been obtained from Drosophila melanogaster. For comparison, we collected microsatellite data for the distantly related species Drosophila virilis. Screening about 0.5 Mb of nonredundant genomic sequence from GenBank, we identified 239 dinucleotide microsatellites. On average, D. virilis dinucleotides were significantly longer than D. melanogaster microsatellites (7.69 repeats vs. 6.75 repeats). Similarly, direct cloning of microsatellites resulted in a higher mean repeat number in D. virilis than in D. melanogaster (12.7 repeats vs. 12.2 repeats). Characterization of 11 microsatellite loci mapping to division 40-49 on the fourth chromosome of D. virilis indicated that D. virilis microsatellites are more variable than those of D. melanogaster.     

Using Next Generation RAD Sequencing to Isolate Multispecies Microsatellites for Pilosocereus (Cactaceae)

Microsatellite markers (also known as SSRs, Simple Sequence Repeats) are widely used in plant science and are among the most informative molecular markers for population genetic investigations, but the development of such markers presents substantial challenges. In this report, we discuss how next generation sequencing can replace the cloning, Sanger sequencing, identification of polymorphic loci, and testing cross-amplification that were previously required to develop microsatellites. We report the development of a large set of microsatellite markers for five species of the Neotropical cactus genus Pilosocereus using a restriction-site-associated DNA sequencing (RAD-seq) on a Roche 454 platform. We identified an average of 165 microsatellites per individual, with the absolute numbers across individuals proportional to the sequence reads obtained per individual. Frequency distribution of the repeat units was similar in the five species, with shorter motifs such as di- and trinucleotide being the most abundant repeats. In addition, we provide 72 microsatellites that could be potentially amplified in the sampled species and 22 polymorphic microsatellites validated in two populations of the species Pilosocereus machrisii. Although low coverage sequencing among individuals was observed for most of the loci, which we suggest to be more related to the nature of the microsatellite markers and the possible bias inserted by the restriction enzymes than to the genome size, our work demonstrates that an NGS approach is an efficient method to isolate multispecies microsatellites even in non-model organisms.     

A set of polymorphic trinucleotide and tetranucleotide microsatellite markers for the Japanese flounder (Paralichthys olivaceus)

We have developed the first set of trinucleotide and tetranucleotide markers for the Japanese flounder, Paralichthys olivaceus. One hundred and sixty-seven polymorphic trinucleotide and tetranucleotide microsatellites were isolated using clones derived from two libraries. Of almost 200,000 clones analysed, 0.5% presented trinucleotide or tetranucleotide repeat regions. Among the trinucleotide repeats analysed in this study, the most frequent one was (CAG)(n) and the most common tetranucleotide repeat was (GATA)(n). The position of the new markers in the genetic linkage map was determined. Markers were evenly distributed along the P. olivaceus linkage groups, without distinction between the kinds of repeats and library of origin. The markers isolated in this study contribute significantly to the genetic linkage map of the Japanese flounder.     

Characterization of microsatellites and development of chromosome specific STMS markers in bread wheat

Microsatellites, or simple sequence repeats (SSRs), have become the markers of choice for genetic studies with many crop species including wheat. Currently an international effort is underway to enrich the repertoire of available sequence tagged microsatellite site (STMS) markers in wheat. As a part of this effort, we have sequenced 43 clones obtained from a microsatellite-enriched wheat genomic library; 34 clones contained 41 different microsatellites. These microsatellites (mono-, di-, tri- nucleotide repeats) were classified as 19 simple perfect, 18 simple imperfect and 4 compound imperfect types. Dinucleotide repeats were the most abundant (70%). Primer pairs for only 16 microsatellites could be designed, since the flanking sequences of the others were either too short or were otherwise not suitable for designing the microsatellite specific primers. Microsatellite loci of the expected size and polymorphism were successfully amplified from 15 of these 16 primer pairs using three wheat varieties. 14 loci detected by 12 out of the 15 functional primer pairs were assigned to 11 specific chromosomes. An erratum to this article is available at .     

Microsatellite repeats are not randomly distributed within Norway spruce (Picea abies K.) expressed sequences.

A Norway spruce (Picea abies K.) cDNA library obtained from vegetative bud tissue was screened for the presence of (AG)n and (AC)n microsatellite repeats. Ten (AG)n and six (AC)n microsatellites were found, with an average length of 25.5 repeat units. Most of the microsatellites are simple perfect repeats. The microsatellite distribution within the clones is clearly non-random, with different classes of repeats lying in different positions relative to the coding region and in a highly conserved orientation. An estimate of the frequency of dinucleotide microsatellites in expressed regions was obtained, showing that SSRs (simple sequence repeats) are found in genes about 20 times less frequently than in random genomic clones, with (AG)n repeats more frequent than (AC)n repeats. Potential applications of these sequences as expressed region-based molecular markers are shown by developing six SSR markers for the detection of natural variation in Norway spruce populations and testing two of them for the identification of illegitimate progenies from a mapping population.     

High mutation rate of a long microsatellite allele in Drosophila melanogaster provides evidence for allele-specific mutation rates

Within recent years, microsatellite have become one of the most powerful genetic markers in biology. For several mammalian species, microsatellite mutation rates have been estimated on the order of 10(- 3)-10(-5). A recent study, however, demonstrated mutation rates in Drosophila melanogaster of at least one order of magnitude lower than those in mammals. To further test this result, we examined mutation rates of different microsatellite loci using a larger sample size. We screened 24 microsatellite loci in 119 D. melanogaster lines maintained for approximately 250 generations and detected 9 microsatellite mutations. The average mutation rate of 6.3 x 10(-6) is identical to the mutation rate from a previous study. Most interestingly, all nine mutations occurred at the same allele of one locus (DROYANETSB). This hypermutable allele has 28 dinucleotide repeats and is among the longest microsatellite reported in D. melanogaster. The allele-specific mutation rate of 3.0 x 10(-4) per generation is within the range of mammalian mutation rates. Future microsatellite analyses will have to account for the dramatic differences in allele-specific mutation rates.      

Microsatellites in Zea - variability,patterns of mutations,and use for evolutionary studies

To evaluate the performance of microsatellites or simple sequence repeats (SSRs) for evolutionary studies in Zea, 46 microsatellite loci originally derived from maize were applied to diverse arrays of populations that represent all the diploid species of Zea and 101 maize inbreds. Although null phenotypes and amplification of more than two alleles per plant were observed at modest rates, no practical obstacle was encountered for applying maize microsatellites to other Zea species. Sequencing of microsatellite alleles revealed complex patterns of mutation including frequent indels in the regions flanking microsatellite repeats. In one case, all variation at a microsatellite locus came from indels in the flanking region rather than in the repeat motif. Maize microsatellites show great variability within populations and provide a reliable means to measure intraspecific variation. Phylogeographic relationships of Zea populations were successfully reconstructed with good resolution using a genetic distance based on the infinite allele model, indicating that microsatellite loci are useful in evolutionary studies in Zea. Microsatellite loci show a principal division between tropical and temperate inbred lines, and group inbreds within these two broad germplasm groups in a manner that is largely consistent with their known pedigrees. Received: 10 February 2001 / Accepted: 21 May 2001     

Quantifying ascertainment bias and species-specific length differences in human and chimpanzee microsatellites using genome sequences

Surveys of variability of homologous microsatellite loci among species reveal an ascertainment bias for microsatellite length where microsatellite loci isolated in one species tend to be longer than homologous loci in related species. Here, we take advantage of the availability of aligned human and chimpanzee genome sequences to compare length difference of homologous microsatellites for loci identified in humans to length difference for loci identified in chimpanzees. We are able to quantify ascertainment bias for a range of motifs and microsatellite lengths. Because ascertainment bias should not exist if a microsatellite selected in one species is as likely to be longer as it is to be shorter than its homologue, we propose that the nature of ascertainment bias can provide evidence for understanding how microsatellites evolve. We show that bias is greater for longer microsatellites but also that many long microsatellites have short homologues. These results are consistent with the notion that growth of long microsatellites is constrained by an upper length boundary that, when reached, sometimes results in large deletions. By evaluating ascertainment bias separately for interrupted and uninterrupted repeats we also show that long microsatellites tend to become interrupted, thereby contributing a second component of ascertainment bias. Having accounted for ascertainment bias, in agreement with results published elsewhere, we find that microsatellites in humans are longer on average than those in chimpanzees. This length difference is similar among repeat motifs but surprisingly comprises two roughly equal components, one associated with the repeats themselves and one with the flanking sequences. The differences we find can only be explained if microsatellites are both evolving directionally under a biased mutation process and are doing so at different rates in different closely related species.