Microsatellite marker identification using genome screening and restriction-ligation

We have identified a fast and easy method for finding microsatellite markers that utilizes genome screening with inter-simple sequence repeat (ISSR) primers to detect microsatellite regions and to obtain sequence information flanking one side of the microsatellites and a restriction-ligation technique with a specific adaptor to allow sequence walking to obtain sequence information flanking the other side of the microsatellites. Two main alternatives of the method (with or without cloning) are presented. We successfully utilized the method when identifying microsatellite markers for 21 bryophyte species, three algal species, and for the raccoon dog. The proportion of polymorphic markers equaled 95%. We observed that microsatellites are commonly found within the sequenced ISSR amplification products (54% in the present study), in which case specific primers can be identified for the microsatellite without a further restriction-ligation step. It is evident that the DNA regions amplified by ISSR markers commonly represent microsatellite hotspots. We propose that the identified method and the knowledge of the common presence of additional microsatellite repeats within ISSR amplification products are especially attractive to researchers who conduct small-scale microsatellite identification, such as researchers in population genetics and conservation biology.     

Characterization of new Schistosoma mansoni microsatellite loci in sequences obtained from public DNA databases and microsatellite enriched genomic libraries

In the last decade microsatellites have become one of the most useful genetic markers used in a large number of organisms due to their abundance and high level of polymorphism. Microsatellites have been used for individual identification, paternity tests, forensic studies and population genetics. Data on microsatellite abundance comes preferentially from microsatellite enriched libraries and DNA sequence databases. We have conducted a search in GenBank of more than 16,000 Schistosoma mansoni ESTs and 42,000 BAC sequences. In addition, we obtained 300 sequences from CA and AT microsatellite enriched genomic libraries. The sequences were searched for simple repeats using the RepeatMasker software. Of 16,022 ESTs, we detected 481 (3%) sequences that contained 622 microsatellites (434 perfect, 164 imperfect and 24 compounds). Of the 481 ESTs, 194 were grouped in 63 clusters containing 2 to 15 ESTs per cluster. Polymorphisms were observed in 16 clusters. The 287 remaining ESTs were orphan sequences. Of the 42,017 BAC end sequences, 1,598 (3.8%) contained microsatellites (2,335 perfect, 287 imperfect and 79 compounds). The 1,598 BAC end sequences 80 were grouped into 17 clusters containing 3 to 17 BAC end sequences per cluster. Microsatellites were present in 67 out of 300 sequences from microsatellite enriched libraries (55 perfect, 38 imperfect and 15 compounds). From all of the observed loci 55 were selected for having the longest perfect repeats and flanking regions that allowed the design of primers for PCR amplification. Additionally we describe two new polymorphic microsatellite loci.     

Molecular characterization and genetic mapping of random amplified microsatellite polymorphism in barley

 This study has analyzed the molecular basis and genetic behaviour of the polymorphism generated by the amplification of barley genomic DNA with primers complementary to microsatellites. Primers anchored at the 5′ end, used alone or in combination with arbitrary sequence primers, generated random amplified microsatellite polymorphisms (RAMPs). Unanchored primers were also used as single primers in a microsatellite primed-PCR (MP-PCR). Twenty six randomly selected RAMP DNA fragments which showed polymorphism between the cultivars Steptoe and Morex were cloned and sequenced. All sequences showed the expected repeated motif at the end of the insert, with the number of repeats ranging from five to ten. Genomic sequences containing low numbers of microsatellite motifs were preferentially amplified; therefore, only a fraction of the polymorphism could be attributed to variation in the number of microsatellite motifs at the priming site. Some sequences contained either cryptic simple sequences or members of families of repeated DNA. Polymorphism at the internal cryptic simple sequences was detected by RAMP bands inherited as co-dominant markers. Four MP-PCR bands were cloned and sequenced. A number of repeats identical to the primer itself were found at each end of the insert. Two allelic bands were polymorphic for an internal microsatellite. The potential use of cloned bands as fingerprinting tools was investigated by employing them as hybridization probes in Southern blots containing digested barley DNA from a sample of cultivars. RAMP probes produced complex hybridization band patterns. MP-PCR probes produced either a highly variable single locus or low-copy number loci. Segregations for 31 RAMPs and three MP-PCR bands were studied in a population of 70 doubled-haploids from the Steptoe/Morex cross. One third of all markers were co-dominantly inherited. Markers were positioned on an RFLP map and found to be distributed in all barley chromosomes. The new markers enlarged the overall length of the map to 1408 cM. Received: 6 May 1998 / Accepted: 20 July 1998     

High-throughput microsatellite marker development in two sparid species and verification of their transferability in the family Sparidae

Recently, 454 sequencing has emerged as a popular method for isolating microsatellites owing to cost-effectiveness and time saving. In this study, repeat-enriched libraries from two southern African endemic sparids (Pachymetopon blochii and Lithognathus lithognathus) were 454 GS-FLX sequenced. From these, 7370 sequences containing repeats (SCRs) were identified. A brief survey of 23 studies showed a significant difference between the number of SCRs when enrichment was performed first before 454 sequencing. We designed primers for 302 unique fragments containing more than five repeat units and suitable flanking regions. A fraction (<11%) of these loci were characterized with 18 polymorphic microsatellite loci (nine in each of the focal species) being described. Sanger sequencing of alleles confirmed that size variation was because of differences in the number of tandem repeats. However, a case of homoplasy and sequencing errors in the 454 sequencing were identified. These newly developed and four previously isolated loci were successfully used to identify polymorphic markers in nine other economically important species, representative of sparid diversity. The combination of newly developed markers with data from previous sparid cross-species studies showed a significant negative correlation between genetic divergence to focal species and microsatellite transferability. The high level of transferability we described (48% amplification success and 32% polymorphism) suggests that the 302 microsatellite loci identified represent an excellent resource for future studies on sparids. Microsatellite marker development should commonly include tests of transferability to reduce costs and increase feasibility of population genetics studies in nonmodel organisms.     

The bovine genome contains polymorphic microsatellites

Dinucleotide repeats constitute so-called microsatellites of the human and other eukaryotic genomes. Microsatellite polymorphisms can be identified through the amplification of the microsatellite DNA using the polymerase chain reaction (PCR), followed by resolution of the amplified DNA fragments on a polyacrylamide sequencing gel. We performed a preliminary sequence database search to identify bovine sequences containing (CA)n, (AC)n, (GT)n, or (TG)n blocks, with n greater than or equal to 6. This search yielded 10 sequences containing one or two of the specified repeat blocks and often additional dinucleotide repeat blocks. One of the microsatellite-containing regions has been sequenced twice from independent clones and the reported sequences showed variation in the number of repeats. PCR-amplified fragments of another sequence, the gene for steroid 21-hydroxylase, ranged from 186 to 216 nucleotides in 43 unrelated animals. The database search, as well as the hypervariable microsatellite in the bovine steroid 21-hydroxylase gene, indicates that dinucleotide blocks may be an abundant source of DNA polymorphism in cattle.     

WebSat ‐ A web software for microsatellite marker development

Simple sequence repeats (SSR), also known as microsatellites, have been extensively used as molecular markers due to their abundance and high degree of polymorphism. We have developed a simple to use web software, called WebSat, for microsatellite molecular marker prediction and development. WebSat is accessible through the Internet, requiring no program installation. Although a web solution, it makes use of Ajax techniques, providing a rich, responsive user interface. WebSat allows the submission of sequences, visualization of microsatellites and the design of primers suitable for their amplification. The program allows full control of parameters and the easy export of the resulting data, thus facilitating the development of microsatellite markers.     

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 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 .     

Isolation and Enrichment of Abundant Microsatellites from a Channel Catfish (Ictalurus punctatus) Brain cDNA Library

Efforts to construct a genetic linkage map of channel catfish have involved identification of random genomic microsatellite markers, as well as anchored Type I loci (expressed genes) from channel catfish. To identify Type I markers we constructed a directional cDNA library from brain tissue to obtain expressed catfish sequences that could be used for single nucleotide polymorphism (SNP) marker development. These cDNA sequences surprisingly contained a high proportion of microsatellites (about 14%) in noncoding regions of expressed sequence tags (ESTs), many of which were not associated with known sequences. To further identify cDNAs with microsatellites and reduce the number of sequencing reactions needed for marker development, we enriched this library for repeat sequences and sequenced clones from both directions. A total of 1644 clones from seven repeat-enriched captures (CA, GT, CT, GA, MTT, TAG, and TAC) were sequenced from both ends, and 795 nonredundant clones were assembled. Thirty-seven percent of the clones contained microsatellites in the trimmed sequence. After assembly in the TIGR Catfish Gene Index (CfGI), 154 contigs matched known vertebrate genes and 92 contigs contained microsatellites. When BLAST-matched orthologues were available for similarity alignments, 28% of these contigs contained repeats in the 5'-UTR, 72% contained repeats in the 3'-UTR, and 8% contained repeats at both ends. Using biotinylated repeat oligonucleotides coupled with streptavidin-coated magnetic beads, and rapid, single-pass hybridization, we were able to enrich our plasmid library greater than two-fold for repeat sequences and increase the ability to link these ESTs with known sequences greater than six-fold.     

Isolation and enrichment of abundant microsatellites from a channel catfish (Ictalurus punctatus) brain cDNA library

Efforts to construct a genetic linkage map of channel catfish have involved identification of random genomic microsatellite markers, as well as anchored Type I loci (expressed genes) from channel catfish. To identify Type I markers we constructed a directional cDNA library from brain tissue to obtain expressed catfish sequences that could be used for single nucleotide polymorphism (SNP) marker development. These cDNA sequences surprisingly contained a high proportion of microsatellites (about 14%) in noncoding regions of expressed sequence tags (ESTs), many of which were not associated with known sequences. To further identify cDNAs with microsatellites and reduce the number of sequencing reactions needed for marker development, we enriched this library for repeat sequences and sequenced clones from both directions. A total of 1644 clones from seven repeat-enriched captures (CA, GT, CT, GA, MTT, TAG, and TAC) were sequenced from both ends, and 795 nonredundant clones were assembled. Thirty-seven percent of the clones contained microsatellites in the trimmed sequence. After assembly in the TIGR Catfish Gene Index (CfGI), 154 contigs matched known vertebrate genes and 92 contigs contained microsatellites. When BLAST-matched orthologues were available for similarity alignments, 28% of these contigs contained repeats in the 5'-UTR, 72% contained repeats in the 3'-UTR, and 8% contained repeats at both ends. Using biotinylated repeat oligonucleotides coupled with streptavidin-coated magnetic beads, and rapid; single-pass hybridization, we were able to enrich our plasmid library greater than two-fold for repeat sequences and increase the ability to link these ESTs with known sequences greater than six-fold.     

GenBank数据库中鳜鱼微卫星位点的筛选及特征分析

微卫星(Microsatellite)是一类由2-6个核苷酸经多次单位串联组成的高度变异重复DNA序列(Schlotterer and Tautz,1992)。它具有按照孟德尔方式分离、突变快、多态信息含量丰富、呈共显性遗传等特点,其核心序列在同一物种中具有保守性,因此,可以根据微卫星的侧翼序列设计合适的引     

Isolation and characterization of dinucleotide repeat microsatellites in Drosophila ananassae

Drosophila ananassae is a cosmopolitan species with a geographic range throughout most of the tropical and subtropical regions of the world. Previous studies of DNA sequence polymorphism in three genes has shown evidence of selection affecting broad expanses of the genome in regions with low rates of recombination in geographically local populations in and around India. The studies suggest that extensive physical and genetic maps based on molecular markers, and detailed studies of population structure may provide insight into the degree to which natural selection affects DNA sequence polymorphism across broad regions of chromosomes. We have isolated 85 dinucleotide repeat microsatellite sequences and developed assay conditions for genotyping using PCR. The dinucleotide repeats we isolated are shorter, on average, than those isolated in many other Drosophila species. Levels of genetic variation are high, comparable to Drosophila melanogaster. The levels of variation indicate the effective population size of an Indonesian population of D. ananassae is 58,692 (infinite allele model) and 217,284 (stepwise mutation model), similar to estimates of effective population size for D. melanogaster calculated using dinucleotide repeat microsatellites. The data also show that the Indonesian population is in a rapid expansion phase. Cross-species amplification of the microsatellites in 11 species from the Ananassae, Elegans, Eugracilis and Ficusphila subgroups indicates that the loci may be useful for studies of the sister species, D. pallidosa, but will have limited use for more distantly related species.     

Conservation and evolution of microsatellite loci in primate taxa

Microsatellites are promising genetic markers for the study of demographic structure and phylogenetic history in populations. However, little information exists on the molecular nature of the repeats and their flanking sequences of a same microsatellite in a large range of species. In this study, we report polymorphism and consensus sequences of eight microsatellite loci using human primers in 20 primate species. The results show size polymorphism in almost all species and microsatellites. These loci are therefore useful markers for population genetic studies between populations of the same species. Insertion/deletion events are frequent in the flanking regions, the majority concerning several contiguous bases. This is in contrast with the more usual single base pair events in non-coding regions. The ranges of allele lengths in non-human primates often show no overlap with that of human, usually due to the deletion/insertion events in the flanking sequences, producing smaller allele lengths rather than smaller numbers of repeats. The use of length of PCR product will bias the inter-species interpretation reducing the number of observable alleles and treating as the same allele very divergent molecular sequences. Caution should be used when employing microsatellites in cross-species comparisons in which the species under study are separated by significant amounts of evolutionary time: in such cases allele comparison cannot be based on lengths alone.     

High degree of transferability of 86 newly developed zebra finch EST-linked microsatellite markers in 8 bird species

High-resolution analysis for population genetic and functional studies requires the use of large numbers of polymorphic markers. The recent increase of available genetic tools is facilitated by the use of publicly available expressed sequence tag (EST) sequence databases that are a valuable resource for identifying gene-linked markers. In the present study, we applied bioinformatics analyses to identify microsatellite markers present in EST sequences from a zebra finch (Taeniopgia guttata) EST database and we explore the success of cross-species amplification of EST-linked microsatellite markers in 7 passerine and 1 nonpasserine species. Eighty-six zebra finch EST-linked microsatellite loci were screened for polymorphism revealing a high amplification success rate and adequate levels of polymorphism (33.3-51%) for relatively closely related species, whereas success decreased in the most distantly related species to zebra finch. EST-linked microsatellites appear to be more highly transferable between taxa than anonymous microsatellites as they revealed higher amplification and polymorphism success between different families indicating that they will be a useful source of gene-linked polymorphic markers in a broad range of avian species.     

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.     

Highly informative nature of inter simple sequence repeat (ISSR) sequences amplified using tri- and tetra-nucleotide primers from DNA of cauliflower (Brassica oleracea var. botrytis L.).

Inter simple sequence repeat (ISSR) sequences as molecular markers can lead to the detection of polymorphism and also be a new approach to the study of SSR distribution and frequency. In this study, ISSR amplification with nonanchored primer was performed in closely related cauliflower lines. Fourty-four different amplified fragments were sequenced. Sequences of PCR products are delimited by the expected motifs and number of repeats, which validates the ISSR nonanchored primer amplification technique. DNA and amino acids homology search between internal sequences and databases (i) show that the majority of the internal regions of ISSR had homologies with known sequences, mainly with genes coding for proteins implicated in DNA interaction or gene expression, which reflected the significance of amplified ISSR sequences and (ii) display long and numerous homologies with the Arabidopsis thaliana genome. ISSR amplifications revealed a high conservation of these sequences between Arabidopsis thaliana and Brassica oleracea var. botrytis. Thirty-four of the 44 ISSRs had one or several perfect or imperfect internal microsatellites. Such distribution indicates the presence in genomes of highly concentrated regions of SSR, or "SSR hot spots." Among the four nonanchored primers used in this study, trinucleotide repeats, and especially (CAA)5, were the most powerful primers for ISSR amplifications regarding the number of amplified bands, level of polymorphism, and their nature.     

Development,characterization and utilization of GenBank microsatellite markers in <Emphasis Type="Italic">Phyllostachys pubescens</Emphasis> and related species

Public sequence databases provide a rapid, simple and cost-effective source of microsatellite markers. We analyzed 1,532 bamboo (Phyllostachys pubescens) sequences available in public domain DNA databases, and found 3,241 simple sequence repeat (SSR) loci comprising repeats of two or more nucleotides in 920 genomic survey sequences (GSSs) and 68 cDNA sequences. This corresponded to one SSR per 336 bp of GSS DNA and one SSR per 363 bp of cDNA. The SSRs consisted of 76.6 and 74.5% dinucleotide repeats, 20.0 and 22.3% trinucleotide repeats, and 3.4 and 3.2% higher-number repeats in the GSS DNA and cDNA sequences, respectively. The repeat motif AG/CT (or GA/TC) was the most abundant. Nineteen microsatellite markers were developed from Class I and Class II SSRs, showing that the limited polymorphism in Ph. pubescens cultivars and provenances could be attributed to clonal propagation of the bamboo plant. The transferability of the microsatellites reached 75.3%, and the polymorphism of loci successfully transferred was 66.7% for six additional Phyllostachys species. Microsatellite PBM014 transferred successfully to all six species, showed rich polymorphism, and could serve as species-specific alleles for the identification of Phyllostachys interspecies hybrids.     

Low-copy microsatellite markers for Pinus taeda L.

Eighteen low-copy and genomic microsatellite markers were tested for Mendelian inheritance and then assayed in 41 Pinus taeda L. samples drawn from five regions in the southern United States. The PCR products had multiple alleles, high levels of polymorphism, and little non-specific priming. Fifteen of the 18 markers were informative for a P. taeda three-generation RFLP (restriction fragment length polymorphism) pedigree, and a P. taeda population survey revealed three to 28 alleles per locus. The highest allele numbers and polymorphic information content (PIC) values were associated with complex repeat sequences and (or) with sequences consisting of the longer strings of perfect repeats. The abundance of low- to rare-frequency alleles also accounted for high PIC values in both types of markers. Low-copy microsatellites are useful for the large, complex pine genome, especially in the absence of entire gene sequences in public databases and with the low levels of polymorphism in markers developed from expressed sequence tags (ESTs).     

Polymorphism,monomorphism, and sequences in conserved microsatellites in primate species

Dimeric short tandem repeats are a source of highly polymorphic markers in the mammalian genome. Genetic variation at these hypervariable loci is extensively used for linkage analysis, for the identification of individuals, and may be useful for interpopulation and interspecies studies. In this paper, we analyze the variability and the sequences of a segment including three microsatellites, first described in man, in several species of primates (chimpanzee, orangutan, gibbon, and macaque) using the heterologous primers (man primers). This region is located on the human chromosome 6p, near the tumor necrosis factor genes, in the major histocompatibility complex. The fact that these primers work in all species studied indicates that they are conserved throughout the different lineages of the two superfamilies, the Hominoidea and the Cercopithecidea, represented by the macaques. However, the intervening sequence displays intraspecific and interspecific variability. The sites of base substitutions and the insertion/ deletion events are not evenly distributed within this region. The data suggest that it is necessary to have a minimal number of repeats to increase the rate of mutation sufficiently to allow the development of polymorphism. In some species, the microsatellites present single base variations which reduce the number of contiguous repeats, thus apparently slowing the rate of additional slippage events. Species with such variations or a low number of repeats are monomorphic. These microsatellite sequences are informative in the comparison of closely related species and reflect the phylogeny of the Old World monkeys, apes, and man.Correspondence to: B. Crouau-Roy     

Characterization of (GT)n and (CT)n microsatellites in two insect species: Apis mellifera and Bombus terrestris.

A set of 52 (CT)n and 23 (GT)n microsatellites in honeybee, 24 (CT)n and 2 (GT)n microsatellites in bumble-bee (n > 6) have been isolated from partial genomic libraries and sequenced. On average, (CT)n and (GT)n microsatellites occur every 15 kb and 34 kb in honeybee and every 40 kb and 500 kb in bumble-bee, respectively. The prevailing categories are imperfect repeats for (CT)n microsatellites in bumble-bee, and perfect repeats for both (CT)n and (GT)n microsatellites in honey-bee. Comparisons with data available in vertebrates indicate a lower proportion of perfect repeats in bees but length distributions are very similar regardless the phylum. This result extends to insects the concept of an evolutionary conservation for quantitative and qualitative characteristics of (CT)n and (GT)n microsatellites. Many (CT)n and (GT)n repeats are surrounded with various types of microsatellites, revealing an associative distribution of short repeat sequences. As expected, a high level of intrapopulational polymorphism has been found with one tested honeybee microsatellite. Also, flanking regions of this microsatellite are similar enough to allow PCR amplification in several other species of Apis and Bombus.