Isolation of microsatellite loci in the pollinating fig wasp of Ficus hispida, Ceratosolen solmsi

Microsatellite loci were isolated for Ceratosolen solmsi , pollinator of the dioecious Ficus hispida. We developed nine polymorphic microsatellite loci based on the method of polymerase chain reaction isolation of microsatellite arrays (PIMA). Enrichment of genomic libraries was performed by random amplified polymorphic DNA (RAPD). A subset of 38 positive clones was sequenced; 15 clones showed microsatellite loci. We tested 15 designed primer pairs and nine of them produced polymorphic amplification in 48 individual wasps collected from different fruits of the dioecious host fig Ficus hispida in China. Among the 48 individuals, 49 alleles were obtained at the nine loci. The observed heterozygosity ranged between 0.357 and 0.634.     

磁珠富集法筛选实验豚鼠微卫星分子标记

目的直接从实验豚鼠基因组DNA中筛选获得微卫星分子标记。方法应用磁珠和生物素标记的微卫星探针与豚鼠基因组酶切片段杂交,捕获200～1000 bp含有微卫星序列的DNA片段,连接到pMD-18V载体中,转化到感受态细胞E.coli DH5α中构建富集微卫星序列的小片段插入文库。然后用PCR法进行筛选。结果从约2000个转化子中获得240个阳性克隆。对其中98个进行了测序,并成功设计豚鼠微卫星引物17对。结论经过优化的磁珠富集法能够稳定、高效地获得豚鼠微卫星标记。本研究获得的微卫星位点将成为豚鼠遗传学研究的有力工具。     

Vectorette PCR isolation of microsatellite repeat sequences using anchored dinucleotide repeat primers.

We have developed a vectorette PCR approach to provide an improved method for isolation of microsatellite repeats. The modified procedure relies on PCR amplification using a vectorette-specific primer in combination with one of a panel of anchored dinucleotide repeat primers. The target DNA to be screened for microsatellite sequences can be from YAC, P1, cosmid, bacteriophage or plasmid clones. We have used this technique to isolate novel, polymorphic microsatellite repeats from clones containing the amelogenin gene (AMGX) located on human chromosome Xp22.3.     

Development and characterization of microsatellite markers in a clonal plant,Dioscorea japonica Thunb.

We developed 10 microsatellite loci from genomic DNA of a dioecious clonal plant, Dioscorea japonica. Out of 384 clones, 148 contained microsatellite repeats. Polymerase chain reaction primer pairs were designed for 95 of these clones from their sequence data, of which, 10 pairs produced successful amplification. Thirty‐eight individuals were genotyped for allelic diversity. We detected three to nine alleles per locus, and the expected heterozygosity ranged from 0.461 to 0.851.     

Use of SSCP to improve the efficiency of microsatellite identification from microsatellite‐enriched libraries

An inefficient aspect of marker identification from microsatellite‐enriched libraries is the proportion of clones with identical sequences. This can substantially increase the number of clones that need to be sequenced in order to identify a sufficient number of microsatellite loci. We propose the use of single‐stranded conformation polymorphism (SSCP) analysis to identify unique clones prior to sequencing. We used this approach prior to sequencing from microsatellite‐enriched libraries for three marine invertebrate species and were able to obtain a given number of unique clone sequences for only 28% of the sequencing effort that would have been required without SSCP screening.     

Application of restriction fragment fingerprinting with a rice microsatellite sequence to assembling rice YAC clones.

To refine the current physical map of rice, we have established a restriction fragment fingerprinting method for identifying overlap between pairs of rice yeast artificial chromosome (YAC) clones and defining the physical arrangement of YACs within contiguous fragments (contigs). In this method, Southern blots of rice YAC DNAs digested with a restriction endonuclease are probed with a rice microsatellite probe, (GGC)5. The probe produces a unique fingerprint profile characteristic of each YAC clone. The profile is then digitized, processed in a computer, and a statistic that represents the degree of overlap between two YACs is calculated. The statistics have been used to detect overlaps among YAC clones, thereby filling a gap between two neighbouring contigs and organizing overlapping rice YAC clones into contiguous fragments. We applied this method to rearranging YACs that had previously been assigned to rice chromosome 6 by anchoring with RFLP markers.     

Development and characterization of simple sequence repeat DNA markers for Zelkova serrata

We developed 14 microsatellite loci from an enriched genomic DNA library of a broad‐leaved deciduous tree, Zelkova serrata. Of 198 clones from the library, 112 contained microsatellite repeat regions. The M13‐tailed primer method was used for economy. Sequence‐specific primer pairs were designed for 58 of 76 candidate clones. Fourteen of these primer pairs successfully amplified polymorphic single loci among 34 individuals collected from the Kanto breeding region in Japan. The expected heterozygosity for the 14 microsatellite markers ranged from 0.378 to 0.876, suggesting that these will prove valuable for breeding and ecological studies on Z. serrata.     

Microsatellites in the silkworm, Bombyx mori: abundance, polymorphism, and strain characterization.

We have isolated and characterized microsatellites (simple sequence repeat (SSR) loci) from the silkworm genome. The screening of a partial genomic library by the conventional hybridization method led to the isolation of 28 microsatellites harbouring clones. The abundance of (CA)n repeats in the silkworm genome was akin to those reported in the other organisms such as honey bee, pig, and human, but the (CT)n repeat motif is less common compared to bumble bee and honey bee genomes. Detailed analysis of 13 diverse silkworm strains with a representative of 15 microsatellite loci revealed a number of alleles ranging from 3 to 17 with heterozygosity values of 0.66-0.90. Along with strain-specific microsatellite markers, diapause and non-diapause strain-specific alleles were also identified. The repeat length did not show any relationship with the degree of polymorphism in the present study. The co-dominant inheritance of microsatellite markers was demonstrated in F1 offspring. A list of primer sequences that tag each locus is provided. The availability of microsatellite markers can be expected to enhance the power and resolution of genome analysis in silkworm.     

Development of 50 gene-associated microsatellite markers using BAC clones and the construction of a linkage map of swine chromosome 4

The development of informative polymorphic markers is essential for QTL mapping. We developed 50 microsatellite markers from BAC clones containing genes that were predicted to map swine chromosome 4 (SSC4) according to comparative analysis between human and swine chromosomes, and constructed a linkage map that consisted of 37 markers including 24 markers closely linked to genes in BAC clones. Microsatellite markers were developed by direct-sequencing of BAC clones and our results demonstrated that this method was effective for developing microsatellite markers in specific regions on chromosomes. Effective development of microsatellite markers closely linked to genes can further accelerate the comparative studies of chromosomes between different species.     

东方田鼠部分BAC文库的微卫星筛选

目的 从东方田鼠的部分BAC文库中筛选微卫星.方法 应用非放射性的菌落杂交方法和磁珠富集法从东方田鼠的BAC文库中筛选高质量的微卫星标记.结果 以地高辛标记的寡聚核苷酸(CA)20为探针,通过菌落杂交法从136个东方田鼠BAC克隆中筛选出杂交信号最强的20个阳性克隆.再将这20个阳性克隆分别通过链霉亲和素磁珠法构建亚克隆文库,从中选取400个经PCR鉴定为阳性的亚克隆进一步测序分析,共得到220个微卫星序列,阳性率55％.选取重复次数高,侧翼序列完整的微卫星序列设计74对引物,共有35对引物能扩增出清晰的条带,其中16对引物具有多态性.结论 成功且高效地从阳性BAC克隆中筛选出微卫星序列,这些微卫星和阳性BAC克隆可用于后续的定位研究.     

珍稀濒危树种毛红椿微卫星DNA分离及SSR反应体系优化

本研究以江西宜丰种源毛红椿为材料,成功提取其基因组DNA。利用改良的链亲和素磁珠法亲和捕捉出毛红椿基因组微卫星DNA片断,并构建了富含微卫星的基因组文库。从构建的基因组文库中随机挑选了63个单克隆进行测序,其中50个单克隆成功测序,含有微卫星的单克隆有18个,并根据测序结果设计并合成SSR引物18对。利用所合成的引物优化SSR反应体系,对影响SSR反应的各个因子进行了探讨。确定了模板DNA浓度最适浓度为30ng;dNTP的最适浓度为0.3mmol·L-1;0.3μmol·L-1是引物在反应体系中的最合适浓度。建立了重复性好、稳定性好的SSR反应体系,为下一步进行毛红椿群体遗传结构和遗传变异研究提供了技术支持。     

Construction of a BAC library and its application to the identification of simple sequence repeats in peach [ Prunus persica (L.) Batsch

The Rosaceae contains many economically important crop species, but their genomes are not well characterized, and comparative genetic mapping lags well behind that of other families. To facilitate genome comparisons and gene discovery in the Rosaceae, we have begun the development of genomic resources for peach as the model genome for this family. First, we developed a simplified, cost-effective method for constructing BAC libraries, particularly appropriate for plant species of relatively minor economic importance. Second, we used the library to investigate the abundance and local distribution of simple sequence repeats (SSRs) in peach. Our results indicate that microsatellite loci are locally much more highly abundant than previously estimated, and BAC sequencing results suggest that microsatellite repeats are not randomly distributed within gene-containing regions of the peach genome. This makes it relatively easy to identify SSRs in peach by hybridization to BAC clones, and even by random sequencing of BAC clones, not known a priori to contain SSRs.     

Microsatellite DNA fingerprinting, differentiation, and genetic relationships of clones, cultivars, and varieties of six poplar species from three sections of the genus Populus.

Accurate identification of Populus clones and cultivars is essential for effective selection, breeding, and genetic resource management programs. The unit of cultivation and breeding in poplars is a clone, and individual cultivars are normally represented by a single clone. Microsatellite DNA markers of 10 simple sequence repeat loci were used for genetic fingerprinting and differentiation of 96 clones/cultivars and varieties belonging to six Populus species (P. deltoides, P. nigra, P. balsamifera, P. trichocarpa, P. grandidentata, and P maximowiczii) from three sections of the genus. All 96 clones/cultivars could be uniquely fingerprinted based on their single- or multilocus microsatellite genotypes. The five P. grandidentata clones could be differentiated based on their single-locus genotypes, while six clones of P. trichocarpa and 11 clones of P. maximowiczii could be identified by their two-locus genotypes. Twenty clones of P. deltoides and 25 clones of P. nigra could be differentiated by their multilocus genotypes employing three loci, and 29 clones of P. balsamifera required the use of multilocus genotypes at five loci for their genetic fingerprinting and differentiation. The loci PTR3, PTR5, and PTR7 were found to be the most informative for genetic fingerprinting and differentiation of the clones. The mean number of alleles per locus ranged from 2.9 in P. trichocarpa or P. grandidentata to 6.0 in P. balsamifera and 11.2 in 96 clones of the six species. The mean number of observed genotypes per locus ranged from 2.4 in P. grandidentata to 7.4 in P. balsamifera and 19.6 in 96 clones of the six species. The mean number of unique genotypes per locus ranged from 1.3 in P. grandidentata to 3.9 in P. deltoides and 8.8 in 96 clones of the six species. The power of discrimination of the microsatellite DNA markers in the 96 clones ranged from 0.726 for PTR4 to 0.939 for PTR7, with a mean of 0.832 over the 10 simple sequence repeat loci. Clones/cultivars from the same species showed higher microsatellite DNA similarities than the clones from the different species. A UPGMA cluster plot constructed from the microsatellite genotypic similarities separated the 96 clones into six major groups corresponding to their species. Populus nigra var. italica clones were genetically differentiated from the P. nigra var. nigra clones. Microsatellite DNA markers could be useful in genetic fingerprinting, identification, classification, certification, and registration of clones, clultivars, and varieties as well as genetic resource management and protection of plant breeders' rights in Populus.     

Joint inference of microsatellite mutation models, population history and genealogies using transdimensional Markov Chain Monte Carlo

We provide a framework for Bayesian coalescent inference from microsatellite data that enables inference of population history parameters averaged over microsatellite mutation models. To achieve this we first implemented a rich family of microsatellite mutation models and related components in the software package BEAST. BEAST is a powerful tool that performs Bayesian MCMC analysis on molecular data to make coalescent and evolutionary inferences. Our implementation permits the application of existing nonparametric methods to microsatellite data. The implemented microsatellite models are based on the replication slippage mechanism and focus on three properties of microsatellite mutation: length dependency of mutation rate, mutational bias toward expansion or contraction, and number of repeat units changed in a single mutation event. We develop a new model that facilitates microsatellite model averaging and Bayesian model selection by transdimensional MCMC. With Bayesian model averaging, the posterior distributions of population history parameters are integrated across a set of microsatellite models and thus account for model uncertainty. Simulated data are used to evaluate our method in terms of accuracy and precision of estimation and also identification of the true mutation model. Finally we apply our method to a red colobus monkey data set as an example.     

Targeted, haplotype-resolved resequencing of long segments of the human genome

Currently, challenges exist to acquire long-range (hundreds of kilobase pairs) phase-discriminated sequence across substantial numbers of individuals. We have developed a straightforward method for isolating and characterizing specific genomic regions in a haplospecific manner. Real-time PCR is carried out to STS content map and genotype pools of fosmid clones arrayed in 384-well microtiter plates. Single-nucleotide polymorphisms, microsatellite markers, and insertion-deletion polymorphisms are used to differentiate the target region into haplotype-specific tiling paths. DNA of clones from these tiling paths is retrieved from the library and either sequenced by standard shotgun methods or amplified in vitro and sequenced by a primer-based, directed method. This approach provides convenient access to complete, haplotype-resolved resequencing data from multiple individuals across tens to hundreds of thousands of basepairs. We illustrate its implementation with a detailed example of more than 400 kbp from the human CFTR region, across 15 individuals, and summarize our experience applying it to many other human loci.     

Discovery of four natural clones in a crayfish species Procambarus clarkii

Self-cloning is quite rare in shrimp, lobsters, crayfish and crabs. Here we report the discovery of four natural clones of red swamp crayfish (Procambarus clarkii), each containing 2-6 genetically identical individuals, during the genotyping of 120 individuals with five microsatellites. The four clones were heterozygote at most of the five microsatellite loci. Phylogenetic analysis using microsatellite genotypes suggests recent origin of the four clones. Sequencing a part of the mitochondrial gene Cox I confirmed that the four clones were from the species Procambarus clarkii.     

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.     

Evidence for a monophyletic origin of triploid clones of the Amazon molly, Poecilia formosa

Asexual reproduction in vertebrates is rare and generally considered an evolutionary dead end. Asexuality is often associated with polyploidy, and several hypotheses have been put forward to explain this relationship. So far, it remains unclear whether polyploidization in asexual organisms is a frequent or a rare event. Here we present a field study on the gynogenetic Amazon molly, Poecilia formosa. We used multilocus fingerprints and microsatellites to investigate the genetic diversity in 339 diploid and 55 triploid individuals and in 25 P. mexicana, its sexual host. Although multilocus DNA fingerprints found high clonal diversity in triploids, microsatellites revealed only two very similar clones in the triploids. Phylogenetic analysis of microsatellite data provided evidence for a monophyletic origin of the triploid clones of P. formosa. In addition, shared alleles within the triploid clones between the triploid and diploid genotypes and between asexual and sexual lineages indicate a recent origin of triploid clones in Poecilia formosa.     

Three-gene identity coefficients demonstrate that clonal reproduction promotes inbreeding and spatial relatedness in yellow-cedar, Callitropsis nootkatensis

Asexual reproduction has the potential to promote population structuring through matings between clones as well as through limited dispersal of related progeny. Here we present an application of three-gene identity coefficients that tests whether clonal reproduction promotes inbreeding and spatial relatedness within populations. With this method, the first two genes are sampled to estimate pairwise relatedness or inbreeding, whereas the third gene is sampled from either a clone or a sexually derived individual. If three-gene coefficients are significantly greater for clones than nonclones, then clonality contributes excessively to genetic structure. First, we describe an estimator of three-gene identity and briefly evaluate its properties. We then use this estimator to test the effect of clonality on the genetic structure within populations of yellow-cedar (Callitropsis nootkatensis) using a molecular marker survey. Five microsatellite loci were genotyped for 485 trees sampled from nine populations. Our three-gene analyses show that clonal ramets promote inbreeding and spatial structure in most populations. Among-population correlations between clonal extent and genetic structure generally support these trends, yet with less statistical significance. Clones appear to contribute to genetic structure through the limited dispersal of offspring from replicated ramets of the same clonal genet, whereas this structure is likely maintained by mating among these relatives.