Development of microsatellite markers in Fosterella rusbyi (Bromeliaceae) using 454 pyrosequencing

? Premise of the study: Polymorphic microsatellite markers were developed for Fosterella rusbyi (Bromeliaceae) to evaluate the population genetic structure and genetic diversity of natural populations of F. rusbyi and other Fosterella species in Bolivia. ? Methods and Results: 454 pyrosequencing technology was used to generate 73027 sequence reads from F. rusbyi DNA, which together contained 2796 perfect simple sequence repeats (SSRs). Primer pairs were designed for 30 loci, of which 15 were used to genotype 30 F. rusbyi plants from two geographical areas in Bolivia. All markers were polymorphic, with two to nine alleles in the overall sample. Cross-species amplification was tested in 10 additional Fosterella species. Seven loci showed consistent amplification in six or more species. ? Conclusions: The 15 SSR markers developed for F. rusbyi are promising candidates for population genetic analyses within F. rusbyi and other species of Fosterella.     

Rapid microsatellite marker development in the endangered neotropical freshwater turtle Podocnemis lewyana (Testudines: Podocnemididae) using 454 sequencing

Using high throughput sequencing we obtained a large number of microsatellites from Podocnemis lewyana, an endemic turtle from northwestern South America. We used 454 Genome Sequence FLX platform of sheared genomic DNA from randomly sampling approximately 17% of the haploid genome. We identified 86,501 reads (8.1% of all reads) that contained our definition of microsatellite loci. AC and TC were the most abundant motifs in the P. lewyana genome. TGC and AAAC were most abundant tri and tetra-nucleotide motifs respectively. 72.7% of microsatellite reads had flanking sequence regions suitable for primer design and PCR amplification. We validated the identified potentially amplifiable loci (PAL) and tested for polymorphism by selecting 15 loci corresponding to tetranucleotides. Twelve loci showed polymorphism in eight individuals. These findings demonstrates that microsatellite detection using next-generation sequencing is an efficient way of getting a lot of loci for listed taxa and in turn will have a large impact on future genetic studies aiming to understand and implement conservation plans for this highly threatened freshwater turtle.     

Development of polymorphic microsatellite markers in Camellia chekiangoleosa (Theaceae) using 454-ESTs

? Premise of the study: A set of microsatellite markers for Camellia chekiangoleosa was developed and characterized using 454 sequencing technology to study the population genetic structure and the diversity of germplasm collections. ? Methods and Results: Eighteen polymorphic microsatellite markers were identified and tested in 150 individuals from three natural populations of C. chekiangoleosa. Alleles numbered from two to seven, and the observed and expected heterozygosities ranged from 0.100 to 0.760 and 0.133 to 0.809, respectively. ? Conclusions: These markers will potentially be conducive to further genetic studies on C. chekiangoleosa.     

Development and cross-species/genera transferability of microsatellite markers discovered using 454 genome sequencing in chokecherry (Prunus virginiana L.)

Chokecherry (Prunus virginiana L.) (2n?=?4x?=?32) is a unique Prunus species for both genetics and disease-resistance research due to its tetraploid nature and X-disease resistance. However, no genetic and genomic information on chokecherry is available. A partial chokecherry genome was sequenced using Roche 454 sequencing technology. A total of 145,094 reads covering 4.8?Mbp of the chokecherry genome were generated and 15,113 contigs were assembled, of which 11,675 contigs were larger than 100?bp in size. A total of 481 SSR loci were identified from 234 (out of 11,675) contigs and 246 polymerase chain reaction (PCR) primer pairs were designed. Of 246 primers, 212 (86.2?%) effectively produced amplification from the genomic DNA of chokecherry. All 212 amplifiable chokecherry primers were used to amplify genomic DNA from 11 other rosaceous species (sour cherry, sweet cherry, black cherry, peach, apricot, plum, apple, crabapple, pear, juneberry, and raspberry). Thus, chokecherry SSR primers can be transferable across Prunus species and other rosaceous species. An average of 63.2 and 58.7?% of amplifiable chokecherry primers amplified DNA from cherry and other Prunus species, respectively, while 47.2?% of amplifiable chokecherry primers amplified DNA from other rosaceous species. Using random genome sequence data generated from next-generation sequencing technology to identify microsatellite loci appears to be rapid and cost-efficient, particularly for species with no sequence information available. Sequence information and confirmed transferability of the identified chokecherry SSRs among species will be valuable for genetic research in Prunus and other rosaceous species. Key message A total of 246 SSR primers were identified from chokecherry genome sequences. Of which, 212 were confirmed amplifiable both in chokecherry and other 11 other rosaceous species.     

种间转移扩增法筛选长爪沙鼠微卫星位点

目的筛选长爪沙鼠新的微卫星位点,为长爪沙鼠遗传分析提供遗传标记物。方法从GenBank中随机选取小鼠微卫星位点引物536对,用这些引物对长爪沙鼠基因组DNA扩增,将阳性目的条带进行序列分析,找出符合微卫星序列特征的短串联重复序列。结果 536对小鼠微卫星引物在长爪沙鼠基因组中扩增出了313个阳性条带,经序列分析,确定130个长爪沙鼠微卫星位点;其中完美型位点占80.77%(105/130),不完美型位点占19.23%(25/130),与小鼠同源性为24.3%(130/536)。将筛选出的微卫星位点在GenBank中注册,注册号从GU562694到GU562823。结论小鼠和沙鼠的微卫星位点具有较高的同源性,用小鼠的微卫星位点引物直接扩增长爪沙鼠基因组DNA可有效地筛选出长爪沙鼠微卫星位点。     

Development and characterization of microsatellite markers for Vriesea simplex (Bromeliaceae) and cross-amplification in other species of Bromeliaceae

Ten polymorphic microsatellite loci were isolated and characterized for Vriesea simplex epiphytic and endemic species from the Brazilian Atlantic Rainforest. The number of alleles per locus ranged from 2 to 16. The observed and expected heterozygosity ranged from 0.000 to 0.414 and 0.068 to 0.795, respectively. All loci departed significantly from Hardy–Weinberg equilibrium. Linkage disequilibrium was not detected in any pair of loci. Transferability of 10 loci was positive across ten other Bromeliaceae species. The loci will be used for studying population genetic structure, mating system variation, and the origin and maintenance of reproductive barriers to gene exchange among sympatric Vriesea species.     

Isolation and characterization of microsatellite loci for the Potentilla core group (Rosaceae) using 454 sequencing

Microsatellites are valuable markers for the analysis of genetic diversity, linkage mapping or genotyping. The limited availability of microsatellites for the genus Potentilla (Rosaceae) stipulated the isolation of markers from a representative (Potentilla pusilla Host) of the Potentilla core group that constitutes the most species‐rich evolutionary lineage within the genus. Thousand four hundred and seventy‐six simple sequence repeat (SSR) containing candidate sequences were isolated from a single‐type line using 454 sequencing. Seventy‐four functional microsatellite markers were developed from 200 sequences selected for suitable priming sites flanking microsatellite repeats referring to a 37% primer‐to‐marker conversion ratio. Seventy‐two markers were polymorphic. These numbers confirm the increased efficiency of pyrosequencing over traditional isolation techniques in the development of microsatellites. Amplification primer sequences and the sequences of corresponding target fragments are provided for all functional markers, and molecular polymorphisms estimated for four accessions of P. pusilla and among seven core group species represented by 14 individuals are reported. Cross‐species transferability ranged between 86.4% and 97.3% among the studied taxa, and 57, 11 and six of the selected primer pairs amplified fragments of expected size and number in seven, six and five of the species, respectively. Reproducibility of the molecular phenotypes was 97.0%, which was inferred using a replicate sample of P. pusilla.     

Isolation and characterization of polymorphic microsatellite markers in lesser kestrel (Falco naumanni) and cross-amplification in common kestrel (Falco tinnunculus)

Lesser kestrel, Falco naumanni, is a colonial and migratory species breeding in part of the Mediterranean Basin and part of central Asia and north-east of China and Mongolia. This species is catalogued in IUCN red list category as vulnerable. Twenty microsatellite loci were selected from libraries enriched in AC or AG tandem repeats and specific PCR were devised from their flanking sequences. Most microsatellites (14) were found polymorphic among 30 individuals of F. naumanni representing 20 reproduction areas of the species in the region of Extremadura, Spain. Polymorphisms were detected by size variation of the amplified loci, which allele number and observed heterozygosity ranged from 3 to 20 and from 0.300 to 0.933, respectively. Cross-species amplification showed that 13 of selected loci were also found polymorphic in common kestrel species (Falco tinnunculus). Novel polymorphic microsatellites will serve to conservation studies in lesser kestrel.     

Development and characterization of nine polymorphic microsatellite markers for Mexican spadefoot toads (Spea multiplicata) with cross-amplification in Plains spadefoot toads (S. bombifrons)

We developed nine polymorphic microsatellite markers for the Mexican spadefoot toad, Spea multiplicata. Allele numbers range from five to 12, with observed heterozygosities from 0.48 to 0.87. Because two loci are in linkage disequilibrium, these nine loci provide eight independent markers. Three loci exhibit departure from Hardy-Weinberg equilibrium, possibly resulting from null alleles or population admixture. These markers will be useful for assessing population structure and relatedness in S. multiplicata. Based on our success at cross-amplification in the Plains spadefoot toad (Spea bombifrons), these loci also may be useful in this species with additional optimization.     

Development of ten highly polymorphic microsatellite markers for Sunbirds (Aves: Nectariniidae) with broad cross-amplification utility in at least eight species

We describe the isolation of ten microsatellite loci from the Rwenzori Double-collared Sunbird using an enrichment protocol. All loci were variable with the number of alleles ranging from 5 to 13, and observed heterozygosity ranging from 0.500 to 0.929. Nine of these loci were screened on a panel of seven additional Sunbird species from three genera. All nine were successfully amplified and remained highly variable. Given 10–15% sequence divergence among these species in the mtDNA ND2 gene, our results suggest that these markers will work broadly across most members of the species rich bird family Nectariniidae.     

Development and characterization of microsatellite markers for Echinopsis rhodotricha and cross-amplification in other species of Cactaceae

Located in central South America, the Chaco is a large subtropical dry forest characterized by plants with xeromorphic features, including numerous cacti. In the Brazilian Chaco at the northeasternmost part of the Chaquenian region, Echinopsis rhodotricha (Cactaceae, Trichocereeae) is one of the species threatened by intense deforestation caused by expanding pastureland. This study characterizes the microsatellite loci isolated from E. rhodotricha and cross-amplification in thirteen other cactus species. Twelve microsatellite loci were developed from an enriched genomic library. Eight of these were polymorphic and characterized in 48 individuals from three E. rhodotricha populations. The loci showed a mean of 3.2 alleles per locus and overall levels of expected and observed heterozygosities ranging from 0.00 to 0.83 and 0.00 to 0.66, respectively. Five loci showed significant departures from the Hardy–Weinberg equilibrium and also exhibited signs of null alleles. Cross-amplification in other Cactaceae species was successful, ranging from one (Ferocactus latispinus, Cacteae and Harrisia adscendens, Trichocereeae) to twelve loci (Echinopsis calochlora, Trichocereeae). The development of these microsatellite markers will contribute to investigations of population structure, genetic diversity, and gene flow in E. rhodotricha populations, as well as in other cactus species, providing information useful for the creation and delimitation of conservation areas in the Brazilian Chaco region.