Variation of 15 autosomal microsatellite DNA loci in the Russian population

The allele frequencies of 15 autosomal STR loci (D3S1358, vWA, FGA, TH01, TPOX, CSF1PO, D5S818, D13S317, D7S820, D16S539, D2S1338, D8S1179, D21S11, D18S51, and D19S433) used in forensic medicine were determined for the Russian population of European Russia (N = 176). The power of discrimination (PD) and power of exclusion (PE) of the system of the 15 STR loci were 0.999 999 999 999 999 986 and 0.999 999 331 310 171 000, respectively. The allele and genotype frequency distributions in the Russian population corresponded to the Hardy-Weinberg equilibrium. The D2S1338, D18S51, D21S11, and FGA loci were identified as the most informative markers for the Russian population and proposed as a reference for forensic studies in the Russian Federation.     

Allelic polymorphism of six microsatellite DNA Loci in populations of Sakha (Yakutia)

The allele frequency distributions of six STR loci (D3S1358, D16S539, THOI, D8S1179, LPL, and HUMvWFII) used in forensic practice were analyzed in populations of Sakha (Yakutia): three ethnogeographical groups of Sakha (Yakuts), Evenks, Yukagirs, Dolgans, and Russians. There were significant differences between Russians and all other populations by five markers. The total discriminating power (PD) of the locus system studied was assessed for each population. The interpopulation genetic difference (F _ST) was 0.005. Data on the allelic polymorphism of the above STR loci were used to analyze phylogenetic relationships among the populations of Sakha and those of other regions: East Europe, South Siberia, Chukotka, and Kamchatka.     

Performance of different SNP panels for parentage testing in two East Asian cattle breeds

The International Society for Animal Genetics (ISAG) proposed a panel of single nucleotide polymorphisms (SNPs) for parentage testing in cattle (a core panel of 100 SNPs and an additional list of 100 SNPs). However, markers specific to East Asian taurine cattle breeds were not included, and no information is available as to whether the ISAG panel performs adequately for these breeds. We tested ISAG's core (100 SNP) and full (200 SNP) panels on two East Asian taurine breeds: the Korean Hanwoo and the Japanese Wagyu, the latter from the Australian herd. Even though the power of exclusion was high at 0.99 for both ISAG panels, the core panel performed poorly with 3.01% false‐positive assignments in the Hanwoo population and 3.57% in the Wagyu. The full ISAG panel identified all sire–offspring relations correctly in both populations with 0.02% of relations wrongly excluded in the Hanwoo population. Based on these results, we created and tested two population‐specific marker panels: one for the Wagyu population, which showed no false‐positive assignments with either 100 or 200 SNPs, and a second panel for the Hanwoo, which still had some false‐positive assignments with 100 SNPs but no false positives using 200 SNPs. In conclusion, for parentage assignment in East Asian cattle breeds, only the full ISAG panel is adequate for parentage testing. If fewer markers should be used, it is advisable to use population‐specific markers rather than the ISAG panel.     

Genetic characteristics of 32 autosomal STR loci and its application for identifying a locus in hereditary hearing loss in the Korean population

Microsatellites, short tandem repeats, are useful markers for genetic analysis because of their high frequency of occurrence over the genome, high information content due to variable repeat lengths, and ease of typing. To establish a panel of microsatellite markers useful for genetic studies for hereditary hearing loss in the Korean population, the allele frequencies and heterozygosities of 32 microsatellite markers in 172 unrelated Korean individuals were examined. The heterozygosity values for these markers ranged from 48 to 87%. All the markers except D6S1038 and D14S1034 marker showed PIC values over 0.5. This indicates these markers have a high degree of polymorphism and are randomly distributed in the Korean population. Therefore, the combinations of these STR loci provide a powerful tool to find the candidate loci of a causative gens for non-syndromic hearing loss in the Korean population.     

Microsatellite markers for the Mexican spotted owl (Strix occidentalis lucida)

A genomic cosmid library was used to develop seven highly polymorphic microsatellite markers for the Mexican spotted owl (Strix occidentalis lucida). These are the first reported microsatellite markers derived from this species. The cloned and sequenced repeat motifs include a triplet repeat of (AAT)_n, two tetranucleotide repeats of (GATA)_n, a tetranucleotide repeat of (ATCC)_n, a compound repeat of (GA)_n(GATA)_n and the two pentanucleotide repeats (AGAAT)_n and (ATTTT)_n. The microsatellites described represent six presumably independent loci with the two pentanucleotide repeats having originated from a single cosmid. Primer pairs allow locus‐specific amplification of each marker from Mexican spotted owl genomic DNA.     

The positions of 12 simple sequence repeat markers relative to reference loci on mouse Chromosome 16

The genetic map positions of 12 simple sequence repeat (SSR) markers spanning mouse Chromosome (Chr) 16 were determined relative to reference markers on that chromosome. Interval mapping data were obtained with a panel of DNAs from two intersubspecific backcrosses. All but one of the markers were typed by use of nonradioactive polymerase chain reaction (PCR) products analyzed on agarose gels. The marker order was determined to be Prm-1, D16Mit9, Igl-1, D16Mit29, D16Mit1/D16Mit2, Smst, D16Mit4, D16Mit11, Gap43, D16Mit14, D16Mit30, D16Mit5, Pit-1, D16Mit27, D16H21S16 (formerly D21S16h), D16Mit19, App, D16Mit7, Sod-1. Two of these markers mapped to the known human Chr 21 (HSA21)/Chr 16 conserved linkage group. Nine additional SSR markers could not be typed because they were not polymorophic (four markers), did not amplify MOLD/Rk DNA (three markers), or failed to give PCR products under a range of conditions (two markers). A subset of the most robust SSRs provide a useful marker set for the analysis of previously unmapped crosses.     

Development of microsatellite marker loci for European hazelnut (<Emphasis Type="Italic">Corylus avellana</Emphasis> L.) from ISSR fragments

Polymorphic microsatellite markers were developed for European hazelnut (Corylus avellana L.) from the sequences of inter-simple sequence repeat (ISSR) fragments and flanking regions. Twenty-five ISSR primers were used to generate fragments for cloning. Of the 520 unique sequences obtained, 41 contained long internal repeats (≥20 bp) with flanking sequences sufficient for primer design. From these, we developed 23 new polymorphic microsatellite loci. The flanking sequences were obtained for fragment ends by chromosome walking, and an additional 47 polymorphic markers were developed. Two additional polymorphic markers were developed from a GA-enriched library. The 72 new marker loci were characterized using 50 diverse hazelnut accessions. For the internal repeat loci, the number of alleles per locus ranged from 2 to 16, with a mean of 7.52. Mean values for expected heterozygosity (H_e), observed heterozygosity (H_o), and polymorphism information content (PIC) were 0.62, 0.59, and 0.58, respectively. The estimated frequency of null alleles (r) was ≥0.05 at six of the 23 loci. For the 47 marker loci developed from fragment ends, the number of alleles per locus ranged from 2 to 16, with a mean of 7.30. Mean values for H_e, H_o, and PIC were 0.62, 0.47, and 0.58, respectively. The estimated frequency of null alleles (r) was ≥0.10 at 18 of the 47 loci. Of the 70 loci developed from ISSR and flanking sequences, 50 segregated in our mapping population and were assigned to linkage groups.     

Polymorphism profile of nine short tandem repeat Loci in the Han chinese

Nine short tandem repeat (STR) markers (D3S1358, VWA, FGA, THO1, TPOX, CSFIPO, D5S818, D13S317, and D7S820) and a sex-identification marker (Amel-ogenin locus) were amplified with multiplex PCR and were genotyped with a four-color fluorescence method in samples from 174 unrelated Han individuals in North China. The allele frequencies, genotype frequencies, heterozygosity, probability of discrimination powers, probability of paternity exclusion and Hardy-Weinberg equilibrium expectations were determined. The results demonstrated that the genotypes at all these STR loci in Han population conform to Hardy-Weinberg equilibrium expectations. The combined discrimination power (DP) was 1.05×10-10 within nine STR loci analyzed and the probability of paternity exclusion (EPP) was 0.9998. The results indicate that these nine STR loci and the Amelo-genin locus are useful markers for human identification, paternity and maternity testing and sex determination in forensic sciences.     

Comparing two commercial domestic dog (Canis familiaris) STR genotyping kits for forensic identity calculations in a mixed‐breed dog population sample

Almost half of all US households own a dog (Canis familiaris). Though these household pets can attack humans and other animals, they are also frequently victims of cruelty, neglect and theft. In human‐oriented investigations, the tendency of domestic dogs to leave behind physical traces (such as hair) can serve as valuable links between crime scenes and suspects/victims. This demonstrated utility of canine biological evidence has created demand for genotyping marker sets for canine forensic genetic testing. Through research and casework, short tandem repeat (STR) panels have been shown to be very efficient for identity and parentage testing in dogs. However, there is an absence of comparative studies between different canine forensic identification kits. The Thermo Fisher Scientific Canine Genotypes ? Panel 1.1 and 2.1 Kits were originally designed and developed for routine and forensic use respectively, although both kits can be used for either purpose. In this study, we evaluated both STR panels to determine how critical forensic genetic metrics are affected by panel‐to‐panel variation in marker composition and design. Our results show that although STR panel composition can influence estimates such as inbreeding, combined power of discrimination and combined probability of exclusion, greater average allele number values exhibited across all markers in Panel 2.1 facilitated significantly more precise estimates of random match probability (RMP) and combined probability of identity. Furthermore, we demonstrate that a theta (θ) correction of 0.09 can be used to conservatively adjust RMPs generated from a small reference database of fewer than 50 samples, confirming that Panel 2.1 is a more robust forensic genotyping system than is Panel 1.1. for domestic dogs. We also demonstrate that opportunistic local sampling of fewer than 50 mixed‐breed dogs can produce sufficient discriminatory and exclusionary power with either genotyping kit.     

Development of simple sequence repeat markers for the plant pathogenic rust fungus,Puccinia graminis

Twenty‐four dinucleotide simple sequence repeat markers were developed for the phytopathogenic fungus, Puccinia graminis. The identified loci were polymorphic, with allelic diversity ranging from two to 11 alleles. Observed and expected levels of heterozygosity ranged from 0.000 to 0.960 and from 0.113 to 0.846, respectively. Fourteen of the loci deviated significantly from Hardy–Weinberg equilibrium. Null alleles were observed for 10 of the 24 loci with a frequency of 4–16%. A preliminary screen of other Puccinia cereal rust fungi (P. coronata, P. striiformis and P. triticina) indicated that these primer pairs are specific to P. graminis.     

Nuclear microsatellite markers for the date palm (Phoenix dactylifera L.): characterization and utility across the genus Phoenix and in other palm genera

A (GA)_n microsatellite‐enriched library was constructed and 16 nuclear simple sequence repeat (SSR) loci were characterized in Phoenix dactylifera. Across‐taxa amplification and genotyping tests showed the utility of most SSR markers in 11 other Phoenix species and the transferability of some of them in Elaeis guineensis, 11 species of Pritchardia, Pritchardiopsis jeanneneyi and six species of Astrocaryum. The first to be published for P. dactylifera, these new SSR resources are available for cultivar identification, pedigree analysis, germplasm diversity as well as genetic mapping studies.     

Isolation, characterization and mapping of simple sequence repeat markers in zoysiagrass (Zoysia spp.)

The genus Zoysia consists of 16 species that are naturally distributed on sea coasts and grasslands around the Pacific. Of these, Zoysia japonica, Zoysia matrella, and Zoysia tenuifolia are grown extensively as turfgrasses, and Z. japonica is also used as forage grass in Japan and other countries in East Asia. To develop simple sequence repeat (SSR) markers for zoysiagrass (Zoysia spp.), we used four SSR-enriched genomic libraries to isolate 1,163 unique SSR clones. All four libraries contained a high percentage of perfect clones, ranging from 67.1 to 96.0%, and compound clones occurred with higher frequencies in libraries A (28.6%) and D (11.6%). From these clones, we developed 1,044 SSR markers when we tested all 1,163 SSR primer pairs. Using all 1,044 SSR markers, we tested one screening panel consisting of eight Zoysia clones for testing PCR amplifications, from which five unrelated clones, among the eight, were used for polymorphism assessment, and found that the polymorphic information content ranged from 0 (monomorphic loci) to 0.88. Of the 1,044 SSR markers, 170 were segregated in our mapping population and we mapped 161 on existing amplified fragment length polymorphism-based linkage groups, using this mapping population. These SSR markers will provide an ideal marker system to assist with gene targeting, quantitative trait locus mapping, variety or species identification, and marker-assisted selection in Zoysia species.Electronic supplementary material Supplementary material is available in the online version of this article at and is accessible for authorized users.     

Development of diagnostic microsatellite markers from whole‐genome sequences of Ammodramus sparrows for assessing admixture in a hybrid zone

Studies of hybridization and introgression and, in particular, the identification of admixed individuals in natural populations benefit from the use of diagnostic genetic markers that reliably differentiate pure species from each other and their hybrid forms. Such diagnostic markers are often infrequent in the genomes of closely related species, and genomewide data facilitate their discovery. We used whole‐genome data from Illumina HiSeqS2000 sequencing of two recently diverged (600,000 years) and hybridizing, avian, sister species, the Saltmarsh (Ammodramus caudacutus) and Nelson's (A. nelsoni) Sparrow, to develop a suite of diagnostic markers for high‐resolution identification of pure and admixed individuals. We compared the microsatellite repeat regions identified in the genomes of the two species and selected a subset of 37 loci that differed between the species in repeat number. We screened these loci on 12 pure individuals of each species and report on the 34 that successfully amplified. From these, we developed a panel of the 12 most diagnostic loci, which we evaluated on 96 individuals, including individuals from both allopatric populations and sympatric individuals from the hybrid zone. Using simulations, we evaluated the power of the marker panel for accurate assignments of individuals to their appropriate pure species and hybrid genotypic classes (F1, F2, and backcrosses). The markers proved highly informative for species discrimination and had high accuracy for classifying admixed individuals into their genotypic classes. These markers will aid future investigations of introgressive hybridization in this system and aid conservation efforts aimed at monitoring and preserving pure species. Our approach is transferable to other study systems consisting of closely related and incipient species.     

Regeneration of multiple shoots from transgenic potato events facilitates the recovery of phenotypically normal lines: assessing a cry9Aa2 gene conferring insect resistance

Background

Tools for authenticating cell lines are critical for quality control in cell-based biological experiments. Currently there are methods to authenticate human cell lines using short tandem repeat (STR) markers based on the technology and procedures successfully used in the forensic community for human identification, but there are no STR based methods for authenticating nonhuman cell lines to date. There is significant homology between the human and vervet monkey genome and we utilized these similarities to design the first multiplex assay based on human STR markers for vervet cell line identification.

Results

The following STR markers were incorporated into the vervet multiplex PCR assay: D17S1304, D5S1467, D19S245, D1S518, D8S1106, D4S2408, D6S1017, and DYS389. The eight markers were successful in uniquely identifying sixty-two vervet monkey DNA samples and confirmed that Vero76 cells and COS-7 cells were derived from Vero and CV-1 cells, respectively. The multiplex assay shows specificity for vervet DNA within the determined allele range for vervet monkeys; however, the primers will also amplify human DNA for each marker resulting in amplicons outside the vervet allele range in several of the loci. The STR markers showed genetic stability in over sixty-nine passages of Vero cells, suggesting low mutation rates in the targeted STR sequences in the Vero cell line.

Conclusions

A functional vervet multiplex assay consisting of eight human STR markers with heterozygosity values ranging from 0.53-0.79 was successful in uniquely identifying sixty-two vervet monkey samples. The probability of a random match using these eight markers between any two vervet samples is approximately 1 in 1.9 million. While authenticating a vervet cell line, the multiplex assay may also be a useful indicator for human cell line contamination since the assay is based on human STR markers.     

New microsatellite resources for groupers (Serranidae)

We characterized nine microsatellite loci and identified an additional 60 genomic regions containing microsatellites in the red hind grouper, Epinephelus guttatus. The nine loci were highly polymorphic, and primers designed from red hind genomic DNA produced a strong amplification product in a test panel of 16 other groupers in the genera Epinephelus and Mycteroperca collected from across the world. Most of the amplified regions were homologous to the red hind locus and a well‐defined microsatellite repeat was generally evident. The nine loci, together with the 60 uncharacterized microsatellite‐containing regions, provide a powerful tool for ecological and evolutionary studies in groupers.     

用多重PCR检测上海地区汉族人群9个STR基因座的多态性

利用多重PCR和四色荧光（5－FAM,JOE,NED和ROX）自动化检测技术调查上海地区汉族人群D3S1358、vWA、FGA、D8S1179、D21S11、D18S51、D5S818、D13S317、D7S820等9个STR基因座多态性分布并计算 该9个基因座的的基因频率（Pi)、个体鉴别力（DP）、无偏倚期望杂合性（H）、多态性信息含量（PIC）和非父排除概率（PE）。结果显示：9个STR基因座的基因型分布符合Hardy-Weinberg平衡,9个STR基因座中FGA基因座的DP值最高为0.9584,D8S1179的H值最高为0.9403,D18S51的PIC值最高为0.8560,D18S51的PE值最高为0.7391,9个STR基因座累积个体鉴别力（CDP)为0.9999996,累积非父排除能力（CPE）为0.99991。9个STR基因座适合作为中国人群的遗传标志,用于人类学、遗传疾病基因连锁分析、法医学亲子鉴定和个体识别等研究领域。     

Genetic mapping of two DNA markers,D16Ros1 and D16Ros2, flanking the mutation site in the chakragati mouse,a transgenic insertional mutant

We present here the genetic mapping of two novel loci, D16Ros1 and D16Ros2, to mouse Chromosome (Chr) 16. The probes for these loci were genomic framents isolated from the chakragati mouse, a behavioural mutant resulting from insertional mutagenesis during the course of making transgenic mice. D16Ros1 and D16Ros2 were first mapped by recombinant inbred (RI) strain analysis and subsequently by the analysis of 145 progeny of two interspecific backcrosses between Mus domesticus and Mus spretus. These progeny had been typed for the centromere and this allowed mapping of D16Ros1 and D16Ros2 relative to the centromere. The other markers included in this study were Prm-1, Gap43 and Sod-1. The genetic map generated spanned 47.5 cM from the centromere to Sod-1, the most distal marker mapped here. The linkage data presented here should prove useful in mapping other loci relative to the centromere of Chr 16.     

Evaluation of linkage disequilibrium and its effect on non-parametric multipoint linkage analysis using two high density single-nucleotide polymorphism mapping panels

Genotype data from the Illumina Linkage III SNP panel (n = 4,720 SNPs) and the Affymetrix 10 k mapping array (n = 11,120 SNPs) were used to test the effects of linkage disequilibrium (LD) between SNPs in a linkage analysis in the Collaborative Study on the Genetics of Alcoholism pedigree collection (143 pedigrees; 1,614 individuals). The average r2 between adjacent markers across the genetic map was 0.099 +/- 0.003 in the Illumina III panel and 0.17 +/- 0.003 in the Affymetrix 10 k array. In order to determine the effect of LD between marker loci in a nonparametric multipoint linkage analysis, markers in strong LD with another marker (r2 > 0.40) were removed (n = 471 loci in the Illumina panel; n = 1,804 loci in the Affymetrix panel) and the linkage analysis results were compared to the results using the entire marker sets. In all analyses using the ALDX1 phenotype, 8 linkage regions on 5 chromosomes (2, 7, 10, 11, X) were detected (peak markers p < 0.01), and the Illumina panel detected an additional region on chromosome 6. Analysis of the same pedigree set and ALDX1 phenotype using short tandem repeat markers (STRs) resulted in 3 linkage regions on 3 chromosomes (peak markers p < 0.01). These results suggest that in this pedigree set, LD between loci with spacing similar to the SNP panels tested may not significantly affect the overall detection of linkage regions in a genome scan. Moreover, since the data quality and information content are greatly improved in the SNP panels over STR genotyping methods, new linkage regions may be identified due to higher information content and data quality in a dense SNP linkage panel.     

Comparing molecular measures for detecting inbreeding depression

Correlations between heterozygosity and components of fitness have been investigated in natural populations for over 20 years. Positive correlations between a trait of interest and heterozygosity (usually measured at allozyme loci) are generally recognized as evidence of inbreeding depression. More recently, molecular markers such as microsatellites have been employed for the same purpose. A typical study might use around five to ten markers. In this paper we use a panel of 71 microsatellite loci to: (1) Compare the efficacy of heterozygosity and a related microsatellite‐specific variable, mean d², in detecting inbreeding depression; (2) Examine the statistical power of heterozygosity to detect such associations. We performed our analyses in a wild population of red deer (Cervus elaphus) in which inbreeding depression in juvenile traits had previously been detected using a panel of nine markers. We conclude that heterozygosity‐based measures outperform mean d²‐based measures, but that power to detect heterozygosity‐fitness associations is nonetheless low when ten or fewer markers are typed.     

A large population genetic study of 15 autosomal short tandem repeat loci for establishment of Korean DNA Profile Database

Genotyping of highly polymorphic short tandem repeat (STR) markers is widely used for the genetic identification of individuals in forensic DNA analyses and in paternity disputes. The National DNA Profile Databank recently established by the DNA Identification Act in Korea contains the computerized STR DNA profiles of individuals convicted of crimes. For the establishment of a large autosomal STR loci population database, 1805 samples were obtained at random from Korean individuals and 15 autosomal STR markers were analyzed using the AmpFlSTR Identifiler PCR Amplification kit. For the 15 autosomal STR markers, no deviations from the Hardy-Weinberg equilibrium were observed. The most informative locus in our data set was the D2S1338 with a discrimination power of 0.9699. The combined matching probability was 1.521 × 10⁻¹⁷. This large STR profile dataset including atypical alleles will be important for the establishment of the Korean DNA database and for forensic applications.