DNA-based parentage verification in two Australian goat herds

This study aimed to evaluate a set of DNA markers for their effectiveness in parentage inference, to quantify the level of pedigree errors in Australian Angora and Cashmere goat herds using different pedigree recording methods, and to investigate genotype mismatches between parent and offspring. The 14 microsatellite markers evaluated in this study provided a high level of power (probability of exclusion, PE >99.70%) for parentage testing. The extent of PE depended on polymorphic information content (PIC) and number of alleles for each marker. The minimum number of MS markers essential for accurate determination of parentage was 12, when neither parent is known (PE1) and 10, when one parent is known (PE2). In both populations, the error rates of recorded sire and dam pedigree were significant, averaging around 12%. The error rates of sire and dam pedigree varied considerably between the two populations, reflecting management differences on the two properties. Of 14 MS markers, one locus, SRCRSP07, had null alleles present in the heterozygous state. This null allele was revealed by mismatches of genotypes of parent-offspring pairs. Highly significant deviation from Hardy–Weinberg Equilibrium and significant heterozygote deficiency was also observed at this locus.     

Characterization of new microsatellite loci in Pieris amamioshimensis (Ericaceae), a species nearly extinct in the wild

A set of 11 polymorphic microsatellite markers has been developed and characterized for the critically endangered species Pieris amamioshimensis. Fifty‐nine individuals of an ex‐situ population were used to identify these markers. The total number of alleles for each locus ranged from 3 to 9, with an average of 5.4. The expected heterozygosities (H_S) and observed heterozygosities (H_O) ranged from 0.47 to 0.77 and 0.22 to 0.88, respectively. In total, four loci exhibited significant deviations from Hardy–Weinberg equilibrium: two loci showed significant heterozygosity excess and the other two loci showed significant heterozygosity deficit. The polymorphism information content (0.43 ≤ PIC ≤ 0.73), the probability of exclusions (PE₁ = 0.9565, PE₂ = 0.9969 and PE₃ = 0.9999) and probabilities for identity (PI = 3.78 × 10^?9 and PI‐Sib = 2.35 × 10^?4) suggest that these markers are useful for estimating not only genetic diversity but also parentage, for the ex‐situ conservation management of populations.     

Effects of genotyping errors on parentage exclusion analysis

Genetic markers are widely used to determine the parentage of individuals in studies of mating systems, reproductive success, dispersals, quantitative genetic parameters and in the management of conservation populations. These markers are, however, imperfect for parentage analyses because of the presence of genotyping errors and undetectable alleles, which may cause incompatible genotypes (mismatches) between parents and offspring and thus result in false exclusions of true parentage. Highly polymorphic markers widely used in parentage analyses, such as microsatellites, are especially prone to genotyping errors. In this investigation, I derived the probabilities of excluding a random (related) individual from parentage and the probabilities of Mendelian-inconsistent errors (mismatches) and Mendelian-consistent errors (which do not cause mismatches) in parent-offspring dyads, when a marker having null alleles, allelic dropouts and false alleles is used in a parentage analysis. These probabilities are useful in evaluating the impact of various types of genotyping errors on the information content of a set of markers in and thus the power of a parentage analysis, in determining the threshold number of genetic mismatches that is appropriate for a parentage exclusion analysis and in estimating the rates of genotyping errors and frequencies of null alleles from observed mismatches between known parent-offspring dyads. These applications are demonstrated by numerical examples using both hypothetical and empirical data sets and discussed in the context of practical parentage exclusion analyses.     

Parentage testing in alpacas (Vicugna pacos) using semi-automated fluorescent multiplex PCRs with 10 microsatellite markers

The aim of this study was to assess and apply a microsatellite multiplex system for parentage determination in alpacas. An approach for parentage testing based on 10 microsatellites was evaluated in a population of 329 unrelated alpacas from different geographical zones in Perú. All microsatellite markers, which amplified in two multiplex reactions, were highly polymorphic with a mean of 14.5 alleles per locus (six to 28 alleles per locus) and an average expected heterozygosity ( H _E) of 0.8185 (range of 0.698–0.946). The total parentage exclusion probability was 0.999456 for excluding a candidate parent from parentage of an arbitrary offspring, given only the genotype of the offspring, and 0.999991 for excluding a candidate parent from parentage of an arbitrary offspring, given the genotype of the offspring and the other parent. In a case test of parentage assignment, the microsatellite panel assigned 38 (from 45 cases) offspring parentage to 10 sires with LOD scores ranging from 2.19 × 10⁺¹³ to 1.34 × 10⁺¹⁵ and Δ values ranging from 2.80 × 10⁺¹² to 1.34 × 10⁺¹⁵ with an estimated pedigree error rate of 15.5%. The performance of this multiplex panel of markers suggests that it will be useful in parentage testing of alpacas.     

Population estimators or progeny tests: what is the best method to assess null allele frequencies at SSR loci?

Nuclear SSRs are notorious for having relatively high frequencies of null alleles, i.e. alleles that fail to amplify and are thus recessive and undetected in heterozygotes. In this paper, we compare two kinds of approaches for estimating null allele frequencies at seven nuclear microsatellite markers in three French Fagus sylvatica populations: (1) maximum likelihood methods that compare observed and expected homozygote frequencies in the population under the assumption of Hardy-Weinberg equilibrium and (2) direct null allele frequency estimates from progeny where parent genotypes are known. We show that null allele frequencies are high in F. sylvatica (7.0% on average with the population method, 5.1% with the progeny method), and that estimates are consistent between the two approaches, especially when the number of sampled maternal half-sib progeny arrays is large. With null allele frequencies ranging between 5% and 8% on average across loci, population genetic parameters such as genetic differentiation (F _ST) may be mostly unbiased. However, using markers with such average prevalence of null alleles (up to 15% for some loci) can be seriously misleading in fine scale population studies and parentage analysis.     

Development of polymorphic microsatellite markers for the zebra finch (Taeniopygia guttata)

To study the population genetics as well as the mating system of captive zebra finch (Taeniopygia guttata) populations, we developed primers for 12 microsatellite loci and screened them in 529 individuals from two successive generations of a single captive population. All markers were polymorphic with five to 14 alleles per locus. We checked all markers for Mendelian inheritance in 307 offspring whose parents were known for sure. Four markers showed evidence for the presence of null alleles. Once allowing for null alleles, we found no mismatches between offspring and parents, suggesting a very low rate of mutation. Average observed and expected heterozygosities across the eight loci showing no evidence for null‐alleles was 0.819 and 0.812, respectively.     

Isolation and characterization of 149 novel microsatellite DNA markers for striped bass,Morone saxatilis,and cross‐species amplification in white bass,Morone chrysops,and their hybrid

To support detailed genetic analysis of striped bass (Morone saxatilis) and white bass (Morone chrysops), we isolated 153 microsatellite loci from repeat‐enriched striped bass DNA libraries. Of these, 147 markers amplified in striped bass (average 4.7 alleles per locus) and 133 in white bass (average 2.2 alleles per locus). One hundred twenty‐two markers amplified in their hybrid. Development of new microsatellite markers will facilitate evaluations of genetic structure in wild populations and will support pedigree analysis and linkage mapping for selective breeding.     

Development and diversity of microsatellite markers for endangered species Clinostigma savoryanum

A set of microsatellite markers was developed for Clinostigma savoryanum, an endemic palm species distributed in the Bonin Islands. We obtained 233 sequences that were unique, containing microsatellites from an enriched library. Twelve loci were screened for their feasibility to be used as high resolution genetic markers using each 30 individuals from two insular populations, Haha-jima and Mukou-jima. They showed polymorphisms of two to eight alleles per locus and expected heterozygosities of 0.124–0.789. There is no evidence for significant scoring error due to stuttering, large allele dropout and null alleles at 95% confidence interval except for the presence of null alleles in CLS00-77 of Mukou-jima population.     

Implementation of a parentage control system in Portuguese beef-cattle with a panel of microsatellite markers

A study was conducted to assess the feasibility of applying a panel of 10 microsatellite markers in parentage control of beef cattle in Portugal. In the first stage, DNA samples were collected from 475 randomly selected animals of the Charolais, Limousin and Preta breeds. Across breeds and genetic markers, means for average number of alleles, effective number of alleles, expected heterozygosity and polymorphic information content, were 8.20, 4.43, 0.733 and 0.70, respectively. Enlightenment from the various markers differed among breeds, but the set of 10 markers resulted in a combined probability above 0.9995 in the ability to exclude a random putative parent. The marker-set thus developed was later used for parentage control in a group of 140 calves from several breeds, where there was the suspicion of possible faulty parentage recording. Overall, 76.4% of the calves in this group were compatible with the recorded parents, with most incompatibilities due to misidentification of the dam. Efforts must be made to improve the quality of pedigree information, with particular emphasis on information recorded at the calf's birth.     

Analysis of microsatellites and parentage testing in saltwater crocodiles

Fifteen microsatellite loci were evaluated in farmed saltwater crocodiles for use in parentage testing. One marker (C391) could not be amplied. For the remaining 14, the number of alleles per locus ranged from two to 16, and the observed heterozygosities ranged from 0.219 to 0.875. The cumulative exclusion probability for all 14 loci was .9988. the 11 loci that showed the greatest level of polymorphism were used for parentage testing, with an exclusion probability of .9980. With these 11 markers on 107 juveniles from 16 known breeding pairs, a 5.6% pedigree error rate was detected. This level of pedigree error, if consistent, could have an impact on the accuracy of gentic parameter and breeding value estimation. The usefulness of these markers was also evaluated for assigning parentage in situations where maternity, paternity, or both may not be known. In these situations, a 2% error in parentage assignment was predicted. It is therefore recommended that more micro-satellite markers be used in these situations. The use of these microsatellite markers will broaden the scope of a breeding program, allowing progeny to be tested from adults maintained in large breeding lagoons for selection as future breeding animals.     

Parentage testing of racing camels (Camelus dromedarius) using microsatellite DNA typing

The camel racing industry would have added value in being able to assign parentage with high certainty. This study was aimed at assessing and applying microsatellite multiplexes to construct a parentage testing system for camels. An efficient system of 17 loci from 700 camel samples was used to construct a database of unrelated adults. Based on this, we estimated measures of polymorphism among the markers. In three multiplex reactions, we detected a total of 224 alleles, with 5–23 alleles/locus (mean = 13.18 ± 6.95 SD) and an average heterozygosity (H_E) of 0.54 (range 0.032–0.905). The total parentage exclusion probability was 0.99999 for excluding a candidate parent from parentage of an arbitrary offspring, given only the genotype of the offspring, and 0.9999 for excluding a candidate parent from parentage of an arbitrary offspring, given the genotype of the offspring and the other parent. We used 15 juveniles for parentage testing, as well as 17 sires (bull camels) and 21 dams (cows). In the case of parentage assignment, the microsatellite panel assigned all 15 offspring parentage with high confidence. Overall, these findings offer a set of microsatellite markers that are easy, simple and highly informative for parentage testing in camels.     

Fifteen new polymorphic microsatellite loci for the meadow brown butterfly,Maniola jurtina

We characterized fifteen microsatellite markers for the butterfly Maniola jurtina. For the six studied populations (96 samples) the total number of alleles per locus ranged from 3 to 55 and mean overall expected heterozygosity across all loci was 0.74. In spite of a high frequency of null alleles detected in part of the loci, a recurrent phenomenon in Lepidopteron, the estimation of pairwise F_ST seems rather insensitive to the presence of these null alleles as shown by the high correlation between F_ST calculated after correction for the presence of null alleles and non-corrected F_ST, indicating that the loci may be usable in population genetics, more specifically for the study of populations genetics structure.     

Genetic diversity and parentage assignment in Dojo loach,Misgurnus anguillicaudatus based on microsatellite markers

In this study, genetic diversity and structure of three Misgurnus anguillicaudatus populations from three different geographical locations in China (Hunan, Hubei and Henan province) were investigated using microsatellite markers. High level of genetic diversity of all three populations was revealed by expected heterozygosity (H_e), observed heterozygosity (H_o) and allele number. Significant genetic differentiations were found between all pairs of populations. The efficiency of eight microsatellite markers in parentage assignment of 540 progeny from twenty full-sib families was evaluated. Simulation based on allele frequency data demonstrated that probabilities of exclusion per locus range from 0.313 to 0.825 when no parent information is available and 0.504 to 0.904 when one parent is known. The assignment success rate based on the real data using eight markers was 96.85%. This study indicates that these M. anguillicaudatus resources are valuable genetic and breeding material for aquaculture and the microsatellite markers will be useful for investigation of genetic background and molecular marker-assisted selective breeding in this species.     

Microsatellite markers for the whelk Buccinum undatum

Five microsatellite loci are described for the commercially exploited marine gastropod, Buccinum undatum. Levels of polymorphism were variable with three to 19 alleles per locus and expected heterozygosities of 0.26–0.94 in 60 individuals of the population from which the loci were isolated. Homozygote excess at two of the loci might be attributable to null alleles, and these loci should not be used in, for example, parentage analysis. Nevertheless, because null allele frequencies can be estimated and their effects partitioned, all are useful markers for studies of population differentiation.     

Sixteen novel microsatellite loci developed for the giant panda (Ailuropoda melanoleuca)

Sixteen novel microsatellite DNA loci were developed from the giant panda (Ailuropoda melanoleuca) using a magnetic-bead capture method. A total of 115 alleles were obtained for these markers, ranging from 4 to 12 alleles per locus (average 7.188). These loci exhibited high levels of polymorphic information content and expected heterozygosity, 0.558–0.855 (average 0.729) and 0.628–0.885 (average 0.778), respectively. Therefore, the allelic polymorphism and heterozygosity show that the giant pandas raised in China Research and Conservation Center possess abundant genetic variation. In addition, if the three markers showing null alleles were excluded, the remaining 13 microsatellite loci still presented extremely low non-exclusion probabilities of parentage (0.002), paternity (0.000) and identity (0.000). As a result, this new suit of microsatellite markers would be a very informative tool for the genetic and conservation studies of giant pandas.     

Characterization of 29 polymorphic artiodactyl microsatellite markers for the mountain goat (Oreamnos americanus)

We report the results of a cross‐species amplification test of 156 bovine, ovine and cervid microsatellite markers in a wild population of mountain goats, Oreamnos americanus, inhabiting Caw Ridge, Alberta, Canada. Twenty‐nine markers were found to be low to moderately polymorphic with between two to nine alleles per locus. Observed heterozygosity ranged from 0.14 to 0.85 for a sample of 215 mountain goats. This set of markers will be used in parentage analyses to construct the pedigree of the long‐term studied population and to investigate the effects of individual genetic variability on life‐history traits.     

Development of novel tetra- and trinucleotide microsatellite markers for giant grouper <Emphasis Type="Italic">Epinephelus lanceolatus</Emphasis> using 454 pyrosequencing

Giant grouper (Epinephelus lanceolatus) is a commercially important species, but its wild population has recently been classified as vulnerable. This species has significant potential for use in aquaculture, though a greater understanding of population genetics is necessary for selective breeding programs to minimize kinship for genetically healthy individuals. High-throughput pyrosequencing of genomic DNA was used to identify and characterize novel tetra- and trinucleotide microsatellite markers in giant grouper from Sabah, Malaysia. In total, of 62,763 sequences containing simple sequence repeats (SSRs) were obtained, and 78 SSR loci were selected to possibly contain tetra- and trinucleotide repeats. Of these loci, 16 had tetra- and 8 had trinucleotide repeats, all of which exhibited polymorphisms within easily genotyped regions. A total of 143 alleles were identified with an average of 5.94 alleles per locus, with mean observed and expected heterozygosities of 0.648 and 0.620, respectively. Among of them, 15 microsatellite markers were identified without null alleles and with Hardy–Weinberg equilibrium. These alleles showed a combined non-exclusion probability of 0.01138. The probability of individual identification (P_ID) value combined with in descending order 12 microsatellite markers was 0.00008, which strongly suggests that the use of the microsatellite markers developed in this study in various combinations would result in a high resolution method for parentage analysis and individual identification. These markers could be used to establish a broodstock management program for giant grouper and to provide a foundation for genetic studies such as population structure, parentage analysis, and kinship selection.     

SNPs for Parentage Testing and Traceability in Globally Diverse Breeds of Sheep

DNA-based parentage determination accelerates genetic improvement in sheep by increasing pedigree accuracy. Single nucleotide polymorphism (SNP) markers can be used for determining parentage and to provide unique molecular identifiers for tracing sheep products to their source. However, the utility of a particular “parentage SNP” varies by breed depending on its minor allele frequency (MAF) and its sequence context. Our aims were to identify parentage SNPs with exceptional qualities for use in globally diverse breeds and to develop a subset for use in North American sheep. Starting with genotypes from 2,915 sheep and 74 breed groups provided by the International Sheep Genomics Consortium (ISGC), we analyzed 47,693 autosomal SNPs by multiple criteria and selected 163 with desirable properties for parentage testing. On average, each of the 163 SNPs was highly informative (MAF≥0.3) in 48±5 breed groups. Nearby polymorphisms that could otherwise confound genetic testing were identified by whole genome and Sanger sequencing of 166 sheep from 54 breed groups. A genetic test with 109 of the 163 parentage SNPs was developed for matrix-assisted laser desorption/ionization–time-of-flight mass spectrometry. The scoring rates and accuracies for these 109 SNPs were greater than 99% in a panel of North American sheep. In a blinded set of 96 families (sire, dam, and non-identical twin lambs), each parent of every lamb was identified without using the other parent’s genotype. In 74 ISGC breed groups, the median estimates for probability of a coincidental match between two animals (P_I), and the fraction of potential adults excluded from parentage (P_E) were 1.1×10(−39) and 0.999987, respectively, for the 109 SNPs combined. The availability of a well-characterized set of 163 parentage SNPs facilitates the development of high-throughput genetic technologies for implementing accurate and economical parentage testing and traceability in many of the world’s sheep breeds.     

A High Throughput Single Nucleotide Polymorphism Multiplex Assay for Parentage Assignment in New Zealand Sheep

Accurate pedigree information is critical to animal breeding systems to ensure the highest rate of genetic gain and management of inbreeding. The abundance of available genomic data, together with development of high throughput genotyping platforms, means that single nucleotide polymorphisms (SNPs) are now the DNA marker of choice for genomic selection studies. Furthermore the superior qualities of SNPs compared to microsatellite markers allows for standardization between laboratories; a property that is crucial for developing an international set of markers for traceability studies. The objective of this study was to develop a high throughput SNP assay for use in the New Zealand sheep industry that gives accurate pedigree assignment and will allow a reduction in breeder input over lambing. This required two phases of development- firstly, a method of extracting quality DNA from ear-punch tissue performed in a high throughput cost efficient manner and secondly a SNP assay that has the ability to assign paternity to progeny resulting from mob mating. A likelihood based approach to infer paternity was used where sires with the highest LOD score (log of the ratio of the likelihood given parentage to likelihood given non-parentage) are assigned. An 84 “parentage SNP panel” was developed that assigned, on average, 99% of progeny to a sire in a problem where there were 3,000 progeny from 120 mob mated sires that included numerous half sib sires. In only 6% of those cases was there another sire with at least a 0.02 probability of paternity. Furthermore dam information (either recorded, or by genotyping possible dams) was absent, highlighting the SNP test’s suitability for paternity testing. Utilization of this parentage SNP assay will allow implementation of progeny testing into large commercial farms where the improved accuracy of sire assignment and genetic evaluations will increase genetic gain in the sheep industry.     

Twelve novel microsatellite markers for the Great Plains toad,Bufo cognatus

Here I report on 12 microsatellite loci designed for populations of the Great Plains toad (Bufo cognatus) in the deserts of the southwestern USA. Diversity at these loci measured for 134 individuals from four breeding aggregations was relatively high with seven to 34 alleles per locus (mean = 17.8). Observed heterozygosities ranged from 0.444 to 0.949 and expected heterozygosities ranged from 0.597 to 0.951. These markers will be useful for studies of population genetic structure, parentage and relatedness in this explosively breeding amphibian.