Effectiveness of human microsatellite loci for assessing paternity in a captive colony of vervets (Chlorocebus aethiops sabaeus)

Microsatellite polymorphisms are playing an increasingly vital role in primatological research, and are particularly useful for paternity exclusion in both wild and captive populations. Although vervet monkeys (Chlorocebus aethiops) are commonly studied in both settings, few previous studies have utilized microsatellite markers for assessing genetic variation in this species. In a pilot project to assess paternity in the UCLA-VA Vervet Monkey Research Colony (VMRC), we screened 55 commercially available human microsatellite markers chosen from a panel of 370 that have been shown to be polymorphic in baboons (Papio hamadryas). Using a standard PCR protocol, 43 (78%) loci produced amplifiable product. Of these, 14 were polymorphic and 11 were genotyped in 51 individuals, including 19 offspring and 14 potential sires. The average heterozygosity across the 11 loci was.719. In all 19 paternity cases all but one male was excluded as the true sire at two or more loci. This includes successfully distinguishing between two maternal half-sib brothers who were potential sires in most of the paternity cases. Given that the colony is descended from 54 wild-caught founders trapped between 1975 and 1987 from an introduced population on St. Kitts, West Indies, these values imply high microsatellite variability in natural vervet populations. Our results provide a panel of markers derived from the human genome that is suitable for assessing genetic variation and paternity in vervets.     

Genetic maternity and paternity in a local population of armadillos assessed by microsatellite DNA markers and field data

Genetic data from polymorphic microsatellite loci were employed to estimate paternity and maternity in a local population of nine-banded armadillos (Dasypus novemcinctus) in northern Florida. The parentage assessments took advantage of maximum likelihood procedures developed expressly for situations when individuals of neither gender can be excluded a priori as candidate parents. The molecular data for 290 individuals, interpreted alone and in conjunction with detailed biological and spatial information for the population, demonstrate high exclusion probabilities and reasonably strong likelihoods of genetic parentage assignment in many cases; low mean probabilities of successful reproductive contribution to the local population by individual armadillo adults in a given year; and statistically significant microspatial associations of parents and their offspring. Results suggest that molecular assays of highly polymorphic genetic systems can add considerable power to assessments of biological parentage in natural populations even when neither parent is otherwise known.     

Complete exclusion of nonsires in an analysis of paternity in a natural plant population using amplified fragment length polymorphism (AFLP)

The utility of the new polymerase chain reaction (PCR)-based multilocus DNA fingerprinting technique amplified fragment length polymorphism (AFLP) for paternity analysis in natural plant populations was assessed. In a natural population of 25 plants of Persoonia mollis (Proteaceae), three AFLP primer pairs generated 147 dominant loci. Of these, 125 (85%) were polymorphic, with a mean recessive allele frequency of 0.735. The theoretical expected percentage of offspring for which all males except the true father can be excluded ( P _ET) was 99.9% for this population. The estimates of P _ET drop marginally to 99.6% and 97.6% for larger populations of 100 and 1000 individuals, respectively. A preliminary investigation confirmed the power of AFLP for paternity analysis by assigning paternity, or excluding all known potential sires, for 242 of 252 (96.0%) naturally pollinated seeds. Ambiguous paternity for the remaining 10 seeds was quickly resolved by utilizing two further AFLP primer pairs, ultimately generating over 200 polymorphic loci and resulting in the exclusion of all nonsires for all 252 (100%) seeds. This study highlights the utility of AFLP for paternity analysis because: (i) it generates sufficiently large numbers of highly reproducible polymorphic loci, that are (ii) quickly and accurately scored using an automated DNA sequencer and dedicated software, and (iii) unlike microsatellites, requires no sequence knowledge so it is more easily applied to new study species.     

Genetic evidence for extra-pair fertilizations in a monogamous passerine, the Great Tit Parus major

The incidence of extra-pair paternity in a Great Tit Parus major population at Wytham Wood, Oxford, in 1985–1987 was determined using two polymorphic allozymes. In 831 nestlings from 94 broods, 27 genetic exclusions were detected in 25 (3%) nestlings from 16 broods. Seven (44%) of these broods contained offspring that excluded the putative male parent from being the genetic parent. The distribution of exclusion types indicated that excluded offspring were the result of fertilizations by extra-pair males and not of egg-dumping. The true frequency of extra-pair paternity was estimated as 14% of offspring. These results suggest a mixed reproductive strategy for males in which they breed mo-nogamously whilst simultaneously seeking extra-pair matings with females of other pairs.     

Probability of paternity exclusion and the number of loci needed to determine the fathers in a troop of macaques

We calculated the probability of paternity exclusion (P) in 6 troops of rhesus and Japanese macaques housed in open enclosures and 68 wild troops of Japanese, crab-eating, and toque macaques using 33 genetic loci which encoded the blood protein variations detected by electrophoretic techniques. In the open enclosures, especially of rhesus troops, we obtained a fairly high probability of paternity exclusion and succeeded in determining the fathers of offspring. However, we found significant differences between the observed and calculated probabilities in most of the troops. These differences were ascribed to a situation whereby the Hardy-Weinberg equilibrium had not been attained in the troops and/or the numbers of variable loci were too small. In the wild troops of Japanese, crab-eating, and toque macaques, the means ofP were 0.2274 (0.0192–0.5017), 0.4635 (0.1676–0.7151), and 0.7382 (0.6266–0.7954), respectively. We also estimated the number of loci needed to determine the fathers of offspring with a probability of 0.8 assuming that ten males were present in the troop. The estimated number was about 13.5 times, 5 times and 1.8 times the number of loci examined on average in the troops of Japanese, crab-eating and toque macaques, respectively. This means that determination of most of the fathers of offspring in wild troops of these macaques, even of toque macaques which have a rather high probability of paternity exclusion, is difficult so long as we employ only electrophoretic techniques.     

Rapid and efficient resolution of parentage by amplification of short tandem repeats.

Short tandem repeat (STR) loci are highly informative polymorphic loci that are gaining popularity for identity testing. We have conducted parentage testing by using nine STR loci on 50 paternity trios that had been previously tested using VNTR loci. These nine unlinked STR loci are amplified in three multiplex reactions and, when examined for genetic informativeness, provide a combined average power of exclusion of 99.73% (Caucasian data). The informative value of the selected loci is based on extensive STR typing of four racial/ethnic populations. In 37 of the 50 cases, paternity could not be excluded by any of the loci. In the remaining 13 cases, paternity was excluded by at least two of the STR markers. The probability of paternity calculated for the alleged father of each matching trio was > 99% in 36 of the 37 inclusion cases. All data agreed with the results reported using VNTR loci and conventional Southern technology. Our studies validate the use of DNA typing with STR loci for parentage testing, thus providing an accurate, highly sensitive, and rapid assay.     

Deterministic paternity exclusion using RAPD markers

The Random Amplified Polymorphic DNA (RAPD) technique can potentially provide hundreds of polymorphic markers for use by ecologists studying mating systems in natural populations. We consider here the implications of the dominance displayed by RAPD markers for deterministic paternity assignment. Our goal was to provide a means for assessing the costs associated with such a study for ecologists who might be considering the use of RAPD markers for paternity analysis. The theoretical expected proportion of offspring for which all males except the true father can be exlucded (P(ET)) is calculated for both dominant and codominant marker systems. The ability to assign paternity unambiguously generally increases with the number of loci and the frequency of the recessive allele (but only up to a point), and decreases with increasing sample size (number of individuals surveyed). The gain in P(ET) with decreasing sample size is unexpectedly slight. Not surprisingly, the performance of dominant markers at paternity exclusion is, in general, greatly exceeded by codominant markers, with the exception of the case in which the frequency of the recessive allele is high at all loci. In this case, codominant markers perform only slightly better than do dominant markers. Thus, a researcher should expect to score more than 50 RAPD loci for each offspring for most applications of paternity exclusion analysis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Impact of candidate sire number and sire relatedness on DNA polymorphism-based measures of exclusion probability and probability of unambiguous parentage

Genetic paternity testing can provide sire identity data for offspring when females have been exposed to multiple males. However, correct paternity assignment can be influenced by factors determined in the laboratory and by size and genetic composition of breeding groups. In the present study, DNA samples from 26 commingled beef bulls and their calves from the Nebraska Reference Herd-1 (NRH1), along with previously reported Illinois Reference/Resource Families data, were used to estimate the impact of sire number and sire relatedness on microsatellite-based paternity testing. Assay performance was measured by exclusion probabilities and probabilities of unambiguous parentage (PUP) were derived. Proportion of calves with unambiguous parentage (PCUP) was also calculated to provide a readily understandable whole-herd measure of unambiguous paternity assignment. For NRH1, theoretical and observed PCUP values were in close agreement (85.3 and 85.8%, respectively) indicating good predictive value. While the qualitative effects on PUP values of altering sire number and sire relatedness were generally predictable, we demonstrate that the impacts of these variables, and their interaction effects, can be large, are non-linear, and are quantitatively distinct for different combinations of sire number and degree of sire relatedness. In view of the potentially complex dynamics and practical consequences of these relationships in both research and animal production settings, we suggest that a priori estimation of the quantitative impact of a given set of interacting breeding group-specific and assay-specific parameters on PUP may be indicated, particularly when candidate sire pools are large, sire relatedness may be high, and/or loci numbers or heterozygosity values may be limiting.     

Ten polymorphic microsatellite DNA loci for paternity and population genetics analysis in the fen raft spider (Dolomedes plantarius)

Ten polymorphic di‐ and trinucleotide microsatellite loci were developed in the fen raft spider Dolomedes plantarius from a partial phagemid genomic library enriched for microsatellite inserts. The expected heterozygosity at these loci ranges from 0.62 to 0.9, with the observed allele numbers varying from four to 15 in the 22 individuals tested. Average paternity exclusion probabilities ranged between 0.290 and 0.686. In combination, the 10 polymorphic loci elicit an exclusion probability of 0.999. The high level of polymorphism of these microsatellite loci makes them ideal genetic markers for paternity and population genetics analysis in this endangered species.     

应用微卫星分型进行小熊猫亲子鉴定

小熊猫栖息于喜马拉雅与横断山脉,是亚洲濒危物种。中国的小熊猫谱系已登记圈养小熊猫个体９６８ 只,现有存活个体３５５ 只（２０１３ 年）,然而,现有谱系中存在部分信息不明确的问题。为此,我们选择１９ 对小熊猫特异性引物对４１ 只圈养小熊猫进行微卫星扩增,并分析其亲缘关系。将获取的亲子鉴定结果,结合种群原始记录信息,利用Pedigraph 软件构建福州圈养小熊猫的种群遗传谱系图。结果表明：在母子关系确实的情况下,１９个基因座位的联合父权排除概率为０. ９９９９９９６８;利用６ 个已知双亲的后代检验１９ 个基因座位的可信度,后代与双亲的基因型完全符合孟德尔遗传定律,表明１９个基因座位能有效确认小熊猫的亲权关系。应用１９ 个微卫星标记成功地为１５ 个后代找到了生物学父亲。尽管一些雌性个体在繁殖期有多重交配的行为,亲子鉴定的结果显示同一窝小熊猫均来自单一父权。基因型比对结果表明７ 对双胞胎均属于异卵双生子。福州种群的后代中除＃９２０和＃９２１ 外,其余均源于＃４８７ 或＃８９８ 两只雄性,表明不同个体参与繁殖的机会不均等。因此,利用现代繁殖技术,加强濒危野动物种群管理,科学制定繁殖计划具有积极的现实意义。     

Paternity assessment in wild groups of toque macaques Macaca sinica at Polonnaruwa, Sri Lanka using molecular markers

Genetic variation at four microsatellite loci in conjunction with that at a highly variable allozyme locus was used to analyse paternity over a 12-year period in 13 social groups of toque macaques Macaca sinica inhabiting a natural forest in Polonnaruwa, Sri Lanka. Paternity exclusion analysis revealed that the set of offspring produced by a female usually consists of half-siblings because few males father more than one offspring with a particular female. No evidence of offspring produced by matings between first degree relatives was found. The social unit in toque macaques was not identical to the reproductive unit and the possibility of paternity by males outside the social group should be considered when estimating male reproductive output. Although it was common for multiple males to father offspring in a social group each year, reproduction within a group during a breeding season tended to be limited to a few males. The mean number of males reproducing per group per year was independent of the number of males in a group. The paternity data suggests that many males may father relatively few offspring during their entire lives and that the effective population size for toque macaques may be much smaller than indicated by demographic data.     

Isolation and characterization of novel microsatellite loci for parentage assessment in the lance‐tailed manakin (Chiroxiphia lanceolata)

The lance‐tailed manakin (Chiroxiphia lanceolata) is a lek‐breeding bird from Central America in which males court females with complex cooperative displays. To resolve detailed patterns of paternity in the wild, we isolated and characterized 12 novel microsatellite loci in this species. Eleven of these loci were polymorphic (five to 14 alleles), with observed heterozygosities ranging from 0.36 to 0.87 (N = 574 individuals). We tested for linkage disequilibrium using randomized subsamples of adults to control for known family structure among long‐lived and sedentary individuals. These loci will be valuable in resolving paternity among many candidate fathers in this species.     

Statistical confidence for likelihood-based paternity inference in natural populations

Paternity inference using highly polymorphic codominant markers is becoming common in the study of natural populations. However, multiple males are often found to be genetically compatible with each offspring tested, even when the probability of excluding an unrelated male is high. While various methods exist for evaluating the likelihood of paternity of each nonexcluded male, interpreting these likelihoods has hitherto been difficult, and no method takes account of the incomplete sampling and error-prone genetic data typical of large-scale studies of natural systems. We derive likelihood ratios for paternity inference with codominant markers taking account of typing error, and define a statistic Δ for resolving paternity. Using allele frequencies from the study population in question, a simulation program generates criteria for Δ that permit assignment of paternity to the most likely male with a known level of statistical confidence. The simulation takes account of the number of candidate males, the proportion of males that are sampled and gaps and errors in genetic data. We explore the potentially confounding effect of relatives and show that the method is robust to their presence under commonly encountered conditions. The method is demonstrated using genetic data from the intensively studied red deer ( Cervus elaphus ) population on the island of Rum, Scotland. The Windows-based computer program, CERVUS , described in this study is available from the authors. CERVUS can be used to calculate allele frequencies, run simulations and perform parentage analysis using data from all types of codominant markers.     

栲树微卫星分子标记的开发

采用基因组DNA富集法FIASCO对我国典型常绿阔叶林建群种栲树(Castanopsis fargesii Franch.)进行了微卫星分子标记的开发。从栲树基因组中分离和筛选了15个微卫星位点,并对江西九连山栲树自然分布居群的遗传多样性进行了分析。结果表明,栲树具有较高水平的遗传多样性,每个位点在28株栲树个体上的平均等位基因数(A)为6.7(4～8个),平均观察杂合度(HO)为0.690(0.250～1.000),平均预期杂合度(HE)为0.698(0.293～0.867)。每个位点的第一排除概率值Pr(Ex1)为0.043～0.527,位点综合值为0.9972。单个位点的第二排除概率Pr(EX2)为0.159～0.694,位点综合值为0.9999。这些微卫星标记可为研究栲树的遗传多样性及居群遗传结构提供有效的遗传工具。     

Genetic kinship and social structure in a herd of square‐lipped rhinoceroses (Ceratotherium simum simum) at the zoological center,Tel Aviv/Ramat‐Gan,Israel

Zoos and zoological parks serve as genetic and demographic reserves for strengthening endangered populations and reestablishing extinct populations in the wild. Knowing the genetic ties within captive populations is a very helpful tool for successful reproductive management. In the present study we addressed kinship relationships and behavior among rhinoceroses (Ceratotherium simum simum) raised at the Zoological Center, Tel Aviv/Ramat Gan, Israel, with the hope of identifying reasons for the declining rate of reproduction within the herd. We used the random amplified polymorphic DNA (RAPD) technique to reveal the paternity of the rhinos born at the park. In this way, we identified the paternity of five out of seven young born in the herd, which are currently in Ramat Gan. One male accounted for three (37.5%) births, and two other males accounted for one each. The paternity of the two other animals is unknown and may be of animals that are no longer in the Zoological Center. The genetic determinations were accompanied by behavioral observations, which enabled us to determine the social dynamics in the herd. This study suggests that there are at least three contributing factors to the reproductive decline in the herd: 1) a surplus of males, 2) exclusion of potentially reproductive males from the breeding stock, and 3) specific behavioral and physiological problems in some members of the herd. Zoo Biol 21:561–571, 2002. © 2002 Wiley‐Liss, Inc.     

Molecular genetic insights on cheetah (Acinonyx jubatus) ecology and conservation in Namibia

The extent and geographic patterns of molecular genetic diversity of the largest remaining free-ranging cheetah population were described in a survey of 313 individuals from throughout Namibia. Levels of relatedness, including paternity/maternity (parentage), were assessed across all individuals using 19 polymorphic microsatellite loci, and unrelated cheetahs (n = 89) from 7 regions were genotyped at 38 loci to document broad geographical patterns. There was limited differentiation among regions, evidence that this is a generally panmictic population. Measures of genetic variation were similar among all regions and were comparable with Eastern African cheetah populations. Parentage analyses confirmed several observations based on field studies, including 21 of 23 previously hypothesized family groups, 40 probable parent/offspring pairs, and 8 sibling groups. These results also verified the successful integration and reproduction of several cheetahs following natural dispersal or translocation. Animals within social groups (family groups, male coalitions, or sibling groups) were generally related. Within the main study area, radio-collared female cheetahs were more closely interrelated than similarly compared males, a pattern consistent with greater male dispersal. The long-term maintenance of current patterns of genetic variation in Namibia depends on retaining habitat characteristics that promote natural dispersal and gene flow of cheetahs.     

Predominance of single paternity in the black spiny-tailed iguana: conservation genetic concerns for female-biased hunting

Because of female-biased illegal harvesting, knowledge about the genetic mating system of the black spiny-tailed iguana Ctenosaura pectinata is of primary interest for the conservation of this threatened species. Based on the high levels of multiple paternity found in clutches of many other reptiles, particularly in lizards, it is hypothesised that multiple paternity may also be common in black iguanas. This was investigated by using microsatellite DNA to estimate the number of males siring nine litters (9 mothers, 121 offspring genotyped at ten polymorphic loci) of black iguanas. Contrary to expectations, only 11% of sampled black iguana females produced litters consistent with being sired by multiple males. These data are the first evidence for the predominance of single paternity within an iguanid lizard, and suggest that black iguana may be more susceptible to loss of genetic variation in the face of gender-biased over-hunting pressure than previously thought.     

DNA “fingerprinting” and the genetic management of a captive chimpanzee population (Pan troglodytes)

DNA fingerprinting probes are cloned sequences which simultaneously detect a large number of similar hypervariable loci in the target DNA. The resulting highly polymorphic pattern visualized on an autoradiograph allows resolution of questions concerning individual identification and parentage. M13 bacteriophage has been used as a DNA fingerprinting probe for paternity ascertainment among captive chimpanzees housed in multi-male groups as part of the National Chimpanzee Breeding and Research Program. In 31 cases of unknown paternity where DNA samples for mother, offspring, and all potential sires were available, DNA fingerprinting with M13 resulted in the unambiguous assignment of paternity for all 31 infants. Knowledge of pedigrees among the captive-born animals is used to address several issues important in the genetic management of captive breeding colonies, including estimation of effective population size and of the rate of decline in genetic variability, variance in male and female reproduction, and the effect of social dominance on male reproductive success. Our analysis demonstrates the beneficial effects of genetic management by comparing the managed dedicated cohort to the Bastrop colony as a whole.     

Exclusion probabilities for single-locus paternity analysis when related males compete for matings

The statistical power of single-locus paternity analyses has previously been assessed by calculating an expected exclusion probability ( E ), the probability of excluding a randomly chosen nonfather. This E -statistic assumes that putative sires are a random selection of individuals from a panmictic study population. In species that display male natal philopatry, closely related individuals may be the principal competitors for paternity. In such structured populations, the E statistic will overestimate exclusion probability because males competing for paternity are more closely related than males chosen randomly from the population. A suite of loci thought to be sufficient for a panmictic population may frequently incorrectly assign paternity to close relatives of true sires. This study provides equations for calculating the expected probability of excluding a close male relative of the genetic sire ( Erel ) for any genotyping system that uses codominant markers. We also describe the use of Monte Carlo modelling to estimate exclusion probabilities when multiple male relatives compete for paternity. We show that the utility of a set of codominant markers will depend on the breeding behaviour and social system of the species in question.     

Polymorphic microsatellite loci and low-invasive DNA sampling inMacaca cyclopis

Polymorphic genetic markers and methods for DNA sampling in the field are the basic requirements for studies on population and conservation genetics of wildMacaca cyclopis. In this paper we screened microsatellites for their polymorphism and accessed the validity in paternity identification and gene typing of DNA samples from various sources. Among the 36 primer sets tested, 21 are polymorphic with an average observed heterozygosity 0.56. All theeight loci examined for a parent-offspring triad followed Medelian inheritance. Application of the two most polymorphic loci in paternity identification of a daptive group showed that the top-ranking male sired all the juveniles. DNA samples from wound and menstrual bleeding, or from ejaculates and hairs produced concordant microsatellite banding patterns for specific individuals. The success in DNA extraction from samples collected low-invasively and the polymorphic loci screened in this study can be applied in future studies on population and conservation genetics of natural primate populations.