Variability of allozyme and cpSSR markers in the populations of Siberian spruce

The variability of 21 allozyme and three microsatellite loci of chloroplast DNA (cpDNA) was studied in the populations of Siberian spruce (Picea obovata Ledeb.) from Irkutsk oblast, Magadan oblast, Buryatia, and Mongolia. It was demonstrated that the highest level of genetic diversity among the examined populations at both allozyme and microsatellite loci was observed in the Tulyushka population from Irkutsk oblast. The lowest level of genetic diversity was observed in marginal isolated populations of Bogd Uul and Magadan. In the relict spruce population from Olkhon Island, differing from the other populations in the lowest allelic diversity of both types of markers, no expected decline of expected heterozygosity and haplotype diversity was observed. In this population, the variability parameters mentioned were close to the population mean. The obtained intrapopulation and intraspecific variability parameters of allozyme and microsatellite loci of chloroplast DNA and the data on the population differentiation at these loci indicate that the given markers can be used for the analysis of the population structure of Siberian spruce.     

Genetics of the Shimokita macaque population suggest an ancient bottleneck

The macaque population of the Shimokita Peninsula represents the northernmost distribution of this species and is isolated from other populations in the Tohoku region of Japan. A previous protein-based study revealed a high level of genetic variability in this population and considerable differentiation from other populations. In order to reassess the genetic features of the Shimokita macaques, we examined 11 autosomal microsatellite loci and three Y chromosomal microsatellite loci. We observed considerable differentiation from other Japanese populations of macaques, but in contrast to the previous results, we observed significantly lower genetic variability in this population. There was a weak indication of a population bottleneck, suggesting a decay over time from an excess of heterozygotes that might be expected in the initial stages of a bottleneck. This may indicate that an ancient bottleneck occurred during the warm period after the last glacial period rather than a recent bottleneck due to hunting in modern times. The frequencies of private alleles were exceptionally high in the Shimokita population, suggesting that the difference in variability as determined in various studies was due to accidental sampling of marker loci with low power to resolve genetic variations in the protein-based studies. The assessments of interpopulation differentiation as determined using autosomal and Y chromosomal markers were highly correlated, and using both types of markers the Shimokita population was found to be the most differentiated of the study populations, probably due to infrequent gene flow with surrounding populations.     

Evaluation of factors affecting individual assignment precision using microsatellite data from horse breeds and simulated breed crosses

Assignment tests have been utilized to investigate population classification, measure genetic diversity and to solve forensic questions. Using microsatellite data from 26 loci genotyped in eight horse breeds we examined how population differentiation, number of scored loci, number of scored animals per breed and loci variability affected individual assignment precision applying log likelihood methods. We found that both genetic differentiation and number of scored loci were highly important for recognizing the breed of origin. When comparing two and two breeds, a proportion of 95% of the most differentiated breeds (0.200 < or = FST < or = 0.259) could be identified scoring only three loci, while the corresponding number was six for the least differentiated breeds (0.080 < or = FST < or = 0.139). An identical proportion of simulated breed crosses, differentiated from their parental breeds by FST estimates in the range 0.050-0.069, was identified when scoring 12 loci. This level of source identification was not obtained for the less differentiated breed crosses. The current data further suggested that population sample size and locus variability were not critical for the assignment precision as long as moderately large sample sizes (> or = 20 animals per population) and fairly variable loci were used.     

Population genetic structure of the sidespot barb,Barbus neefi,from the north-eastern escarpment,South Africa

Allozyme analysis was used to determine patterns of genetic variation within and between populations of Barbus neefi. The products of 29 loci were analysed, with 17 loci being monomorphic in all populations. The genetic variability estimates compared well with values reported in the literature. The percentage of polymorphic loci (0.95 criterion) ranged from 0–20.69% and average expected heterozygosity from 0.004–0.069. Headstream populations generally revealed lower genetic variability than populations in low lying areas, which emphasizes the importance of conserving headstream populations. Fixed allele mobility differences were observed at the MPI-1 protein coding locus between the Selons River population and the other populations. The measures of genetic differentiation as assessed by F-statistics, the effective number of migrants per generation and Nei's unbiased genetic distance consistently separated the Selons River population from the rest. Nevertheless, these estimates all fell within the range considered for conspecific populations. There was also a clear genetic division between populations from north and south of the Olifants River. The three populations from the Dorps, Spekboom and Blyde Rivers (Limpopo River system) and the population from the Crocodile River (Incomati River system) showed negligible genetic differentiation. Human-assisted transfer of populations may be responsible for this close similarity.     

New polymorphic microsatellite markers in Pacific abalone Haliotis discus hannai and their application to genetic characterization of wild and aquaculture populations

Seven new microsatellite markers were developed for the Pacific abalone (Haliotis discus hannai, Haliotidae), and allelic variability was compared between a wild population and a hatchery population in Yeosu, Korea. All loci amplified readily and demonstrated allelic variability, with the number of alleles ranging from 6 to 15 in the wild population and from 3 to 12 in farmed populations. Average observed and expected heterozygosities were estimated at 0.65 and 0.77 in the hatchery samples, and 0.79 and 0.87 in the wild samples. These results indicated lower genetic variability in the hatchery population, as compared with the wild population and significant genetic differentiation between the wild population and the hatchery samples (F _ST=0.055, p<0.001). These microsatellite loci may be valuable for future population genetic studies and for tracking hatchery samples used in stock enhancement programs.     

Rate and directionality of mutations and effects of allele size constraints at anonymous, gene-associated, and disease-causing trinucleotide loci.

We studied the patterns of within- and between-population variation at 29 trinucleotide loci in a random sample of 200 healthy individuals from four diverse populations: Germans, Nigerians, Chinese, and New Guinea highlanders. The loci were grouped as disease-causing (seven loci with CAG repeats), gene-associated (seven loci with CAG/CCG repeats and eight loci with AAT repeats), or anonymous (seven loci with AAT repeats). We used heterozygosity and variance of allele size (expressed in units of repeat counts) as measures of within-population variability and GST (based on heterozygosity as well as on allele size variance) as the measure of genetic differentiation between populations. Our observations are: (1) locus type is the major significant factor for differences in within-population genetic variability; (2) the disease-causing CAG repeats (in the nondisease range of repeat counts) have the highest within-population variation, followed by the AAT-repeat anonymous loci, the AAT-repeat gene-associated loci, and the CAG/CTG-repeat gene-associated loci; (3) an imbalance index beta, the ratio of the estimates of the product of effective population size and mutation rate based on allele size variance and heterozygosity, is the largest for disease-causing loci, followed by AAT- and CAG/CCG-repeat gene-associated loci and AAT-repeat anonymous loci; (4) mean allele size correlates positively with allele size variance for AAT- and CAG/CCG-repeat gene-associated loci and negatively for anonymous loci; and (5) GST is highest for the disease-causing loci. These observations are explained by specific differences of rates and patterns of mutations in these four groups of trinucleotide loci, taking into consideration the effects of the past demographic history of the modern human population.     

History vs. current demography: explaining the genetic population structure of the common frog (Rana temporaria)

The amount of genetic variability at neutral marker loci is expected to decrease, and the degree of genetic differentiation among populations to increase, as a negative function of effective population size. We assessed the patterns of genetic variability and differentiation at seven microsatellite loci in the common frog (Rana temporaria) in a hierarchical sampling scheme involving three regions (208-885 km apart), three subregions within regions and nine populations (5-20 km apart) within subregions, and related the variability and differentiation estimates to variation in local population size estimates. Genetic variability within local populations decreased significantly with increasing latitude, as well as with decreasing population size and regional site occupancy (proportion of censured localities occupied). The positive relationship between population size and genetic variability estimates was evident also when the effect of latitude (cf. colonization history) was accounted for. Significant genetic differentiation was found at all hierarchical levels, and the degree of population differentiation tended to increase with increasing latitude. Isolation by distance was evident especially at the regional sampling level, and its strength increased significantly towards the north in concordance with decreasing census and marker-based neighbourhood size estimates. These results are in line with the conjecture that the influence of current demographic factors can override the influence of historical factors on species population genetic structure. Further, the observed reductions in genetic variability and increased degree of population differentiation towards the north are in line with theoretical and empirical treatments suggesting that effective population sizes decline towards the periphery of a species' range.     

Genetic characterization of European-Zebu composite bovine using RFLP markers

A population of 370 European-Zebu composite beef heifers, consisting of six different breed compositions (A-F), were characterized genetically, using RFLP markers of luteinizing hormone receptor (LHR) and follicle-stimulating hormone receptor (FSHR) genes. Our objectives were to genetically characterize this population and to determine the structure and the genetic variability of this hybrid herd. The genotypes were determined through PCR, followed by digestion with restriction endonucleases. The PCR-RFLP analysis made it possible to identify the LHR and FSHR genotypes, as well as to characterize the degree of heterozygosis, which was high for all of the breed compositions, for both loci, except for two combinations for LHR (B and C). The observed heterozygosity (Ho) was lower than the expected heterozygosity (He) for compositions C (for LHR) and A and D (for FSHR); however, for the population as a whole, Ho was above He (with a mean of 57 versus 46%, respectively), reflecting the elevated genetic variability in this population and also the informative value of the RFLP markers, which could be useful for population genetic characterization studies. The analysis of the degree of genetic structure of this population, estimated by the Nei's statistic, for both loci, indicated an elevated total genetic diversity (HT = 47%), with most of this variability being due to intrapopulational diversity (HS = 46%), with a low degree of genetic differentiation among the six breed compositions (GST = 1.2%). The estimates generated by the Wright's F statistic indicated a non-endogamic population, with excess heterozygotes (FIT = -0.22), which was also observed at the intrapopulational level (FIS = -0.23). The results gave evidence that the genetic selection applied to this European-Zebu composite population did not affect the expected high genetic variability for this type of crossbreeding, which makes it possible to use these animals to obtain economically valuable productive and reproductive traits.     

LOW GENIC DIFFERENTIATION AMONG ISOLATED POPULATIONS OF THE CALIFORNIA FAN PALM (WASHINGTONIA FILIFERA)

The purpose of this study was to assess the relative roles of population size and geographic isolation in determining population-genetic structure. Using electrophoretic techniques to quantify allozymic variation at 16 genetic loci, we measured genic variation within and among 16 natural populations of the California fan palm (Washingtonia filifera). Genotypes were determined for every individual in each population so that parametric values rather than sample estimates for measures of genic variability were obtained. Palm populations displayed low levels of within-population variability. The proportion of polymorphic loci and observed heterozygosity were 0.098 and 0.009 per population, respectively. Population size displayed a significant positive correlation with proportion of polymorphic loci, but not with observed heterozygosity. Low levels of genetic differentiation among populations were demonstrated by an F-statistic analysis and the computation of genetic similarity values. A hierarchical analysis of gene diversity revealed that only about 2% of the total gene diversity in W. filifera resides as among-population diversity. Climatic and geological changes since the Pliocene have eliminated widespread palm populations, and the species is presently restricted to isolated locations around the Colorado Desert. Existing populations in southern California are either relicts or recent recolonizations resulting from the dispersal of seeds from a refugium population in Baja California, Mexico. The observed patterns of low within- and low among-population genic diversity seem most consistent with a recent colonization by fan palms. It is hypothesized that stochastic processes reduced levels of genic variability in this refugium population during its formation. Dispersal of seeds from this refugium into suitable habitats in the Colorado Desert would produce populations with low variability and high genetic similarity because of their common ancestry. However, low intrapopulation variability and genetic homogeneity across populations could be the product of uniform selection pressures favoring a narrow array of specialized genotypes in either relict or colonizing populations.     

Genetic diversity and bottleneck analysis of Indian bellary sheep by microsatellite markers

Bellary sheep population variability and structure was investigated genetically utilizing FAO recommended microsatellite markers. Genetic variation at 20 microsatellite loci, population structure, and genetic bottleneck hypothesis were examined. Estimates of genetic variability such as effective number of alleles and gene diversities revealed substantial genetic variation frequently displayed by microsatellite markers. A total of 133 alleles were detected. Average polymorphism across the studied loci and expected gene diversity in the population were 1.419 ± 0.405 and 0.684 ± 0.140, respectively. No significant genotypic linkage disequilibrium was detected across population, suggesting no evidence of linkage between loci. The population was observed to be significantly differentiated into different groups, showed fairly high level of inbreeding (f = 0.253 ± 0.050) and global heterozygote deficit. Population structure analysis indicated the intermixing/introduction of unique/rare alleles in these migrating flocks. A normal L-shaped distribution of mode-shift test, non-significant heterozygosity excess on the basis of different models, as revealed from sign, standardized differences and Wilcoxon sign rank tests suggested that there was no recent bottleneck. The study revealed that even a breed with increasing population trend needs genetic management for the conservation and improvement. The text was submitted by the authors in English.     

Low level of genetic variability in European bisons (Bison bonasus) from the Bialowieza National Park in Poland

Nuclear DNA markers (microsatellites) were used to screen the genetic variability in the European bison population of the Bialowieza National Park, Poland. The species is listed as endangered and the Bialowieza population is the largest one worldwide. Many other herds were founded by individuals from Bialowieza. Out of 18 microsatellites, nine were polymorphic, five were found to be homozygous, and four loci did not amplify. No significant deviation from Hardy–Weinberg-equilibrium (HWE) was observed, and the average number of alleles was 2.3 per locus. Thus, the European bison is characterized by a very low level of genetic diversity, most likely resulting from the population decline in the nineteenth century. Nevertheless, allelic variability derived from the nine polymorphic loci established in this study allowed to identify each individual by its genotypic profile. This data is valuable for conservation plans of this impressive species, especially for the control of breeding success in these animals.     

Genetic variability within and between the troops of toque macaque,Macaca sinica,in Sri Lanka

Genetic variability within and between the troops of toque macaque in Sri Lanka was studied from a population genetical perspective. Studies were made using electrophoretical blood protein variations as markers in order to clarify the genetic characteristics of the population of this species. A total of 256 samples from 20 troops which were collected in the field in 1981 to 1982 and 1983 to 1984 were examined for 32 blood protein loci. Eleven loci, that is, Tf, Alb, TBPA, Hb-α, PHI, PGM-II, CA-I, IDH, AK, ADA, and Ch-E showed the polymorphism in one or more troops. Of these 11 loci, 7 loci, that is, Tf, TBPA, Hb-α, PHI, PGM-II, CA-I, and IDH were highly polymorphic in most troops. The genetic variability within troops were quantified as H=0.0782 in average and this value was on higher level than other primates and comparable with that of continental macaques,Macaca fascicularis, in Thailand. The genetic differentiation between troops was quantified byG _ST andF _ST and these values were relatively smaller than those of other insular macaques.     

云南红豆杉天然群体内同工酶遗传变异的研究

采用水平淀粉凝胶电泳技术,对分布于金沙江流域的云南红豆杉天然群体的10种酶系统同工酶的遗传变异进行了研究。在谱带遗传分析的基础上确定了15个酶基因座及其等位基因。其中有14个酶基因座属多态,只有一个单态基因座（ME－3）。14个多态基因座中,4个基因座遗传变异小,对该天然群体的遗传变异贡献不大,其余10个基因座遗传变异丰富,对该天然群体的遗传变异贡献大。该天然群体具有明显丰富的遗传变异性,多态基因座比率P=0.933,等位基因平均数A=2.90,平均期望杂合度He=0.290。紫杉醇含量与群体遗传变异有着密切的关系。 Abstract：Genetic variation of ten isoenzymes was studied within population of Taxus yun nanensis Cheng et L. K. Fu in the Jinsha River Valley using the method of hor izo ntal starch gel electrophoresis.On the basis of banding analysis,eight enzyme sy stems , presumablly coded by fifteen isoenzyme loci and their alleles were score d , and fourteen were polymorphic with only one monomorphic locus（ME－3）. Amon g them , four polymorphic loci with inevident genetic variation made little cont ribution to genetic variation of this population and other ten polymorphic loci with evident genetic variation made great contribution to genetic variation of this population . Isoenzyme data indicated high level of genetic variability in this population with P=0.933,A=2.90,He=0.290 . The taxol content had close r elation to genetic variation of population.     

Divergent evolution of molecular markers during laboratory adaptation in Drosophila subobscura

The impact of genetic drift in population divergence can be elucidated using replicated laboratory experiments. In the present study we used microsatellite loci to study the genetic variability and differentiation of laboratory populations of Drosophila subobscura derived from a common ancestral natural population after 49 generations in the laboratory. We found substantial genetic variability in all our populations. The high levels of genetic variability, similar across replicated populations, suggest that careful maintenance procedures can efficiently reduce the loss of genetic variability in captive populations undergoing adaptation, even without applying active management procedures with conservation purposes, in organisms that generate a high number of offspring such as Drosophila. Nevertheless, there was a significant genetic differentiation between replicated populations. This shows the importance of genetic drift, acting through changes in allele frequencies among populations, even when major changes in the degree of genetic diversity in each population are not involved.     

Genetic population structure in olive fly Bactrocera oleae (Gmelin): gene flow and patterns of geographic differentiation

Four wild Spanish populations of Bactrocera oleae (Gmelin) (Dipt., Tephritidae) were studied by gel electrophoresis, in order to find out their population genetic structure and the relative importance of gene flow in that structure. A great amount of genetic variability was observed. In terms of the pattern of the genetic variability in our populations, the most noticeable characteristics were the similarity of the configuration of allelic frequencies from locality to locality, the existence of exceptions and quantitative differences within that similarity, and the heterogeneity among the variable loci. Gene flow estimated from Wright's method gave a value of Nm = 8.9. However, the F _ST statistic in three of the loci ranged from 0.0451 to 0.0620 indicating a substantial degree of differentiation among populations (P < 0.001). The present observations seem to support the hypothesis that although gene flow could be high ( Nm = 8.9), 'natural' selection, probably due to agricultural practices, may be the major factor responsible for the pattern of the genetic variability observed in B. oleae .     

Microsatellite Polymorphisms in Cassava Landraces from the Cerrado Biome, Mato Grosso do Sul, Brazil

Using nine microsatellite loci, we investigated genetic structure and diversity in 83 Brazilian cassava accessions, including several landraces, in the Cerrado biome in Mato Grosso do Sul, Brazil. All nine loci were polymorphic, averaging 6.00 alleles per locus. Treating each of seven municipalities as a cassava group or population, they averaged 3.5 alleles per locus, with 97% polymorphic loci, high values for observed heterozygosity (0.32) and gene diversity (0.56). Total genetic variability was high (0.668), and most of this genetic variability was concentrated within municipalities (0.577). Cluster and structure analyses divided accessions into two major clusters or populations (K = 2). Also, a significant genetic versus geographic correlation was found (r = 0.4567; P < 0.0260). Migratory routes in the Cerrado are considered main contributors to the region’s high cassava diversity and spatial genetic structure, amplifying interactions between traditional farmers and the evolutionary dynamics of this crop.     

D17S30 and TP53 VNTR loci polymorphisms in a Turkish population

VNTR loci are useful as genetic markers in population genetics, forensics, and chimerism detection because of their high level of variability. In this study we present frequency information for two polymorphic VNTR loci, namely, D17S30 and TP53, which we examined in 100 healthy individuals from a Turkish population.     

Microevolution in Solatopupa landsnails (Pulmonata Chondrinidae): genetic diversity and founder effects

Enzyme variability at 28 presumptive gene loci was studied, by standard starch gel electrophoresis, in 30 populations belonging to the five recognized species of the landsnail Solatopupa from its entire NW Mediterranean range.
Six genetically differentiated groups can be identified among the 30 populations sampled. These are distinguished by two to 19 diagnostic loci, different levels of genetic variability and populations genetics. They are also significantly different as far as the D values are considered. There is no evidence of gene flow among them. Genetically inferred groups correspond in four cases to morphologically distinguished species. In contrast, S. similis , as identified by morphological features, is likely to be a complex of at least two cryptic species.
Populations and species of Solatopupa are characterized by: high fixation of alternative alleles both within and between species; medium-lo-low levels of genie variation; heterozygote deficiency; sharp genetic differentiation among population within species; restricted gene flow; and high genetic distances. Genetic variability is partly associated with climatic factors related to moisture.
Both deterministic and stochastic processes may play a part in the genetic differentiation of Solatopupa snails. Founder events seem to be the main factor affecting the genetic structure of populations and perhaps also speciation. Solatopupa populations display many attributes of populations that may be expected to undergo speciation events involving reorganization of the whole genome after a founder event.     

Evaluating the effects of historic bottleneck events: an assessment of microsatellite variability in the endangered,North Atlantic right whale

Commercial exploitation reduced the North Atlantic right whale (Eubalaena glacialis) population from c. 12,000 in the 11th century to around 300 by the 21st century. We examine the effect of this population decline on levels of genetic variation at 16 microsatellite loci and contrast levels of variability to that in a closely related species (E. australis). Of the 13 loci developed from the E. glacialis genome, 100% were polymorphic in E. australis. In contrast, nine loci were polymorphic in E. glacialis and four were fixed. Both allelic diversity (A) and heterozygosity (H) were significantly lower in E. glacialis than E. australis (A = 3.2 +/- 2.6 vs. A= 6.9 +/- 3.3, P < 0.001; H= 0.31 +/- 0.25 vs. H= 0.72 +/- 0.23, P < 0.001, respectively). Bottleneck anlayses indicate that the population is in mutation-drift equilibrium and that a genetic bottleneck did not occur during the most recent decline (18th-20th centuries). Nevertheless, low frequency alleles are relatively uncommon in E. glacialis, suggesting that genetic variability has been reduced in this population. Possible origins of low genetic variability are discussed, including the slow but continual erosion of alleles during the 800-year period of decline.     

GENETIC STRUCTURE OF NORWAY SPRUCE (PICEA ABIES): CONCORDANCE OF MORPHOLOGICAL AND ALLOZYMIC VARIATION

This study describes the population structure of Norway spruce (Picea abies) as revealed by protein polymorphisms and morphological variation. Electrophoretically detectable genetic variability was examined at 22 protein loci in 70 populations from the natural range of the species in Europe. Like other conifers, Norway spruce exhibits a relatively large amount of genetic variability and little differentiation among populations. Sixteen polymorphic loci (73%) segregate for a total of 51 alleles, and average heterozygosity per population is 0.115. Approximately 5% of the total genetic diversity is explained by differences between populations (G_ST = 0.052), and Nei's standard genetic distance is less than 0.04 in all cases. We suggest that the population structure largely reflects relatively recent historical events related to the last glaciation and that Norway spruce is still in a process of adaptation and differentiation. There is a clear geographic pattern in the variation of allele frequencies. A major part of the allelefrequency variation can be accounted for by a few synthetic variables (principal components), and 80% of the variation of the first principal component is “explained” by latitude and longitude. The central European populations are consistently depauperate of genetic variability, most likely as an effect of severe restrictions of population size during the last glaciation. The pattern of differentiation at protein loci is very similar to that observed for seven morphological traits examined. This similarity suggests that the same evolutionary forces have acted upon both sets of characters.