Genetic variation in caribou and reindeer (Rangifer tarandus)

Genetic variation at seven microsatellite DNA loci was quantified in 19 herds of wild caribou and domestic reindeer (Rangifer tarandus) from North America, Scandinavia and Russia. There is an average of 2.0-6.6 alleles per locus and observed individual heterozygosity of 0.33-0.50 in most herds. A herd on Svalbard Island, Scandinavia, is an exception, with relatively few alleles and low heterozygosity. The Central Arctic, Western Arctic and Porcupine River caribou herds in Alaska have similar allele frequencies and comprise one breeding population. Domestic reindeer in Alaska originated from transplants from Siberia, Russia, more than 100 years ago. Reindeer in Alaska and Siberia have different allele frequencies at several loci, but a relatively low level of genetic differentiation. Wild caribou and domestic reindeer in Alaska have significantly different allele frequencies at the seven loci, indicating that gene flow between reindeer and caribou in Alaska has been limited.     

Genetic variation in domestic reindeer and wild caribou in Alaska

Reindeer ( Rangifer tarandus tarandus ) were introduced into Alaska 100 years ago and have been maintained as semidomestic livestock. They have had contact with wild caribou ( R. t. granti ) herds, including deliberate crossbreeding and mixing in the wild. Reindeer have considerable potential as a domestic animal for meat or velvet antler production, and wild caribou are important to subsistence and sport hunters. Our objective was to quantify the genetic relationships of reindeer and caribou in Alaska. We identified allelic variation among five herds of wild caribou and three herds of reindeer with DNA sequencing and restriction enzymes for three loci: a DQA locus of the major histocompatibility complex ( Rata-DQA1 ), K-casein and the D-loop of mitochondrial DNA. These loci are of interest because of their potential influence on domestic animal performance and the fitness of wild populations. There is considerable genetic variation in reindeer and caribou for all three loci, including five, three and six alleles for DQA , K-casein and D-loop respectively. Most alleles occur in both reindeer and caribou, which may be the result of recent common ancestry or genetic introgression in either direction. However, allele frequencies differ considerably between reindeer and caribou, which suggests that gene flow has been limited.     

Enzyme polymorphism in Schistosoma mattheei from cattle in the Eastern Transvaal Lowveld

Enzyme electrophoresis was conducted on 10 Schistosoma mattheei adult worm samples, comprising 270 individuals, collected from cattle in the Eastern Transvaal Lowveld. Glucose-6-phosphate dehydrogenase (G6PDH) was studied in all the samples and phosphoglucomutase (PGM) and malate dehydrogenase (MDH) in five populations each. Only one population was polymorphic for G6PDH. In this population, in addition to the allele found in all the other samples, a second allele occurred with a similar Rf value to S. haematobium. The two alleles were in Hardy-Weinberg equilibrium. MDH-1 exhibited two alleles. However, these alleles were not in equilibrium. In certain populations, heterozygotes occurred together with homozygotes of one of the alleles only. PGM was monomorphic in all the populations studied.     

Mitochondrial DNA and microsatellite DNA variation in domestic reindeer (Rangifer tarandus tarandus) and relationships with wild caribou (Rangifer tarandus granti, Rangifer tarandus groenlandicus, and Rangifer tarandus caribou)

Reindeer (Rangifer tarandus tarandus) in Alaska are semidomestic livestock descended from 1280 animals introduced from Siberia, Russia, approximately 100 years ago. Genetic variation at 18 microsatellite DNA loci and the cytochrome b gene of mitochondrial DNA (mtDNA) was quantified in reindeer from Alaska, Siberia (Russia), and Scandinavia and compared with wild North American caribou. Mean sequence divergence among 15 mtDNA haplotypes in reindeer was 0.007 substitutions per nucleotide site, and reindeer mtDNA is polyphyletic with caribou mtDNA. Microsatellite allele and mtDNA haplotype frequencies are similar between Alaskan and Russian reindeer and differentiated between these and Scandinavian reindeer. The frequencies of microsatellite alleles and mtDNA haplotypes are different in reindeer and wild caribou (Rangifer tarandus granti, Rangifer tarandus groenlandicus, and Rangifer tarandus caribou). Alaskan reindeer have maintained a genetic variation comparable to that in Russia and differentiated from that of wild caribou, >100 years after their introduction to Alaska.     

Population and Family Studies of the CAG Repeats in the IT-15Gene

A simple and effective method for typing of CAG repeats in the IT-15gene has been suggested. This method was applied for examination of the CAG allele distribution in Huntington's disease (HD) patients in five different populations from the Commonwealth of Independent States. A total of 21 normal alleles with the sizes ranging from 9 to 32 triplet repeats units were revealed. Moreover, alleles with the sizes ranging from 16 to 20 repeats predominated constituting from 54.4 to 74.6% of all alleles in different populations. The number of repeats in one allele in HD patients exceeded 38 units (43 triplets on average). In two families an increase in the CAG repeat units number in the mutant allele upon its paternal transmission was recorded.     

Population and family studies of CAG repeats in the IT-15 gene

A simple and effective method for typing of CAG repeats in the IT-15 gene has been suggested. This method was applied for examination of the CAG allele distribution in Huntington's disease (HD) patients in five different populations from the Commonwealth of Independent States. A total of 21 normal alleles with the sizes ranging from 9 to 32 triplet repeat units were revealed. Moreover, alleles with the size ranging from 16 to 20 repeats predominated constituting from 54.4 to 74.6% of all alleles in different populations. The number of repeats in one allele in HD patients exceeded 38 units (43 triplets on average). In two families an increase in the CAG repeat units number in the mutant allele upon its paternal transmission was recorded.     

Polymorphism of the mtDNA control region in wild reindeer Rangifer tarandus (Mammalia: Artioodactyla) from the European part of Russia

Genetic diversity of wild reindeer (Rangifer tarandus) inhabiting the European part of Russia, including Komi Republic, Arkhangelsk oblast, Murmansk oblast, and the Republic of Karelia was characterized using sequence polymorphism of the mtDNA control region. Despite of currently low population number of wild reindeer, they were characterized by a high level of genetic diversity (?? = 0.018; H = 0.872 to 0.914). Phylogenetic analysis showed close relationships between European reindeer and wild reindeer of Siberia. In reindeer from Murmansk oblast a haplotype in common with the wild reindeer form Southwestern Norway was described. The reindeer sample examined contained no haplotypes earlier described for the reindeer of Central Norway. It is suggested that in recent past wild reindeer from the European north of Russia formed one population with the reindeer from the north of the Asian part of Eurasia.     

Functional microsatellite and possible selective sweep in natural populations of the black-chinned tilapia Sarotherodon melanotheron (Teleostei, Cichlidae)

The Prolactin I (PrlI) gene is a key locus involved in fish osmotic regulation. Two microsatellites, PrlI GT and PrlI AC, are present in the promoter region of this gene in tilapias. One of these microsatellite is associated to PrlI gene expression and growth rate. Aquaria reared individuals homozygous for long microsatellite alleles at the PrlI AC locus expressed less PrlI in fresh water than fishes with other genotypes. To assess the occurrence of selection acting on these microsatellites we carried out a survey of their variability compared with four others microsatellites in natural populations. Samples of two tilapia species were studied, Oreochromis niloticus (6 samples) a typically freshwater species inhabiting osmotically stable environments and Sarotherodon melanotheron (5 samples) a brackish water species obliged and able to adapt very rapidly to any salinity changes. For both species the different populations studied exhibited a high amount of differentiation (all F(st) value were statistically significant) at every loci. Only one locus, PrlI AC, was monomorphic for the same allele in all S. melanotheron populations. We have hypothesized that this outlier locus with its unique allele could have experienced a selective sweep that took place in the early stages of the species origin. S. melanotheron represents an example of adaptation (to fluctuant salinity environment) acting indirectly on gene product through its promoter.     

Analysis of polymorphism of CTG repetitive sequences in the gene of myotonic dystrophy in human populations of the Volga-Ural region]

Distribution of CTG repetitive sequences in the myotonic dystrophy (MD) gene was analyzed in ten populations of the Volga-Ural region, including Tatars, Chuvashes, Maris, Udmurts, Mordovians, Komis, and four ethnogeographical groups of Bashkirs. A total of 25 alleles were found (9 to 14 in individual populations), with each allele containing 5 to 34 trinucleotide repeats. The allele frequency distribution had two peaks corresponding to alleles with 5 and 11-14 CTG repeats. The frequency of the (CTG)5 allele varied from 0.23 to 0.47 in Maris and Mordovians, respectively. Regarding the (CTG)11-14 alleles, those containing 13 and 12 trinucleotides were most frequent in all populations; their frequencies varied from 0.15 in Mordovians to 0.24 in Maris and Bashkirs from the Abzelilovskii raion (district). Alleles with large numbers of repeats (more than 30) were only found in Tatars and Bashkirs from the Abzelilovskii raion, where their frequency was 0.01. The data obtained were compared with those on other human populations from various regions of the world. In general, the populations of the Volga-Ural region took an intermediate position between European and Asian populations (although were somewhat more similar to the latter ones) with respect to the distribution of allelic frequencies of the CTG repetitive sequences. In individual populations, the number of genotypes varied from 13 to 27 in Mordovians and Bashkirs from the Ilishevskii raion, respectively. The observed heterozygosity was the highest (91%) in Udmurts and the lowest (58%) in Mordovians; the average heterozygosity was 81%. Such a high heterozygosity, as well as the revealed differentiation of the populations with respect to the distribution of the allelic frequencies of CTG repetitive sequences in the MD gene, allow this polymorphic DNA locus to be considered a highly informative genetic marker of populations.     

Genetic variation of the MHC DQB locus in the finless porpoise (Neophocaena phocaenoides)

The Major Histocompatibility Complex (MHC) is a large multigene coding for glycoproteins that play a key role in the initiation of immune responses in vertebrates. The exon 2 region of the MHC DQB locus was analyzed using 160 finless porpoises from 5 populations in Japanese waters. The 5 populations were based on a previous mitochondrial DNA control region analysis, which showed distinct geographical separation. Eight DQB alleles were detected, and the geographical distribution of the alleles indicated that most of them are shared among the populations. Heterozygosity of the DQB alleles in each population ranged from 0.55 to 0.78, and for all 5 populations was 0.78. Low MHC variability is not a common feature in marine mammals, but the finless porpoise populations inhabiting coastal waters had a relatively high MHC heterozygosity. Balancing selection in the MHC DQB alleles of the finless porpoise was indicated by the higher rate of nonsynonymous than synonymous substitutions for PBR; however, an excess of hetrozygotes compared to expectation was not observed. This suggests that the MHC DQB locus in the finless porpoise may have been under balancing selection for a long evolutionary time period, and is influenced by genetic drift beyond the effect of balancing selection for short time periods in small local populations.     

Color-vision polymorphism in wild capuchins (Cebus capucinus) and spider monkeys (Ateles geoffroyi) in Costa Rica

New World monkeys are unique in exhibiting a color-vision polymorphism due to an allelic variation of the red-green visual pigment gene. This makes these monkeys excellent subjects for studying the adaptive evolution of the visual system from both molecular and ecological viewpoints. However, the allele frequencies of the pigments within a natural population have not been well investigated. As a first step toward understanding the relationship between vision and behavior, we conducted color-vision typing by analyzing fecal DNA from two wild groups of white-faced capuchin monkeys (Cebus capucinus) and one group of black-handed spider monkeys (Ateles geoffroyi) inhabiting Santa Rosa National Park of Costa Rica. All color-typed monkeys were individually identified. In C. capucinus and A. geoffroyi we found three and two pigment types, respectively, and the spectral mechanism that created one of the two Ateles pigments was found to be novel. In one Cebus group and the Ateles group, all alleles were present, whereas in the other Cebus group only two alleles were found, with one allele predominating. This was likely due to the effect of close inbreeding, indicating that wild populations can exhibit a variety of allele compositions. This result also suggests that the color-vision polymorphism can be easily distorted by natural factors, such as inbreeding, skewing the population structure.     

Selective pressures on MHC class II genes in the guppy (Poecilia reticulata) as inferred by hierarchical analysis of population structure

Genes of the major histocompatibility complex, which are the most polymorphic of all vertebrate genes, are a pre‐eminent system for the study of selective pressures that arise from host–pathogen interactions. Balancing selection capable of maintaining high polymorphism should lead to the homogenization of MHC allele frequencies among populations, but there is some evidence to suggest that diversifying selection also operates on the MHC. However, the pattern of population structure observed at MHC loci is likely to depend on the spatial and/or temporal scale examined. Here, we investigated selection acting on MHC genes at different geographic scales using Venezuelan guppy populations inhabiting four regions. We found a significant correlation between MHC and microsatellite allelic richness across populations, which suggests the role of genetic drift in shaping MHC diversity. However, compared to microsatellites, more MHC variation was explained by differences between populations within larger geographic regions and less by the differences between the regions. Furthermore, among proximate populations, variation in MHC allele frequencies was significantly higher compared to microsatellites, indicating that selection acting on MHC may increase population structure at small spatial scales. However, in populations that have significantly diverged at neutral markers, the population‐genetic signature of diversifying selection may be eradicated in the long term by that of balancing selection, which acts to preserve rare alleles and thus maintain a common pool of MHC alleles.     

Mitochondrial DNA polymorphism in Tuvinian population of reindeer Rangifer tarandus L

Mitochondrial DNA variation was examined in one of the southern most populations of domestic reindeer, inhabiting Tyva Republic (Tuva). In Tuvinian population sequence polymorphism of the mitochondrial DNA D loop region was demonstrated. In a sample of 29 individuals 7 mitotypes were distinguished, pointing to the preservation of rather high level of genetic diversity in this population.     

Mitochondrial DNA polymorphism in Tuvinian population of reindeer Rangifer tarandus L.

Mitochondrial DNA variation was examined in one of the southem most populations of domestic reindeer, inhabiting Tyva Republic (Tuva). In Tuvinian population sequence polymorphism of the mitochondrial DNA D-loop region was demonstrated. In a sample of 29 individuals 7 mitotypes were distinguished, pointing to the preservation of rather high level of genetic diversity in this population.     

Population subdivision in westslope cutthroat trout (Oncorhynchus clarki lewisi) at the northern periphery of its range: evolutionary inferences and conservation implications

Westslope cutthroat trout (Oncorhynchus clarki lewisi, Salmonidae) are native to the upper Columbia, Missouri, and South Saskatchewan river drainages of western North America and are at the northern periphery of their range in southeastern British Columbia, Canada. We examined geographical variation in allele frequencies at eight microsatellite loci in 36 samples of westslope cutthroat trout from British Columbia to assess levels of population subdivision and to test the hypothesis that different habitat types (principally mainstem vs. above migration barrier habitats) would influence levels of genetic diversity, genetic divergence among populations, and attainment of equilibrium between gene flow and genetic drift. Across all samples, the mean number of alleles per locus was 3.9 and mean expected heterozygosity was 0.56. Population subdivision was extensive with an overall Fst (theta) of 0.32. Populations sampled above migration barriers had significantly fewer alleles, lower expected heterozygosity, but greater average pairwise Fst than populations sampled from mainstem localities. We found evidence for isolation-by-distance from a significant correlation between genetic distance and geographical distance (r = 0.31), but the pattern was much stronger (r = 0.51) when above barrier populations and a population that may have been involved in headwater exchanges were removed. By contrast, isolation-by-distance was not observed when only above barrier populations were tested among themselves. Our data support the maintenance of separate demographic management strategies for westslope cutthroat trout inhabiting different river systems and illustrate how differing habitat structure (e.g. presence of migration barriers) may influence patterns of biodiversity and gene flow-drift equilibrium.     

Haemochromatosis gene mutations in Finns, Swedes and Swedish Saamis

Frequencies of three different mutant haemochromatosis (HFE) alleles (282Tyr, 63Asp and 65Cys) were studied in three northern European populations, i.e. Finns, Swedes and Swedish Saamis. In Finns and Swedes the allele frequencies were within the range found in other populations from northern and western Europe. The Saamis differed from the Swedes with respect to all mutant alleles. Lower frequencies compared to Swedes were found for the 282Tyr (p = 0.0046) and 63Asp (p = 0.034) alleles, whereas the frequency of the 65Cys allele was higher (p = 0.046) in the Saamis. The total distribution of HFE alleles in Saamis showed a highly significant difference from that in Swedes (chi2 = 16.7, 3 d.f., p = 0.0008). These results further underline the genetic uniqueness of the Saamis.     

Transferrin subtypes in 11 south China minority populations.

Transferrin subtypes were determined by isoelectric focussing (IEF) in a total of 2,121 individuals from 11 South China minority populations. The C1, C2 and DCHI alleles were present in all the populations; B alleles were lacking, C4 was found in 3 populations and C3 in 6. C2 and C4 allele frequencies are notable in these minority groups. The frequency of the C2 allele was higher (0.25-0.38) than that of Han Chinese (0.18-0.25). In Bai the C2 frequency was as high as 0.38. The C4 allele was present at a low frequency (less than 0.01), which suggests that this allele probably existed in the ancestral Mongoloid population at a low frequency and increased in frequency in Amerindians due to genetic drift or other factors.     

Apparent Selection of Enzyme Alleles in Laboratory Populations of Drosophila

Twelve laboratory populations of recently collected Drosophila willistoni were begun with different frequencies of alleles at three enzyme loci, six populations at 25 degrees and six at 19 degrees . Periodic sampling of the populations allowed monitoring of the frequency changes in allozymes over time.-At Lap-5 (a locus coding for leucine amino peptidase), three alleles converged to the same frequencies in all populations at both temperatures. The apparent equilibrium frequency of the major allele was about.75; this is different from the frequency (.57) found in the natural population from which the experimental populations were begun. Allele frequency changes at the esterase-5 locus (Est-5) were slower but consistent in all cages. It is difficult to determine if an equilibrium has been reached. However, the frequency of the rare allele in all cages is about the same as in wild populations, 5%. Alleles at both Lap-5 and Est-5 are non-randomly associated with inversions in the chromosomes onto which they map. Because of these associations, it is impossible to unambiguously attribute the change in allele frequencies to selection at the loci being observed.-After one year, no significant gene frequency changes were detected at Est-7, the third locus studied.     

Geographic differences in the allele frequencies of the human Y-linked tetranucleotide polymorphism DYS19

We have studied the allele frequency distribution of the microsatellite locus DYS 19 in several populations with different geographical origins worldwide. Three new alleles were found. In addition, remarkable geographic and ethnic differences were observed in the allele frequency profiles and DNA marker (gene) diversity among populations and major ethnic groups. Amerindians showed an overwhelming predominance of the A allele, while in Caucasians the B allele was modal, and in Greater Asians and Africans allele C became predominant. Even within these geographic regions there were significant gradients, as exemplified by the decreasing frequency profile of the B allele from Great Britain over Germany to Slovakia. Thus, DYS 19 emerges as a useful tool for studying the structure and dynamics of human populations.     

Marker-assisted introgression using non-unique marker alleles II: selection on probability of presence of the introgressed allele

If marker alleles that identify a gene for introgression are not completely unique to the different base populations, the trait allele can be lost quickly during the process of backcrossing. This study considers ways to deal with incompletely informative markers in order to retain the desired allele. Selection was based on the probability of the presence of the desired (introgressed) trait allele, which was calculated for each marker genotype, using a single marker or a diallelic or triallelic marker bracket. The percentage of individuals retaining the introgressed allele was calculated over five generations of backcrossing, for selected fractions between 0 and 1, for marker alleles that could occur in both base populations. The best results were obtained with a rather large selected fraction, when all individuals, heterozygous and homozygous for the most desirable allele at the marker loci, were selected. Additional selection against marker homozygotes (which might have the highest probability of carrying the desired-trait allele, but produce uninformative gametes) altered the optimum selected fraction, making the selected fraction more consistently inversely related to a better retention of the desired-trait allele. A marker bracket was found to give a better retention of the desired-trait allele than a single marker and triallelic markers were better than diallelic markers, giving a retention of almost 50%. The earlier that preselection of parents (on informativeness) took place the better the overall result; preselection should occur preferably in the base populations. Preselection could make marker alleles unique to alternative base populations and markers would effectively become fully informative. Selection in the base populations might not be possible or not desirable, for example, because of the available number of individuals. This is unlikely to be a problem when parents are paired up to exclude any common marker alleles.