Null alleles at two lactate dehydrogenase loci in rainbow trout are associated with decreased developmental stability

Previous studies with rainbow trout (Oncorhynchus mykiss) have shown that allozymic heterozygotes have increased developmental stability, as measured by reduced fluctuating bilateral asymmetry. In this paper, we examine the phenotypic effects of null alleles at two lactate dehydrogenase (LDH) loci. If the association between allozymic heterozygosity and developmental stability is due largely to linked chromosomal segments, then we would expect null allele heterozygotes to have increased developmental stability. In contrast, heterozygotes for LDH null alleles in three populations have reduced developmental stability. This suggests that the reduction in enzyme activity at these loci is having a deleterious effect on development that is strong enough to mask any beneficial effects that may be associated with heterozygosity for these chromosomal segments. The LDH loci examined in this study are members of two different paralogous pairs of duplicate genes produced by the polyploidization of the ancestral salmonid genome. The apparent deleterious effects of these null alleles in heterozygotes could retard the possible loss of duplicate gene expression.     

Demographic Genetics of Brown Trout (Salmo Trutta) and Estimation of Effective Population Size from Temporal Change of Allele Frequencies

We studied temporal allele frequency shifts over 15 years and estimated the genetically effective size of four natural populations of brown trout (Salmo trutta L.) on the basis of the variation at 14 polymorphic allozyme loci. The allele frequency differences between consecutive cohorts were significant in all four populations. There were no indications of natural selection, and we conclude that random genetic drift is the most likely cause of temporal allele frequency shifts at the loci examined. Effective population sizes were estimated from observed allele frequency shifts among cohorts, taking into consideration the demographic characteristics of each population. The estimated effective sizes of the four populations range from 52 to 480 individuals, and we conclude that the effective size of natural brown trout populations may differ considerably among lakes that are similar in size and other apparent characteristics. In spite of their different effective sizes all four populations have similar levels of genetic variation (average heterozygosity) indicating that excessive loss of genetic variability has been retarded, most likely because of gene flow among neighboring populations.     

Loss of duplicate gene expression in salmonids: Evidence for a null allele polymorphism at the duplicate aspartate aminotransferase loci in brook trout (Salvelinus fontinalis)

Unusual phenotypic distributions at the muscle-specific, duplicate aspartate aminotransferase (AAT) loci were found in wild populations of brook trout (Salvelinus fontinalis), a species of the tetraploid-derivative Salmonidae. Analysis of these phenotypic distributions ruled out disparate gene frequencies, nonrandom association between the two loci, and inbreeding as possible explanations; however, models incorporating a null allele fit the data. Inheritance data from hatchery populations of brook trout also indicated a null allele polymorphism. This proposed AAT null allele, along with other null allele polymorphisms in salmonids, is evidence that loss of duplicate gene expression is still occurring. In contrast, there is no such evidence of ongoing loss of duplicate gene expression in the Catostomidae, another tetraploid-derivative lineage. We interpret this and other differences between salmonids and catostomids as reflecting an autotetraploid origin for salmonids and an allotetraploid origin for catostomids. The significance of these findings is also considered with respect to current models of the rate of loss of duplicate gene expression in tetraploid-derivative organisms.     

Phosphoglucose isomerase isozymes and allozymes of the brown trout, Salmo trutta L

1. In brown trout the Pgi-1 and Pgi-2 loci are predominantly expressed in white skeletal muscle; Pgi-3 being mainly expressed in most other tissues. 2. Total PGI activity determinations revealed that the allele formerly designated Pgi-2(65) is a null allele, Pgi-2(n). 3. Enzyme kinetic studies on the partially purified PGI homodimeric isozymes revealed that from 5 to 25 degrees C both PGI-1 and PGI-2 had significantly higher mean Km(F6P) values compared to PGI-3. 4. Distinct metabolic roles for the "muscle" (PGI-1, PGI-2) and "liver" (PGI-3) isozymes are proposed. 5. Significant Km (F6P) differences were found among the PGI-2 allozymes and among the PGI-3 allozymes.     

Identifying footprints of selection in stocked brown trout populations: a spatio‐temporal approach

Studies of interactions between farmed and wild salmonid fishes have suggested reduced fitness of farmed strains in the wild, but evidence for selection at the genic level is lacking. We studied three brown trout populations in Denmark which have been significantly admixed with stocked hatchery trout (19–64%), along with two hatchery strains used for stocking. The wild populations were represented by contemporary samples (2000–2006) and two of them by historical samples (1943–1956). We analysed 61 microsatellite loci, nine of which showed putative functional relationships [expressed sequence tag (EST)‐linked or quantitative trait loci]. F_ST‐based outlier tests provided support for diversifying selection at chromosome regions marked by three loci, two anonymous and one EST‐linked. Patterns of differentiation suggested that the loci were candidates for being under diversifying hitch‐hiking selection in hatchery vs. wild environments. Analysis of hatchery strain admixture proportions showed that in one wild population, two of the loci showed significantly lower admixture proportions than the putatively neutral loci, implying contemporary selection against alleles introduced by hatchery strain trout. In the most strongly admixed population, however, there was no evidence for selection, possibly because of immigration by stocked trout overcoming selection against hatchery‐derived alleles or supportive breeding practices allowing hatchery strain trout to escape natural selection. To our knowledge, this is the first study demonstrating footprints of selection in wild salmonid populations subject to spawning intrusion by farmed fish.     

Persistence time of loss-of-function mutations at nonessential loci affecting eye color in Drosophila melanogaster

Persistence time of a mutant allele, the expected number of generations before its elimination from the population, can be estimated as the ratio of the number of segregating mutations per individual over the mutation rate per generation. We screened two natural populations of Drosophila melanogaster for mutations causing clear-cut eye phenotypes and detected 25 mutant alleles, falling into 19 complementation groups, in 1164 haploid genomes, which implies 0.021 eye mutations/genome. The de novo haploid mutation rate for the same set of loci was estimated as 2 x 10(-4) in a 10-generation mutation-accumulation experiment. Thus, the average persistence time of all mutations causing clear-cut eye phenotypes is approximately 100 generations (95% confidence interval: 61-219). This estimate shows that the strength of selection against phenotypically drastic alleles of nonessential loci is close to that against recessive lethals. In both cases, deleterious alleles are apparently eliminated by selection against heterozygous individuals, which show no visible phenotypic differences from wild type.     

Genetic structure of two Turkish brown trout populations

The genetic structure of two brown trout Salmo trutta populations living in Lake Abant in Bolu and Üzüm River in Antalya was determined by examining 15 enzyme coding loci ( AAT, ADH, LDH, MDH, MEP, GPI, PGM and SOD ) using starch gel electrophoresis. Population specific mobilities were observed for the fixed alleles of LDH-B2, mMEP-2 and SOD-1 loci. Polymorphisms in sAA T-4, GPI-B2 loci were observed within the populations. Average heterozygosity of Abant and Antalya populations was 0.0358 and 0.0224 respectively. For LDH-C which is the post glaciation marker locus, the ancestral allele * 105 was found to be fixed in both of the populations. Nei's genetic distance between the two populations was 0.2507 which is the level of genetic distance often found between different species. This difference seems to be due to the presence of unique alleles in the LDH-B2, mMEP-2 and SOD-1 loci of the Abant population, indicating that the conservation of the Abant population and its heterozygosity is of prime importance.     

鳙团移核鱼LDH,MDH同工酶的研究

对二龄鳙鱼细胞核和团头鲂细胞质配合的核质杂种鱼－－鳙团移核鱼及其亲本,供核体鳙鱼和受核体团头鲂肌组织ＬＤＨ、ＭＤＨ同工酶进行了研究试验。鳙团移核鱼和供核体鳙鱼肌组织ＬＤＨ同工酶均具有ＬｄｈＡ２Ｂ２一条谱带;受核体团头鲂的则具有ＬｄｈＡ２、ＬｄｈＡ２Ｂ１、ＬｄｈＡ２Ｂ２、ＬｄｈＡ１Ｂ３、ＬｄｈＢ４等五条谱带。移核鱼和供核体鳙鱼肌组织的ＭＤＨ同工酶都各具有二条谱带：Ｓ－ｍｄｈＡ２、Ｓ－ｍｄｈＡＢ;受核     

A Highly Polymorphic Plasma Protein Locus in Brown Trout (Salmo trutta L.) Populations from Portugal

Genetic polymorphism of an unidentified plasma protein (PX) is described for the first time in Salmo trutta (L.) by means of isoelectric focusing. The analysis of 414 individuals from different geographic origins in Portugal allowed the identification of nine alleles. Heterozygosity in natural populations is generally above 0.60, thus giving similar values to those reported for brown trout microsatellite loci. Substructuring of Portuguese brown trout is evident between northern and southern basins. Genetic affinities between the southernmost rivers and the hatchery stock were detected, suggesting the existence of recent stocking influences.     

Post-glacial colonization of brown trout, Salmo trutta L.: Ldh-5 as a phylogeographic marker locus

The Ldh-5 locus, which codes for the eye-specific lactate dehydrogenase in brown trout, has been shown to be polymorphic for two codominant alleles, Ldh-5 (100) and Ldh-5 (90). The Ldh-5 (100 ) allele is present in 11 other salmonid species and is therefore likely to be the ancestral one, whereas the unique brown trout Ldh-5 (90 ) allele would seem to be the result of a mutation in that lineage. The Ldh-5 (90 ) allele appears to have arisen in north-west Europe during or after the last glaciation, with allelic substitution taking place under the action of natural selection. The Ldh-5 (90 ) allele can be used as a phylogeographic marker to trace the post-glacial spread of the populations possessing it. Examination of the current distribution of the two alleles suggests that, in the formerly glaciated area of north-west Europe, there have been two post-glacial colonizations by brown trout. The first was by an 'ancestral' race fixed for the Ldh-5(100 ) allele. This was later replaced by, or introgressed with, the later-arriving 'modern' race characterized by the Ldh-5 (90 ) allele, except where physical barriers prevented colonization by this latter form. Artificial stocking has resulted in 'genetic contamination' of many populations of the ancestral race and there is an urgent need to conserve the remaining pristine populations, especially in view of the likely genetic propensity for longevity and ultimate large size exhibited by this race.     

Reliability assessment of null allele detection: inconsistencies between and within different methods

Microsatellite loci are widely used in population genetic studies, but the presence of null alleles may lead to biased results. Here, we assessed five methods that indirectly detect null alleles and found large inconsistencies among them. Our analysis was based on 20 microsatellite loci genotyped in a natural population of Microtus oeconomus sampled during 8 years, together with 1200 simulated populations without null alleles, but experiencing bottlenecks of varying duration and intensity, and 120 simulated populations with known null alleles. In the natural population, 29% of positive results were consistent between the methods in pairwise comparisons, and in the simulated data set, this proportion was 14%. The positive results were also inconsistent between different years in the natural population. In the null‐allele‐free simulated data set, the number of false positives increased with increased bottleneck intensity and duration. We also found a low concordance in null allele detection between the original simulated populations and their 20% random subsets. In the populations simulated to include null alleles, between 22% and 42% of true null alleles remained undetected, which highlighted that detection errors are not restricted to false positives. None of the evaluated methods clearly outperformed the others when both false‐positive and false‐negative rates were considered. Accepting only the positive results consistent between at least two methods should considerably reduce the false‐positive rate, but this approach may increase the false‐negative rate. Our study demonstrates the need for novel null allele detection methods that could be reliably applied to natural populations.     

Balancing selection,genetic drift,and human‐mediated introgression interplay to shape MHC (functional) diversity in Mediterranean brown trout

The extraordinary polymorphism of major histocompatibility complex (MHC) genes is considered a paradigm of pathogen‐mediated balancing selection, although empirical evidence is still scarce. Furthermore, the relative contribution of balancing selection to shape MHC population structure and diversity, compared to that of neutral forces, as well as its interaction with other evolutionary processes such as hybridization, remains largely unclear. To investigate these issues, we analyzed adaptive (MHC‐DAB gene) and neutral (11 microsatellite loci) variation in 156 brown trout (Salmo trutta complex) from six wild populations in central Italy exposed to introgression from domestic hatchery lineages (assessed with the LDH gene). MHC diversity and structuring correlated with those at microsatellites, indicating the substantial role of neutral forces. However, individuals carrying locally rare MHC alleles/supertypes were in better body condition (a proxy of individual fitness/parasite load) regardless of the zygosity status and degree of sequence dissimilarity of MHC, hence supporting balancing selection under rare allele advantage, but not heterozygote advantage or divergent allele advantage. The association between specific MHC supertypes and body condition confirmed in part this finding. Across populations, MHC allelic richness increased with increasing admixture between native and domestic lineages, indicating introgression as a source of MHC variation. Furthermore, introgression across populations appeared more pronounced for MHC than microsatellites, possibly because initially rare MHC variants are expected to introgress more readily under rare allele advantage. Providing evidence for the complex interplay among neutral evolutionary forces, balancing selection, and human‐mediated introgression in shaping the pattern of MHC (functional) variation, our findings contribute to a deeper understanding of the evolution of MHC genes in wild populations exposed to anthropogenic disturbance.     

Genetic differentiation among the sympatric brown trout (Salmo trutta) populations of Lough Melvin, Ireland

Three morphotypes of brown trout have been described from Lough Melvin in north-west Ireland: gillaroo; sonaghen; ferox. The extensive genetic differences among the three types indicate that they are reproductively isolated, i.e. separate stocks of trout. For example, only gillaroo possess the Ldh -1(n) allele. Ferox show a high frequency of the Ldh -5(100) allele and this allele does not exceed a frequency of 0.02 in the other two types. Sonaghen are characterized by relatively much higher frequencies for Ck -2(115) and Gpi- 2(135) alleles. Sampling over a period of 7 years and experiments with artificial stocks of gillaroo and sonaghen have demonstrated that these differences are temporally stable. On the basis of observation of mature adults and the genetic composition of fry samples, it has been shown that the three types maintain their genetic integrity as the result of their distinctive spawning habits with gillaroo spawning in the lake and outflowing river, sonaghen in the smaller inflowing rivers and ferox in the deep downstream section of the largest inflowing river. The ferox is a relict population of an early post-glacial trout colonist while gillaroo and sonaghen are representative of a more recent independent colonization. However, it cannot be determined at present whether or not gillaroo and sonaghen were already differentiated prior to colonizing Melvin although the weight of evidence favours a sympatric split. It is proposed that the three types of trout be designated as separate subspecies to highlight the need for independent management and urgent requirement for conservation action.     

A mannose phosphate isomerase polymorphism in the Isopod Asellus aquaticus

A mannose phosphate isomerase locus in Asellus aquaticus is highly polymorphic in two populations examined in Britain. Breeding studies indicate four classes of electrophoretic alleles based on mobility differences, a further null allele, and probable genetically determined variation in enzyme activity between individuals with the same electrophoretic alleles. No linkage with the polymorphic glucose phosphate isomerase and phosphoglucomutase loci was detectable.     

Temporal genetic variation of brown trout <Emphasis Type="Italic">Salmo trutta</Emphasis> L. from Vorobiev creek (White sea) based on allozyme analysis

We performed an analysis of allozyme variation in brown trout from Vorobiev creek. Seventeen allozyme loci encoding glycerol-3-phosphate dehydrogenase (G3PDH), aspartate aminotransferase (AAT), malate dehydrogenase (MDH), lactate dehydrogenase (LDH), superoxide dismutase (SOD), and esterase D (EST-D) were studied. We found statistically significant differences in allele frequencies for the AAT-1,2*, G3PDH-2,3*, LDH-5*, and MDH-2* loci between brown trout samples collected in 1981–1982 and/or 1992–1995. We suggest that temporal changes of allele frequencies in brown trout from Vorobiev Creek are associated with gene drift.     

Selection and genetic drift in captive versus wild populations: an assessment of neutral and adaptive (MHC-linked) genetic variation in wild and hatchery brown trout (<Emphasis Type="Italic">Salmo trutta</Emphasis>) populations

Captive bred individuals are often released into natural environments to supplement resident populations. Captive bred salmonid fishes often exhibit lower survival rates than their wild brethren and stocking measures may have a negative influence on the overall fitness of natural populations. Stocked fish often stem from a different evolutionary lineage than the resident population and thus may be maladapted for life in the wild, but this phenomenon has also been linked to genetic changes that occur in captivity. In addition to overall loss of genetic diversity via captive breeding, adaptation to captivity has become a major concern. Altered selection pressure in captivity may favour alleles at adaptive loci like the Major Histocompatibility Complex (MHC) that are maladaptive in natural environments. We investigated neutral and MHC-linked genetic variation in three autochthonous and three hatchery populations of Austrian brown trout (Salmo trutta). We confirm a positive selection pressure acting on the MHC II β locus, whereby the signal for positive selection was stronger in hatchery versus wild populations. Additionally, diversity at the MHC II β locus was higher, and more uniform among hatchery samples compared to wild populations, despite equal levels of diversity at neutral loci. We postulate that this stems from a combination of stronger genetic drift and a weakening of positive selection at this locus in wild populations that already have well adapted alleles for their specific environments.     

Fine-spotted brown trout: genetic aspects and the need for conservation

In Lake Svartavasstjønn on the Hardangervidda plateau, a fine-spotted variant of brown trout has been found. The spotted variability shows a classical Mendelian mode of inheritance. In this population genetic variability was found in LDH-5 *, MDH-3 * and MDH-3 *. The fast allele at LDH-5 * had a frequency of 0,913. This is remarkable, as this allele has been found in frequencies above 0.4 in only five out of 50 investigated populations in Norway. The genetic characteristics of brown trout from Lake Svartavasstjønn were compared with 11 other populations sampled from a broad geographical area of Norway. Among these was Lake Setningen, where fine-spotted individuals occur at low frequency. Using a cluster analysis based on eight loci found to be polymorphic in brown trout, we found no indication of a close relationship between the fine-spotted brown trout from Lake Svartavasstjønn and the population in Lake Setningen. During a field survey in 1990 we found that the reproduction of fine-spotted trout in Lake Svartavasstjønn had terminated. The fine-spotted trout represents a valuable but threatened genetic resource, and attempts are carried out to conserve it.     

Partial nucleotide sequences, and routine typing by polymerase chain reaction-restriction fragment length polymorphism, of the brown trout (Salmo trutta) lactate dehydrogenase, LDH-C1*90 and *100 alleles

The cDNA nucleotide sequences of the lactate dehydrogenase alleles LDH-C1*90 and *100 of brown trout (Salmo trutta) were found to differ at position 308 where an A is present in the *100 allele but a G is present in the *90 allele. This base substitution results in an amino acid change from aspartic acid at position 82 in the LDH-C1 100 allozyme to a glycine in the 90 allozyme. Since aspartic acid has a net negative charge whilst glycine is uncharged, this is consistent with the electrophoretic observation that the LDH-C1 100 allozyme has a more anodal mobility relative to the LDH-C1 90 allozyme. Based on alignment of the cDNA sequence with the mouse genomic sequence, a local primer set was designed, incorporating the variable position, and was found to give very good amplification with brown trout genomic DNA. Sequencing of this fragment confirmed the difference in both homozygous and heterozygous individuals. Digestion of the polymerase chain reaction products with BslI, a restriction enzyme specific for the site difference, gave one, two and three fragments for the two homozygotes and the heterozygote, respectively, following electrophoretic separation. This provides a DNA-based means of routine screening of the highly informative LDH-C1* polymorphism in brown trout population genetic studies. Primer sets presented could be used to sequence cDNA of other LDH* genes of brown trout and other species.     

Chinook salmon NADP+-dependent cytosolic isocitrate dehydrogenase: Electrophoretic and genetic dissection of a complex isozyme system and geographic patterns of variation

Species in the genus Oncorhynchus express complicated isocitrate dehydrogenase (IDHP) isozyme patterns in many tissues. Subcellular localization experiments show that the electrophoretically distinct isozymes of low anodal mobility expressed predominantly in skeletal and heart muscle are mitochondrial forms (mIDHP), while the more anodal, complex isolocus isozyme system predominant in liver and eye is cytosolic (sIDHP). The two loci encoding sIDHP isozymes are considered isoloci because the most common allele at one of these loci cannot be separated electrophoretically from the most common allele of the other. Over 12 electrophoretically detectable alleles are segregating at the two sIDHP* loci in chinook salmon. Careful electrophoretic comparisons of the sIDHP isozyme patterns of muscle, eye, and liver extracts of heterozygotes reveal marked differences between the tissues with regard to both relative isozyme staining and the expression of several common alleles. Presumed single-dose heterozygotes at the sIDHP isolocus isozyme system exhibit approximate 9:6:1 ratios of staining intensity in liver and eye, while they exhibit approximate 1:2:1 ratios in skeletal muscle. The former proportions are consistent with the equal expression of two loci (isolocus expression), while the latter are consistent with the expression of a single locus. Screening of over 10,000 fish from spawning populations and mixed-stock fishery samples revealed that certain variant alleles (*127, *50) are detectable only in liver and eye, while other alleles (*129, *94, and *74) are strongly expressed in muscle, eye, and liver. The simplest explanation for these observations is that the "isolocus" sIDHP system of chinook salmon (and that of steelhead and rainbow trout) results from the expression of two distinct loci (sIDHP-1* and sIDHP-2*) that have the same common allele (as defined by electrophoretic mobility). IDHP expression in skeletal muscle is due to the nearly exclusive expression of the sIDHP-1* locus, while IDHP expression in eye and liver tissues is due to high levels of expression of both sIDHP-1* and sIDHP-2*--giving rise to the isolocus situation in these latter tissues. Direct inheritance studies confirm this model of two genetically independent (disomic) loci encoding sIDHP in chinook salmon. Extensive geographic surveys of chinook salmon populations from California to British Columbia reveal marked differences in allele frequencies at both sIDHP-1* and sIDHP-2* and considerably more interpopulation differentiation than was recognized previously when sIDHP was treated as an isolocus system with only five recognized alleles.(ABSTRACT TRUNCATED AT 400 WORDS)     

Allozymic evidence of parapatric differentiation of brown trout (Salmo trutta L.) within an Atlantic river basin of the Iberian Peninsula

The genetic variation of brown trout from Duero, one of the main Atlantic Iberian river basins, was assessed at 34 enzymatic loci in 62 native populations. A strong intrabasin differentiation was detected (G(ST) = 0.46; range D: 0-0.066), mainly attributable to the existence of two divergent groups of populations within Duero: southern and northern groups. This divergence was mainly a consequence of the unequal distribution of *75 and *100 alleles at sMDH-B1,2* isoloci, which were correlated with substantial differences in genetic diversity among regions. The Lower Course region (nearly fixed for the *100 allele) and Pisuerga River (nearly fixed for the *75 allele) showed lower heterozygosities (H approximately 0.8%) in contrast with adjacent areas, which evidenced intermediate frequencies for both alleles and higher heterozygosities (H: 2.2-3.1%). Vicariance appeared as the more probable explanation for the significant positive correlation detected between genetic and geographical distances in Duero Basin. Genetic relationships with adjacent Iberian drainages indicate a close similarity between the southern group and Cantabric trout, whereas the northern group constitutes an ancient form from this basin. This study confirmed complex genetic relationships in brown trout from northwest Iberia, reasserting the existence of clines at several loci and for genetic diversity. The interaction between Cantabric and Duero trout, as well as the location of the limit of the anadromous form around the 42 degrees N parallel, are both required to understand the genetic characteristics of brown trout from this area.