High levels of fluctuating asymmetry in isolated stickleback populations (original) (raw)
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Evolution, 2012
Parallel (or convergent) evolution provides strong evidence for a deterministic role of natural selection: similar phenotypes evolve when independent populations colonize similar environments. In reality, however, independent populations in similar environments always show some differences: some nonparallel evolution is present. It is therefore important to explicitly quantify the parallel and nonparallel aspects of trait variation, and to investigate the ecological and genetic explanations for each. We performed such an analysis for threespine stickleback (Gasterosteus aculeatus) populations inhabiting lake and stream habitats in six independent watersheds. Morphological traits differed in the degree to which lake-stream divergence was parallel across watersheds. Some aspects of this variation were correlated with ecological variables related to diet, presumably reflecting the strength and specifics of divergent selection. Furthermore, a genetic scan revealed some markers that diverged between lakes and streams in many of the watersheds and some that diverged in only a few watersheds. Moreover, some of the lake-stream divergence in genetic markers was associated within some of the lake-stream divergence in morphological traits. Our results suggest that parallel evolution, and deviations from it, are primarily the result of natural selection, which corresponds in only some respects to the dichotomous habitat classifications frequently used in such studies.
Isolated populations of fish living in ponds are often phenotypically and genetically diverged from their source populations. However, to what degree this divergence reflects maternal, genetic or environmental effects is often unclear, as is the possible adaptive nature of this differentiation due to the strong impact of random genetic drift on populations residing in isolated habitats. Further studies utilizing an F 2-backcross-design-as well as replicate populationsmight shed more light on the questions that remain open. Nevertheless, these results reinforce the conjecture that Fennoscandian pond populations of nine-spined sticklebacks might, or should be viewed as a significant evolutionary and conservation unit that require special attention in regional and national management and conservation plans.
Biological Journal of The Linnean Society, 2009
The frequent occurrence of parallel phenotypic divergence in similar habitats is often evoked when emphasizing the role of ecology in adaptive radiation and speciation. However, because phenotypic plasticity can contribute to the observed pattern of divergence, confirmation of divergence at loci underlying phenotypic traits is important for confirming adaptive divergence. In the present study, we examine parallel morphological, neutral, and potentially adaptive genetic divergence of threespine stickleback inhabiting different habitats within a lake. Three genetic clusters best explained the neutral genetic structure within the lake; however, morphological differences were only weakly connected to genetic clusters and there was considerable phenotypic variation within clusters. Among the factors that could contribute to the observed pattern of morphological and genetic divergence are phenotypic plasticity, selective mortality of hybrids, and habitat choice based on morphology. Several loci are identified as outliers indicating divergent selection between the morphs and some parallels in morphological and adaptive genetic divergence are found in stickleback spawning at two lava sites. However, neutral genetic structure indicates considerable genetic connectivity among the two lava sites, and the parallels in morphology may therefore represent selective distribution of phenotypes rather than parallel divergence. © 2009 The Linnean Society of London, Biological Journal of the Linnean Society, 2009, 98, 803–813.
Biological Journal of the Linnean Society, 2009
The frequent occurrence of parallel phenotypic divergence in similar habitats is often evoked when emphasizing the role of ecology in adaptive radiation and speciation. However, because phenotypic plasticity can contribute to the observed pattern of divergence, confirmation of divergence at loci underlying phenotypic traits is important for confirming adaptive divergence. In the present study, we examine parallel morphological, neutral, and potentially adaptive genetic divergence of threespine stickleback inhabiting different habitats within a lake. Three genetic clusters best explained the neutral genetic structure within the lake; however, morphological differences were only weakly connected to genetic clusters and there was considerable phenotypic variation within clusters. Among the factors that could contribute to the observed pattern of morphological and genetic divergence are phenotypic plasticity, selective mortality of hybrids, and habitat choice based on morphology. Several loci are identified as outliers indicating divergent selection between the morphs and some parallels in morphological and adaptive genetic divergence are found in stickleback spawning at two lava sites. However, neutral genetic structure indicates considerable genetic connectivity among the two lava sites, and the parallels in morphology may therefore represent selective distribution of phenotypes rather than parallel divergence.
Evolution, 2006
The complex interactions between genetic diversity and evolution have important implications in many biological areas including conservation, speciation, and mate choice. A common way to study these interactions is to look at heterozygosity-fitness correlations (HFCs). Until recently, HFCs based on noncoding markers were believed to result primarily from global inbreeding effects. However, accumulating theoretical and empirical evidence shows that HFCs may often result from genes being linked to the markers used (local effect). Moreover, local effect HFCs could differ from global inbreeding effects in their direction and occurrence. Consequently, the investigation of the structure and consequences of local HFCs is emerging as a new important goal in evolutionary biology. In this study of a wild threespine stickleback (Gasterosteus aculeatus) population, we first tested the presence of significant positive or negative local effects of heterozygosity at 30 microsatellites loci on five fitness components: survival, mating success, territoriality, length, and body condition. Then, we evaluated the direction and shape of total impact of local HFCs, and estimated the magnitude of the impacts on fitness using regression coefficients and selection differentials. We found that multilocus heterozygosity was not a reliable estimator of individual inbreeding coefficient, which supported the relevance of single-locus based analyses. Highly significant and temporally stable local HFCs were observed. These were mainly positive, but negative effects of heterozygosity were also found. Strong and opposite effects of heterozygosity are probably present in many populations, but may be blurred in HFC analyses looking for global effects only. In this population, both negative and positive HFCs are apparently driving mate preference by females, which is likely to contribute to the maintenance of both additive and nonadditive genetic variance.
Molecular Ecology, 2006
Three measures of divergence, estimated at nine putatively neutral microsatellite markers, 14 quantitative traits, and seven quantitative trait loci (QTL) were compared in eight populations of the three-spined stickleback (Gasterosteus aculeatus L.) living in the Scheldt river basin (Belgium). Lowland estuarine and polder populations were polymorphic for the number of lateral plates, whereas upland freshwater populations were low-plated. The number of short gill rakers and the length of dorsal and pelvic spines gradually declined along a coastal-inland gradient. Plate number, short gill rakers and spine length showed moderate to strong signals of divergent selection between lowland and upland populations in comparison between PST (a phenotypic alternative for QST) and neutral FST. However, such comparisons rely on the unrealistic assumption that phenotypic variance equals additive genetic variance, and that nonadditive genetic effects and environmental effects can be minimized. In order to verify this assumption and to confirm the phenotypic signals of divergence, we tested for divergent selection at the underlying QTL. For plate number, strong genetic evidence for divergent selection between lowland and upland populations was obtained based on an intron marker of the Eda gene, of which the genotype was highly congruent with plate morph. Genetic evidence for divergent selection on short gill rakers was limited to some population pairs where FST at only one of two QTL was detected as an outlier, although FST at both loci correlated significantly with PST. No genetic confirmation was obtained for divergent selection on dorsal spine length, as no outlier FSTs were detected at dorsal spine QTL, and no significant correlations with PST were observed.
Ecological genetics of freshwater fish: a short review of the genotype–phenotype connection
Animal Biodiversity and Conservation
Molecular ecology or ecological genetics is an expanding application of population genetics which has flourished in the last two decades but it is dominated by systematic and phylogeographic studies, with relatively little emphasis on the study of the genetic basis of the process of adaptation to different ecological conditions. The relationship between genotype and adaptive phenotypes is weak because populations are often difficult to quantify and experiments are logistically challenging or unfeasible. Interestingly, in freshwater fish, studies to characterize the genetic architecture of adaptive traits are not as rare as in other vertebrate groups. In this review, we summarize the few cases where the relationship between the ecology and genetics of freshwater fish is more developed, namely the relationship between genetic markers and ecological phenotypes.