Spatially structured genetic variation in a broadcast spawning bivalve: quantitative vs. molecular traits

Luttikhuizen, Pieternella C.; Drent, Jan; Delden, W. van; Piersma, Theunis

doi:10.1046/j.1420-9101.2003.00510.x

Cited by 69 publications

(64 citation statements)

References 96 publications

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“…This result is consistent with previous reports of conspecific populations from the South China Sea and Sulu Sea reefs (Juinio-Meñez et al 2003), and contrasts with earlier population genetic studies of other tridacnid species, which revealed little genetic differentiation over broader geographic scales (reviewed by Juinio-Meñez et al 2003). Locus-specific heterozygote deficiencies (in this case GPI-1*) is a pattern frequently observed in bivalves (Luttikhuizen et al 2003 and references therein), and may be attributed to genotype scoring errors, as well as to biological/reproductive factors e.g. genetic differences between cohorts, differential selection, and subpopulation structure (Wahlund effect).…”

Section: Discussionsupporting

confidence: 87%

Influence of the North Equatorial Current on the population genetic structure of Tridacna crocea (Mollusca: Tridacnidae) along the eastern Philippine seaboard

Ravago-Gotanco

Magsino²,

Juinio‐Meñez³

2007

Mar. Ecol. Prog. Ser.

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Tridacna crocea populations were sampled from 15 locations throughout the eastern Philippine seaboard and screened for allozyme variation at 7 polymorphic loci in order to examine the influence of the North Equatorial Current (NEC) bifurcation on population genetic structure. Significant genetic differentiation among all populations was detected (F ST = 0.065). Ordination methods and cluster analysis revealed 2 regional groups and a north-south spatial genetic structure broadly concordant with the bifurcation of the NEC into the Kuroshio and Mindanao current branches. Analysis of molecular variance (AMOVA) indicated greater partitioning of genetic variance among groups (F CT = 0.049) than among populations within groups (F SC = 0.029). An isolation-by-distance signal across the entire Philippine seaboard and marked geographical variation of allele frequencies between Kuroshio and Mindanao Current regions suggested that genetic differentiation is likely due to limited larval exchange and genetic drift. The Mindanao current populations are characterized by greater genetic diversity and differentiation (observed heterozygosity, H O = 0.298; F ST = 0.056) than the Kuroshio populations (H O = 0.152; F ST = 0.025), attributable to variable atmospheric and hydrographic regional conditions. Weaker connectivity among Mindanao current populations are attributed to complex patterns of hydrographic circulation south of the NEC bifurcation, which may translate to greater entrainment potential, in turn influencing dispersal and recruitment of planktonic propagules at varying spatial and temporal scales. Fine-scale genetic differentiation was also detected within Kuroshio and Mindanao current populations, indicating the influence of small-scale temporal and spatial physical processes that affect larval dispersal and recruitment along the eastern Philippine seaboard.

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Section: Discussionsupporting

confidence: 87%

Influence of the North Equatorial Current on the population genetic structure of Tridacna crocea (Mollusca: Tridacnidae) along the eastern Philippine seaboard

Ravago-Gotanco

Magsino²,

Juinio‐Meñez³

2007

Mar. Ecol. Prog. Ser.

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“…In addition, common garden experiments are also used to study the consequences of local adaptation for conservation (McKay et al, 2001) or even for ecosystem functioning (Bassar et al, 2010). Despite its name, and although it has been used extensively with plants (Linhart and Grant, 1996), this experimental approach can also be applied to a large variety of organisms including fish (Bassar et al, 2010;DeFaveri and Merilä, 2014), invertebrates (Spitze, 1993;Luttikhuizen et al, 2003) and small mammals (Bozinovic et al, 2009). The main limitations to this experimental design are the ability to breed the species and to grow the produced offspring in laboratory or seminatural conditions.…”

Section: Introductionmentioning

confidence: 99%

Common garden experiments in the genomic era: new perspectives and opportunities

Villemereuil¹,

Gaggiotti²,

Mouterde³

et al. 2015

Heredity

308

242

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The study of local adaptation is rendered difficult by many evolutionary confounding phenomena (for example, genetic drift and demographic history). When complex traits are involved in local adaptation, phenomena such as phenotypic plasticity further hamper evolutionary biologists to study the complex relationships between phenotype, genotype and environment. In this perspective paper, we suggest that the common garden experiment, specifically designed to deal with phenotypic plasticity, has a clear role to play in the study of local adaptation, even (if not specifically) in the genomic era. After a quick review of some high-throughput genotyping protocols relevant in the context of a common garden, we explore how to improve common garden analyses with dense marker panel data and recent statistical methods. We then show how combining approaches from population genomics and genome-wide association studies with the settings of a common garden can yield to a very efficient, thorough and integrative study of local adaptation. Especially, evidence from genomic (for example, genome scan) and phenotypic origins constitute independent insights into the possibility of local adaptation scenarios, and genome-wide association studies in the context of a common garden experiment allow to decipher the genetic bases of adaptive traits.

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“…This led to the idea of testing selective divergence in quantitative traits by comparison of their population differentiation (Q ST ) with the population differentiation obtained from neutral molecular markers (F ST ) (Spitze, 1993). Three outcomes, each having a unique interpretation, are possible (Merila and Crnokrak, 2001): (i) Q ST 4F ST : this is commonly interpreted as evidence of divergent selection and adaptation to local environments (Podolsky and Holtsford, 1995;Bonnin et al, 1996;Latta and Mitton, 1997;Jaramillo-Correa et al, 2001;Steinger et al, 2002;Storz, 2002;Chan and Arcese, 2003;Luttikhuizen et al, 2003); (ii) Q ST and F ST do not differ: genetic drift alone is sufficient to explain the pattern of differentiation (Yang et al, 1996), although effects of natural selection and drift in certain cases can be indistinguishable in certain cases (Sokal and Wartenburg, 1983); and (iii) Q ST oF ST : convergent selection favoring the same phenotype in different environments is assumed (Kuittinen et al, 1997;Petit et al, 2001;Edmands and Harrison, 2003). However, interpretation of any discrepancy between Q ST and F ST as evidence of selection on a particular quantitative trait may not always hold.…”

Section: Introductionmentioning

confidence: 99%

Distinguishing adaptive from nonadaptive genetic differentiation: comparison of QST and FST at two spatial scales

et al. 2005

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Genetic differentiation in 20 hierarchically sampled populations of wild barley was analyzed with quantitative traits, allozymes and Random Amplified Polymorphic DNAs (RAPDs), and compared for three marker types at two hierarchical levels. Regional subdivision for both molecular markers was much lower than for quantitative traits. For both allozymes and RAPDs, most loci exhibited minor or no regional differentiation, and the relatively high overall estimates of the latter were due to several loci with exceptionally high regional differentiation. The allozymeand RAPD-specific patterns of differentiation were concordant in general with one another, but not with quantitative trait differentiation. Divergent selection on quantitative traits inferred from very high regional Q ST was in full agreement with our previous results obtained from a test of local adaptation and multilevel selection analysis. In contrast, most variation in allozyme and RAPD variation was neutral, although several allozyme loci and RAPD markers were exceptional in their levels of regional differentiation. However, it is not possible to answer the question whether these exceptional loci are directly involved in the response to selection pressure or merely linked to the selected loci. The fact that Q ST and F ST did not differ at the population scale, that is, within regions, but differed at the regional scale, for which local adaptation has been previously shown, implies that comparison of the level of subdivision in quantitative traits, as compared with molecular markers, is indicative of adaptive population differentiation only when sampling is carried out at the appropriate scale. Heredity (2005) 95, 466-475.

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Spatially structured genetic variation in a broadcast spawning bivalve: quantitative vs. molecular traits

Cited by 69 publications

References 96 publications

Influence of the North Equatorial Current on the population genetic structure of Tridacna crocea (Mollusca: Tridacnidae) along the eastern Philippine seaboard

Influence of the North Equatorial Current on the population genetic structure of Tridacna crocea (Mollusca: Tridacnidae) along the eastern Philippine seaboard

Common garden experiments in the genomic era: new perspectives and opportunities

Distinguishing adaptive from nonadaptive genetic differentiation: comparison of QST and FST at two spatial scales

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