Data from: Population size is weakly related to quantitative genetic variation and trait differentiation in a stream fish ...
How population size influences quantitative genetic variation and differentiation among natural, fragmented populations remains unresolved. Small, isolated populations might occupy poor quality habitats and lose genetic variation more rapidly due to genetic drift than large populations. Genetic drif...
| Main Authors: | , , , |
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| Format: | Dataset |
| Language: | English |
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Dryad
2015
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| Subjects: | |
| Online Access: | https://dx.doi.org/10.5061/dryad.rq122 https://datadryad.org/stash/dataset/doi:10.5061/dryad.rq122 |
| Summary: | How population size influences quantitative genetic variation and differentiation among natural, fragmented populations remains unresolved. Small, isolated populations might occupy poor quality habitats and lose genetic variation more rapidly due to genetic drift than large populations. Genetic drift might furthermore overcome selection as population size decreases. Collectively, this might result in directional changes in additive genetic variation (VA) and trait differentiation (QST) from small to large population size. Alternatively, small populations might exhibit larger variation in VA and QST if habitat fragmentation increases variability in habitat types. We explored these alternatives by investigating VA and QST using nine fragmented populations of brook trout varying 50-fold in census size N (179-8416) and 10-fold in effective number of breeders, Nb (18-135). Across 15 traits, no evidence was found for consistent differences in VA and QST with population size and almost no evidence for increased ... : Trait measurements and pedigrees for Cape Race brook trout populationsIndividual trait measurements and pedigrees used in animal models to estimate quantitative genetic parameters for fifteen traits for nine brook trout populations from Cape Race, Newfoundland, Canada.CR_traits_pedigrees.xlsxCape Race breeding design summaryA table summarizing, per population, the number of females and males used to generate families as well as the range and mean number of crosses per male for the common garden experiment used to estimate quantitative genetic parameters for Cape Race brook trout populations.CR.breeding.design.summary.xlsxQuantitative genetic parameter values and QST values for Cape Race brook trout populationsQuantitative genetic parameter values (QGV) and QST values for fifteen traits for nine brook trout populations estimated from animal models and used to generate figures and in statistical analyses.CR.QGV.QST.xlsxR code for animal models and statistical analysesExamples of R code specifying animal models ... |
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