Data from: Subsampling reveals that unbalanced sampling affects STRUCTURE results in a multi-species dataset

Studying the genetic population structure of species can reveal important insights into several key evolutionary, historical, demographic, and anthropogenic processes. One of the most important statistical tools for inferring genetic clusters is the program STRUCTURE. Recently, several papers have p...

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Bibliographic Details
Main Author: Meirmans, Patrick
Format: Dataset
Language:unknown
Published: DRYAD 2018
Subjects:
Bayesian clustering
population structure
genetic differentiation
phylogeography
High-alpine plants
IntraBioDiv
Alps
Carpathians
Europe
Anthropocene
Arabis alpina
Carex sempervirens
Dryas octopetala
Geum montanum
Geum reptans
Hedysarum hedysaroides
Hypochaeris uniflora
Juncus trifidus
Loiseleuria procumbens
Luzula alpinopilosa
Saxifraga stellaris
Sesleria caerulea
Life sciences
medicine and health care
geo
envir
Online Access:https://doi.org/10.5061/DRYAD.NH4366S
Description
Summary:Studying the genetic population structure of species can reveal important insights into several key evolutionary, historical, demographic, and anthropogenic processes. One of the most important statistical tools for inferring genetic clusters is the program STRUCTURE. Recently, several papers have pointed out that STRUCTURE may show a bias when the sampling design is unbalanced, resulting in spurious joining of underrepresented populations and spurious separation of overrepresented populations. Suggestions to overcome this bias include subsampling and changing the ancestry model, but the performance of these two methods has not yet been tested on actual data. Here, I use a dataset of twelve high-alpine plant species to test whether unbalanced sampling affects the STRUCTURE inference of population differentiation between the European Alps and the Carpathians. For four of the twelve species, subsampling of the Alpine populations –to match the sample size between the Alps and the Carpathians– resulted in a drastically different clustering than the full dataset. On the other hand, STRUCTURE results with the alternative ancestry model were indistinguishable from the results with the default model. Based on these results, the subsampling strategy seems a more viable approach to overcome the bias than the alternative ancestry model. However, subsampling is only possible when there is an a priori expectation of what constitute the main clusters. Though these results do not mean that the use of STRUCTURE should be discarded, it does indicate that users of the software should be cautious about the interpretation of the results when sampling is unbalanced. dataThis folder contains for every species the data for the AFLP markers. These are formatted in plain text files with each AFLP marker represented by a single column. A zero (0)represents absence of an marker band and a one (1) represents presence of a marker band. Preceding the AFLP data are four columns with metadata: 1) individual: The name of the individual ...

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