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On the connections between the spatial Lambda–Fleming–Viot model and other processes for analysing geo-referenced genetic data

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  • Wirtz, Johannes
  • Guindon, Stéphane

Abstract

The introduction of the spatial Lambda-Fleming–Viot model (ΛV) in population genetics was mainly driven by the pioneering work of Alison Etheridge, in collaboration with Nick Barton and Amandine Véber about ten years ago (Barton et al., 2010; Barton et al., 2013). The ΛV model provides a sound mathematical framework for describing the evolution of a population of related individuals along a spatial continuum. It alleviates the “pain in the torus†issue with Wright and Malécot’s isolation by distance model and is sampling consistent, making it a tool of choice for statistical inference. Yet, little is known about the potential connections between the ΛV and other stochastic processes generating trees and the spatial coordinates along the corresponding lineages. This work focuses on a version of the ΛV whereby lineages move rapidly over small distances. Using simulations, we show that the induced ΛV tree-generating process is well approximated by a birth–death model. Our results also indicate that Brownian motions modelling the movements of lines of descent along birth–death trees do not generally provide a good approximation of the ΛV due to habitat boundaries effects that play an increasingly important role in the long run. Accounting for habitat boundaries through reflected Brownian motions considerably increases the similarity to the ΛV model however. Finally, we describe efficient algorithms for fast simulation of the backward and forward in time versions of the ΛV model.

Suggested Citation

  • Wirtz, Johannes & Guindon, Stéphane, 2024. "On the connections between the spatial Lambda–Fleming–Viot model and other processes for analysing geo-referenced genetic data," Theoretical Population Biology, Elsevier, vol. 158(C), pages 139-149.
    • Handle: RePEc:eee:thpobi:v:158:y:2024:i:c:p:139-149
    DOI: 10.1016/j.tpb.2024.06.002
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    References listed on IDEAS

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    1. Guindon, Stéphane & Guo, Hongbin & Welch, David, 2016. "Demographic inference under the coalescent in a spatial continuum," Theoretical Population Biology, Elsevier, vol. 111(C), pages 43-50.
    2. Gideon S Bradburd & Peter L Ralph & Graham M Coop, 2016. "A Spatial Framework for Understanding Population Structure and Admixture," PLOS Genetics, Public Library of Science, vol. 12(1), pages 1-38, January.
    3. John Novembre & Toby Johnson & Katarzyna Bryc & Zoltán Kutalik & Adam R. Boyko & Adam Auton & Amit Indap & Karen S. King & Sven Bergmann & Matthew R. Nelson & Matthew Stephens & Carlos D. Bustamante, 2008. "Genes mirror geography within Europe," Nature, Nature, vol. 456(7219), pages 274-274, November.
    4. Chaolong Wang & Sebastian Zöllner & Noah A Rosenberg, 2012. "A Quantitative Comparison of the Similarity between Genes and Geography in Worldwide Human Populations," PLOS Genetics, Public Library of Science, vol. 8(8), pages 1-16, August.
    5. Kelleher, J. & Etheridge, A.M. & Barton, N.H., 2014. "Coalescent simulation in continuous space: Algorithms for large neighbourhood size," Theoretical Population Biology, Elsevier, vol. 95(C), pages 13-23.
    6. John Novembre & Toby Johnson & Katarzyna Bryc & Zoltán Kutalik & Adam R. Boyko & Adam Auton & Amit Indap & Karen S. King & Sven Bergmann & Matthew R. Nelson & Matthew Stephens & Carlos D. Bustamante, 2008. "Genes mirror geography within Europe," Nature, Nature, vol. 456(7218), pages 98-101, November.
    7. Wirtz, Johannes & Guindon, Stéphane, 2022. "Rate of coalescence of lineage pairs in the Spatial Λ-Fleming–Viot process," Theoretical Population Biology, Elsevier, vol. 146(C), pages 15-28.
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