How to Measure Group Selection in Real-world Populations
How to Measure Group Selection in Real-world Populations
Multilevel selection and the evolution of cooperation are fundamental to the formation of higher-level organisation and the evolution of biocomplexity, but such notions are controversial and poorly understood in natural populations. The theoretic principles of group selection are well developed in idealised models where a population is neatly divided into multiple semi-isolated sub-populations. But since such models can be explained by individual selection given the localised frequency-dependent effects involved, some argue that the group selection concepts offered are, even in the idealised case, redundant and that in natural conditions where groups are not well-defined that a group selection framework is entirely inapplicable. This does not necessarily mean, however, that a natural population is not subject to some interesting localised frequency-dependent effects – but how could we formally quantify this under realistic conditions? Here we focus on the presence of a Simpson’s Paradox where, although the local proportion of cooperators decreases at all locations, the global proportion of cooperators increases. We illustrate this principle in a simple individual-based model of bacterial biofilm growth and discuss various complicating factors in moving from theory to practice of measuring group selection.
672-679
Powers, Simon T
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Heys, Christopher
9fda39f2-bb17-4185-a6c9-9235d527953c
Watson, Richard A
ce199dfc-d5d4-4edf-bd7b-f9e224c96c75
August 2011
Powers, Simon T
474bffcd-e5ab-4be0-89fe-b0d0b2bdf2c1
Heys, Christopher
9fda39f2-bb17-4185-a6c9-9235d527953c
Watson, Richard A
ce199dfc-d5d4-4edf-bd7b-f9e224c96c75
Powers, Simon T, Heys, Christopher and Watson, Richard A
(2011)
How to Measure Group Selection in Real-world Populations.
In,
Advances in Artificial Life, ECAL 2011.
MIT Press, .
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Book Section
Abstract
Multilevel selection and the evolution of cooperation are fundamental to the formation of higher-level organisation and the evolution of biocomplexity, but such notions are controversial and poorly understood in natural populations. The theoretic principles of group selection are well developed in idealised models where a population is neatly divided into multiple semi-isolated sub-populations. But since such models can be explained by individual selection given the localised frequency-dependent effects involved, some argue that the group selection concepts offered are, even in the idealised case, redundant and that in natural conditions where groups are not well-defined that a group selection framework is entirely inapplicable. This does not necessarily mean, however, that a natural population is not subject to some interesting localised frequency-dependent effects – but how could we formally quantify this under realistic conditions? Here we focus on the presence of a Simpson’s Paradox where, although the local proportion of cooperators decreases at all locations, the global proportion of cooperators increases. We illustrate this principle in a simple individual-based model of bacterial biofilm growth and discuss various complicating factors in moving from theory to practice of measuring group selection.
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GroupSelectionSpatialPopulations.pdf
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Published date: August 2011
Organisations:
Agents, Interactions & Complexity
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Local EPrints ID: 272753
URI: http://eprints.soton.ac.uk/id/eprint/272753
PURE UUID: e7911560-e49d-4bc9-be5d-9ce98b59eedc
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Date deposited: 07 Sep 2011 17:10
Last modified: 15 Mar 2024 03:21
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Author:
Simon T Powers
Author:
Christopher Heys
Author:
Richard A Watson
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