Abstract
Symmetry arguments are frequently used - often implicitly - in mathematical modelling of natural selection. Symmetry simplifies the analysis of models and reduces the number of distinct population states to be considered. Here, I introduce a formal definition of symmetry in mathematical models of natural selection. This definition applies to a broad class of models that satisfy a minimal set of assumptions, using a framework developed in previous works. In this framework, population structure is represented by a set of sites at which alleles can live, and transitions occur via replacement of some alleles by copies of others. A symmetry is defined as a permutation of sites that preserves probabilities of replacement and mutation. The symmetries of a given selection process form a group, which acts on population states in a way that preserves the Markov chain representing selection. Applying classical results on group actions, I formally characterize the use of symmetry to reduce the states of this Markov chain, and obtain bounds on the number of states in the reduced chain.
Original language | English |
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Article number | 20230306 |
Journal | Journal of the Royal Society Interface |
Volume | 20 |
Issue number | 208 |
DOIs | |
State | Published - Nov 15 2023 |
Externally published | Yes |
Funding
This project was supported by grant no. 62220 from the John Templeton Foundation. Opinions expressed by the author do not necessarily reflect the views of the funding agency. Acknowledgements
Keywords
- Markov chain
- evolution
- group theory
- natural selection
- symmetry