Evolutionary games on cycles with strong selection

Philipp M. Altrock; Arne Traulsen; Nowak, Martin A.

Evolutionary games on cycles with strong selection

Citation:

Altrock, P.M., Traulsen, A. & Nowak, M.A., 2017. Evolutionary games on cycles with strong selection. Physical Review E , 95 , pp. 022407.

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Evolutionary games on cycles with strong selection

Abstract:

Evolutionary games on graphs describe how strategic interactions and population structure determine evolutionary success, quantified by the probability that a single mutant takes over a population. Graph structures, compared to the well-mixed case, can act as amplifiers or suppressors of selection by increasing or decreasing the fixation probability of a beneficial mutant. Properties of the associated mean fixation times can be more intricate, especially when selection is strong. The intuition is that fixation of a beneficial mutant happens fast in a dominance game, that fixation takes very long in a coexistence game, and that strong selection eliminates demographic noise. Here we show that these intuitions can be misleading in structured populations. We analyze mean fixation times on the cycle graph under strong frequency-dependent selection for two different microscopic evolutionary update rules (death-birth and birth-death). We establish exact analytical results for fixation times under strong selection and show that there are coexistence games in which fixation occurs in time polynomial in population size. Depending on the underlying game, we observe inherence of demographic noise even under strong selection if the process is driven by random death before selection for birth of an offspring (death-birth update). In contrast, if selection for an offspring occurs before random removal (birth-death update), then strong selection can remove demographic noise almost entirely.

Publisher's Version

Last updated on 09/29/2017

Recent Publications

Altrock, P.M., Liu, L. & Michor, F., 2015. The mathematics of cancer: integrating quantitative models. Nature Reviews Cancer , 15 , pp. 730-745. Publisher's Version Abstract

altrock2015nrc.pdf

Mathematical modelling approaches have become increasingly abundant in cancer research. The complexity of cancer is well suited to quantitative approaches as it provides challenges and opportunities for new developments. In turn, mathematical modelling contributes to cancer research by helping to elucidate mechanisms and by providing quantitative predictions that can be validated. The recent expansion of quantitative models addresses many questions regarding tumour initiation, progression and metastases as well as intra-tumour heterogeneity, treatment responses and resistance. Mathematical models can complement experimental and clinical studies, but also challenge current paradigms, redefine our understanding of mechanisms driving tumorigenesis and shape future research in cancer biology.

Li, X.-Y., et al., 2015. Which games are growing bacterial populations playing?. Journal of the Royal Society Interface , 12 , pp. 20150122. Publisher's Version Abstract

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Gerlee, P. & Altrock, P.M., 2015. Complexity and stability in growing cancer cell populations. PNAS , 112 (21) , pp. E2742–E2743. Publisher's Version Abstract

gerlee2015pnas.pdf

The study by Archetti et al. (http://www.pnas.org/content/112/6/1833) demonstrates frequency-dependent growth rates of two phenotypically distinct cancer subclones. One clone produced the insulin-like growth factor (IGF)-II, the other did not. In a mix of producers and nonproducers, the growth rates of both clones varied with the frequency of producers. Because a similar effect was shown when varying the concentration of serum, the production of IGF-II could be viewed as a public goods game. We welcome these experimental results but have serious concerns about the theoretical framework used for explaining them. Evolutionary game theory has certain advantages when it comes to understanding complex interactions, but further evidence is needed for its application to growing tumors.

Ashcroft, P., Altrock, P.M. & Galla, T., 2014. Fixation in finite populations evolving in fluctuating environments. Journal of the Royal Society Interface , 11 , pp. 20140663. Publisher's Version Abstract

ashcroft2014interface.pdf

The environment in which a population evolves can have a crucial impact on selection. We study evolutionary dynamics in finite populations of fixed size in a changing environment. The population dynamics are driven by birth and death events. The rates of these events may vary in time depending on the state of the environment, which follows an independent Markov process. We develop a general theory for the fixation probability of a mutant in a population of wild-types, and for mean unconditional and conditional fixation times. We apply our theory to evolutionary games for which the payoff structure varies in time. The mutant can exploit the environmental noise; a dynamic environment that switches between two states can lead to a probability of fixation that is higher than in any of the individual environmental states. We provide an intuitive interpretation of this surprising effect. We also investigate stationary distributions when mutations are present in the dynamics. In this regime, we find two approximations of the stationary measure. One works well for rapid switching, the other for slowly fluctuating environments.

Marusyk, A., et al., 2014. Non-cell-autonomous driving of tumourgrowth supports sub-clonal heterogeneity. Nature , 514 , pp. 54–58. Publisher's Version Abstract

marusyk2014nature.pdf

Cancers arise through a process of somatic evolution that can result in substantial sub-clonal heterogeneity within tumours. The mechanisms responsible for the coexistence of distinct sub-clones and the biological consequences of this coexistence remain poorly understood. Here we used a mouse xenograft model to investigate the impact of sub-clonal heterogeneity on tumour phenotypes and the competitive expansion ofindividual clones.We found that tumour growth can be driven by a minor cell subpopulation, which enhances the proliferation of all cells within a tumour by overcoming environmental constraints and yet can be outcompeted by faster proliferating competitors, resulting in tumour collapse. We developed a mathematical modelling framework to identify the rules underlying the generation of intra-tumour clonal heterogeneity. We found that non-cell-autonomous driving of tumour growth, together with clonal interference, stabilizes sub-clonal heterogeneity, thereby enabling inter-clonal interactions that can lead to new phenotypic traits.

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Dr. Philipp M. Altrock

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