Publikation: Which games are growing bacterial populations playing?
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Datum
2015
Autor:innen
Pietschke, Cleo
Fraune, Sebastian
Altrock, Philipp M.
Bosch, Thomas C. G.
Traulsen, Arne
Herausgeber:innen
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Deutsche Forschungsgemeinschaft (DFG): FR 3041/2-1
Deutsche Forschungsgemeinschaft (DFG): Bo 848/17-2
Institutionen der Bundesrepublik Deutschland: LPDS 2012-12
Deutsche Forschungsgemeinschaft (DFG): Bo 848/17-2
Institutionen der Bundesrepublik Deutschland: LPDS 2012-12
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Interface : Journal of the Royal Society. Royal Society of London. 2015, 12(108), 20150121. ISSN 1742-5689. eISSN 1742-5662. Verfügbar unter: doi: 10.1098/rsif.2015.0121
Zusammenfassung
Microbial communities display complex population dynamics, both in frequency and absolute density. Evolutionary game theory provides a natural approach to analyse and model this complexity by studying the detailed interactions among players, including competition and conflict, cooperation and coexistence. Classic evolutionary game theory models typically assume constant population size, which often does not hold for microbial populations. Here, we explicitly take into account population growth with frequency-dependent growth parameters, as observed in our experimental system. We study the in vitro population dynamics of the two commensal bacteria ( Curvibacter sp. (AEP1.3) and Duganella sp. (C1.2)) that synergistically protect the metazoan host Hydra vulgaris (AEP) from fungal infection. The frequency-dependent, nonlinear growth rates observed in our experiments indicate that the interactions among bacteria in co-culture are beyond the simple case of direct competition or, equivalently, pairwise games. This is in agreement with the synergistic effect of anti-fungal activity observed in vivo . Our analysis provides new insight into the minimal degree of complexity needed to appropriately understand and predict coexistence or extinction events in this kind of microbial community dynamics. Our approach extends the understanding of microbial communities and points to novel experiments.
Zusammenfassung in einer weiteren Sprache
Fachgebiet (DDC)
570 Biowissenschaften, Biologie
Schlagwörter
bacterial interactions, frequency-dependent selection, Lotka –Volterra equations, nonlinear dynamics, population dynamics
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ISO 690
LI RICHTER, Xiang-Yi, Cleo PIETSCHKE, Sebastian FRAUNE, Philipp M. ALTROCK, Thomas C. G. BOSCH, Arne TRAULSEN, 2015. Which games are growing bacterial populations playing?. In: Interface : Journal of the Royal Society. Royal Society of London. 2015, 12(108), 20150121. ISSN 1742-5689. eISSN 1742-5662. Verfügbar unter: doi: 10.1098/rsif.2015.0121BibTex
@article{LiRichter2015-07Which-73418,
title={Which games are growing bacterial populations playing?},
year={2015},
doi={10.1098/rsif.2015.0121},
number={108},
volume={12},
issn={1742-5689},
journal={Interface : Journal of the Royal Society},
author={Li Richter, Xiang-Yi and Pietschke, Cleo and Fraune, Sebastian and Altrock, Philipp M. and Bosch, Thomas C. G. and Traulsen, Arne},
note={Article Number: 20150121}
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<dcterms:abstract>Microbial communities display complex population dynamics, both in frequency and absolute density. Evolutionary game theory provides a natural approach to analyse and model this complexity by studying the detailed interactions among players, including competition and conflict, cooperation and coexistence. Classic evolutionary game theory models typically assume constant population size, which often does not hold for microbial populations. Here, we explicitly take into account population growth with frequency-dependent growth parameters, as observed in our experimental system. We study the in vitro population dynamics of the two commensal bacteria ( Curvibacter sp. (AEP1.3) and Duganella sp. (C1.2)) that synergistically protect the metazoan host Hydra vulgaris (AEP) from fungal infection. The frequency-dependent, nonlinear growth rates observed in our experiments indicate that the interactions among bacteria in co-culture are beyond the simple case of direct competition or, equivalently, pairwise games. This is in agreement with the synergistic effect of anti-fungal activity observed in vivo . Our analysis provides new insight into the minimal degree of complexity needed to appropriately understand and predict coexistence or extinction events in this kind of microbial community dynamics. Our approach extends the understanding of microbial communities and points to novel experiments.</dcterms:abstract>
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