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Alternating lysis and lysogeny is a winning strategy in bacteriophages due to Parrondo's paradox

Kang Hao Cheong, Tao Wen, Sean Benler, Jin Ming Koh, Eugene V. Koonin

2022Proceedings of the National Academy of Sciences53 citationsDOIOpen Access PDF

Abstract

SignificanceBacteriophages, the most widespread reproducing biological entity on Earth, employ two strategies of virus-host interaction: lysis of the host cell and lysogeny whereby the virus genome integrates into the host genome and propagates vertically with it. We present a population model that reveals an effect known as Parrondo's paradox in game theory: Alternating between lysis and lysogeny is a winning strategy for a bacteriophage, even when each strategy individually is at a disadvantage compared with a competing bacteriophage. Thus, evolution of bacteriophages appears to optimize the ratio between the lysis and lysogeny propensities rather than the phage burst size in any individual phase. This phenomenon is likely to be relevant for understanding evolution of other host-parasites systems.

Topics & Concepts

Lysogenic cycleBacteriophageLysisBiologyHost (biology)GenomePopulationBacterial virusGeneticsGeneEscherichia coliImmunologyDemographySociologyEvolution and Genetic DynamicsBacteriophages and microbial interactionsMathematical and Theoretical Epidemiology and Ecology Models
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