BMC Biology (Mar 2019)

Behavioral heterogeneity in quorum sensing can stabilize social cooperation in microbial populations

  • Kelei Zhao,
  • Linjie Liu,
  • Xiaojie Chen,
  • Ting Huang,
  • Lianming Du,
  • Jiafu Lin,
  • Yang Yuan,
  • Yingshun Zhou,
  • Bisong Yue,
  • Kun Wei,
  • Yiwen Chu

DOI
https://doi.org/10.1186/s12915-019-0639-3
Journal volume & issue
Vol. 17, no. 1
pp. 1 – 15

Abstract

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Abstract Background Microbial communities are susceptible to the public goods dilemma, whereby individuals can gain an advantage within a group by utilizing, but not sharing the cost of producing, public goods. In bacteria, the development of quorum sensing (QS) can establish a cooperation system in a population by coordinating the production of costly and sharable extracellular products (public goods). Cooperators with intact QS system and robust ability in producing public goods are vulnerable to being undermined by QS-deficient defectors that escape from QS but benefit from the cooperation of others. Although microorganisms have evolved several mechanisms to resist cheating invasion in the public goods game, it is not clear why cooperators frequently coexist with defectors and how they form a relatively stable equilibrium during evolution. Results We show that in Pseudomonas aeruginosa, QS-directed social cooperation can select a conditional defection strategy prior to the emergence of QS-mutant defectors, depending on resource availability. Conditional defectors represent a QS-inactive state of wild type (cooperator) individual and can invade QS-activated cooperators by adopting a cheating strategy, and then revert to cooperating when there are abundant nutrient supplies irrespective of the exploitation of QS-mutant defector. Our mathematical modeling further demonstrates that the incorporation of conditional defection strategy into the framework of iterated public goods game with sound punishment mechanism can lead to the coexistence of cooperator, conditional defector, and defector in a rock-paper-scissors dynamics. Conclusions These findings highlight the importance of behavioral heterogeneity in stabilizing the population structure and provide a potential reasonable explanation for the maintenance and evolution of cooperation in microbial communities.

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