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Vicente J Ontiveros1, José A Capitán1,2, Emilio O Casamayor3

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Summary
This summary is machine-generated.

Fitness equalizing mechanisms, like trade-offs, are key to species coexistence. This study reveals these mechanisms are significant in bacterial communities, with rare or core taxa driving trade-offs in different environments.

Keywords:
colonization–extinction dynamicsfitness equalizationnatural bacterial communitiesneutral theoryspecies coexistencespecies sorting

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Area of Science:

  • Community Ecology
  • Microbial Ecology
  • Theoretical Ecology

Background:

  • Fitness equalizing mechanisms, such as trade-offs, are crucial for species coexistence in community ecology.
  • These mechanisms are understudied in highly diverse microbial communities, where coexistence is often attributed to niche differentiation and high dispersal.
  • The principle 'everything is everywhere, but the environment selects' often guides microbial community dynamics.

Purpose of the Study:

  • To investigate the role of fitness equalizing mechanisms in promoting species coexistence within bacterial communities.
  • To analytically derive colonization-persistence trade-offs under fitness equalization assumptions.
  • To identify signals of these trade-offs in natural bacterial communities and determine which species subsets drive them.

Main Methods:

  • Utilized a dynamical stochastic model grounded in island biogeography theory.
  • Analyzed temporal dynamics of bacterial communities across three distinct systems: soils, alpine lakes, and shallow saline lakes.
  • Assumed fitness equalization mechanisms to derive and test for colonization-persistence trade-offs.

Main Results:

  • Successfully derived colonization-persistence trade-offs analytically under fitness equalization.
  • Detected evidence of these trade-offs in natural bacterial communities across the studied systems.
  • Demonstrated that rare taxa drive the trade-off in aquatic communities (alpine lakes, saline lakes), while core taxa drive it in soil communities.

Conclusions:

  • Equalizing mechanisms, particularly colonization-persistence trade-offs, play a more significant role in bacterial community dynamics than previously recognized.
  • Different species subsets (rare vs. core) are responsible for driving these trade-offs in distinct environmental contexts.
  • Dynamical models are essential for understanding temporal patterns and processes in highly diverse microbial communities.