2019
DOI: 10.1101/770156
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Understanding the evolution of interspecies interactions in microbial communities

Abstract: 20Microbial communities are complex multi-species assemblages that are characterized by a 21 multitude of interspecies interactions, which can range from mutualism to competition. The 22The next step will be to test these hypotheses experimentally and provide input for a more 38 refined version of the model in turn, thus closing the scientific cycle of models and 39 experiments. 40 control the processes that they mediate [7,8]. 51 52 Microbial communities, like all complex systems, are more than the sum of the… Show more

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Cited by 4 publications
(4 citation statements)
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References 144 publications
(118 reference statements)
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“…In contrast, if protection is provided by multiple species present in the community, or by the physical properties of the community (e.g., biofilm matrix), collective resistance or tolerance would likely be more stable due to relatively higher functional redundancy of “protection” within the community. Ecological stability of collective resistance and collective tolerance could thus alter the length of antibiotic exposure, and therefore alter the timescales in which selection for resistance can act [ 67 , 68 ]. Inactivation of antibiotics may result in transient and short-lived antibiotic exposure leading to changes at ecological rather than evolutionary timescales, that is, changes in the composition and frequencies of different species within the community similar to the effect of ecological disturbances.…”
Section: Ecological Context Can Influence the Selection For Antimicrobial Resistancementioning
confidence: 99%
“…In contrast, if protection is provided by multiple species present in the community, or by the physical properties of the community (e.g., biofilm matrix), collective resistance or tolerance would likely be more stable due to relatively higher functional redundancy of “protection” within the community. Ecological stability of collective resistance and collective tolerance could thus alter the length of antibiotic exposure, and therefore alter the timescales in which selection for resistance can act [ 67 , 68 ]. Inactivation of antibiotics may result in transient and short-lived antibiotic exposure leading to changes at ecological rather than evolutionary timescales, that is, changes in the composition and frequencies of different species within the community similar to the effect of ecological disturbances.…”
Section: Ecological Context Can Influence the Selection For Antimicrobial Resistancementioning
confidence: 99%
“…Together with abiotic factors, species interactions determine community structure (Little et al ., 2008; Nadell et al ., 2016) and impact evolution (Celiker and Gore, 2013; Mitri and Foster, 2013). The positive or negative influence and the strength of direct and indirect interactions in communities may vary with space and time, although how time regulates interactions is not yet well understood (Gorter et al ., 2020). Ultimately, the selection of traits and, hence, the nature of interactions depend on the environment, which may favour or disfavour relations depending on their effects on fitness (Fig.…”
Section: The Cooperation – Competition Continuummentioning
confidence: 99%
“…Prior studies of community-level eco-evolutionary dynamics, which have explored the evolution of species interactions abstractly or the specific traits that determine such interactions (4345), focused on niche-based food web models (i.e., those involving resource consumption) rather than the non-resource based antagonistic interactions that characterize our work. Even when studies did investigate antagonistic interactions and resultant species dynamics, they emphasized very slow mutation regimes and assumed a separation of ecological and evolutionary timescales (4648). Such assumptions do not work very well for microbial systems, where high mutation rates and extensive horizontal gene transfers are commonplace, creating an overlap of ecological and evolutionary timescales (4750).…”
Section: Introductionmentioning
confidence: 99%
“…Such assumptions do not work very well for microbial systems, where high mutation rates and extensive horizontal gene transfers are commonplace, creating an overlap of ecological and evolutionary timescales (4750). These eco-evolutionary feedbacks can affect the nature of trait evolution (48) and even destabilize species interactions (51). Recent models exploring these fast-evolving regimes in antibiotic-mediated antagonistic communities have uncovered mechanisms responsible for de novo assembly of diverse microbial communities with higher-order interactions, but such results are qualitatively different from what is possible when mutation is rare (38, 47).…”
Section: Introductionmentioning
confidence: 99%