Intraguild predation enables coexistence of competing phytoplankton in a well-mixed water column

Resource competition theory predicts that when two species compete for a single, finite resource, the better competitor should exclude the other. However, in some cases, weaker competitors can persist through intraguild predation, that is, by eating their stronger competitor. Mixotrophs, species tha...

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Bibliographic Details
Published in:Ecology (Durham) 2019-12, Vol.100 (12), p.1-15
Main Authors: Moeller, Holly V., Neubert, Michael G., Johnson, Matthew D.
Format: Article
Language:English
Subjects:
Animals
Coexistence
community ecology
competition
Constraining
Ecosystem
Heterotrophy
Laboratories
Mathematical analysis
Mathematical models
Micromonas commoda
Mixotrophy
Models, Biological
model‐data comparison
Ochromonas
Photosynthesis
Phytoplankton
Predation
Predators
Predatory Behavior
Species
Species Specificity
Water
Water circulation
Water column
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Summary:Resource competition theory predicts that when two species compete for a single, finite resource, the better competitor should exclude the other. However, in some cases, weaker competitors can persist through intraguild predation, that is, by eating their stronger competitor. Mixotrophs, species that meet their carbon demand by combining photosynthesis and phagotrophic heterotrophy, may function as intraguild predators when they consume the phototrophs with which they compete for light. Thus, theory predicts that mixotrophy may allow for coexistence of two species on a single limiting resource. We tested this prediction by developing a new mathematical model for a unicellular mixotroph and phytoplankter that compete for light, and comparing the model’s predictions with a laboratory experimental system. We find that, like other intraguild predators, mixotrophs can persist when an ecosystem is sufficiently productive (i.e., the supply of the limiting resource, light, is relatively high), or when species interactions are strong (i.e., attack rates and conversion efficiencies are high). Both our mathematical and laboratory models show that, depending upon the environment and species traits, a variety of equilibrium outcomes, ranging from competitive exclusion to coexistence, are possible.
ISSN:0012-9658
1939-9170
DOI:10.1002/ecy.2874