Parsing propagule pressure: Number, not size, of introductions drives colonization success in a novel environment

Predicting whether individuals will colonize a novel habitat is of fundamental ecological interest and is crucial to conservation efforts. A consistently supported predictor of colonization success is the number of individuals introduced, also called propagule pressure. Propagule pressure increases...

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Veröffentlicht in:Ecology and evolution Jg. 8; H. 16; S. 8043 - 8054
Hauptverfasser: Koontz, Michael J., Oldfather, Meagan F., Melbourne, Brett A., Hufbauer, Ruth A.
Format: Journal Article
Sprache:Englisch
Veröffentlicht: England John Wiley & Sons, Inc 01.08.2018
John Wiley and Sons Inc
Wiley
Schlagworte:
Beetles
biocontrol
Colonization
Computer simulation
Conservation
Demographics
Dependence
Environmental quality
Harsh environments
Introduced species
invasion
microcosm
Microcosms
Original Research
population dynamics
Population number
Populations
Pressure
propagule pressure
reintroduction
Simulation
stochasticity
Success
Wildlife conservation
microcosm
conservation
invasion
reintroduction
simulation
propagule pressure
stochasticity
biocontrol
population dynamics
ISSN:2045-7758, 2045-7758
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Zusammenfassung:Predicting whether individuals will colonize a novel habitat is of fundamental ecological interest and is crucial to conservation efforts. A consistently supported predictor of colonization success is the number of individuals introduced, also called propagule pressure. Propagule pressure increases with the number of introductions and the number of individuals per introduction (the size of the introduction), but it is unresolved which process is a stronger driver of colonization success. Furthermore, their relative importance may depend upon the environment, with multiple introductions potentially enhancing colonization of fluctuating environments. To evaluate the relative importance of the number and size of introductions and its dependence upon environmental variability, we paired demographic simulations with a microcosm experiment. Using Tribolium flour beetles as a model system, we introduced a fixed number of individuals into replicated novel habitats of stable or fluctuating quality, varying the number of introductions through time and size of each introduction. We evaluated establishment probability and the size of extant populations through seven generations. We found that establishment probability generally increased with more, smaller introductions, but was not affected by biologically realistic fluctuations in environmental quality. Population size was not significantly affected by environmental variability in the simulations, but populations in the microcosms grew larger in a stable environment, especially with more introduction events. In general, the microcosm experiment yielded higher establishment probability and larger populations than the demographic simulations. We suggest that genetic mechanisms likely underlie these differences and thus deserve more attention in efforts to parse propagule pressure. Our results highlight the importance of preventing further introductions of undesirable species to invaded sites and suggest conservation efforts should focus on increasing the number of introductions or reintroductions of desirable species rather than increasing the size of those introduction events into harsh environments. Increased propagule pressure consistently correlates with colonization success, but it is unclear which of its two key components—the number of introductions or the size of introductions—drives this pattern in different environmental contexts. We pair demographic simulations with a highly replicated microcosm experiment using Tribolium flour beetles to address this open question and find that colonization success is enhanced with more smaller introductions compared to fewer larger introductions in both stable and randomly fluctuating environments. Furthermore, we find that colonization success was greater in the microcosm experiment compared to demographic simulations, which suggests nondemographic mechanisms such as adaptation and expression of genetic load are at work and deserve further attention in efforts to parse propagule pressure.
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ISSN:2045-7758
2045-7758
DOI:10.1002/ece3.4226