Abstract
The enemy release hypothesis (ERH) attributes the success of some exotic plant species to reduced top‐down effects of natural enemies in the non‐native range relative to the native range. Many studies have tested this idea, but very few have considered the simultaneous effects of multiple kinds of enemies on more than one invasive species in both the native and non‐native ranges. Here, we examined the effects of two important groups of natural enemies–insect herbivores and soil biota–on the performance of Tanacetum vulgare (native to Europe but invasive in the USA) and Solidago canadensis (native to the USA but invasive in Europe) in their native and non‐native ranges, and in the presence and absence of competition.In the field, we replicated full‐factorial experiments that crossed insecticide, T. vulgare–S. canadensis competition, and biogeographic range (Europe vs. USA) treatments. In greenhouses, we replicated full‐factorial experiments that crossed soil sterilization, plant–soil feedback, and biogeographic range treatments. We evaluated the effects of experimental treatments on T. vulgare and S. canadensis biomass.The effects of natural enemies were idiosyncratic. In the non‐native range and relative to populations in the native range, T. vulgare escaped the negative effects of insect herbivores but not soil biota, depending upon the presence of S. canadensis; and S. canadensis escaped the negative effects of soil biota but not insect herbivores, regardless of competition. Thus, biogeographic escape from natural enemies depended upon the enemies, the invader, and competition. Synthesis: By explicitly testing the ERH in terms of more than one kind of enemy, more than one invader, and more than one continent, this study enhances our nuanced perspective of how natural enemies can influence the performance of invasive species in their native and non‐native ranges.
Highlights
The enemy release hypothesis (ERH) is a leading explanation for successful biological invasions by exotic plant species
In the non-native range and relative to populations in the native range, T. vulgare escaped the negative effects of insect herbivores but not soil biota, depending upon the presence of S. canadensis; and S. canadensis escaped the negative effects of soil biota but not insect herbivores, regardless of competition
A handful of studies have experimentally shown that natural enemies inhibit invasive plant species more in their native ranges than in their non-native ranges (e.g., DeWalt et al, 2004; Lucero et al, 2019; Williams et al, 2010), but we examined the effects of multiple enemy guilds on more than one invasive species in both ranges
Summary
The enemy release hypothesis (ERH) is a leading explanation for successful biological invasions by exotic plant species. The ERH asserts that biogeographic translocation allows some exotic plant species to leave behind their natural enemies, resulting in relative freedom from top-down controls in non-native communities relative to native communities (Keane & Crawley, 2002) This idea can be tested experimentally by excluding natural enemies in the native and non-native ranges of invaders (Maron & Vilà, 2001). These findings suggest that antagonistic fungi and insect herbivores acted singly and jointly (in a nonlinear fashion) to limit C. hirta survival in the native range but not in the non-native range, as predicted by the ERH This example illustrates how testing the ERH on single enemy guilds in isolation limits our understanding of the effects of natural enemies on invasion trajectories, which in turn hinders our ability to explain, predict, and manage the spread of invasive species. Our field experiments crossed insect exclusion treatments with interspecific competition treatments to account for the possibility that herbivory and competition interacted to influence plant performance
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