Mitigating exotic impacts: restoring deer mouse populations elevated by an exotic food subsidy

The threat posed by exotic organisms to native systems has led to extensive research on exotic invaders, yet management of invasives has progressed relatively slowly. This is partly due to poor understanding of how exotic species management influences native organisms. To address this shortfall, we...

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Bibliographic Details
Published in:Ecological applications 2008-03, Vol.18 (2), p.321-334
Main Authors: Pearson, D.E, Fletcher, R.J. Jr
Format: Article
Language:English
Subjects:
Animal traps
Animals
Applied ecology
biological control agents
Centaurea - drug effects
Centaurea maculosa
Centaurea stoebe subsp. stoebe
community ecology
Conservation of Natural Resources
demography
Depopulation
Ecological invasion
Ecosystem
exotic species
Food
Food Chain
food limitation
Food movements
food resources
Food security
Food supply
Herbicides
Herbicides - pharmacology
Insecta - physiology
invasive species
Mice
movement
Natural resources
Peromyscus - physiology
Peromyscus maniculatus
Pest Control
population biology
Population Dynamics
population ecology
spotted knapweed
survival
Time Factors
Urophora
Urophora spp
weed control
weeds
wildlife food habits
wildlife management
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Summary:The threat posed by exotic organisms to native systems has led to extensive research on exotic invaders, yet management of invasives has progressed relatively slowly. This is partly due to poor understanding of how exotic species management influences native organisms. To address this shortfall, we experimentally evaluated the efficacy of an invasives management tool for restoring native deer mouse (Peromyscus maniculatus) populations elevated by exotic species. The exotic insects, Urophora spp., were introduced in North America for biological control of the Eurasian invader, spotted knapweed (Centaurea maculosd), but instead of controlling C. maculosa, Urophora have become an important food resource that doubles P. maniculatus populations, with substantial indirect effects on other organisms. We hypothesized that herbicide suppression of Urophora's host plant would reduce the Urophora food resource and restore P. maniculatus populations to natural levels. Prior to treatment, mouse populations did not differ between controls and treatments, but following treatment, P. maniculatus were half as abundant where treatment reduced Urophora. Peromyscus maniculatus is insensitive to direct herbicide effects, and herbicide-induced habitat changes could not explain the P. maniculatus response. Treatment-induced reductions of the Urophora food resource offered the most parsimonious explanation for the mouse response. Multistate mark-recapture models indicated that P. maniculatus survival declined where Urophora were removed, and survival rates were more correlated with variation in population size than movement rates. Other demographic and reproductive parameters (sex ratios, reproductive status, pregnancy rates, and juvenile recruitment) were unaffected by treatment. These results suggest the Urophora biocontrol elevated P. maniculatus survival, and the herbicide treatment restored mouse populations by removing the exotic food and reducing survival. This work illustrates the importance of mechanistic understandings of community and population ecology for improving invasive species management.
ISSN:1051-0761
1939-5582
DOI:10.1890/07-0766.1