Numbers matter: how irruptive bark beetles initiate transition to self-sustaining behavior during landscape-altering outbreaks

Michael Howe, Kenneth F. Raffa, Brian H. Aukema, Claudio Gratton, Allan L. Carroll

Research output: Contribution to journalArticlepeer-review

13 Scopus citations

Abstract

Irruptive forest insects such as bark beetles undergo intermittent outbreaks that cause landscape-scale tree mortality. Despite their enormous economic and ecological impacts, we still have only limited understanding of the dynamics by which populations transition from normally stable endemic to irruptive densities. We investigated density-dependent changes in mountain pine beetle reliance on stressed hosts, host selection, spatial configuration of attacks, and the interaction of host selection and spatial configuration by performing a complete census of lodgepole pine across six stands and 6 years. In addition, we compared the dynamics of mountain pine beetle with those of other bark beetles. We found that as population size increased, reliance on stressed trees decreased and new attacks shifted to larger trees with thicker phloem and higher growth rates that can support higher offspring production. Moreover, the spatial configuration of beetle-attacked trees shifted from random to spatially aggregated. Further, we found evidence that beetle utilization of larger trees was related to aggregation behavior as the size of tree attacked was positively correlated at 10–25 m, within the effective distance of pheromone-mediated signaling. In contrast, non-irruptive bark beetle species did not exhibit such density-dependent spatial aggregation at the stand scale or switches in host selection behavior. These results identify how density-dependent linkages between spatial configuration and host utilization can converge to drive population transitions from endemic to irruptive phases. Specifically, a combination of stand-level spatial aggregation, behavioral shifts, and higher quality of attainable hosts defines a critical threshold beyond which continual population growth becomes self-driving.

Original languageEnglish (US)
Pages (from-to)681-698
Number of pages18
JournalOecologia
Volume198
Issue number3
DOIs
StatePublished - Mar 2022

Bibliographical note

Funding Information:
This investigation comprised a very large and complex multi-year field study that would not have been possible without invaluable contributions from Douglas Linton, Tony Ibaraki, Greg Smith, Andrew Copeland, Dion Manastyrski and Fred Davis. Funding was generously provided to ALC by Natural Resources Canada—Mountain Pine Beetle Initiative. Further support was provided by the University of Wisconsin–Madison College of Agricultural and Life Sciences, Graduate School and Vilas-Sorenson Professorship. We thank Anthony R. Ives, (UW-Madison) and Guillherme Ludwig (University of Campinas) for helpful conversations on analyzing point patterns.

Publisher Copyright:
© 2022, The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.

Keywords

  • Bark beetles
  • Density dependence
  • Feedbacks
  • Phase transitions
  • Population dynamics
  • Trees
  • Animals
  • Coleoptera
  • Disease Outbreaks
  • Pinus
  • Plant Bark
  • Weevils

PubMed: MeSH publication types

  • Journal Article

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