Explaining mountain pine beetle dynamics: From life history traits to large, episodic outbreaks

The Mountain pine beetle (MPB) is a destructive forest pest that undergoes boom-bust cycles every 20-40 years. It also has unusual life-history traits, including a chemosensory affinity for large pine trees, coordinated attacks facilitated by aggregation and anti-aggregation pheromones, and variable dispersal that increases in the absence of trees. Using an empirically calibrated model, we show that MPB's distinctive life-history characteristics are responsible for its distinctive population dynamics. Specifically, three life-history traits are necessary for episodic boom-bust dynamics: density-dependent dispersal, where beetles disperse once most of the large trees have been killed; an Allee effect, which requires a threshold number of beetles to overcome tree defenses; and a short generation time, notably in comparison with their pine tree hosts. In addition to explaining the qualitative behavior of MPB dynamics, these three ingredients explain residual tree density, the duration of outbreaks, and the average waiting time between outbreaks. The peak number of beetles, believed to be the primary factor driving range expansion, is mostly a consequence of MPB's constitutive high fecundity. However, two life history traits -- MPB's size-dependent fecundity and preference for large trees -- are responsible for 25% of the peak number of beetles. By identifying patterns across the extensive MPB literature, and by integrating data across multiple sources, we develop a highly accurate description of MPB's density-dependent interactions with lodgepole pine. We conclude with a simplified mechanistic model, distilled to two difference equations, effectively capturing the essence of MPB outbreak dynamics.