Spatial genetic structure of the mountain pine beetle (<i>Dendroctonus ponderosae</i>) outbreak in western Canada: historical patterns and contemporary dispersal

Samarasekera, G. D. N. Gayathri; Bartell, N. V.; Lindgren, B. Staffan; Cooke, Janice E. K.; Davis, Corey S.; James, Patrick M. A.; Coltman, David W.; Mock, Karen E.; Murray, Brent W.

doi:10.1111/j.1365-294x.2012.05587.x

Cited by 59 publications

(88 citation statements)

References 101 publications

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“…These results provide a mechanistic link between two major environmental threats, transport of invasive species and climatedriven range expansions, in that lack of coevolved defense is an important driver of each (41,42,51). Mountain pine beetle has also expanded its northern range, where it is attacking lodgepole pines in historically unexposed areas, and has spread eastward to breach the geophysical barrier of the Rocky Mountains to attack hybrid lodgepole-jack pine, Pinus banksiana, in Alberta, Canada (7,56). Previous dispersal events likely deposited small numbers of beetles in these habitats, but populations quickly collapsed because of Allee effects.…”

Section: Discussionmentioning

confidence: 99%

Temperature-driven range expansion of an irruptive insect heightened by weakly coevolved plant defenses

Raffa¹,

Powell²,

Townsend

2012

Proc. Natl. Acad. Sci. U.S.A.

185

202

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Warming climate has increased access of native bark beetles to high-elevation pines that historically received only intermittent exposure to these tree-killing herbivores. Here we show that a dominant, relatively naïve, high-elevation species, whitebark pine, has inferior defenses against mountain pine beetle compared with its historical lower-elevation host, lodgepole pine. Lodgepole pines respond by exuding more resin and accumulating higher concentrations of toxic monoterpenes than whitebark pine, where they co-occur. Furthermore, the chemical composition of whitebark pine appears less able to inhibit the pheromonal communication beetles use to jointly overcome tree defenses. Despite whitebark pine's inferior defenses, beetles were more likely to attack their historical host in mixed stands. This finding suggests there has been insufficient sustained contact for beetles to alter their complex behavioral mechanisms driving host preference. In no-choice assays, however, beetles readily entered and tunneled in both hosts equally, and in stands containing less lodgepole pine, attacks on whitebark pines increased. High-elevation trees in pure stands may thus be particularly vulnerable to temperature-driven range expansions. Predators and competitors were more attracted to volatiles from herbivores attacking their historical host, further increasing risk in less coevolved systems. Our results suggest cold temperatures provided a sufficient barrier against herbivores for high-elevation trees to allocate resources to other physiological processes besides defense. Changing climate may reduce the viability of that evolutionary strategy, and the life histories of high-elevation trees seem unlikely to foster rapid counter adaptation. Consequences extend from reduced food supplies for endangered grizzly bears to altered landscape and hydrological processes.climate change | coevolution | disturbance | plant-insect interactions | forest insects

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Section: Discussionmentioning

confidence: 99%

Temperature-driven range expansion of an irruptive insect heightened by weakly coevolved plant defenses

Raffa¹,

Powell²,

Townsend

2012

Proc. Natl. Acad. Sci. U.S.A.

185

202

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“…Some modifications to the ecoregion boundaries were made so that their boundaries closely approximated the geographic extent of interbreeding populations of D. ponderosae. Relatively large ecoregions (e.g., Coast Range, Middle Rockies, North Rockies, and Southern Rockies) were subdivided into separate regions based upon the underlying pine forest distribution and topographic features (e.g., river canyons, deserts, and mountains) known to affect movement of D. ponderosae populations (Mock et al 2007;Chen and Walton 2011;Gayathri Samarasekera et al 2012). For example, we created five subregions from the Ecoregion Level III classification of ''Middle Rockies'' to correspond to geographically distinct, forested areas (i.e., Black Hills, Big Horn mountains, Central mountains, Yellowstone Ecosystem, and the western Montana mountains) (Fig.…”

Section: Estimation Of D Ponderosae Abundance and Study Areamentioning

confidence: 99%

Geographically variable response of Dendroctonus ponderosae to winter warming in the western United States

et al. 2015

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Context Milder winters have contributed to recent outbreaks of Dendroctonus ponderosae in Canada, but have not been evaluated as a factor permitting concurrent outbreaks across its large range (ca.1500 9 1500 km) in the western United States (US). Objectives We examined the trend in minimum air temperatures in D. ponderosae habitats across the western US and assessed whether warming winters explained the occurrence of outbreaks using physiological and population models. Methods We used climate data to analyze the history of minimum air temperatures and reconstruct physiological effects of cold on D. ponderosae. We evaluated relations between winter temperatures and beetle abundance using aerial detection survey data.Results Extreme winter temperatures have warmed by about 4°C since 1960 across the western US. At the broadest scale, D. ponderosae population dynamics between 1997 and 2010 were unrelated to variation in minimum temperatures, but relations between cold and D. ponderosae dynamics varied among regions. In the 11 coldest ecoregions, lethal winter temperatures have become less frequent since the 1980s and beetlecaused tree mortality increased-consistent with the climatic release hypothesis. However, in the 12 warmer regions, recent epidemics cannot be attributed to warming winters because earlier winters were not cold enough to kill D. ponderosae. Conclusions There has been pronounced warming of winter temperatures throughout the western US, and this has reduced previous constraints on D. ponderosae abundance in some regions. However, other considerations are necessary to understand the broad extent of recent D. ponderosae epidemics in the western US.

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“…The MPB has been migrating for the past 8000 years, following a northerly expansion of its host tree species. As temperature increased, expansion has been extraordinarily rapid in the past few decades, so rapid that no loss of genetic variability was detected in expanding populations (Samarasekera et al 2012). Our model explains the role of weather in this expansion, and predicts that the pace of population growth in Alberta and northern BC will continue to increase.…”

Section: Modeling Conclusionmentioning

confidence: 87%

“…This irruptive species attacks and kills most Pinus species in western North America (Wood 1982). Genetic data suggest that MPB migrated north following the postglacial Holocene recolonization of British Columbia by several Pinus species (Richardson et al 2002;Mock et al 2007;Godbout et al 2008;Samarasekera et al 2012). Recent warming has increased the speed of this MPB migration into new regions in Alberta, British Columbia, the Yukon, and Northwest Territories, Canada Safranyik et al 2010;Cudmore et al 2010;de la Giroday et al 2012), with exposure to at least one new host tree species, jack pine (Pinus banksiana) (Cullingham et al 2011).…”

mentioning

confidence: 99%

Individual-Based Modeling: Mountain Pine Beetle Seasonal Biology in Response to Climate

Régnière

Bentz

Powell

et al. 2015

Simulation Modeling of Forest Landscape Disturbances

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Spatial genetic structure of the mountain pine beetle (Dendroctonus ponderosae) outbreak in western Canada: historical patterns and contemporary dispersal

Cited by 59 publications

References 101 publications

Temperature-driven range expansion of an irruptive insect heightened by weakly coevolved plant defenses

Temperature-driven range expansion of an irruptive insect heightened by weakly coevolved plant defenses

Geographically variable response of Dendroctonus ponderosae to winter warming in the western United States

Individual-Based Modeling: Mountain Pine Beetle Seasonal Biology in Response to Climate

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