Fluctuations in density of an outbreak species drive diversity cascades in food webs

Eveleigh, Eldon S.; McCann, Kevin S.; McCarthy, Peter C.; Pollock, Steven J.; Lucarotti, Christopher J.; Morin, Benoit; McDougall, G. A.; Strongman, D. B.; Huber, John; Umbanhowar, James; Faria, Lucas Del Bianco

doi:10.1073/pnas.0704301104

Cited by 184 publications

(265 citation statements)

References 32 publications

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“…Moreover, insights into the temporal and spatial nature of defoliator outbreaks have come to form the basis of pest management strategies, which is perhaps best illustrated in the long-standing debate over whether to manage spruce budworm outbreaks through a "foliage protection" versus "population control" strategy (Royama 1984;Régnière et al 2012). Another important contribution of this work has been confirmation of the importance of forestry practices in affecting the behaviour and structure of defoliator populations (e.g., forest fragmentation, Roland 1993Roland , 2005precommercial thinning, Moreau et al 2006b; forest composition, Eveleigh et al 2007). Understanding the role forest composition and structure play in shaping outbreaks provides a basis for selecting silvicultural practices aimed at reducing forest susceptibility to defoliator damage.…”

Section: Discussionmentioning

confidence: 98%

Population studies of tree-defoliating insects in Canada: a century in review

et al. 2016

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Abstract-Our review highlights research during the past century focussed on the population ecology of outbreak-prone insect defoliators in Canadian forests. Based on reports from national and provincial surveys that began in the 1930s, there have been at least 106 insect defoliators reported to outbreak, most of which are native Lepidoptera, Hymenoptera (sawflies), or Coleoptera (in order of frequency from most to least). Studies comparing life-history traits of outbreak versus non-outbreak species to better understand why certain species are more outbreak-prone indicate several traits especially common among outbreak species, including egg clustering and aggregative larval feeding. There have been at least 50 time-series studies examining the spatiotemporal population behaviour of 12 major defoliator species. These studies provide evidence for both regular periodicity and spatial synchrony of outbreaks for most major species. Life-table studies seeking to understand the agents causing populations to fluctuate have been carried out for at least seven outbreak species, with the majority identifying natural enemies (usually parasitoids) as the major driver of outbreak collapse. Our review concludes with several case studies highlighting the impact and historical underpinnings of population studies for major defoliator species and a discussion of potential avenues for future research.

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Section: Discussionmentioning

confidence: 98%

Population studies of tree-defoliating insects in Canada: a century in review

et al. 2016

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“…For example, in the conifer forests of northern North America, Nosema fumiferanae is a microsporidium that is considered a regulating component of outbreaks of the eastern spruce budworm, Choristoneura fumiferana (Régnière 1984;van Frankenhuyzen et al 2007). Extensive defoliating outbreaks of this moth occur in 35-40 year cycles (Royama 1984;Boulanger & Arseneault 2004), in which N. fumiferanae and other entomopathogens and parasites increase and decrease with host density and can dampen the outbreaks (Eveleigh et al 2007). In the extended periods between budworm outbreaks, N. fumiferanae maintains infection across seasonal generations via transovarial transmission (Eveleigh et al 2012).…”

Section: Gypsy Moth: Nosema Lymantriae and Vairimorpha Disparismentioning

confidence: 99%

Microsporidia Biological Control Agents and Pathogens of Beneficial Insects

Bjørnson

2014

Microsporidia

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“…Recent reports suggest that consumers may temporally change diet through learning and phenotypic plasticity (Kause et al 1999;Dukas & Bernays 2000;Egas & Sabelis 2001), which may provide a potential driving force for the introduction of temporal variability in food-web structure (Warren 1989;Winemiller 1990;Eveleigh et al 2007). Given this inherent flexibility in trophic interactions (MacArthur & Pianka 1966;Murdock 1969;Stephens & Krebs 1986), an environmental change that may alter a predator's diet selection behaviour (e.g.…”

Section: Introductionmentioning

confidence: 99%

Food-chain length and adaptive foraging

Kondo

Ninomiya

2009

Proc. R. Soc. B.

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Food-chain length, the number of feeding links from the basal species to the top predator, is a key characteristic of biological communities. However, the determinants of food-chain length still remain controversial. While classical theory predicts that food-chain length should increase with increasing resource availability, empirical supports of this prediction are limited to those from simple, artificial microcosms. A positive resource availability -chain length relationship has seldom been observed in natural ecosystems. Here, using a theoretical model, we show that those correlations, or no relationships, may be explained by considering the dynamic food-web reconstruction induced by predator's adaptive foraging. More specifically, with foraging adaptation, the food-chain length becomes relatively invariant, or even decreases with increasing resource availability, in contrast to a non-adaptive counterpart where chain length increases with increasing resource availability; and that maximum chain length more sharply decreases with resource availability either when species richness is higher or potential link number is larger. The interactive effects of resource availability, adaptability and community complexity may explain the contradictory effects of resource availability in simple microcosms and larger ecosystems. The model also explains the recently reported positive effect of habitat size on food-chain length as a result of increased species richness and/or decreased connectance owing to interspecific spatial segregation.

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Fluctuations in density of an outbreak species drive diversity cascades in food webs

Cited by 184 publications

References 32 publications

Population studies of tree-defoliating insects in Canada: a century in review

Population studies of tree-defoliating insects in Canada: a century in review

Microsporidia Biological Control Agents and Pathogens of Beneficial Insects

Food-chain length and adaptive foraging

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