Emergence asynchrony between herbivores leads to apparent competition in the field

Blitzer, Eleanor J.; Welter, Stephen C.

doi:10.1890/11-0117.1

Cited by 15 publications

(11 citation statements)

References 30 publications

(41 reference statements)

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“…Despite an overall imprint of phylogenetic relatedness, species with more similar parasitoid communities did not exhibit any more similar (or dissimilar) temporal dynamics than species attacked by distinct parasitoid assemblages. This is consistent with earlier work at the Finnish study site, where a previous multi-year experiment (Tack et al, 2011), as well as a natural experiment (Kaartinen & Roslin, 2013), failed to reveal any detectable impact of increased densities of herbivore species i in year t − 1 on the abundance of herbivore species j (sharing parasitoids with herbivore species i) in year t. This contrasts with empirical field studies showing apparent competition in plant-feeding insects (Blitzer & Welter, 2011;Frost et al, 2016;Morris, Lewis, & Godfray, 2004). Indeed, while parasitism usually causes high mortality in plant feeding insects (Hawkins, Cornell, & Hochberg, 1997), studies have generally failed to find an impact of parasitoids on the pattern of herbivore cycling and outbreak dynamics (Hagen, Jepsen, Schott, & Ims, 2010;Schott, Hagen, Ims, & Yoccoz, 2010).…”

Section: Do Herbivores With Similar Parasitoid Communities Show Morsupporting

confidence: 90%

Related herbivore species show similar temporal dynamics

Blanchet

Roslin

Kimura

et al. 2018

Journal of Animal Ecology

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Within natural communities, different taxa display different dynamics in time. Why this is the case we do not fully know. This thwarts our ability to predict changes in community structure, which is important for both the conservation of rare species in natural communities and for the prediction of pest outbreaks in agriculture. Species sharing phylogeny, natural enemies and/or life-history traits have been hypothesized to share similar temporal dynamics. We operationalized these concepts into testing whether feeding guild, voltinism, similarity in parasitoid community and/or phylogenetic relatedness explained similarities in temporal dynamics among herbivorous community members. Focusing on two similar datasets from different geographical regions (Finland and Japan), we used asymmetric eigenvector maps as temporal variables to characterize species- and community-level dynamics of specialist insect herbivores on oak (Quercus). We then assessed whether feeding guild, voltinism, similarity in parasitoid community and/or phylogenetic relatedness explained similarities in temporal dynamics among taxa. Species-specific temporal dynamics varied widely, ranging from directional decline or increase to more complex patterns. Phylogeny was a clear predictor of similarity in temporal dynamics at the Finnish site, whereas for the Japanese site, the data were uninformative regarding a phylogenetic imprint. Voltinism, feeding guild and parasitoid overlap explained little variation at either location. Despite the rapid temporal dynamics observed at the level of individual species, these changes did not translate into any consistent temporal changes at the community level in either Finland or Japan. Overall, our findings offer no direct support for the notion that species sharing natural enemies and/or life-history traits would be characterized by similar temporal dynamics, but reveal a strong imprint of phylogenetic relatedness. As this phylogenetic signal cannot be attributed to guild, voltinism or parasitoids, it will likely derive from shared microhabitat, microclimate, anatomy, physiology or behaviour. This has important implications for predicting insect outbreaks and for informing insect conservation. We hope that future studies will assess the generality of our findings across plant-feeding insect communities and beyond, and establish the more precise mechanism(s) underlying the phylogenetic imprint.

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Section: Do Herbivores With Similar Parasitoid Communities Show Morsupporting

confidence: 90%

Related herbivore species show similar temporal dynamics

Blanchet

Roslin

Kimura

et al. 2018

Journal of Animal Ecology

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“…The population dynamics of these parasites is likely to have been positively a↵ected by the increase in potential larval hosts (A. levana) between the two time-periods (Morris, Lewis & Godfray, 2004). Moreover, the di↵erences in phenology between A. urticae, A. io, and A. levana may form a breeding ground to stimulate parasites population dynamics as it may also correlate with a prolonged temporal niche for parasites to achieve their reproductive cycle (Blitzer & Welter, 2011). In a scenario of parasite-driven apparent competition, the phenologically late species is expected to be the more vulnerable as its larval growth will coincide with an increase in parasite population size (Blitzer & Welter, 2011).…”

Section: Discussionmentioning

confidence: 99%

Species range expansion constrains the ecological niches of resident butterflies

Audusseau

Vaillant

Janz

et al. 2015

Preprint

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Changes in community composition resulting from climate change entail modifications of biotic interactions and reshape local species distributions. Such changes are currently occurring in nettle-feeding butterflies in Sweden where Araschnia levana has recently expanded its range northward and is now likely to interact with the resident species (Aglais urticae and Aglais io). Butterfly occurrence data collected over years and across regions enabled us to investigate how a recent range expansion of A. levana may have a↵ected the environmental niche of resident species. • We focused on two regions of Sweden (Skåne and Norrström) where A. levanahas and has not established, and two time-periods (2001)(2002)(2003)(2004)(2005)(2006)(2009)(2010)(2011)(2012) corresponding to before and after its establishment.• We performed two distinct analyses in each region using the PCA-env and the framework described in Broennimann et al. (2012). We first described the main sources of variation in the environment. Second, we characterized, in each timeperiod and region, the realized niches of our focal species across topographic and land use gradients. Third, we quantified overlaps and di↵erences in realized niches between and within species over time.• We found indications of niche partitioning between native species, although niche di↵erentiation was not clearly associated to specific environmental factors. Looking over time, we found a larger shift in species distributions of the resident species in Skåne than in Norrström. These shifts showed a consistent pattern of avoiding overlap with the environmental space occupied by A. levana, and it was stronger for A. urticae than for A. io.• Interspecific interactions play a role in shaping species distributions. It seemed clear that the range expansion of A. levana modified local biotic interactions, and potentially induced shifts in resident species distribution. We suggest that parasite-driven apparent competition may mediate niche partitioning in this community.

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“…For example, ELP invaders may subsidize herbivore density when native plants are scarce, essentially preventing some herbivores from starving. ELP-supported herbivore density, then, could more strongly suppress native species (Settle et al 1996, Blitzer andWelter 2011). However, the importance of ELP-mediated apparent competition may depend strongly on the relative palatability of invaders ( Fig.…”

Section: Extended Leaf Phenology May Drive Plant Invasion Through Dirmentioning

confidence: 99%

“…For example, ELP invaders may subsidize herbivore density when native plants are scarce, essentially preventing some herbivores from starving. ELP‐supported herbivore density, then, could more strongly suppress native species (Settle et al , Blitzer and Welter ).…”

mentioning

confidence: 99%

Extended leaf phenology may drive plant invasion through direct and apparent competition

Smith

Hall

2015

Oikos

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Invasive plants can inflict great harm, yet drivers of successful invasion remain unclear. Many invaders of North American deciduous forests exhibit extended leaf phenology (ELP), or longer growing season relative to natives. ELP may grant invaders competitive advantages, but we argue that ELP more potently drives invasion in the presence of herbivores. ELP invaders can support herbivores by lessening starvation during winter; consequently, native plants may suffer when attacked later through apparent competition. As modeled here, even short ELP can promote competitive success of invaders, and apparent competition sharply enhances ELP invader dominance. In 'partial enemy escape' scenarios, a less palatable ELP invader nearly excludes a preferred native where an invader without ELP could not. Together, ELP and apparent competition enhance invasion even when biotic resistance should suppress it, i.e. when the invader competes weakly or provides preferred forage. Thus, ELP-apparent competition interactions grant invaders considerable success while challenging core tenets of invasion ecology.

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Emergence asynchrony between herbivores leads to apparent competition in the field

Cited by 15 publications

References 30 publications

Related herbivore species show similar temporal dynamics

Related herbivore species show similar temporal dynamics

Species range expansion constrains the ecological niches of resident butterflies

Extended leaf phenology may drive plant invasion through direct and apparent competition

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