Morphological variation associated with dispersal capacity in a tree‐killing bark beetle<i>Dendroctonus ponderosae</i>Hopkins

Shegelski, Victor A.; Evenden, Maya L.; Sperling, Felix A. H.

doi:10.1111/afe.12305

Cited by 13 publications

(18 citation statements)

References 66 publications

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“…Information on parasitoid mobility is scarce and controversial (Jeffs & Lewis, 2013), but the general belief is that parasitoids are less mobile than their hosts (Cronin & Reeve, 2005; Jeffs & Lewis, 2013). However, the ability of insects to disperse is usually associated to body size (Shegelski, Evenden, & Sperling, 2019) and, in our study, the body size of most parasitoids is similar to that of their hosts (unpublished data). We can thus assume similar mobility for hosts and parasitoids.…”

Section: Discussionsupporting

confidence: 66%

Spatial variability of hosts, parasitoids and their interactions across a homogeneous landscape

Torné‐Noguera

Arnán

Rodrigo

et al. 2020

Ecology and Evolution

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Species assemblages and their interactions vary through space, generating diversity patterns at different spatial scales. Here, we study the local-scale spatial variation of a cavity-nesting bee and wasp community (hosts), their nest associates (parasitoids), and the resulting antagonistic network over a continuous and homogeneous habitat. To obtain bee/wasp nests, we placed trap-nests at 25 sites over a 32 km 2 area.We obtained 1,541 nests (4,954 cells) belonging to 40 host species and containing 27 parasitoid species. The most abundant host species tended to have higher parasitism rate. Community composition dissimilarity was relatively high for both hosts and parasitoids, and the main component of this variability was species turnover, with a very minor contribution of ordered species loss (nestedness). That is, local species richness tended to be similar across the study area and community composition tended to differ between sites. Interestingly, the spatial matching between host and parasitoid composition was low. Host β-diversity was weakly (positively) but significantly related to geographic distance. On the other hand, parasitoid and host-parasitoid interaction β-diversities were not significantly related to geographic distance. Interaction β-diversity was even higher than host and parasitoid β-diversity, and mostly due to species turnover. Interaction rewiring between plots and between local webs and the regional metaweb was very low. In sum, species composition was rather idiosyncratic to each site causing a relevant mismatch between hosts and parasitoid composition. However, pairs of host and parasitoid species tended to interact similarly wherever they co-occurred. Our results additionally show that interaction β-diversity is better explained by parasitoid than by host β-diversity. We discuss the importance of identifying the sources of variation to understand the drivers of the observed heterogeneity. K E Y W O R D Sbeta-diversity, homogeneous habitat, host-parasitoid food web, local scale, spatial variation, species interactions, trap-nests | 3697 TORNÉ-NOGUERA ET Al.

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Section: Discussionsupporting

confidence: 66%

Spatial variability of hosts, parasitoids and their interactions across a homogeneous landscape

Torné‐Noguera

Arnán

Rodrigo

et al. 2020

Ecology and Evolution

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“…Although much of this variation can be explained by morphological or physiological factors, some may be genetic, but specific genes that dictate flight capacity in bark beetles have yet to be discovered. Flight mill studies of D. ponderosae illustrate that beetles with similar body condition, size, and mass still exhibit variable flight capacity (Shegelski et al 2019). Multiple approaches to measuring flight capacity and dispersal are required to get an accurate view of dispersal by flight in bark beetles.…”

Section: Flight Capacitymentioning

confidence: 99%

“…Jactel (1993) uses pronotum width as a proxy for body size; Botterweg (1982) and Forsse and Solbreck (1985) use elytra mass and length, respectively; and studies by Evenden et al (2014) and Anderbrant and Schlyter (1989) use beetle mass. It is important to distinguish between these terms as physical body dimensions often do not predict flight capacity of individual bark beetles (Botterweg 1982;Forsse and Solbreck 1985;Jactel 1993;Shegelski et al 2019).…”

Section: Body Massmentioning

confidence: 99%

“…Wing beat frequency increases with wing loading (body mass/wing area), inertia, and resistance. Bark beetle wing size and shape influence these measures and affect wing-beat frequency (Atkins 1960) and subsequent flight capability (Shegelski et al 2019). Wing area is one of the most important morphological factors that influence flight capacity in D. ponderosae (Shegelski et al 2019).…”

Section: Wing Size and Shapementioning

confidence: 99%

“…Flight muscle size also correlates with flight capacity in bark beetles. Wing shape and size contributes to flight capacity in some bark beetles (Shegelski et al 2019), but research into specific genes coding for wing structure is lacking. Flight muscle size seems to be equally important in the prediction of flight capacity in both Dendroctonus and Ips, suggesting that the energetic capacity of large Dendroctonus beetles is a key driver of flight capacity.…”

Section: Evaluation Of Morphological Factors On Flightmentioning

confidence: 99%

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Factors influencing dispersal by flight in bark beetles (Coleoptera: Curculionidae: Scolytinae): from genes to landscapes

et al. 2019

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Dispersal by flight is obligatory for bark beetles in the subfamily Scolytinae. Adult bark beetles must leave the natal host and fly to seek new hosts for brood production. Because of the eruptive nature of some bark beetle populations, dispersal capacity has implications for beetle spread and invasion across the landscape. Bark beetle dispersal can occur over short distances within a stand or over long distances above the forest canopy, where wind aids dispersal. Despite the obvious importance of dispersal for predicting population spread, knowledge gaps in understanding factors that influence bark beetle dispersal remain. In this review, we synthesize information on bark beetle flight to gain a better understanding of this important life history trait. We assess the impact of genetic, physiological, and morphological traits on flight in different bark beetle species. We also consider the impact of abiotic and biotic environmental conditions on flight. We discuss how measurements of these factors could contribute to the development of comprehensive models to better predict spread of bark beetle populations. Through the synthesis of flight research on a variety of bark beetle species, this review provides suggestions for future avenues of research on this important aspect of bark beetle ecology.Résumé : Le vol est le moyen de dispersion obligatoire chez les scolytes dans la sous-famille des Scolytinae. Les scolytes adultes doivent quitter l'hôte où ils sont nés et s'envoler pour chercher de nouveaux hôtes afin d'assurer leur progéniture. À cause de la nature éruptive de certaines populations de scolytes, la capacité de dispersion a des répercussions sur la propagation et l'invasion de l'insecte dans le paysage. La dispersion des scolytes peut survenir sur de courtes distances à l'intérieur d'un peuplement d'arbres ou sur de longues distances au-dessus du couvert forestier où le vent favorise la dispersion. Malgré l'importance évidente de la dispersion pour prédire la propagation de la population, il y a encore des lacunes dans les connaissances concernant la compréhension des facteurs qui influencent la dispersion des scolytes. Dans cette revue de littérature, nous résumons l'information sur le vol des scolytes pour avoir une meilleure compréhension de cet aspect important du cycle vital. Nous évaluons l'impact des traits génétiques, physiologiques et morphologiques sur le vol chez les différentes espèces de scolytes. Nous discutons de la façon dont la mesure de ces facteurs abiotiques et biotiques pourrait contribuer au développement de modèles complets pour mieux prédire la propagation des populations de scolytes. Par le biais de la synthèse de la recherche sur le vol chez une variété d'espèces de scolytes, cette revue de littérature fournit des suggestions pour de futures avenues de recherche sur cet aspect important de l'écologie des scolytes. [Traduit par la Rédaction]

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Can morphological traits explain species‐specific differences in meta‐analyses? A case study of forest beetles

Staton

Girling

Redak

et al. 2023

Ecological Applications

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Meta-analyses have become a valuable tool with which to synthesize effects across studies, but in ecology and evolution, they are often characterized by high heterogeneity, where effect sizes vary between studies. Much of this heterogeneity can be attributed to species-specific differences in responses to predictor variables. Here, we aimed to incorporate a novel trait-based approach to explain species-specific differences in a meta-analysis by testing the ability of morphological traits to explain why the effectiveness of flight-intercept trap design varies according to beetle species, a critical issue in forest pest management. An existing morphological trait database for forest beetles was supplemented, providing trait data for 97 species, while data from a previous meta-analysis on capture rates of bark or woodboring beetles according to different trap designs were updated. We combined these sources by including nine morphological traits as moderators in meta-analysis models, for five different components of trap design. Traits were selected based on theoretical hypotheses relating to beetle movement, maneuverability, and sensory perception. We compared the performance of morphological traits as moderators versus guild, taxonomic family, and null meta-analysis models. Morphological traits for the effect of trap type (panel vs. multiple-funnel) on beetle capture rates improved model fit (AIC c ), reduced within-study variance (σ 2 ), and explained more variation (McFadden's pseudo-R 2 ) compared with null, guild, and taxonomic family models. For example, morphological trait models explained 10% more of the variance (pseudo-R 2 ) when compared with a null model. However, using traits was less informative to explain how detailed elements of trap design such as surface treatment and color influence capture rates. The reduction of within-study variance when accounting for morphological traits demonstrates their potential value for explaining species-specific differences. Morphological traits associated with flight efficiency, maneuverability, and eye size were particularly informative for explaining the effectiveness of trap type. This could lead to improved predictability of optimal trap design according to species. Therefore, morphological

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Morphological variation associated with dispersal capacity in a tree‐killing bark beetleDendroctonus ponderosaeHopkins

Cited by 13 publications

References 66 publications

Spatial variability of hosts, parasitoids and their interactions across a homogeneous landscape

Spatial variability of hosts, parasitoids and their interactions across a homogeneous landscape

Factors influencing dispersal by flight in bark beetles (Coleoptera: Curculionidae: Scolytinae): from genes to landscapes

Can morphological traits explain species‐specific differences in meta‐analyses? A case study of forest beetles

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