Full text

Turn on search term navigation
REFERENCES Abrahamson, W. G., & Blair, C. P.. (2008) Sequential radiation through host-race formation: Herbivore diversity leads to diversity in natural enemies. In K. Tilmon (Ed.), Specialization, speciation, and radiation: The evolutionary biology of herbivorous insects (pp.188202). Berkeley, CA: University of California Press. Agrawal, A. A., Petschenka, G., Bingham, R. A., Weber, M. G., & Rasmann, S. (2012). Toxic cardenolides: Chemical ecology and coevolution of specialized plant–herbivore interactions. New Phytologist, 194, 2845. Ahuja, I., Rohloff, J., & Bones, A. M. (2010). Defence mechanisms of Brassicaceae: Implications for plant-insect interactions and potential for integrated pest management. A review. Agronomy for Sustainable Development, 30, 311348. Ali, J. G., & Agrawal, A. A. (2012). Specialist versus generalist insect herbivores and plant defense. Trends in Plant Science, 17, 293302. Bateman, P. W., & Fleming, P. A. (2009). There will be blood: Autohaemorrhage behaviour as part of the defence repertoire of an insect. Journal of Zoology, 278, 342348. Calcagno, M. P., Avila, J. L., Rudman, I., Otero, L. D., & Alonso-Amelot, M. E. (2004). Food-dependent regurgitate effectiveness in the defence of grasshoppers against ants: The case of bracken-fed Abracris flavolineata (Orthoptera: Acrididae). Physiological Entomology, 29, 123128. Canestrari, D., Bolopo, D., Turlings, T. C., Röder, G., Marcos, J. M., & Baglione, V. (2014). From parasitism to mutualism: Unexpected interactions between a cuckoo and its host. Science, 343, 13501352. Desurmont, G. A., Harvey, J., van Dam, N. M., Cristescu, S. M., Schiestl, F. P., Cozzolino, S., … Danner, H. (2014). Alien interference: Disruption of infochemical networks by invasive insect herbivores. Plant, Cell & Environment, 37, 18541865. Desurmont, G. A., Weston, P. A., & Agrawal, A. A. (2014). Reduction of oviposition time and enhanced larval feeding: Two potential benefits of aggregative oviposition for the viburnum leaf beetle. Ecological Entomology, 39, 125132. Eisner, T., & Aneshansley, D. J. (1999). Spray aiming in the bombardier beetle: Photographic evidence. Proceedings of the National Academy of Sciences, 96, 97059709. Fahey, J. W., Zalcmann, A. T., & Talalay, P. (2001). The chemical diversity and distribution of glucosinolates and isothiocyanates among plants. Phytochemistry, 56, 551. Francis, F., Lognay, G., Wathelet, J.-P., & Haubruge, E. (2001). Effects of allelochemicals from first (Brassicaceae) and second (Myzus persicae and Brevicoryne brassicae) trophic levels on Adalia bipunctata. Journal of Chemical Ecology, 27, 243256. Geervliet, J. B. F., Verdel, M. S. W., Snellen, H., Schaub, J., Dicke, M., & Vet, L. E. M. (2000). Coexistence and niche segregation by field populations of the parasitoids Cotesia glomerata and C. rubecula in the Netherlands: Predicting field performance from laboratory data. Oecologia, 124, 5563. Glauser, G., Schweizer, F., Turlings, T. C., & Reymond, P. (2012). Rapid profiling of intact glucosinolates in arabidopsis leaves by UHPLC-QTOFMS using a charged surface hybrid column. Phytochemical Analysis, 23, 520528. Gols, R., & Harvey, J. A. (2009). Plant-mediated effects in the Brassicaceae on the performance and behaviour of parasitoids. Phytochemistry Reviews, 8, 187206. Gols, R., Wagenaar, R., Bukovinszky, T., Dam, N. M. V., Dicke, M., Bullock, J. M., & Harvey, J. A. (2008). Genetic variation in defense chemistry in wild cabbages affects herbivores and their endoparasitoids. Ecology, 89, 16161626. Grant, J. B. (2006). Diversification of gut morphology in caterpillars is associated with defensive behavior. Journal of Experimental Biology, 209, 30183024. Gross, P. (1993). Insect behavioral and morphological defenses against parasitoids. Annual Review of Entomology, 38, 251273. Hare, J. D. (2011). Ecological role of volatiles produced by plants in response to damage by herbivorous insects. Annual Review of Entomology, 56, 161180. Hartmann, T. (2004). Plant-derived secondary metabolites as defensive chemicals in herbivorous insects: A case study in chemical ecology. Planta, 219, 14. Harvey, J. A., Van Dam, N. M., & Gols, R. (2003). Interactions over four trophic levels: Foodplant quality affects development of a hyperparasitoid as mediated through a herbivore and its primary parasitoid. Journal of Animal Ecology, 72, 520531. Heckel, D. G. (2014) Insect detoxification and sequestration strategies. In C. Voelckel, G. Jander (Ed.), Annual plant reviews vol. 47: Insect-Plant interactions (pp. 77114). John Wiley & Sons, Ltd, Chichester, West Sussex, UK. Higginson, A. D., Delf, J., Ruxton, G. D., & Speed, M. P. (2011). Growth and reproductive costs of larval defence in the aposematic lepidopteran Pieris brassicae. Journal of Animal Ecology, 80, 384392. Hopkins, R. J., van Dam, N. M., & van Loon, J. J. (2009). Role of glucosinolates in insect-plant relationships and multitrophic interactions. Annual Review of Entomology, 54, 5783. Hunter, A. F. (2000). Gregariousness and repellent defences in the survival of phytophagous insects. Oikos, 91, 213224. Karban, R., & Agrawal, A. A. (2002). Herbivore offense. Annual Review of Ecology and Systematics, 33, 641664. Middendorf III, G. A., & Sherbrooke, W. C. (1992). Canid elicitation of blood-squirting in a horned lizard (Phrynosoma cornutum). Copeia, 1992, 519527. Müller, C., Agerbirk, N., & Olsen, C. E. (2003). Lack of sequestration of host plant glucosinolates in Pieris rapae and P. grarricae. Chemoecology, 13, 4754. Nishida, R. (2002). Sequestration of defensive substances from plants by Lepidoptera. Annual Review of Entomology, 47, 5792. Opitz, S. E., & Müller, C. (2009). Plant chemistry and insect sequestration. Chemoecology, 19, 117154. Pasteels, J., Rowell-Rahier, M., & Raupp, M.. (1988) Plant-derived defense in chrysomelid beetles. In P. Barbosa & D. K. Letourneau (Ed.), Novel aspects of insect-plant interactions (pp. 235271). New York, NY: Wiley. Price, P. W., Bouton, C. E., Gross, P., McPheron, B. A., Thompson, J. N., & Weis, A. E. (1980). Interactions among three trophic levels: Influence of plants on interactions between insect herbivores and natural enemies. Annual review of Ecology and Systematics, 11, 4165. Quicke, D. L. (1997). Parasitic wasps. London: Chapman & Hall Ltd. Roessingh, P., Städler, E., Baur, R., Hurter, J., & Ramp, T. (1997). Tarsal chemoreceptors and oviposition behaviour of the cabbage root fly (Delia radicum) sensitive to fractions and new compounds of host-leaf surface extracts. Physiological Entomology, 22, 140148. Rostás, M., & Blassmann, K. (2009). Insects had it first: Surfactants as a defence against predators. Proceedings of the Royal Society B: Biological Sciences, 276, 633638. Schweizer, F., Fernández-Calvo, P., Zander, M., Diez-Diaz, M., Fonseca, S., Glauser, G., … Reymond, P. (2013). Arabidopsis basic helix-loop-helix transcription factors MYC2, MYC3, and MYC4 regulate glucosinolate biosynthesis, insect performance, and feeding behavior. The Plant Cell Online, 25, 31173132. Sword, G. A. (2001). Tasty on the outside, but toxic in the middle: Grasshopper regurgitation and host plant-mediated toxicity to a vertebrate predator. Oecologia, 128, 416421. Tullberg, B. S., & Hunter, A. F. (1996). Evolution of larval gregariousness in relation to repellent defences and warning coloration in tree-feeding Macrolepidoptera: A phylogenetic analysis based on independent contrasts. Biological Journal of the Linnean Society, 57, 253276. Turchin, P., & Kareiva, P. (1989). Aggregation in Aphis varians: An effective strategy for reducing predation risk. Ecology, 70, 10081016. Warham, J. (1977). The incidence, functions, and ecological significance of petrel stomach oils. Proceedings of the New Zealand Ecological Society, 24, 8493. Winde, I., & Wittstock, U. (2011). Insect herbivore counteradaptations to the plant glucosinolate–myrosinase system. Phytochemistry, 72(13), 15661575. Zhukovskaya, M., Yanagawa, A., & Forschler, B. T. (2013). Grooming behavior as a mechanism of insect disease defense. Insects, 4, 609630.
Word count: 1171

Show less

© 2017. This work is published under http://creativecommons.org/licenses/by/4.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.

Abstract

In the arms race between plants, herbivores, and their natural enemies, specialized herbivores may use plant defenses for their own benefit, and variation in plant traits may affect the benefits that herbivores derive from these defenses. Pieris brassicae is a specialist herbivore of plants containing glucosinolates, a specific class of defensive secondary metabolites. Caterpillars of P. brassicae are known to actively spit on attacking natural enemies, including their main parasitoid, the braconid wasp Cotesia glomerata. Here, we tested the hypothesis that variation in the secondary metabolites of host plants affects the efficacy of caterpillar regurgitant as an anti-predator defense. Using a total of 10 host plants with different glucosinolate profiles, we first studied natural regurgitation events of caterpillars on parasitoids. We then studied manual applications of water or regurgitant on parasitoids during parasitization events. Results from natural regurgitation events revealed that parasitoids spent more time grooming after attack when foraging on radish and nasturtium than on Brassica spp., and when the regurgitant came in contact with the wings rather than any other body part. Results from manual applications of regurgitant showed that all parameters of parasitoid behavior (initial attack duration, attack interruption, grooming time, and likelihood of a second attack) were more affected when regurgitant was applied rather than water. The proportion of parasitoids re-attacking a caterpillar within 15 min was the lowest when regurgitant originated from radish-fed caterpillars. However, we found no correlation between glucosinolate content and regurgitant effects, and parasitoid behavior was equally affected when regurgitant originated from a glucosinolate-deficient Arabidopsis thaliana mutant line. In conclusion, host plant affects to a certain extent the efficacy of spit from P. brassicae caterpillars as a defense against parasitoids, but this is not due to glucosinolate content. The nature of the defensive compounds present in the spit remains to be determined, and the ecological relevance of this anti-predator defense needs to be further evaluated in the field.

Details

Title
The spitting image of plant defenses: Effects of plant secondary chemistry on the efficacy of caterpillar regurgitant as an anti-predator defense
Author
Desurmont, Gaylord A 1   VIAFID ORCID Logo  ; Köhler, Angela 1 ; Maag, Daniel 1 ; Laplanche, Diane 1 ; Xu, Hao 1 ; Baumann, Julien 1 ; Demairé, Camille 1 ; Devenoges, Delphine 1 ; Glavan, Mara 1 ; Mann, Leslie 1 ; Turlings, Ted C J 1 

 Institute of Biology, University of Neuchâtel, Neuchâtel, Switzerland 
Pages
6304-6313
Section
ORIGINAL RESEARCH
Publication year
2017
Publication date
Aug 2017
Publisher
John Wiley & Sons, Inc.
e-ISSN
20457758
Source type
Scholarly Journal
Language of publication
English
DOI
https://doi.org/10.1002/ece3.3174
ProQuest document ID
2036324907
Copyright
© 2017. This work is published under http://creativecommons.org/licenses/by/4.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.