Your search keyword '"Janssen, Arne"' showing total 27 results

1. Herbivore Host Plant Selection: Whitefly Learns to Avoid Host Plants That Harbour Predators of Her Offspring

Author

Janssen, Arne and Sabelis, Maurice W.

Published

2003

2. Flexible Antipredator Behaviour in Herbivorous Mites through Vertical Migration in a Plant

Author

Magalhães, Sara, Janssen, Arne, Hanna, Rachid, and Sabelis, Maurice W.

Published

2002

3. Evolution of Herbivore-Induced Plant Volatiles

Author

Janssen, Arne, Sabelis, Maurice W., and Bruin, Jan

Published

2002

4. Odour-Mediated Responses of Phytophagous Mites to Conspecific and Heterospecific Competitors

Author

Janssen, Arne and Sabelis, Maurice W.

Published

1997

5. Herbivore Benefits from Vectoring Plant Virus through Reduction of Period of Vulnerability to Predation

Author

Belliure, Belén, Janssen, Arne, and Sabelis, Maurice W.

Published

2008

6. Can Plants Use an Entomopathogenic Virus as a Defense against Herbivores?

Author

van Munster, Manuela, Janssen, Arne, Clérivet, Alain, and van den Heuvel, Johannes

Published

2005

7. Enhanced top‐down control of herbivore population growth on plants with impaired defences.

Author

Legarrea, Saioa, Janssen, Arne, Dong, Lin, Glas, Joris J., van Houten, Yvonne M., Scala, Alessandra, and Kant, Merijn R.

Subjects

*PLANT defenses, *PLANT populations, *PLANT growth, *BIOLOGICAL pest control, *PREDATORY mite, *HERBIVORES, *TROPHIC cascades

Abstract

Herbivore densities can be regulated by bottom‐up and top‐down forces such as plant defences and natural enemies, respectively. These forces can interact with each other to increase plant protection against herbivores; however, how much complementarity exists between bottom‐up and top‐down forces still remains to be fully elucidated. Particularly, because plant defences can hinder natural enemies, how these interactions affect herbivore performance and dynamics remains elusive.To address this topic, we performed laboratory and greenhouse bioassays with herbivorous mite pests and predatory mites on mutant tomato plants that lack defensive hairs on stems and leaves. Particularly, we investigated the behaviour and population dynamics of different phytophagous mite species in the absence and presence of predatory mites.We show that predatory mites do not only perform better on tomatoes lacking defensive hairs but also that they can suppress herbivore densities better and faster on these hairless plants. Hence, top‐down control of herbivores by natural enemies more than compensated the reduced bottom‐up herbivore control by plant defences.Our results lead to the counter‐intuitive insight that removing, instead of introducing, plant defence traits can result in superior protection against important pests through biological control. Read the free Plain Language Summary for this article on the Journal blog. [ABSTRACT FROM AUTHOR]

Published

2022

8. Mite damage provides refuges and affects preference and performance of a subsequent herbivorous moth.

Author

Paz‐Neto, Antônio de Almeida, Calvet, Érica Costa, Melo, José Wagner da Silva, de Lima, Debora Barbosa, Gondim, Manoel Guedes Correa, and Janssen, Arne

Subjects

CATERPILLARS, MITES, MOTHS, PLANT anatomy, PLANT physiology, PYRALIDAE, HERBIVORES

Abstract

Damage by herbivores often modifies plant structure and physiology, which may change the behaviour and performance of future herbivores. Here, we studied such interactions among the major coconut pest, the mite Aceria guerreronis (Acari: Eriophyidae), and two minor pests, the mite Steneotarsonemus concavuscutum (Acari: Tarsonemidae) and the moth Atheloca bondari (Lepidoptera: Pyralidae). All these species develop in the meristematic zone of coconuts, which is difficult to access because of the small opening between the epicarp and perianth. Both mites cause necrosis on the epicarp of the nuts, which may facilitate access to the meristematic zone by caterpillars of the moth. However, the caterpillars co‐occur predominantly with A. guerreronis and not with S. concavuscutum. We show that caterpillars did not colonize nuts without mites and colonized nuts with A. guerreronis most frequently, in agreement with the openings caused by this mite and caterpillar size. When the opening between epicarp and perianth was artificially increased, caterpillars also colonized nuts without mites and nuts with S. concavuscutum. When offered a choice, caterpillars preferred nuts with easy access to the meristematic region, regardless of the presence of mites. Caterpillars performed better on the A. guerreronis‐infested nuts than on other nuts, but moth females did not preferentially oviposit in coconut bunches infested with mites. Hence, caterpillars, not adults, select suitable feeding sites within a bunch of coconuts, and A. guerreronis facilitates the infestation of coconuts by A. bondari. We discuss how damage by mites affects the relevance of A. bondari as a coconut pest. [ABSTRACT FROM AUTHOR]

Published

2022

9. The distribution of herbivores between leaves matches their performance only in the absence of competitors.

Author

Godinho, Diogo P., Janssen, Arne, Li, Dan, Cruz, Cristina, and Magalhães, Sara

Subjects

*TWO-spotted spider mite, *SPIDER mites, *HERBIVORES, *TETRANYCHUS, *FOLIAGE plants, *PLANT defenses

Abstract

Few studies have tested how plant quality and the presence of competitors interact in determining how herbivores choose between different leaves within a plant. We investigated this in two herbivorous spider mites sharing tomato plants: Tetranychus urticae, which generally induces plant defenses, and Tetranychus evansi, which suppresses them, creating asymmetrical effects on coinfesting competitors. On uninfested plants, both herbivore species preferred young leaves, coinciding with increased mite performance. On plants with heterospecifics, the mites did not prefer leaves on which they had a better performance. In particular, T. urticae avoided leaves infested with T. evansi, which is in agreement with T. urticae being outcompeted by T. evansi. In contrast, T. evansi did not avoid leaves with the other species, but distributed itself evenly over plants infested with heterospecifics. We hypothesize that this behavior of T. evansi may prevent further spread of T. urticae over the shared plant. Our results indicate that leaf age determines within‐plant distribution of herbivores only in absence of competitors. Moreover, they show that this distribution depends on the order of arrival of competitors and on their effects on each other, with herbivores showing differences in behavior within the plant as a possible response to the outcome of those interactions. [ABSTRACT FROM AUTHOR]

Published

2020

10. The omnivorous predator Macrolophus pygmaeus, a good candidate for the control of both greenhouse whitefly and poinsettia thrips on gerbera plants.

Author

Leman, Ada, Ingegno, Barbara L., Tavella, Luciana, Janssen, Arne, and Messelink, Gerben J.

Subjects

GREENHOUSE whitefly, HERBIVORES, THRIPS, BIOLOGICAL pest control, PREDATORY animals, POINSETTIAS, ORNAMENTAL plants

Abstract

The poinsettia thrips Echinothrips americanus Morgan is a relatively new pest that has spread rapidly worldwide and causes serious damage in both vegetable and ornamental plants. In this study, we investigated if and how effective this pest can be controlled in gerbera by the omnivorous predator Macrolophus pygmaeus (Rambur). Because herbivores on plants can interact through a shared predator, we also investigated how poinsettia thrips control is affected by the presence of the greenhouse whitefly Trialeurodes vaporariorum (Westwood), a pest that commonly coexists with E. americanus in gerbera. In laboratory studies, we found that the predator M. pygmaeus fed on both pests when offered together. Olfactometer tests showed a clear preference of the predators for plants infested by whiteflies but not by thrips. In a greenhouse experiment, densities of both pests on single gerbera plants were reduced to very low levels by the predator, either with both pests present together or alone. Hence, predator‐mediated effects between whiteflies and thrips played only a minor role. The plant feeding of the shared predator probably reduced the dependence of predator survival and reproduction on the densities of the two pests, thereby weakening potential predator‐mediated effects. Thus, M. pygmaeus is a good candidate for biological control of both pests in gerbera. However, further research is needed to investigate pest control at larger scales, when the pests can occur on different plants. [ABSTRACT FROM AUTHOR]

Published

2020

11. Herbivores avoid host plants previously exposed to their omnivorous predator Macrolophus pygmaeus.

Author

Zhang, Nina Xiaoning, van Wieringen, Daan, Messelink, Gerben J., and Janssen, Arne

Subjects

HERBIVORES, CHEMICAL plants, HOST plants, GREEN peach aphid, FRANKLINIELLA occidentalis, TWO-spotted spider mite, SPIDER mites

Abstract

Herbivorous arthropods use various cues to choose suitable host plants. We investigated whether three species of herbivores use cues associated with their omnivorous predator Macrolophus pygmaeus to select host plants. Earlier, we found that this omnivore induces plant defences which decreased the performance of two of the herbivores, i.e. the spider mite Tetranychus urticae and the western flower thrips Frankliniella occidentalis, whereas the green peach aphid Myzus persicae was not affected. Hence, the spider mite and thrips were expected to avoid plants that were previously exposed to M. pygmaeus because of their lower quality, and the aphid was not expected to avoid exposed plants because they were of equal quality as unexposed plants. However, the cues left behind by M. pygmaeus may also be indicative of predation risk, in which case all three herbivores were expected to avoid exposed plants. Spider mites and western flower thrips preferred clean plants over plants that had previously been exposed to M. pygmaeus, but no longer harboured this omnivore. Aphids showed no preference, in agreement with their performance, but not in agreement with reducing predation risk. We furthermore showed that the preference of spider mites and thrips for clean plants increased through time. Higher proportions of aphids left plants previously exposed to M. pygmaeus than clean plants through time. Hence, omnivorous predators can decrease herbivore densities on plants not only by killing them but also by indirectly affecting herbivore host plant selection. [ABSTRACT FROM AUTHOR]

Published

2019

12. Herbivore performance and plant defense after sequential attacks by inducing and suppressing herbivores.

Author

Oliveira, Elisa Faria, Pallini, Angelo, and Janssen, Arne

Subjects

PHYTOPHAGOUS insects, HERBIVORES, PLANT defenses, HOST plants, SPIDER mites

Abstract

It is well known that herbivore‐induced plant defenses alter host plant quality and can affect the behavior and performance of later arriving herbivores. Effects of sequential attacks by herbivores that either suppress or induce plant defenses are less well studied. We sequentially infested leaves of tomato plants with a strain of the phytophagous spider mite Tetranychus urticae that induces plant defenses and the closely related Tetranychus evansi, which suppresses plant defenses. Plant quality was quantified through oviposition of both spider mite species and by measuring proteinase inhibitor activity using plant material that had been sequentially attacked by both herbivore species. Spider‐mite oviposition data show that T. evansi could suppress an earlier induction of plant defenses by T. urticae, and T. urticae could induce defenses in plants previously attacked by T. evansi in 1 day. Longer attacks by the second species did not result in further changes in oviposition. Proteinase inhibitor activity levels showed that T. evansi suppressed the high activity levels induced by T. urticae to constitutive levels in 1 day, and further suppressed activity to levels similar to those in plants attacked by T. evansi alone. Attacks by T. urticae induced proteinase inhibitor activity in plants previously attacked by T. evansi, eventually to similar levels as induced by T. urticae alone. Hence, plant quality and plant defenses were significantly affected by sequential attacks and the order of attack does not affect subsequent performance, but does affect proteinase inhibitor activity levels. Based on our results, we discuss the evolution of suppression of plant defenses. [ABSTRACT FROM AUTHOR]

Published

2019

13. Phytophagy of omnivorous predator Macrolophus pygmaeus affects performance of herbivores through induced plant defences.

Author

Zhang, Nina Xiaoning, Messelink, Gerben J., Alba, Juan M., Schuurink, Robert. C., Kant, Merijn R., and Janssen, Arne

Subjects

SPIDER mites, THRIPS, PREDATION, HERBIVORES, SWEET peppers, PLANT defenses, GREEN peach aphid, FRANKLINIELLA occidentalis, REPRODUCTION

Abstract

Plants possess various inducible defences that result in synthesis of specialized metabolites in response to herbivory, which can interfere with the performance of herbivores of the same and other species. Much less is known of the effects of plant feeding by omnivores. We found that previous feeding of the omnivorous predator Macrolophus pygmaeus on sweet pepper plants significantly reduced reproduction of the two-spotted spider mite Tetranychus urticae and western flower thrips Frankliniella occidentalis on the same plants, also on leaves that had not been exposed to the omnivore. In contrast, no effect was found on the reproduction of the green peach aphid Myzus persicae. Juvenile survival and developmental time of T. urticae and M. persicae, and larval survival of F. occidentalis were not affected by plant feeding by M. pygmaeus. Larvae of F. occidentalis feeding on leaves previously exposed to M. pygmaeus required longer to develop into adults. Defence-related plant hormones were produced locally and systemically after exposure to M. pygmaeus. The concentrations of 12-oxo-phytodienoic acid and jasmonic acid-isoleucine in the attacked leaves were significantly higher than in the corresponding leaves on the uninfested plants, and jasmonic acid concentrations showed the same trend, suggesting that jasmonic-acid-related defence pathways were activated. In contrast, similar concentrations of salicylic acid were found in the attacked leaves of M. pygmaeus-infested plants and uninfested plants. Our results show that plant feeding by omnivorous predators decreases the performance of herbivores, suggesting that it induces plant defences. [ABSTRACT FROM AUTHOR]

Published

2018

14. Down-regulation of plant defence in a resident spider mite species and its effect upon con- and heterospecifics.

Author

Godinho, Diogo, Janssen, Arne, Dias, Teresa, Cruz, Cristina, and Magalhães, Sara

Subjects

*DOWNREGULATION, *PLANT defenses, *HERBIVORES, *SPIDER mites, *PROTEINASES, *ANIMAL behavior

Abstract

Herbivorous spider mites occurring on tomato plants ( Solanum lycopersicum L.) cope with plant defences in various manners: the invasive Tetranychus evansi reduces defences below constitutive levels, whereas several strains of T. urticae induce such defences and others suppress them. In the Mediterranean region, these two species co-occur on tomato plants with T. ludeni, another closely related spider mite species. Unravelling how this third mite species affects plant defences is thus fundamental to understanding the outcome of herbivore interactions in this system. To test the effect of T. ludeni on tomato plant defences, we measured (1) the activity of proteinase inhibitors, indicating the induction of plant defences, in those plants, and (2) mite performance on plants previously infested with each mite species. We show that the performance of T. evansi and T. ludeni on plants previously infested with T. ludeni or T. evansi was better than on clean plants, indicating that these two mite species down-regulate plant defences. We also show that plants attacked by these mite species had lower activity of proteinase inhibitors than clean plants, whereas herbivory by T. urticae increased the activity of these proteins and resulted in reduced spider mite performance. This study thus shows that the property of down-regulation of plant defences below constitutive levels also occurs in T. ludeni. [ABSTRACT FROM AUTHOR]

Published

2016

15. Herbivores with similar feeding modes interact through the induction of different plant responses.

Author

Oliveira, Elisa, Pallini, Angelo, and Janssen, Arne

Subjects

PLANT defenses, HERBIVORES, ANIMAL feeding behavior, OVIPARITY, PROTEINASES, DOWNREGULATION, ANIMAL behavior

Abstract

Plants respond to attacks by herbivores with various defences, which are mounted through the activation of different biochemical pathways that are known to interact. Thus, the attack of a plant by one herbivore species may result in changes in the performances of other species on the same plant. It has been suggested that species with comparable feeding modes induce similar plant defences and such herbivores are therefore expected to have a negative effect on each other's performance. We studied two closely related phytophagous mite species with identical feeding modes. Yet, one of the species ( Tetranychus urticae) induces tomato plant defences, whereas the other ( T. evansi) reduces them. We found that the 'inducing' species benefits from the downregulation of defences by the 'reducing' species, which, in turn, suffers from the induction of defences by the inducing species. Moreover, the performances of the two mite species on leaves that were previously attacked by both species simultaneously were intermediate between that on leaves previously attacked by each of the mites separately. The activity of proteinase inhibitor, a defensive compound, was not found to be intermediate in leaves attacked by both species simultaneously-it was almost as high as the activity seen in leaves with defences induced by T. urticae. Oviposition rates of T. urticae showed a nonlinear correlation with inhibitor activity, suggesting that it is potentially problematic to use this activity as an indicator of the level of plant defence. Our results show that herbivores with similar feeding modes have opposite effects on plant defence and differentially affect each other's performance on co-infested plants. [ABSTRACT FROM AUTHOR]

Published

2016

16. A Herbivorous Mite Down-Regulates Plant Defence and Produces Web to Exclude Competitors.

Author

Sarmento, Renato A., Lemos, Felipe, Dias, Cleide R., Kikuchi, Wagner T., Rodrigues, Jean C. P., Pallini, Angelo, Sabelis, Maurice W., and Janssen, Arne

Subjects

PLANT ecology, HERBIVORES, MITES, TETRANYCHUS, PLANT growth, OVIPARITY, PLANT defenses, POISONOUS plants

Abstract

Herbivores may interact with each other through resource competition, but also through their impact on plant defence. We recently found that the spider mite Tetranychus evansi down-regulates plant defences in tomato plants, resulting in higher rates of oviposition and population growth on previously attacked than on unattacked leaves. The danger of such downregulation is that attacked plants could become a more profitable resource for heterospecific competitors, such as the twospotted spider mite Tetranychus urticae. Indeed, T. urticae had an almost 2-fold higher rate of oviposition on leaf discs on which T. evansi had fed previously. In contrast, induction of direct plant defences by T. urticae resulted in decreased oviposition by T. evansi. Hence, both herbivores affect each other through induced plant responses. However, when populations of T. evansi and T. urticae competed on the same plants, populations of the latter invariably went extinct, whereas T. evansi was not significantly affected by the presence of its competitor. This suggests that T. evansi can somehow prevent its competitor from benefiting from the down-regulated plant defence, perhaps by covering it with a profuse web. Indeed, we found that T. urticae had difficulties reaching the leaf surface to feed when the leaf was covered with web produced by T. evansi. Furthermore, T. evansi produced more web when exposed to damage or other cues associated with T. urticae. We suggest that the silken web produced by T. evansi serves to prevent competitors from profiting from downregulated plant defences. [ABSTRACT FROM AUTHOR]

Published

2011

17. A herbivore that manipulates plant defence.

Author

Sarmento, Renato Almeida, Lemos, Felipe, Bleeker, Petra M., Schuurink, Robert C., Pallini, Angelo, Oliveira, Maria Goreti Almeida, Lima, Eraldo R., Kant, Merijn, Sabelis, Maurice W., and Janssen, Arne

Subjects

HERBIVORES, PLANT defenses, JASMONIC acid, PREDATORY animals, MITES, PROTEINASES, ENZYME inhibitors

Published

2011

18. Spider mite web mediates anti-predator behaviour.

Author

Lemos, Felipe, Sarmento, Renato, Pallini, Angelo, Dias, Cleide Rosa, Sabelis, Maurice W., and Janssen, Arne

Subjects

TETRANYCHUS, HERBIVORES, MORTALITY, PREDATION, NATURAL selection, ANIMAL behavior, ANIMAL morphology, LIFE history theory

Abstract

Herbivores suffer significant mortality from predation and are therefore subject to natural selection on traits promoting predator avoidance and resistance. They can employ an array of strategies to reduce predation, for example through changes in behaviour, morphology and life history. So far, the anti-predator response studied most intensively in spider mites has been the avoidance of patches with high predation risk. Less attention has been given to the dense web produced by spider mites, which is a complex structure of silken threads that is thought to hinder predators. Here, we investigate the effects of the web produced by the red spider mite, Tetranychus evansi Baker & Pritchard, on its interactions with the predatory mite, Phytoseiulus longipes Evans. We tested whether female spider mites recognize predator cues and whether these can induce the spider mites to produce denser web. We found that the prey did not produce denser web in response to such cues, but laid more eggs suspended in the web, away from the leaf surface. These suspended eggs suffered less from predation by P. longipes than eggs that were laid on the leaf surface under the web. Thus, by altering their oviposition behaviour in response to predator cues, females of T. evansi protect their offspring. [ABSTRACT FROM AUTHOR]

Published

2010

19. Vector and virus induce plant responses that benefit a non-vector herbivore.

Author

Belliure, Belén, Sabelis, Maurice W., and Janssen, Arne

Subjects

PLANT viruses, DISEASE vectors, PLANT defenses, HERBIVORES, PHYTOPATHOGENIC microorganisms, TOMATO spotted wilt virus disease, ARTHROPODA, THRIPS, OVIPARITY, SPIDER mites

Abstract

Copyright of Basic & Applied Ecology is the property of Urban & Fischer Verlag and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2010

20. Domatia reduce larval cannibalism in predatory mites.

Author

Ferreira, João A. M., Eshuis, Brechtje, Janssen, Arne, and Sabelis, Maurice W.

Subjects

HERBIVORES, FUNGI, FUNGIVORES, DEVELOPMENTAL biology, CLIMATE change, BIODIVERSITY, ENTOMOLOGY, PREDATORY animals, PLANT species

Abstract

1. Acarodomatia are small structures on the underside of leaves of many plant species, which are mainly inhabited by carnivorous and fungivorous mites. 2. Domatia are thought to protect these mites against adverse environmental conditions and against predation. They are considered as an indirect plant defence; they provide shelter to predators and fungivores and these in turn protect the plants against herbivores and fungi. 3. We studied the possible role of domatia of coffee ( Coffea arabica L.) (Rubiaceae) and sweet pepper ( Capsicum annum L.) (Solanaceae) in reducing cannibalism in the mites inhabiting the domatia. We measured cannibalism of larvae by adults of the predatory mites Iphiseiodes zuluagai Denmark & Muma and Amblyseius herbicolus Chant on coffee leaf discs and of the predatory mite Iphiseius degenerans (Berl.) on sweet pepper leaf. Domatia were closed with glue or left open. 4. Cannibalism in all three species increased when domatia were closed. With I. degenerans, moreover, we found that the previous diet of the cannibal attenuated the effect of domatia on cannibalism. 5. We conclude that domatia can protect young predatory mites against cannibalism by adults and that the diet of cannibals affects the rate of cannibalism. [ABSTRACT FROM AUTHOR]

Published

2008

21. Do domatia mediate mutualistic interactions between coffee plants and predatory mites?

Author

Matos, Cláudia H. C., Pallini, Angelo, Chaves, Fredson F., Schoereder, José H., and Janssen, Arne

Subjects

MITES, COFFEE, PHYTOSEIIDAE, RUBIACEAE, ARACHNIDA, HERBIVORES, PREDATORY animals

Abstract

Many plant species possess structures on their leaves that often harbour predatory or fungivorous mites. These so-called domatia are thought to mediate a mutualistic interaction; the plant gains protection because mites decimate plant pathogenic fungi or herbivores, whereas the mites find shelter in the domatia. We tested this hypothesis using two species of coffee ( Coffea spp.) plants that posses domatia consisting of small cavities at the underside of the leaves, and which often harbour mites. We assessed densities of domatia, of the predatory mite Iphiseiodes zuluagai Denmark and Muma (Acari: Phytoseiidae) and of herbivorous mites Oligonychus ilicis (McGregor) (Acari: Tetranychidae) and Brevipalpus phoenicis (Geijskes) (Acari: Tenuipalpidae) on Coffea arabica L. (Rubiaceae) and Coffea canephora Pierre in the field. Over a period of 50 days, C. arabica harboured on average 7.5 times more predatory mites and 0.4–0.66 fewer prey mites than C. canephora. Hence, the higher density of predatory mites on C. arabica could not be explained by higher densities of prey. However, the density of domatia on C. arabica was on average 1.65 times higher than on C. canephora, and within each species, leaves with higher densities of domatia also harboured more predators. This suggests a positive effect of domatia on predatory mites. In the laboratory, survival of adult female predatory mites on leaves of C. arabica with open domatia was indeed significantly higher than on leaves with closed domatia. Hence, predatory mites benefited from the domatia. However, plants with higher densities of domatia did not harbour fewer herbivores. Taken together, our study only provides partial evidence for a mutualistic interaction between coffee plants and predatory mites, mediated by domatia. [ABSTRACT FROM AUTHOR]

Published

2006

22. Can plants betray the presence of multiple herbivore species to predators and parasitoids? The role of learning in phytochemical information networks.

Author

Takabayashi, Junji, Sabelis, Maurice, Janssen, Arne, Shiojiri, Kaori, and Wijk, Michiel

Subjects

ARTHROPODA, HERBIVORES, PREDATORY animals, PARASITOIDS, PHYTOCHEMICALS, BOTANICAL chemistry

Abstract

In response to feeding by phytophagous arthropods, plants emit volatile chemicals. This is shown to be an active physiological response of the plant and the released chemicals are therefore called herbivore-induced plant volatiles (HIPV). One of the supposed functions of HIPV for the plant is to attract carnivorous natural enemies of herbivores. Depending on which plant and herbivore species interact, blends of HIPV show qualitative and quantitative variation. Hence, one may ask whether this allows the natural enemies to discriminate between volatiles from plants infested by herbivore species that are either suitable or unsuitable as a food source for the natural enemy. Another question is whether natural enemies can also recognise HIPV when two or more herbivore species that differ in suitability as a food source simultaneously attack the same plant species. By reviewing the literature we show that arthropod predators and parasitoids can tell different HIPV blends apart in several cases of single plant–single herbivore systems and even in single plant–multiple herbivore systems. Yet, there are also cases where predators and parasitoids do not discriminate or discriminate only after having learned the association between HIPV and herbivores that are either suitable or non-suitable as a source of food. In this case, suitable herbivores may profit from colonising plants that are already infested by another non-suitable herbivore. The resulting temporal or partial refuge may have important population dynamical consequences, as such refuges have been shown to stabilise otherwise unstable predator–prey models of the Lotka-Volterra or Nicholson-Bailey type. [ABSTRACT FROM AUTHOR]

Published

2006

23. Herbivore arthropods benefit from vectoring plant viruses.

Author

Belliure, Belén, Janssen, Arne, Maris, Paul C., Peters, Dick, and Sabelis, Maurice W.

Subjects

*HERBIVORES, *ARTHROPODA, *FRANKLINIELLA, *TOMATOES, *VIRUSES

Abstract

Plants infected with pathogens often attract the pathogens’ vectors, but it is not clear if this is advantageous to the vectors. We therefore quantified the direct and indirect (through the host plant) effects of a pathogen on its vector. A positive direct effect of the plant-pathogenicTomato spotted wilt viruson its thrips vector (Frankliniella occidentalis) was found, but the main effect was indirect; juvenile survival and developmental rate of thrips was lower on pepper plants that were damaged by virus-free thrips than on unattacked plants, but such negative effects were absent on plants that were damaged and inoculated by infected thrips or were mechanically inoculated with the virus. Hence, potential vectors benefit from attacking plants with virus because virus-infected plants are of higher quality for the vector's offspring. We propose that plant pathogens in general have evolved mechanisms to overcome plant defences against their vectors, thus promoting pathogen spread. [ABSTRACT FROM AUTHOR]

Published

2005

24. Herbivore host plant selection: whitefly learns to avoid host plants that harbour predators of her offspring.

Author

Nomikou, Maria, Janssen, Arne, and Sabelis, Maurice W.

Subjects

*HERBIVORES, *ANIMALS, *FLORIVORES, *HOST plants, *AGRICULTURAL pests, *PREDATORY animals

Abstract

Evidence is accumulating that herbivorous arthropods do not simply select host plants based on their quality, but also on the predation risk associated with different host plants. It has been suggested that herbivores exclude plant species with high predation risk from their host range. This assumes a constant, predictable predation risk as well as a rather static behaviour on the part of the herbivore; plants are ignored irrespective of the actual predation risk. We show that adult females of a small herbivore, the whitefly Bemisia tabaci, can learn to avoid plants with predatory mites that attack only juvenile whiteflies, while they accept host plants of the same species without predators. Predatory mites disperse more slowly than whiteflies; they cannot fly and walk from plant to plant. Hence, by avoiding plants with predators, the whiteflies create a temporary refuge for their offspring. We suggest that the experience of arthropod herbivores with risks associated with host plants plays an important role in their host plant selection. [ABSTRACT FROM AUTHOR]

Published

2003

25. An ecological cost of plant defence: attractiveness of bitter cucumber plants to natural enemies of herbivores.

Author

Agrawal, Anurag A, Janssen, Arne, Bruin, Jan, Posthumus, Maarten A, and Sabelis, Maurice W

Subjects

*CUCUMBERS, *HERBIVORES, *PLANT defenses

Abstract

Abstract Plants produce defences that act directly on herbivores and indirectly via the attraction of natural enemies of herbivores. We examined the pleiotropic effects of direct chemical defence production on indirect defence employing near-isogenic varieties of cucumber plants (Cucumis sativus ) that differ qualitatively in the production of terpenoid cucurbitacins, the most bitter compounds known. In release–recapture experiments conducted in greenhouse common gardens, blind predatory mites were attracted to plants infested by herbivorous mites. Infested sweet plants (lacking cucurbitacins), however, attracted 37% more predatory mites than infested bitter plants (that produce constitutive and inducible cucurbitacins). Analysis of the headspace of plants revealed that production of cucurbitacins was genetically correlated with large increases in the qualitative and quantitative spectrum of volatile compounds produced by plants, including induced production of (E )-β-ocimene (3E )-4,8-dimethyl-1,3,7-nonatriene, (E ,E )-α-farnesene, and methyl salicylate, all known to be attractants of predators. Nevertheless, plants that produced cucurbitacins were less attractive to predatory mites than plants that lacked cucurbitacins and predators were also half as fecund on these bitter plants. Thus, we provide novel evidence for an ecological trade-off between direct and indirect plant defence. This cost of defence is mediated by the effects of cucurbitacins on predator fecundity and potentially by the production of volatile compounds that may be repellent to predators. [ABSTRACT FROM AUTHOR]

Published

2002

26. Correction to: Phytophagy of omnivorous predator Macrolophus pygmaeus affects performance of herbivores through induced plant defences.

Author

Zhang, Nina Xiaoning, Messelink, Gerben J., Alba, Juan M., Schuurink, Robert. C., Kant, Merijn R., and Janssen, Arne

Subjects

PREDATION, HERBIVORES, PLANT defenses

Abstract

Unfortunately, the citation of one of the papers was published erroneously in the original version and corrected here by this Erratum. The original article was corrected. [ABSTRACT FROM AUTHOR]

Published

2018

27. No adaptation of a herbivore to a novel host but loss of adaptation to its native host.

Author

Grosman, Amir H., Sabelis, Maurice W., Menken, Steph B.J., Breeuwer, Johannes A.J., Janssen, Arne, Molina-Rugama, Adrián J., Mendes-Dias, Rondinelli, and Pallini, Angelo

Subjects

HERBIVORES, BIOLOGICAL adaptation, ARTHROPODA, GENETIC pleiotropy, GENETIC mutation

Abstract

Most herbivorous arthropods are host specialists and the question is which mechanisms drive the evolution of such specialization. The theory of antagonistic pleiotropy suggests that there is a trade-off between adaptation of herbivores to a novel host and their native host. The mutation accumulation hypothesis proposes that herbivores on a novel host lose their adaptation to the native host through the accumulation of mutations with negligible effects on performance on the novel host. Experimental evidence for either of the two hypotheses is scarce. We compared the fitness of two sympatric moth strains from an introduced host and a native host. The strain from the novel host did not perform better on this host than the strain from the native host. The strain from the novel host performed less well on the native host than did the strain from the native host. Hence, selection on the novel host did not result in noticeable gain in performance, but adaptation to the native host was lost. These results are more readily explained by the mutation-accumulation hypothesis than by the trade-off hypothesis. [ABSTRACT FROM AUTHOR]

Published

2015