371 results on '"Multitrophic Interactions (MTI)"'
Search Results
2. Coexistence and niche segregation by field populations of the parasitoids Cotesia glomerata and C. rubecula in the Netherlands: predicting field performance from laboratory data
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Monique S. W. Verdel, H. Snellen, Jacqueline B. F. Geervliet, Marcel Dicke, Louise E. M. Vet, Jasmin Schaub, and Multitrophic Interactions (MTI)
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Pieris brassicae ,biology ,Competition ,Ecology ,fungi ,Parasitism ,food and beverages ,Pieris rapae ,biology.organism_classification ,Cotesia glomerata ,Generalist and specialist species ,Laboratorium voor Entomologie ,Hymenoptera ,Infochemicals ,Parasitoid ,Tritrophic interactions ,Pieris (butterfly) ,Cotesia ,Learning ,EPS ,Laboratory of Entomology ,Ecology, Evolution, Behavior and Systematics - Abstract
Field experiments with foraging parasitoids are essential to validate the conclusions from laboratory studies and to interpret differences in searching and host selection behaviour of parasitoid species. Furthermore, field experiments can indicate whether the parameters measured in the laboratory are relevant to elucidation of the ecological processes under study, such as adaptation or species interactions. In previous extensive laboratory studies we studied plant- and host-searching behaviour, host acceptance, host suitability; host plant preference, and learning of two congeneric parasitoids of Pieris caterpillars: the generalist Cotesia glomerata, which has been reported to attack several Pieridae species, and C. rubecula, a specialist of the small cabbage white Pieris rapae. In the present field study our aim was to verify the importance of these previous laboratory findings for explaining the performance of these two species in the field. We investigated experimentally whether parasitism on three Pieris species varied with parasitoid species and with food plant of the caterpillars. We exposed different types of host plants, infested with different Pieris species, to parasitism by natural populations of Cotesia species, by setting the experimental plants out in Brussels sprouts cabbage fields. Furthermore we made direct observations of parasitoid foraging in the field. In general, the field results confirmed our predictions on the range of host plant and host species used in the field. The two Coresia species appear to coexist through niche segregation, since C. glomerata was mainly recovered from P. brassicae and C. rubecula from P. rapae. Although C. glomerata is a generalist at the species level, it can be a specialist at the population level under certain ecological circumstances. Our study shows the importance of variation in host plant attraction and host species acceptance in restricting host plant and host diet in the field. Furthermore the results suggest that, at least in the Netherlands, specialisation of C. glomerata on P. brassicae may occur as a result of C. rubecula outcompeting C. glomerata in P. rapae larvae [KEYWORDS: hymenoptera; infochemicals; tritrophic interactions; competition; learning]
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- 2017
3. The role of ethylene and darkness in accelerated shoot elongation of Ammophila breviligulata upon sand burial
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W.H. van der Putten, Laurentius A. C. J. Voesenek, C. W. P. M. Blom, M. A. Maun, and Multitrophic Interactions (MTI)
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Biomass (ecology) ,biology ,fungi ,food and beverages ,Context (language use) ,biology.organism_classification ,Rhizome ,Shoot ,Botany ,Darkness ,Ammophila breviligulata ,Poaceae ,Elongation ,Ecology, Evolution, Behavior and Systematics - Abstract
The impact of elevated ethylene concentrations and darkness on the growth and development of shoot organs of Ammophila breviligulata was investigated under experimental conditions in a complete two-way design. The results were compared with data of partially sand buried plants. Enhanced ethylene concentrations and sand burial stimulated the formation of new stem nodes, a prerequisite for burial-induced shoot elongation. However, internode elongation itself could not be promoted by the phytohormone ethylene, by darkness, or by their interaction. Sand burial inhibited the formation of rhizomes and tillers and the investment in root and rhizome biomass. Darkness mimicked this effect for the number of rhizomes and the biomass allocated to roots and rhizomes, indicating that the change in light regime upon sand burial may play an important role in the signal transduction chain that leads to a different allocation pattern in A. breviligulata. The results are discussed within the context of alternative signals that might initiate the internode elongation response in sand-buried A. breviligulata plants. [KEYWORDS: ethylene; darkness; sand burial; shoot elongation; allocation Deep-water rice; growth; morphology; submergence; seedlings; accretion; arenaria; survival; roots; seed]
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- 2017
4. An ecogenomic analysis of herbivore-induced plant volatiles inBrassica juncea
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Louise E. M. Vet, Jeffrey A. Harvey, Tom O.G. Tytgat, Cornelis A. Hordijk, Nicole M. van Dam, Jeroen J. Jansen, A. Sankara Reddy, Harry R. Harhangi, Vartika Mathur, Multitrophic Interactions (MTI), Microbial Ecology (ME), and Terrestrial Ecology (TE)
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Brassica ,Spodoptera litura ,Insect ,natural enemies ,Analytical Chemistry ,Parasitoid ,chemistry.chemical_compound ,Ecogenomics ,Gene Expression Regulation, Plant ,brussels-sprouts plants ,Laboratory of Entomology ,GeneralLiterature_REFERENCE(e.g.,dictionaries,encyclopedias,glossaries) ,media_common ,Jasmonic acid ,Green leaf volatiles ,food and beverages ,PE&RC ,Lepidoptera ,Larva ,international ,parasitoids cotesia-glomerata ,Female ,Mustard Plant ,insect herbivores ,media_common.quotation_subject ,Cyclopentanes ,arabidopsis-thaliana ,Spodoptera ,Biology ,Host Specificity ,green leaf volatiles ,Botany ,Genetics ,Animals ,Herbivory ,Oxylipins ,Laboratorium voor Nematologie ,Ecology, Evolution, Behavior and Systematics ,Volatile Organic Compounds ,secondary metabolism ,Herbivore ,jasmonic acid ,fungi ,Plutella ,Laboratorium voor Entomologie ,biology.organism_classification ,Hymenoptera ,Plant Leaves ,glucosinolate hydrolysis ,chemistry ,nicotiana-attenuata ,Laboratory of Nematology - Abstract
[KEYWORDS: gene expression green leaf volatiles mustard parasitoids Spodoptera sulphides] Upon herbivore feeding, plants emit complex bouquets of induced volatiles that may repel insect herbivores as well as attract parasitoids or predators. Due to differences in the temporal dynamics of individual components, the composition of the herbivore-induced plant volatile (HIPV) blend changes with time. Consequently, the response of insects associated with plants is not constant either. Using Brassica juncea as the model plant and generalist Spodoptera spp. larvae as the inducing herbivore, we investigated herbivore and parasitoid preference as well as the molecular mechanisms behind the temporal dynamics in HIPV emissions at 24, 48 and 72 h after damage. In choice tests, Spodoptera litura moth preferred undamaged plants, whereas its parasitoid Cotesia marginiventris favoured plants induced for 48 h. In contrast, the specialist Plutella xylostella and its parasitoid C. vestalis preferred plants induced for 72 h. These preferences matched the dynamic changes in HIPV blends over time. Gene expression analysis suggested that the induced response after Spodoptera feeding is mainly controlled by the jasmonic acid pathway in both damaged and systemic leaves. Several genes involved in sulphide and green leaf volatile synthesis were clearly up-regulated. This study thus shows that HIPV blends vary considerably over a short period of time, and these changes are actively regulated at the gene expression level. Moreover, temporal changes in HIPVs elicit differential preferences of herbivores and their natural enemies. We argue that the temporal dynamics of HIPVs may play a key role in shaping the response of insects associated with plants.
- Published
- 2013
5. The contribution of floral resources and honeydew to the performance of predatory hoverflies (Diptera: Syrphidae)
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Felix L. Wäckers, Paul C. J. van Rijn, Jurgen Kooijman, Population Biology (IBED, FNWI), and Multitrophic Interactions (MTI)
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Aphid ,Honeydew ,Natural pest control ,Survival ,Reproduction ,Biological pest control ,Biology ,medicine.disease_cause ,biology.organism_classification ,NIOO ,Plant-provided food ,Agronomy ,Brevicoryne brassicae ,Insect Science ,Pollen ,Episyrphus balteatus ,Botany ,medicine ,Nectar ,Hoverfly ,Conservation biological control ,Field margins ,Agronomy and Crop Science ,Functional agro biodiversity - Abstract
Hoverflies with predatory larval stages are important natural enemies of aphids and other pests in field crops. Many adult hoverflies are actively visiting and feeding on flowers, indicating that pollen and nectar are important resources for them. The scarcity of suitable flowers in intensified agriculture is therefore likely to limit their effectiveness as biological control agents. In this study on Episyrphus balteatus we quantify how permanent and temporal availability of pollen and nectar affects adult survival and reproduction, and assess to what extent aphid honeydew can substitute floral resources. Our results show that honeydew of cabbage aphids ( Brevicoryne brassicae ) strongly enhances hoverfly survival in the absence of floral resources. Less to be expected, when floral resources are available, honeydew supplementation still generates additional survival. A sucrose solution (as mimic for nectar) strongly increases adult longevity relative to water only, similar to honeydew. Flowers of buckwheat ( Fagopyrum esculentum ), permanently providing both nectar and pollen, further increases adult longevity and also supports egg production. Feeding on flowers of buckwheat during a 6 days pre-ovipositional period allows adult females to produce eggs for a week thereafter, and to survive for another 2 weeks, indicating that they can store and benefit from these nutritional resources for a substantial time. This suggests that the hoverflies only occasionally need to commute between aphid patches for oviposition (e.g., in the crop) and floral patches for feeding (e.g., at the border of the field). Honeydew, when locally at sufficiently high levels, may be used by the hoverflies to restore their energy demands, thereby postponing the need to search for floral resources. Cage experiments show that when suitable flowers are present the hoverflies can strongly suppress the growth of cabbage aphid colonies on Brussels sprouts.
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- 2013
6. Plant-soil feedback: the past, the present and future challenges
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James D. Bever, David A. Wardle, John N. Klironomos, T. Martijn Bezemer, Tess F. J. van de Voorde, Andrew Kulmatiski, Tadashi Fukami, Brenda B. Casper, Jennifer A. Schweitzer, Paul Kardol, Wim H. van der Putten, Katherine N. Suding, Richard D. Bardgett, Terrestrial Ecology (TE), and Multitrophic Interactions (MTI)
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serpentine grassland ,species coexistence ,Ecology (disciplines) ,media_common.quotation_subject ,Climate change ,microbial communities ,Plant Ecology and Nature Conservation ,Plant Science ,litter decomposition ,Ecological systems theory ,natural vegetation ,Ecosystem services ,Ecosystem ,Restoration ecology ,restoration ecology ,Laboratorium voor Nematologie ,Ecology, Evolution, Behavior and Systematics ,ecosystem processes ,media_common ,Ecology ,business.industry ,Global warming ,Environmental resource management ,PE&RC ,density-dependence ,invasive plant ,international ,Conceptual model ,Environmental science ,Plantenecologie en Natuurbeheer ,home-field advantage ,Laboratory of Nematology ,business - Abstract
Summary Plant–soil feedbacks is becoming an important concept for explaining vegetation dynamics, the invasiveness of introduced exotic species in new habitats and how terrestrial ecosystems respond to global land use and climate change. Using a new conceptual model, we show how critical alterations in plant–soil feedback interactions can change the assemblage of plant communities. We highlight recent advances, define terms and identify future challenges in this area of research and discuss how variations in strengths and directions of plant–soil feedbacks can explain succession, invasion, response to climate warming and diversity-productivity relationships. While there has been a rapid increase in understanding the biological, chemical and physical mechanisms and their interdependencies underlying plant–soil feedback interactions, further progress is to be expected from applying new experimental techniques and technologies, linking empirical studies to modelling and field-based studies that can include plant–soil feedback interactions on longer time scales that also include long-term processes such as litter decomposition and mineralization. Significant progress has also been made in analysing consequences of plant–soil feedbacks for biodiversity-functioning relationships, plant fitness and selection. To further integrate plant–soil feedbacks into ecological theory, it will be important to determine where and how observed patterns may be generalized, and how they may influence evolution. Synthesis. Gaining a greater understanding of plant–soil feedbacks and underlying mechanisms is improving our ability to predict consequences of these interactions for plant community composition and productivity under a variety of conditions. Future research will enable better prediction and mitigation of the consequences of human-induced global changes, improve efforts of restoration and conservation and promote sustainable provision of ecosystem services in a rapidly changing world.
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- 2013
7. Dealing with double trouble: consequences of single and double herbivory in Brassica juncea
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Vartika Mathur, Tom O.G. Tytgat, A.S. Reddy, R.M. de Graaf, N.M. van Dam, Louise E. M. Vet, V. Kalia, Multitrophic Interactions (MTI), and Terrestrial Ecology (TE)
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black mustard ,induced plant-responses ,Brassica ,specialist herbivores ,Spodoptera litura ,milkweed asclepias-syriaca ,Biochemistry ,induced resistance ,Ecogenomics ,Botany ,Leaf size ,Research programm of Radboud Institute for Biological and Environmental Sciences ,Laboratory of Entomology ,diamondback moth ,Laboratorium voor Nematologie ,Ecology, Evolution, Behavior and Systematics ,Herbivore ,Diamondback moth ,biology ,fungi ,Plutella ,food and beverages ,Brassicaceae ,plutella-xylostella ,biology.organism_classification ,PE&RC ,Laboratorium voor Entomologie ,Trichome ,international ,nicotiana-attenuata ,wild radish ,insect resistance ,Laboratory of Nematology - Abstract
In their natural environment, plants are often attacked simultaneously by many insect species. The specificity of induced plant responses that is reported after single herbivore attacks may be compromised under double herbivory and this may influence later arriving herbivores. The present study focuses on the dynamics of induced plant responses induced by single and double herbivory, and their effects on successive herbivores. Morphological (leaf length, area and trichome density) and chemical changes (leaf alkenyl and indole glucosinolates) in Brassica juncea were evaluated 4, 10, 14 and 20 days after damage by the specialist Plutella xylostella alone, or together with the generalist Spodoptera litura. To assess the biological effect of the plant’s responses, the preference and performance of both herbivores on previously induced plants were measured. We found that alkenyl glucosinolates were induced 20 days after damage by P. xylostella alone, whereas their levels were elevated as early as 4 days after double herbivory. Trichome density was increased in both treatments, but was higher after double herbivory. Interestingly, there was an overall decrease in indole glucosinolates and an increase in leaf size due to damage by P. xylostella, which was not observed during double damage. S. litura preferred and performed better on undamaged plants, whereas P. xylostella preferred damaged plants and performed better on plants damaged 14 and 10 days after single and double herbivory, respectively. Our results suggest that temporal studies involving single versus multiple attacker situations are necessary to comprehend the role of induced plant responses in plant–herbivore interactions.
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- 2013
8. Above- and below-ground herbivory effects on below-ground plant–fungus interactions and plant–soil feedback responses
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Henk Martens, Patrick P.J. Mulder, Olga Kostenko, Tess F. J. van de Voorde, T. Martijn Bezemer, Wim H. van der Putten, Terrestrial Ecology (TE), and Multitrophic Interactions (MTI)
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Jacobaea vulgaris ,Soil test ,growth ,Plant Ecology and Nature Conservation ,Plant Science ,complex mixtures ,diversity ,resistance ,pyrrolizidine alkaloids ,allocation ,Fusarium oxysporum ,Botany ,Laboratorium voor Nematologie ,Ecology, Evolution, Behavior and Systematics ,BU Microbiological & Chemical Food Analysis ,Biomass (ecology) ,Rhizosphere ,Herbivore ,defoliation ,Ecology ,biology ,fungi ,national ,food and beverages ,Phoma exigua ,senecio-jacobaea ,biology.organism_classification ,PE&RC ,Agronomy ,Soil water ,community ,Plantenecologie en Natuurbeheer ,BU Microbiologische & Chemische Voedselanalyse ,Laboratory of Nematology ,grassland - Abstract
1.Feeding by insect herbivores can affect plant growth and the concentration of defense compounds in plant tissues. Since plants provide resources for soil organisms, herbivory can also influence the composition of the soil community via its effects on the plant. Soil organisms, in turn, are important for plant growth. We tested whether insect herbivores, via their effects on the soil microbial community, can influence plant-soil feedbacks. 2.We first examined the effects of above-ground (AG) and below-ground (B) insect herbivory on the composition of pyrrolizidine alkaloids (PAs) in roots and on soil fungi in roots and rhizosphere soil of ragwort (Jacobaea vulgaris). The composition of fungal communities in roots and rhizosphere soil was affected by both AG and BG herbivory, but fungal composition also differed considerably between roots and rhizosphere soil. The composition of PAs in roots was affected only by BG herbivory. 3.Thirteen different fungal species were detected in roots and rhizosphere soil. The presence of the potentially pathogenic fungus Fusarium oxysporum decreased and that of Phoma exigua increased in presence of BG herbivory, but only in soil samples. 4.We then grew new plants in the soils conditioned by plants exposed to the herbivore treatments and in unconditioned soil. A subset of the new plants was exposed to foliar insect herbivory. Plant-soil feedback was strongly negative, but the feedback effect was least negative in soil conditioned by plants that had been exposed to BG herbivory. There was a negative direct effect of foliar herbivory on plant biomass during the feedback phase, but this effect was far less strong when the soil was conditioned by plants exposed to AG herbivory. AG herbivory during the conditioning phase also caused a soil feedback effect on the PA concentration in the foliage of ragwort. 5.Synthesis. Our results illustrate how insect herbivory can affect interactions between plants and soil organisms, and via these effects how herbivory can alter the performance of late-growing plants. Plant-soil feedback is emerging as an important theme in ecology and these results highlight that plant-soil feedback should be considered from a multitrophic AG and BG perspective
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- 2013
9. Effect of belowground herbivory on parasitoid associative learning of plant odours
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M. De Rijk, H.M. Kruidhof, R. Soler Gamborena, D. Hoffmann, Louise E. M. Vet, Jeffrey A. Harvey, Terrestrial Ecology (TE), and Multitrophic Interactions (MTI)
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media_common.quotation_subject ,Insect ,natural enemies ,PRI Agrosysteemkunde ,Parasitoid ,root herbivores ,Botany ,Laboratory of Entomology ,preference ,Ecology, Evolution, Behavior and Systematics ,media_common ,Larva ,Herbivore ,biology ,Ecology ,Host (biology) ,behavior ,national ,wasps ,biology.organism_classification ,Cotesia glomerata ,PE&RC ,Laboratorium voor Entomologie ,Associative learning ,volatiles ,aboveground multitrophic interactions ,quality ,infochemical use ,Agrosystems ,Delia radicum ,performance - Abstract
Root herbivores can influence both the performance and the behaviour of parasitoids of aboveground insect herbivores through changes in aboveground plant quality and in the composition of the plant's odour blend. Here we show that root herbivory by Delia radicum larvae did not influence the innate preferences for plant odours of the two closely related parasitoid species Cotesia glomerata and C. rubecula, but did affect their learned preferences, and did so in an opposite direction. While C. glomerata learned to prefer the odour of plants with intact roots, C. rubecula learned to prefer the odour of root-infested plants. The learned preference of C. glomerata for the odour of plants with intact roots matches our previously published result of its better performance when developing in P. brassicae hosts feeding on this plant type. In contrast, the relatively stronger learned preference of C. rubecula for the odour of root-infested plants cannot be merely explained by its performance, as the results of our present study indicate that D. radicum root herbivory did not influence the performance of C. rubecula nor of its host P. rapae. Our results stress the importance of assessing the influence of root herbivores on both innate and learned responses of parasitoids to plant odours.
- Published
- 2013
10. Silene as a model system in ecology and evolution
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Janis Antonovics, Lynda F. Delph, Deborah Charlesworth, Jacqui A. Shykoff, Giorgina Bernasconi, John R. Pannell, Boris Vyskot, Arjen Biere, Lorne M. Wolfe, Dmitry A. Filatov, Michael E. Hood, Alex Widmer, Tatiana Giraud, David E. McCauley, Gabriel A. B. Marais, Sexe et évolution, Département PEGASE [LBBE] (PEGASE), Laboratoire de Biométrie et Biologie Evolutive - UMR 5558 (LBBE), Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de Recherche en Informatique et en Automatique (Inria)-VetAgro Sup - Institut national d'enseignement supérieur et de recherche en alimentation, santé animale, sciences agronomiques et de l'environnement (VAS)-Centre National de la Recherche Scientifique (CNRS)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de Recherche en Informatique et en Automatique (Inria)-VetAgro Sup - Institut national d'enseignement supérieur et de recherche en alimentation, santé animale, sciences agronomiques et de l'environnement (VAS)-Centre National de la Recherche Scientifique (CNRS)-Laboratoire de Biométrie et Biologie Evolutive - UMR 5558 (LBBE), Université de Lyon-Université de Lyon-Institut National de Recherche en Informatique et en Automatique (Inria)-VetAgro Sup - Institut national d'enseignement supérieur et de recherche en alimentation, santé animale, sciences agronomiques et de l'environnement (VAS)-Centre National de la Recherche Scientifique (CNRS), and Multitrophic Interactions (MTI)
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0106 biological sciences ,[SDV]Life Sciences [q-bio] ,Ecology (disciplines) ,biological invasions ,Genomics ,Biology ,Models, Biological ,010603 evolutionary biology ,01 natural sciences ,Chromosomes, Plant ,Evolution, Molecular ,03 medical and health sciences ,Genetic algorithm ,Genetics ,Silene latifolia ,sex chromosome evolution ,Genetics(clinical) ,Silene ,ComputingMilieux_MISCELLANEOUS ,Genetics (clinical) ,Plant Diseases ,030304 developmental biology ,0303 health sciences ,Ecology ,Phylogenetic tree ,Basidiomycota ,Hadena ,biology.organism_classification ,speciation ,sexual conflict ,Evolutionary biology ,Evolutionary ecology ,Microbotryum - Abstract
The genus Silene, studied by Darwin, Mendel and other early scientists, is re-emerging as a system for studying interrelated questions in ecology, evolution and developmental biology. These questions include sex chromosome evolution, epigenetic control of sex expression, genomic conflict and speciation. Its well-studied interactions with the pathogen Microbotryum has made Silene a model for the evolution and dynamics of disease in natural systems, and its interactions with herbivores have increased our understanding of multi-trophic ecological processes and the evolution of invasiveness. Molecular tools are now providing new approaches to many of these classical yet unresolved problems, and new progress is being made through combining phylogenetic, genomic and molecular evolutionary studies with ecological and phenotypic data. Heredity (2009) 103, 5-14; doi: 10.1038/hdy.2009.34; published online 15 April 2009
- Published
- 2016
11. Where, when and how plant–soil feedback matters in a changing world
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G. F. (Ciska) Veen, Mark A. Bradford, E. Pernilla Brinkman, Tess F. J. van de Voorde, Wim H. van der Putten, Terrestrial Ecology (TE), and Multitrophic Interactions (MTI)
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0106 biological sciences ,Environmental change ,Climate change ,plant–soil feedback triangle ,Plant Ecology and Nature Conservation ,Biology ,010603 evolutionary biology ,01 natural sciences ,Decomposer ,NIOO ,biodiversity loss ,biodiversity loss carbon and nutrient cycling climate change community composition invasive plants land use plant-soil feedback triangle range expansion arbuscular mycorrhizal fungi home-field advantage drying-rewetting frequency climate-change litter decomposition community structure microbial communities elevated co2 land-use nitrogen transformations Environmental Sciences & Ecology ,Land use, land-use change and forestry ,Ecosystem ,Global environmental change ,invasive plants ,community composition ,range expansion ,Laboratorium voor Nematologie ,Ecology, Evolution, Behavior and Systematics ,Biotic component ,business.industry ,Ecology ,Environmental resource management ,land use ,Global change ,PE&RC ,climate change ,carbon and nutrient cycling ,Plantenecologie en Natuurbeheer ,Terrestrial ecosystem ,EPS ,Laboratory of Nematology ,business ,010606 plant biology & botany - Abstract
Summary It is increasingly acknowledged that plant–soil feedbacks may play an important role in driving the composition of plant communities and functioning of terrestrial ecosystems. However, the mechanistic understanding of plant–soil feedbacks, as well as their roles in natural ecosystems in proportion to other possible drivers, is still in its infancy. Such knowledge will enhance our capacity to determine the contribution of plant–soil feedback to community and ecosystem responses under global environmental change. Here, we review how plant–soil feedbacks may develop under extreme drought and precipitation events, CO2 and nitrogen enrichment, temperature increase, land use change and plant species loss vs. gain. We present a framework for opening the ‘black box of soil’ considering the responses of the various biotic components (enemies, symbionts and decomposers) of plant–soil feedback to the global environmental changes, and we discuss how to integrate these components to understand and predict the net effects of plant–soil feedbacks under the various scenarios of change. To gain an understanding of how plant–soil feedback plays out in realistic settings, we also use the framework to discuss its interaction with other drivers of plant community composition, including competition, facilitation, herbivory, and soil physical and chemical properties. We conclude that understanding the role that plant–soil feedback plays in shaping the responses of plant community composition and ecosystem processes to global environmental changes requires unravelling the individual contributions of enemies, symbionts and decomposers. These biotic factors may show different response rates and strengths, thereby resulting in different net magnitudes and directions of plant–soil feedbacks under various scenarios of global change. We also need tests of plant–soil feedback under more realistic conditions to determine its contribution to changes in patterns and processes in the field, both at ecologically and evolutionary relevant time-scales.
- Published
- 2016
12. Contrasting patterns of herbivore and predator pressure on invasive and native plants
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W.H. van der Putten, Jeffrey A. Harvey, B. Wouters, T. Engelkes, T.M. Bezemer, Terrestrial Ecology (TE), and Multitrophic Interactions (MTI)
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insect herbivores ,Introduced species ,Biology ,below-ground enemies ,release ,Predation ,NIOO ,evolution ,Predator ,Laboratorium voor Nematologie ,Ecology, Evolution, Behavior and Systematics ,Trophic level ,Herbivore ,Ecology ,fungi ,food and beverages ,Native plant ,PE&RC ,populations ,communities ,Guild ,climate-change ,hypothesis ,Laboratory of Nematology ,competition ,Plant tolerance to herbivory - Abstract
Invasive non-native plant species often harbor fewer herbivorous insects than related native plant species. However, little is known about how herbivorous insects on non-native plants are exposed to carnivorous insects, and even less is known on plants that have recently expanded their ranges within continents due to climate warming. In this study we examine the herbivore load (herbivore biomass per plant biomass), predator load (predator biomass per plant biomass) and predator pressure (predator biomass per herbivore biomass) on an inter-continental non-native and an intra-continental range-expanding plant species and two congeneric native species. All four plant species co-occur in riparian habitat in north-western Europe. Insects were collected in early, mid and late summer from three populations of all four species. Before counting and weighing the insects were classified to trophic guild as carnivores (predators), herbivores, and transients. Herbivores were further subdivided into leaf-miners, sap-feeders, chewers and gallers. Total herbivore loads were smaller on inter-continental non-native and intra-continental range-expanding plants than on the congeneric natives. However, the differences depended on time within growing season, as well as on the feeding guild of the herbivore. Although the predator load on non-native plants was not larger than on natives, both non-native plant species had greater predator pressure on the herbivores than the natives. We conclude that both these non-native plant species have better bottom-up as well as top-down control of herbivores, but that effects depend on time within growing season and (for the herbivore load) on herbivore feeding guild. Therefore, when evaluating insects on non-native plants, variation within season and differences among feeding guilds need to be taken into account.
- Published
- 2012
13. Community patterns of soil bacteria and nematodes in relation to geographic distance
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T. Martijn Bezemer, Henk Duyts, Etienne Yergeau, Fernando Monroy, Wim H. van der Putten, Simon R. Mortimer, Terrestrial Ecology (TE), Terrestrial Microbial Ecology (TME), and Multitrophic Interactions (MTI)
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Geographic distance ,Microbial biogeography ,Biodiversity ,Soil Science ,microbial communities ,global diversity ,Biology ,Spatial distribution ,Microbiology ,Geographical distance ,Ecosystem ,microorganisms ,Laboratorium voor Nematologie ,biogeography ,biodiversity ,PCR-DGGE ,Ecology ,cooccurrence patterns ,Community structure ,spatial scales ,Plant community ,PE&RC ,gradient ,Grasslands ,international ,Community similarity ,Common spatial pattern ,Biological dispersal ,Laboratory of Nematology ,ecology ,Taxa turnover ,chalk grassland - Abstract
Ecosystems consist of aboveground and belowground subsystems and the structure of their communities is known to change with distance. However, most of this knowledge originates from visible, aboveground components, whereas relatively little is known about how soil community structure varies with distance and if this variability depends on the group of organisms considered. In the present study, we analyzed 30 grasslands from three neighboring chalk hill ridges in southern UK to determine the effect of geographic distance (1–198 km) on the similarity of bacterial communities and of nematode communities in the soil. We found that for both groups, community similarity decayed with distance and that this spatial pattern was not related to changes either in plant community composition or soil chemistry. Site history may have contributed to the observed pattern in the case of nematodes, since the distance effect depended on the presence of different nematode taxa at one of the hill ridges. On the other hand, site-related differences in bacterial community composition alone could not explain the spatial turnover, suggesting that other factors, such as biotic gradients and local dispersal processes that we did not include in our analysis, may be involved in the observed pattern. We conclude that, independently of the variety of causal factors that may be involved, the decay in similarity with geographic distance is a characteristic feature of both communities of soil bacteria and nematodes.
- Published
- 2012
14. The importance of plant-soil interactions, soil nutrients, and plant life history traits for the temporal dynamics of Jacobaea vulgaris in a chronosequence of old-fields
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Tess Van de Voorde, NIOO-KNAW KNAW, Martijn Bezemer, Wim Van der Putten, Multitrophic Interactions (MTI), and Terrestrial Ecology (TE)
- Subjects
Biomass (ecology) ,Jacobaea vulgaris ,biology ,Ecology ,media_common.quotation_subject ,Chronosequence ,food and beverages ,Ecological succession ,biology.organism_classification ,complex mixtures ,Competition (biology) ,NIOO ,Agronomy ,Propagule ,Seedling ,Soil water ,Ecology, Evolution, Behavior and Systematics ,media_common - Abstract
We examined to what extent temporal dynamics of Jacobaea vulgaris cover in old-fields were related to plant–soil feedback, soil nutrients, seed availability and performance, and seedling establishment. Long-term measurements at an experimental field and in ten old-fields representing a chronosequence following land abandonment revealed a remarkably similar hump-shaped temporal pattern of J. vulgaris cover, which peaked at about five years after abandonment. In a plant–soil feedback study, J. vulgaris biomass of plants grown in soil from all chronosequence fields was lower than in sterilized control soil. However, biomass of J. vulgaris in the feedback study was lower when grown in soil collected from fields with a high density of J. vulgaris plants than in soil from fields with a low density of J. vulgaris. When plants were grown again in the conditioned soil, a strong negative plant–soil feedback response was observed for soils from all fields. These results indicate that soils from all stages of the chronosequence can develop a strong negative soil feedback to J. vulgaris, and that there is a positive relationship between J. vulgaris density and the subsequent level of control by the soil community. In a common-garden experiment with turfs collected from the chronosequence fields in which J. vulgaris was seeded, seedling establishment was significantly lower in turfs from older than from young fields. In a seed bank study the number of emerging seedlings declined with time since abandonment of the field. In conclusion, negative plant–soil feedback is an important factor explaining the hump-shaped population development of J. vulgaris. However, it is not operating alone, as propagule availability and characteristics, and competition may also be important. Thus, in order to explain its contribution to plant population dynamics, the role of biotic plant–soil interactions, soil nutrients and life history characteristics along successional gradients should be considered from a community perspective.
- Published
- 2011
15. Modelling C and N mineralisation in soil food webs during secondary succession on ex-arable land
- Author
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R. Holtkamp, A. van der Wal, P.C. de Ruiter, W.H. van der Putten, Paul Kardol, Stefan C. Dekker, Microbial Ecology (ME), Multitrophic Interactions (MTI), and Terrestrial Ecology (TE)
- Subjects
restoration ,Secondary succession ,Energy channels ,Direct and indirect effects ,Chronosequence ,Soil Science ,Ecological succession ,Wiskundige en Statistische Methoden - Biometris ,Microbiology ,Trophic levels ,Soil food web ,Ecosystem ,Mathematical and Statistical Methods - Biometris ,Laboratorium voor Nematologie ,Land use change ,nitrogen mineralization ,biodiversity ,Trophic level ,ecosystem ,decomposition ,Milieukunde ,Ecology ,Soil organic matter ,dynamics ,PE&RC ,Food web model ,abandonment ,Food web ,chronosequence ,Sociologie ,nematodes ,Environmental science ,fungal biomass ,Laboratory of Nematology - Abstract
The rate of secondary succession after land abandonment depends on the interplay between aboveground and belowground processes. Changes in vegetation composition lead to altered amounts and composition of soil organic matter (SOM) with consequences for the abundance and functioning of the soil food web. In turn, soil food web structure determines the mineralisation rate of nutrients that can be taken up by plants. This study analyses changes in the C and N mineralisation rates along with soil food web structure during secondary succession after land abandonment. In a previous study, changes in soil food web structure and SOM quantity and quality were measured at different stages of secondary succession on abandoned arable fields (abandoned for 2, 9 and 22 years and a heathland, which is the assumed target of the secondary succession). Based on these measurements we expected the C and N mineralisation rates to increase during secondary succession. The key hypothesis is that with a description of the soil food webs in terms of quantified biomasses, natural death rates, energy conversion efficiencies and diets enables a calculation of C and N mineralisation rates in soils. The basic assumptions connected to this hypothesis are that on a time-scale of years the population sizes are in steady state. We also calculated mineralisation rates per trophic level and energy channel. Based on the same measurements we expected that the contributions by the lower trophic level groups will increase as well as the mineralisation rates by bacterial and fungal energy channels. Measured C and N mineralisation indeed increased during the 22-year period of abandonment. The calculated C and N mineralisation rates showed the same trend after land abandonment as the measured values. Calculated contributions to mineralisation of organisms at trophic level 1 increase during secondary succession following land abandonment. The fungal decomposition channel contributed more to N mineralisation than the bacterial decomposition channel, whereas both channels contributed equally to C mineralisation rates. Direct contributions by higher trophic levels to mineralisation decreased during secondary succession. However, higher trophic levels were direct important for N mineralisation and indirect for both C and N mineralisation due to their effect on biomass turnover rates of groups at lower trophic levels. The increasing total N mineralisation rate of the soil food web, however, does not benefit plants, as during succession plant species that mainly grow under high nutrient availability are replaced by species that can grow in nutrient poor condition.
- Published
- 2011
16. Additive and interactive effects of functionally dissimilar soil organisms on a grassland plant community
- Author
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Stéphane Saj, Frédéric Henry, Susanne Wurst, Alia Rodriguez, Christina Witt, Natalia Ladygina, Merijn R. Kant, Ilja Sonnemann, Stefan Reidinger, Robert Koller, Dept Ecol, University of São Paulo (USP), University of Copenhagen = Københavns Universitet (KU), Max Planck Institute for Chemical Ecology, Max-Planck-Gesellschaft, Laboratoire Agronomie et Environnement (LAE), Institut National de la Recherche Agronomique (INRA)-Université de Lorraine (UL), Sch Biol Sci, Queen Mary University of London (QMUL), Consejo Superior de Investigaciones Científicas [Madrid] (CSIC), University of Helsinki, University of Reading (UOR), Royal Netherlands Academy of Arts and Sciences (KNAW), EU Marie Curie BIORHIZ Research Network, Population Biology (IBED, FNWI), and Multitrophic Interactions (MTI)
- Subjects
0106 biological sciences ,Nematodes ,[SDV]Life Sciences [q-bio] ,Teneur en matière organique ,Plante herbacée ,F62 - Physiologie végétale - Croissance et développement ,01 natural sciences ,Mycorhizé à vésicule et arbuscule ,Prairie ,Decomposer ,COLONIZATION ,Interactions biologiques ,Nutrient ,AMF ,Biomasse ,Glomus ,Agrostis capillaris ,2. Zero hunger ,Biomass (ecology) ,ARBUSCULAR-MYCORRHIZAL FUNGI ,biology ,MICROBIAL COMMUNITY ,food and beverages ,04 agricultural and veterinary sciences ,Coleoptera ,C/N content ,Productivity (ecology) ,[SDE]Environmental Sciences ,Shoot ,Functional groups ,PLFA ,Collembolans ,Micro-organisme du sol ,FOOD-WEB ,Nématode à vie libre ,EARLY SUCCESSION ,Soil Science ,Teneur en azote ,complex mixtures ,010603 evolutionary biology ,Microbiology ,ROOT HERBIVORY ,BELOW-GROUND BIOTA ,Botany ,Enchytraeidae ,Plant biomass ,Wireworms ,fungi ,Activité biologique dans le sol ,P34 - Biologie du sol ,Plant community ,15. Life on land ,biology.organism_classification ,SPECIES DIVERSITY ,Agronomy ,040103 agronomy & agriculture ,INSECT HERBIVORY ,Collembola ,0401 agriculture, forestry, and fisheries - Abstract
International audience; The productivity and diversity of plant communities are affected by soil organisms such as arbuscular mycorrhizal fungi (AMF), root herbivores and decomposers. However, it is unknown how interactions between such functionally dissimilar soil organisms affect plant communities and whether the combined effects are additive or interactive. In a greenhouse experiment we investigated the individual and combined effects of AMF (five Glomus species), root herbivores (wireworms and nematodes) and decomposers (collembolans and enchytraeids) on the productivity and nutrient content of a model grassland plant community as well as on soil microbial biomass and community structure. The effects of the soil organisms on productivity (total plant biomass), total root biomass, grass and forb biomass, and nutrient uptake of the plant community were additive. AMF decreased, decomposers increased and root herbivores had no effect on productivity, but in combination the additive effects canceled each other out. AMF reduced total root biomass by 18%, but decomposers increased it by 25%, leading to no net effect on total root biomass in the combined treatments. Total shoot biomass was reduced by 14% by root herbivores and affected by an interaction between AMF and decomposers where decomposers had a positive impact on shoot growth only in presence of AMF. AMF increased the shoot biomass of forbs, but reduced the shoot biomass of grasses, while root herbivores only reduced the shoot biomass of grasses. Interactive effects of the soil organisms were detected on the shoot biomasses of Lotus corniculatus, Plantago lanceolata, and Agrostis capillaris. The C/N ratio of the plant community was affected by AMF. In soil, AMF promoted abundances of bacterial, actinomycete, saprophytic and AMF fatty acid markers. Decomposers alone decreased bacterial and actinomycete fatty acids abundances but when decomposers were interacting with herbivores those abundances were increased. Our results suggests that at higher resolutions, i.e. on the levels of individual plant species and the microbial community, interactive effects are common but do not affect the overall productivity and nutrient uptake of a grassland plant community, which is mainly affected by additive effects of functionally dissimilar soil organisms. (c) 2010 Elsevier Ltd. All rights reserved.
- Published
- 2010
17. Behaviour of male and female parasitoids in the field: influence of patch size, host density, and habitat complexity
- Author
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T. Engelkes, Jeffrey A. Harvey, O. Kostenko, W.H. van der Putten, Roxina Soler, Taiadjana M. Fortuna, A.F.D. Kamp, Roel Wagenaar, Louise E. M. Vet, T.M. Bezemer, Rieta Gols, Terrestrial Ecology (TE), and Multitrophic Interactions (MTI)
- Subjects
cotesia-glomerata ,insect herbivores ,Foraging ,foraging behavior ,natural enemies ,Biology ,c-rubecula hymenoptera ,Population density ,Grassland ,Parasitoid wasp ,Laboratory of Entomology ,aphidius-nigripes hymenoptera ,Laboratorium voor Nematologie ,spp. hymenoptera ,geography ,geography.geographical_feature_category ,Ecology ,Host (biology) ,apanteles-glomeratus ,Species diversity ,PE&RC ,Laboratorium voor Entomologie ,biology.organism_classification ,Cotesia glomerata ,weather conditions ,Agronomy ,Habitat ,Insect Science ,volatile infochemicals ,Laboratory of Nematology - Abstract
1. Two field experiments were carried out to examine the role of patch size, host density, and complexity of the surrounding habitat, on the foraging behaviour of the parasitoid wasp Cotesia glomerata in the field. 2. First, released parasitoids were recaptured on patches of one or four Brassica nigra plants, each containing 10 hosts that were placed in a mown grassland area. Recaptures of females were higher than males, and males and females aggregated at patches with four plants. 3. In experiment 2, plants containing 0, 5 or 10 hosts were placed in unmown grassland plots that differed in plant species composition, on bare soil, and on mown grassland. Very low numbers of parasitoids were recaptured in the vegetated plots, while high numbers of parasitoids were recaptured on plants placed on bare soil or in mown grassland. Recaptures were higher on plants on bare soil than on mown grassland, and highest on plants containing 10 hosts. The host density effect was significantly more apparent in mown grassland than on bare soil. 4. Cotesia glomerata responds in an aggregative way to host density in the field. However, host location success is determined mostly by habitat characteristics, and stronger host or host-plant cues are required when habitat complexity increases.
- Published
- 2010
18. Predicting population and community dynamics - the type of aggregation matters
- Author
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Bert Hidding, Marc Breulmann, Sabine Duquesne, Katrin M. Meyer, Justin M. Calabrese, Christian Schöb, Andreas Huth, Alberto Basset, Martin Schädler, Tess F. J. van de Voorde, Katja Schiffers, Tamara Münkemüller, Meyer, K. M., Schiffers, K., Münkemüller, T., Schädler, M., Calabrese, J. M., Basset, Alberto, Breulmann, M., Duquesne, S., Hidding, B., Huth, A., Schöb, C., van de Voorde, T. F. J., Terrestrial Microbial Ecology (TME), Aquatic Ecology (AqE), and Multitrophic Interactions (MTI)
- Subjects
0106 biological sciences ,trophic guilds ,body-size ,Environmental change ,Genotype ,media_common.quotation_subject ,Population ,trait convergence ,environmental-change ,Biology ,010603 evolutionary biology ,01 natural sciences ,Outcome (game theory) ,Organizational level ,Specie ,Community dynamics ,Functional type ,soil-microorganisms ,Pattern–process relationship ,ecological networks ,bewicks swans ,education ,Function (engineering) ,Laboratorium voor Nematologie ,Ecology, Evolution, Behavior and Systematics ,media_common ,Trophic guild ,education.field_of_study ,Ecology ,010604 marine biology & hydrobiology ,Body size cla ,Aggregate (data warehouse) ,Ecological study ,Study design ,PE&RC ,Data science ,Ecological network ,Scale ,Phenotype ,food webs ,plant genotype ,Laboratory of Nematology ,burial depth - Abstract
When investigating complex ecological dynamics at the population or community level, we necessarily need to abstract and aggregate ecological information. The way in which information is aggregated may be crucial for the outcome of the study. In this paper, we suggest that in addition to the traditional spatial, temporal and organizational levels, we need a more flexible framework linking ecological processes, study objects and types of aggregation. We develop such a framework and exemplify the most commonly used types of aggregation and their potential influence on identifiable drivers of community dynamics. We also illustrate strategies to narrow down the range of possible aggregation types for a particular study. With this approach, we hope (i) to clarify the function of aggregation types as related to traditional ecological levels and (ii) to raise the awareness of how important a deliberate way of aggregating ecological information is for a sound and reliable outcome of any empirical or theoretical ecological study.
- Published
- 2010
19. Vertebrate herbivores influence soil nematodes by modifying plant communities
- Author
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G. F. (Ciska) Veen, Han Olff, Wim H. van der Putten, Henk Duyts, Terrestrial Ecology (TE), Multitrophic Interactions (MTI), and Olff group
- Subjects
Nematoda ,Population Dynamics ,DIVERSITY ,NUTRIENTS ,nitrogen ,above-belowground interactions ,food-web ,Soil ,Grazing ,DEFOLIATION ,Abiotic component ,defoliation ,Ecology ,Community structure ,GRASSLAND ECOSYSTEM ,Plants ,PE&RC ,grassland ecosystem ,below-ground biota ,Rabbits ,FOOD-WEB ,Soil biology ,vertebrate herbivores ,Biology ,soil biota ,diversity ,nutrients ,vegetation ,BELOW-GROUND BIOTA ,Soil food web ,Animals ,grazing ,patterns ,Laboratorium voor Nematologie ,Ecology, Evolution, Behavior and Systematics ,Ecosystem ,Herbivore ,Community ,floodplain grassland ,MICROBIAL RESPONSES ,Plant community ,The Netherlands ,Feeding Behavior ,microbial responses ,structural equation modeling (SEM) ,NITROGEN ,Agronomy ,Wildlife Ecology and Conservation ,nematodes ,PATTERNS ,Cattle ,VEGETATION ,Laboratory of Nematology ,community ecology ,top-down-bottom-up control - Abstract
Abiotic soil properties, plant community composition, and herbivory all have been reported as important factors influencing the composition of soil communities. However, most studies thus far have considered these factors in isolation, whereas they strongly interact in the field. Here, we study how grazing by vertebrate herbivores influences the soil nematode community composition of a floodplain grassland while we account for effects of grazing on plant community composition and abiotic soil properties. Nematodes are the most ubiquitous invertebrates in the soil. They include a variety of feeding types, ranging from microbial feeders to herbivores and carnivores, and they perform key functions in soil food webs.Our hypothesis was that grazing affects nematode community structure and composition through altering plant community structure and composition. Alternatively, we tested whether the effects of grazing may, directly or indirectly, run via changes in soil abiotic properties. We used a long-term field experiment containing plots with and without vertebrate grazers (cattle and rabbits). We compared plant and nematode community structure and composition, as well as a number of key soil abiotic properties, and we applied structural equation modeling to investigate four possible pathways by which grazing may change nematode community composition.Aboveground grazing increased plant species richness and reduced both plant and nematode community heterogeneity. There was a positive relationship between plant and nematode diversity indices. Grazing decreased the number of bacterial-feeding nematodes, indicating that in these grasslands, top-down control of plant production by grazing leads to bottom-up control in the basal part of the bacterial channel of the soil food web.According to the structural equation model, grazing had a strong effect on soil abiotic properties and plant community composition, whereas plant community composition was the main determinant of nematode community composition. Other pathways, which assumed that grazing influenced nematode community composition by inducing changes in soil abiotic properties, did not significantly explain variation in nematode community composition.We conclude that grazing-induced changes in nematode community composition mainly operated via changes in plant community composition. Influences of vertebrate grazers on soil nematodes through modification of abiotic soil properties were of less importance.
- Published
- 2010
20. Identification of biologically relevant compounds in aboveground and belowground induced volatile blends
- Author
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Cornelis A. Hordijk, Bao-Li Qiu, Nicole M. van Dam, Jeroen J. Jansen, Louise E. M. Vet, Terrestrial Ecology (TE), Multitrophic Interactions (MTI), and Microbial Wetland Ecology (MWE)
- Subjects
parasitic wasps ,Wasps ,Brassica ,Aboveground-belowground interactions ,natural enemies ,Biochemistry ,Parasitoid ,Terpene ,chemistry.chemical_compound ,PLSDA ,Ecogenomics ,Organic Chemicals ,Laboratory of Entomology ,partial least-squares ,Pieris brassicae ,Behavior, Animal ,biology ,plants ,Jasmonic acid ,Discriminant Analysis ,General Medicine ,PE&RC ,Lepidoptera ,Chemical ecology ,Shoot ,Female ,specialist herbivore ,Plant Shoots ,performance ,Parasitoid preference ,cotesia-glomerata ,Cyclopentanes ,Article ,Botany ,Animals ,Volatile organic compounds ,Oxylipins ,Least-Squares Analysis ,Ecology, Evolution, Behavior and Systematics ,Terpenes ,jasmonic acid ,herbivore-induced volatiles ,biology.organism_classification ,Cotesia glomerata ,root ,Laboratorium voor Entomologie ,Animal Feed ,Multivariate analysis ,chemistry ,Indirect defenses ,Volatilization - Abstract
Plants under attack by aboveground herbivores emit complex blends of volatile organic compounds (VOCs). Specific compounds in these blends are used by parasitic wasps to find their hosts. Belowground induction causes shifts in the composition of aboveground induced VOC blends, which affect the preference of parasitic wasps. To identify which of the many volatiles in the complex VOC blends may explain parasitoid preference poses a challenge to ecologists. Here, we present a case study in which we use a novel bioinformatics approach to identify biologically relevant differences between VOC blends of feral cabbage (Brassica oleracea L.). The plants were induced aboveground or belowground with jasmonic acid (JA) and shoot feeding caterpillars (Pieris brassicae or P. rapae). We used Partial Least Squares--Discriminant Analysis (PLSDA) to integrate and visualize the relation between plant-emitted VOCs and the preference of female Cotesia glomerata. Overall, female wasps preferred JA-induced plants over controls, but they strongly preferred aboveground JA-induced plants over belowground JA-induced plants. PLSDA revealed that the emission of several monoterpenes was enhanced similarly in all JA-treated plants, whereas homoterpenes and sesquiterpenes increased exclusively in aboveground JA-induced plants. Wasps may use the ratio between these two classes of terpenes to discriminate between aboveground and belowground induced plants. Additionally, it shows that aboveground applied JA induces different VOC biosynthetic pathways than JA applied to the root. Our bioinformatic approach, thus, successfully identified which VOCs matched the preferences of the wasps in the various choice tests. Additionally, the analysis generated novel hypotheses about the role of JA as a signaling compound in aboveground and belowground induced responses in plants.
- Published
- 2010
21. Chemical espionage on species-specific butterfly anti-aphrodisiacs by hitchhiking Trichogramma wasps
- Author
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Foteini G. Pashalidou, Nina E. Fatouros, Martinus E. Huigens, Jozef B. Woelke, Hans M. Smid, Tibor Bukovinszky, Terrestrial Ecology (TE), Multitrophic Interactions (MTI), Aquatic Ecology (AqE), Wageningen University and Research [Wageningen] (WUR), Netherlands Institute of Ecology (NIOO-KNAW), and Netherlands Organization for Scientific Research (NWO)86305020German Research Foundation (DFG)FA 824/1-11
- Subjects
0106 biological sciences ,oilseed rape ,parasitic wasps ,[SDV]Life Sciences [q-bio] ,odor perception ,foraging behavior ,Trichogramma evanescens ,Pieris rapae ,010603 evolutionary biology ,01 natural sciences ,podisus-maculiventris hemiptera ,sex-pheromone ,Botany ,Laboratory of Entomology ,Ecology, Evolution, Behavior and Systematics ,weevil ceutorhynchus-assimilis ,Pieris brassicae ,learning ,biology ,egg parasitoids ,entomophagous insects ,fungi ,Trichogramma brassicae ,Pieris ,PE&RC ,Laboratorium voor Entomologie ,biology.organism_classification ,010602 entomology ,phoresy ,Pieris (butterfly) ,rape brassica-napus ,infochemical use ,Sex pheromone ,Butterfly ,egg parasitoid ,Animal Science and Zoology ,Trichogramma - Abstract
Parasitic wasps employ a wide range of chemical cues to find their hosts. Very recently, we discovered how 2 closely related egg parasitoids, Trichogramma brassicae and Trichogramma evanescens, exploit the anti-aphrodisiac pheromone benzyl cyanide of one of their hosts, the gregarious large cabbage white butterfly Pieris brassicae that deposits a clutch of more than 20 eggs per oviposition bout. The pheromone is transferred by male butterflies to females during mating to enforce female monogamy. On detecting the anti-aphrodisiac, the tiny parasitic wasps ride on a mated female butterfly to a host plant and then parasitize her freshly laid eggs. The present study demonstrates that both wasp species similarly exploit the anti-aphrodisiac mixture of methyl salicylate and indole of another host, the more common solitary small cabbage white butterfly Pieris rapae that deposits only one egg at a time. Interestingly, this behavior is innate in T. brassicae, whereas T. evanescens learns it after one successful ride on a mated female butterfly. Moreover, we show that the wasps only respond to the anti-aphrodisiacs of the 2 cabbage white butterflies when the ubiquitous compounds are part of a complete mated female odor blend. Obviously, parasitic wasps use the sophisticated espionage-and-ride strategy to find eggs of different gregarious and solitary host species. From the wasps' perspective there seems to be a trade-off between the abundance and egg-laying behavior of the butterflies. Our findings suggest that Pieris butterflies are under strong selective pressure to minimize the use of an anti-aphrodisiac. Copyright 2010, Oxford University Press.
- Published
- 2010
22. Herbivore-induced plant responses in Brassica oleracea prevail over effects of constitutive resistance and result in enhanced herbivore attack
- Author
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J.J.A. van Loon, N.M. van Dam, Louise E. M. Vet, Erik H. Poelman, Marcel Dicke, Multitrophic Interactions (MTI), and Terrestrial Ecology (TE)
- Subjects
insect herbivores ,interspecific interactions ,media_common.quotation_subject ,specialist herbivores ,Pieris rapae ,Insect ,Biology ,Generalist and specialist species ,generalist herbivores ,Botany ,Laboratory of Entomology ,media_common ,Herbivore ,Ecology ,Resistance (ecology) ,EPS-2 ,fungi ,food and beverages ,tritrophic interaction webs ,biology.organism_classification ,Inducible plant defenses against herbivory ,Laboratorium voor Entomologie ,arthropod community structure ,Insect Science ,primrose oenothera-biennis ,nicotiana-attenuata ,Brassica oleracea ,wild radish ,Plant tolerance to herbivory ,performance - Abstract
1. Plant responses to herbivore attack may have community-wide effects on the composition of the plant-associated insect community. Thereby, plant responses to an early-season herbivore may have profound consequences for the amount and type of future attack. 2. Here we studied the effect of early-season herbivory by caterpillars of Pieris rapae on the composition of the insect herbivore community on domesticated Brassica oleracea plants. We compared the effect of herbivory on two cultivars that differ in the degree of susceptibility to herbivores to analyse whether induced plant responses supersede differences caused by constitutive resistance. 3. Early-season herbivory affected the herbivore community, having contrasting effects on different herbivore species, while these effects were similar on the two cultivars. Generalist insect herbivores avoided plants that had been induced, whereas these plants were colonised preferentially by specialist herbivores belonging to both leaf-chewing and sap-sucking guilds. 4. Our results show that community-wide effects of early-season herbivory may prevail over effects of constitutive plant resistance. Induced responses triggered by prior herbivory may lead to an increase in susceptibility to the dominant specialists in the herbivorous insect community. The outcome of the balance between contrasting responses of herbivorous community members to induced plants therefore determines whether induced plant responses result in enhanced plant resistance.
- Published
- 2010
23. Stress‐induced DNA methylation changes and their heritability in asexual dandelions
- Author
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Koen J. F. Verhoeven, Arjen Biere, Peter J. van Dijk, Jeroen J. Jansen, Terrestrial Ecology (TE), Multitrophic Interactions (MTI), and CL / OTHER-CL
- Subjects
Genetic Markers ,disease resistance ,Genotype ,Taraxacum ,Physiology ,Inheritance Patterns ,plant evolution ,Cyclopentanes ,arabidopsis-thaliana ,Plant Science ,Sodium Chloride ,Biology ,tobacco plants ,phenotypic plasticity ,Epigenesis, Genetic ,Stress, Physiological ,Reproduction, Asexual ,Genetic variation ,Oxylipins ,Epigenetics ,Amplified Fragment Length Polymorphism Analysis ,genome ,Laboratorium voor Nematologie ,Plant evolution ,Genetics ,Phenotypic plasticity ,Genetic Variation ,Methylation ,DNA Methylation ,Heritability ,PE&RC ,gene-expression ,Genetic marker ,DNA methylation ,Laboratory of Nematology ,transposable elements ,Salicylic Acid ,epigenetic inheritance ,hypomethylation - Abstract
*DNA methylation can cause heritable phenotypic modifications in the absence of changes in DNA sequence. Environmental stresses can trigger methylation changes and this may have evolutionary consequences, even in the absence of sequence variation. However, it remains largely unknown to what extent environmentally induced methylation changes are transmitted to offspring, and whether observed methylation variation is truly independent or a downstream consequence of genetic variation between individuals. *Genetically identical apomictic dandelion (Taraxacum officinale) plants were exposed to different ecological stresses, and apomictic offspring were raised in a common unstressed environment. We used methylation-sensitive amplified fragment length polymorphism markers to screen genome-wide methylation alterations triggered by stress treatments and to assess the heritability of induced changes. *Various stresses, most notably chemical induction of herbivore and pathogen defenses, triggered considerable methylation variation throughout the genome. Many modifications were faithfully transmitted to offspring. Stresses caused some epigenetic divergence between treatment and controls, but also increased epigenetic variation among plants within treatments. *These results show the following. First, stress-induced methylation changes are common and are mostly heritable. Second, sequence-independent, autonomous methylation variation is readily generated. This highlights the potential of epigenetic inheritance to play an independent role in evolutionary processes, which is superimposed on the system of genetic inheritance.
- Published
- 2009
24. A multitrophic perspective on functioning and evolution of facilitation in plant communities
- Author
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Wim H. van der Putten and Multitrophic Interactions (MTI)
- Subjects
media_common.quotation_subject ,insect herbivory ,Context (language use) ,Plant Science ,natural enemies ,Biology ,Competition (biology) ,Predation ,soil feedback ,ecological communities ,Laboratorium voor Nematologie ,Ecology, Evolution, Behavior and Systematics ,media_common ,Local adaptation ,Trophic level ,rhizosphere bacteria ,Ecology ,Plant community ,PE&RC ,succession ,mycorrhizal fungi ,Plant ecology ,ammophila-arenaria ,Facilitation ,Laboratory of Nematology ,sand dune ,local adaptation - Abstract
Summary 1. Plant facilitation has been studied mostly in the context of plant-plant interactions, whereas multitrophic interactions including those that occur below ground have not yet received much attention. Here, I will discuss how above-ground and below-ground natural enemies and their pre dators influence plant facilitation and its evolution. 2. Specific above-ground and below-ground plant enemies and their predators play a major role in structuring the composition and dynamics of plant communities. In successional sequences, above ground and below-ground multitrophic level interactions may tip the balance from competitive to facilitative states and vice versa. 3. Little is known about how above-ground and below-ground multitrophic interactions develop along resource or stress gradients and how the outcomes of above-ground-below-ground interac tions depend on variations in these environmental conditions. 4. Facilitated plants need to fit into the above-ground-below-ground multitrophic communities of their facilitators. 5. Little is known also about the evolution of plant facilitation. The observed distance in phylogeny between facilitators and facilitated plants suggests that host-specific enemies may very well co-deter mine which species become facilitated by which facilitators. 6. Further, very little attention has been given to how plant strategies (allelopathy, accumulation of enemies, monopolization of symbionts) may be the result of selection against being facilitative. 7. Synthesis. Plant facilitation cannot be understood without considering a plant's natural enemies and also its enemies' enemies. Plant enemies can turn competitive interactions into facilitative inter actions, whereas the enemies' enemies can turn facilitation back into competition. Below-ground interactions will have longer-lasting effects on facilitation than those above ground, because many organisms can persist in the soil, even when the host plants have disappeared.
- Published
- 2009
25. Microorganisms and nematodes increase levels of secondary metabolites in roots and root exudates of Plantago lanceolata
- Author
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Arjen Biere, W.H. van der Putten, Susanne Wurst, Roel Wagenaar, Multitrophic Interactions (MTI), and Terrestrial Ecology (TE)
- Subjects
Exudate ,growth ,specialist ,specificity ,Soil Science ,Plant Science ,chemistry ,chemistry.chemical_compound ,Botany ,medicine ,Plantaginaceae ,generalist ,induction ,Laboratorium voor Nematologie ,Aucubin ,Rhizosphere ,Plantago ,biology ,food and beverages ,Plant physiology ,herbivore damage ,PE&RC ,biology.organism_classification ,Catalpol ,defense ,deterrent iridoid glycosides ,Shoot ,responses ,Laboratory of Nematology ,medicine.symptom - Abstract
Plant secondary metabolites play an important role in constitutive and inducible direct defense of plants against their natural enemies. While induction of defense by aboveground pathogens and herbivores is well-studied, induction by belowground organisms is less explored. Here, we examine whether soil microorganisms and nematodes can induce changes in levels of the secondary metabolites aucubin and catalpol (iridoid glycosides, IG) in roots and root exudates of two full-sib families of Plantago lanceolata originating from lines selected for low and high constitutive levels of IG in leaves. Addition of soil microorganisms enhanced the shoot and root biomass, and the concentration of aucubin in roots of both Plantago lines without affecting IG levels in the rhizosphere. By contrast, nematode addition tended to reduce the root biomass and enhanced the stalk biomass, and increased the levels of aucubin and catalpol in root exudates of both Plantago lines, without affecting root IG concentrations. The Plantago lines did not differ in constitutive levels of aucubin and total IG in roots, while the concentration of catalpol was slightly higher in roots of plants originally selected for low constitutive levels of IG in leaves. Root exudates of “high IG line” plants contained significantly higher levels of aucubin, which might be explained by their higher root biomass. We conclude that soil microorganisms can induce an increase of aucubin concentrations in the roots, whereas nematodes (probably plant feeders) lead to an enhancement of aucubin and catalpol levels in root exudates of P. lanceolata. A potential involvement of secondary metabolites in belowground interactions between plants and soil organisms is discussed.
- Published
- 2009
26. Local variation in belowground multitrophic interactions
- Author
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Francisco Monroy, Fernando Monroy, Wim Van der Putten, and Multitrophic Interactions (MTI)
- Subjects
harmful soil organisms ,ectoparasitic nematodes ,Soil Science ,Ecological succession ,natural enemies ,Microbiology ,entomopathogenic nematodes ,heterodera-arenaria ,coastal foredunes ,Laboratorium voor Nematologie ,root-feeding nematodes ,Organism ,Ammophila arenaria ,Rhizosphere ,Herbivore ,biology ,Ecology ,Heterodera ,arenaria l. link ,plant-parasitic nematodes ,Heterodera arenaria ,PE&RC ,biology.organism_classification ,grass ammophila-arenaria ,Nematode ,Laboratory of Nematology - Abstract
A growing number of studies point at the involvement of root herbivores in influencing plant performance, community composition and succession. However, little is known about the factors that control root herbivore abundance and the role of local variation in the effectiveness of these factors. Here, we performed a full factorial experiment with plants, root-feeding nematodes and rhizosphere microbial communities from two dune sites, to test the hypothesis that the outcome of belowground multitrophic interactions depends on local differences between the interacting organisms. The organisms included the marram grass Ammophila arenaria, the cyst nematode Heterodera arenaria, microbial plant pathogens and natural enemies of the nematodes from two coastal foredune systems, one in The Netherlands and one in Wales. The two plant populations differed at the molecular and phenotypic level, and the microbial communities from the two dune sites differed in the composition of the dominant soil fungi but not of the dominant bacteria. Plants were negatively affected by the rhizosphere microorganisms from one of the sites. Nevertheless, nematode performance was not affected by the origin of both the host plants and the microbial communities. The reproductive output of the cyst nematode depended on the presence of microorganisms, as well as on inter-population variability in the response of the nematode to these natural enemies. In the absence of microorganisms, the two nematode populations differed in the number and size of the produced cysts, although maternal effects cannot be excluded. Inter-population differences in the host plant were a secondary factor in the nematode–microorganisms interactions, and did not influence bottom–up control of the cyst nematodes. Our results did not reveal strong signals of coevolution in belowground multitrophic interactions of plants, cyst nematodes and soil microbial communities. We conclude that the interactions between the studied organisms do not necessarily depend on their local vs. non-local origin. Nevertheless, we were able to show that local variation in soil organism community composition can be an important factor in determining the outcome of interactions in belowground multitrophic systems.
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- 2009
27. Preparing a Paper for Publication: An Action Plan for Rapid Composition and Completion
- Author
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Jeffrey A. Harvey and Multitrophic Interactions (MTI)
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Ecology ,business.industry ,Computer science ,Interpretation (philosophy) ,Data science ,Field (computer science) ,Task (project management) ,Software ,Action plan ,Animal Science and Zoology ,business ,Composition (language) ,Ecology, Evolution, Behavior and Systematics ,Nature and Landscape Conservation - Abstract
An important challenge for scientists, especially those early in their careers, is preparing an effective article for submission to a peer-reviewed journal. Here, I present a number of suggestions on how it could be accomplished. This action plan addresses (1) how to approach a topic by developing a story line connected with what is already known in the field, (2) how to most efficiently organize and sequence one's efforts by starting with the descriptive parts of the manuscript and subsequently moving to the more interpretive parts, and (3) the advantages of using bibliographic software to facilitate quick and accurate referencing. I suggest that authors should aim to produce a story that does not overcomplicate the topic under investigation while at the same time presenting a full and accurate coverage and interpretation of the data. Importantly, the preparation of manuscripts becomes easier with time and practice, as individuals hone their own style and approach to this task.
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- 2009
28. Nectar-providing plants enhance the energetic state of herbivores as well as their parasitoids under field conditions
- Author
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Felix L. Wäckers, Karin Winkler, Delia M. Pinto, and Multitrophic Interactions (MTI)
- Subjects
Sector Fruit ,Honeydew ,Applied Plant Research, Fruit Research Unit ,Biological pest control ,Applied Plant Research ,natural enemies ,medicine.disease_cause ,Predation ,Nectar source ,food source ,oligosaccharides ,Pollen ,Botany ,medicine ,Nectar ,insects ,Lobularia maritima ,Herbivore ,Ecology ,biology ,biological-control ,biology.organism_classification ,Praktijkonderzoek Plant & Omgeving, Sector Fruit ,Agronomy ,Insect Science ,Praktijkonderzoek Plant & Omgeving ,Fruit Research Unit ,lepidoptera ,pests ,resources ,management ,honeydew - Abstract
1. The use of flowering vegetation has been widely advocated as a strategy for providing parasitoids and predators with nectar and pollen. However, their herbivorous hosts and prey may exploit floral food sources as well. 2. Previous laboratory studies have shown that not all flower species are equally suitable in providing accessible nectar. Relatively little is known about actual nectar exploitation under field conditions. 3. The present study investigates nectar exploitation by the pest, Plutella xylostella, and its parasitoid, Diadegma semiclausum, under field conditions and examines whether floral nectar exploitation in the field can be predicted based on controlled laboratory studies. 4. Insects were collected from fields bordered by flowering margins containing Fagopyrum esculentum, Lobularia maritima, Anethum graveolens, Centaurea jacea or the grass Lolium perenne (control). Whole insect bodies were individually assayed by HPLC to establish their sugar profile as a measure of the level of energy reserves and the degree of food source use. 5. The average overall sugar content of P. xylostella and D. semiclausum collected in fields bordered by flowering margins was significantly higher than those of individuals collected from grass-bordered control plots. To the authors' knowledge, this represents the first demonstration that nectar-providing plants enhance the energetic state of herbivores under field conditions. 6. In contrast to earlier laboratory studies, the present study did not find elevated sugar contents in P. xylostella and D. semiclausum individuals collected from fields bordered by buckwheat (F. esculentum). 7. The present study shows widespread sugar feeding by both the herbivore and its parasitoid. It also shows that laboratory studies establishing nectar exploitation under controlled conditions can not always be extrapolated to actual exploitation under field conditions. This emphasises the importance of studying field-collected insects with regard to food source use and nutritional status.
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- 2009
29. Genotype–environment interactions affect flower and fruit herbivory and plant chemistry of Arabidopsis thaliana in a transplant experiment
- Author
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T. J. de Jong, H. G. J. van Mil, Young Hae Choi, N.M. van Dam, A. Mosleh Arany, Hye Kyong Kim, E. van der Meijden, Robert Verpoorte, and Multitrophic Interactions (MTI)
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Herbivore ,biology ,fungi ,food and beverages ,Brassicaceae ,biology.organism_classification ,chemistry.chemical_compound ,chemistry ,Curculionidae ,Glucosinolate ,parasitic diseases ,Genetic variation ,Botany ,Plant defense against herbivory ,Arabidopsis thaliana ,Gene–environment interaction ,Ecology, Evolution, Behavior and Systematics - Abstract
Large differences exist in flower and fruit herbivory between dune and inland populations of plants of Arabidopsis thaliana (Brassicaceae). Two specialist weevils Ceutorhynchus atomus and C. contractus (Curculionidae) and their larvae are responsible for this pattern in herbivory. We test, by means of a reciprocal transplant experiment, whether these differences reflect environmental influences or genetic variation in plant defense level. All plants suffered more damage after being transplanted to the dune site than after being transplanted to the inland site. Plants of inland origin suffered more flower and fruit herbivory than plants of dune origin when grown at the dune transplant site, but differences were much smaller at the inland site. Both flower damage by adult weevils and fruit damage by their larvae were subject to significant genotype x environment interactions. The observed pattern in herbivory is a strong indication for local adaption of plant defense to the le! vel of herbivory by Ceutorhynchus. In order to identify the mechanism of defense, a quantitative analysis of glucosinolates was performed on the seeds with HPLC. Highly significant differences were found in glucosinolate types and total concentration. These patterns were mainly determined by the origin of the plants (dune or inland) and by a genotype x environment interaction. Herbivory was not significantly correlated to the concentration of glucosinolates in seeds. We therefore analyzed the total metabolic composition of seeds, using NMR spectroscopy and multivariate data analysis. Major differences in chemical composition were found in the water-methanol fractions: more glucosinolate and sucrose in the dune and more fatty acids, lipids and sinapoylmalate in the inland populations. We discuss which of these chemical factors could explain the marked differences in damage between populations.
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- 2009
30. Nonlinear effects of plant root and shoot jasmonic acid application on the performance of Pieris brassicae and its parasitoid Cotesia glomerata
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Nicole M. van Dam, Bao-Li Qiu, Louise E. M. Vet, Ciska E. Raaijmakers, Jeffrey A. Harvey, and Multitrophic Interactions (MTI)
- Subjects
ecological costs ,Brassica ,herbivore ,induced resistance ,food-web ,chemistry.chemical_compound ,host-plant ,Botany ,Laboratory of Entomology ,Ecology, Evolution, Behavior and Systematics ,Pieris brassicae ,Herbivore ,biology ,insect parasitoids ,Jasmonic acid ,fungi ,food and beverages ,feeding insect ,PE&RC ,Laboratorium voor Entomologie ,biology.organism_classification ,Cotesia glomerata ,signaling pathways ,chemistry ,solitary specialist ,Glucosinolate ,infochemical use ,Shoot ,Braconidae - Abstract
Summary 1Plant species employ several direct and indirect defence strategies to protect themselves against insect herbivores. Most studies, however, have focused on shoot-induced responses. Much less is known about interactions between below- and above-ground herbivores and how these may affect their respective parasitoids. 2Here, we quantify the impact of below-ground induced responses vs. that of above-ground induced responses in a feral Brassica on the performance of Pieris brassicae and its endoparasitoid Cotesia glomerata. Jasmonic acid (JA) was applied to induce the plants above- or below-ground. The glucosinolate, sugar and amino acid levels of the leaves were analysed. 3Pieris brassicae larvae grew significantly slower on shoot JA-induced (SJA) plants than on root JA-induced (RJA) and control plants, which were treated with acidic water. On RJA and control plants they showed similar developmental trajectories. Pupal masses, survival till eclosion and egg load, however, were similar on all plants. 4The development of C. glomerata larvae on SJA plants was significantly longer than that on RJA and control plants. In contrast, the parasitoid's pupal stage lasted longer in hosts feeding on control plants. The total developmental times eventually were similar in all groups. However, the masses of male and female C. glomerata adults that developed hosts on control and RJA plants were significantly larger than those from hosts on SJA plants. JA application increased total glucosinolate contents and decreased the sugars and total amino acids levels independent of whether JA was applied. However, the trajectories of herbivore-induced glucosinolate levels differed between RJA and SJA plants. 5These results show that the differential effects of above- and below-ground-induced responses on herbivores also affect higher trophic levels in a nonlinear fashion via differential changes in host plant quality. In particular, the indirect effects that below-ground herbivores have on the performance of above-ground parasitoids may exceed the direct effects of plant chemistry on herbivore performance. Consequently, above-ground and below-ground interactions mediated by induced plant responses have the potential to mediate insect community structure and function in complex ways.
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- 2009
31. Chemical diversity in Brassica oleracea affects biodiversity of insect herbivores
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Joop J. A. van Loon, Nicole M. van Dam, Marcel Dicke, Erik H. Poelman, Louise E. M. Vet, and Multitrophic Interactions (MTI)
- Subjects
0106 biological sciences ,pieris-rapae ,Insecta ,Time Factors ,Oviposition ,Glucosinolates ,Pieris rapae ,Brassica ,barbarea-vulgaris ,Generalist and specialist species ,010603 evolutionary biology ,01 natural sciences ,generalist herbivores ,chemistry.chemical_compound ,plant defense ,genotypic variation ,Botany ,Plant defense against herbivory ,Animals ,Cluster Analysis ,Laboratory of Entomology ,Ecology, Evolution, Behavior and Systematics ,Barbarea vulgaris ,2. Zero hunger ,Herbivore ,biology ,Ecology ,EPS-2 ,fungi ,food and beverages ,Brassicaceae ,Biodiversity ,Feeding Behavior ,15. Life on land ,wild populations ,biology.organism_classification ,Laboratorium voor Entomologie ,feeding stimulants ,chemistry ,arthropod community structure ,Glucosinolate ,Larva ,primrose oenothera-biennis ,Brassica oleracea ,Female ,genetic-variation ,010606 plant biology & botany - Abstract
Intraspecific variation in plants plays a major role in the composition and diversity of the associated insect community. Resistance traits of plants are likely candidates mediating community composition. However, it is debated whether total concentrations of chemical compounds or specific compounds determine herbivore resistance, and how chemical diversity among plant genotypes in turn affects the composition of the associated herbivore community. To study the role of specific chemical compounds in affecting the herbivore community, we used cultivated Brassica oleracea. The cultivars differ qualitatively in glucosinolate profile, i.e., foliar composition of different glucosinolate compounds, and only a little in total concentration of glucosinolates, the secondary metabolites specific for the Brassicaceae family. In field and laboratory experiments, we tested whether individual compounds explained differences in herbivore community composition, and whether herbivores with a similar degree of host plant specialization responded in a similar way to variation in glucosinolate profiles. In the field B. oleracea cultivars differed widely in species richness and composition of the herbivore community, as well as in the density of insects they harbored. Plants with high concentrations of the short side chain alkenyl glucosinolate, glucoiberin, harbored low herbivore diversity. Higher biodiversity was found when plants had glucosinolate profiles containing high concentrations of glucosinolates with elongated side chains, which are biosynthetically linked to glucoiberin. Although glucosinolates are known to have differential effects on generalist and specialist herbivores, all herbivore species exhibited similar responses to the intraspecific variation in foliar glucosinolate profiles of the B. oleracea cultivars. This observation is supported by the correspondence between oviposition preferences of the specialist herbivore Pieris rapae and the generalist Mamestra brassicae in the field and the laboratory, using the same cultivars, and may be due to the relatively low concentrations of glucosinolates in cultivars. Our results show that variation in the concentration of short side-chain glucosinolates affects the composition of the herbivore community associated with brassicaceous plants.
- Published
- 2009
32. Snowdrop lectin (Galanthus nivalis agglutinin) in aphid honeydew negatively affects survival of a honeydew- consuming parasitoid
- Author
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Jörg Romeis, Joseph Woodring, Petra A. M. Hogervorst, Felix L. Wäckers, and Multitrophic Interactions (MTI)
- Subjects
2. Zero hunger ,0106 biological sciences ,0303 health sciences ,Honeydew ,Aphid ,biology ,media_common.quotation_subject ,fungi ,Longevity ,food and beverages ,Forestry ,Genetically modified crops ,biology.organism_classification ,01 natural sciences ,Parasitoid ,010602 entomology ,03 medical and health sciences ,Rhopalosiphum padi ,Sitobion avenae ,Insect Science ,Botany ,Composition (visual arts) ,Agronomy and Crop Science ,030304 developmental biology ,media_common - Abstract
1. Insecticidal proteins can be excreted in the honeydew when sap sucking insects feed on insect resistant transgenic plants. Honeydew can be an important source of carbohydrates thus potentially exposing a broad range of honeydew feeding insects to transgene products. 2. Snowdrop lectin ( Galanthus nivalis agglutinin; GNA) dissolved in a 2 m sucrose solution had no antifeedant effect on female aphid parasitoids (Aphidius ervi) but had a direct negative effect on their longevity. 3. When feeding on honeydew from Rhopalosiphum padi feeding on a GNA containing artificial diet Aphidius ervi suffered a longevity reduction that was more pronounced than was to be expected based on the detected GNA concentration in the honeydew. 4. Analysis of carbohydrate and amino acid composition revealed that a change in honeydew composition caused by a GNA effect on the aphids could be a possible explanation for the additional reduction in parasitoid longevity. 5. When comparing the effect of honeydew from Sitobion avenae and R. padi feeding on GNA expressing or nontransformed wheat plants on A. ervi longevity aphid species was found to have a significant effect whereas the wheat variety had no effect. The latter result was probably due to low GNA expression levels in the plants. Differences in nutritional suitability between honeydew from R. padi and S. avenae could be explained by differences in carbohydrate and amino acid composition. 6. This is the first study to demonstrate that GNA ingested by aphids and transported into the honeydew can negatively affect the parasitoids consuming this honeydew. 7. We recommend that honeydew should be considered as a route of exposure to transgene products in future risk assessment studies.
- Published
- 2009
33. Competition and brood reduction: testing alternative models of clutch-size evolution in parasitoids
- Author
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John J. Pexton, James B. Whitfield, George E. Heimpel, Paul J. Ode, Jetske G. de Boer, Louise E. M. Vet, and Multitrophic Interactions (MTI)
- Subjects
Avian clutch size ,media_common.quotation_subject ,Population ,Hymenoptera ,Competition (biology) ,Parasitoid ,braconidae ,Laboratory of Entomology ,education ,host discrimination ,larval aggression ,Ecology, Evolution, Behavior and Systematics ,media_common ,cotesia-flavipes ,education.field_of_study ,biology ,solitary ,Ecology ,fungi ,transition ,wasps ,biology.organism_classification ,PE&RC ,Laboratorium voor Entomologie ,Brood ,nonsiblicidal behavior ,gregarious development ,Animal Science and Zoology ,hymenoptera ,Braconidae ,Scramble competition - Abstract
Competition between siblings occurs in many taxa including parasitoid wasps. Larvae of solitary species eliminate competitors by engaging in aggressive behavior, thus restricting brood size to a single individual. In gregarious species, more than one offspring can develop per host. There are 2 models by which gregariousness can arise in a population of solitary individuals: 1) through a reduction in larval mobility (with the retention of aggressive behavior) or 2) through a reduction in fighting behavior or ability. When more larvae are present than can be supported by available host resources, these 2 models make opposing predictions regarding the process of brood size reduction: Mortality occurring early in larval development under the reduced mobility hypothesis versus mortality occurring throughout larval development under the reduced aggression hypothesis. Here, we measure changes in brood size over the course of larval development of the gregarious parasitoid, Cotesia flavipes. Superparasitized hosts contained approximately twice as many C. flavipes eggs as hosts parasitized by a single parasitoid female. Brood sizes in superparasitized hosts declined gradually as C. flavipes individuals developed, whereas brood sizes remained constant during larval development in singly parasitized hosts. An absence of wounded or destroyed larvae suggested no aggressive behavior. Collectively, these results support the reduced aggression hypothesis. Copyright 2009, Oxford University Press.
- Published
- 2009
34. Disease status and population origin effects on floral scent: potential consequences for oviposition and fruit predation in a complex interaction between a plant, fungus, and noctuid moth
- Author
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Arjen Biere, Andreas Jürgens, Stefan Dötterl, Lorne W. Wolfe, and Multitrophic Interactions (MTI)
- Subjects
Pollination ,Acyclic Monoterpenes ,Oviposition ,Population ,Zoology ,Flowers ,Alkenes ,Moths ,Biochemistry ,Gas Chromatography-Mass Spectrometry ,Predation ,Host-Parasite Interactions ,Ocimene ,chemistry.chemical_compound ,Pollinator ,Botany ,Silene latifolia ,Animals ,education ,Silene ,Ecology, Evolution, Behavior and Systematics ,Plant Diseases ,education.field_of_study ,Aldehydes ,biology ,Behavior, Animal ,Basidiomycota ,fungi ,Microbotryum violaceum ,food and beverages ,General Medicine ,biology.organism_classification ,chemistry ,Fruit ,Odorants ,Pollen ,Hadena - Abstract
In the Silene latifolia-Hadena bicruris nursery pollination system, the Hadena moth is both pollinator and seed predator of its host plant. Floral scent, which differs among S. latifolia individuals and populations, is important for adult Hadena to locate its host. However, the success of moth larvae is strongly reduced if hosts are infected by the anther smut fungus Microbotryum violaceum, a pathogen that is transmitted by flower visitors. There were no qualitative differences between the scent of flowers from healthy and diseased plants. In addition, electroantennographic measurements showed that Hadena responded to the same subset of 19 compounds in samples collected from healthy and diseased plants. However, there were significant quantitative differences in scent profiles. Flowers from diseased plants emitted both a lower absolute amount of floral scent and had a different scent pattern, mainly due to their lower absolute amount of lilac aldehyde, whereas their amount o! f (E)-beta-ocimene was similar to that in healthy flowers. Dual choice behavioral wind tunnel tests using differently scented flowers confirmed that moths respond to both qualitative and quantitative aspects of floral scent, suggesting that they could use differences in floral scent between healthy and infected plants to discriminate against diseased plants. Population mean fruit predation rates significantly increased with population mean levels of the emission rates of lilac aldehyde per flower, indicating that selection on floral scent compounds may not only be driven by effects on pollinator attraction but also by effects on fruit predation. However, variation in mean emission rates of scent compounds per flower generally could not explain the higher fruit predation in populations originating from the introduced North American range compared to populations native to Europe.
- Published
- 2009
35. Intraspecific competition between adult females of the hyperparasitoid Trichomalopsis apanteloctena (Hymenoptera: Chelonidae), for domination of Cotesia kariyai (Hymenoptera: Braconidae) cocoons
- Author
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Yutaka Nakamatsu, Jeffrey A. Harvey, Toshiharu Tanaka, and Multitrophic Interactions (MTI)
- Subjects
biology ,Cotesia kariyai ,Host (biology) ,Ecology ,Insect Science ,Trichomalopsis ,fungi ,Inclusive fitness ,Hymenoptera ,biology.organism_classification ,Braconidae ,Intraspecific competition ,Parasitoid - Abstract
The development of parasitoid wasps is dependent on the finite resources contained in a single item of resource (=host) that is frequently not much larger than the adult parasitoid. When the costs of egg production are high, and host distribution is highly aggregated, parasitoid females may spend prolonged periods guarding their eggs and host resources as an adaptive strategy to optimize their inclusive fitness. Here, we examine aggressive interactions between the females of the secondary hyperparasitoid Trichomalopsis apanteloctena (Crawford) (Hymenoptera: Chelonidae), for control of cocoon clusters of their primary parasitoid host Cotesia kariyai (Watanabe) (Hymenoptera: Braeonidae). Generally, larger female hyperparasitoids were more successful at defending cocoon clusters than smaller female hyperparasitoids. However, when first encountering host cocoons, larger females behaved more aggressively toward conspecific wasps than smaller females. After occupation of a host cocoon cluster, females of similar size rarely engaged in physical combat, but both females primarily exhibited threatening behavior toward each other. However, larger females usually displaced smaller females which had initially occupied cocoon clusters. Some small females chewed through the outer cocoon silk layer to avoid being displaced by larger females and these wasps were able to continue parasitizing cocoons of C. kariyai. Extended bouts of aggression tended to reduce the number of eggs laid by the guarding female because of disruption of oviposition behavior. The relationship between the size of host cocoons and body mass in T. apanteloctena was also examined. The size of hyperparasitoid progeny was strongly correlated with host size. However, the relationship between maternal size, the number of matured eggs in her ovarioles and body mass in her offspring was not significant.
- Published
- 2009
36. Metabolomic analysis of the interaction between plants and herbivores
- Author
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Wim H. van der Putten, Nicole M. van Dam, J. William Allwood, Emma Marsden-Edwards, Jeroen J. Jansen, Royston Goodacre, Ecosystems Studies, and Multitrophic Interactions (MTI)
- Subjects
pieris-rapae ,Endocrinology, Diabetes and Metabolism ,Clinical Biochemistry ,Pieris rapae ,Biochemistry ,induced resistance ,chemistry.chemical_compound ,Metabolomics ,Botany ,cell-cultures ,magnetic-resonance-spectroscopy ,induced responses ,Laboratorium voor Nematologie ,Trophic level ,Herbivore ,brassica-rapa leaves ,biology ,Jasmonic acid ,fungi ,jasmonic acid ,food and beverages ,sequestration ,biology.organism_classification ,PE&RC ,defense ,chemistry ,Shoot ,Brassica oleracea ,insect ,Laboratory of Nematology ,Plant tolerance to herbivory - Abstract
Insect herbivores by necessity have to deal with a large arsenal of plant defence metabolites. The levels of defence compounds may be increased by insect damage. These induced plant responses may also affect the metabolism and performance of successive insect herbivores. As the chemical nature of induced responses is largely unknown, global metabolomic analyses are a valuable tool to gain more insight into the metabolites possibly involved in such interactions. This study analyzed the interaction between feral cabbage (Brassica oleracea) and small cabbage white caterpillars (Pieris rapae) and how previous attacks to the plant affect the caterpillar metabolism. Because plants may be induced by shoot and root herbivory, we compared shoot and root induction by treating the plants on either plant part with jasmonic acid. Extracts of the plants and the caterpillars were chemically analysed using Ultra Performance Liquid Chromatography/Time of Flight Mass Spectrometry (UPLCT/MS). The study revealed that the levels of three structurally related coumaroylquinic acids were elevated in plants treated on the shoot. The levels of these compounds in plants and caterpillars were highly correlated: these compounds were defined as the ‘metabolic interface’. The role of these metabolites could only be discovered using simultaneous analysis of the plant and caterpillar metabolomes. We conclude that a metabolomics approach is useful in discovering unexpected bioactive compounds involved in ecological interactions between plants and their herbivores and higher trophic levels.
- Published
- 2009
37. Field parasitism rates of caterpillars on Brassica oleracea plants are reliably predicted by diffential attraction of Cotesia parasitoids
- Author
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Cornelis A. Hordijk, Joop J. A. van Loon, Nicole M. van Dam, Erik H. Poelman, Ayub M. O. Oduor, Colette Broekgaarden, Louise E. M. Vet, Marcel Dicke, Jeroen J. Jansen, Microbial Wetland Ecology (MWE), Multitrophic Interactions (MTI), and Terrestrial Ecology (TE)
- Subjects
specialist ,Parasitism ,herbivore ,Pieris rapae ,natural enemies ,Parasitoid ,Laboratorium voor Plantenveredeling ,Botany ,Laboratory of Entomology ,Ecology, Evolution, Behavior and Systematics ,biology ,EPS-2 ,abiotic factors ,rubecula hymenoptera ,Cotesia glomerata ,biology.organism_classification ,Laboratorium voor Entomologie ,methyl salicylate ,defense ,Horticulture ,Plant Breeding ,damaged plants ,volatiles ,Pieris (butterfly) ,Cotesia ,host ,Brassica oleracea ,Braconidae - Abstract
1. Herbivore-induced plant volatiles (HIPVs) play an important role in host location of parasitoid wasps and may benefit the plant by top–down control of its herbivorous attackers. Although many studies have shown that accessions of plants differ in attractiveness to parasitoid wasps under controlled laboratory studies, few studies have confirmed that the most attractive accessions also sustain highest parasitism rates in the field. Here, we tested whether in-flight preference of parasitoids for HIPVs from cultivars of Brassica oleracea in the laboratory reliably predicts the parasitism rates of herbivores feeding on these cultivars in the field. 2. In wind tunnel tests in the laboratory, we ranked cultivars of B. oleracea for the preference of two congeneric parasitoids ( Cotesia glomerata and C. rubecula ) for their HIPVs. The cultivars were then compared for their relative parasitism rates of caterpillars in the field. Throughout the growth season in the field, we infested the different cultivars with Pieris caterpillars on a weekly basis. The caterpillars were recollected after 3 days, dissected and scored for the rate of parasitism. 3. Cultivars of B. oleracea that we identified as most attractive to parasitoids in the laboratory also sustained highest proportions of parasitism in the field. The composition of the headspace of the B. oleracea cultivars damaged by P. rapae differs among these cultivars in the amounts of terpenoids and methyl salicylate emitted, which may be responsible for the differential attraction of parasitoids to the cultivars. 4. Our results show that intraspecific variation in HIPVs of plants is paralleled by differential parasitism of caterpillars in the field. The widely used laboratory assays on HIPV-based preferences of parasitoids provided reliable information on relative parasitism differences of herbivores as found in the field. 5. Thereby, our work confirms that through HIPVs plants attract parasitoids that effectively parasitize herbivores even under the complex and variable abiotic and biotic conditions in (agro-) ecosystems.
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- 2009
38. Chemical complexity of volatiles from plants induced by multiple attack
- Author
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Marcel Dicke, Roxina Soler, Joop J. A. van Loon, and Multitrophic Interactions (MTI)
- Subjects
0106 biological sciences ,Multiple attack ,Context (language use) ,arbuscular mycorrhizal fungi ,arabidopsis-thaliana ,natural enemies ,Arbuscular mycorrhizal fungi ,010603 evolutionary biology ,01 natural sciences ,Host-Parasite Interactions ,chemistry.chemical_compound ,Plant Growth Regulators ,Botany ,Animals ,Arabidopsis thaliana ,Natural enemies ,Laboratory of Entomology ,Arthropods ,Molecular Biology ,Herbivore ,biology ,Ecology ,EPS-2 ,Jasmonic acid ,jasmonic acid ,tritrophic interaction webs ,Cell Biology ,Plants ,lima-bean leaves ,biology.organism_classification ,Laboratorium voor Entomologie ,Attraction ,life-history traits ,chemistry ,nicotiana-attenuata ,foraging efficiency ,Volatilization ,indirect defense ,010606 plant biology & botany - Abstract
The attack of a plant by herbivorous arthropods can result in considerable changes in the plant's chemical phenotype. The emission of so-called herbivore-induced plant volatiles (HIPV) results in the attraction of carnivorous enemies of the herbivores that induced these changes. HIPV induction has predominantly been investigated for interactions between one plant and one attacker. However, in nature plants are exposed to a variety of attackers, either simultaneously or sequentially, in shoots and roots, causing much more complex interactions than have usually been investigated in the context of HIPV. To develop an integrated view of how plants respond to their environment, we need to know more about the ways in which multiple attackers can enhance, attenuate, or otherwise alter HIPV responses. A multidisciplinary approach will allow us to investigate the underlying mechanisms of HIPV emission in terms of phytohormones, transcriptional responses and biosynthesis of metabolite! s in an effort to understand these complex plant-arthropod interactions.
- Published
- 2009
39. Plant–soil feedback induces shifts in biomass allocation in the invasive plant Chromolaena odorata
- Author
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Nicola Stevens, Wim H. van der Putten, Mariska te Beest, Han Olff, Olff group, and Multitrophic Interactions (MTI)
- Subjects
POPULATION-DYNAMICS ,solidago-gigantea asteraceae ,ved/biology.organism_classification_rank.species ,biological invasions ,Chromolaena odorata ,AMMOPHILA-ARENARIA ,Introduced species ,Plant Science ,Shrub ,phenotypic plasticity ,Invasive species ,PYRROLIZIDINE ALKALOIDS ,SOLIDAGO-GIGANTEA ASTERACEAE ,MICROBIAL COMMUNITIES ,Panicum maximum ,Ecology ,biology ,south-africa ,accumulation of local pathogens ,food and beverages ,PE&RC ,SOUTH-AFRICA ,Biosystematiek ,INCREASED COMPETITIVE ABILITY ,Panicum ,evolution of increased competitive ability ,enemy release ,Soil biology ,microbial communities ,borne pathogens ,BORNE PATHOGENS ,pyrrolizidine alkaloids ,PHENOTYPIC PLASTICITY ,Dominance (ecology) ,Laboratorium voor Nematologie ,Ecology, Evolution, Behavior and Systematics ,Ammophila arenaria ,plant-soil interactions ,ved/biology ,biological-control ,increased competitive ability ,population-dynamics ,biology.organism_classification ,Wildlife Ecology and Conservation ,ammophila-arenaria ,Biosystematics ,Laboratory of Nematology ,biomass allocation ,BIOLOGICAL-CONTROL - Abstract
P> Soil communities and their interactions with plants may play a major role in determining the success of invasive species. However, rigorous investigations of this idea using cross-continental comparisons, including native and invasive plant populations, are still scarce.We investigated if interactions with the soil community affect the growth and biomass allocation of the (sub)tropical invasive shrub Chromolaena odorata. We performed a cross-continental comparison with both native and non-native-range soil and native and non-native-range plant populations in two glasshouse experiments.Results are interpreted in the light of three prominent hypotheses that explain the dominance of invasive plants in the non-native range: the enemy release hypothesis, the evolution of increased competitive ability hypothesis and the accumulation of local pathogens hypothesis.Our results show that C. odorata performed significantly better when grown in soil pre-cultured by a plant species other than C. odorata. Soil communities from the native and non-native ranges did not differ in their effect on C. odorata performance. However, soil origin had a significant effect on plant allocation responses.Non-native C. odorata plants increased relative allocation to stem biomass and height growth when confronted with soil communities from the non-native range. This is a plastic response that may allow species to be more successful when competing for light. This response differed between native and non-native-range populations, suggesting that selection may have taken place during the process of invasion. Whether this plastic response to soil organisms will indeed select for increased competitive ability needs further study.The native grass Panicum maximum did not perform worse when grown in soil pre-cultured by C. odorata. Therefore, our results did not support the accumulation of local pathogens hypothesis.Synthesis. Non-native C. odorata did not show release from soil-borne enemies compared to its native range. However, non-native plants responded to soil biota from the non-native range by enhanced allocation in stem biomass and height growth. This response can affect the competitive balance between native and invasive species. The evolutionary potential of this soil biota-induced change in plant biomass allocation needs further study.
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- 2009
40. Role of glucosinolates in insect-plant relationships and multitrophic interactions
- Author
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N.M. van Dam, Richard J. Hopkins, J.J.A. van Loon, and Multitrophic Interactions (MTI)
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Crops, Agricultural ,pieris-rapae ,Food Chain ,Insecta ,mustard oil bomb ,oilseed rape ,Oviposition ,Glucosinolates ,Pieris rapae ,arabidopsis-thaliana ,Breeding ,parasitoid diaeretiella-rapae ,chemistry.chemical_compound ,beetle psylliodes-chrysocephala ,Botany ,Animals ,Laboratory of Entomology ,Ecology, Evolution, Behavior and Systematics ,cabbage root fly ,Abiotic component ,Appetitive Behavior ,Biotic component ,biology ,Host (biology) ,Myrosinase ,EPS-2 ,fungi ,food and beverages ,Brassicaceae ,brassica-napus ,sawfly athalia-rosae ,Feeding Behavior ,plutella-xylostella ,biology.organism_classification ,Laboratorium voor Entomologie ,Crucifer ,chemistry ,Insect Science ,Glucosinolate - Abstract
Glucosinolates present classical examples of plant compounds affecting insect-plant interactions. They are found mainly in the family Brassicaceae, which includes several important crops. More than 120 different glucosinolates are known. The enzyme myrosinase, which is stored in specialized plant cells, converts glucosinolates to the toxic isothiocyanates. Insect herbivores may reduce the toxicity of glucosinolates and their products by excretion, detoxification, or behavioral adaptations. Glucosinolates also affect higher trophic levels, via reduced host or prey quality or because specialist herbivores may sequester glucosinolates for their own defense. There is substantial quantitative and qualitative variation between plant genotypes, tissues, and ontogenetic stages, which poses specific challenges to insect herbivores. Even though glucosinolates are constitutive defenses, their levels are influenced by abiotic and biotic factors including insect damage. Plant breeders may use knowledge on glucosinolates to increase insect resistance in Brassica crops. State-of-the-art techniques, such as mutant analysis and metabolomics, are necessary to identify the exact role of glucosinolates. Acronyms and Definitions Constitutive defense: defense characteristics that are always expressed in the plant Induced defense: induced responses that reduce the negative fitness consequences of an attack by a pest or pathogen Induced response: change in chemical compound levels after damage by herbivores Multitrophic interactions: interactions that involve more than two trophic levels in a food web Sequestration: the active accumulation of material as a means of protection against organisms from a higher trophic level Synomone: an allelochemical that elicits a response from which both the originator and receiver benefit Token (or sign) stimulus: a stimulus by which an animal distinguishes an important object
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- 2009
41. Influence of presence and spatial arrangement of belowground insects on host-plant selection of aboveground insects: a field study
- Author
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Louise E. M. Vet, Jeffrey A. Harvey, Thomas S. Hoffmeister, W.H. van der Putten, A. M. Cortesero, Roxina Soler, S. V. Schaper, T. M. Bezemer, Royal Netherlands Academy of Arts and Sciences (KNAW), University of Bremen, Laboratory of Nematology, Wageningen University and Research [Wageningen] (WUR), Biologie des organismes et des populations appliquées à la protection des plantes (BIO3P), Institut National de la Recherche Agronomique (INRA)-Université de Rennes 1 (UR1), Université de Rennes (UNIV-RENNES)-Université de Rennes (UNIV-RENNES)-AGROCAMPUS OUEST, Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro)-Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro), Université de Rennes 1 (UR1), Université de Rennes (UNIV-RENNES), Laboratory of Entomology, Animal Population Biology, Multitrophic Interactions (MTI), Institut National de la Recherche Agronomique (INRA)-Université de Rennes (UR)-AGROCAMPUS OUEST, and Université de Rennes (UR)
- Subjects
0106 biological sciences ,HERBIVORE BEHAVIOUR ,ALIMENTATION ,pieris-rapae ,PIERIS RAPAE ,media_common.quotation_subject ,[SDV]Life Sciences [q-bio] ,Pieris rapae ,Insect ,natural enemies ,Generalist and specialist species ,010603 evolutionary biology ,01 natural sciences ,Competition (biology) ,MULTITROPHIC INTERACTIONS ,resistance ,brassicae l ,Botany ,ABOVE-BELOWGROUND INTERACTIONS ,Laboratory of Entomology ,Laboratorium voor Nematologie ,media_common ,BREVICORYNE BRASSICAE ,Larva ,Aphid ,Ecology ,biology ,fungi ,food and beverages ,PLANT SELECTION ,15. Life on land ,biology.organism_classification ,PE&RC ,Laboratorium voor Entomologie ,Agronomy ,Brevicoryne brassicae ,mediated interactions ,Insect Science ,DELIA RADICUM ,PLANT-INSECT INTERACTIONS ,responses ,root herbivory ,Laboratory of Nematology ,coleoptera-chrysomelidae ,competition ,Delia radicum ,performance ,010606 plant biology & botany - Abstract
International audience; 1. Several studies have shown that above- and belowground insects can interact by influencing each others growth, development, and survival when they feed on the same host-plant. In natural systems, however, insects can make choices on which plants to oviposit and feed. A field experiment was carried out to determine if root-feeding insects can influence feeding and oviposition preferences and decisions of naturally colonising foliar-feeding insects. 2. Using the wild cruciferous plant Brassica nigra and larvae of the cabbage root fly Delia radicum as the belowground root-feeding insect, naturally colonising populations of foliar-feeding insects were monitored over the course of a summer season. 3. Groups of root-infested and root-uninfested B. nigra plants were placed in a meadow during June, July, and August of 2006 for periods of 3 days. The root-infested and the root-uninfested plants were either dispersed evenly or placed in clusters. Once daily, all leaves of each plant were carefully inspected and insects were removed and collected for identification. 4. The flea beetles Phyllotreta spp. and the aphid Brevicoryne brassicae were significantly more abundant on root-uninfested (control) than on root-infested plants. However, for B. brassicae this was only apparent when the plants were placed in clusters. Host-plant selection by the generalist aphid M. persicae and oviposition preference by the specialist butterfly P. rapae, however, were not significantly influenced by root herbivory. 5. The results of this study show that the presence of root-feeding insects can affect feeding and oviposition preferences of foliar-feeding insects, even under natural conditions where many other interactions occur simultaneously. The results suggest that root-feeding insects play a role in the structuring of aboveground communities of insects, but these effects depend on the insect species as well as on the spatial distribution of the root-feeding insects.
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- 2009
42. Consequences of constitutive and induced variation in plant nutritional quality for immune defence of a herbivore against parasitism
- Author
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Georgios Prekatsakis, Jeffrey A. Harvey, Marcel Dicke, Rieta Gols, Tibor Bukovinszky, Louise E. M. Vet, Erik H. Poelman, Terrestrial Ecology (TE), Aquatic Ecology (AqE), and Multitrophic Interactions (MTI)
- Subjects
0106 biological sciences ,Food Chain ,Parasitism ,Pieris rapae ,Brassica ,iridoid glycosides ,010603 evolutionary biology ,01 natural sciences ,Host-Parasite Interactions ,Parasitoid ,bottom-up ,chemical defense ,Botany ,Animals ,Laboratory of Entomology ,Ecology, Evolution, Behavior and Systematics ,Trophic level ,2. Zero hunger ,Herbivore ,trophic levels ,biology ,fungi ,food and beverages ,wasps ,biology.organism_classification ,Cotesia glomerata ,PE&RC ,populations ,Laboratorium voor Entomologie ,Immunity, Innate ,communities ,010602 entomology ,insect herbivore ,England ,Larva ,Linear Models ,Brassica oleracea ,lepidoptera ,Butterflies ,Braconidae ,performance - Abstract
The mechanisms through which trophic interactions between species are indirectly mediated by distant members in a food web have received increasing attention in the field of ecology of multitrophic interactions. Scarcely studied aspects include the effects of varying plant chemistry on herbivore immune defences against parasitoids. We investigated the effects of constitutive and herbivore-induced variation in the nutritional quality of wild and cultivated populations of cabbage (Brassica oleracea) on the ability of small cabbage white Pieris rapae (Lepidoptera, Pieridae) larvae to encapsulate eggs of the parasitoid Cotesia glomerata (Hymenoptera, Braconidae). Average encapsulation rates in caterpillars parasitised as first instars were low and did not differ among plant populations, with caterpillar weight positively correlating with the rates of encapsulation. When caterpillars were parasitised as second instar larvae, encapsulation of eggs increased. Caterpillars were larger on the cultivated Brussels sprouts plants and exhibited higher levels of encapsulation compared with caterpillars on plants of either of the wild cabbage populations. Observed differences in encapsulation rates between plant populations could not be explained exclusively by differences in host growth on the different Brassica populations. Previous herbivore damage resulted in a reduction in the larval weight of subsequent herbivores with a concomitant reduction in encapsulation responses on both Brussels sprouts and wild cabbage plants. To our knowledge this is the first study demonstrating that constitutive and herbivore-induced changes in plant chemistry act in concert, affecting the immune response of herbivores to parasitism. We argue that plant-mediated immune responses of herbivores may be important in the evaluation of fitness costs and benefits of herbivore diet on the third trophic level.
- Published
- 2009
43. Plant ectoparasitic nematodes prefer roots without their microbial enemies
- Author
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Henk Duyts, Wim H. van der Putten, Maarten J. K. de Milliano, Anna M. Piśkiewicz, and Multitrophic Interactions (MTI)
- Subjects
feeding nematodes ,Soil biology ,Biological pest control ,Soil Science ,Plant Science ,Tylenchorhynchus ,Botany ,Meloidogyne incognita ,meloidogyne-incognita ,Rotylenchulus reniformis ,Laboratorium voor Nematologie ,coastal foredunes ,Ammophila arenaria ,Rhizosphere ,biology ,biological-control ,soil-borne fungi ,PE&RC ,biology.organism_classification ,grass ammophila-arenaria ,Nematode ,Agronomy ,community ,rotylenchulus-reniformis ,parasitic nematodes ,Laboratory of Nematology ,clonal grass - Abstract
Root-feeding nematodes are major soil-borne pests in agriculture. In natural ecosystems, their abundance can be strongly controlled by natural enemies. In coastal foredune soil, the abundance of the ectoparasitic nematode Tylenchorhynchus ventralis is controlled by local interactions with soil microorganisms. If not controlled, T. ventralis reduces growth and performance of the host plant Ammophila arenaria. In the present study, we examine if the nematodes may sense the presence of soil microorganisms and, if so, they are able to actively avoid their enemies. First, using Petri dishes with agar medium we examined if T. ventralis can choose between A. arenaria seedlings inoculated with or without soil microorganisms. We observed that there was a trend (although non-significant) in nematode migration towards the non-inoculated plants. If the seedlings were not present, the nematodes did not make any choice and stayed in the centre of the Petri dish. Then, using Y-tubes filled with sterilized dune soil, we examined if T. ventralis could choose between A. arenaria roots with or without microorganisms. We also included treatments of microbial suspensions without plants and a microbe-free filtrate. We observed that the nematodes preferred roots without microorganisms. Microorganisms alone or roots with microbial filtrate did not influence nematode choice significantly. We conclude that the nematode T. ventralis is able to choose roots without soil microorganisms when having roots with them as alternative. Such avoidance could explain why biological control of nematodes in field is not always effective, especially when microbial antagonists accumulate in specific parts of the rhizosphere.
- Published
- 2008
44. Long-term organic farming fosters below and aboveground biota: Implications for soil quality, biological control and productivity
- Author
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Andreas Fließbach, Jaap Bloem, Michael Bonkowski, Soren Christensen, Christophe Robin, Heikki Setälä, T. Martijn Bezemer, Juha Mikola, Paul Mäder, Stefan Scheu, David Dubois, Wim H. van der Putten, Katarina Hedlund, Klaus Birkhofer, F. Ekelund, Lucie Gunst, Fabienne Tatin-Froux, Microelectronic Systems Institute ( MES ), Darmstadt University of Technology [Darmstadt], DAIMI ( DAIMI ), DAIMI, University of Copenhagen ( KU ), Laboratoire Agronomie et Environnement ( LAE ), Institut National de la Recherche Agronomique ( INRA ) -Université de Lorraine ( UL ), Department of Ecological and Environmental Sciences, Laboratoire Chrono-environnement ( LCE ), Université Bourgogne Franche-Comté ( UBFC ) -Centre National de la Recherche Scientifique ( CNRS ) -Université de Franche-Comté ( UFC ), CONSIDER, Microelectronic Systems Institute (MES), DAIMI (DAIMI), University of Copenhagen = Københavns Universitet (KU), Laboratoire Agronomie et Environnement (LAE), Institut National de la Recherche Agronomique (INRA)-Université de Lorraine (UL), Laboratoire Chrono-environnement - UFC (UMR 6249) (LCE), Centre National de la Recherche Scientifique (CNRS)-Université de Franche-Comté (UFC)-Université Bourgogne Franche-Comté [COMUE] (UBFC), Department of Ecological and Environmental Sciences [Lahti], University of Helsinki, Laboratoire Chrono-environnement - CNRS - UFC (UMR 6249) (LCE), Centre National de la Recherche Scientifique (CNRS)-Université de Franche-Comté (UFC), Université Bourgogne Franche-Comté [COMUE] (UBFC)-Université Bourgogne Franche-Comté [COMUE] (UBFC), Centre for Terrestrial Ecology, The Netherlands Institute of Ecology (NIOO), Wageningen University and Research Centre (WUR), Agroscope, Research Institute of Organic Agriculture - Forschungsinstitut für biologischen Landbau (FiBL), Lund University [Lund], Laboratory of Nematology, Wageningen University and Research [Wageningen] (WUR), Multitrophic Interactions (MTI), and Université Bourgogne Franche-Comté [COMUE] (UBFC)-Centre National de la Recherche Scientifique (CNRS)-Université de Franche-Comté (UFC)
- Subjects
0106 biological sciences ,generalist predators ,respiration microbienne ,[SDV]Life Sciences [q-bio] ,faune du sol ,natural enemies ,alternative prey ,01 natural sciences ,nitrogen ,food-web ,Soil ,agriculture biologique ,cycle biologique ,herbicide ,minéralisation de l'azote ,fertilisation organique ,fertilisation minérale ,Wageningen Environmental Research ,Laboratory of Entomology ,ComputingMilieux_MISCELLANEOUS ,2. Zero hunger ,chemistry.chemical_classification ,Intensive farming ,agriculture biodynamique ,agriculture conventionnelle ,food and beverages ,nutrient cycling ,04 agricultural and veterinary sciences ,sustainability ,PE&RC ,long terme ,6. Clean water ,mycorrhizal fungi ,[ SDE.MCG ] Environmental Sciences/Global Changes ,ennemi naturel ,microbial community structure ,ecosystem functioning ,[SDE]Environmental Sciences ,Organic farming ,DOK trial ,farming system ,fertilization ,microbial community ,soil fauna ,soil quality ,agricultural systems ,management ,Nutrient cycle ,agroecosystems ,[SDE.MCG]Environmental Sciences/Global Changes ,Soil biology ,Soil Science ,Microbiology ,Soil quality ,suisse ,productivité ,culture céréaliere ,Alterra - Centrum Bodem ,Organic matter ,triticum aestivum ,biomasse microbienne ,Laboratorium voor Nematologie ,biomass ,Soil Science Centre ,Soil carbon ,15. Life on land ,Laboratorium voor Entomologie ,Manure ,qualité biologique du sol ,Agronomy ,chemistry ,13. Climate action ,Biodiversity and ecosystem services ,040103 agronomy & agriculture ,0401 agriculture, forestry, and fisheries ,Environmental science ,Laboratory of Nematology ,Cereals, pulses and oilseeds ,010606 plant biology & botany - Abstract
International audience; Organic farming may contribute substantially to future agricultural production worldwide by improving soil quality and pest control, thereby reducing environmental impacts of conventional farming. We investigated in a comprehensive way soil chemical, as well as below and aboveground biological parameters of two organic and two conventional wheat farming systems that primarily differed in fertilization and weed management strategies. Contrast analyses identified management related differences between “herbicide-free” bioorganic (BIOORG) and biodynamic (BIODYN) systems and conventional systems with (CONFYM) or without manure (CONMIN) and herbicide application within a long-term agricultural experiment (DOK trial, Switzerland). Soil carbon content was significantly higher in systems receiving farmyard manure and concomitantly microbial biomass (fungi and bacteria) was increased. Microbial activity parameters, such as microbial basal respiration and nitrogen mineralization, showed an opposite pattern, suggesting that soil carbon in the conventional system (CONFYM) was more easily accessible to microorganisms than in organic systems. Bacterivorous nematodes and earthworms were most abundant in systems that received farmyard manure, which is in line with the responses of their potential food sources (microbes and organic matter). Mineral fertilizer application detrimentally affected enchytraeids and Diptera larvae, whereas aphids benefited. Spider abundance was favoured by organic management, most likely a response to increased prey availability from the belowground subsystem or increased weed coverage. In contrast to most soil-based, bottom-up controlled interactions, the twofold higher abundance of this generalist predator group in organic systems likely contributed to the significantly lower abundance of aboveground herbivore pests (aphids) in these systems. Long-term organic farming and the application of farmyard manure promoted soil quality, microbial biomass and fostered natural enemies and ecosystem engineers, suggesting enhanced nutrient cycling and pest control. Mineral fertilizers and herbicide application, in contrast, affected the potential for top-down control of aboveground pests negatively and reduced the organic carbon levels. Our study indicates that the use of synthetic fertilizers and herbicide application changes interactions within and between below and aboveground components, ultimately promoting negative environmental impacts of agriculture by reducing internal biological cycles and pest control. On the contrary, organic farming fosters microbial and faunal decomposers and this propagates into the aboveground system via generalist predators thereby increasing conservation biological control. However, grain and straw yields were 23% higher in systems receiving mineral fertilizers and herbicides reflecting the trade-off between productivity and environmental responsibility.
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- 2008
45. Reciprocal interactions between the cabbage root fly (Deliaradicum) and two glucosinolate phenotypes ofBarbareavulgaris
- Author
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van Nm Dam, CE Raaijmakers, van H Hanneke Leur, and Multitrophic Interactions (MTI)
- Subjects
biology ,fungi ,food and beverages ,Brassicaceae ,biology.organism_classification ,medicine.disease_cause ,Gluconasturtiin ,chemistry.chemical_compound ,chemistry ,Insect Science ,Glucosinolate ,Shoot ,Infestation ,Anthomyiidae ,Botany ,medicine ,Ecology, Evolution, Behavior and Systematics ,Delia radicum ,Barbarea vulgaris - Abstract
The cabbage root fly, Delia radicum L. (Diptera: Anthomyiidae), has a life cycle with spatially separated components: adults live and oviposit above ground, whereas larvae feed and pupate below ground. Oviposition choice is affected by shoot glucosinolates. However, little is known about below-ground plant defence against D. radicum. Here, we investigate the effect of glucosinolates on oviposition preference and performance of D. radicum, using two naturally occurring heritable chemotypes of Barbarea vulgaris R. Br. (Brassicaceae) with different glucosinolate profiles: BAR-type plants (the most common and genetically dominant glucosinolate profile, dominated by glucobarbarin) and NAS-type plants (the recessive phenotype, dominated by gluconasturtiin). Performance was studied by applying 10 neonate D. radicum larvae per plant and measuring pupal biomass after 18 days. There was no difference in retrieval, but pupae had a higher biomass after development on BAR-type plants. On average, BAR-type plants received 1.8 times more eggs than NAS types, but this difference was not statistically significant. In a separate experiment, we compared the physiological response of both chemotypes to D. radicum feeding. Infestation reduced root and shoot biomass, root sugar and amino acid levels, and shoot sugar levels. Except for shoot sugar levels, these responses did not differ between the two chemotypes. Shoot or root glucosinolate profiles did not change on infestation. As glucosinolate profiles were the only consistent difference between the chemotypes, it is likely that this difference caused the reduced biomass of D. radicum pupae on NAS-type plants. In an experimental garden, plants were heavily infested by root flies, but we found no differences in the percentage of fallen-over flower stalks between the chemotypes. Overall, we found more pupae in the soil near BAR-type plants, but this was not statistically significant. The results of the performance experiment suggest that BAR-type plants may be more suitable hosts than NAS-type plants.
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- 2008
46. Oviposition Cues for a Specialist Butterfly–Plant Chemistry and Size
- Author
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Jeffrey A. Harvey, S. van Nouhuys, Arjen Biere, J. H. Reudler Talsma, and Multitrophic Interactions (MTI)
- Subjects
0106 biological sciences ,Iridoid Glycosides ,Iridoid ,medicine.drug_class ,Oviposition ,media_common.quotation_subject ,Plant size ,Insect ,Biology ,Generalist and specialist species ,Melitaea cinxia ,010603 evolutionary biology ,01 natural sciences ,Biochemistry ,Article ,Sexual Behavior, Animal ,chemistry.chemical_compound ,Plantago lanceolata ,Botany ,medicine ,Animals ,Iridoids ,Glycosides ,Plantago ,Ecology, Evolution, Behavior and Systematics ,Aucubin ,media_common ,Herbivore ,Iridoid glycosides ,Feeding Behavior ,General Medicine ,Catalpol ,010602 entomology ,chemistry ,Butterfly ,Female ,Butterflies - Abstract
The oviposition choice of an insect herbivore is based on a complex set of stimuli and responses. In this study, we examined the effect of plant secondary chemistry (the iridoid glycosides aucubin and catalpol) and aspects of size of the plant Plantago lanceolata, on the oviposition behavior of the specialist butterfly Melitaea cinxia. Iridoid glycosides are known to deter feeding or decrease the growth rate of generalist insect herbivores, but can act as oviposition cues and feeding stimulants for specialized herbivores. In a previous observational study of M. cinxia in the field, oviposition was associated with high levels of aucubin. However, this association could have been the cause (butterfly choice) or consequence (plant induction) of oviposition. We conducted a set of dual- and multiple-choice experiments in cages and in the field. In the cages, we found a positive association between the pre-oviposition level of aucubin and the number of ovipositions. The association reflects the butterfly oviposition selection rather than plant induction that follows oviposition. Our results also suggest a threshold concentration below which females do not distinguish between levels of iridoid glycosides. In the field, the size of the plant appeared to be a more important stimulus than iridoid glycoside content, with bigger plants receiving more oviposition than smaller plants, regardless of their secondary chemistry. Our results illustrate that the rank of a cue used for oviposition may be dependent on environmental context.
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- 2008
47. Performance of specialist and generalist herbivores feeding on cabbage cultivars is not explained by glucosinolate profiles
- Author
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Joop J. A. van Loon, Nicole M. van Dam, Ron J. F. H. Galiart, Erik H. Poelman, Ciska E. Raaijmakers, and Multitrophic Interactions (MTI)
- Subjects
pieris-rapae ,0106 biological sciences ,oilseed rape ,Brassica ,Pieris rapae ,mustard ,Generalist and specialist species ,010603 evolutionary biology ,01 natural sciences ,resistance ,chemistry.chemical_compound ,Botany ,Laboratory of Entomology ,diamondback moth ,Ecology, Evolution, Behavior and Systematics ,Herbivore ,Diamondback moth ,biology ,plutella-xylostella ,wild populations ,Laboratorium voor Entomologie ,biology.organism_classification ,phytophagous insects ,chemistry ,rape brassica-napus ,Insect Science ,Glucosinolate ,responses ,Brassica oleracea ,010606 plant biology & botany ,Pieridae - Abstract
Plants display a wide range of chemical defences that may differ in effectiveness against generalist and specialist insect herbivores. Host plant-specific secondary chemicals such as glucosinolates (GS) in Brassicaceae typically reduce the performance of generalist herbivores, whereas specialists have adaptations to detoxify these compounds. The concentration of glucosinolates may also alter upon herbivory, allowing the plant to tailor its response to specifically affect the performance of the attacking herbivore. We studied the performance of three Lepidoptera species, two specialists [ Pieris rapae L. (Pieridae), Plutella xylostella L. (Yponomeutidae)] and one generalist [ Mamestra brassicae L. (Noctuidae)], when feeding on eight cultivars of Brassica oleracea L. and a native congener ( Brassica nigra L.) and related this to the GS content. We tested the hypotheses (i) that a generalist herbivore is more affected by high GS concentrations, and (ii) that generalist feeding has a stronger effect on GS levels. Although performance of the three herbivores was different on the B. oleracea cultivars, M. brassicae and P. xylostella had a similar ranking order of performance on the eight cultivars. In most of the cultivars, the concentration of indole GS was significantly higher after feeding by P. rapae or M. brassicae than after P. xylostella feeding. As a consequence, the total concentration of GS in the cultivars showed a different ranking order for each herbivore species. The generalist M. brassicae performed equally well as the specialist P. xylostella on cultivars with high concentrations of GS. Our findings suggest that secondary metabolites other than GSs or differences in nutrient levels affect performance of the species studied.
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- 2008
48. Responses of root-feeding nematodes (Helicotylenchus spp.) to local and non-local populations of the host plant Ammophila arenaria
- Author
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Helena Freitas, Wim H. van der Putten, Catarina Schreck Reis, and Multitrophic Interactions (MTI)
- Subjects
0106 biological sciences ,grass ,Range (biology) ,Helicotylenchus pseudorobustus ,Population ,Soil Science ,degeneration ,l. link ,feedback ,01 natural sciences ,Abundance (ecology) ,Marram grass ,Plant-nematode interactions ,vegetation ,Helicotylenchus n. sp ,14. Life underwater ,Helicotylenchus ,education ,Laboratorium voor Nematologie ,Ammophila arenaria ,Abiotic component ,education.field_of_study ,Ecology ,biology ,Host (biology) ,dunes ,food and beverages ,04 agricultural and veterinary sciences ,soil organisms ,biology.organism_classification ,PE&RC ,Agricultural and Biological Sciences (miscellaneous) ,communities ,mycorrhizal fungi ,Nematode ,Host specificity ,Coastal sand dunes ,040103 agronomy & agriculture ,0401 agriculture, forestry, and fisheries ,parasitic nematodes ,Laboratory of Nematology ,010606 plant biology & botany - Abstract
The root-feeding nematode community of wild plants may vary throughout their natural range. Little is known about how the variation of wild plants along their range affects their relationship with root-feeding nematodes. In the present study, we examined local and non-local combinations of host plants and root-feeding nematodes to test the hypothesis that nematode reproduction is favoured by local hosts. In two indoor experiments, we exposed populations of the wild dune grass Ammophila arenaria from northern and southern European coastal sand dunes to plant parasitic nematode species (Helicotylenchus spp.) from those same geographical origins. First, we used the southern nematode species to determine whether the effect of a local versus a non-local host may depend on nematode density. Then, in a cross-inoculation experiment we investigated how both nematode species performed with their local, as compared to the non-local hosts. In both experiments, plant biomass and ontogenetic characteristics were not significantly different between the northern and southern populations. The applied nematode densities did not have a negative impact on plant performance. This allowed us to consider the response of the two different nematode species and their host plants without co-varying differences in plant responses. Reproduction of the nematode species differed according to host origin, but contrary to what we expected, nematode species did not perform better on their local hosts. Helicotylenchus n. sp., the southern species originating from Portugal, performed better on the non-local than on the local host. Male to female ratios were significantly different between the two nematode populations and were lowest in Helicotylenchus pseudorobustus from The Netherlands. Female and juveniles percentages were also quite distinct, with more females in the nematode species from The Netherlands and more juveniles in the nematode species from Portugal. We concluded that ectoparasitic root-feeding nematodes Helicotylenchus spp. do not necessarily perform best on their local host population of the foredune grass A. arenaria. Our results imply that the natural distribution of Helicotylenchus spp. along the European coast is determined by other factors than host populations. These other factors that could be abiotic, e.g. water availability, or biotic, e.g. local natural enemies adapted to Helicotylenchus spp. Introducing plant genotypes from other parts of the natural range will, therefore, not necessarily lead to reduced abundance of semi-endo or ectoparasitic root-feeding nematodes.
- Published
- 2008
49. Barbarea vulgaris Glucosinolate Phenotypes Differentially Affect Performance and Preference of Two Different Species of Lepidopteran Herbivores
- Author
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Hanneke van Leur, Nicole M. van Dam, Wim H. van der Putten, Louise E. M. Vet, and Multitrophic Interactions (MTI)
- Subjects
0106 biological sciences ,oviposition behavior ,pieris-rapae ,Oviposition ,Performance ,Pieris rapae ,host-plant selection ,Moths ,Generalist and specialist species ,01 natural sciences ,Biochemistry ,p-napi-oleracea ,Gluconasturtiin ,chemistry.chemical_compound ,Laboratory of Entomology ,Amino Acids ,brassicae lepidoptera ,Barbarea vulgaris ,2-phenylethyl glucosinolate ,2. Zero hunger ,Diamondback moth ,food and beverages ,feeding deterrent ,General Medicine ,plutella-xylostella ,PE&RC ,Phenotype ,Carbohydrate Metabolism ,Female ,Mamestra brassicae ,Butterflies ,Barbarea ,Glucosinolates ,arabidopsis-thaliana ,Biology ,Article ,Botany ,Animals ,Polymorphism ,diamondback moth ,Laboratorium voor Nematologie ,Ecology, Evolution, Behavior and Systematics ,Chemotype ,fungi ,Feeding Behavior ,Laboratorium voor Entomologie ,biology.organism_classification ,Co-evolution ,Plant Leaves ,010602 entomology ,chemistry ,Glucosinolate ,Laboratory of Nematology ,010606 plant biology & botany - Abstract
The composition of secondary metabolites and the nutritional value of a plant both determine herbivore preference and performance. The genetically determined glucosinolate pattern of Barbarea vulgaris can be dominated by either glucobarbarin (BAR-type) or by gluconasturtiin (NAS-type). Because of the structural differences, these glucosinolates may have different effects on herbivores. We compared the two Barbarea chemotypes with regards to the preference and performance of two lepidopteran herbivores, using Mamestra brassicae as a generalist and Pieris rapae as a specialist. The generalist and specialist herbivores did not prefer either chemotype for oviposition. However, larvae of the generalist M. brassicae preferred to feed and performed best on NAS-type plants. On NAS-type plants, 100% of the M. brassicae larvae survived while growing exponentially, whereas on BAR-type plants, M. brassicae larvae showed little growth and a mortality of 37.5%. In contrast to M. brassicae, the larval preference and performance of the specialist P. rapae was unaffected by plant chemotype. Total levels of glucosinolates, water soluble sugars, and amino acids of B. vulgaris could not explain the poor preference and performance of M. brassicae on BAR-type plants. Our results suggest that difference in glucosinolate chemical structure is responsible for the differential effects of the B. vulgaris chemotypes on the generalist herbivore. Electronic supplementary material The online version of this article (doi:10.1007/s10886-007-9424-9) contains supplementary material, which is available to authorized users.
- Published
- 2008
50. The effect of direct and indirect defenses in two wild brassicaceous plant species on a specialist herbivore and its gregarious endoparasitoid
- Author
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Leontien M. A. Witjes, Marcel Dicke, Maarten A. Posthumus, Rieta Gols, Jeffrey A. Harvey, Joop J. A. van Loon, and Multitrophic Interactions (MTI)
- Subjects
pieris-rapae ,parasitoid diaeretiella-rapae ,trophic level ,infochemicals ,domestication ,host-plant ,cotesia-rubecula ,Botany ,Plant defense against herbivory ,Sinapis arvensis ,Laboratory of Entomology ,generalist ,induction ,Ecology, Evolution, Behavior and Systematics ,VLAG ,Pieris brassicae ,Herbivore ,biology ,Host (biology) ,fungi ,Organic Chemistry ,food and beverages ,sequestration ,biology.organism_classification ,Cotesia glomerata ,PE&RC ,Laboratorium voor Entomologie ,Organische Chemie ,Insect Science ,Weed ,Braconidae - Abstract
Most studies on plant defenses against insect herbivores investigate direct and indirect plant defenses independently. However, these defenses are not necessarily mutually exclusive. Plant metabolites can be transmitted through the food chain and can also affect the herbivore’s natural enemies. A conflict may arise when a natural enemy is attracted to a plant that is suboptimal in terms of its own fitness. In addition, plant defenses are often studied in cultivated plant species in which artificial selection may have resulted in reduced resistance against insect herbivores. In this study, we investigated both direct and indirect plant defenses in two closely related wild brassicaceous plant species, Brassica nigra L. and Sinapis arvensis L. The herbivore Pieris brassicae L. (Lepidoptera: Pieridae), which is specialized on brassicaceous plant species, developed faster and attained higher pupal mass when reared on B. nigra than on S. arvensis . In contrast, Cotesia glomerata L. (Hymenoptera: Braconidae), which is a gregarious endoparasitoid of P. brassicae caterpillars, developed equally well on P. brassicae irrespective of the food plant on which its host had been reared. The feeding strategy of the parasitoid larvae, that is, selectively feeding on hemolymph and fat body, is likely to allow for a much wider host-size range without affecting the size or development time of the emerging parasitoids. In flight chamber experiments, C. glomerata , which had an oviposition experience in a host that fed on Brussels sprout, exhibited significant preference for host-damaged B. nigra over host-damaged S. arvensis plants. Headspace analysis revealed quantitative and qualitative differences in volatile emissions between the two plant species. This parasitoid species may use a range of cues associated with the host and the host’s food plant in order to recognize the different plant species on which the host can feed. These results show that there is no conflict between direct and indirect plant defenses for this plant‐host‐ parasitoid complex.
- Published
- 2008
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