Responses of a predatory bug to a mixture of herbivore-induced plant volatiles from multiple plant species

The attractiveness of herbivore-induced plant volatiles (HIPVs) from a specific plant species to natural enemies has been well established. However, under natural conditions and polycultural agriculture systems, the interactions among trophic levels are thought to be more complex. For instance, complex mixtures of volatiles emitted from diverse host plant species infested by polyphagous herbivores might affect responses of natural enemies. In this study, we investigated whether a mixture of HIPVs emitted from herbivore-damaged multiple host plant species affect responses of a predatory bug. Therefore, we report (1) olfactory responses of the predatory bug (Orius strigicollis) to volatiles emitted from cotton bollworm (Helicoverpa armigera) first instar larvae-damaged multiple plant species (tomato, French bean and sweet corn), (2) chemical analyses of volatiles emitted from the three plant species exposed to different treatments and (3) olfactory responses of the predators to a reconstituted HIPV blend from multiple plant species based on chemical analyses. O. strigicollis significantly preferred volatiles emanating from H. armigera-damaged multiple plant species to volatiles emanating from a single plant species. In all the three plant species, H. armigera-damaged seedlings emitted significantly a greater amount of volatiles as well as a larger number of volatile compounds than an undamaged or a mechanically injured seedling. The predators preferred the reconstituted HIPVs from multiple plant species to the reconstituted HIPVs from a single plant species. Thus, the mixture of HIPVs from multiple plant species enhanced the attractiveness to the predators.     

Biological activity and specificity of Miridae-induced plant volatiles

The ability of zoophytophagous predators to produce defensive plant responses due to their phytophagous behavior has been recently demonstrated. In the case of tomatoes, the mirids Nesidiocoris tenuis and Macrolophus pygmaeus are able to attract or repel pests and/or natural enemies in different ways. Nevertheless, the herbivore-induced plant volatiles (HIPVs) released by the phytophagy of both mirids, which are responsible for these behaviors, are unknown. In this work, the HIPVs produced by the plant feeding of N. tenuis and M. pygmaeus were characterized. In addition, the role of each HIPV in the repellence or attraction of two tomato pests, Bemisia tabaci and Tuta absoluta, and of the natural enemy Encarsia formosa was evaluated. Six green leaf volatiles (GLVs) plus methyl salicylate and octyl acetate clearly stood out as major differential peaks on the chromatogram in a directed analysis. The six GLV and methyl salicylate were repellent for B. tabaci and attractive to E. formosa, whereas they showed no effect on T. absoluta. Octyl acetate, which was significantly present only in the M. pygmaeus-punctured plants, was significantly attractive to T. absoluta, repellent to E. formosa and indifferent to B. tabaci. Unlike the remaining HIPVs, octyl acetate was emitted directly by M. pygmaeus and not by the plant. Our results showed that mirid herbivory could modulate the pest and natural plant enemy locations, since tomato plants release a blend of volatiles in response to this activity. These results could serve as a basis for future development of plant protection.     

Invasive insect herbivores as disrupters of chemically-mediated tritrophic interactions: effects of herbivore density and parasitoid learning

Invasive insect herbivores have the potential to interfere with native multitrophic interactions by affecting the chemical cues emitted by plants and disrupting the attraction of natural enemies mediated by herbivore-induced plant volatiles (HIPVs). In a previous study, we found that the presence of the exotic herbivore Spodoptera littoralis on Brassica rapa plants infested by the native herbivore Pieris brassicae makes these dually-infested plants unattractive to the main parasitoid of P. brassicae, the braconid wasp Cotesia glomerata. Here we show that this interference by S. littoralis is strongly dependent on the relative densities of the two herbivores. Parasitoids were only deterred by dually-infested plants when there were more S. littoralis larvae than P. brassicae larvae on a plant. Furthermore, the blend of HIPVs emitted by dually-infested plants differed the most from HIPVs emitted by Pieris-infested plants when S. littoralis density exceeded P. brassicae density. We further found that associative learning by the parasitoid affected its preferences: attraction to dually-infested plants increased after parasitoids were presented a P. brassicae caterpillar (rewarding experience) in presence of the odor of a dually-infested plant, but not when presented a S. littoralis caterpillar (non-rewarding experience). A non-rewarding experience prior to the bioassays resulted in a general decrease in parasitoid motivation to respond to plant odors. We conclude that herbivore density and associative learning may play an important role in the foraging behavior of natural enemies in communities, and such effects should not be overlooked when investigating the ecological impact of exotic species on native food webs.     

What signals do herbivore-induced plant volatiles provide conspecific herbivores?

Herbivore-induced plant volatiles (HIPVs) have been opined as ‘indirect or direct defenses’ of plants and are extensively studied. In contrast, HIPVs may also indicate that plant defenses have been overcome by herbivores infesting the plant; however, studies on this aspect have so far received little attention. Using the interaction of Capsicum annum (Bell pepper) with its pest Scirtothrips dorsalis (Chilli thrips) as a model system, we studied the role of HIPVs in this selected insect–plant interaction. Multiple-choice olfactometer assays with headspace volatiles collected from different growth stages of un-infested C. annum plants represented by pre-flowering (PF), flowering (FL) and fruiting stages (FR) proved FR volatiles to be highly attractive to S. dorsalis. Further, FR plants were infested with S. dorsalis adults and HIPVs released by infested plants were collected and subjected to multiple-choice olfactometer bioassays. Thrips were significantly attracted to HIPVs than to headspace volatiles of un-infested FR plants or thrips body odour. Coupled GC-EAG with S. dorsalis and HIPVs or FR plant volatile revealed specific compounds that elicited an EAG response. Individual EAG-active compounds were less attractive to thrips, however, synthetic blends of EAG-active compounds at the ratio similar to headspace samples were found to be highly attractive. However, when given a choice between synthetic blends of HIPVs and FR, thrips were significantly attracted to synthetic blend of HIPVs. Our study provides empirical data on signals HIPVs may provide to conspecific herbivores and suggests that the role of HIPVs, mostly generalized as defense, may vary based on the interaction and must be studied closely to understand their ecological functions.     

Olfactory response of four aphidophagous insects to aphid- and caterpillar-induced plant volatiles

Plants damaged by herbivores emit blends of volatile organic compounds (VOCs) that attract the herbivore’s natural enemies. Most work has focussed on systems involving one plant, one herbivore and one natural enemy, though, in nature, plants support multiple herbivores and multiple natural enemies of these herbivores. Our study aimed to understand how different aphid natural enemies respond to aphid-induced VOCs, and whether attraction of the natural enemies that responded to aphid-induced VOCs was altered by simultaneous damage by a chewing herbivore. We used a model system based on Brassica juncea (Brassicaceae), Myzus persicae (Hemiptera: Aphididae) and Plutella xylostella (Lepidoptera: Plutellidae). Ceraeochrysa cubana (Neuroptera: Chrysopidae) did not show preferences for any plant odour, while Cycloneda sanguinea (Coleoptera: Coccinellidae) responded to undamaged plants over air but not to aphid-damaged plants over undamaged plants. Therefore, no further tests were carried out with these two species. Chrysoperla externa (Neuroptera: Chrysopidae) preferred aphid-damaged plants, but not caterpillar-damaged plants, over undamaged plants, and preferred plants damaged by both herbivores over both undamaged plants and aphid-damaged plants. When tested for responses against undamaged plants, Aphidius colemani (Hymenoptera: Braconidae) preferred aphid-damaged plants but not plants damaged by caterpillars. Plants damaged by both herbivores attracted more parasitoids than undamaged plants, but not more than aphid-damaged plants. Thus, multiply damaged plants were equally attractive to A. colemani and more attractive to C. externa than aphid-damaged plants, while C. cubana and C. sanguinea did not respond to aphid-induced VOCs, highlighting how different natural enemies can have different responses to herbivore-damaged plants.     

Phloem-feeding herbivory on flowering melon plants enhances attraction of parasitoids by shifting floral to defensive volatiles

Emission of herbivore-induced plant volatiles (HIPVs) can differ according to the type of herbivory and the plant development stage, ultimately affecting recruitment of the natural enemy. Little is known about plant defenses induced at the flowering stage by phloem-feeding insects. We investigated the olfactory preference of Encarsia desantisi parasitoids and the chemical profile of flowering melon plants induced or not by the phloem-feeding of Bemisia tabaci whiteflies. In addition, we tested whether the parasitoids were attracted to synthetic defensive HIPVs, which mimicked whitefly-infested flowering melons. The parasitoids recognized volatiles from undamaged melons but preferred the scent of host-infested melons in olfactometry assays. Amounts of most individual volatiles did not differ between plant treatments; however, only whitefly-induced melons released methyl salicylate and tetradecane, compounds known to attract parasitoids. Interestingly, grouping volatiles by chemical classes revealed that whitefly-infested melon released larger amounts of monoterpenes and smaller amounts of benzenoids than undamaged melons, which might underlying the parasitoid attraction and indicate a possible trade-off between defensive and reproductive defenses at the melon flowering stage. Additionally, E. desantisi preferred the mix of synthetic and defensive HIPVs over hexane (control), opening a new avenue for further investigations in using olfactory lures for B. tabaci biological control. This study is the first report of induced defenses in melon plants and their mediation in a tritrophic interaction, as well as the first record of E. desantisi behavioral preference for HIPVs.     

Herbivore- and MeJA-induced volatile emissions from the redroot pigweed <Emphasis Type="Italic">Amaranthus retroflexus</Emphasis> Linnaeus: their roles in attracting <Emphasis Type="Italic">Microplitis mediator</Emphasis> (Haliday) parasitoids

The redroot pigweed Amaranthus retroflexus Linnaeus (Caryophyllales: Amaranthaceae), an annual weed, is a host plant of the cotton bollworm Helicoverpa armigera (Hübner) (Lepidoptera: Noctuidae). Microplitis mediator (Haliday) (Hymenoptera: Braconidae) is a parasitoid of H. armigera. Here, the electrophysiological and behavioral responses of M. mediator to induced redroot pigweed volatiles were investigated. Female parasitoids were significantly attracted to odors from plants induced by H. armigera damage, H. armigera continuous feeding, and 10 mM methyl jasmonate (MeJA) spray. The gas chromatography–mass spectrometry (GC–MS) results demonstrated that there were significant changes in volatiles from these three treatments in comparison with the control. When the constitutive compound 6-methyl-5-hepten-2-one was emitted in significant amounts from treated plants, it could elicit a medium electrophysiological response (0.2?≤?value?<?0.8) , a significant behavioral response of M. mediator females. β-Elemene, emitted from two treatments (plants damaged by H. armigera, plants with H. armigera continuous feeding), showed a very weak electrophysiological response (value?<?0.2), but was significantly attractive to M. mediator. The results showed that 6-methyl-5-hepten-2-one and β-elemene might play important roles in mediating the foraging behavior of M. mediator. Further work will be conducted to evaluate the function of these two compounds under semi-field and field conditions and exploit them as attractants for M. mediator to control H. armigera.     

Experience of plant infestation by the omnivorous arthropod <Emphasis Type="Italic">Nesidiocoris tenuis</Emphasis> affects its subsequent responses to prey-infested plant volatiles

Nesidiocoris tenuis, an omnivorous arthropod, infests plants in either the absence or presence of prey arthropods. We studied whether plant-infestation experience of N. tenuis affected its subsequent prey-finding behavior. We used sesame plants and eggplants as food plants for N. tenuis, and common cutworm (CCW) (Spodoptera litura larvae) as prey. We focused on their olfactory response to CCW-infested sesame plants versus CCW-infested eggplants in a Y-tube olfactometer. When N. tenuis adults experienced the infestation of sesame plants for one day, they preferred volatiles from CCW-infested sesame plants to those from CCW-infested eggplants. By contrast, when N. tenuis experienced the infestation of eggplants for one day, they showed no difference in their preference between the two odor sources. When the duration of the infestation of plants was increased to four days, N. tenuis that had experienced sesame plants showed a reversed response: they preferred CCW-infested eggplant volatiles, while those that had infested eggplants again showed no difference in their preference. Next, we studied the olfactory preference of N. tenuis that had previously infested plants with moth (Ephestia kuehniella) eggs. We found that irrespective of plant species and of duration of experience (either one or four days), N. tenuis adults that had previously experienced one plant species showed a significant preference for volatiles from CCW-infested plants of the same species. The blends of the volatiles emitted from CCW-infested sesame plants and those from CCW-infested eggplants were qualitatively different. Possibility to control the olfactory response of N. tenuis to certain prey-infested plant volatiles by adjusting their feeding history is discussed.     

New evidence for a multi-functional role of herbivore-induced plant volatiles in defense against herbivores

A diverse, often species-specific, array of herbivore-induced plant volatiles (HIPVs) are commonly emitted from plants after herbivore attack. Although research in the last 3 decades indicates a multi-functional role of these HIPVs, the evolutionary rationale underpinning HIPV emissions remains an open question. Many studies have documented that HIPVs can attract natural enemies, and some studies indicate that neighboring plants may eavesdrop their undamaged neighbors and induce or prime their own defenses prior to herbivore attack. Both of these ecological roles for HIPVs are risky strategies for the emitting plant. In a recent paper, we reported that most branches within a blueberry bush share limited vascular connectivity, which restricts the systemic movement of internal signals. Blueberry branches circumvent this limitation by responding to HIPVs emitted from neighboring branches of the same plant: exposure to HIPVs increases levels of defensive signaling hormones, changes their defensive status, and makes undamaged branches more resistant to herbivores. Similar findings have been reported recently for sagebrush, poplar and lima beans, where intra-plant communication played a role in activating or priming defenses against herbivores. Thus, there is increasing evidence that intra-plant communication occurs in a wide range of taxonomically unrelated plant species. While the degree to which this phenomenon increases a plant’s fitness remains to be determined in most cases, we here argue that withinplant signaling provides more adaptive benefit for HIPV emissions than does between-plant signaling or attraction of predators. That is, the emission of HIPVs might have evolved primarily to protect undamaged parts of the plant against potential enemies, and neighboring plants and predators of herbivores later co-opted such HIPV signals for their own benefit.Key words: intra-plant signaling, plantplant communication, eavesdropping, systemic wound signals, plant defense, tri-trophic interactionsPlants often emit a unique blend of volatiles in response to herbivore attack. The emission of these herbivore-induced plant volatiles (HIPVs) is an active response to herbivore feeding, producing a blend of volatiles that is distinct from those emitted following mechanical injury alone.¹ Their emission can be variable; while some compounds follow a diurnal pattern with increasing amounts during the time of high photosynthesis,^2,3 others are emitted primarily at night.⁴ In some cases, the HIPV blend produced also differs depending on the species of herbivore feeding on the plant.⁵ This specificity is thought to be due to chemicals in the herbivore’s regurgitant, such as the fatty-acid amino-acid conjugate volicitin, that activate the emission of volatiles in plants.^6,7 Furthermore, HIPVs are emitted not only from the site of damage, but also at times from systemically undamaged parts of the plant.⁸ This and other systemic responses are, however, restricted within a plant such that only parts of the plant that share vascular connections with the damaged tissue receive wound signals and have the potential to respond.^9,10The ecological role of HIPVs has been a subject of fascination and the evolutionary advantage gained for plants by emitting HIPVs remains an unresolved topic of discussion. While some HIPV compounds, and some of their precursors, have sufficient volatility that their release is essentially inevitable after synthesis,¹¹ most tend to be tightly regulated. Assuming that HIPV emissions evolved as a result of trophic interactions among plants, herbivores, and natural enemies, there are four general ecological roles that HIPVs may play: (1) a direct negative effect on the herbivore, (2) a signal to alert natural enemies of the herbivore, (3) a warning signal to nearby undamaged plants, and (4) a systemic warning signal within the damaged plant (Fig. 1). The first two potential roles involve the manipulation of animal behavior, while the last two may alter plant “behavior”.Open in a separate windowFigure 1Herbivore-induced plant volatiles (HIPVs) play multiple roles in interactions among plants, herbivores, and natural enemies (possible interactions are depicted by arrows). Some of them benefit the HIPV-emitting plant (Emitter); these positive interactions include repellent effects on herbivores, attraction of natural enemies of herbivores, activation or priming of defenses in unwounded parts within the emitting plant (within-plant signaling), and growth inhibitory effects on neighboring plants (Receiver) through allelopathy. On the other hand, HIPVs may negatively affect the emitting plant by attracting herbivores or natural enemies (e.g., certain parasitoids) that result in increased damage. Finally, neighboring plants may “eavesdrop” from the emitting plant by responding to HIPVs (between-plant signaling). This latter interaction may be negative to the emitter if it is outcompeted by neighbors who receive wound signals, but beneficial to the receiving plant. Drawing by Robert Holdcraft.Scents can have a demonstrable effect on animal behavior. With respect to plant-herbivore interactions, scents can provide information about the status of a plant to herbivores and their natural enemies. For example, HIPVs may repel adults moths searching for oviposition sites,³ which has been interpreted from the perspective of either a plant minimizing damage or, perhaps more realistically, an adult moth searching for an undamaged, high quality resource for her offspring. Conversely, HIPV-emitting plants may increase their chance of being injured if herbivores are attracted to these volatiles.¹² The more commonly accepted role of HIPVs in manipulating animal behavior is to attract natural enemies of the herbivores. This tri-trophic “cry for help”¹³ has a potential evolutionary benefit for both the plant emitting the volatiles and the natural enemies responding to this emission.^14–16 Although this idea makes sense in an evolutionary perspective, only a few studies have documented the occurrence of this phenomenon in natural systems.¹⁷ Indeed, the effectiveness of a cry for help depends on the presence of a helper and, equally importantly, the ability of the helper to increase plant fitness. In the case of predator attraction, the herbivore may be removed from the plant and consumed, thereby reducing damage for the emitting plant.¹⁸ However, insect herbivores infected by parasitoids, which also use HIPV cues to locate hosts,¹⁹ may also consume less plant material²⁰ but may also in some cases consume more plant material than unparasitized insect herbivores.²¹ Since there is currently no evidence that plants can modify HIPV blends to attract selectively predators versus parasitoids, an answered cry for help may not reliably decrease the total amount of damage to an emitting plant. Thus, the fact that natural enemies respond to HIPVs does not imply that these volatiles evolved for this purpose or that there is an adaptive advantage for a plant to use HIPVs to attract natural enemies. Rather, natural enemies of insect herbivores may have learned to co-opt the HIPV signal emitted by plants and, by doing so, increased their fitness irrespective of the ultimate fitness outcome to the plant.Though more controversial, scents can also have an effect on plant behavior.²² Early work suggested that HIPVs from wounded willows,²³ poplars²⁴ and sugar maples²⁴ could trigger defense responses from other neighboring conspecifics. More recent studies have shown that this signaling can occur between different species of plants.²⁵ While these results are intriguing, they appear to have little adaptive function from the perspective of an emitting plant, which could be facilitating the fitness of potential resource competitors. Further, unless the individual within the same plant species shared some degree of kinship,²⁶ an emitting plant would also be at a disadvantage by providing an HIPV wound signal to a conspecific that, in theory, occupies the same competitive niche space. On the other hand, unwounded conspecific should benefit from being able to ‘eavesdrop’ by detecting HIPVs from wounded plants as they share the same herbivore complex and thus are vulnerable to attack. Moreover, from a heterospecific receiver’s perspective, the benefits of eavesdropping can be confounded by the potential of mounting defenses against a signal generated by incompatible herbivores feeding on a different plant species.²⁷ So, eavesdropping may be adaptive for a receiving plant if it realizes increased fitness relative to a conspecific that did not receive the signal. The emitting plant derives no apparent adaptive benefit of using HIPVs to warn neighboring plants. However, the emitting plant may benefit if their HIPVs have inhibitory allelopathic activity on neighboring plants.²⁸Our recent work¹ highlighted another scenario by which an HIPV-emitting plant would derive a direct benefit from the emissions: when HIPVs act as systemic wound signals within damaged plants. We showed that branches of blueberry shrubs lack effective vascular connections and thus cannot transmit wound signals among branches via the vasculature. To compensate, HIPVs can be transmitted among branches and, in so doing, overcome the vascular constraints of the branching life history strategy. Exposure to HIPVs increased levels of defensive signaling hormones in undamaged branches, changed their defensive chemical status, and made them more resistant to herbivores.¹ This idea that HIPVs may function in intra-plant communication to activate or prime defenses in other parts of the emitting plant against future attack was first suggested separately by Farmer²⁹ and Orians.⁹ The hypothesis was first tested with mechanically clipped wild sagebrush,³⁰ and it was further tested with insect herbivores of wild lima bean³¹ and hybrid poplar.³² Under this scenario, the emitting plant derives a direct benefit from the HIPVs, providing an unambiguous fitness advantage.So, what is the most beneficial factor to a plant for emitting volatiles in response to herbivore feeding? In terms of maximizing the potential benefit and minimizing the potential risk to the emitting plant, the function of HIPVs in mediating systemic wound signaling clearly provides the greatest potential adaptive advantage. Thus, we propose that the primary adaptive benefit for the evolution of HIPVs is to signal and protect unwounded parts of the attacked plant with high risk of infestation against herbivores. Later, these volatiles provided cues that led to adaptive fitness advantages for neighboring plants and natural enemies of herbivores, which may or may not benefit the HIPV-emitting plant. Indeed, ecologically adaptive advantages have emerged and contribute to a diverse, multi-functional chemical ecology mediated by HIPVs.     

Attraction of <Emphasis Type="Italic">Telenomus podisi</Emphasis> to volatiles induced by <Emphasis Type="Italic">Euschistus heros</Emphasis> in three different plant species

Specialized natural enemies that forage for polyphagous hosts need to locate hosts on different plants. Telenomus podisi (Hymenoptera: Platygastridae) is a stink bug egg parasitoid with a preference for Euschistus heros (Hemiptera, Pentatomidae), a polyphagous species. The aim of this study was to evaluate the induction of defences in three E. heros host plants: maize (Zea mays), sunflower (Helianthus annuus) and pigeon pea (Cajanus cajan). We hypothesized that E. heros damage to these three plants enhances the attraction of the parasitoid T. podisi as has been observed in other systems. Using Y-tube olfactometer bioassays, we tested parasitoid responses to combinations of the following odour sources: clean air, undamaged plants and plants damaged by stink bug feeding. Volatiles were collected by means of dynamic headspace collection and analysed by gas chromatography coupled to mass spectrometry. T. podisi did not distinguish odours from undamaged plants against air for any of the three plant species. For maize, the parasitoid preferred the odour from herbivore-damaged plants over both clean air and undamaged plants. For sunflower, the parasitoid only preferred the odour of herbivore-damaged plants over the odour of undamaged plants. For pigeon pea, no preferences were observed. Quantitative differences in the volatile profile of damaged and undamaged plants were observed in each plant species. We conclude that sunflower and maize plants, when damaged by E. heros, release volatiles that attract the parasitoid T. podisi; the parasitoid appears to use a different blend composition to distinguish herbivore-damaged plants of each species.     

Effect of vegetation cover on the abundance and diversity of ladybirds (Coccinellidae) assemblages in a peat bog

Predaceous ladybirds are important natural enemies of many insect pests in terrestrial ecosystems such as peatlands, which are habitats for specialized cold-adapted plants. Ladybird assemblages of pristine peat bogs have not yet been assessed. In total, 15 ladybird species were recorded in peat bog in Belarus by using entomological sweep net. The present study shows low diversity, evenness and species richness of ladybird assemblages. However, a small number of species were present in high numbers. These are Coccinella hieroglyphica, Chilocorus bipustulatus, Coccinulla qutuordecimpustulata and Hippodamia tredecimpunctata. Ladybird abundance was positively related to shrub cover and number of vascular plant species, and negatively related to herb cover. In terms of ladybird diversity, only shrub cover had a significant negative effect.     

Flowering banker plants for the delivery of multiple agroecosystem services

Ecosystem services provided by agricultural ecosystems include natural pest control and pollination, and these are important to ensure crop productivity. This study investigates the use of the banker plant Calendula officinalis L. to provide multiple ecosystem services by increasing the abundance of natural enemies for biological control of tomato pests, providing forage resources to wild bees, and improving crop yield. C. officinalis was selected for this experiment as it is used as a banker plant for Dicyphini (Hemiptera: Miridae) predators. Strips of flowering C. officinalis were established in the field edges of tomato fields and arthropod visitation to C. officinalis strips and tomato was measured. Crop damage from multiple pests of tomato was assessed in fields with C. officinalis strips and control sites. The contribution of pollination to crop yield was assessed through a pollinator exclusion experiment. The inclusion of C. officinalis in tomato fields was associated with increased abundance of Dicyphini, parasitoids, bees and other arthropod groups within these strips. A reduction in the total leaf crop damage from Lepidoptera pests was recorded in fields with C. officinalis strips. Increased fruit set and biomass were recorded in open-pollinated tomato but this was not significantly different between control and C. officinalis fields. Results presented here demonstrate that the inclusion of a companion plant can improve the conservation of beneficial arthropods and the delivery of agroecosystem services but efficacy is likely to be improved with the addition of plants, with different functional traits, and with improved attractiveness to crop pollinators.     

An omnivorous arthropod, <Emphasis Type="Italic">Nesidiocoris tenuis</Emphasis>, induces gender-specific plant volatiles to which conspecific males and females respond differently

Nesidiocoris tenuis Reuter (Heteroptera: Miridae) is an omnivorous mirid bug that preys on diverse generalist herbivorous arthropods. N. tenuis adults are attracted to volatiles from plants induced by their prey, such as tobacco cutworms (CCW) (Spodoptera litura larvae) and two-spotted spider mites (Tetranychus urticae). N. tenuis adults also induce volatiles when they infest plants. In this study, we focused on olfactory responses of N. tenuis males and females to volatiles from eggplants and sesame plants induced by conspecifics of the same or different gender by using a Y-tube olfactometer. Males were attracted to volatiles from plants of both species induced by either males or females. The male preference was biased to volatiles from plants of both species induced by females, probably because the biased response would facilitate their mate-finding. Females were attracted only to volatiles from plants of both species induced by females. Mating occurs multiple times in this species. Thus, the responses would indirectly affect mating of males and females. Slight but significant qualitative and quantitative differences were detected between the volatiles of plants of both species induced by N. tenuis females and those of the plants induced by conspecific males. N. tenuis might use such differences in their gender-specific responses.     

Behavioral responses of <Emphasis Type="Italic">Hyalesthes obsoletus</Emphasis> to host-plant volatiles cues

The polyphagous planthopper Hyalesthes obsoletus Signoret is considered to be the principal vector of stolbur phytoplasma, which is associated with yellow diseases of grapevine. To explore the possibility of developing novel control strategies, the behavioral responses to six synthetic mixtures and nine single compounds, previously identified from the headspace of Vitex agnus-castus L. (chaste tree) and Urtica dioica L. (nettle), were investigated in Y-tube bioassays. Choice tests revealed differences in the behavioral responses of males and females to the volatiles that they were exposed to. Males were attracted to a mixture containing (E)-β-caryophyllene, 1,8-cineole, (E,E)-α-farnesene, (E)-β-farnesene, and methyl salicylate (mixture 2). The addition of methyl benzoate to this five-compound mixture (mixture 3) did not attract males but elicited positive responses in females. Furthermore, females were attracted to a mixture containing (E)-β-caryophyllene, (E,E)-α-farnesene, (Z)-3-hexenyl acetate, (Z)-3-hexen-1-ol, and benzothiazole (mixture 4), but here addition of methyl salicylate (mixture 5) did not attract females. Neither males nor females showed attractivity or repellency toward the singly tested compounds. This study enhances knowledge on the interaction of insect behaviorally effective constituents in complex plant volatile mixtures. The attractive mixtures of plant volatiles identified suggest the possibility of using them in monitoring and management of H. obsoletus.     

Ants visiting extrafloral nectaries and pyrrolizidine alkaloids may shape how a specialist herbivore feeds on its host plants

The presence of extrafloral nectaries (EFNs) attracts predators and parasitoids, and protects the plant against herbivorous insects. By improving plant defences, EFNs reduce the fitness of herbivores. The use of similar host plants with no EFNs or adaptations in response to predators and parasitoids may enhance herbivore fitness. In this context, we studied the feeding habit (on leaves or on unripe seeds inside the pods) of larvae of the specialist moth Utetheisa ornatrix in two Crotalaria host plant species in which EFNs are present (C. micans) or absent (C. paulina). We hypothesized that the moths’ feeding habit was influenced by its natural enemies via their presence on EFNs. In C. micans, we found more larvae feeding inside the pods rather than on the leaves, while in C. paulina, larvae were found in both parts of the plant. There was greater activity of natural enemies in C. micans than in C. paulina. The moth sequesters enough pyrrolizidine alkaloid (PAs) to defend against predators in the leaves and seeds of C. paulina, but only in seeds of C. micans. Therefore, a change in the feeding habit in U. ornatrix larvae is a plastic response that depends on whether EFNs are present or not, or whether PA concentrations are low or high. This change does not affect overall moth performance. However, other factors, such as pod hardness, predation by organisms other than those visiting EFNs or even parasitoids cannot be ruled out as being responsible for the change in feeding habit. To date, both the EFNs and PAs in Crotalaria species are a parsimonious explanation of how larvae of U. ornatrix use different species of Crotalaria for feeding.     

A functional response evaluation of pre-infestation with <Emphasis Type="Italic">Bemisia tabaci</Emphasis> cryptic species MEAM1 on predation by <Emphasis Type="Italic">Propylea japonica</Emphasis> of <Emphasis Type="Italic">Myzus persicae</Emphasis> on host plant tomatoes

Herbivore feeding on host plants may induce defense responses of the plant which influence other herbivores and interacting species in the vicinity, such as natural enemies. The present work evaluated the impact of pre-infestation with the tobacco whitefly Bemisia tabaci cryptic species MEAM 1, on the predation ability of the ladybird Propylea japonica, to the green peach aphid Myzus persicae, on tomato plants. The results show that B. tabaci pre-infestation density, duration, and leaf position, can impact prey consumed by P. japonica under various aphid densities. The aphids consumed by P. japonica in each treatment were fit using the Holling type II functional response equation. The predatory efficiency (a/T _h) of P. japonica was the highest in the treatment with 60 aphids and 48-h infestation directly on damaged leaves. The predatory efficiencies of P. japonica decreased with a reduction of pre-infestation density and duration. We also observed that pre-infestation on young and undamaged leaves increased predation by P. japonica.     

Vetch aphid, <Emphasis Type="Italic">Megoura crassicauda</Emphasis> (Hemiptera: Aphididae), parasitism does not reduce the bean production of narrow-leaved vetch, <Emphasis Type="Italic">Vicia sativa</Emphasis> subsp. <Emphasis Type="Italic">nigra</Emphasis> (Fabaceae)

Megoura crassicauda Mordvilko (Hemiptera: Aphididae) is a dominant aphid species found on Vicia sativa subsp. nigra (L.) Ehrh. (Fabaceae) in the spring. Worker ants of Formica japonica, the dominant ant species attracted to the extrafloral nectaries of V. s. nigra, often attack ladybirds (Coccinella septempunctata), which are aphid enemies. However, the workers of F. japonica do not attack or exclude M. crassicauda, the non-myrmecophilous aphid. It appears that the “bodyguard” retained by the plant guards the plant’s herbivore by attacking the herbivores’ enemies, rather than guarding the plant itself. The relationship between V. s. nigra and M. crassicauda was observed in the field to examine and evaluate the cost of parasitism. Parasitism by M. crassicauda delayed flower bud formation markedly in V. s. nigra but did not kill the plants. V. s. nigra plants that were parasitized showed a net bean production similar to that of the non-parasitized controls. The parasitism rate of M. crassicauda increased when extrafloral nectaries were used by F. japonica. These results may indicate that M. crassicauda provides V. s. nigra with benefits by preventing other serious disadvantages.     

Spatio-temporal variation of strawberry aphid populations and their parasitoids

Aphids are common herbivores in the strawberry crop that can reduce plant vigor and fruit quality and also transmit viruses. Aphid species prefer diverse plant organs, which represent particular habitats of different quality for aphids and for the development of natural enemies’ populations. Different habitat units (young leaves, mature leaves, buds, flowers) of strawberry were sampled fortnightly during all seasons. We identified seven aphid species, namely Chaetosiphon fragaefolii, Aphis gossypii, and Macrosiphum euphorbiae, the most abundant. During the autumn, C. fragaefolli and M. euphorbiae were scarce and A. gossypii was denser on mature leaves, while during summer M. euphorbiae was absent. During the winter, C. fragaefolii predominated on buds and young leaves, A. gossypii on flowers, and both species on mature leaves. During the spring, C. fragaefolii was even more abundant on buds, A. gossypii predominated on mature leaves, and the three species were equally abundant on flowers and young leaves. Parasitoids emerged from A. gossypii, M. euphorbiae and Myzus persicae, but not from C. fragaefolii. Three Aphidius and two Aphelinus species were recovered. All primary parasitoid species emerged from A. gossypii, and secondary parasitoids emerged only from this aphid. Aphis gossypii parasitism on mature leaves was markedly higher in winter and summer than in autumn and spring. Parasitism of A. gossypii was independent of its density, and the number of parasitized aphids was never higher than six. Our results contribute to define the most appropriate sample unit to estimate aphid density of different species and provide information about seasonal natural parasitism.     

Application of methyl jasmonate to grey willow (<Emphasis Type="Italic">Salix cinerea</Emphasis>) attracts insectivorous birds in nature

It has been suggested that insectivorous birds may be guided by herbivore-induced plant volatiles (HIPVs) to herbivore-rich trees with herbivorous damage. The HIPV production in plants is partly mediated by jasmonic acid signalling pathway. Methyl jasmonate (MeJA) was proved to be a suitable agent for induction of HIPVs similar to those induced by herbivorous insects in many plant species. We studied the effects of methyl jasmonate on volatile emission and natural enemy attraction using mature grey willow (Salix cinerea) under natural conditions in Czech Republic. We treated 12 experimental shrubs with 30 mM MeJA and completed the experiment with 12 control shrubs. We monitored attacks by natural predators with artificial plasticine caterpillars which were checked daily. Birds most often pecked the caterpillars exposed on MeJA-treated shrubs and this attractiveness differed significantly from control. Attractiveness of MeJA-treated shrubs did not differ significantly from control shrubs for arthropod predators. Spraying MeJA on grey willows resulted in significantly higher production of α-pinene, β-pinene, 3-carene, limonene and β-ocimene. There was a marginally significant positive correlation between the predation rate by birds and relative change in α-pinene emissions.