Showing papers in "Arthropod-plant Interactions in 2011"

Condition-dependent tolerance of monoterpenes in an insect herbivore

Abstract: The ability of a herbivore to tolerate plant defensive chemicals may vary with the herbivore’s energetic state. We investigated the effect of body condition on the survivorship of individual mountain pine beetles, Dendroctonus ponderosae, exposed to host monoterpenes at concentrations comparable to constitutive and induced levels of defence using fumigant exposure. Body condition index was calculated as the residual mass after fitting the relationship between fresh weight and body size. Differences in survivorship among the four monoterpenes tested (α-pinene, myrcene, terpinolene and limonene) were small. Beetles with a higher body condition index survived high monoterpene concentrations better than those in poorer condition. There was no direct effect of sex, but positive effects of body size and fat content on survivorship favoured females, the sex that pioneers attacks on live trees. Higher body condition index corresponded to both higher fat content and fat-free body mass; the same conclusions about monoterpene identity and size-dependent or energy-dependent tolerance of high monoterpene concentrations held if fat or fat-free body mass were used in place of body condition index. This study highlights the need to consider insect body condition in understanding insect–plant interactions.

A quantitative evaluation of major plant defense hypotheses, nature versus nurture, and chemistry versus ants

Abstract: Variation in plant secondary metabolite content can arise due to environmental and genetic variables. Because these metabolites are important in modifying a plant’s interaction with the environment, many studies have examined patterns of variation in plant secondary metabolites. Investigations of chemical defenses are often linked to questions about the efficacies of plant defenses and hypotheses on their evolution in different plant guilds. We performed a series of meta-analyses to examine the importance of environmental and genetic sources of variation in secondary metabolites as well as the antiherbivore properties of different classes of defense. We found both environmental and genetic variation affect secondary metabolite production, supporting continued study of the carbon-nutrient balance and growth-differentiation balance hypotheses. Defenses in woody plants are more affected by genetic variation, and herbaceous plant defenses are more influenced by environmental variation. Plant defenses in agricultural and natural systems show similar responses to manipulations, as do plants in laboratory, greenhouse, or field studies. What does such variation mean to herbivores? A comparison of biotic, physical, and chemical defenses revealed the most effective defensive strategy for a plant is biotic mutualisms with ants. Fast-growing plants are most often defended with qualitative defenses and slow-growing plants with quantitative defenses, as the plant apparency and resource availability hypotheses predict. However, we found the resource availability hypothesis provides the best explanation for the evolution of plant defenses, but the fact that there is considerable genetic and environmental variation in defenses indicates herbivores can affect plant chemistry in ecological and evolutionary time.

Feeding by a gall-inducing caterpillar species alters levels of indole-3-acetic and abscisic acid in Solidago altissima (Asteraceae) stems

Abstract: Various plant antagonists appear to alter phytohormone levels for their own benefit. Among insects, gall-inducing species appear to influence phytohormones and it is widely believed that they alter levels of indole-3-acetic acid (IAA) to help produce their galls, but evidence exists for only a limited number of species. To further explore the role of phytohormones in gall formation, we measured levels of IAA and abscisic acid (ABA), a hormone involved in plant defenses and that can influence IAA, in tissues of control stems of Solidagoaltissima (Asteraceae) and those galled by Gnorimoschema gallaesolidaginis (Gelechiidae). This gall-inducing caterpillar species significantly altered the distribution of IAA in galls and the larvae themselves contained high concentrations of IAA. In contrast, the generalist caterpillar Heliothis virescens (Noctuidae) neither altered IAA nor accumulated significant concentrations of IAA, suggesting that G. gallaesolidaginis may have a distinctive influence over IAA. The gall-inducing caterpillars, particularly younger larvae, also contained high levels of ABA but did not increase levels of ABA, which is induced by herbivory of H. virescens. Because G. gallaesolidaginis also does not increase levels of other defense-related hormones, avoiding generalized plant defenses may facilitate gall induction and formation.

Induced mutations affecting pollinator choice in Mimulus lewisii (Phrymaceae)

Abstract: The flowering plants are one of the most phenotypically varied and wide-ranging groups of organisms on earth, and yet, we have limited understanding of the contribution of animal pollinators to the diversification of floral form. To explore the interaction between variation in floral form and pollinator behavior, we observed the foraging behavior of bumblebees (Bombus impatiens) when presented with both wild-type Mimulus lewisii plants and each of three chemically induced single-locus mutants with altered floral phenotypes, including loss of the three lower petals, loss of nectar guides, and a change in petal color patterning. We found that each of the mutants attracted successful pollinator visits at just 29–80% of the rate relative to wild-type flowers, suggesting that effective recruitment of bumblebee pollinators requires the landing platform provided by the lower petals, and visual cues provided by the nectar guides and petal color pattern. Since single-locus recessive mutations are capable of ablating the lower petals, nectar guides, and color pattern, such changes in floral form provide insight into the driving forces behind plant adaptation.

Aphid-host plant interactions: does aphid honeydew exactly reflect the host plant amino acid composition?

Abstract: Plants provide aphids with unbalanced and low concentrations of amino acids. Likely, intracellular symbionts improve the aphid nutrition by participating to the synthesis of essential amino acids. To compare the aphid amino acid uptakes from the host plant and the aphids amino acid excretion into the honeydew, host plant exudates (phloem + xylem) from infested and uninfested Vicia faba L. plants were compared to the honeydew produced by two aphid species (Acyrthosiphon pisum Harris and Megoura viciae Buckton) feeding on V. faba. Our results show that an aphid infestation modifies the amino acid composition of the infested broad bean plant since the global concentration of amino acids significantly increased in the host plant in response to aphid infestations. Specifically, the concentrations of the two amino acids glutamine and asparagine were strongly enhanced. The amino acid profiles from honeydews were similar for the two aphid species, but the concentrations found in the honeydews were generally lower than those measured in the exudates of infested plants (aphids uptakes). This work also highlights that aphids take large amounts of amino acids from the host plant, especially glutamine and asparagine, which are converted into glutamic and aspartic acids but also into other essential amino acids. The amino acid profiles differed between the host plant exudates and the aphid excretion product. Finally, this study highlights that the pea aphid, a “specialist” for the V. faba host plant, induced more important modifications into the host plant amino acid composition than the “generalist” aphid M. viciae.

Entomovectoring in plant protection

Abstract: This paper gives an overview on the unique concept of the entomovector technology to employ pollinating insects, including honey bees and bumble bees in the context of biological control of insect pests and diseases. After a brief introductory description, the multifaceted aspects of this intriguing technology are highlighted by describing the most significant results and achievements of research groups around the world concerning: (1) the importance of vector selection, as this determines the transport efficacy of biocontrol agents into the crop and is influenced by the vector–plant interactions, (2) the different potential biocontrol agents used so far, (3) the significance of the diluent and formulation for an increased vector loading and transport, (4) the different dispenser types developed over the past 20 years, and (5) the safety of this technology to the environment and humans. For all these interactions, we identify in a critical manner the limitations and the successes obtained so far. The needs for further research are also discussed to increase the potential of the entomovector technology in practical use.

Ovipositing Orius laevigatus increase tomato resistance against Frankliniella occidentalis feeding by inducing the wound response

Abstract: The anthocorid predator Orius laevigatus is widely used as biological control agent of thrips pests, including the western flower thrips Frankliniella occidentalis. In the current study, it was shown that O. laevigatus adults can increase plant resistance to feeding damage of F. occidentalis on tomato plants. The predator elicits a jasmonic acid (JA) mediated wound response during endophytic oviposition, resulting in reduced thrips feeding. A strong accumulation of H2O2, a molecule involved in different parts of the wound response, in leaf tissue surrounding the predator eggs or oviposition puncture sites was observed. Infestation of tomato plants with adult predators led to the upregulation of three JA regulated wound responsive genes: the precursor prosystemin, the jasmonic acid biosynthesis enzyme allene oxide synthase and the defence protein proteinase inhibitor I. Likewise, the presence of adults caused accumulation of proteinase inhibitor II, a principal marker for the wound response.

Physiological responses of resistant and susceptible reproductive stage soybean to soybean aphid (Aphis glycines Matsumura) feeding

Abstract: We examined the physiological responses of four soybean genotypes (KS4202, K-1639-2, ‘Jackson,’ ‘Asgrow 2703’) to soybean aphid (Aphis glycines Matsumura) feeding in reproductive stage soybeans (R1, beginning bloom). Photosynthetic capacity was evaluated by taking survey measurements at 7, 17, 24, and 28 days after aphid introduction and by measuring assimilation/internal CO2 (ACi) curves at 29 days after aphid introduction. There were no significant differences in survey measurements between the control and infested KS4202, K-1639-2, Jackson, and Asgrow 2703 plants at 7, 17, 24, and 28 days after aphid introduction. At 29 days after aphid introduction, Asgrow 2703 plants showed a significant reduction in photosynthetic capacity compared to its control plants, while infested KS4202 plants had photosynthetic rates similar to control plants, suggesting the plant’s ability to compensate for aphid feeding. Differences in gas-exchange parameters, specifically Jmax and CE, between control and infested Asgrow 2703 plants showed that soybean aphid feeding negatively impacts the carbon-linked/dark reactions, specifically rubisco activity and RuBP regeneration. This research also investigated the role of peroxidases in the defense response of soybeans to the soybean aphid. Enzyme kinetics studies documented the up-regulation of peroxidase activity for both Asgrow 2703 and KS4202 aphid-infested plants compared to their respective uninfested control plants at 24 and 28 days after aphid introduction. Peroxidase expression profiles identified differences in the isozyme profiles of aphid-infested and control plants for Asgrow 2703 and KS4202. Differences between physiological responses of infested KS4202 and Asgrow 2703, particularly temporal changes in photosynthesis activity, imply that KS4202 tolerates some impacts of soybean aphid feeding on photosynthetic integrity.

Relationship between plant development, tannin concentration and insects associated with Copaifera langsdorffii (Fabaceae)

Abstract: Plant development is the main factor that determines the insect-ontogeny interaction, since it leads to variations in resource quality and availability. The aim of this study was to test the hypothesis that plant development and varying tannin concentration leads to changes in species richness, abundance and composition of ants, free-feeding herbivores and galling insects associated with Copaifera langsdorffii (Fabaceae). The plant ontogeny and tannin concentration effects on insects were tested on 60 individuals with height varying from 0.9 to 11.0 m. A positive correlation was observed for tree height and species richness and abundance of ants, free-feeding and galling insects. In contrast, we did not find a significant relation between leaf tannin concentration and plant height, or richness and abundance of the different insect guilds. The assemblage of ants (composition of species) did not change between saplings and adults of C. langsdorffii. However, the assemblage of free-feeding herbivores and galling insects varied between the two development stages studied. The present study reveals an ontogenetic succession pattern for herbivore insects along the C. langsdorffii growth, probably due to both indirect and direct benefits from the host plant architecture and quality. Those plants with more complex architectures should support a wider diversity of insects, since they present higher number of sites for egg laying, housing, feeding and better environmental conditions. This is the first work to investigate the host plant ontogeny effect on insects in Cerrado “Savanna” vegetation. The pattern described, along with other previous studies, suggests a vast occurrence of ontogenetic succession in tropical areas.

Similar responses of insect herbivores to leaf fluctuating asymmetry

Abstract: Fluctuating asymmetry (FA) represents small, random variation from symmetry and it has been used as an indicator of plant quality and susceptibility to herbivory. In this study, the effects of FA on the responses of distinct herbivore species belonging to several guilds were examined along an environmental gradient in south Florida. This approach was chosen because it relies on a multi-species approach to the study of fluctuating asymmetry and patterns of herbivory between and within plants along an environmental gradient of salinity and plant stress. To examine differences in FA between and within plant communities, seven plant species were investigated. Four of these plants were coastal species and three species occurred in upland communities. Levels of FA were assessed before herbivory and plants were followed for the whole herbivory season in 2006. Coastal plants exhibited significantly higher salt concentration, higher percentage of asymmetric leaves and higher asymmetry levels than upland plants. Herbivore abundance varied widely amongst the seven species studied, but quantitative syntheses of our results indicated significant and positive responses of insect herbivores to leaf asymmetry: insects were 25.11% more abundant on more asymmetric plants and stronger effects of asymmetry were observed for leaf miners compared to gall-formers. As demonstrated by other recent studies, FA might be used as a reliable stress indicator, leading to similar responses of insect herbivores to variation in leaf symmetry.

Floral epidermal structure and flower orientation: Getting to grips with awkward flowers

Abstract: The petal epidermis has been found to be important in mediating flower-pollinator interactions. Structures produced on the petal surface, in particular cone-shaped papillate (or conical) cells, have been shown to enhance bumblebee preference for flowers. One reason for this increase in preference is that the conical cells facilitate efficient handling of flowers. This is particularly clear when flower architecture requires bees to land on a vertical surface. We therefore tested the hypothesis that flowers that are held vertically show a greater tendency to produce conical cells. Analysis of 183 species finds that there is no significant relationship between the structures on the petal surface and flower orientation. We discuss the multifunctional properties of conical cells and other floral surface structures that may mean that other factors are of equal or greater importance in the relationship between pollinators and petal epidermal form.

Differential responses of midgut soluble aminopeptidases of Helicoverpa armigera to feeding on various host and non-host plant diets

Abstract: Differential responses of midgut soluble aminopeptidases were studied in Helicoverpa armigera larvae fed on various host (chickpea and pigeon pea) and non-host (bitter gourd and chili) plant diets. Larval growth was significantly reduced by non-host plant diets. Although the serine proteinase activities were inhibited, aminopeptidase activities were significantly increased in the larvae fed on non-host plant diets. Results were qualitatively and quantitatively confirmed with in vivo and in vitro analyses. It was noted that aminopeptidases had given more preference to ApNA than LpNA on non-host plant diets and vice versa on host plant diets. However, optimum pH for aminopeptidase activity (around pH 7.0–8.0) and susceptibility to inhibitors was similar in the larvae fed on host as well as non-host plant diets. These results suggest that H. armigera regulates digestive enzyme levels to obtain better nourishment from the diet and avoid toxicity due to nutritional imbalance. A detailed biochemical and molecular analysis of gut aminopeptidases upon exposure of the insect to a particular diet will highlight their specific roles.

Foraging activity of bumblebees (Bombus terrestris L.) on Bt-expressing eggplants

Abstract: A greenhouse experiment was setup to study foraging behavior of the bumblebee Bombus terrestris L. on Cry3Bb-expressing genetically modified (GM) eggplants and their near-isogenic control. Commonly, more bumblebees visited GM eggplants compared to near-isogenic control, but this difference was only marginally significant. The mean length of feeding bouts was similar on the two treatments. Neither the number of flowers produced nor their size could explain bumblebees’ tendency to prefer GM eggplants. Volatile compounds were extracted from five plants per genotype and separated using gas chromatography. Thirteen compounds were identified and five of them appeared significantly more abundant in GM eggplants. Six of the identified compounds [(+)-limonene, Z-jasmone, p-cymene, α-pinene, methyl-salicilate, and (−)-limonene] were tested in electrophysiological bioassays with antennas detached from young bumblebees, and a response was recorded in all six cases. Experimental results indicate that pollination activity of bumblebees is compatible with this GM eggplant event as a food source and that chemical cues may have an important role in plant identification. The implications for environmental risk assessment of GM plants are discussed.

Background matching behaviour and pathogen acquisition: plant site preference does not predict the bacterial acquisition efficiency of vectors

Abstract: Many insect-borne pathogens are heterogeneously distributed within their hosts: therefore, a vector’s within-plant distribution may be a predictor of its exposure to pathogens. In this study, we set out to quantify plant site preference, in the context of background matching, and investigated its effect on acquisition of a bacterial pathogen by its leafhopper vectors. The two green-coloured species, Graphocephala atropunctata and Draeculacephala minerva, preferred green plant tissue and artificial backgrounds whereas the brown-coloured Homalodisca vitripennis preferred brown stem tissue and backgrounds. Within-plant feeding site did not predict either the acquisition success or the number of plant-pathogenic Xylella fastidiosa cells acquired by the vectors; an 86% mortality for G. atropunctata was reported on the lignified stem tissue. Overall, H. vitripennis acquired significantly more cells than G. atropunctata. A novel artificial diet-based transmission system was used to further illustrate that the observed between-species difference in the number of cells acquired was independent of vector-host plant interactions. H. vitripennis, a less efficient vector of the bacterium X. fastidiosa on grapevines, acquired more bacterial cells than G. atropunctata, possibly due to its larger size. Contrary to previous assumptions, pathogen acquisition efficiency by the vectors did not explain their reported differences in inoculation. Vector interactions with the host during the inoculation stage should be evaluated as another determinant of X. fastidiosa transmission efficiency.

Cardenolides from Gomphocarpus sinaicus and Pergularia tomentosa (Apocynaceae: Asclepiadoideae) deter the feeding of Spodoptera littoralis

Abstract: Methanol extracts of Gomphocarpus sinaicus, Pergularia tomentosa and Cynanchum acutum (Apocynaceae, sub-family Asclepiadoideae) deterred feeding of Spodoptera littoralis in a binary-choice bioassay. Analyses of extracts using high-performance liquid chromatography with photodiode array detection indicated that methanol extracts of P. tomentosa and G. sinaicus contained cardenolides, while these compounds were not detected in extracts of C. acutum. Activity-guided fractionation of the methanol extracts of G. sinaicus and P. tomentosa resulted in the isolation of six cardenolides: 7,8-dehydrocalotropin, calotropin and coroglaucigenin 3-(6-deoxy-β-allopyranoside)-19-acetate (frugoside 19-acetate) from G. sinaicus, and coroglaucigenin, 16α-acetoxycalotropin and calactin from P. tomentosa. The isolation of 16α-acetoxycalotropin was a new report from P. tomentosa. Each of the 6 cardenolides deterred feeding by S. littoralis, while two cardenolide standards, digoxin and digitoxin, did not affect feeding. Differences among cardenolides in their effect on feeding were associated with specific structural features. C. acutum is the only one of the three species tested that is known to support the development of S. littoralis, although the development of larvae was delayed. The observed feeding deterrent activity of the cardenolide-free methanol extract of C. acutum would suggest that compounds other than cardenolides are responsible for the deterrent activity. These compounds, although deterrent in a short-term feeding assay, might not prevent long term feeding, thus allowing the larvae to develop on the plant.

Oviposition pattern and within-season spatial and temporal variation of pre-dispersal seed predation in a population of Mimosa bimucronata trees

Abstract: Spatial and temporal variation of pre-dispersal seed predation was investigated in a population of Mimosa bimucronata trees located in the south-east region of Brazil. Three main hypotheses were addressed: (1) that the life stages of the seed predator Acanthoscelides schrankiae are synchronised with the reproductive stages of its host plant; (2) that seed predation levels vary spatially as a result of differences in fruiting phenology synchrony and fruit production among trees; and (3) that predation levels should be affected by the proximity of trees, showing a spatial structure. Also investigated was the oviposition pattern of A. schrankiae among seeds and fruits. Twenty spatially referenced trees were monitored throughout a year to examine tree phenology and egg laying and adult emergence. The bruchine’s life stages were synchronised with the reproductive stages of M. bimucronata trees. Egg distribution among seeds and fruits was aggregated. Infestation rates of adult bruchines were not spatially related to fruiting phenology and there is evidence that seed predation is a spatially density-independent process, because the relationship between infestation rates and fruit production was not significant. Finally, it was observed that the distribution of adult bruchines was spatially structured, because similar levels of infestation were found among nearby trees.

Genetically based population variation in aphid association with ants and predators

Abstract: A species’ genotype can have extended consequences for the structure of the surrounding community, but few studies have investigated the extended consequences of genetic variation in animals. Accordingly, I examined the importance of genetically based variation among five populations of the ant-tended aphid Aphis asclepiadis for its interactions with both ants and predators. In a common environment, aphid source population accounted for 23 and 17% of the variation in the occurrence of ants and predators, respectively. Ant exclusion increased predator abundance, accounting for 25% of variation, but there was no detectable influence of ants on aphid abundance. There was an indication that aphid source populations varied in honeydew quality, but this was uncorrelated with rates of ant attendance. This study provides the first evidence for genetic variation in aphids for attractiveness to ants, and underscores the important link between intra-specific genetic variation in aphids and the processes governing arthropod community structure.

Tri-trophic level interactions affect host plant development and abundance of insect herbivores

Abstract: Understanding the interactions among plants, hemipterans, and ants has provided numerous insights into a range of ecological and evolutionary processes. In these systems, however, studies concerning the isolated direct and indirect effects of aphid colonies on host plant and other herbivores remain rare at best. The aphid Uroleucon erigeronensis forms dense colonies on the apical shoots of the host plant Baccharis dracunculilfolia (Asteraceae). The honeydew produced by these aphids attracts several species of ants that might interfere with other herbivores. Four hypotheses were tested in this system: (1) ants tending aphids reduce the abundance of other herbivores; (2) the effects of ants and aphids upon herbivores differ between chewing and fluid-sucking herbivores; (3) aphids alone reduce the abundance of other herbivores; and (4), the aphid presence negatively affects B. dracunculifolia shoot growth. The hypotheses were evaluated with ant and aphid exclusion experiments, on isolated plant shoots, along six consecutive months. We adjusted linear mixed-effects models for longitudinal data (repeated measures), with nested spatial random effect. The results showed that: (1) herbivore abundance was lower on shoots with aphids than on shoots without aphids, and even lower on shoots with aphids and ants; (2) both chewing and fluid-sucking insects responded similarly to the treatment, and (3) aphid presence affected negatively B. dracunculifolia shoot growth. Thus, since aphids alone changed plant growth and the abundance of insect herbivores, we suggest that the ant–aphid association is important to the organization of the system B. dracunculifolia-herbivorous insects.

The effect of nitrogen additions on bracken fern and its insect herbivores at sites with high and low atmospheric pollution

Abstract: The impact of atmospheric pollution, including nitrogen deposition, on bracken fern herbivores has never been studied. Bracken fern is globally distributed and has a high potential to accumulate nitrogen in plant tissue. We examined the response of bracken fern and its herbivores to N fertilization at a high and low pollution site in forests downwind of Los Angeles, California. Foliage from the high pollution site had higher total N and nitrate than the low pollution site. Bracken fern biomass, foliar N and herbivore abundance were all affected by fertilization treatments. Biomass and herbivore responses were greatest during a year of high precipitation. N additions at the low pollution site were primarily associated with decreased fern biomass, and with transient impacts on herbivore abundance. N additions significantly affected bracken fern and its herbivores at the high pollution site where foliar N and nitrate decreased in response to N addition treatments, while biomass and herbivore abundance increased. High atmospheric deposition and fertilization were both associated with increased herbivore richness. Herbivore abundance was most impacted by fertilization during the early expansion of fern fronds. The most abundant chewing herbivore, a sawfly, was positively associated with plant nitrogen at the low pollution site, but negatively associated with plant nitrogen at the high pollution site, where concentrations of both total N and nitrate were high. While overall growth and herbivore impacts in this xeric location were limited, the variable response we observed associated with rainfall, may indicate impacts could be larger in more mesic environments.

Parasitoid attack of the seed-feeding beetle Bruchus loti enhances the germination success of Lathyrus japonicus seeds

Abstract: Hard seeds of some legume species can germinate after seed-feeding insects bore through the seed coat and consequently break seed dormancy. Larvae of bruchine beetles are the main seed feeders attacking many legume species. Boring of the hard seed coat by bruchine beetle larvae enhances the germination percentage of legume species, but consuming too much of a single seed may reduce the chances the seed will survive. We hypothesise that the early mortality of bruchine larvae due to parasitism contributes positively to seed germination because larvae are killed before consuming too large a quantity of the seed. Here, we tested this hypothesis using Lathyrus japonicus seeds and Bruchus loti, the main seed feeder attacking this plant. B. loti larvae were mainly parasitised by two species of idiobiont parasitoids—Pteromalus sp. and Dinarmus sp. The seeds from which Pteromalus wasps emerged germinated more successfully than did the seeds from which B. loti adults emerged. B. loti larvae parasitised by the two wasp species consumed the seeds less intensively than did unparasitised larvae. Thus, the results of experiments supported our hypothesis. However, the germination success varied significantly between the seeds from which Pteromalus and Dinarmus wasps emerged. The difference in the size of seeds the two wasp species chose for parasitism may have influenced the germination percentage.

Behavioral plasticity of a grass-feeding caterpillar in response to spiny- or smooth-edged leaf blades

Abstract: Ontogenetic changes in feeding behavior of armyworms, Pseudaletia unipucta (Haworth), were compared on tall fescue [Schedonorus arundinaceus (Schreb.) Dumort] cultivars with spiny-, intermediate-, or smooth-edged leaf blades to clarify whether the edge spines deter caterpillars, in which case release of modified, smooth-edged forage grasses for improved livestock performance might aggravate armyworm damage to pastures. Edge biting, success initiating edge-feeding, and propensity to window- or edge-feed were observed for individual 2nd, 3rd, or 4th instars on grass leaf blades with intact margins. Early second instars bit smooth and spiny leaf edges with equal frequency but were unable to initiate edge-feeding. They fed on leaf edges after margins were cut away, but not when leaf juice was applied to intact edges, indicating the leaf margin is a barrier. Third and 4th instars mostly edge-fed on smooth leaves, but on the grasses with spiny margins they compensated for the difficulty of edge-feeding by prolonging their window-feeding. There was no developmental cost to window-feeding by 3rd instars, but 4th instars suffered reduced weight gain on spiny grass apparently because, unlike earlier instars, their mandibles are too large and not well shaped for efficient window-feeding between the parallel vascular bundles. Armyworms display behavioral plasticity in feeding mode in response to spiny- versus smooth-edged grasses. Greater use of smooth-bladed pasture grasses may result in proportionately more edge-feeding by armyworms but is unlikely to result in markedly greater pasture losses because this grass-feeding specialist so effectively exploits conventional tall fescue despite its structural characteristics.

Resistance induction and herbivore virulence in the interaction between Myzus persicae (Sulzer) and a major aphid resistance gene (Rm2) from peach

Abstract: In gene-for-gene host–enemy interactions, monogenic plant resistance results from pathogen recognition that initiates the induction of plant defense responses. Schematically, as the result of the on/off process of recognition, phenotypic variability in enemy virulence is expected to be qualitative, with either a failure or a success of host colonization. We focussed on a major gene from peach conferring avoidance resistance against the green peach aphid Myzus persicae. Measurements of herbivore density and time-dependent aspects of resistance induction were examined, as well as variability in the aphid’s ability to exploit the resistant host. Varying densities of infestation did not provoke differences in the aphid’s tendency to leave a plant, and a single aphid was sufficient to elicit a response. Similarly, the duration of infestation did not affect the aphid response. A brief aphid feeding time of 3 h triggered induced resistance, which became effective between 24 and 48 h after the initial attack. Induced resistance decayed over time in the absence of additional infestation. Thirty aphid genotypes collected from natural populations were tested in the laboratory. No clone could colonize the resistant host, suggesting that all of them triggered the induction of effective plant defense responses. However, we detected significant quantitative variation among clones in the tendency of aphids to leave plants. These results improve our understanding of induced resistance as a dynamic phenomenon and suggest that the potential for aphids to adapt to a major plant resistance gene may depend on factors other than the mere capacity to evade recognition.

Water availability alters the tri-trophic consequences of a plant-fungal symbiosis

Abstract: Plant–microbe protection symbioses occur when a symbiont defends its host against enemies (e.g., insect herbivores); these interactions can have important influences on arthropod abundance and composition. Understanding factors that generate context-dependency in protection symbioses will improve predictions on when and where symbionts are most likely to affect the ecology and evolution of host species and their associated communities. Of particular relevance are changes in abiotic contexts that are projected to accompany global warming. For example, increased drought stress can enhance the benefits of fungal symbiosis in plants, which may have multi-trophic consequences for plant-associated arthropods. Here, we tracked colonization of fungal endophyte-symbiotic and aposymbiotic Poa autumnalis (autumn bluegrass) by Rhopalosiphum padi (bird-cherry-oat aphids) and their parasitoids (Aphelinus sp.) following manipulations of soil water levels. Endophyte symbiosis significantly reduced plant colonization by aphids. Under low water, symbiotic plants also supported a significantly higher proportion of aphids that were parasitized by Aphelinus and had higher above-ground biomass than aposymbiotic plants, but these endophyte-mediated effects disappeared under high water. Thus, the multi-trophic consequences of plant-endophyte symbiosis were contingent on the abiotic context, suggesting the potential for complex responses in the arthropod community under future climate shifts.

Tithonia diversifolia , Cyperus rotundus and Hyptis suaveloensis ethanol extracts combinatorially and competitively inhibit affinity purified cowpea storage bruchid ( Callosobrochus maculatus ) glutathione S-transferase

Abstract: Ethanol extracts of Tithonia diversifolia, Cyperus rotundus and Hyptis suaveloensis have earlier been reported to have insecticidal activity against storage bruchid (Callosbrochus maculatus) reared on cowpea (Vigna unguiculata). Here, antioxidant capacities of the ethanol extracts of these plants were evaluated by determining their effects on DPPH radical scavenging, lipid peroxidation and their total phenolic contents. These extracts were further investigated for their influence on the activity of uncharacterized but purified C. maculatus glutathione S-transferases. The antioxidant properties, as a factor of total phenols and reducing power, are 0.026, 0.043; 0.21, 0.040; 0.15, 0.034 mg/ml for T. diversifolia, C. rotundus and H. suaveloensis, respectively. Using 1-chloro-2,4–dintrobenzene (CDNB) as substrate, the GST activity was inhibited in a concentration depedent manner with 50% inhibition concentration (IC50) of 87.8, 95.4 and 115.8 μg/ml for T. diversifolia, C. rotundus and H. suaveloensis, respectively. When compared with standard GSTs inhibitors, the order of inhibition was cibracon blue > triphenyltinchloride > hematin > T. diversifolia > tributyltin acetate > C. rotundus > H. suaveloensis > ethacrynic acid. These extracts bind competitively to both the active site and the hydrophobic binding site of the enzyme as presented by the Dixon and Scatchard plots. Displacement of the fluorescent probe, l-anilino-8-naphthalenesulfonate, tryptophan quenching and spectral changes induced by the plant extracts binding demonstrated a common high affinity site for which the plant secondary metabolites bind. The combinatorial competitive inhibitory approach of these plant polyphenols might contribute to the insecticidal activity against C. maculatus.

Lima bean–lady beetle interactions: spider mite mediates sublethal effects of its host plant on growth and development of its predator

Abstract: Cultivated plants can have negative effects on natural enemies that attack spider mites. In this study, we tested the hypothesis that spider mites mediate effects of a lima bean, Phaseolus lunatus L., cultivar on the life history of a lady beetle Stethorus punctillum Weise. We provi- sioned laboratory arenas with two-spotted spider mites, Tetranychus urticae Koch, from planters containing Hen- derson Bush Bean or Fordhook 242 lima bean plants and monitored the growth, development, larval survival, fecundity, and adult life span of predators. We determined the protein content and the linamarin (a cyanogenic gly- coside) content in foliage, spider mites, and predators. Predators took longer to develop and were smaller sized when consuming mites from the Henderson foliage. There was no significant mite-mediated effect of cultivar on predator fecundity or life span. Although soluble protein was greater in foliage of the Henderson than the Fordhook cultivar, mites contained less protein when reared on the Henderson, and predators contained less protein when fed with mites from the Henderson. Linamarin content was greater in Henderson than Fordhook foliage, and greater in spider mites and predators in the Henderson treatment. Linamarin in Henderson foliage may reduce the ability of spider mites to utilize plant protein. As a result, prey quality is reduced and predators that feed on these prey (from the Henderson treatment) grow at a slower rate and are smaller sized than their cohorts (from the Fordhook treatment). In conclusion, T. urticae mediates the effects of the Henderson cultivar on S. punctillum development but not fecundity or life span.

How a lack of choice can force ants to climb up waxy plant stems

Abstract: The aim of this study was to analyse the ability of generalist ants to climb waxy stems and to understand whether the avoidance of such stems is solely based on their reduced ability to adhere to these surfaces. We performed observations of the locomotory behaviour and recorded the traversed distances of Lasius niger ants on flower stems of three plant species covered with epicuticular wax crystals: Anethum graveolens, Dahlia pinnata, and Tagetes patula. Using conventional and cryo-scanning electron microscopy, the surface micromorphology of plant stems and structure of ant attachment organs were examined. The present study demonstrates that the reason ants do not climb wax-covered stems is not because they are incapable of walking on such vertical surfaces, as previously assumed, but rather because they have a choice of other substrates. Presumably, additional locomotory efforts are needed to master climbing on “greasy” stems, and ants need a certain time to adapt to a new quality of the stem surface, and after this period, they can walk on these waxy stems.

Variable responses of hawkmoths to nectar-depleted plants in two native Petunia axillaris (Solanaceae) populations

Abstract: Pollination success of deceptive orchids is affected by the density and distribution of nectar providing plant species and overall plant density. Here we extended the framework of how plant density can affect pollination to examine how it may promote the success of plant intraspecific cheaters. We compared hawkmoth behaviour in two native populations of Petunia axillaris, where we simultaneously offered rewarding and manually depleted P. axillaris. We asked whether pollinator foraging strategies change as a function of plant density and whether such changes may differentially affect nectarless plants. We observed the first choice and number of flowers visited by pollinators and found that in the dense population, pollinators visited more flowers on rewarding plants than on nectar-depleted plants. In the sparse population, such discrimination was absent. As we found no differences in nectar volume between plants of the two populations, the observed differences in plant density may be temporal. We reason that if differences were more permanent, an equivalent of the remote habitat hypothesis prevails: in a sparse population, cheating plants benefit from the absence of inter- and intraspecific competitors because pollinators tend to visit all potential resources. In a denser population, a pollinator’s optimal foraging strategy involves more selectivity. This would cause between-plant competition for pollinators in a pollinator-limited context, which applies to most hawkmoth-pollinated systems. We propose that nectar-provisioning of plants can be density-dependant, with cheaters able to persist in low density areas.

Relative contributions to seed production by floral visitors of slickspot peppergrass, Lepidium papilliferum (Brassicaceae)

Abstract: Assessing the relative contributions to seed production made by different types of floral visitors is fundamental to understanding the evolution of floral morphology and the influence that particular pollinator taxa have on plant fitness and reproduction. This 3-year study examined the pollinator activity and the seed production in three populations of Lepidium papilliferum, a threatened mustard endemic to sagebrush-steppe habitat in southwest Idaho. Relative amounts of time visitor taxa spent foraging on flowers, visitation rates (number of flowers visited per unit time during a foraging bout), and pollination effectiveness (fruit set per single visit to a virgin flower) were recorded for each of 12 insect taxa that visited L. papilliferum flowers. Relative contributions to seed production were calculated as the product of relative interaction frequencies (the relative number of flowers visited by each taxon—the “quantity” component of pollination) and pollination effectiveness (fruit set per single visit to a virgin flower—the “quality” component of pollination). Despite the superiority of some insect taxa in terms of pollination effectiveness, estimates of relative pollinator contributions to seed production were influenced primarily by an insect taxon’s interaction frequency with flowers. Pollinator assemblages varied widely both spatially and temporally, which suggest that L. papilliferum is not under strong selective pressure to shift from its generalist pollination strategy toward greater specialization. For this threatened plant, reliance on a diverse assemblage of insect pollinators may serve as an important buffer against disruption in reproductive success caused by fluctuations in population sizes of individual pollinator taxa.

Bottom-up effects of Brassica napus nutrition on the oviposition preference and larval performance of Ceutorhynchus obstrictus (Coleoptera: Curculionidae)

Abstract: The cabbage seedpod weevil, Ceutorhynchus obstrictus (Marsham) (Coleoptera: Curculionidae), is a serious pest of canola, Brassica napus L. and Brassica rapa L., both in Europe and North America. Nitrogen and sulfur levels can be readily manipulated by growers and could potentially be exploited to improve current pest management strategies. In an effort to better understand the relationship between host plant nutrition and C. obstrictus oviposition preference and its larval developmental biology, we exposed gravid females to host plants grown under differing regimes of nitrogen and sulfur. Results indicated that plants grown with a higher supply of nitrogen were preferred as hosts. Plants with a higher sulfur supply were also preferred but only in plants grown at lower nitrogen levels. In contrast, larval development time increased with increasing nitrogen levels although larval dry weights were unaffected. The results were inconsistent with the preference-performance hypothesis. The inconsistencies between oviposition choice and larval growth and development may be due to a conflict between maternal and larval fitness. Observed changes in larval development time may not represent a significant fitness cost for larval C. obstrictus, as no corresponding change in larval weight was observed. Possible causal mechanisms for the increase in development time include differences in oil, protein and glucosinolate contents of the seed. Fertilizer management regimes currently recommended were considered to be optimal for management of C. obstrictus as the yield benefits from higher rates of nitrogen fertilization would more than compensate for increased level of infestation.

Olfactory responses of Neoseiulus cucumeris

Abstract: We studied the olfactory responses of Neoseiulus cucumeris (Acari: Phytoseiidae) to odors from eggplant (Solanum melongena L.), pepper (Capsicum aunuum), and tomato (Solanum lycopersicum), three host plants, and their complexes with different treatments (undamaged, mechanically damaged, infested, pre-infested) in an olfactometer. The results showed that N. cucumeris preferred the odors of undamaged eggplant, pepper, and tomato to clean air. N. cucumeris preferred the volatiles from eggplant infested with Frankliniella occidentalis (Thysanoptera: Thripidae) over undamaged, mechanically damaged, and pre-infested with F. occidentalis eggplant volatiles. The same results were observed with pepper and tomato. N. cucumeris adults preferred the odors of undamaged eggplant and tomato to undamaged pepper. Similarly, same results were observed with mechanically damaged eggplant, pepper, tomato, and same plants pre-infested with F. occidentalis. Compared with odors of tomato infested with F. occidentalis, N. cucumeris adults significantly responded to odors of eggplant and pepper infested with F. occidentalis. There was no significant difference of N. cucumeris in making choice between eggplant infested with F. occidentalis and pepper infested with F. occidentalis.