Waxy bloom in peas influences the performance and behavior of Aphidius ervi, a parasitoid of the pea aphid

Leaf surface waxy bloom can influence the predator–prey interactions that take place on peas. We tested whether the interaction between the pea aphid Acyrthosiphon pisum Harris (Homoptera: Aphidae) and a parasitoid, Aphidius ervi Haliday (Hymenoptera: Aphidiidae), is affected by reduced wax. We performed greenhouse experiments comparing aphid parasitism by individual A. ervi on two varieties of reduced wax peas to two normal wax sister varieties. We also observed the behavior of individual A. ervi in the greenhouse and measured field parasitism in small plots of reduced wax and normal wax peas. In the greenhouse, individual A. ervi parasitized more aphids on the reduced wax varieties than on their normal wax counterparts. Wasps spent more time actively foraging on reduced wax pea plants, which may contribute to the higher parasitism observed on those varieties. The greenhouse results suggested that the improved performance of individual A. ervi on reduced wax peas might contribute to a higher parasitism on reduced wax peas in the field. Field parasitism was significantly higher in reduced wax pea plots during 2000. Overall parasitism was higher in 2000 than in 2001 and 2002. In the latter years, parasitism was higher on reduced wax plants, but not significantly different from normal wax plants. Improved foraging by individual A. ervi resembles improved foraging by other carnivorous insects on reduced wax peas. The advantages of reduced wax for biological control of the pea aphid may hold when any of several different natural enemies is abundant.     

Leaf surface wax and plant morphology of peas influence insect density

Insect predators and parasitoids adhere better, forage more effectively, and take more aphid prey on pea plants (Pisum sativum L.) (Leguminosae) with mutations that reduce the crystalline wax bloom on the plant surface. To assess the agronomic potential of this trait for pest management, abundance of pea aphids (Acyrthosiphon pisum L.) (Homoptera: Aphididae) and coccinellid predators, and percent parasitism of the aphids were evaluated on pea lines differing in wax bloom and plant architecture over two field seasons. Three pairs of pea lines were evaluated, each pair with a different architecture and differing within the pair in the amount of surface wax bloom (reduced or normal). The trials included plots treated with a narrow spectrum insecticide (pymetrozine) to reduce aphid populations and untreated controls. Reduced wax peas had significantly fewer aphids per plant in 2002 but not in 2003. Total natural enemy abundance was greater on reduced wax than on normal wax pea lines in both years of the study. Pymetrozine reduced aphid densities significantly in both years. Among the four pea lines evaluated for yield, seed yield per plant was affected by plant morphology and insecticide treatment. Yield was greatest on semileafless plants and on pymetrozine sprayed plots in both years. Yield of the reduced wax line in the semileafless background was similar to or exceeded yield in its normal wax sister line, suggesting that this morphological type was best for an agronomically viable reduced wax phenotype. Pea weevil (Bruchus pisorum L.) (Coleoptera: Bruchidae) damage to seed was overall more frequent on seeds from reduced wax varieties than from normal wax varieties. The results illustrate the trade‐offs associated with a reduced wax trait in peas but also show that certain combinations of reduced wax and gross morphology lead to reduced pea aphid populations and yields similar to those of normal wax peas.     

Leaf surface waxbloom in Pisum sativum influences predation and intra-guild interactions involving two predator species

Suppression of shared prey populations by insect predators can be influenced by interactions among these predators (intra-guild interactions). Intra-guild interactions among predators attacking herbivores may be influenced by plant characteristics, but this possibility has not been examined. Plant surface waxes are a ubiquitous and variable morphological feature that are known to affect insect predator behavior, and potentially in- fluence inter-predator interactions. To test this possibility we measured the effectiveness of individual and multiple predators on Pisum sativum L. lines with either wild-type crystalline waxes (normal waxbloom) or with reduced waxbloom resulting from a genetic mutation. On caged five-node plants of each line, reduction in populations of Acyrthosiphon pisum (Harris) (Homoptera: Aphidae) by individuals or pairs of second-instar Hippodamia con- vergens Guerin de Meneville (Coleoptera: Coccinellidae), and second-instar Chrysoperla plorabunda (Fitch) (Neuroptera: Chrysopidae), was significantly greater on the reduced waxbloom plants. Intra-specific interference by H. convergens depended on plant waxbloom type. Pairs of H. convergens larvae were no more effective than individuals of this species at reducing aphid populations on normal waxbloom plants, indicating interference, but were additive in their reduction of aphids on reduced waxbloom plants, indicating no interference. In contrast, pairs of C. plorabunda apparently interfered regardless of plant waxbloom type; pairs were no more effective at reducing aphids than individuals of this species. Heterospecific pairs of H. convergens and C. plorabunda were more effective on reduced waxbloom plants and showed no evidence of interference on either waxbloom type. Differences in behavior of the two predator species provided a partial explanation for the asymmetrical effect on intraspecific interactions in the two species. H. conver- gens spent significantly more time walking and less time ”scrambling” (ineffective locomotion) on reduced waxbloom plants than on normal waxbloom plants, and distributed these activities differently among plant parts on the two waxbloom types. In contrast, C. plorabunda spent the same amount of time walking and scrambling on each waxbloom type, although they distributed this walking and scrambling differently among plant parts of the two waxbloom types. The stronger influence of plant waxbloom on H. convergens behavior is consistent with the difference in intra-specific interference for this species on the two waxbloom types. The mechanisms of intra-specific interference by H. convergens on normal waxbloom plants and by C. plorabunda on both waxbloom types were not determined. Received: 14 July 1999 / Accepted: 10 January 2000     

The role of vision and color in the close proximity foraging behavior of four coccinellid species

The role of vision and color in close-proximity foraging behavior was investigated for four species of lady beetles: Coccinella septempunctata, Hippodamia convergens, Harmonia axyridis, and Coleomegilla maculata. The effect of light level and color cues on consumption rates varied among the four predator species. The consumption rates of these predators on the pea aphid Acyrthosiphon pisum (Harris) was measured under light and dark conditions. C. septempunctata,H. convergens, and Ha. axyridis consumed significantly more aphids in the light than in the dark, while the consumption rate of Col. maculata was not affected by light level. Foraging ability was also measured on red and green color morphs of the pea aphid on red, green, and white backgrounds. C. septempunctata consumed significantly more of the aphid morph that contrasted with the background color, and showed no difference between morphs on the white background. H. axyridis consumed significantly more red morph aphids regardless of background. The remaining two species showed no difference in consumption rates on the two color morphs. The variation in the use of visual cues demonstrates how different species of predators can exhibit different foraging behaviors when searching for the same prey. Received: 4 August 1997 / Accepted: 3 February 1998     

A plant surface mutation mediates predator interference among ladybird larvae

Abstract.  1. We investigated mechanisms causing predator–predator interference between fourth instar Hippodamia convergens larvae foraging for pea aphids on pea plants, Pisum sativum , with a wild-type wax bloom, and the lack of such interference between larvae foraging on pea plants with a reduced-wax bloom caused by the single gene mutation wel .
2. Observations showed that behavioural interactions between larvae were not affected by wax phenotype. Specifically, larvae did not encounter one another more frequently on normal-wax peas as may have been predicted because reduced ability by coccinellids to attach to normal-wax plant surfaces could restrict them to foraging on only some parts of these plants.
3. In a controlled bioassay on normal-wax peas, H. convergens larvae avoided leaflets previously exposed to another larva. On reduced-wax peas, this effect was not detected.
4. In microcosm experiments, inter-predator interference in terms of prey consumption occurred on normal-wax peas, but not on reduced-wax peas. The interference on normal-wax peas occurred whether two H. convergens larvae were placed on a pea aphid-infested, normal-wax plant simultaneously or sequentially.
5. We conclude that the observed inter-predator interference is not as a result of direct physical contact, but rather arises because of (i) inhibition of foraging by chemical trails left by other larvae, (ii) the inability of larvae to access portions of the normal-wax plants creating aphid refugia, or (iii) a combination of these factors.     

Intra versus interspecific interactions of ladybeetles (Coleoptera: Coccinellidae) attacking aphids

Summary The nature and relative strengths of intra versus interspecific interactions among foraging ladybeetle larvae were studied experimentally by measuring short-term growth rates of predators and reductions in population sizes of prey in laboratory microcosms. In these microcosms, ladybeetle larvae foraged singly or as conspecific or heterospecific pairs, for pea aphids on bean plants over a two-day period. Similarly sized third instar larvae ofHippodamia convergens andH. tredecimpunctata, H. convergens andH. sinuata, andH. convergens andCoccinella septempunctata, were tested in experiments designed to ensure that paired larvae experienced moderate competition. Interspecific competition in these experiments did not differ significantly from intraspecific competition, in that an individual's weight gain did not depend on whether its competitor was heterospecific or conspecific. Furthermore, aphid populations were reduced equally by heterospecific and conspecific pairs. These results suggest that there is little or no difference between intra and interspecific interactions among larvae of these ladybeetles when two similarly sized individuals co-occur on a host plant. Thus, the species diversityper se of assemblages of ladybeetle larvae may have little influence over the short term on the reduction of aphid populations by ladybeetle predation.     

Attachment forces of pea aphids (Acyrthosiphon pisum) on different legume species

1. Sympatric populations of insects adapted to different host plants are good model systems not only to study how they adapt to the chemistry of their food plant, but also to investigate whether morphological modifications evolved enabling them to live successfully on a certain plant species. 2. The pea aphid, Acyrthosiphon pisum (Harris) encompasses at least 11 genetically distinct sympatric host races, each showing a preference for a certain legume species. The leaflet surfaces of these legumes differ considerably in their wax coverage. 3. It was investigated whether the attachment structures of three pea aphid genotypes from different host races are adapted to the different surface properties of their host plants and whether they show differences in their attachment ability on the respective host and non‐host plants. 4. The surface morphology of plants and aphid tarsi was examined using SEM (scanning electron microscopy). The ability of the aphids to walk on specific surfaces was tested using traction force measurements. 5. The presence of wax blooms on the leaflets lowers the aphids' attachment ability considerably and diminishes their subsequent attachment on ‘neutral’ surfaces like glass. The pea aphid host races differ in their ability to walk on certain surfaces. However, the genotype from the adapted aphid host race was not necessarily the one with the best walking performance on their host plant. All aphids, regardless of the original host plant, were most efficient on the neutral control surface glass. The general host plant Vicia faba was the plant with the most favourable surface for all aphid host races.     

Effects of a simple plant morphological mutation on the arthropod community and the impacts of predators on a principal insect herbivore

Plant features that enhance predator effectiveness can be considered extrinsic-resistance factors because they result in reduced insect herbivory. In this paper we test the hypothesis that reduced epicuticular wax (EW) in Pisum sativum L. is an extrinsic-resistance factor contributing to field resistance to Acyrthosiphon pisum (Harris). We monitored pea aphid populations in the field on reduced EW and normal EW near isolines of peas for two seasons and confirmed that aphid populations are lower on reduced EW peas than on normal EW peas. We also monitored predators within the canopies of the two pea lines to discover community level patterns in response to differences in EW. We found that while predator numbers were similar between the two lines, there were more syrphids on the normal EW peas, and a trend towards more coccinellids on reduced EW peas. We tested the impact of predators on pea aphids on the two EW lines by monitoring their population levels in cages that excluded predators, and in cages that allowed predators to enter. We found that pea aphid populations were similar on the two EW lines when predators were excluded. When predators were allowed access to the plants, pea aphid populations were reduced more on reduced EW peas than on normal EW peas. We also examined the intrinsic resistance to aphids in reduced EW peas with laboratory dual-choice tests comparing aphid response to reduced EW and normal EW peas, and found that walking, apterous aphids displayed no preference for one pea line over the other. Bioassays to measure growth and fecundity of the pea aphid on the two EW types in the greenhouse and in the field showed that intrinsic rate of increase, and other life table parameters, were not different for aphids on the two lines. Together these results support the hypothesis that reduced EW in peas is a predator-dependent extrinsic resistance factor. Genetically reducing EW bloom in peas and other waxy crop plants might improve the effectiveness of arthropod natural enemies of insect pests. More generally, the results show that a subtle change in plant morphology can substantially influence the impact of predators on insect herbivore populations. The benefit of extrinsic resistance to herbivory conferred by reduced EW may balance any benefits of a prominent EW bloom, thereby sustaining EW polymorphisms in some natural plant populations.     

Potential cotton aphid,Aphis gossypii,population suppression by arthropod predators in upland cotton

The cotton aphid, Aphis gossypii Glover, predation rate of convergent lady beetle, Hippodamia convergens Guerin‐Meneville, was determined by assigning a single predator randomly to each of four prey density treatments in the laboratory. Prey densities included 25, 50, 100, and 200 aphids per Petri dish arena. Predation response was recorded at 1, 4, 8, 16, 24, and 48 h after assigning predators to their prey treatments. Rate of consumption increased through time, with all 25 aphids consumed during the first 4 h of the experiment. At the highest density, adult lady beetle consumed on average 49, 99, 131, 163, 183, and 200 aphids within 1, 4, 8, 16, 24 and 48 h, respectively. Predators showed a curvilinear feeding response in relation to total available time, indicating that convergent lady beetles have the potential to suppress larger populations of aphids through continuous feeding by regulating their predation efficiency during feeding. The analysis of age‐specific mortality in absence of prey revealed that lady beetles could survive for an extended period of time (more than 2 weeks) without prey. The ability of a predator to survive without prey delays or prevents the rebound of pest populations that is a significant factor in natural biological control. A two‐year field sampling of 10 cotton arthropod predator species showed that spiders (27%) were the most dominant foliage dwelling predators in the Texas High Plains cotton followed by convergent lady beetles (23.5%), hooded beetles (13.5%), minute pirate bugs (11%), green lacewings (9.5%), bigeyed bugs (7.5%), scymnus beetles (3%), soft‐winged flower beetles (2%), damsel bugs (1.5%), and assassin bugs (1.5%). A field cage study showed that one H. convergens adult per plant released at prey density of one aphid per leaf kept the aphid population below economic threshold for the entire growing season.     

Increased nitrogen fertilization inhibits the biocontrol activity promoted by the intercropping partner plant

The examination of the compatibility between agricultural practices and biocontrol activities is crucial for establishing an efficient, eco-friendly, and sustainable pest management program. In this study, we examined the population dynamics of two specialist aphids, the English grain aphid (Sitobion avenae) on potted wheat and the pea aphid (Acyrthosiphon pisum) on potted alfalfa, as well as the biocontrol activity of a generalist predator, the harlequin ladybird beetle (Harmonia axyridis). We investigated their responses to the presence of the intercropping partner plant species (alfalfa and wheat, respectively) through plant volatiles or visual cues at three nitrogen fertilizer levels in a greenhouse. In the absence of the predator, the English grain aphid population growth rate increased significantly with increasing nitrogen levels, whereas the pea aphid population increased significantly more slowly in response to high nitrogen levels. The English grain aphid and pea aphid population dynamics were unaffected by the presence of the intercropping partner. However, the presence of the intercropping partner enhanced the control of both aphid populations by the harlequin ladybird beetle. Increasing nitrogen fertilizer levels decreased the predation rates, which were otherwise increased by the intercropping partner. The beneficial effects of the intercropping partner were eventually non-existent at the highest nitrogen level tested. These results imply that the interaction between the presence of intercropping partner and the nitrogen fertilizer application affects the biocontrol activity of the natural enemies of insect pests. Thus, the compatibility between agricultural intensification and biocontrol strategies in integrated pest management programs need to be investigated.     

Comparison of the wing polyphenic response of pea aphids (Acyrthosiphon pisum) to crowding and predator cues

相似文献   

Genetic variation in the effect of a facultative symbiont on host-plant use by pea aphids

Ecological specialisation on different host plants occurs frequently among phytophagous insects and is normally assumed to have a genetic basis. However, insects often carry microbial symbionts, which may play a role in the evolution of specialisation. The bacterium Regiella insecticola is a facultative symbiont of pea aphids (Acyrthosiphon pisum) where it is found most frequently in aphid clones feeding on Trifolium giving rise to the hypothesis that it may improve aphid performance on this plant. A study in which R. insecticola was eliminated from a single naturally infected aphid clone supported the hypothesis, but a second involving two aphid clones did not find the same effect. We created a series of new pea aphid–R. insecticola associations by injecting different strains of bacteria into five aphid clones uninfected by symbionts. For all aphid clones, the bacteria decreased the rate at which aphids accepted Vicia faba as a food plant and reduced performance on this plant. Their effect on aphids given Trifolium pratense was more complex: R. insecticola negatively affected acceptance by all aphid clones, had no effect on the performance of four aphid clones, but increased performance of a fifth, thus demonstrating genetic variation in the effect of R. insecticola on pea aphid host use. We discuss how these results may explain the distribution and frequency of this symbiont across different aphid populations. Julia Ferrari and Claire L. Scarborough contributed equally to the work.     

Plant waxy bloom on peas affects infection of pea aphids by Pandora neoaphidis

This study examined the effects of the surface wax bloom of pea plants, Pisum sativum, on infection of pea aphids, Acyrthosiphon pisum, by the fungal pathogen Pandora neoaphidis. In prior field surveys, a higher proportion of P. neoaphidis-killed pea aphids (cadavers) had been observed on a pea line with reduced wax bloom, as compared with a sister line with normal surface wax bloom. Laboratory bioassays were conducted in order to examine the mechanisms. After plants of each line infested with aphids were exposed to similar densities of conidia, the rate of accumulation of cadavers on the reduced wax line was significantly greater than on the normal wax bloom line; at the end of the experiment (13d), the proportion of aphid cadavers on the reduced wax line was approximately four times that on the normal wax bloom line. When plants were exposed to conidia first and then infested with aphids, the rate of accumulation of cadavers was slightly but significantly greater on the reduced wax line, and infection at the end of the experiment (16d) did not differ between the lines. When aphids were exposed first and then released onto the plants, no differences in the proportion of aphid cadavers were observed between the pea lines. Greater infection of pea aphid on reduced wax peas appears to depend upon plants being exposed to inoculum while aphids are settled in typical feeding positions on the plant. Additional experiments demonstrated increased adhesion and germination by P. neoaphidis conidia to leaf surfaces of the reduced wax line as compared with normal wax line, and this could help explain the higher infection rate by P. neoaphidis on the reduced wax line. In bioassays using surface waxes extracted from the two lines, there was no effect of wax source on germination of P. neoaphidis conidia.     

Pea aphid dropping behavior diminishes foraging efficiency of a predatory ladybeetle

Antipredator defensive behaviors are a well‐studied and often crucial part of prey life histories, but little has been done to quantify how such behaviors affect natural enemies, their foraging, and their effectiveness as biological control agents. We explored how the generalist predatory coccinellid Harmonia axyridis Pallas (Coleoptera: Coccinellidae) affects the dropping behavior of the pea aphid, Acyrthosiphon pisum (Harris) (Homoptera: Aphididae), and in turn, how that defensive behavior affects the foraging efficiency of the predator. Experimental arenas that allowed or prevented pea aphid dropping were compared to determine how dropping influences the foraging of multiple life stages of H. axyridis: second instars, fourth instars, and adults. Dropping reduced predation on aphids by all ladybeetle life stages. Despite older predators inducing more dropping, aphid dropping reduced predation by approximately 40% across all ladybeetle life stages. Aphid dropping and predator consumption of aphids were both correlated with how much the predator moved, which also increased with predator life stage. We suggest that the high rates of dropping induced by H. axyridis and the subsequent decrease in H. axyridis foraging efficiency may partially explain why H. axyridis is less effective at controlling pea aphids than it is at controlling other aphid species that do not drop.     

The role of sinigrin in host plant recognition by aphids during initial plant penetration

Plant penetration behaviour (probing) of the cabbage aphid, Brevicoryne brassicae, and the pea aphid, Acyrthosiphon pisum, was studied on excised leaves of broad beans, Vicia faba, kept in water or in a 1% aqueous solution of sinigrin. Using the DC EPG (Electrical Penetration Graph) technique it was shown that the cabbage aphid on sinigrin-untreated bean leaves showed numerous short probes into epidermis and mesophyll. None of these aphids showed either phloem salivation or ingestion waveforms on untreated leaves. In contrast, on sinigrin-treated bean leaves, 35% of the probing time was spent on phloem sap ingestion (E2) and almost all aphids reached phloem vessels and started feeding. The duration of phloem salivation before phloem ingestion and the mean duration of phloem ingestion periods were similar on a host and a sinigrin-treated non-host plant. However, the total probing time by B. brassicae was 10% longer, the total phloem sap ingestion time was twice as long, and the time to the first phloem phase within a probe was three times shorter on the host plant compared to sinigrin-treated broad beans. Acyrthosiphon pisum also responded to the addition of sinigrin to broad beans, but in this case sinigrin acted as a deterrent. On sinigrin-treated leaves, A. pisum terminated probes before ingestion from phloem vessels, and none of these aphids showed phloem salivation and ingestion on treated leaves. Glucosinolates were detected in the mesophyll cells of the brassicaceous plant, Sinapis alba. Based on this finding and in addition to the foregoing EPG analysis of aphid probing on these plants and broad beans, our hypothesis is that aphids may recognise their host plants as soon as they probe the mesophyll tissue and before they start ingestion from phloem vessels.     

Impact of environmental stress on aphid clonal resistance to parasitoids: Role of Hamiltonella defensa bacterial symbiosis in association with a new facultative symbiont of the pea aphid

Resistance to endoparasitoids in aphids involves complex interactions between insect and microbial players. It is now generally accepted that the facultative bacterial symbiont Hamiltonella defensa of the pea aphid Acyrthosiphon pisum is implicated in its resistance to the parasitoid Aphidius ervi. It has also been shown that heat negatively affects pea aphid resistance, suggesting the thermosensitivity of its defensive symbiosis. Here we examined the effects of heat and UV-B on the resistance of A. pisum to A. ervi and we relate its stability under heat stress to different facultative bacterial symbionts hosted by the aphid. For six A. pisum clones harboring four different facultative symbiont associations, the impact of heat and UV-B was measured on their ability to resist A. ervi parasitism under controlled conditions. The results revealed that temperature strongly affected resistance, while UV-B did not. As previously shown, highly resistant A. pisum clones singly infected with H. defensa became more susceptible to parasitism after exposure to heat. Interestingly, clones that were superinfected with H. defensa in association with a newly discovered facultative symbiont, referred to as PAXS (pea aphid X-type symbiont), not only remained highly resistant under heat stress, but also expressed previously unknown, very precocious resistance to A. ervi compared to clones with H. defensa alone. The prevalence of dual symbiosis involving PAXS and H. defensa in local aphid populations suggests its importance in protecting aphid immunity to parasitoids under abiotic stress.     

Comparative transmission of pea mosaic virus by one strain ofMyzus persicae Sulz. and two strains ofAcyrthosiphon pisum Harris

Experiments were conducted to compare the efficiency of transmission of a strain of pea mosaic virus (PMV) isolated in Czechoslovakia by two strains (clones) of the pea aphidAcyrthosiphon pisum Harris (green and red) and one strain ofMyzus persicae Sulz. PMV is a nonpersistent virus and the preliminary fasting of aphids before acquisition feeding increases the efficiency of aphids in transmission of this virus. In our experiments two hour fasted individuals were used and two periods of acquisition feeding on the source (1 and 5 minutes). On the healthy test plants the aphids were left over night. As the source and test plants pea (Pisum sativum L.) of the cv. Raman were used. During the one minute acquisition period on the source of infection the aphids were observed under the stereoscopic microscope. They usually made two to three probes. During the five minute acquisition feeding time the aphids were not observed and they were taken from the source of infection after a lapse of five minutes. To compare the efficiency in transmission of this virus by these aphids only one aphid per tested plant was used and in all trials only two to four day old nymphs were taken. Differences in transmission efficiency between two strains ofAcyrthosiphon pisum Harris were highly significant. The green strain of pea aphid was the less efficient vector in comparison with the green peach aphid and the red strain of the pea aphid, the latter being the most efficient vector of this virus.     

Influence of aphid honeydew on the foraging behaviour of Hippodamia convergens larvae

1. Environmental cues associated with prey are known to increase predator foraging efficiency. Ladybird larvae are major predators of aphids. The sugary excretion of aphids (honeydew) has been proposed to serve as a prey‐associated cue for ladybird larvae. 2. Ladybird larvae are regularly found on the ground moving between plants or after falling off plants. The use of prey‐associated cues would be particularly beneficial for ladybird larvae on the ground in that such cues would help them to decide which plants to climb because aphids are patchily distributed within as well as amongst plants and, as a result, many plants are either not infested with aphids or do not host an aphid species of high nutritional value for ladybird larvae. 3. Laboratory experiments with larvae of Hippodamia convergens Guérin‐Méneville (Coleoptera: Coccinellidae) were carried out to explore whether honeydew accumulated on the ground is used as a foraging cue. The study also investigated whether, if honeydew is a foraging cue, larvae show differential responses to honeydew of high‐quality prey Acyrthosiphon pisum Harris compared with that of low‐quality prey Aphis fabae Scopoli (both: Homoptera: Aphididae). 4. Hippodamia convergens larvae stayed longer in areas containing honeydew but did not engage in longer bouts of searching. Furthermore, larvae did not distinguish between honeydew from high‐ and low‐quality aphid prey.     

Predator and parasitoid attacking ant-attended aphids: effects of predator presence and attending ant species on emerging parasitoid numbers

Interaction between a predator and a parasitoid attacking ant-attended aphids was examined in a system on photinia plants, consisting of the aphid Aphis spiraecola, the two ants Lasius japonicus and Pristomyrmex pungens, the predatory ladybird beetle Scymnus posticalis, and the parasitoid wasp Lysiphlebus japonicus. The ladybird larvae are densely covered with waxy secretion and are never attacked by attending ants. The parasitoid females are often attacked by ants, but successfully oviposit by avoiding ants. The two ants differ in aggressiveness towards aphid enemies. Impacts of the predator larvae and attending ant species on the number of parasitoid adults emerging from mummies per aphid colony were assessed by manipulating the presence of the predator in introduced aphid colonies attended by either ant. The experiment showed a significant negative impact of the predator on emerging parasitoid numbers. This is due to consumption of healthy aphids by the predator and its predation on parasitized aphids containing the parasitoid larvae (intraguild predation). Additionally, attending ant species significantly affected emerging parasitoid numbers, with more parasitoids in P. pungens-attended colonies. This results from the lower extent of interference with parasitoid oviposition by the less aggressive P. pungens. Furthermore, the predator reduced emerging parasitoid numbers more when P. pungens attended aphids. This may be ascribed to larger numbers of the predator and the resulting higher levels of predation on unparasitized and parasitized aphids in P. pungens-attended colonies. In conclusion, a negative effect of the predator on the parasitoid occurs in ant-attended aphid colonies, and the intensity of the interaction is affected by ant species.     

Has the Attraction of Predatory Coccinellids to Cornicle Droplets Constrained Aphid Alarm Signaling Behavior?

When attacked by a predator, aphids of many species secrete cornicle droplets, containing an alarm pheromone, that results in the dispersal of nearby conspecifics. As females are parthenogenetic, alarm signaling functions to enhance the survival of clone-mates. Enigmatically, however, aphids are physically able to, but usually do not emit alarm pheromone when initially detecting a predator, but rather signal only when captured by a predator. We hypothesized that cornicle droplets may be attractive to natural enemies and result in an increased risk of predation for the signaler, thereby selecting for prudent alarm signalers. We tested this hypothesis by investigating the olfactory cues that the multicolored Asian ladybird beetle, Harmonia axyridis Pallas, uses to locate pea aphids, Acyrthosiphon pisum. In choice tests, H. axyridis were attracted to odors from pea aphid colonies, whether feeding or not feeding on a host plant leaf, but were not attracted to cornicle droplets containing alarm pheromone. Further, individual pea aphids emitting cornicle droplets were not located more often or in a shorter period of time by beetles than aphids not emitting cornicle droplets. Thus, the cost of emitting early alarm signals is not prohibitively high in regards to the attraction of predators such as H. axyridis.