Plant population size and isolation affect herbivory of <Emphasis Type="Italic">Silene latifolia</Emphasis> by the specialist herbivore <Emphasis Type="Italic">Hadena bicruris</Emphasis> and parasitism of the herbivore by parasitoids

Habitat fragmentation can affect levels of herbivory in plant populations if plants and herbivores are differentially affected by fragmentation. Moreover, if herbivores are top–down controlled by predators or parasitoids, herbivory may also be affected by differential effects of fragmentation on herbivores and their natural enemies. We used natural Silene latifolia populations to examine the effects of plant population size and isolation on the level of herbivory by the seed predating noctuid Hadena bicruris and the rate of parasitism of the herbivore by its parasitoids. In addition, we examined oviposition rate, herbivory and parasitism in differently sized experimental populations. In natural populations, the level of herbivory increased and the rate of parasitism decreased with decreasing plant population size and increasing degree of isolation. The number of parasitoid species also declined with decreasing plant population size. In the experimental populations, the level of herbivory was also higher in smaller populations, in accordance with higher oviposition rates, but was not accompanied by lower rates of parasitism. Similarly, oviposition rate and herbivory, but not parasitism rate, increased near the edges of populations. These results suggests that in this system with the well dispersing herbivore H. bicruris, habitat fragmentation increases herbivory of the plant through a behavioural response of the moth that leads to higher oviposition rates in fragmented populations with a reduced population size, increased isolation and higher edge-to-interior ratio. Although the rate of parasitism and the number of parasitoid species declined with decreasing population size in the natural populations, we argue that in this system it is unlikely that this decline made a major contribution to increased herbivory.     

Impact of natural enemies on <Emphasis Type="Italic">Obolodiplosis robiniae</Emphasis> invasion

The gall midge Obolodiplosis robiniae is a pest of black locust Robinia pseudoacacia. The species was recently introduced into Europe and it is nowadays a usual insect in Slovakia, where two-year field surveys were undertaken during 2007–2008. The main objective of this study was to determine the natural enemies attacking O. robiniae and estimate their influence on midge population, less than 3 years after its introduction. Eight parasitoids and bushcricket Tettigonia viridissima were responsible for midge regulation. The parasitoid complex was not typically that of an introduced species as it was predicted. Firstly, the midge was heavily influenced by a specialized parasitoid Platygaster robiniae, which was a predominant parasitoid and accounted for 98% of all specimens reared. Secondly, annual larval parasitism varied from 5.4 to 10.8%, though the late season average parasitism achieved 26.0% and often exceeded 40%. P. robiniae was also very efficient in exploiting galls and was capable of consistently regulating midge population. The surveys demonstrated that the average cumulative impact of natural enemies on the midge was substantial. Stably around 20% of attacked galls were recorded during the late summer. Bushcrickets were as efficient as parasitoids and played an important role at control, especially during lack of parasitoids. Greater impact of parasitoids was found in the larger settlements than it was in the countryside, when countertendency was valid for bushcrickets. There is an indication that O. robiniae parasitized by specialized parasitoid, and attacked by bushcrickets represents only a moderate risk for R. pseudoacacia or forest stands.     

Fitness and life history parameters of <Emphasis Type="Italic">Leptomastix epona</Emphasis> and <Emphasis Type="Italic">Pseudaphycus flavidulus</Emphasis>, two parasitoids of the obscure mealybug <Emphasis Type="Italic">Pseudococcus viburni</Emphasis>

Fitness and life table parameters of two endoparasitoids of the obscure mealybug Pseudococcus viburni (Signoret), the solitary Leptomastix epona (Walker) and the gregarious Pseudaphycus flavidulus (Brèthes), were examined in relation to temperature and host size with a view to determine the efficacy of the parasitoids as biocontrol agents of the pest. Three temperature levels (21°C, 26°C and 31°C) and two host sizes classes (small, which mostly comprised third instar nymphs and large, which consisted of female adults) were studied. The lower developmental threshold and thermal constant of the host and the parasitoids were found similar so the coincidence of pest and parasitoids is likely. The rate of development of the parasitoids increased with a linear trend as the temperature increased from 21°C to 31°C. Temperature had a significant effect on mummification in both parasitoid species and on successful parasitism by P. flavidulus. Host size had a significant effect on the mummification caused by L. epona and on the proportion of the male offspring which emerged as well as on the successful parasitism by P. flavidulus. Life table parameters of the parasitoids were estimated in small and large hosts at 26°C in the laboratory. Both parasitoids achieved a greater intrinsic rate of natural increase and gross reproductive rate in addition to a shorter generation and doubling time in large mealybugs compared with small ones. Consequently, large hosts are expected to have a higher impact on the rise of the parasitoids population and the potential of the parasitoids to control the mealybug population improves with the increase of host size. Handling Editor: Torsen Meiners.     

Parasitism rates and parasitoid complexes of the wheat midges, <Emphasis Type="Italic">Sitodiplosis mosellana</Emphasis>, <Emphasis Type="Italic">Contarinia tritici</Emphasis> and <Emphasis Type="Italic">Haplodiplosis marginata</Emphasis>

Three species of cecidomyiid midges (Diptera: Cecidomyiidae), whose larvae overwinter in the soil, can cause significant yield losses on wheat in Europe: the orange wheat blossom midge, Sitodiplosis mosellana (Géhin), the yellow wheat blossom midge, Contarinia tritici (Kirby), and the saddle gall midge, Haplodiplosis marginata (von Roser). The biological control of wheat midges by their parasitoids can contribute to reduce the midge populations. Soil samples were collected in several fields in Belgium in 2012–2014 in order to characterize the parasitism rates and parasitoid complexes in overwintering larvae. The parasitism rates varied greatly between the sampled fields: 3–100, 0–100 and 2% for S. mosellana, H. marginata and C. tritici, respectively. The parasitism rate was not related to the larval density of wheat midge. The three wheat midges have totally distinct parasitoid complexes in Belgium. Eight species (Hymenoptera: Pteromalidae and Platygastridae) were found as parasitoid of S. mosellana: Macroglenes penetrans (Kirby), Amblypasis tritici (Walker), Euxestonotus error (Fitch), Euxestonutus sp. Fouts, Leptacis sp. Foerster, Platygaster gracilipes (Huggert), Platygaster nisus Walker, and Platygaster tuberosula (Kieffer). According to their abundance, M. penetrans, E. error and P. tuberosula appeared as the main parasitoids of S. mosellana in Belgium. For the two other wheat midges, only one species of the family Platygastridae was found for each midge: Platygaster equestris (Spittler) for H. marginata and Synopeas myles (Walker) for C. tritici.     

Intraguild interactions between generalist predators and an introduced parasitoid of Glycaspis brimblecombei (Homoptera: Psylloidea)

Studies were conducted to evaluate potential impacts of generalist predators on the biological control of Glycaspis brimblecombei Moore (Homoptera: Psylloidea), a pest of eucalyptus trees in California, and its introduced parasitoid Psyllaephagus bliteus (Hymenoptera: Encyrtidae). Based on the results of the monitoring populations of G. brimblecombei and their natural enemies in inland and coastal California in the field, P. bliteus or Anthocoris nemoralis (Fabricius) (Heteroptera: Anthocoridae), alone or both species together were released into cages with G. brimblecombei to simulate predatory interference on the introduced parasitoid in the laboratory. Although coastal sites had higher densities of natural enemies as were percent parasitism and predation, the mean number of G. brimblecombei did not vary between inland and coastal sites. P. bliteus or A. nemoralis significantly reduced the psyllid densities in cages. However, when both species were together, the presence of A. nemoralis increased the parasitoid mortality relative to the mortality observed in the parasitoid-alone treatment. Moreover, the increase in parasitoid mortality was followed by the decrease in mortality of the psyllids. The current study also indicated that predation risk of parasitized hosts varies depending on the developmental stages of the psyllids.     

Occurrence and activity of <Emphasis Type="Italic">Bemisia tabaci</Emphasis> parasitoids on cassava in different agro-ecologies in Uganda

Bemisia tabaci Gennadius (Homoptera: Aleyrodidae) is the vector of cassava mosaic geminiviruses that cause cassava mosaic disease (CMD), which in turn causes devastating yield losses. Surveys were conducted from October 2000 to November 2001 in four agro-ecologies in Uganda to enhance the understanding of parasitoid fauna and parasitism of B. tabaci in cassava fields. Such an understanding is an essential prerequisite for the development of biological control methods of B. tabaci to complement current CMD control practices. Parasitoid abundance and parasitism efficiency varied between locations and sampling dates within the locations; highest parasitoid densities were observed at Namulonge in the Lake Victoria crescent while the lowest was at Kalangala. In all locations, parasitism was mainly due to Encarsia sophia Dodd and Girault and Eretmocerus mundus Mercet (all Hymenoptera: Aphelinidae). Two occasionally observed species included Encarsia mineoi Viggiani (Hymenoptera: Aphelinidae), only observed at Namulonge, and blackhead Encarsia (Hymenoptera: Aphelinidae) observed at Bulisa, Namulonge and Lyantonde. Parasitism efficiency was highest at Bulisa (57.9%), but ranged from 40.2 to 46.9% at the other three sites. This paper discusses the possible causes of variations in parasitoid abundance and parasitism efficiency, and proposes further studies that might be carried out to assess the potential for augmentation of parasitoids to control B. tabacipopulations and CMD.     

Effect of host feeding on life history traits of <Emphasis Type="Italic">Tamarixia radiata</Emphasis>, parasitoid of the Asian citrus psyllid, <Emphasis Type="Italic">Diaphorina citri</Emphasis>

The parasitoid Tamarixia radiata (Hymenoptera: Eulophidae) is being used for the biological control of the Asian citrus psyllid (ACP), Diaphorina citri (Hemiptera: Liviidae). The parasitoid is strongly synovigenic, as it is born with very few mature eggs. Synovigenic insects need to feed on host haemolymph to mature additional eggs, and are able to resorb mature eggs to allocate resources toward maintenance. We investigated the effect of host feeding on parasitism, longevity and egg load dynamics, and estimated egg maturation and resorption rates. Although host feeding does not increase survival or longevity, it results in increased parasitization rates when parasitoids are seven days old, and that a single host meal leads to an average gain of three eggs. We discuss the importance of these data to predict the foraging and parasitization behavior of T. radiata in the field, and to potentially improve current efforts to control ACP.     

Larval parasitoids of the apple ermine moth, <Emphasis Type="Italic">Yponomeuta malinellus</Emphasis>in Korea,Japan, and China

Larval parasitoids of Yponomeuta malinellus Zell. (Lepidoptera: Yponomeutidae), the apple ermine moth (AEM), were sought in northeast Asia with the goal of identifying potential biological controls of the moth, which appeared to threaten the apple industry in Washington State, USA during the 1980s. Ten primary and four secondary parasitoids were found. Dolichogenidea delecta (Haliday) (Braconidae), Ageniaspis fuscicollis (Dalman) (Encyrtidae), Herpestomus brunnicornis Grav. (Icheumonidae), Bessa paralella (Meigen), and Zenillia dolosa (Meigen) (Tachinidae) were the most important parasitoids. The composition of parasitoid species was more diverse in Korea and Japan than in China; two species were found in China, compared to nine in Korea and seven in Japan. A. fuscicollis caused a greater mortality in all investigated countries; 22.7, 11.0, and 9.3% in China, Korea, and Japan, respectively. There was a high similarity in the composition of the parasitoid complex between Korean and Honshu populations but the rates of parasitization were different. The polyphagous B paralella caused significantly higher parasitism in Honshu (18.2%) than in Korea (0.5%). In contrast, H. brunnicornis caused significantly higher parasitism in Korea (8.7%) than in Japan (2.4%). A. fuscicollis and H. brunnicornis, judged to be the most appropriate parasitoids for biological control of AEM moth in the USA, were collected and sent to the USA for release. A. fuscicollis established and is contributing to the control of AEM.     

Effect of a turnip rape <Emphasis Type="Italic">(Brassica rapa)</Emphasis> trap crop on stem-mining pests and their parasitoids in winter oilseed rape <Emphasis Type="Italic">(Brassica napus)</Emphasis>

Concerns about the negative effects of chemical control of oilseed rape (Brassica napus L.) pests on non-target species, human safety, and development of insecticide resistance, require alternative control strategies such as the use of trap crops and biocontrol to be developed. Psylliodes chrysocephala(L.) (Coleoptera: Chrysomelidae) (cabbage stem flea beetle) and Ceutorhynchus pallidactylus (Marsh.) (Coleoptera: Curculionidae) (cabbage stem weevil) are two major stem-mining pests of oilseed rape. This study investigated the phenology of these pests and their main parasitoids in the UK, the potential use of turnip rape (Brassica rapa L.) as a trap crop to reduce oilseed rape infestation, and the effects of insecticide treatment on pest incidence and larval parasitism. Water trap samples, plant dissections and pest larval dissections were done to determine: the incidence of adult pests and their parasitoids, the level of plant infestation by the pests and percentage larval parasitism, respectively. The turnip rape trap crop borders reduced P. chrysocephalabut not C. pallidactylus infestation of oilseed rape plots. Treatment of the trap crop with insecticide had little effect on either pest or parasitoid incidence in the oilseed rape. TersilochusmicrogasterSzép. andT. obscurator Aub. (Hymenoptera: Ichneumonidae) were the main larval parasitoids of P. chrysocephalaand C. pallidactylus, respectively. Tersilochus microgasteris reported for the first time in the UK. The implications for integrated pest management are discussed.     

Effect of <Emphasis Type="Italic">Diachasmimorpha longicaudata</Emphasis> releases on the native parasitoid guild attacking <Emphasis Type="Italic">Anastrepha</Emphasis> spp. larvae in disturbed zones of Chiapas,Mexico

We evaluated the effect of augmentative releases of Diachasmimorpha longicaudata (Ashmead), on the native parasitoid guild of Anastrepha spp. over a two year period in zones adjacent to mango commercial orchards in Chiapas, Mexico. We chose two 15 ha working zones, 15 km apart, harbouring fruit fly hosts of varying densities without chemical control. In 2013, parasitoids were released in zone “A” while zone “B” served as control. In 2014 zones were exchanged. As expected, releases of D. longicaudata significantly increased total parasitism, from around 0.5–5% to over 22%, but annual parasitism by native parasitoids was only significantly affected in zone “A”. The numbers of native parasitoids were higher in zone “A” in both years, and diversity (H′) was not affected by D. longicaudata releases in both zones. Our results suggest that releases of D. longicaudata affect the relative abundance but not the species richness of native parasitoids.     

Phenology and parasitism rates in introduced populations of <Emphasis Type="Italic">Pseudacteon tricuspis</Emphasis>, a parasitoid of <Emphasis Type="Italic">Solenopsis invicta</Emphasis>

We documented patterns of seasonal abundance and rates of parasitism in introduced populations of Pseudacteon tricuspis Borgmeier, a phorid parasitoid of the red imported fire ant, Solenopsis invicta Buren. Adult P. tricuspis populations were censused at monthly intervals for 1 year at three sites in northern Florida. Censuses were conducted by aspirating phorids attracted to disturbed S. invicta mounds. Pseudacteon tricuspis adults were present in every month at all sites, although abundances varied greatly among sites and over time. The highest densities of flies (up to 453 censused at 10 disturbed S. invicta mounds in 30 min) were observed in November, and changes in abundance over time were positively correlated among sites. Sex ratios were usually male biased. Parasitism rates were evaluated by collecting workers from field colonies and monitoring them in the laboratory for evidence of parasitism. Parasitism rates were very low – always less than 1%. The average parasitism rate per colony over 16 colonies and 2 years was 0.058%. No pupariation occurred within the first 8 days of collection, suggesting parasitism by P. tricuspis induced behavioral changes in parasitized workers that precluded such workers from our collections. If so, true field parasitism rates may be several times higher than measured here, yet still low in an absolute sense. These low parasitism rates can be reconciled with observed adult phorid densities by considering the large number of host ants present at the study sites.     

Genetic diversity of the endangered coastal violet <Emphasis Type="Italic">Viola grayi</Emphasis> Franchet et Savatier (Violaceae) and its genetic relationship to the species in subsection <Emphasis Type="Italic">Rostratae</Emphasis>

Viola grayi, a coastal violet, is found on sandy seashores in limited regions in Japan, but not on rocky sea cliffs or in inland areas. This stemmed violet is classified in the subsection Rostratae. Because of recent human activity on sandy seashores, this species is now recorded as endangered. The present status of this species was surveyed and its genetic diversity was analyzed using 17 newly developed simple sequence repeat markers. The results are compared with those for two commonly found inland violet species in the same subsection, V. grypoceras and V. kusanoana. The coastal violet populations showed markedly lower genetic diversity than those of the common species, V. grypoceras, whereas V. kusanoana showed intermediate genetic diversity. About a half of the total genetic variation of V. grayi is found among populations in analysis of molecular variance. In contrast, only less than 25% of the total variation is found among populations for the two common violets. These three species showed a remarkably high inbreeding coefficient, which indicates high inbreeding under natural mating conditions, although these species have both chasmogamous and cleistogamous flowers. In a population-based dendrogram, V. grayi was clustered in a single and concise group, whereas V. grypoceras and V. kusanoana were found in somewhat discrete positions. In the Bayesian analysis of genetic structure of the coastal violet, delta K was the highest at K = 7, and the seven clusters almost correspond to seven populations studied here. Implications of the conservation of this endangered coastal violet are presented.     

The impact of habitat fragmentation on trophic interactions of the monophagous butterfly <Emphasis Type="Italic">Polyommatus coridon</Emphasis>

Theory predicts that habitat fragmentation, including reduced area and connectivity of suitable habitat, changes multitrophic interactions. Species at the bottom of trophic cascades (host plants) are expected to be less negatively affected than higher trophic levels, such as herbivores and their parasitoids or predators. Here we test this hypothesis regarding the effects of habitat area and connectivity in a trophic system with three levels: first with the population size of the larval food plant Hippocrepis comosa, next with the population density of the monophagous butterfly species Polyommatus coridon and finally with its larval parasitism rate. Our results show no evidence for negative effects of habitat fragmentation on the food plant or on parasitism rates, but population density of adult P. coridon was reduced with decreasing connectivity. We conclude that the highly specialized butterfly species is more affected by habitat fragmentation than its larval food plant because of its higher trophic position. However, the butterfly host species was also more affected than its parasitoids, presumably because of lower resource specialization of local parasitoids which also frequently occur in alternative hosts. Therefore, conservation efforts should focus first on the most specialized species of interaction networks and second on higher trophic levels.     

Oviposition Sites of the Cypress Seed Bug <Emphasis Type="Italic">Orsillus maculatus</Emphasis> and Response of the Egg Parasitoid <Emphasis Type="Italic">Telenomus</Emphasis> gr. <Emphasis Type="Italic">Floridanus</Emphasis>

Phytophagous insects have many strategies to escape parasitoids, for example by hiding eggs into plant tissues, but oviposition in holes made by another insect is rather scarce. The cypress seed bug Orsillus maculatus Fieber (Heteroptera: Lygaeidae) is strictly dependent on the availability of cones of Cupressus sempervirens L. to oviposit. Females lay eggs either in exit holes cut through the cone scale by emerging adults of the cypress seed chalcid, Megastigmus wachtli Seitner (Hymenoptera: Torymidae), or on the inner side of scales of partly open cones. A recently discovered egg parasitoid belonging to the genus Telenomus has been shown to attack bug eggs in both oviposition sites. In this paper we investigated the parasitoid performance according to oviposition sites. Field samplings were conducted in two evergreen cypress orchards located in the south of France. The distribution and condition of the egg patches were compared between the two locations and oviposition sites. Seed bugs preferred to oviposit in emergence holes of M. wachtli, and parasitoid performance was higher in eggs laid on cone scales. The chalcid emergence holes seemed to ensure bug eggs with enemy-free space. Oviposition site selection could be an adaptive strategy to escape parasitoid attack.     

Landscape effects on the complex of <Emphasis Type="Italic">Bactrocera oleae</Emphasis> parasitoids and implications for conservation biological control

We studied the parasitoid complex of Bactrocera oleae Rossi (Diptera: Tephritidae) in order to analyse the parasitism response to landscape structure at different spatial extents. Olive fruits were sampled and incubated in the laboratory for insect emergence, thus allowing the calculation of parasitoid emergence rates. A landscape analysis was performed in five concentric buffers, ranging from 0.5 to 2 km diameter around the sampling points. Woodland was chosen as focal class. The percentage of landscape and the splitting index, a measure of fragmentation, were used to quantify landscape composition and configuration, respectively. Significant effects of landscape on parasitism rates were detected. In particular, the percent parasitoid emergence was negatively affected by the splitting index of woodland at a spatial extent ranging from 1 to 2 km. These findings suggest that landscape characteristics are likely to affect parasitoids in well-structured agroecosystems as well. In particular, connectivity at a large scale may favour B. oleae parasitoids more than the abundance of woodland. Potential implications for conservation biological control are discussed.     

Cascading effects of a specialist parasitoid on plant biomass in a <Emphasis Type="Italic">Citrus</Emphasis> agroecosystem

We studied a specialist parasitoid (Coccobius fulvus Compere et Annecke; Hymenoptera: Aphelinidae), its host (the arrowhead scale, Unaspis yanonensis Kuwana; Hemiptera: Diaspididae) and the host plant (Citrus unshiu Marc; Rutaceae) to examine the indirect effects, via host–parasitoid interactions, of the parasitoid on plant biomass. We compared plant biomass and herbivore abundance in a system of two trophic levels (plants and herbivores) with a system of three trophic levels (plants, herbivores and parasitoids) using enclosure experiments in an agricultural setting. Each of eight young Citrus trees was infested with 40 scales and placed in an enclosure. We introduced three female parasitoids into half of the enclosures and monitored temporal changes in scale density and cumulative parasitism for the subsequent 11months. Plant biomass was then compared between treatment groups (parasitoids added) and controls (parasitoids excluded). During the experiment, cumulative parasitism increased rapidly in the parasitoid-addition enclosures to a maximum of 89%, and the number of live scales in the control enclosures was approximately 10-fold that in the treatment enclosures. At the end of the experiment, plant biomass was threefold higher in the parasitoid-addition enclosures than in the control enclosures. These results have two implications for terrestrial communities. First, specialist parasitoids, which are the principal natural enemies of most herbivorous insects, can trigger trophic cascades in the same way that generalist predators can. Second, cascading effects can be detected by observing changes in plant biomass. The latter finding is contrary to recent conclusions about top-down cascades (i.e. that trophic cascades are less likely to be observed when plant biomass, rather than plant damage, is considered as the plant-response variable).     

Selection of Bemisia nymphal stages for oviposition or feeding,and host-handling times of arrhenotokous and thelytokous <Emphasis Type="Italic">Eretmocerus mundus</Emphasis> and arrhenotokous <Emphasis Type="Italic">E. eremicus</Emphasis>

Host-handling behavior is an important aspect of parasitoid foraging behavior. When a parasitoid encounters a potential host, the handling behavior starts with the evaluation of the host and continues if the host has been judged acceptable. Host handling is usually terminated after egg laying or host feeding and host marking. Host-handling behavior of an arrhenotokous population of two Eretmocerus species, E. mundus Mercet and E. eremicus Rose and Zolnerowich, along with a thelytokous population of E. mundus were compared under laboratory conditions. Several elements of host-handling behavior, including encountering, ascending, turning on host, descending, preening, egg laying, and host feeding were recorded. There were no correlations among the durations of these phases across parasitoid populations/species or host nymphal instars. Duration of different phases of host-handling behavior showed only slight and sometimes significant differences between different Eretmoceruspopulations/species. The actual laying of the egg had the longest duration of all host-handling behaviors, and was longer on third nymphal instars than on younger ones. Females of the three populations/species accepted the first three nymphal stages either for egg laying or for host feeding. Females spent a lot of time to make wounds in the host when preparing for host feeding, and eventually killed the host. The implications of these findings for the use of the different Eretmoceruspopulations/species in biological control are discussed.     

Leaf nutrient levels and the spatio-temporal distributions of <Emphasis Type="Italic">Plutella xylostella</Emphasis> and its larval parasitoids <Emphasis Type="Italic">Diadegma insulare</Emphasis> and <Emphasis Type="Italic">Microplitis plutellae</Emphasis> in canola

Seasonal distribution patterns of the diamondback moth, Plutella xylostella (L.) (Lepidoptera: Plutellidae), and its principal parasitoids Diadegma insulare (Cresson) (Hymenoptera: Ichneumonidae) and Microplitis plutellae (Muesebeck) (Hymenoptera: Braconidae) were investigated over three site-years in commercial fields of canola (Brassica napus L.) in southern Alberta, Canada. The sampling of P. xylostella, D. insulare, and M. plutellae from points arranged in grid patterns, together with the mapping and analysis of their spatial distributions over time, generated a detailed picture of the pattern of crop infestation by the herbivore and its parasitoids. Plutella xylostella exhibited significant aggregations on different scales most often when its host plants were in early flowering. Diadegma insulare adults exhibited significant aggregated distributions during early flowering and distributions subsequently became more uniform as the wasps moved into the crop later in the season. However, M. plutellae distributions were aggregated in mid flowering in only one site-year. The close spatial associations between densities of D. insulare and P. xylostella indicated that host abundance was the main determinant of parasitoid distribution patterns. Spatial distributions of nutrient contents in leaf tissue and their spatial associations with the herbivore and parasitoids were also investigated. Significant spatial associations existed between certain nutrients (e.g. nitrogen, sulfur, and potassium) and P. xylostella distributions. Sulfur exhibited a positive effect on the distributions of D. insulare but not of M. plutellae. We observed similar relationships between nutrients and the distribution of P. xylostella parasitoids as for nutrients and P. xylostella, but these relationships lacked consistency and may be the results of the spatial associations between the parasitoids and their hosts. Aggregated distributions of adults and larvae of P. xylostella hold promise for spatially targeted insecticidal applications as a means for reducing the environmental impact of insecticides on nontarget and beneficial species in canola agroecosystems.     

Abundances of five parasitoids attacking the scale insect <Emphasis Type="Italic">Nipponaclerda biwakoensis</Emphasis> on morphologically changed reed shoots due to damage by a stem-boring caterpillar

Abundances of the scale insect Nipponaclerda biwakoensis and its five parasitoids per shoot of the common reed, Phragmites australis, were compared between shoots damaged by a stem-boring caterpillar and undamaged shoots. Reed shoots that were damaged by the stem-borer in spring change morphologically during summer, inducing tillers from the nodes beneath the damaged part. The number of female scales per shoot did not differ significantly between damaged and undamaged shoots in the second scale generation (September), but was significantly lower on damaged shoots in the third generation (November). Three parasitoid species attacking the scale exhibited different responses to the shoot damage, with the response by each parasitoid being constant in the two scale generations: the parasitism rate by Aprostocetus sp. per shoot was higher on damaged shoots, whereas that by Astymachus japonicus was lower on damaged shoots, and no difference was detected for Boucekiella depressa. In the third scale generation, the parasitism rate by Encyrtidae sp. 1 showed no difference, with respect to shoot damage, whereas that by Encyrtidae sp. 2 was lower on damaged shoots. In three dominant parasitoids, shoot damage had no effect on the number of emerging adults per host, and the sex ratio and body size of the adults. The number of emerging adults per shoot differed significantly between damaged and undamaged shoots for four parasitoids, except B. depressa. These results suggest that shoot damage by the stem-borer exerts a delayed negative impact on the scale numbers and affects the parasitism rate of the scales by three parasitoids and the emerging adult numbers of four parasitoids.