Cost-benefits of reduced aphicide usage on dwarf hops susceptible and partially resistant to damson-hop aphid

Soil‐applied imidacloprid at full (125 g a.i. ha^?1) and half approved doses gave levels of control of damson‐hop aphid, (Phorodon humuli), similar to that provided by foliar spray(s) of tebufenpyrad on the aphid‐susceptible dwarf hop cvs First Gold and Herald. On those cultivars, aphid control was unreliable on plots treated with quarter dose imidacloprid and was generally no better than on untreated plants. Aphids were virtually eliminated from the leaves by the end of July each year in all treatments consistent with the action of natural enemies. Aphid contamination of cones reflected the numbers on foliage at flowering time, but varied widely between years. Yields and percentage α‐acids content of dried hops were unaffected by the numbers of aphids on leaves early in the season and in cones at harvest, but aphid contamination reduced the economic values of crops by as much as 80%. Few P. humuli colonised the partially aphid‐resistant breeding line 23/90/08 before their numbers were regulated and consistent with natural enemy activity. Yields, percentage α‐acids content, and commercial value of harvested cones were similar in all treatments on 23/90/08 whether or not plants were treated with aphicides. The commercial risks posed by P. humuli preclude substantial reductions in aphicide usage on aphid‐susceptible dwarf hop cultivars, but future cultivars expressing a similar level of partial resistance to aphids as 23/90/08 should not need treatment with aphicides.     

Distribution of damson-hop aphid (Phorodon humuli) migrants on hops in relation to hop variety and wind shelter

The distribution of migrant Phorodon humuli was studied in two hopgardens during June 1972. Migrants accumulating upon the young tissues near the bines' apices were counted. Plant size affected distribution, 100 % more migrants were found on 2-bine than on single bine strings and there was a positive linear relation between bine height and log₁₀ aphid numbers. Plants surrounding wire-trellis support poles were more heavily infested than plants not at poles, and migrants were more abundant on leeward orientated than windward strings. It is argued that the distribution of alatae reflected local patterns of wind shelter. Differences between plants declined in successive weeks. The influence of hop variety on migrant settling was studied in one of the hop-gardens. Fewer migrants settled on the variety Tolhurst than on Northern Brewer, and Fuggle was intermediate. Part, but not all, of the difference between varieties was explained by the larger average size of Northern Brewer plants. The observed aphid deposition rates in the two hop gardens were compared with hypothetical deposition rates calculated from numbers of P. humuli caught in a nearby 12-2 m Rothamsted Insect Survey suction-trap, and used to estimate flight durations. The estimates indicated that most infestation probably resulted from aphids within 1 h flying time of their primary host source.     

Survival, growth, and reproduction of two aphid species on sucrose solutions containing host or non-host honeydews

Aphids, like most phloem-feeding insects, commonly exhibit a high degree of host specificity. Plant-specific chemical compounds are likely to serve as important host selection cues for monophagous aphids and such substances could be present in aphid honeydew. Apterous virginoparae ofMyzus persicae (Sulzer) andPhorodon humuli (Schrank) were reared on a buffered sucrose solution containing various aphid honeydews or a mixture of amino acids. In two separate experiments, the host-specificP. humuli (hop aphid) could grow and reproduce only on diets containing honeydew collected from hop (Humulus lupulus L.).M. persicae (the green peach aphid, GPA) did not perform well on diets containing hop honeydew, perhaps because hop is a poor GPA host. Honeydew collected from preferred GPA host plants rape,Brassica napus L., and jimsonweed,Datura stramonium L., allowed GPA growth and reproduction. Hop aphids, however, performed poorly on rape and jimsonweed honeydew diets. Bell pepper,Capsicum annuum L., honeydew supported neither the hop aphid nor GPA. The study of aphid honeydew components may contribute towards a more complete understanding of host preference and selection phenomena in aphids.     

Host plant recognition in monophagous weevils: Specialization ofCeutorhynchus inaffectatus to glucosinolates from its host plantHesperis matronalis

Several aphid honeydews were incorporated into sucrose solutions and presented to hop aphids, Phorodon humuli (Schrank), as artificial diets in free-choice bioassays. Small additions of honeydew collected from two species of aphid feeding on hop, Humulus lupulus L., arrested the searching behavior of the hop aphid and appeared to stimulate prolonged periods of ingestion. This effect was more dependent on the host plant honeydew source than the species of aphid that produced the honeydew. Aphid honeydews collected from plants other than hop (non-hosts to P. humuli) contained hop aphid phagostimulants that were less effective. Our results indicate that analysis of aphid honeydew could help describe chemical cues involved in the recognition of appropriate host plants by aphid species.     

Behavior and Population Development of <Emphasis Type="Italic">Phorodon humuli</Emphasis> (Schrank) (Homoptera: Aphididae) on Two Hop Cultivars of Different Susceptibility

The two hop cultivars “Hallertauer Magnum” (HM) and “Spalter Select” (SE) are regarded by growers as extremely different in their susceptibility to the damson-hop aphid Phorodon humuli (Schrank). To investigate these anecdotal observations, spring migration and initial population development of P. humuli were monitored on the two cultivars in 1998 and 1999 in an experimental hop garden. Numbers of migrant aphids on SE were significantly lower, comprising 18.8 and 30.2% as compared to HM in 1998 and 1999, respectively. Population development of apterous aphids on these two cultivars differed significantly. At the end of the monitoring period numbers of aphids on SE were 7.5 and 14.2% as compared to HM in 1998 and 1999, respectively. In behavioral studies of P. humuli alates released on glasshouse plants, those on SE spent significantly more time in motile behavior patterns than aphids on HM. In the glasshouse, population development also differed significantly and the number of aphids developing on SE was 12.9% of that on HM after 28 days. It is concluded that SE exhibits a certain repellent effect on P. humuli and, compared to HM, is possibly nutritionally less suitable to the aphid.     

Susceptibility of hop to Phorodon humuli

A portion of the USDA World Hop (Humulus lupulus L.) Germ Plasm Collection was screened for antibiosis to the hop aphid, Phorodon humuli (Shrank). Hop aphid development and reproduction on the retained accessions 58016, 21090M, 21211, 21240, and 60038 were then compared to hop aphids reared on the commercial hop cultivars (cvs) L-8, Perle, Chinook, Galena, Eroica, Willamette, and Cascade. In general, hop aphids matured faster and reproduced more on the commercial cvs than on 21090M, 58016, 21211, or 21240. Accession 60038, of note because it supported unusually high numbers of aphids during screening, was found to be the most susceptible of any hop tested. Mortality and natality schedules were then combined to construct matrix models of aphid population growth on 60038, 58016, Cascade, and Perle (the most and least susceptible noncommercial and commercial hops, respectively). Beginning with one one-day-old nymph per leaf, the models predicted that P. humuli would require 24 days to surpass an action threshold of 100 aphids per leaf on 58016. This was seven days longer than on the susceptible Cascade and five days longer than on Perle. A commercial hop with the antibiosis of 58016 would probably require fewer insecticide applications during the growing season, thus retarding the development of insecticide resistance in P. humuli and enhancing the effectiveness of integrated management programs by protecting beneficial insects.

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Zusammenfassung Ein Teil der Genbank des USDA von Hopfen (Humulus lupulus L.) wurde auf Resistenz gegen Phorodon humuli (Shrank) getestet. Dabei wurden die besonders widerstands fähigen Klone 58016, 21090M, 21211, 21240 sowie Klon 60038, der ungewöhnlich viele Blattläuse ertrug, ausgewählt. Anschließend wurde die Entwicklung und Vermehrung der Blattläuse auf den ausgewählten Klonen und auf den Handelssorten (cvs) L-8, Perle, Chinook, Galena, Eroica, Willamette, Cascade untersucht. Im Allgemeinen entwickelten sich die Blattläuse auf den Handelssorten reascher und vermehrten sich stärker als auf den resistenten Klonen. Klon 60038 war dagegen die anfälligste Sorte. Mortalitäts- und Natlitätsdaten wurden kombiniert um Matrixmodelle des Populationswachstums der Blattläuse auf 60038, 58016, Cascade und Perle (die am meisten und am wenigsten anfälligen kommerziellen und nichtkommerziellen Sorten) zu konstruieren. Die Modelle begannen bei 1 Larve pro Blatt und sagten voraus, dass die Aktionsgrenze von 100 Tieren pro Blatt auf 58016 nach 24 Tagen erreicht wird. Das ist 7 Tage später als auf den anfälligen Sorten Cascade und 5 Tage später als auf Perle. Eine kommerzielle Sorte mit der Anfälligkeit von 58016 würde vermutlich während der Vegetationszeit weniger Insektizidspritzungen benötigen. Damit würde die Resistenzentwicklung bei Phorodon humuli verlangsamt und die Wirkung von IPM Programmen durch Schutz der natürlichen Feinde verbessert.

     

Influence of hop yard ground flora on invertebrate pests of hops and their natural enemies

A 3‐year study in Washington State, USA examined the influence of hop yard ground flora both on the invertebrate pests of hops [including hop aphid (Phorodon humuli Schrank), two‐spotted spider mite (Tetranychus urticae Koch) and hop looper (Hypena humuli Harris)] and on their natural enemies. Each year half of the experimental plots were sown with a mixture of ‘insectary’ plants [including California poppy (Eschscholzia californica von Chamisso), dwarf cornflower (Centaurea cyanus L.) and buckwheat (Fagopyrum esculentum Moench)]. Season‐long average cover provided by the flowering mixture ranged from 2% to 26%, with some blooms being present for most of the season in each year. In terms of vegetation, the other main differences between cover‐cropped and control plots were in the proportions of bare soil (which was always significantly higher in control plots) and the percentage of Chenopodium album L., which was significantly higher in the cover‐cropped plots in two of the three seasons. Populations of spider mites on hop foliage were significantly lower in cover‐cropped plots than in control plots in 2 of 3 years, while mite numbers in the cones at harvest were generally low and usually did not differ between treatments. Responses of hop aphids were much more variable, with no consistent treatment effect on either leaf or cone infestations. Larval populations of hop looper tended to be higher in cover‐cropped plots in the first two generations, but usually not in the third (final) generation. Of the beneficial invertebrates, spiders and nabids consistently reached higher average densities in the ground flora of cover‐cropped plots than in control plots in all 3 years, while anthocorids, geocorids and parasitic hymenoptera reached higher mean densities in the former plots in 2 of 3 years. Adult coccinellids were higher in cover‐cropped plots only in 2006.     

The development of an action threshold for cabbage aphid (Brevicoryne brassicae) in oilseed rape in the UK

Replicated small plot field experiments were done at two sites growing winter oilseed rape (ADAS Boxworth, Cambridgeshire and ADAS High Mowthorpe, North Yorkshire) and two sites growing spring oilseed rape (ADAS Bridgets, Hampshire and ADAS Rosemaund, Herefordshire) to investigate the effect of cabbage aphid (Brevicoryne brassicae) on crop yield and quality. All four sites were included in the first 2 yr of the experiment in 1994 and 1995 but only those with winter oilseed rape were continued into the final year in 1996. Plots were artificially inoculated with cabbage aphids at either five aphid 4 m^-2 or 5 aphids 16 m^-2 or left uninoculated to become naturally infested. In 1995 and 1996 the naturally infested treatment was omitted. Sprays of the aphicide pirimicarb at GS 3.3, 3.7, 4.5, 4.9 and 5.5 were used to manipulate aphid populations. Once a plot had been treated at a target growth stage it was sprayed on all subsequent occasions to prevent recolonisation. Aphid numbers were assessed prior to each spray date and their effect on the crop measured in terms of yield of seed and oil and glucosinolate content. Artificial inoculation of aphids was often successful in establishing different populations of the pest at a range of growth stages. Results showed that cabbage aphid sometimes reduced both crop yield and quality. Yield responses to insecticide treatment tended to be larger in spring oilseed rape than in winter oilseed rape mainly because it became more heavily infested at an early growth stage. Tentative thresholds are proposed for control of the pest in both winter and spring oilseed rape. It is stressed that cabbage aphid is a sporadic pest and rarely likely to reach these threshold levels in field crops.     

Within‐plant distribution of Phorodon humuli (Hemiptera: Aphididae) and natural enemies on hops with implications for sampling and management

A field trial was performed on a hop yard throughout 2006, 2007 and 2008 in order to analyze the within‐plant distribution of Phorodon humuli (Schrank) and its natural enemies. The aphid population was higher on the leaves of the middle section of the main stem. Specifically, the population was significantly higher at 2 and 3.25 m than at 6 m during the three years. Natural enemies consisted of aphidophagous predators of which Coccinella septempunctata was recorded in the highest number. Its number was greater where the aphid population was higher, with a significantly higher number of eggs, larvae and adults at 2 and 3.25 m than at 6 m. Lacewing eggs were also frequently observed, with a significantly higher population where the number of aphids was higher. The number of winged aphids was higher at 3.25 m than at 2 m within a plant. Understanding hop aphid distribution within the hop canopy is important in developing sampling programs, in evaluating injury and helps the development of sustainable management practices.     

Electrical penetration graphs of the damson-hop aphid, Phorodon humuli on resistant and susceptible hops (Humulus lupulus)

Electrical penetration graphs (EPG's) were used to locate resistance to Phorodon humuli (Schrank) (Homoptera, Aphididae) in hops (Humulus lupulus, Cannabinaceae). Aphids on those hops showing resistance had a much reduced E2 pattern (uptake of phloem). In addition, many aphids on the resistant plants spent time non-probing within two minutes of withdrawing from the phloem. This was not observed with aphids on susceptible hops. The results suggest that resistance is located in the phloem. The involvement of a mechanical factor such as the blocking of aphid stylets, the presence of antinutritional factors, or simply an inadequate supply of nutrients, are discussed as possible resistance mechanisms.     

The role of Anthocoris species (Hemiptera: Anthocoridae) in the integrated control of the damson-hop aphid (Phorodon humuli)

Field studies in 1974, 1975 and 1976 investigated integrated control of the damson-hop aphid Phorodon humuli on hops. After the aphicidal effects of an early-season soil drench of mephosfolan had declined, natural enemies controlled the aphids for the remainder of the season. Anthocorid bugs, particularly Anthocoris nemoralis, were the most abundant predators. In each year a rapid decline in aphid numbers occurred in mid- to late-July, coinciding with the peak numbers of fourth and fifth instar larvae and adults, the most voracious anthocorid stages. Aphids in the cones remained under control for the rest of the season in 1974 and 1975, and increased in 1976 but damaging numbers did not develop. When predators were excluded by caging mephosfolan-treated bines, high aphid densities developed on the leaves, and the cones were heavily infested. Plants not treated with an insecticide were almost completely defoliated by late-July. Heavily infested ‘missed bines’, due to uneven uptake of mephosfolan, attracted large numbers of anthocorids, which later dispersed into the surrounding plants.     

Intercropping oilseed rape as a potential relay crop for enhancing the biological control of green peach aphids and aphid‐transmitted virus diseases

Tobacco viruses transmitted by green peach aphids, Myzus persicae (Sulzer) (Hemiptera: Aphididae), cause severe disease in flue‐cured tobacco, Nicotiana tabacum L. (Solanaceae), in China and throughout the world. Field experiments were conducted in 2016 and 2017 in Longyan City, Fujian Province, China, to determine whether M. persicae and aphid‐transmitted virus diseases are affected by intercropping of oilseed rape, Brassica napus L. (Brassicaceae), in tobacco fields. The results showed that, compared with those in monocultured fields, the densities of M. persicae and winged aphids in intercropped fields significantly decreased in both 2016 and 2017. In particular, the appearance of winged aphids was delayed by ca. 7 days. Moreover, the densities of Aphidius gifuensis Ashmead (Hymenoptera: Aphidiidae), a parasitoid of the aphid, significantly increased in 2016 and 2017. Accordingly, the incidence rates of aphid‐transmitted virus diseases (those caused by the cucumber mosaic virus, potato virus Y, and tobacco etch virus) significantly decreased in the intercropped fields in 2016 and 2017. Tobacco yields and monetary value significantly increased in 2016 (by 10–25 and 14–29%, respectively) and 2017 (by 17–22 and 22–34%, respectively). Consequently, our results suggest that intercropping oilseed rape in tobacco fields is a good approach to regulating and controlling aphids and tobacco mosaic viruses, for example potyvirus, and this intercropping can help control aphid‐transmitted virus diseases in tobacco.     

油菜田害虫调查及蚜虫防治药剂筛选

田间调查试验表明,合肥市油菜田害虫的发生种类有15种,主要害虫为蚜虫类、油菜潜叶蝇Phytomyza horticola、小菜蛾Plutella maculipennis和菜青虫Pieris rapae。其中,以蚜虫类危害最重,全生育期在冬、春季各有一个峰值。油菜苗期以萝卜蚜、小菜蛾危害较重,后期以桃蚜Myzus persicae、油菜潜叶蝇危害较重。蚜虫防治药剂筛选试验表明,70%吡虫啉水分散粒剂防治蚜虫药效高,持效期长,且对油菜安全,10%烯啶虫胺可溶液剂和25%吡蚜酮可湿性粉剂防效也较好,可作为70%吡虫啉水分散粒剂的轮换药剂。     

Evaluation of airborne methyl salicylate for improved conservation biological control of two-spotted spider mite and hop aphid in Oregon hop yards

The use of synthetic herbivore-induced plant volatiles (HIPV) to attract natural enemies has received interest as a tool to enhance conservation biological control (CBC). Methyl salicylate (MeSA) is a HIPV that is attractive to several key predators of two-spotted spider mite, Tetranychus urticae Koch (Acari: Tetranychidae), and hop aphid, Phorodon humuli (Schrank) (Homoptera: Aphididae). A 2-year study was conducted to evaluate the recommended commercial use of MeSA in hop yards in Oregon. Slow-release MeSA dispensers were stapled to supporting poles in 0.5 ha plots and these plots were compared to a paired non-treated plot on each of three farms in 2008 and 2009. Across both years, there was a trend for reduced (range 40–91%) mean seasonal numbers of T. urticae in five of the six MeSA-baited plots. Stethorus spp., key spider mite predators, tended to be more numerous in MeSA-baited plots compared to control plots on a given farm. Mean seasonal densities of hop aphid and other natural enemies (e.g., Orius spp. and Anystis spp.) were similar between MeSA-treated and control plots. Variability among farms in suppression of two-spotted spider mites and attraction of Stethorus spp. suggests that the use of MeSA to enhance CBC of spider mites in commercial hop yards may be influenced by site-specific factors related to the agroecology of individual farms or seasonal effects that require further investigation. The current study also suggests that CBC of hop aphid with MeSA in this environment may be unsatisfactory.     

Winter wheat (Triticum aestivum) response to Barley yellow dwarf virus at various nitrogen application rates in the presence and absence of its aphid vector,Rhopalosiphum padi

Barley yellow dwarf (BYD) is one of the most common diseases of cereal crops, caused by the phloem‐limited, cereal aphid‐borne Barley yellow dwarf virus (BYDV) (Luteoviridae). Delayed planting and controlling aphid vector numbers with insecticides have been the primary approaches to manage BYD. There is limited research on nitrogen (N) application effects on plant growth, N status, and water use in the BYDV pathosystem in the absence of aphid control. Such information will be essential in developing a post‐infection management plan for BYDV‐infected cereals. Through a greenhouse study, we assessed whether manipulation of N supply to BYDV‐infected winter wheat, Triticum aestivum L. (Poaceae), in the presence or absence of the aphid vector Rhopalosiphum padi L. (Hemiptera: Aphididae), could improve N and/or water uptake, and subsequently promote plant growth. Similar responses of shoot biomass and of water and N use efficiencies to various N application rates were observed in both BYDV‐infected and non‐infected plants, suggesting that winter wheat plants with only BYDV infection may be capable of outgrowing infection by the virus. Plants, which simultaneously hosted aphids and BYDV, suffered more severe symptoms and possessed higher virus loads than those infected with BYDV only. Moreover, in plants hosting both BYDV and aphids, aphid pressure was positively associated with N concentration within plant tissue, suggesting that N application and N concentration within foliar tissue may alter BYDV replication indirectly through their influence on aphid reproduction. Even though shoot biomass, tissue N concentration, and water use efficiency increased in response to increased N application, decision‐making on N fertilization to plants hosting both BYDV and aphids should take into consideration the potential of aphid outbreak and/or the possibility of reduced plant resilience to environmental stresses due to decreased root growth.     

Habitat variation,mutualism and predation shape the spatio‐temporal dynamics of tansy aphids

1. Spatially distributed resources can lead to the formation of metapopulations, where individual subpopulations are often small and can experience frequent local extinction events followed by recolonisation. An example of terrestrial metapopulations are specialised phytophagous insects on their patchily distributed host plants. 2. The present study investigated the population dynamics of a specialised aphid (Metopeurum fuscoviride) on its patchily distributed host plant (Tanacetum vulgare) and associated community of mutualistic ants and predators in a small‐scale field site. Furthermore, aphid habitat differences (plant size, C/N ratio, location and surrounding vegetation) were quantified, and seasonal timing and precipitation were considered. 3. Seasonal timing and precipitation both had effects on aphid colonisation, extinction events and aphid colony persistence. Towards the end of the season, and after higher precipitation, aphid colonisation events decreased and extinction events increased. Plant size and location as well as aphid within‐field dispersal determined the spatio‐temporal distribution of aphid colonies. 4. Mutualistic ants (Lasius niger and Myrmica rubra) increased the chance of establishment of aphid colonies. However, when M. rubra was tending, aphid colony persistence was reduced. Aphid persistence and extinction were dependent on aphid abundance, as a higher colony size reduced the probability of extinction by predation. 5. The results emphasise the importance of dispersal limitation, population growth and the presence of mutualists when studying the spatio‐temporal dynamics of tansy aphids, particularly in a small‐scale field site.     

Temporal and spatial variability of rosy apple aphid Dysaphis plantaginea populations: is there a role of the alternate host plant Plantago major?

• 1 The rosy apple aphid Dysaphis plantaginea (Passerini) (Homoptera: Aphididae) is a pest of economic importance to the apple industry worldwide, particularly in organic apple orchards where no acceptable controls are available. In the Similkameen Valley of British Columbia, Canada, the rosy apple aphid population size varies widely between orchards and between years. To explain this variation, potential environmental correlates of aphid density were evaluated. The architecture of the alternate host was also evaluated for its effect on rosy apple aphid summer survival and reproduction.
• 2 The percentage of trees infested by rosy apple aphids among orchards was in the range 8–94% for trees having at least one cluster with more than ten aphids in 2007 and in the range 0–39% in 2008.
• 3 A general linear model correlating aphid densities to the environmental variables of abundance of the alternate host (plantain Plantago spp.), foliar nitrogen, tree age and planting density, and reduced by stepwise regression, indicated that foliar nitrogen and tree age explained 33% of the variation. Abundance of the summer, alternate food plant, plantain, was not related to later aphid densities on apple trees.
• 4 Plantain architecture, however, influenced aphid numbers and 25‐fold more aphids were found on low‐lying plantain leaves than on more upright leaves. Experimental manipulation of leaf angle and leaf size showed that significantly more aphids occurred on low angle, large leaves. Finally, mowing that encouraged low lying plants prior to spring aphid migration was associated with a four‐fold greater number of both winged and wingless aphids on the plantain.

     

Assessment of aphid lethal paralysis virus as an apparent population growth‐limiting factor in grain aphids in the presence of other natural enemies

The influence of aphid lethal paralysis virus (ALPV), Rhopalosiphum padi virus (RhPV), natural enemies and fungal infection on the population growth of Rhopalosiphum padi and Sitobion avenae in the wheat fields of the Western Cape Province of South Africa was investigated at two sites. Time‐specific life tables were compiled for R. padi at one site. During the logarithmic phase of the development of R. padi aphids, natural enemies were not present in high numbers and the apparent large‐scale mortality observed appeared to be due to other causes. During the decline phase of this aphid population, the population size was reduced by 49%. This reduction coincided with a calculated high mortality of 70 aphids per plant. A dramatic decline in R. padi numbers and a high incidence of ALPV present in the aphid population was experienced during this period. Virus assays were carried out by double‐antibody sandwich enzyme‐linked immunosorbent assay (DAS‐ELISA) and an indirect immunofluorescent technique. Entomophthorales‐type fungal infection of aphids also reached its highest level during the decline phase, but at a later stage than ALPV infection, with a calculated level of 21 aphids per plant. This suggested that the presence of ALPV limited population development in R. padi. Similar results were obtained with S. avenae.     

Interactions of elevated carbon dioxide and temperature with aphid feeding on transgenic oilseed rape: Are Bacillus thuringiensis (Bt) plants more susceptible to nontarget herbivores in future climate?

Climate change factors such as elevated carbon dioxide (CO₂) and temperature typically affect carbon (C) and nitrogen (N) dynamics of crop plants and the performance of insect herbivores. Insect‐resistant transgenic plants invest some nutrients to the production of specific toxic proteins [i.e. endotoxins from Bacillus thuringiensis (Bt)], which could alter the C–N balance of these plants, especially under changed abiotic conditions. Aphids are nonsusceptible to Lepidoptera‐targeted Bt Cry1Ac toxin and they typically show response to abiotic conditions, and here we sought to discover whether they might perform differently on compositionally changed Bt oilseed rape. Bt oilseed rape had increased N content in the leaves coupled with reduced total C compared with its nontransgenic counterpart, but in general the C : N responses of both plant types to elevated CO₂ and temperature were similar. Elevated CO₂ decreased N content and increased C : N ratio of both plant types. Elevated temperature increased C and N contents, total chlorophyll and carotenoid concentrations under ambient CO₂, but decreased these under elevated CO₂. In addition, soluble sugars were increased and starch decreased by elevated temperature under ambient but not under elevated CO₂, whereas photosynthesis was decreased in plants grown under elevated temperature in both CO₂ levels. Myzus persicae, a generalist aphid species, responded directly to elevated temperature with reduced developmental time and decreased adult and progeny weights, whereas the development of the Brassica specialist Brevicoryne brassicae was less affected. Feeding by M. persicae resulted in an increase in the N content of oilseed rape leaves under ambient CO₂, indicating the potential of herbivore feeding itself to cause allocation changes. The aphids performed equally well on both plant types despite the differences between C–N ratios of Bt and non‐Bt oilseed rape, revealing the absence of plant composition‐related effects on these pests under elevated CO₂, elevated temperature or combined elevated CO₂ and temperature conditions.     

The effect of increasing dosage of barley yellow dwarf virus on some resistant and susceptible barleys

Five spring barleys, grown either in pots out of doors or in the field, were inoculated with barley yellow dwarf virus (BYDV) using 5, 10, 20 or 50 infective aphids (Rhopalosiphum padi) per plant. Control plants of each variety received no aphids. Infection with all aphid numbers had highly significant adverse effects on all varieties except Cb 1029, an early maturing BYDV-resistant barley of Ethiopian origin. 12583 Co, a locally bred, late maturing barley possessing the same resistance gene as Cb 1029 suffered more in a pot experiment, but less than three susceptible varieties all of which were severely damaged even when few infective aphids were used. Progressive effects with increasing aphid numbers, indicative of dosage response, occurred in some varieties. These effects included delay in heading and increased stunting, but not less yield. In Cb 1029, BYDV infection caused a reduction in the number of heads per plant, but this was partly compensated for by an increase in the number of grains per head. Conversely, BYDV infection in 12583 Co caused an increase in the number of heads, partly offset by a decrease in the number of Brains tier head.