菜蚜危害甘蓝防治指标新探讨

本项研究突破了单纯以调查时的蚜量作为防治指标的传统方法引用了"累计蚜量"、"临界危害量"、"有害株"等新概念和新公式。通过试验测定出在亩产3500公斤春甘蓝菜区、菜蚜危害甘蓝的防治指标：苗期有害株率为8-9％;莲座期有害株率为4-5％;包心有害株率为7-8％。     

Intraguild predation on the aphid parasitoid <Emphasis Type="Italic">Aphelinus asychis</Emphasis> by the ladybird <Emphasis Type="Italic">Harmonia axyridis</Emphasis>

We investigated intraguild predation (IGP) on an aphid parasitoid, Aphelinus asychis Walker (Hymenoptera: Aphelinidae), by the multicolored Asian ladybird, Harmonia axyridis (Pallas) (Coleoptera: Coccinellidae), and used the green peach aphid, Myzus persicae (Sulzer) (Hemiptera: Aphididae) as the prey/host in the laboratory. The ladybirds reared on artificial diet and on aphids consumed more aphids than mummies, while those reared on parasitized aphids consumed similar numbers of aphids and mummies. The ladybirds chose more mummies in treatments when mummies were more abundant, and more aphids when numbers of aphids and mummies were equal, or when aphids were more abundant. However, at all density treatments, rejection rates of mummies (36%) were much greater than of aphids (2%). H. axyridis prey on more aphids than A. asychis mummies, which enhances biological control by the two species. However, prior feeding experience affected subsequent choice, increasing the competition between natural enemies which would reduce their combined effectiveness for biological control.     

The assimilation and allocation of nutrients by symbiotic and aposymbiotic pea aphids, Acyrthosiphon pisum

The failure of a nutritionally balanced diet to ameliorate the impact of symbiont disruption in the pea aphid Acyrthosiphon pisum (Harris) was investigated using two approaches. The assimilation of dietary nutrients by aphids was investigated using chemically-defined diets containing ³ H-labelled inulin and ¹⁴C-labelled sucrose or amino acids. Symbiotic aphids (i.e., aphids containing their bacteria) had a high sucrose demand and assimilated 72% of sucrose ingested in the diet, whereas the assimilation of sucrose by aposymbiotic aphids (in which the bacteria had been disrupted), was significantly reduced to 47%. The assimilation of individual dietary amino acids by symbiotic aphids varied between 61 and 92%, and there was no impact on the feeding or assimilation rate when the aphids were fed a phloem sap-like diet containing a reduced amount of essential amino acids. Consequently, the absolute amount of each essential amino acid assimilated by symbiotic aphids feeding on a phloem sap-like diet was reduced by 36–59%. Aposymbiotic aphids consistently assimilated a lower proportion of ingested amino acids, and lysine in particular was poorly assimilated from the diet. In a second experiment, the allocation of free amino acids in the haemocoel to aphid embryos was investigated following microinjection of ¹⁴C-labelled amino acids. After 2 h, radiolabel could be detected at varying levels from the embryo complement of both symbiotic and aposymbiotic aphids, indicating rapid but selective uptake by the embryos. The essential amino acids phenylalanine and lysine were incorporated into the protein fraction of embryo tissues, but the rate of incorporation per unit biomass was approximately 4-fold higher in the embryos of aposymbiotic aphids, possibly reflecting increased demand due to the lack of amino acid provisioning from the symbiotic bacteria.     

Efficiency of herbivore exclusion by ants attracted to aphids on the vetch <Emphasis Type="Italic">Vicia angustifolia</Emphasis> L. (Leguminosae)

The efficiency of herbivore exclusion by ants on the vetch Vicia angustifolia L. (Leguminosae) with extrafloral nectary, mediated by ant attraction to aphids was investigated in a field census and laboratory experiments. In the field, workers of Lasius japonicus Santschi and Tetramorium tsushimae Emery frequently visited plants of the vetch parasitized by aphids of Aphis craccivora Koch, but only a few workers visited plants without aphids. An increase in the number of ants visiting a plant with increasing numbers of aphids caused a decrease in the number of larvae of the weevil, Hypera postica Gyllenhal. Therefore, the efficiency of herbivore exclusion by ants was higher on plants parasitized by Ap.craccivora aphids than that on plants unparasitized by aphids. In the laboratory experiments, L.japonicus workers frequently patrolled not only shoots with Ap.craccivora aphids but also shoots without them. However, T.tsushimae workers visited mainly shoots with Ap.craccivora aphids but less frequently on shoots without aphids. Therefore, L.japonicus workers excluded herbivores more efficiently on plants of the vetch than T.tsushimae workers. Consequently, the efficiency of herbivore exclusion by ants on the vetch can be influenced directly by differences in ant species and indirectly by the presence of aphids on plants. The present study highlights the significance of indirect interactions between ants and plants with extrafloral nectary, mediated by ant attraction to aphids for herbivore exclusion of plants.     

Occurrence of Chaperonin 60 and Chaperonin 10 in primary and secondary bacterial symbionts of aphids: Implications for the evolution of an endosymbiotic system in aphids

Summary All aphids harbor symbiotrophic prokaryotes (primary symbionts) in a specialized-abdominal cell, the bacteriocyte. Chaperonin 60 (Cpn60, symbionin) and chaperonin 10 (Cpn10), which are high and low molecular weight heatshock proteins, were sought in tissues of more than 60 aphid species. The endosymbionts were compared immunologically and histologically. It was demonstrated that (1) there are two types of aphids in terms of the endosymbiotic system: some with only primary symbionts and others with, in addition, secondary symbionts; (2) the primary symbionts of various aphids are quite similar in morphology whereas the secondary symbionts vary; and (3) irrespective of the aphid species, Cpn60 is abundant in both the primary and secondary symbionts, while Cpn10 is abundant in the secondary symbionts but present in small amounts in the primary ones. Based on these results, we suggest that the primary symbionts have been derived from a prokaryote that was acquired by the common ancestor of aphids whereas the secondary symbionts have been acquired by various aphids independently after divergence of the aphid species. In addition, we point out the possibility that the prokaryotes under intracellular conditions have been subject to some common evolutionary pressures, and as a result, have come to resemble cell organelles.     

Antipredator response of pea aphids <Emphasis Type="Italic">Acyrthosiphon pisum</Emphasis> (Hemiptera: Aphididae): effects of predation risks from an alternative patch on a current patch

To escape from predators, herbivorous prey could leave their current patch and relocate to an alternative patch. However, when other predators are present on the new patch, prey are again exposed to predation risk. Thus, patch leaving might be affected by the other predators. We studied patch leaving of pea aphids Acyrthosiphon pisum Harris (Hemiptera: Aphididae) in response to ladybird larvae Harmonia axyridis Pallas (Coleoptera: Coccinellidae) on broad bean Vicia faba L. shoots that were offered as patches for aphids. We tested whether shoot leaving was affected by the presence of predators on alternative shoots under laboratory conditions. Odors from alternative shoots were evaluated as possible cues used by aphids to assess predation risk on the shoots. We exposed aphids to odors from alternative shoots with conspecifics plus either adult or larval ladybirds or larval green lacewings Mallada desjardinsi Navas (Neuroptera: Chrysopidae). Shoot leaving was reduced only when adult ladybirds were present on the alternative shoots compared with controls (i.e., no predators on the alternative shoots). Odors of both adult ladybirds and of conspecifics being attacked by ladybird larvae were required for reduced leaving. Hence, predation risks on current and alternative patches might affect the antipredator responses of aphids.     

Herbivore-induced emissions of maize volatiles repel the corn leaf aphid, shape Rhopalosiphum maidis

When maize plants, Zea mays L., are mechanically damaged and the damaged sites are treated with caterpillar regurgitant, the plants will release a specific blend of volatiles. It is known that these volatiles can be attractive to natural enemies of herbivores. We hypothesise that the plant volatiles constitute part of the induced plant defence and that herbivores will be affected by the odours as well. In laboratory and semi-field studies this hypothesis was tested for the aphid Rhopalosiphum maidis (Fitch) (Rhynchota, Sternorrhyncha, Aphididae).In a Y-tube olfactometer significantly more aphids chose the odour of healthy, undamaged maize seedlings when tested against clean air or plants treated with regurgitant. Clean air was chosen more often when tested next to the odour of treated plants. This apparently repellent effect of the odour of treated plants was significant for winged aphids, but not for the wingless aphids.In field experiments aphids were released in the centre of circles of eight potted maize plants. Four plants in each circle were damaged and treated with caterpillar regurgitant while the other plants were left unharmed. At different intervals after aphid release, the number of aphids was counted on each plant. Significantly fewer winged and wingless aphids were found back on treated plants than on healthy plants.We suggest that herbivores may be repelled by the odours because they could indicate that: 1) the plant has initiated the production of toxic compounds; 2) potential competitors are present on the plant; 3) the plant is attractive to parasitoids and predators. Aphids may be particularly sensitive to induced maize volatiles because one of the major compounds emitted by the plant is (E)--farnesene, which is a common alarm pheromone for aphids. Collections and analyses of the odours emitted by crushed R. maidis confirmed that it too emits (E)--farnesene when stressed. The results are discussed in context of plant defence strategies and their possible exploitation for the control of pest insects.     

The evaluation of the European earwig (Forficula auricularia) as a predator of the damson-hop aphid (Phorodon humuli). II. Choice of prey

Experiments on the European earwig (Forficula auricularia L.) were made determine the efficiency of prey capture and defence reactions of the damson-hop aphid (Phorodon humuli (Schrank)).The older the earwig the more efficient was its search for aphids. Adult aphids waxed early earwig instars successfully. Young earwigs did not choose but encountered and captured young aphids more successfully than older ones, allowing older aphids to reproduce successfully.     

Aphid-symbiotic bacteria cultured in insect cell lines

The cells and tissues of many aphids contain bacteria known as "secondary symbionts," which under specific environmental circumstances may be beneficial to the host insect. Such symbiotic bacteria are traditionally described as intractable to cultivation in vitro. Here we show that two types of aphid secondary symbionts, known informally as T type and U type, can be cultured and maintained in three insect cell lines. The identities of the cultured bacteria were confirmed by PCR with sequencing of 16S rRNA gene fragments and fluorescence in situ hybridization. In cell lines infected with bacteria derived from aphids harboring both T type and U type, the U type persisted, while the T type was lost. We suggest that the two bacteria persist in aphids because competition between them is limited by differences in tropism for insect tissues or cell types. The culture of these bacteria in insect cell lines provides a new and unique research opportunity, offering a source of unibacterial material for genomic studies and a model system to investigate the interactions between animal cells and bacteria. We propose the provisional taxon names "Candidatus Consessoris aphidicola" for T type and "Candidatus Adiaceo aphidicola" for U type.     

Role of plant abundance in determining the abundance of herbivorous insects

Summary The proposal (Gaston and Lawton 1988a, b) that small species of insects are more abundant because they have lower per capita resource requirements than large species does not hold for aphids (Dixon 1990a). There are good theoretical grounds, supported by empirical data, for the suggestion that host specific aphids that live on uncommon plants incur great losses in finding their host plants and as a consequence have a lower realized r _m and are rarer than aphids living on common plants. This is also likely to apply to other organisms that are host specific and time-limited dispersers.     

Inter-Individual Variation and Consistency in Walking Behavior of the Rose Aphid, <Emphasis Type="Italic">Macrosiphum rosae</Emphasis> (Hemiptera: Aphididae)

Variations in morphological and behavioral properties of animals are generally considered as evolutionary adaptations to unpredictable environments. At the same time, individuals may present a strong consistency in their expressed behavior. In this study, we investigated inter-individual variations and consistency in walking behavior of both apterous and winged morphs of the rose aphid, Macrosiphum rosae (L.) (Hemiptera: Aphididae). Adult apterous and winged aphids were released three times on the surface of a corn leaf cut (40 cm × 5 mm) and the time elapsed and the numbers of steps walked by individuals to go through it were recorded. Although, our results revealed a strong consistency in walking speed of both apterous and winged individual aphids, we found a wide variation in walking speed of different individuals for these morphs. These variations were predominantly associated with the differences in the number of steps walked by individual aphids, and less importantly, to their walking speed. Altogether, winged aphids walked with a higher average speed than apterous ones (42.42 vs. 38.92 cm min^?1, respectively) (P < 0.01). This may be an evolutionary adaptation of winged aphids where they should walk actively to find a suitable site for establishment after an unpredictable air-borne flight. We measured the wet body weight of apterous and winged adults to find a correlation between body weight and walking speed. Although, the winged aphids were significantly lighter than apterous ones (P < 0.01), we found no reliable data to correlate the observed variations in walking behavior of rose aphids to their body weight. The importance of this inter-individual variation in the evolutionary biology of clonal aphids has been discussed.     

Effects of reduced rates of two insecticides on enzyme activity and mortality of an aphid and its lacewing predator

By applying insecticides at lower rates of active ingredients per unit area, survival rates of the pests' natural enemies can be enhanced, whereas pest mortality can remain high. The effects of reduced application rates of the insecticides lambda-cyhalothrin and dimethoate on the mortality of bird cherry-oat aphid, Rhopalosiphon padi (L.), and lacewing Micromus tasmaniae Walker were determined in the laboratory and field. Cholinesterase (ChE) and glutathione S-transferase (GST) activities in survivors provided a measure of sublethal effects and general fitness. In the laboratory, lacewings were less sensitive than aphids to both insecticides, and dimethoate was more toxic than lambda-cyhalothrin. However, these results could not be recreated in the field, in part due to very low recapture rates. In summary, lambda-cyhalothrin seemed to have no effect on aphids, but it was toxic to lacewings. Dimethoate was far less toxic in the field, but aphids were still more sensitive than were lacewings. Cholinesterase activity was reduced by dimethoate exposure in the laboratory in both species, but there were species-specific differences. Dimethoate and lambda-cyhalothrin had no effects on GST activity in either species. The high mortality rate for lacewings and aphids exposed to dimethoate in the field suggests that the application rate could be reduced to as low as 10% of that recommended by manufacturers, and this should still be highly efficacious against aphids, while protecting the predatory lacewing. Measurement of enzyme activity could provide a useful indicator of "fitness" of survivors.     

Capacity assessment of <Emphasis Type="Italic">Myzus persicae,Aphis gossypii</Emphasis> and <Emphasis Type="Italic">Aphis spiraecola</Emphasis> (Hemiptera: Aphididae) to acquire and retain PVY<Superscript>NTN</Superscript> in Tunisia

The study was carried out to investigate the ability of three aphids, Myzus persicae, Aphis gossypii and Aphis spiraecola, to acquire and retain the Potato Virus Y (PVY) isolate, PVY^NTN. Tobacco plants, Nicotiana tabacum var. Xanthi, were used as test plant for the virus inoculation and aphid acquisition. The serological test double-antibody sandwich enzyme-linked immunosorbent assay was applied for virus detection on the test plants and aphids. Furthermore, virus retention by aphids was also assessed using a monoclonal anti-PVY^N. Although a duration of 2 min was enough for the virus acquisition, the three tested aphids showed different capacities to retain PVY^NTN. The retention of PVY^NTN was 3 h for M. persicae and A. spiraecola, and 2 h for A. gossypii. This study provides basic information of the virus retention by potato-colonizing aphid species, which may increase our understanding of PVY epidemiology in Tunisia.     

Colors of young and old spring leaves as a potential signal for ant-tended hemipterans

A new hypothesis explaining the adaptive significance of bright autumn leaf colors argues that these colors signal tree quality to myrmecophilous specialist aphids. In turn, the aphids attract aphid-tending ants during the following spring, which defend the trees from other aphids and herbivores. In this context, other types of plant coloration, such as the color change observed in young and old spring leaves, may function as a signal of plant quality for aphids and other myrmecophilous hemipterans. If these plant colors are costly for plants, then vividly colorful plants would be required to invest more in growth than in defense; as a result, colorful plants may be more palatable for honeydew-producing hemipterans, such as aphids, scale insects and treehoppers, although the relative importance of hemipterans other than aphids may be relatively low. These hemipterans may be attracted to colorful plants, after which their attendant ants would protect the plants from herbivory. However, it is necessary to examine color vision in hemipterans to support this hypothesis.Key words: ant-Hemiptera interactions, indirect effects, myrmecophiles, plant-ant mutualism, plant coloration, tritrophic interactionsRecently, the adaptive significance of plant coloration has attracted scientific interest.¹ Various theories have been postulated to explain the adaptive value of autumn leaf colors (red and yellow).² The coevolution hypothesis, the most novel and challenging theory among those proposed, argues that bright leaf colors serve as a conspicuous defense signal against autumn-colonizing insect herbivores, particularly aphids.³ According to this hypothesis, the production of autumn color pigments is an indicator of a particularly vigorous tree. Aphids, which have color vision and have long been associated with trees, migrate to winter host trees in the autumn and cause substantial damage. Therefore, vivid leaf color in the autumn would encourage aphids to colonize other less vigorously defended trees.⁴ Hamilton and Brown³ and Holopainen and Peltonen⁵ detected a higher number of specialist aphids on tree species with more intense autumn colors.After Hamilton and Brown,³ several researchers have attempted to explain the relationship between aphids and autumn color.^2,6 However, they did not account for several possibilities.⁶ First, healthy, vigorous trees may not be well defended, because they invest more in growth than in defense. Second, some aphid species avoid colonizing trees with bright colors, whereas others are attracted to bright colors. Finally, there are numerous multispecific interactions between plants, herbivores, predators and parasitoids in tree crowns. Ants prey on various arthropods living in trees, and ant-aphid mutualism affects arboreal arthropod communities. I incorporated these factors and formed a hypothesis in which autumn leaf colors signal tree quality to myrmecophilous specialist aphids. These aphids, in turn, attract aphid-tending ants during the following spring, which then defend the trees from other aphids and herbivores. Thus, autumn colors may be adaptive, because they attract myrmecophilous specialist aphids and their attendant ants, thereby reducing herbivory and interspecific competition among aphids.⁶In this addendum, I extend my former hypothesis beyond the relationship between autumn leaf colors and aphids. First, myrmecophilous aphids are not the only arthropods that benefit trees. Styrsky and Eubanks⁷ recently reviewed the literature regarding the effects of interactions between ants and honeydew-producing hemipterans on plants, and found that plants actually benefited indirectly from these interactions in most cases. This finding supports a new hypothesis focused on plant-ant mutualism via aphids. In addition, the mutualism between ants and honeydew-producing hemipterans includes many other organisms in addition to aphids, such as scale insects and treehoppers. Scale insects, especially soft scales (Coccidae) and mealybugs (Pseudococcidae), comprise many species that are tended by honeydew-collecting ants,⁸ and ant-scale insect mutualism is often beneficial for host plants.⁷ Although the female adults of scale insects are usually immobile, first-instar nymphs (crawlers) disperse by wind and locate on host plants, usually trees.⁹ The nymphs, emerging at various times from spring to autumn,¹⁰ may use plant coloration to select a suitable host. However, because specialist coccids and mealybugs represent a minority among the speciose scale insects,10 coevolutionary relationships between plants and ants via specialist scale insects may be relatively rare. The treehoppers also comprise many myrmecophilous species,^8,11 but the diversity of this group is highest in tropical regions; only a relatively small number of membracid species are present in temperate regions.¹² Therefore, scale insects and treehoppers may be attracted to autumn colors, and their attendant ants may then defend trees against other herbivorous insects. To fully account for the adaptive value of autumn colors, one would expect the importance of these hemipterans to be less than that of aphids, based on their low host-plant specificity, restricted distribution and life cycles. However, hemipterans may be associated with plant coloration in other aspects than autumn leaf color.Second, the colors of young and old spring leaves may also signal plant quality to ant-tended honeydew-producing hemipterans. The young leaves of many plants are reddish or yellowish (Fig. 1A and B).¹³ In the spring and other seasons, the old leaves of some evergreen tree species turn red or yellow (Fig. 1B). Because changes in leaf color may occur from spring to autumn, various hemipteran species may play specific roles as the season progresses. Aphids migrate in the spring and in the autumn,¹⁴ although most host-alternating aphids migrate to trees in autumn and to herbs in the late spring in temperate regions.¹⁵ If plants pay some cost for these colors¹⁶ and vivid colors indicate high plant quality for hemipterans, then changing colors may attract myrmecophilous hemipterans including aphids, scale insects and treehoppers, which may then protect plants against herbivory by other insects.Open in a separate windowFigure 1(A) Red young leaves of the evergreen oak Quercus glauca. (B) Yellowish young and reddish old leaves of the camphor tree Cinnamomum camphora.However, color vision has not been examined in detail in most hemipteran insects.^17,18 Many insects are insensitive to red, although one species of flower-visiting thrip is specifically attracted to red flowers.¹⁹ Thus, studies on color vision in hemipteran insects are required to evaluate this new hypothesis, as well as the coevolution hypothesis.     

Aphids on ornamental plants from Córdoba, Argentina (Hemiptera: Aphididae)

The quality of the ornamental plants is closely related to their phytosanitary state, that, in turn, is affected by the activity of some insect groups. Aphids are common pests of nearly all kinds of plants, ornamental plants among them. The fauna associated with aphids that colonize ornamental plants includes honey ants (Hymenoptera: Formicidae) that establish mutualistic relations, and some parasitoids (Hymenoptera: Braconidae, Aphidiinae) that contribute to the control of the aphid population. Very little is known about the aphids and their associated fauna living on ornamental plants of Cordoba, Argentina. The goal of this work was to identify the aphids that colonize ornamental plants, as well as their associated honey ants and parasitoids. Samples of sprouts, leaves and/or flowers of aphid-colonized ornamental plants of the Jardín Botánico Municipal of Cordoba city were collected weekly, from October 2003 to November 2004. Whenever found, the associated honey ants and "mummies" of aphids attacked by parasitoids were also collected. One hundred and thirty two aphid-plant associations were registered, 64.4% of which were unknown in the country. In 33.3% of these associations, the aphids were tended by honey ants whereas the presence of aphid parasitoids was registered in 16.7%. Ninety five species of ornamental plants were colonized by 41 aphid species, whereas six ant species tended 10 aphid species. Aphid parasitoids were represented by four species related to 11 aphid species.     

Dynamic host-feeding and oviposition behavior of an aphid parasitoid <Emphasis Type="Italic">Aphelinus asychis</Emphasis>

In order to maximize the lifetime reproductive success of parasitoids, they should be induced to dynamically accept individual hosts that have different suitability for oviposition. Parasitoids tend to exhibit higher host-selective behavior when their egg load is limited, and are less selective if they are facing time constraints. Here, we evaluated the effects of parasitoid age on egg load, fecundity and host instar preference of a honey-fed aphid parasitoid, Aphelinus asychis Walker (Hymenoptera: Aphelinidae). Host selective experiment was conducted to measure host-preference of honey-fed A. asychis females at different ages, using the second and fourth instars of the green peach aphid Myzus persicae as their hosts. The results showed that the choice of host-instar for oviposition was significantly influenced by the parasitoid age. Honey-fed parasitoids in the age groups of 1, 5, 10 and 20 days tended to parasitize predominantly second-instar aphids, whereas 15-days old parasitoids showed no significant preference of host instars. On the other hand, host-feeding preference was not affected by parasitoid age. Parasitoid females of all ages preferred younger aphids to older aphids. This result could help evaluate the effectiveness of A. asychis for biological control of M. persicae when they encountered mixed-instar aphids in the field. In addition, the results might be helpful in assessing the host killing effects of other host-feeding parasitoids.     

Extraction from soil of apterous Pemphigus populitransversus (Hemiptera: Pemphigidae) feeding on cruciferous vegetable roots

The poplar petiolegall aphid, Pemphigus populitransversus Riley (Hemiptera: Pemphigidae), is a gall-forming aphid attacking leaf petioles of Populus spp., its primary hosts. Its secondary hosts are the roots of cruciferous (Brassicaceae) plants, where it is also commonly known as the "cabbage root aphid." The apterous forms are destructive pests of cruciferous vegetables in many parts of the world. In our experiments, the root-feeding apterous forms were extracted from the soil using a Berlese funnel, which drives the aphids downward by using light and heat. The results show that a majority of apterous aphids (96.9%) were extracted from the soil in 2 h by using a 15-W light bulb in the Berlese funnels, whereas only 18.2% of aphids were extracted using a 25-W light bulb in a similar time period. The 25-W light bulb in the funnel generated too much heat (40-44 degrees C), which dried the soil too fast so that the aphids were unable to crawl downward to the collecting jars or killed the aphids directly. The advantages of using a Berlese funnel equipped with a 15-W light bulb as the light and heat source for sampling and extraction of the root feeding aphids include a uniform handling of each sample, less time spent, extraction of many samples at the same time, and storage of the aphids in containers for later counting in the laboratory. This technique seems to also be useful for extracting other mobile, small soil-dwelling arthropods.     

有翅型荻草谷网蚜的田间扩散飞行行为

研制了NJZ06粘性黄纸诱捕器,用于对有翅型荻草谷网蚜Macrosiphum(Sitobion) miscanthi(Takahashi)在田间的扩散行为的试验研究;黄色诱板上诱集的蚜虫以微小昆虫自动计数系统计数;试验在北京郊区麦田中进行。结果显示,距地面120cm的高度诱蚜量最多,平均诱蚜数达到573.0头/板,与其他高度诱蚜量差异显著;面朝南的诱板诱蚜量居各朝向之首,平均诱蚜数272.5头/板。生态因子对有翅蚜的扩散飞行有一定的影响,但不是决定性的。     

Effects of the concurrent exclusion of ants and earwigs on aphid abundance in an organic citrus grove

Based on the well-known mutualism between ants (Hymenoptera: Formicidae) and aphids (Homoptera: Aphididae), we conducted a five-year experiment of ant-exclusion from the canopies of citrus trees as a possible method of biological control of aphids. However, our results showed that the exclusion of ants from the canopies increased, instead of reducing, aphid abundance. To explain this unexpected result, we reasoned that the exclusion of ants from the canopies might also have excluded crawling insects that prey on aphids, such as the European earwig (Forficula auricularia L., Dermaptera: Forficulidae). Such a possibility is supported by the negative relationship between aphid density and the abundance of earwigs, consistent with a top-down control of aphids by earwigs. In contrast, the abundance of other aphid predators (Coleoptera: Coccinellidae, and Heteroptera) had no such negative effect on aphid density but a positive one, suggesting a bottom-up control, and showed no differences between control and ant-excluded trees. Thus, the most likely explanation for the increase in aphid abundance in the ant-excluded trees is the absence of earwigs from the canopies of the experimental trees, providing further evidence of the major role that earwigs play as control agents of aphids in cultivated trees.     

Evaluation of winter wheat as a potential relay crop for enhancing biological control of cotton aphids

A 2-year study was conducted to evaluate the role of winter wheat, Triticum aestivum L., as a potential relay crop to conserve arthropod natural enemies and suppress cotton aphids, Aphis gossypii Glover, in seedling cotton. The results suggested that the natural enemies that moved from the adjacent wheat fields to cotton fields with the maturity and harvest of wheat could keep the cotton aphid population at the edges (0--4 m) of cotton fields under the action threshold of 100 aphids/m². Data also suggested that the wheat strip served as a reservoir to conserve arthropod predators and relayed its predators to cotton when wheat matured and senesced.