Automatic mass-rearing of Amblyseius womersleyi (Acari: Phytoseiidae)

Using incorporated devices, Tetranychus urticae spider mites were rinsed from hydroponically-grown lima bean plants, collected, separated and blow-dried. This yielded a reliable and large volume of eggs and larvae, which were fed to Amblyseius womersleyi rearings on 15×5cm² polyethylene arenas. Of several feeding regimes tested, daily feeding of 10mg T. urticae eggs and larvae resulted in the highest predator population levels. The best harvest period was between 15 and 27 days, when predator density exceeded 600 mites per arena. A preliminary automatic mass-rearing device was tested for A. womersleyi. This incorporated both rearing and harvesting procedures. A micro-feeder was developed to supply the required volume of spider mites and maize pollen (1:1 mixture) to the predators. A Bakelite rearing arena reduced the space requirements of a polyethylene arena, was more durable and an essential component in the automatic mass-rearing and harvesting. Mite harvesting is carried out through the use of a vacuum-head harvester. Supplements of (sterilized) spider mites, pollen, vermiculite and wheat bran are automatically added to the predators. The devices for harvesting, filling and packing are incorporated and synchronized and the entire system is controlled by a single slide-switch. The design and system can be expanded without changing the basic processes and program, for example to adopt it for other species of predaceous mites.     

A New Finding of a the Predatory Mite,Amblyseius californicus (Acari: Phytoseiidae) in Jeju,Korea

Predatory mites in the Family of Phytoseiidae (Acari) are important components in mite biological control. Until now, a native predatory mite, Amblyseius womersleyi has been a subject of intensive studies for implementation of spider mite biological control in fruit orchards, while imported Phytoseiulus persimilis has been successfully implemented in greenhouse environments since 2002. Because of some ecological constraints of A. womersleyi as well as the field environments, spider mite biological control by A. womersleyi has not been successfully implemented. Therefore, demands for another feasible mite predator have increased. This paper reports a newly found predatory mite, Amblyseius californicus, known also as Neosiulus californicus from Jeju citrus orchards. This is the first record of field occurrence of this species in Korea. Some ecological characteristics of this species useful for biological control are also discussed.     

Geographic distribution of phytoseiid mite species (Acari: Phytoseiidae) on crops in Okinawa,a subtropical area of Japan

We extensively identified phytoseiid mites co‐occurring with spider mites on crops throughout the islands of Okinawa, southwestern Japan to obtain fundamental information for controlling spider mites in the area using natural enemies. Of the 19 species found, three were new to Japan and eight were new to Okinawa. Neoseiulus womersleyi was the most common species with respect to the distribution range. Following N. womersleyi, six species including Amblyseius eharai were common, whereas N. californicus was not, suggesting that the recent change in dominant species from N. womersleyi to N. californicus observed on the main islands of Japan had not happened in Okinawa. On one small island (Tarama Island) located in the southwestern part of Okinawa, N. womersleyi was not found, and instead N. longispinosus, which is morphologically similar to N. womersleyi and has not been found in Japan, occurred. This suggests interisland differences in the relative frequencies of N. womersleyi and N. longispinosus in Okinawa.     

Influence of dispersal from almonds on the population dynamics and acaricide resistance frequencies of spider mites infesting neighboring cotton

Neighboring almond and cotton fields were sampled for spider mites in four locations in the San Joaquin Valley of California. The dominant species in the almonds wasTetranychus pacificus McGregor. In three cotton sites.T. pacificus was present in significantly higher densities near the almonds on at least one sampling date. In contrast.T. urticae Koch andT. turkestani Ugarov & Nikolski were equally abundant across the cotton fields. Almonds appeared to act as a continuous early-season source ofT. pacificus for cotton, with peaks in aerial dispersal from almonds occurring due to overcrowding, plant water stress, and applications of repellent acaricides. Cotton, which experienced little water stress, supported very high densities of spider mites and so acted primarily as a sink for spider-mite dispersal from almonds and other field crops throughout the growth-season. The frequencies of resistance expressed byT. pacificus andT. urticae were similar between neighboring crops, even if the acaricide had been registered for use only in almonds (cyhexatin) or cotton (dicofol). Thus, longterm acaricide selection and movement of spider mites between the two crops resulted in similar proportions of resistant individuals. In these study sites, large-scale dispersal ofT. pacificus from almonds rarely directly affected acaricide efficacy in cotton, because resistance frequencies were similar for spider mites from the two crops and because acaricide applications were usually made in cotton after dispersal from almonds was completed. In two cotton sites, field selection with dicofol was reversed by subsequent immigration of spider mites from neighboring field crops.     

Potential lethal and non-lethal effects of predators on dispersal of spider mites

Predators can affect prey dispersal lethally by direct consumption or non-lethally by making prey hesitate to disperse. These lethal and non-lethal effects are detectable only in systems where prey can disperse between multiple patches. However, most studies have drawn their conclusions concerning the ability of predatory mites to suppress spider mites based on observations of their interactions on a single patch or on heavily infested host plants where spider mites could hardly disperse toward intact patches. In these systems, specialist predatory mites that penetrate protective webs produced by spider mites quickly suppress the spider mites, whereas generalist predators that cannot penetrate the webs were ineffective. By using a connected patch system, we revealed that a generalist ant, Pristomyrmex punctatus Mayr (Hymenoptera: Formicidae), effectively prevented dispersal of spider mites, Tetranychus kanzawai Kishida (Acari: Tetranychidae), by directly consuming dispersing individuals. We also revealed that a generalist predatory mite, Euseius sojaensis Ehara (Acari: Phytoseiidae), prevented between-patch dispersal of T. kanzawai by making them hesitate to disperse. In contrast, a specialist phytoseiid predatory mite, Neoseiulus womersleyi Schicha, allowed spider mites to escape an initial patch, increasing the number of colonized patches within the system. Our results suggest that ants and generalist predatory mites can effectively suppress Tetranychus species under some conditions, and should receive more attention as agents for conservation biological control in agroecosystems.     

Population structure of the predatory mite <Emphasis Type="Italic">Neoseiulus womersleyi</Emphasis> in a tea field based on an analysis of microsatellite DNA markers

The predatory mite Neoseiulus womersleyi (Schicha) (Acari: Phytoseiidae) is an important natural enemy of the Kanzawa spider mite, Tetranychus kanzawaki Kishida (Acari: Tetranychidae), in tea fields. Attraction and preservation of natural enemies by habitat management to reduce the need for acaricide sprays is thought to enhance the activity of N. womersleyi. To better conserve N. womersleyi in the field, however, it is essential to elucidate the population genetic structure of this species. To this end, we developed ten microsatellite DNA markers for N. womersleyi. We then evaluated population structure of N. womersleyi collected from a tea field, where Mexican sunflower, Tithonia rotundifolia (Mill.), was planted to preserve N. womersleyi. Seventy-seven adult females were collected from four sites within 200 m. The fixation indexes F _ST among subpopulations were not significantly different. The kinship coefficients between individuals did not differ significantly within a site as a function of the sampling dates, but the coefficients gradually decreased with increasing distance. Bayesian clustering analysis revealed that the population consisted of three genetic clusters, and that subpopulations within 100 m, including those collected on T. rotundifolia, were genetically similar to each other. Given the previously observed population dynamics of N. womersleyi, it appears that the area inhabited by a given cluster of the mite did not exceed 100 m. The estimation of population structure using microsatellite markers will provide valuable information in conservation biological control.     

Migration of specialist insect predators to exploit patchily distributed spider mites

It is believed that specialist predators of spider mites often migrate by flight or aerial transport to exploit patchily distributed prey. The migration is an important factor in determining the seasonal occurrence of the predators in a field. Several species of specialist insect predators, such as Oligota kashmirica benefica (Coleoptera: Staphylinidae) and Scolothrips takahashii (Thysanoptera: Thripidae), migrate between orchard trees and plants near the trees (e.g., groundcover, weeds, or windbreaks) to exploit abundant spider mites. This migration is at least partly triggered by prey scarcity in the original local habitats. Although these predators are tiny insects, they have flight abilities. For example, adult O. kashmirica benefica (body length, ∼1 mm) could move at least 5–16 m in one flight. Presumably, migration of the insect predators between prey-infested plants occurs mainly by flights. Predatory mites, such as Amblyseius fallacis and Amblyseius womersleyi (Acari: Phytoseiidae), migrated to spider mite-infested plants outside an orchard by aerial transport when they suffered from prey scarcity in the orchard. S. takahashii can use plant volatiles from lima bean plants induced by the spider mite Tetranychus urticae as cues for prey location during migration in Satsuma mandarin groves. However, it remains unknown how far from the trap boxes S. takahashii could respond to herbivore-induced plant volatiles in the groves. Received: August 25, 2000 / Accepted: February 1, 2001     

Species composition and arthropod pest feeding of phytoseiid mites in a Japanese pear greenhouse

A population survey of spider mites and phytoseiid mites was conducted on Japanese pear leaves in a greenhouse. For the survey, the method to estimate phytoseiid mite species composition using quantitative sequencing was modified to be applicable for phytoseiid mite species inhabiting in the greenhouse. Results show the dominant appearance of Neoseiulus californicus (McGregor), Neoseiulus womersleyi (Schicha), and Neoseiulus makuwa (Ehara) from the end of June to late September and their contribution in spider mite control. PCR-based method to detect the ribosomal internal transcribed spacer (ITS) sequences of spider mites from phytoseiid mites was developed. The method shows sensitivity to detect the ITS sequences of Tetranychus urticae Koch from single N. californicus adult at 168 h after ingestion of the spider mite. PCR-based method to detect the cytochrome c oxidase subunit I sequences of several arthropod pests belonging to Hemiptera, Thysanoptera, and Acari from phytoseiid mites was also developed. Results show that phytoseiid mites prey on Eriophyes chibaensis (Kadono) and Aphis gossypii (Glover), in addition to spider mites.     

Functionally different predators break down antipredator defenses of spider mites

Prey that lives with functionally different predators may experience enhanced mortality risk, because of conflicts between the specific defenses against their predators. Because natural communities usually contain combinations of prey and functionally different predators, examining risk enhancement with multiple predators may help to understand prey population dynamics. It is also important in an applied context: risk enhancement with multiple biological control agents could lead to successful suppression of pests. We examined whether risk enhancement occurs in the spider mite Tetranychus kanzawai Kishida (Acari: Tetranychidae) when exposed to two predator species: a generalist ant, Pristomyrmex punctatus Mayr (Hymenoptera: Formicidae), and a specialist predatory mite, Neoseiulus womersleyi Schicha (Acari: Phytoseiidae). We replicated microcosms that consisted of spider mites, ants, and predatory mites. Spider mites avoided generalist ants by staying inside their webs on leaf surfaces. In contrast, spider mites avoided specialist predatory mites that intruded into their webs by exiting the web, which obviously conflicts with the defense against ants. In the presence of both predators, enhanced mortality of spider mites was observed. A conflict occurred between the spider mites’ defenses: they seemed to move out of their webs and be preyed upon by ants. This is the first study to suggest that risk enhancement occurs in web‐spinning spider mites that are exposed to both generalist and specialist predator species, and to provide evidence that ants can have remarkable synergistic effects on the biological control of spider mites using specialist predatory mites.     

Arrestment response of the predatory mite Amblyseius longispinosus to Schizotetranychus nanjingensis webnests on bamboo leaves (Acari: Phytoseiidae, Tetranychidae)

The response of the predatory mite Amblyseius longispinosus (Acari: Phytoseiidae) to the webnest of the spider mite nanjingensis (Acari: Tetranychidae) was examined using two-choice tests in the laboratory. A. longispinosus females were found significantly more often on leaves with webnests than on leaves without webnests and were often observed searching under the webbing. Because spider mites and their eggs were removed from the webnests before experiments, predators responded to stimuli associated with webbing, mite feeding damage and other residues in the webnests.     

Kanzawa spider mites acquire enemy‐free space on a detrimental host plant,oleander

Studies have proposed that predators of herbivores suffer significant fitness losses from the defense chemicals of host plants, and that herbivores adapted to these chemicals may experience reduced predation risk when residing on such plant species. We examined the effects of oleander, Nerium indicum Mill. (Apocynaceae), a host plant of the spider mite, Tetranychus kanzawai Kishida (Acari: Tetranychidae), on their prime predator, Neoseiulus womersleyi (Schicha) (Acari: Phytoseiidae), and tested the hypothesis that this host plant provides enemy‐free space. At the study sites, T. kanzawai occurred on oleander shrubs; in contrast, although N. womersleyi was present in the area, no individuals were found on oleander. Tetranychus kanzawai feeding on oleander negatively affected the settlement, development, and egg production of N. womersleyi. The lower egg production was a result of both the direct effects of oleander and the indirect effects via T. kanzawai. Previous studies showed that the fitness of T. kanzawai in the presence of N. womersleyi was lower than that in the absence of the predator, and lower on oleander than on other palatable host plant species in the absence of predators. Our findings suggest that N. womersleyi may not be able to invade T. kanzawai patches on oleander shrubs, which results in the fitness of T. kanzawai being higher on oleander than on other host plant species in the same area when N. womersleyi is present. This supports the hypothesis that T. kanzawai acquires enemy‐free space on oleander using the direct and indirect adverse effects of oleander on their predators as major defense mechanisms.     

Do spider mite-infested plants and spider mite trails attract predatory mites?

We questioned the well-accepted concept that spider mite-infested plants attract predatory mites from a distance. This idea is based on the preference demonstrated by predatory mites such as Phytoseiulus persimilis Athias-Henriot (Acari: Phytoseiidae) for volatiles produced by spider mite-infested plants in a closed environment (Y-tube wind tunnel). However, in natural open environments, kidney bean leaves heavily infested with Tetranychus urticae Koch (Acari: Tetranychidae) did not attract P. persimilis from the same distances as were used in the Y-tube tests. Therefore, the attraction of predatory mites for spider mite-infested plant volatiles in the Y-tube tests may reflect a preference in a closed environment and should be carefully interpreted as a basis for extrapolating predator–prey attraction mechanisms in the wild. On the other hand, we showed that adult female P. persimilis could follow trails laid down by adult female T. urticae in the laboratory and in natural open environments. Consequently, we propose that following spider mite trails represents another prey-searching cue for predatory mites.     

Predatory mirids of the green apple aphidAphis pomi,the two-spotted spider miteTetranychus urticae and the European red mitePanonychus ULMI in apple orchards in Québec

The incidence of predation of eight species of predacious mirids (Hemiptera: Miridae) present in an apple orchard of Québec on the green apple aphid, two-spotted spider mite and European red mite were investigated. The daily consumption rates varied from 1–2 green apple aphids forHyaliodes vitripennis Say andCampylomma verbasci Meyer to 7–9 aphids forDeraeocoris fasciolus Knight andLepidopsallus minisculus Knight.H. vitripennis consumed significantly more mites than the other mirid species with 26 and 18 mites per day for the two-spotted spider mite and the European red mite respectively. The combined use ofH. vitripennis andL. minisculus is suggested for the control of phytophagous mites. This paper is contribution No. 335/91.06.02R, Research Station, Agriculture Canada, Saint-Jean-sur-Richelieu, Québec, Canada.     

Conditioned olfactory responses of a predatory mite, Neoseiulus womersleyi, to volatiles from prey-infested plants

To clarify the prey‐finding behavior of the predatory mite Neoseiulus womersleyi (Schicha) (Acari: Phytoseiidae), we studied its olfactory responses to volatiles from the prey‐infested plant on which the mites had been collected. We used a local N. womersleyi population called Kanaya collected from tea (Camellia sinensis L.) (Theaceae) plants infested by Tetranychus kanzawai Kishida (Acari: Tetranychidae) in Kanaya City, Japan. Neoseiulus womersleyi (Kanaya population) were more attracted to volatiles from tea plants infested with five female T. kanzawai per leaf for 7 days than to intact tea leaves in a Y‐tube olfactometer. Tetranychus kanzawai‐induced tea leaf volatiles were identified as (E)‐β‐ocimene, (E)‐4,8‐dimethyl‐1,3,7‐nonatriene, and (E,E)‐α‐farnesene. As olfactory responses are known to differ among local populations of N. womersleyi, we compared the responses of the Kanaya population with those of a Kikugawa population collected from tea plants infested by T. kanzawai in Kikugawa City. To test the influence of previous predation experience, we reared the two populations on tea plants infested by T. kanzawai or on kidney bean plants (Phaseolus vulgaris) infested by Tetranychus urticae Koch. The Kanaya population was more attracted to the volatiles from infested plants on which they had been reared. Because the Kanaya population was not attracted to the plant volatiles they had not previously experienced, the positive response to previously experienced volatiles might be the result of learning. By contrast, the Kikugawa population showed no preference for previously experienced volatiles from infested plants. The implications of this flexibility in foraging behavior are discussed.     

The predatory mite <Emphasis Type="Italic">Neoseiulus womersleyi</Emphasis> (Acari: Phytoseiidae) follows extracts of trails left by the two-spotted spider mite <Emphasis Type="Italic">Tetranychus urticae</Emphasis> (Acari: Tetranychidae)

As it walks, the two-spotted spider mite Tetranychus urticae Koch (Acari: Tetranychidae) spins a trail of silk threads, that is followed by the predatory mite, Neoseiulus womersleyi Schicha (Acari: Phytoseiidae). Starved adult female N. womersleyi followed T. urticae trails laid down by five T. urticae females but did not follow a trail of one T. urticae female, suggesting that the amount of spun threads and their chemical components should correlate positively with the number of T. urticae individuals. To examine whether chemical components of T. urticae trails are responsible for the predatory mite’s trail following, we collected separate T. urticae threads from the exuviae and eggs, and then washed the threads with methanol to separate chemical components from physical attributes of the threads. Female N. womersleyi did not follow T. urticae trails that had been washed with methanol but contained physical residues, but they did follow the direction to which the methanol extracts of the T. urticae trails was applied. These results suggest that the predatory mite follows chemical, not physical, attributes of T. urticae trails.     

Predation by Allothrombium pulvinum on the spider mites Tetranychus urticae and Amphitetranychus viennensis: Predation Rate, Prey Preference and Functional Response

The deutonymphs of Allothrombium pulvinum Ewing (Acari: Trombidiidae) are among the most important natural enemies of spider mites in North, North East and West Iran. In this study, maximum predation rate and preference experiments were conducted with A. pulvinum deutonymphs on apple leaf discs, to determine their preference for either of two spider mite species: Amphitetranychus viennensis (Zacher) and Tetranychus urticae Koch (Acari: Tetranychidae). Maximum predation rate tests showed that the predatory mite consumed more eggs and females of T. urticae than of A. viennensis. Furthermore, the Manly’s preference index for eggs and females of T. urticae confirmed that T. urticae were the preferred prey. The functional response of A. pulvinum deutonymphs on females of T. urticae was examined over a 24-h period. Predation of A. pulvinum deutonymphs presented with females of T. urticae followed a type III functional response. Estimated handling time for the predatory mites was 4.51 h and attack coefficient b, which describes the changes in attack rate with prey densities in a type III functional response, was 0.021.     

Attraction of a generalist predator towards herbivore-infested plants

The occurrence and strength of interactions among natural enemies and herbivores depend on their foraging decisions, and several of these decisions are based on odours. To investigate interactions among arthropods in a greenhouse cropping system, we studied the behavioural response of the predatory bug Orius laevigatus (Fieber) (Hemiptera: Anthocoridae) towards cucumber plants infested either with thrips (Frankliniella occidentalis (Pergande) (Thysanoptera: Thripidae)) or with spider mites (Tetranychus urticae Koch (Acari: Tetranychidae)). In greenhouse release-recapture experiments, the predatory bug showed a significant preference for both thrips-infested plants and spider mite-infested plants over clean plants. Predatory bugs preferred plants infested with spider mites to plants with thrips. Experience with spider mites on cucumber leaves prior to their release in the greenhouse had no effect on the preference of the predatory bugs. However, this experience did increase the percentage of predators recaptured. Y-tube olfactometer experiments showed that O. laevigatus was more attracted to odours from plants infested with spider mites than to odours from clean plants. Thus, O. laevigatus is able to perceive odours and may use them to find plants with prey in more natural conditions. The consequences of the searching behaviour for pest control are discussed.     

Voluntary Falling in Spider Mites in Response to Different Ecological Conditions at Landing Points

We examined voluntary-falling behaviour by adult females of the two-spotted spider mite Tetranychus urticae Koch (Acari: Tetranychidae) and one of its major predators Neoseiulus californicus McGregor (Acari: Phytoseiidae). Experiments were conducted using a setup in which mites could only move onto one of two landing points by falling. Significantly more T. urticae females fell onto available food leaves compared to non-food or heavily infested leaves, whereas significantly fewer females fell onto leaves with the predatory mite N. californicus compared to leaves without the predator. This suggests that spider mites can actively choose on which patch to land on the basis of food quality and predation risk on the patch. Using the same experimental setup, starved N. californicus females never fell, suggesting that falling T. urticae females gain the potential advantage of predator avoidance.     

Developmental times and oviposition rates of predatory mitesTyphlodromus pyri andAmblyseius andersoni (Acari: Phytoseiidae) reared on different foods

The developmental times and the reproduction of two resistant Italian strains ofTyphlodromus pyri Scheuten andAmblyseius andersoni (Chant) were studied in the laboratory by rearing them on the spider mitesPanonychus ulmi (Koch) andEotetranychus carpini (Oud.), on the eriophyidColomerus vitis (Pgst.) and on pollen ofMesembryanthemum criniflorum. The response ofT. pyri andA. andersoni females to a spider mite supply (P. ulmi orE. carpini) of 4, 8 and 16 adult female prey per female predator per day was also studied.Development ofT. pyri onE. carpini andC. vitis required a shorter period than onM. criniflorum pollen, while intermediate values were recorded forP. ulmi. When the highest number of prey was offered, the influence of different foods on oviposition rates ofT. pyri was not significant. An increase in spider mite supply favoured a shorter pre-oviposition period and higher oviposition rates.Development ofA. andersoni was faster on pollen than on spider mites, while intermediate values were found concerningC. vitis. Differences statistically significant were recorded for development onP. ulmi andC. vitis. Colomerus vitis proved to be the more suitable food in terms of oviposition. The oviposition rate decreased when feeding uponP. ulmi, but reached intermediate values onE. carpini andM. criniflorum. Increasing spider mite densities caused shorter pre-oviposition times and higher oviposition rates. Using a given number ofE. carpini females, rather than those ofP. ulmi, resulted in higher oviposition rates and shorter pre-oviposition times.For both predators, the results suggest a higher intrinsic rate of population increase onE. carpini orC. vitis than onP. ulmi.The research was supported by a grant from Regione Veneto (Lotta biologica ed integrata nel controllo di insetti ed acari dannosi).The general lines of the research have been planned by C. Duso. The authors contributed equally to the experimental work.     

Which predatory mite can control both a dominant mite pest,Tetranychus urticae,and a latent mite pest,Eotetranychus asiaticus,on strawberry?

After biological control of Tetranychus urticae using Phytoseiulus persimilis, a latent mite pest, Eotetranychus asiaticus, was found on strawberries growing in a plastic greenhouse in western Japan. To determine whether the release ofP. persimilis, an exotic natural enemy of T.urticae, enhanced the occurrence of the latent pest, the efficiency of P. persimilis in controlling E.asiaticus was compared with the efficiency of two indigenous phytoseiid mites, Amblyseius californicus and A. womersleyi, under laboratory conditions. Phytoseiuluspersimilis and A. californicus attacked not onlyT. urticae but also E. asiaticus. However, the predators produced very few eggs and their offspring rarely reached adulthood when fed on E. asiaticus, so their potential as control agents for the latent mite appears to be low. In contrast, A.womersleyi feeding on E. asiaticus reproduced as well as when fed on T. urticae, and exterminated both species of spider mite. This suggests that A. womersleyihas greater potential as a biological control agent in crops where both species may occur. This revised version was published online in August 2006 with corrections to the Cover Date.