Comparison of the Efficacy of Entomopathogenic Nematodes for the Biological Control of the Mushroom Pests Lycoriella auripila (Sciaridae) and Megaselia halterata (Phoridae)

The efficacy of different species of entomopathogenic nematodes was tested against larvae of the mushroom phorid Megaselia halterata (Diptera: Phoridae) and the mushroom sciarid Lycoriella auripila (Diptera: Sciaridae). Sciarid larvae originating from infestations in casing soil during colonization by Agaricus bisporus were almost completely controlled by applications of Steinernema feltiae to the casing soil. When larvae originated from infestations in freshly spawned compost, they could be controlled by compost applications halfway through spawnrunning and by very early casing treatments. The control of phorids in compost was maximally 31% when nematodes were mixed within the infested compost at a concentration of 3 106 nematodes/m2. Only slightly higher reduction rates were obtained at higher concentrations. The control of phorids was more promising in the infested casing layer, in which S. carpocapsae was most successful. At concentrations of 6 and 15 106 nematodes/m2 this species obtained reduction rates of 65 and 73% respectively when it was applied 3 days after the end of the infestation period. These concentrations are, however, too high for practical application.     

Control of the mushroom pests Lycoriella auripila (Diptera: Sciaridae) and Megaselia halterata (Diptera: Phoridae) by Steinernema feltiae (Nematoda: Steinernematidae) in field experiments

The nematode Steinernema feltiae (Nematoda: Steinemematidae) was tested for its ability to control two main mushroom pests i.e. the sciarid Lycoriella auripila (Diptera: Sciaridae) and the phorid Megaselia halterata (Diptera: Phoridae) in growing-rooms filled with spawned compost. A clear difference between female and male sciarid control was observed. A nematode application 1 day after casing preceded by an application 1 day before casing on the compost caused an almost complete control (97%) of the F1-generation of female sciarids. The F2-generation of females was similarly controlled (95%) by an application 7 days after casing. A dosage of 1 × 10⁶nematodes m^-2was found to be equally effective as higher dosages. Diflubenzuron remained active throughout entire the cropping period with high sciarid mortality rates varying from 72% to 99%. Phorid control was variable and seemed to depend on the presence of sciarids. In one occasion the control rate of F2-generation phorid larvae was 75% and was possibly caused by the presence of new infective juvenile nematodes recycled in F2-generation sciarid larvae. Diflubenzuron did not significantly reduce phorid numbers.     

Susceptibility of mushroom pests to the insect-parasitic nematodes Steinernema feltiae and Heterorhabditis heliothidis

The potential of two species of insect-parasitic rhabditid nematodes (Steinernema feltiae, Heterorhabditis heliothidis) for biological control of mushroom flies was studied in pot trials. Three Diptera that commonly infest mushroom crops were used; the larvae of Megaselia halterata (Phoridae), Heteropeza pygmaea (Cecidomyiidae) and Lycoriella auripila (Sciaridae) were all susceptible to parasitism by both nematode species. Fewer adult phorids and sciarids emerged when compost was nematode-treated and, for L. auripila, the effects of nematode applications at spawning, casing or on both occasions were compared. Casing treatments were more effective than spawning treatments; little extra benefit was gained from applying the nematodes twice. Populations of paedogenetic larvae of H. pygmaea built up rapidly in untreated compost, but were reduced when S. feltiae was applied, and were eradicated by H. heliothidis. Because they can penetrate insect cuticle, as well as natural body openings, Heterorhabditis spp. may be more suitable than Steinernema spp. for the control of mushroom fly larvae.     

Comparative Assessment of biological (Nematoda: Steinernema feltiae) and chemical methods of control for the mushroom fly Lycoriella auripila (Diptera: Sciaridae)

The sciarid fly Lycoriella auripila is the major pest of mushrooms cultivated in the UK. Its larvae, which are capable of damaging the crop at all stages of production, may cause severe yield losses and can only be controlled with chemical pesticides. An indigenous isolate of the insect‐parasitic nematode Steinemema feltiae was tested as a biological control agent and its effects compared with two commonly used insecticides, diazinon and diflubenzuron. The timing of application of nematodes was found to affect their efficacy. When applied to compost during spawning, nematodes did not significantly reduce fly emergence, but they did if applied at casing when they were almost as effective as diflubenzuron. Diazinon incorporated into compost did not reduce fly emergence and was also the only treatment that did not lower the incidence of mushrooms spoiled by tunnelling of the larvae of L. auripila. When compared with untreated control plots those treated both with diazinon and diflubenzuron showed significant mean losses in yield of 10% in total weight and 17% in total numbers of mushrooms picked. In contrast, when S. feltiae was applied at casing significant mean increases in yield of 7% and 19%, respectively, were attained. Infective nematodes persisted well in casing, very few were found on sporophores.     

Effects of Application Rates of Steinernema feltiae (Nematoda: Steinernematidae) on Biological Control of the Mushroom Fly Lycoriella auripila (Diptera: Sciaridae)

The potential of Steinernema feltiae for the biological control of Lycoriella auripila was tested in commercial mushroom‐growing conditions. The nematodes, applied at rates of 1.5, 3, 6 or 12 x 10 ⁶ infective juveniles per 34 kg tray of spawn‐run compost, were mixed into the casing material before it was spread over the compost surface. When compared with untreated control trays, any rate of nematode application significantly reduced fly emergence. Insecticides significantly reduced mushroom yields; nematodes significantly increased them. At a rate of 3 x 10 ⁶ infectives/tray S. feltiae elicited mean total increases in the weight and numbers of mushrooms produced of 8% and 11% respectively. The nematodes also reduced the incidence of mushrooms spoiled by tunnelling sciarid larvae. The early decline in the numbers of nematodes persisting in casing was a trend that was reversed later, when evidence was obtained that S. feltiae was recycling in insects that had been killed. When applied at a rate of 3 ‐10⁶infectives/tray of compost S. feltiae should provide reliable and cost‐effective biological control of L. auripila.     

Biological control of glasshouse sciarid flies (Bradysia spp.) with the predatory mite,hypoaspis miles on cyclamen and poinsettia

The predatory mite Hypoaspis miles was released from laboratory cultures into young crops of pot‐grown cyclamen and poinsettia in six small glasshouses. Five different rates of release were used together with a control house. In both crops, rates of 55 mites per pot and above gave satisfactory control of glasshouse sciarids with no later resurgence of the pest. Mites persisted on the pots until the end of the trial, probably feeding on a residual population of sciarids. In separate tests H. miles was found mostly in the top 1 cm of compost and persisted in horticultural compost for up to 7 weeks in the absence of food.     

Effects of Entomopathogenic Nematodes on Control of a Mushroom-infesting Sciarid Fly and on Mushroom Production

The entomopathogenic nematodes Steinernema feltiae (Biosys strain #27) and Heterorhabditis heliothidis were evaluated for the larval control of a mushroom-infesting sciarid, Lycoriella mali, and for the effects of these nematodes on mushroom (Agaricus bisporus) production. In a series of small-scale mushroom crops, infective-stage H. heliothidis and S. feltiae were applied to the mushroom casing surface in the irrigation water or incorporated into the casing material at densities ranging from 28 to 1120 and 11 to 1120 nematodes cm-2 of casing surface respectively. The mortality of L. mali larvae ranged from 52 to 100% for H. heliothidis and 38 to 100% for S. feltiae. Both nematode species reduced mycelial coverage on the casing surface at primordia initiation. Neither mushroom strain (off-white or white hybrid) or method of application (incorporation into or irrigation onto the casing surface) altered the effect on mycelial coverage. The nematodes's negative effect on mycelial growth confounded the benefit of fly control. At high nematode densities (up to 1120 nematodes cm-2), damage-free mushroom yields for the first week of harvest were less than those from the untreated control. However, at lower nematode densities, at or below 140 cm-2, the nematodes had less effect on mushroom growth, and consequently, damage-free mushroom yields for the first week of harvest were frequently greater than those from the untreated control. In the absence of flies, the first-week mushroom yield generally declined with increasing nematode densities for both white and off-white mushroom hybrids. After 4 weeks of harvest, accumulated mushroom yields had nearly recovered from the earlier decline.     

Susceptibility of larvae of the mushroom fly Megaselia halterata to the entomopathogenic nematode Steinernema feltiae in bioassays

Bioassays were initially conducted in Petri-dishes to screen the efficacy of four Heterorhabiditis and Steinernema species against the mushroom phorid Megaselia halterata. Control rates of 61 to 70% control were obtained at a dosage of 1500 infective juveniles (IJs) per 30 larvae. In order to avoid stress-induced susceptibility, an improved bioassay system in micro-wells, filled with 0.6 ml of compost agar and 0.2 of compost colonized by Agaricus bisporus, was developed. In a screening of different species of Heterorhabiditis and Steinernema with applications of 30 IJs per phorid larva, a highest parasitization rate of 20% was obtained with S. feltiae. Bioassays were continued with S. feltiae in dosage-mortality assays in which larvae of the sciarid Lycoriella auripila and the phorid M. halterata were challenged. At the lowest dosage of 30 IJs per sciarid larva, 78% control was obtained. Increasing the dosage from 30 to 1000 led to only small increases of the phorid mortality. At 1000 IJs per larva a significant mortality of 18% was obtained. The nature of the substrate, compost or casing did not greatly influence the parasitization rates. The sex ratio of nematodes that were able to penetrate and establish in the phorid larvae appeared to be female-skewed. Males were only present at a mean of 19%. Low susceptibility of the phorid larva was ascribed to the inaccessibility of its small mouth opening.     

Propensity towards cannibalism among Hypoaspis aculeifer and H. miles, two soil-dwelling predatory mite species

In biological control programmes, the two predatory soil mites Hypoaspis aculeifer and H. miles are often applied against soil-borne pests like mushroom flies, springtails and mites. Although the mites show high consumption rates on varying prey types in Petri dish experiments and in greenhouses, their overall efficiency is sometimes limited. We hypothesized that intraspecific interactions, like cannibalism, could contribute to this decreased competence. Therefore, experiments were conducted to show the propensity of H. aculeifer and H. miles to cannibalise. Adult mites and nymphs were introduced as predators with conspecific eggs, larvae, nymphs, adult females or males as prey and the number of killed individuals was recorded. Additionally, the oviposition rate on conspecific prey was quantified and the correlation with the number of prey consumed was calculated to assess the influence of cannibalism on egg production. The results illustrate that cannibalism occurs infrequently in both Hypoaspis spp., the only exception being H. aculeifer nymphs, which cannibalised one conspecific egg per day. Moreover, cannibalism never occurred in the presence of alternative prey. Oviposition rate decreased during the experiment in both species but it was positively correlated with the cannibalism rate only for H. aculeifer. The benefit of cannibalism for populations of H. aculeifer and H. miles is discussed.     

Phoretic relationship between the myceliophagous mite Microdispus lambi (Acari: Microdispidae) and mushroom flies in Spanish crops

We studied the role played by the phorid Megaselia halterata (Wood) and the sciarid Lycoriella auripila (Winnertz) in the phoretic dispersion of the myceliophagous mite Microdispus lambi (Acari: Pygmephoridae). Twenty‐four crops were monitored during 18 months in commercial mushroom farms in Castilla‐La Mancha (Spain). Adults of both species were collected weekly and the mites they carried were counted and identified. Both phorids (19.6%) and sciarids (4.4%) carried the mite M. lambi. The calculated load of each was 3.4 M. lambi mites per phorid and 1.9 per sciarid. The same percentage of male and female phorid was used as vector, but the load was slightly higher for females (1.86 mites per female compared with1.48 mites per male). A mean of 7.2% of the phorids examined in winter were vectors of M. lambi, while in spring and autumn of the first year the average was more than 22%. The mean load did not vary significantly between seasons. Inside the mushroom farms, less than 10% of a small initial population of phorids carried mites (less than two mites per phorid). As the cycle progressed, more than 35% of a larger population of emerging flies did so (average 3.5 mites per phorid vector). At the end of the growth cycle, the flies may fly off to colonise nearby farms, favouring the propagation of M. lambi from infested to uninfested crops. Megaselia halterata is the principal vector of M. lambi in the mushroom farms of Castilla‐La Mancha due to their high numbers, the high percentage carrying mites and the number of M. lambi they carry.     

Prey preference and life tables of the predatory mite Parasitus bituberosus (Acari: Parasitidae) when offered various prey combinations

Parasitus bituberosus Karg (Acari: Parasitidae) is one of the predatory mite species inhabiting mushroom houses. It is known to accept a wide range of prey, suggesting that it may be a promising candidate for the biological control of key pests of mushroom culture. In our study it did not show any prey preference among four groups of small organisms often occurring in mushroom growth medium, namely rhabditid nematodes, pygmephorid mites, and sciarid and phorid fly larvae. Nevertheless, the type of food these predators fed on affects their development. The shortest egg-to-adult development time was obtained on a nematode diet. On a diet of phorid larvae, mite development stopped at the deutonymph stage; none reached adulthood. All other diets sufficed to reach the adult phase. Female fecundity when fed nematodes and sciarid larvae did not differ, but it was much lower when fed pygmephorid mites. Other life table parameters confirmed that pygmephorid mites constituted the worst diet for P. bituberosus. The highest intrinsic rate of population increase (r _m  = 0.34) was obtained on the nematode diet; when fed sciarid larvae and pygmephorid mites it was 0.25 and 0.14, respectively. Our study provides good reasons to further test P. bituberosus as biocontrol agent of especially sciarid flies and nematodes, especially when the compost is well colonized by mushroom mycelium (which retards nematode growth).     

Combining plant- and soil-dwelling predatory mites to optimise biological control of thrips

The efficiency of a natural enemy combination compared to a single species release for the control of western flower thrips (WFT) Frankliniella occidentalis (Pergande) on cucumber plants was investigated. Since a large part of F occidentalis seems to enter the soil passage, a joint release of the plant-inhabiting predatory mite Amblyseius cucumeris (Oudemans) that feeds on thrips first-instar larvae and the soil-dwelling predatory mite Hypoaspis aculeifer (Canestrini) that preys on thrips pupae in the ground might offer a promising approach for a holistic control strategy. Therefore, two sets of experiments were conducted in cooperation with a commercial vegetable grower where the plants in plots were infested with a defined number of larval and adult F occidentalis. Two species of natural enemies were released either synchronously or solely, and their efficacy was compared to control plots devoid of antagonists. In both experiments, the predatory mites were released twice with a density of 46 A. cucumeris/m2, and 207 H. aculeifer/m2 (low-density) in the first experiment and 528 H. aculeifer/m2 (high-density) in the second one. Population growth of all arthropod species on the plants and in the soil was quantified at regular intervals and included all soil-dwelling mites and alternative preys present in the substrate. The results showed that H. aculeifer alone had a significant impact on thrips population development only when released at high-densities, but competence was lower compared to the other antagonist treatments. The impact of A. cucumeris alone and A. cucumeris & H. aculeifer combined was similar. Thus, the pooled exploitation of natural enemies did not boost thrips control compared to the single species application of A. cucumeris (non-additive effect), which could be explained by resource competition between both predatory mite species. Species number and population size in the soil of the experimental plots both showed a high variability, a possible consequence of their interaction with released soil-dwelling predatory H. aculeifer mites. The impact of resource competition and presence of alternative preys on thrips biological control is exhaustively discussed. From our study, we can extract the subsequent conclusions: (1) the combined use of H. aculeifer and A. cucumeris cannot increase thrips control on cucumber compared to the release of A. cucumeris alone, but the overall reliability of thrips biological control might be enhanced, (2) the availability of alternative preys seemed to affect the thrips predation rate of H. aculeifer, and (3) the impact of naturally occurring soil predatory mites on the control of WFT seemed to be partial.     

The predatory mite Hypoaspis miles: biological and demographic characteristics on two prey species, the mushroom sciarid fly, Lycoriella solani, and the mould mite, Tyrophagus putrescentiae

The biology of Hypoaspis miles Berlese (Acarina: Hypoaspidae) fed on mushroom sciarid larvae (Lycoriella solani Winnertz) (Diptera: Lycoriidae) and mould mites (Tyrophagus putrescentiae Schrank) (Acari: Acaridae), was investigated by laboratory experiments at 20 °C, 75% r.h. and LD16:D8 hours. H. miles had a significantly shorter development time and a significantly lower juvenile mortality when fed on sciarid larvae than on mould mites, the development time being 14.5 days and the mortality 3.5% on the former prey. The preoviposition and postoviposition periods of H. miles were not uninfluenced by the prey species and were 5–9 and 32–37 days, respectively. Oviposition periods of 53.2 and 68.5 days and female longevities of 82 and 109.6 days were observed on diets of sciarid larvae and mould mites, respectively. Male longevity (168–219 days) was uninfluenced by the prey species. The egg production of H. miles on sciarid larvae was estimated to be 44.4 ± 4.33 eggs per female, as compared to 22.43 ± 1.79 eggs per female on mould mites. The sex-ratio of the offspring was significantly influenced by the prey species, the ratios (/(+)) being 0.66 on sciarid larvae and 0.54 on mould mites. The net reproductive rate (R₀) for H. miles fed on sciarid larvae was approximately 27 which was three times higher than for mites feeding on mould mites. The innate capacity of increase (r_m) was highest (0.0747 day^–1) when sciarid larvae served as food, giving a doubling time of 9.3 days as compared to 12.8 days on mould mites. The generation times were 44.28 on sciarid larvae and 40.67 days on mould mites. The daily food consumption rate of juvenile and adult H. miles was 0.24 and 0.86 sciarid larvae and 10.8 and 21.7 mould mites, respectively. In terms of weight consumed, however, the consumption of sciarid larvae was 2–3.5 times the weight of mould mites. The ratio of females to males influenced the oviposition period and egg production of H. miles, with virgin females laying fewer eggs over a longer period of time as compared with females with access to males. The egg production in relation to the sex-ratio was described by models predicting a maximum number of eggs per female of 22.3 to be attained at a sex ratio of 0.69 (/(+)) and a maximum daily number of eggs per female of 0.33 to be attained at a sex ratio of 0.37 (/(+)).     

Influence of Steinernema feltiae and Diflubenzuron on Yield and Economics of the Cultivated Mushroom Agaricus bisporus in Dutch Mushroom Culture

The insect pathogenic nematode Steinernema feltiae (Nematoda: Steinernematidae) was shown to offer an alternative to the use of diflubenzuron for the control of the mushroom fly Lycoriella auripila (Diptera: Sciaridae). The influence of diflubenzuron and S. feltiae treatments on the yield and numbers of the mushroom, Agaricus bisporus , was studied. Applications of diflubenzuron after casing significantly reduced total mushroom yields by 10-13%. The greatest yield reductions were observed in the first flush. In the second flush, high yields were found despite significantly lower numbers of mushrooms. These high yields, however, could not compensate for the yield loss of the first flush. Some of the treatments with S. feltiae significantly increased yields, but these were not associated with a particular time of application. As nematodes did not reduce mushroom yields they were able to compete with diflubenzuron. Although the purchase costs of nematodes were high, their use was more economical than that of diflubenzuron when the yield losses of 10% due to casing treatments were taken into account.     

噻虫嗪对昆虫病原线虫侵染韭菜迟眼蕈蚊能力的影响

【目的】为提高昆虫病原线虫对韭菜迟眼蕈蚊Bradysia odoriphaga Yang et Zhang幼虫的防治效果,将昆虫病原线虫与环境友好型化学杀虫剂混用是一条有效途径。【方法】测定了噻虫嗪与6个昆虫病原线虫品系混用对韭菜迟眼蕈蚊的作用效果,以及温度和土壤含水量对作用效果的影响,并进行了田间验证。【结果】田间推荐浓度噻虫嗪(100 mg·L~(-1))对6种供试线虫存活无显著影响。处理后3 d,低浓度噻虫嗪(15 mg·L~(-1))分别与6品系线虫混合后处理韭菜迟眼蕈蚊幼虫,其死亡率明显高于线虫和噻虫嗪单用处理。小卷蛾斯氏线虫SF-SN+噻虫嗪、印度异小杆线虫LN2+噻虫嗪和小卷蛾斯氏线虫All+噻虫嗪3种组合发挥杀虫作用的最适温度范围分别为20~25℃、25~30℃和25~30℃,显著高于其他温度;最适土壤含水量范围为10%~18%,也显著高于其他湿度。大田条件下,施用后7 d,单用噻虫嗪、线虫+噻虫嗪组合处理对韭菜迟眼蕈蚊的防治效果显著高于单线虫,且以芫菁夜蛾斯氏线虫SF-SN+噻虫嗪的防治效果最高,达到93%以上。【结论】芫菁夜蛾斯氏线虫SF-SN品系与噻虫嗪组合联合防治韭菜迟眼蕈蚊效果最好。     

Pseudomonas tolaasi in Mushroom Crops: A Note on Primary and Secondary Sources of the Bacterium on a Commercial Farm in England

Primary sources of Pseudomonas tolaasi Paine on a mushroom farm were the peat and limestone used in the casing process. The pathogen could not be detected in the farm soil, water supply, the mushroom spawn used, or in compost after spawning, but was isolated from the casing (peat/limestone mixture) layer of symptom-free mushroom beds and both the casing layer and compost of beds bearing diseased mushrooms. Secondary sources were numerous once the pathogen was present in mushroom beds. These included symptomless and diseased mushrooms, the fingers and shoes of people handling the crop, their baskets, knives and ladders. Ps. tolaasi could be isolated from dust in the air in infected houses and also from floors. Spores of infected mushrooms may transport the bacterium, as did sciarid flies and mites which are common pests of mushroom crops.     

Molecular detection of predation by soil micro-arthropods on nematodes

The relative importance of the factors driving change in the population dynamics of nematodes in the soil is almost completely unknown. Top-down control by micro-arthropod predators may have a significant impact on nematode population dynamics. We report experiments showing that mites and Collembola were capable of reducing nematode numbers in the laboratory and were feeding on a targeted nematode species in the field. A PCR-based approach was developed for the detection of predation on three species of slug- and insect-pathogenic nematodes: Phasmarhabditis hermaphrodita, Heterorhabditis megidis and Steinernema feltiae. The collembolan Folsomia candida and the mesostigmatid mite Stratiolaelaps miles were employed as model predators to calibrate post-ingestion prey DNA detection times. Fragments of cytochrome oxidase I (COI) mtDNA were sequenced and species-specific primers were designed, amplifying 154-, 154- and 203-bp fragments for each of the nematode species. Detection times for nematode DNA within the guts of Collembola were longer than in mites, with half-lives (50% of samples testing positive) of 08.75 h and 05.03 h, respectively. F. candida significantly reduced numbers of the nematode H. megidis, with rates of predation of approximately 0.4 nematode infective juveniles per collembolan per hour over 10 h. Four taxa of field-caught micro-arthropod that had been exposed to the nematode P. hermaphrodita for a period of 12 h were analysed and significant numbers of three taxa tested positive. This is the first application of PCR techniques for the study of nematophagy and the first time these techniques have been used to measure predation on nematodes in the field.     

Comparative effects of Steinernema feltiae (Nematoda: Steinernematidae) and insecticides on yield and cropping of the mushroom Agaricus bisporus

In a mushroom crop (Agaricus bisporus) affected by a very low level of sciarid fly (Lycoriella auripila) infestation, the effects of an indigenous isolate of insect-parasitic nematode (Steinernema feltiae) and of two commonly used insecticides (diazinon and diflubenzuron) were studied. When compared with untreated plots, nematodes applied to the casing had no adverse effects on mushroom yields whereas insecticides decreased yields. At a rate of 3 × 10⁶ infective juveniles per tray (surface area = 0.56 m²), S. feltiae elicited increases of 28.5% and 19% in the mean total numbers and weights of mushrooms respectively. Treatment only with diflubenzuron resulted in 14.6% and 6% reductions in mean total numbers and weights of mushrooms, respectively; treatment with both diazinon and diflubenzuron caused 18.5% and 9.4% losses. Application of nematodes generally reduced the mean weight per mushroom whereas insecticides increased it; nematodes delayed the onset of mushroom production (first flush) whereas diflubenzuron delayed the third and fourth flushes. Nematode contamination of sporophores was minimal when S. feltiae was applied at casing. Although their numbers declined with time, the nematodes persisted, in the casing layer, throughout the cropping period of seven weeks. It is concluded that yield benefits associated with nematode application can result mainly from nematode effects on A. bisporus and not solely from suppression of a damaging pest population.     

Mortality of Immature Houseflies (Musca domestica L.) in Artificial Diet and Chicken Manure after Exposure to Encapsulated Entomopathogenic Nematodes (Rhabditida: Steinernematidae, Heterorhabditidae)

The entomopathogenic nematodes, Steinernema felitae (=bibionis) and Heterorhabditis megidis, were encapsulated in calcium alginate and their efficacy was tested against immature houseflies. Aliquots of capsules (15 ml) containing either 1 000 000, 500 000, 250 000 or 125 000 nematodes were added to 70-ml portions of grassmeal diet containing either eggs of first, second or third instar larvae. After 2 days, the treatment with 1 000 000 encapsulated S. feltiae (=bibionis) had killed 94% of housefly eggs and 90% of first instar larvae. By day 6, both of these mortalities had increased significantly (P 0.005) to 100%. By day 2, in the same medium, 1 000 000 encapsulated H. megidis had killed 71.4% of eggs and 90% of first instar larvae. This increased significantly (P 0.01) by day 6, to 99.2% and 100% respectively. Another experiment was carried out where immature houseflies were placed in chicken manure. The emergence of houseflies as adults was used to measure the effect of the encapsulated nematodes. Depending on the numbers of nematodes and the original stage of the housefly, the treatment with encapsulated S. feltiae resulted in 55-96% reduction in adult housefly emergence, whereas treatment with encapsulated H. megidis resulted in 35-98% reduction in emergence. Finally, when encapsulated nematodes were presented as a bait to adult houseflies, little infectivity was observed.     

Biological Control of the Bulb Mite, Rhizoglyphus robini , by the Predatory Mite, Hypoaspis aculeifer , on Lilies: Predator-Prey Dynamics in the Soil, under Greenhouse and Field Conditions

We tested the capacity of the soil-dwelling predatory mite, Hypoapsis aculeifer , to control mites attacking lily bulbs. Experiments in the greenhouse and in the field showed that in the absence of predatory mites populations of the bulb mite, Rhizoglyphus robini , on lily bulbs increased, whereas the release of predatory mites either slowed down the increase - as observed in the field - or caused the bulb mites populations to decrease - as observed in the greenhouse. In all cases the population of predatory mites increased as long as bulb mite densities were not too low. However, within the first week after predator release there was usually a sharp decline to 10-40% of the original number released. Greenhouse experiments on intact lily bulbs in pots, boxes and 1 m 2 plots with peat soil showed that when released in a ratio of 1 predator to 2 or 5 prey, the predatory mite, Hypoaspis aculeifer , suppressed populations of bulb mites to less than 10 individual per bulb within 6 weeks. Elimination of bulb mites was observed only when the predator-to-prey ratio at release was equal to 3:1. Field experiments in 2 m 2 plots with intact bulbs in rather compact sandy soil showed that when released in ratio of 1 predator to 1 or 2 prey, the predatory mite, H. aculeifer , did not cause the population of bulb mites to decrease, but it did reduce their population growth. The initial predator-to-prey ratios required to achieve suppression (ca 1:2) or elimination (3:1) in the soil environment are much higher than those required for bulb mite elimination when lily bulb scales were embedded in a medium of vermiculite (ca 1:20). Among the possible causes are: (1) the initial losses of predators in the greenhouse and even more so in the field due to mortality and/or emigration from the experimental plots; (2) the lower temperatures in the greenhouse and especially in the field, which slow down the growth and predation processes and thereby delay prey extinction; and (3) the spatial complexity of the soil environment which creates refuges for the bulb mites.