Reproductive characteristics of invasive hyperparasitoid Baeoanusia albifunicle have implications for the biological control of eucalypt pest Paropsis charybdis

Hyperparasitoids can impede the establishment of primary parasitoid biological control agents or limit their control capacity. Although modern quarantine practices generally prevent hyperparasitoids being introduced with biological control agents, introductions can occur via natural pathways or accidentally with incoming passengers and cargo. In New Zealand, Baeoanusia albifunicle Girault is a self-introduced hyperparasitoid of Enoggera nassaui Girault, an intentionally introduced control agent of the eucalypt pest Paropsis charybdis Stål. A self-introduced primary parasitoid, Neopolycystus insectifurax (Girault), also parasitises P. charybdis in New Zealand. We assessed B. albifunicle biology to better understand its potential to disrupt P. charybdis control. It was determined that B. albifunicle is an obligate solitary hyperparasitoid with a longer lifespan, lower fecundity and longer generation time than its host. The hyperparasitoid reduced effective parasitism by E. nassaui to <10% in the lab, indicating it may limit control of the first P. charybdis generation by slowing spring population growth. It was confirmed that N. insectifurax is not hyperparasitised by B. albifunicle and therefore has some potential to substitute for any hyperparasitoid-driven decline in E. nassaui.     

Influence of habitat and temperature on dispersal behaviour of two pteromalid parasitoids of houseflies during an inundative release at a dairy barn

1. About 11,000 each of Muscidifurax raptor Girault and Saunders and Urolepis rufipes (Ashmead) were released weekly for 7 weeks at a commercial dairy farm in central New York state, U.S.A. Dispersal behaviour was monitored by parasitism rates of house fly, Musca domestica L., pupae placed in sentinel bags. 2. M. raptor, which was released inside the barn, parasitized fly pupae both inside and outside, and it achieved highest rates of parasitism in indoor straw calf-bedding and in outdoor manure and silage. 3. U. rufipes, which was released outside the barn, did not attack pupae inside the barn, and its highest rates of parasitism occurred in outdoor manure and silage. 4. M. raptor appeared to be more effective than U. rufipes in parasitizing pupae located at sites where natural fly-breeding occurred. 5. Interspecific competition did not appear to explain these distribution patterns. 6. There was no significant trend in parasitism by M. raptor as a function of distance from the release station. Furthermore, high rates of parasitism near open doorways and at an outdoor site 30 m away suggests that M. raptor dispersed throughout the barn and its immediate surroundings. 7. Air temperature was positively correlated to flight activity, but not to parasitization activity in natural fly-breeding substrates.     

Impact of selected pesticides on field population dynamics of parasitic Hymenoptera (Pteromalidae) in caged-layer poultry manure in southern California, U.S.A.

Field studies were conducted at caged-layer poultry facilities in southern California, U.S.A., to determine the effect of selected pesticides on beneficial Pteromalidae. Weekly parasite sampling was conducted using sentinel Musca domestica L. pupae to assess changes in parasitization in relation to pesticide treatment. Sites were sampled weekly for 5 weeks before treatment and for 8-10 weeks post-treatment. Treatments were applied twice to six hen houses (four treated plus two controls) at each of two sites. Treatments were: (1) dimethoate (0.5%), spot-treatment to wet areas only (approximately 5-10% of manure surface); (2) dimethoate (0.5%), entire manure surface; (3) cyromazine (0.1%), entire manure surface; and (4) permethrin (0.05%) applied to all hens in the house for northern fowl mite [Ornithonyssus sylviarum (Canestrini and Fanzago)]. The two discrete pesticide applications during an 8-day period had no significant effect on activity of Muscidifurax spp. and Spalangia spp. at either site.     

Pupal and larval-pupal parasitoids (Hymenoptera) obtained fromAnastrepha Spp. andCeratitis capitata (Dipt.: tephritidae) pupae collected in four localities of Tucuman province,Argentina

Pupal and larval-pupal parasitoids were obtained from 5 % of the 1,413 tephritid puparia collected in four localities of the Tucumán province, Argentina, from April, 1991 to April, 1993.Ceratitis capitata (Wiedemann) was attacked byPachycrepoideus vindemmiae (Rondani) (Pteromalidae), a pupal parasitoid, andAganaspis pelleranoi (Brèthes) (Eucoilidae), a larval parasitoid.Anastrepha spp. were attacked byDoryctobracon areolatus (Szépligeti) (Braconidae), a larval parasitoid, and also byA. pelleranoi. Information about parasitism, percentage of emergence of tephritid species and pupal viability in different localities is provided.     

Low humidity as a cue for habitat preference in the parasitoid Lariophagus distinguendus

The larval and pupal parasitoid Lariophagus distinguendusFörster (Pteromalidae) is a potentialcandidate for the biological control of thegranary weevil Sitophilus granarius L.and other stored product pests that mostlyprefer the dry conditions of a storageenvironment. To predict whether parasitoidswill remain within the dry storage environmentafter release, experiments with L.distinguendus were performed in a humiditygradient chamber. To our knowledge, this is thefirst time that humidity preference wasexamined directly for a parasitoid species.Regardless of experience, parasitoidssignificantly preferred drier areas in theorder 32.5% (most preferred), 53%, 75.5%,and 97.5% r.h. (least preferred). Thisindicates that humidity is used as cue for hosthabitat preference. When used as natural enemyagainst stored product pests this preferenceprobably will retain L. distinguenduswithin the storage environment after theirrelease.     

斯夫金小蜂属一新种（膜翅目：金小蜂科）

1989年6月,在吉林省公主岭市我们从为害旱柳Salix mat sudana Koidz枝梢的黑潜蝇Melanagromyza sp.蛹中饲养出一种斯夫金小蜂。经鉴定,该种为斯夫金小蜂属Sphegigaster一新种。模式标本保存于中国科学院动物研究所。吉林斯夫金小蜂Sphegigaster jilinensis Huang,新种(图1～6)     

鳞卵金小蜂属在我国发现并记述一新种(膜翅目:小蜂总科,金小蜂科)

鳞卵金小蜂属Agiommatus寄生蚕蛾、天蛾、弄蝶等鳞翅目蝶蛾类害虫的卵,为重要的寄生性天敌。主要分布非洲、亚洲南部和澳大利亚。我国以前没有本属分布的记载。1986年,福建省林科所的杨嘉寰先生从闪蛱蝶卵中养出1种寄生蜂。经作者鉴定,属于本属,为1新种,现记述如下。这是鳞卵金小蜂属在我国的首次发现。新种的模式标本保存于西北林学院天敌昆虫研究室。     

Host recognition cues of the granary weevil parasitoid Lariophagus distinguendus

Host recognition was examined in Lariophagus distinguendus (Förster), a parasitoid of larvae of the granary weevil Sitophilus granarius (L.) that live endophytically in wheat grains. On encountering a grain infested with S. granarius, females of L. distinguendus behave in a set sequence. First they show antennal drumming on the grain, second they tap with the tip of the abdomen on the grain surface, third they drill into the grain and then insert their ovipositor. Bioassays revealed that drumming and drilling was stimulated by non-volatile chemicals present on the grain-host complex. Host faeces and herbivore damaged grain material stimulated the most activity, followed by artificially damaged grain, and healthy grain. This is the first report on non-volatile chemicals released from herbivore-damaged seeds as signals for foraging parasitoids. Volatile chemicals from the faeces alone were not active. Experiments on the use of physical cues revealed that the presence of a three-dimensional structure increased the response towards chemicals from the faeces. The shape (ovoid or rectangular solid) and colour (brown or white) of the structure had no impact. Thus, physical cues alone were insufficient to stimulate host recognition behaviour, but acted by increasing the response towards the chemical stimuli.     

Parasitism of house fly (Musca domestica) pupae by four species of Pteromalidae (Hymenoptera): effects of host–parasitoid densities and host distribution

Parasitoid-induced mortality of house fly, Musca domestica L., pupae and parasitoid progeny emergence by four species of pteromalid parasitoids, Muscidifurax raptor Girault & Sanders, M.zaraptor Kogan & Legner, Spalangia cameroni Perkins and S.endius Walker, were determined for a 24 h exposure period using parasitoid: host ratios ranging from 1:2 to 1:50. When the number of parasitoids was held constant (n = 5) and the numbers of hosts varied, and when the number of hosts was held constant (n = 100) and the number of parasitoids varied, both the number of pupae killed per parasitoid and the number of parasitoid progeny per parasitoid increased with increasing parasitoid:host ratios to reach an upper limit asymptotically. Maximum values were, respectively: M.raptor (14.7, 11.1), M.zaraptor (12.3, 9.3), S.cameroni (16.9, 5.5), S.endius (14.8, 9.7) with no consistent effects attributed to parasitoid interference. For M.raptor and S.cameroni at parasitoid:host ratios of 1:10, the pupal mortality and progeny emergence were determined for a 24 h exposure period when hosts were distributed in poultry manure at four levels of aggregation ranging from clumped to uniform. Pupal mortality was least in clumped distributions, while parasitoid progeny emergence was not significantly different.     

Temperature-dependent development and parasitism rates of four species of Pteromalidae (Hymenoptera) parasitoids of house fly (Musca domestica) pupae

Parasitoid development, parasitoid-induced host mortality and parasitoid progeny emergence were determined at five constant temperatures for Muscidifurax raptor Girault and Sanders, Muscidifurax zaraptor Kogan and Legner, Spalangia cameroni Perkins and Spalangia endius Walker using pupae of the house fly, Musca domestica L., as hosts. At temperatures of 20, 25, 30 and 35 degrees C the median development times (days from oviposition to adult emergence), respectively, were M. raptor (28.4, 20.7, 14.3, 14.5), M. zaraptor (30.6, 22.8, 14.1, 14.2), S. cameroni (55.6, 35.2, 21.8, 25.0) and S. endius (52.4, 31.5, 16.3, 14.6). All species failed to emerge at 15 degrees C. Using densities of five parasitoids and 100 hosts and a 24 h exposure period, Muscidifurax species oviposited at a greater rate over a wider range of temperatures than Spalangia species. At 15, 20, 25, 30 and 35 degrees C the mean number of pupae killed per parasitoid were, respectively, M. raptor (1.4, 7.4, 10.5, 13.7, 14.1), M. zaraptor (0.0, 3.3, 8.9, 14.4, 15.0), S.cameroni (0.0, 7.8, 11.0, 11.9, 7.4), S.endius (0.6, 4.0, 7.5, 12.0, 11.7), and means of the number of parasitoid progeny per parasitoid were, respectively, M.raptor (0.2, 5.2, 7.9, 11.8, 11.6), M.zaraptor (1.3, 4.4, 8.2, 13.0, 13.7), S.cameroni (0.0, 2.4, 4.7, 5.1, 1.0), S.endius (0.0, 0.9, 3.4, 7.5, 4.9). Development and ovipositional activity in S.cameroni was strongly inhibited at 35 degrees C. The model by Sharpe & DeMichele (1977) was used to describe temperature-dependent development and the number of parasitoid progeny produced per parasitoid at temperatures of 15-30 degrees C in all species.