Free serosal cells originating from the embryo of the wasp Diadromus pulchellus in the pupal body of parasitized leek-moth,Acrolepiosis assectella. Are these cells teratocyte-like?

In braconid species, teratocytes are derived from a serosal cell membrane which envelops the developing parasitoid embryo. On hatching, this membrane dissociates into individual cells, the teratocytes, which then circulate in the haemolymph of the host. We describe herein such a membrane, surrounding the embryo in eggs of the ichneumonid parasitoid wasp, Diadromus pulchellus. This membrane consisted of a single sheet of tightly packed cells with large 12+/-1.4 &mgr;m nuclei. These cells were released after hatching in vitro and cells of the same size were detected in vivo, in the vicinity of the D. pulchellus embryo. The number of nuclei detected suggests that the serosal membrane consists of about 450+/-150 cells. These cells did not grow after hatching of the parasitoid egg in the parasitized host, Acrolepiosis assectella, during the development of the parasitoid wasp larva. Southern blot experiments, using D. pulchellus satellite DNA or the ribosomal genes as probes, showed that free-living floating cells of wasp origin were present in the body of the parasitized host. This is the first time that free-floating teratocyte-like cells have been described in species of the Ichneumonidae.     

中红侧沟茧蜂在粘虫体内的发育 及畸形细胞发生

中红侧沟茧蜂Microplitis mediator的初产卵因受雌蜂产卵器的机械挤压,在形态上有别于未产出的卵,这种机械挤压激活了蜂卵的胚胎发育。产卵后 6 h,胚带和浆膜层开始分化,20 h胚胎成形,包裹在单层细胞的浆膜层内。32～34 h,幼蜂孵化,顶部的浆膜层立即分散形成畸形细胞,尾部的浆膜层则逐渐释放细胞。1龄幼蜂具一对角质的颚,用来消灭同种竞争者。寄生后108～113 h,1龄幼蜂蜕皮进入2龄。2龄幼蜂为无头型,尾囊发达。成熟的畸形细胞(受寄生日龄6天)表面密布微绒毛,细胞内部高尔基体丰富,内质网发达,细胞核多分支。在高尔基体的两侧和细胞膜附近分布了大量的分泌小池。     

Ultrastructure of Microplitis croceipes (Cresson) (Braconidae : Hymenoptera) teratocytes

The developing embryo of the braconid, Microplitis croceipes (Braconidae : Hymenoptera), is encased in an extraembryonic serosal membrane. Hatching of the parasitoid within the larva of its habitual host, Hehothis virescens (Noctuidae : Lepidoptera), is initiated about 40 hr after oviposition when held at 25 ± 2°C. At this time, the monolayered serosal membrane begins to dissociate into individual cells (teratocytes). After dissociation, teratocytes become dispersed in the hemolymph of the host. The average number of teratocytes released from each parasitoid embryo is 914 ± 43. Teratocytes average 14.1 ± 2.4 μm in diameter when first released, and reach a maximum average diameter of 68.1 ± 4.6 μm 6 days after liberation. Newly released teratocytes have ovoid nuclei, simple mitochondria and a limited number of profiles of the endoplasmic reticulum, all of which indicate relative metabolic inactivity. The ramified nuclei, extensive endoplasmic reticulum, polymorphic mitochondria and accumulation of glycogen granules and lipid droplets observed in older teratocytes provide circumstantial evidence that protein synthesis is occurring. Within hours after dissociation, microvilli begin to cover the surface of the teratocytes. Anatomical deformation (blebs) that occurred on some older (8-day-old) teratocytes probably resulted from enlargement or expansion of microvilli.     

Development of the anal vesicle, salivary glands and gut in the egg-larval parasitoid Chelonus inanitus: tools to take up nutrients and to manipulate the host?

Larvae of endoparasitoids undergo extensive morphological changes and often have special features to allow their development inside the host. We present the first detailed study on the development of the anal vesicle and the gut. The analyses reveal that the anal vesicle is first seen on the dorsal side of the abdomen as an internal structure covered by a membrane. The morphology of the abdomen then changes intensively: new segments are formed and the anal vesicle develops from a crest of large cells to a protrusion. Towards the end of the first instar, the anal vesicle is fully evaginated and no longer covered by a membrane; the large epithelial cells have microvilli on their apical side which suggests uptake of nutrients from the host's haemolymph. When the larva has moulted to the second instar, the ultrastructure of the anal vesicle begins to change and shows signs of degeneration. In this stage the epithelium of the midgut is fully developed and has a brush border which suggests that nutrient uptake occurs now primarily through the midgut. The anal vesicle then degenerates completely. The salivary glands are prominent already in first instar larvae and appear to produce and release a host regulatory 212 kD protein.     

Additive effect of teratocyte and calyx fluid from Cotesia plutellae on immunosuppression of Plutella xylostella

Abstract.  Teratocytes are cells that originate from the extra-embryonic tissues of some hymenopteran parasitoids, typically dissociate upon hatching, and develop in the host haemolymph. They are considered to be involved in parasitoid larval nutrient uptake, host immunosuppression and/or repression of competing parasitoid development. Teratocytes of the parasitoid, Cotesia plutellae (Kurdjumov) (Hymenoptera: Braconidae) are found in its natural host, Plutella xylostella (Linnaeus) (Lepidoptera: Yponomeutidae) and can be cultured in vitro . The present study demonstrates that teratocytes of C. plutellae possess a significantly depressive effect on host cellular immunity. When the hosts are preinjected with 200 cultured teratocytes (corresponding to the normal number of teratocytes released during wasp hatching), haemocyte nodulation is inhibited by approximately 40%, with younger teratocytes being more potent than older ones. Similarly, the medium in which teratocytes are cultured has similar immunosuppressive properties. In comparison, calyx fluid extracted from the C. plutellae ovary also has an immunosuppressive effect on P. xylostella . These two maternal (calyx fluid) and embryonic (teratocytes) factors are additive and result in a reduced level of nodule formation equivalent to that induced by natural parasitization. However, the immunosuppression of the parasitized P. xylostella does not appear to be due to inhibition of phospholipase A₂, an immune mediator, because injection of arachidonic acid failed to restore haemocyte nodulation capability.     

Factors influencing the developmental capacity of Galleria larval epidermis

The nature of the cuticle secreted by integument from a day-1 penultimate instar larval Galleria when cultured in vivo in the abdomen of a last instar larva varied with the age of the host. When placed in a day-5 last instar larva, the implanted integument secreted a pupal cuticle at the time the host metamorphosed and became a pupa. However, when placed in a day-7 last instar larva the implant, from the same stage donor, secreted a larval cuticle at the time the host pupated. Experimental studies involving implantation of the integument for a 24 hr period, into various developmental stages of normal and ligated last instar larvae, pupae, and pharate adults, prior to placing it in a day-7 last instar larva suggest that a non-hormonal factor present in day-4 and -5 last instar larvae is important to initiate pupal syntheses.     

畸形细胞在协调寄生蜂同其寄主 相互关系中的作用

膜翅目内寄生的茧蜂科(Ｂｒａｃｏｎｉｄａｅ)、广腹细蜂科(Ｐｌａｔｙｇａｓｔｅｒｉｄａｅ)、缘腹卵蜂科(Ｓｃｅｌｉｏｎｉｄａｅ)中,蜂卵孵化时,起胚胎营养作用的浆膜(ｓｅｒｏｓａｌｍｅｍｂｒａｎｅ)释放到寄主血淋巴中,分散后游离形成畸形细胞。赤眼蜂科(Ｔｒｉｃｈ...     

畸形细胞在协调寄生蜂同其寄主 相互关系中的作用

Teratocytes originating from the serosal membrane of an endoparasitic wasp embryo, which is one of the species found in the Hymenopteran families Braconidae, Platygasteridae and Socelionidae, act an important role in coordinating the relationship between the larval wasp and its host. It may be concluded that inhibiting the immune system of the host, regulating development of the host and nourishing the parasitoid larva are three major functions of the teratocytes. By means of releasing inhibitor of phenol oxidase, a fundamental ingredient of the immune system of the host, the teratocytes prevent the host from encapsulation, which is fatal to the parasitoid larva. In the process of parasitism, the teratocytes reduce ecdysteroid titer and inhibit the metabolism of JH in the hemoymph of the host, and subsequently result in the developmental arrest of the host larva. On the other hand, the teratocytes secrete proteins or present themselves as food to the parasitoid. Although all those above are generally acknowledged functions of the teratocytes, there are other putative functions of the teratocytes, such as secreting histolytic enzymes and mycostatic material, and protecting the host from overharmed by the parasitoid before the parasitoid emerges from its host. The studies in this area can provide us more understanding and knowledge about the relationship between a parasitoid and its host.     

Protein synthesis by the milk gland and fat body of the tsetse fly,Glossina pallidipes

The patterns of protein synthesis by the milk gland and the fat body of female Glossinapallidipes during the pregnancy cycle were studied by incubation with [³⁵S]methionine both in vivo and in vitro. The pattern of protein synthesis by the milk gland changed with the stage of the larva in the uterus. Very little synthesis occurred in the milk gland until the first instar larva hatched. Then four proteins (13, 16, 24 and 72 kDa) were prominently synthesized. As the larva matured, the synthesis of 19, 38, 40 and 72 kDa proteins increased, whereas that of the 13 and 24 kDa proteins decreased. Just before larviposition, only the 16 and 72 kDa proteins were still being synthesized. The milk gland secreted into the medium primarily the 13, 16, 19 and 72 kDa proteins, all of which were found in the larval gut after a 5 hr pulse of labeled methionine in vivo. During most of the pregnancy cycle protein synthesis in the fat body was low compared to that of the milk gland and only small amounts of several low molecular weight proteins (less than or equal to 16 kDa) were released into the medium. But when a large third instar larva was present in the uterus, the fat body synthesized and secreted a 72 kDa and a 15–17 kDa complex of proteins.     

Dose-dependent influence of Microplitis rufiventris factors on developmental rate and growth of last-instar Spodoptera littoralis larvae

The solitary endoparasitoid, Microplitis rufiventris, attacks and can develop in earlier instars of Spodoptera littoralis larvae with preference to third‐instar larvae. We used the last stadium (sixth instar), a stage which is not naturally parasitized. The newly moulted larvae (0–3 h old) of this stadium were more acceptable for parasitization by the wasp females than the older ones (24 h old). Parasitization by M. rufiventris wasp of last instar S. littoralis larvae leads to dose (no. of eggs + parasitoid factors)‐dependent effects which were more pronounced at 20°C than at 27°C. A single oviposition into a sixth instar host larva resulted in normal development of the host. However, superparasitization increased the proportions of developmentally arrested hosts and number of live wasp larvae. Development of supernumerary individuals of the parasitoid in the host larva leads to dose‐related adverse effects on host growth and development. The present study may provide interesting opportunities for studying the physiological bases of host–parasitoid interactions and parasitoid intra‐specific competition in the biological system considered.     

Analysis of endoparasitoid-released proteins and their effects on host development in the system Chelonus inanitus (Braconidae)-Spodoptera littoralis (Noctuidae)

Having shown earlier that the larva of C. inanitus is essential in inducing the precocious onset of metamorphosis in polydnavirus/venom containing S. littoralis, we here analysed release of proteins by parasitoid larvae and their effects on host development. Parasitoid larvae released proteins in vivo and in vitro in a stage dependent manner. An approximately 212 kD protein was released from the mid 1st instar onwards and additional smaller proteins could be associated mainly with the 2nd and 3rd instar. When parasitoids were implanted into S. littoralis larvae, parasitoid-released proteins were seen 6 hr later. When parasitoids were removed from hosts, parasitoid-released proteins persisted in the host haemolymph for some time. Injection of antiserum against parasitoid-released proteins after removal of the parasitoid larva accelerated the disappearance of the 212 kD protein and reduced the number of larvae entering metamorphosis precociously. Repeated injections of concentrated parasitoid medium into polydnavirus/venom containing larvae caused a reduction of the head capsule width and formation of miniature 6th instar larvae; this effect was not seen in the absence of polydnavirus/venom. These observations suggest that proteins released by the parasitoid might play a role in modifying host metamorphosis in the presence of polydnavirus/venom, and the temporal appearance of the 212 kD protein makes it the most interesting candidate for being involved in such an effect.     

转Bt基因水稻对二化螟绒茧蜂生物学特性的影响

用转Bt基因 (cry1Ab) 水稻KMD1饲喂3龄、4龄和5龄二化螟Chilo suppressalis一定时间后, 作为二化螟绒茧蜂Apanteles chilonis的寄主,研究了转基因水稻经寄主对绒茧蜂生物学特性的影响。结果发现：KMD1处理后,三个龄期幼虫的寄生率都显著下降,其中4龄和5龄达极显著水平;3龄和4龄上的结茧率显著低于对照;蜂蛹历期均短于对照,但仅3龄差异显著;从5龄幼虫所羽化的雄蜂寿命显著短于对照;蜂茧长显著短于对照;而对卵＋幼虫期、茧块茧数、蜂羽化率及性比均无显著影响。     

Physiological and Biochemical Analysis of Factors in the Female Venom Gland and Larval Salivary Secretions of the Ectoparasitoid Wasp Eupelmus orientalis

The stinging adult female and the biting newly-hatched larva of the solitary ectoparasitoid wasp Eupelmus orientalis can both cause permanent paralysis and stop the development of Callosobruchus maculatus host larvae. These two processes of host envenomation appeared to be independent and complementary in primary parasitism or in hyperparasitism of a distantly related hymenopteran host species. In contrast, the development of larvae as hyperparasites on members of their own species or genus depended completely on the prior injection of female venom. The venoms of the female and the first instar larva had similar effects on the cellular metabolism of the primary hosts. Protein synthesis was blocked in C. maculatus hosts envenomated by a female or a first instar larva of E. orientalis, but the absence of DNA breakdown indicated that these paralysed hosts were alive and quiescent. The venomous secretions injected by adult females and first instar larvae of E. orientalis had distinct electrophoretic profiles. The immunoreactive features of proteins from female venom and larval secretions were also examined. There is evidence for antigenic conservation between some venom proteins of E. orientalis and Apis mellifera. Lastly, the hyaluronidase, phospholipase and lipase activities in the female venom gland and in larval-derived secretions of E. orientalis were assayed. No lipase activity was detected. Phospholipase activity was found in both the female venom and the larval secretions of E. orientalis, whereas hyaluronidase was specific to the female venom.     

The effects of host age and superparasitism by the parasitoid, Microplitis rufiventris on the cellular and humoral immune response of Spodoptera littoralis larvae

To study the dynamics of stage-dependent immune responses in Spodoptera littoralis (Boisd.) larvae (Lepidoptera: Noctuidae), single and superparasitism experiments were carried out using the parasitoid Microplitis rufiventris Kok. (Braconidae: Hymenoptera). Compared to younger (preferred) host larvae, the older (non-preferred) host larvae displayed a vigorous humoral response that often damaged and destroyed the single wasp egg or larva. Superparasitism and host age altered both the cellular and humoral immune responses. Younger host larvae showed a stronger encapsulation response compared to older host larvae. Moreover encapsulation rates in younger hosts (e.g., second instar) decreased with increasing numbers of parasitoid eggs deposited/larvae. In older larvae, the encapsulation rate was low in fourth, less in fifth and absent in sixth instar hosts. Conversely, the order and magnitude of the cellular immune response in S. littoralis hosts were highest in second instar larvae with the first instar larvae being a little lower. The immune response steadily decreased from the third through to the fifth instar and was least obvious in the sixth instar. In contrast, the general humoral immune response was most pronounced in sixth instar larvae and diminished towards younger stages. The results suggest that both cellular and humoral responses are stage-dependent. Wasp offspring in younger superparasitized host larvae fought for host supremacy with only one wasp surviving, while supernumerary wasp larvae generally survived in older superparasitized larvae, but were unable to complete development. Older instars seem to have a method for immobilizing/killing wasp larvae that is not operating in the younger instars.     

多胚发育寄生蜂腰带长体茧蜂在寄主亚洲玉米螟幼虫体内的发育

多胚发育的幼虫内寄生蜂腰带长体茧蜂Macrocentrus cingulum的卵、胚胎和幼虫在寄主亚洲玉米螟Ostrinia furnacalis幼虫血腔内发育,通常1枚卵可以分裂增殖为数百只胚胎。本文通过定时解剖寄生的寄主幼虫,初步了解了腰带长体茧蜂多胚的形成过程及其在寄主体内的发育情况。结果表明：以4龄末期亚洲玉米螟幼虫为寄主时,寄生蜂卵产入寄主体内10 min左右开始卵裂,1天左右,初级胚胎从卵壳中被释放出来。之后胚胎在胚外膜内持续分裂产生大量二级胚胎形成桑葚胚。寄生后3天左右,二级胚胎从胚外膜中被释放出来,进入胚胎发育阶段。寄生后6天左右,胚胎进入胚带形成阶段。寄生后8天左右,胚带伸长,头尾形成。寄生后9天左右,身体分节完成,部分幼虫孵化,蜕去胚外膜。寄生后13天左右,蜂幼虫从寄主体内啮出。胚胎在发育初期体积变化不大,但从胚带形成开始,体积则迅速增大。腰带长体茧蜂与另一多胚发育寄生蜂佛州点缘跳小蜂Copidosoma floridanum在胚胎发育进程上明显不同,体现了它们对各自寄主的适应。     

Expression and characterization of a novel teratocyte protein of the braconid,Microplitis croceipes (cresson)

Microplitis croceipes wasps overcome host immunity by inducing changes in host physiology using factors derived from the embryo and/or larva. Teratocytes of some parasitic wasps circulate in the host hemolymph after egg hatch and synthesize proteins (TSPs), some of which are secreted to alter host physiology in support of endoparasitoid development. TSPs appear to alter host physiology, at least in part, by inhibiting synthesis of certain proteins. M. croceipes teratocytes synthesize a 13.9 kDa protein (TSP14), which inhibits synthesis of host proteins that are linked to larval growth and development. A cDNA encoding TSP14 was generated by RT-PCR from teratocyte RNA, and cloned into yeast expression vectors to produce sufficient recombinant protein for functional analyses. RecTSP14 was produced using the yeast expression system at a concentration of more than 300 micrograms/L. The recTSP14 inhibited in vitro translation of larval Heliothis virescens RNA, with the activity sensitive to boiling, protein concentration, incubation time, and storage temperatures. Although recTSP14 inhibited translation of some cellular RNAs in vitro, the in vivo incorporation of [35S]-methionine into proteins of selected insect and mammalian cell lines was not inhibited. These findings suggest that recTSP14 entry is cell type-specific and required to inhibit synthesis of target protein(s).     

The ultrastructure of malpighian tubules and the chemical composition of the cocoon of Aeolothrips intermedius Bagnall (Thysanoptera)

The secretory activity of the two branched malpighian tubules (MTs) of the second‐instar larva in Aeolothrips intermedius is described. MTs of adult thrips have the typical ultrastructure of excretory epithelium with apical microvilli containing long mitochondria and a rich system of basal membrane infoldings. In the second‐instar larva just before pupation, the ultrastructure of MT epithelial cells is dramatically different, and there are numerous huge Golgi systems in the cytoplasm. These cells are involved in an intense secretory activity to produce an electron‐dense product which is released into the MTs lumen. This secretion is extruded from the hindgut and used by the second‐instar larva to build an elaborate protective cocoon for pupation. Electron‐spray‐ionization mass spectrometry analysis of the cocoon revealed the presence of a β‐N‐acetyl‐glucosamine, the main component of chitin, which is also present in the cocoons of Neuroptera and some Coleoptera. J. Morphol., 2010. © 2009 Wiley‐Liss, Inc.     

Host regulation by the aphid parasitoid Aphidius ervi: the role of teratocytes

The biochemical profile and metabolism of Acyrthosiphon pisum(Harris) (Homoptera, Aphididae) are markedly altered and redirected in response to parasitization by the endophagous braconid Aphidius erviHaliday (Hymenoptera, Braconidae). In the present study, the role played in the host regulation process by teratocytes, cells deriving from the dissociation of the embryonic membrane of the parasitoid, is taken into consideration. The protein synthesis activity of these cells of embryonic origin is analysed in vitroand an essential characterization of those proteins de novosynthesized and released in the incubation medium is provided. Teratocytes, obtained by dissecting parasitized host aphids, 3, 4 and 5 days after parasitoid oviposition, were incubated in vitroand, at the end of the incubation period, were separated from the medium for SDS-PAGE analysis of both cellular and secreted proteins. Various cellular proteins were more abundant as the time between parasitization and teratocyte collection increased. Furthermore, two proteins, showing an approximate molecular mass of 15 kD (p15) and 45 kD (p45) respectively, were abundantly secreted in the incubation medium by 5 day-old teratocytes. Incubations in presence of ³⁵S radiolabelled amino acids indicated that p15 and p45 are both synthesized by A. erviteratocytes. The amino acid composition of these two proteins was similar to that reported for other insect proteins with a demonstrated nutritional function. The p45 protein was found to be glycosylated. A tentative physiological model describing the host regulation role played by different parasitoid-derived factors is proposed.     

Immature development of Eretmocerus mundus (Hymenoptera: Aphelinidae)

The development from egg to pupation is followed for the wasp Eretmocerus mundus, parasitizing the whitefly Bemisia tabaci. We elucidate and describe structural details, histological developments and changes that the different parasitoid and host tissues have undergone during parasitism. These include the presence and apparent function of very large salivary glands, which probably produce substances that help to regulate the host's decomposition and parasitoid nutrition. Moreover, the gut of all instars is devoid of both peritrophic membrane and microvilli and, in the early instars, it has squamous rather than columnar epithelial cells. Differing from many other parasitoids, the E. mundus larva usually does not come into contact with the host tissues and does not devour the entire host during its development.The possible reasons for the developmental mechanisms, as well as the functions of the host capsule that envelopes the parasitoid, are discussed.