Fate of polydnavirus DNA of the egg-larval parasitoid Chelonus inanitus in the host Spodoptera littoralis

In situ hybridizations show that 5 min after parasitization, polydnavirus DNA is in close vicinity of the parasitoid egg, but 5 h later also in the yolk and partially in the host embryo. Fifteen hours after parasitization, the viral DNA is seen all over the host embryo and hardly in the yolk. The tissue distribution of the viral DNA was analysed and quantified by dot blots in the fifth instar parasitized larvae. On a per host basis, haemocytes and fat body contained the highest amount of viral DNA, while nervous tissue, intestinal tract and carcass contained less. Of the three viral segments tested, all were found in all tissues. Relative to the quantity of host DNA, viral DNA was most abundant in haemocytes, about five times less abundant in fat body and nervous tissue and about 25 times less abundant in intestinal tract. The total quantity of viral DNA per host was 444+/-145 pg which is similar to the quantity injected by the wasp; thus, the viral DNA persists throughout parasitization. The parasitoid larva contains 820+/-80 pg viral DNA integrated in the genome. This illustrates that the dose of viral DNA injected in virions represents approximately one third of the total viral genomic information present in a host at a late stage of parasitism.     

A putative protein translation inhibitory factor encoded by Cotesia plutellae bracovirus suppresses host hemocyte-spreading behavior

An endoparasitoid, Cotesia plutellae (Hymenoptera: Braconidae), possesses a mutualistic bracovirus (CpBV), which plays significant roles in the parasitized host, Plutella xylostella (Lepidoptera: Plutellidae). CpBV15beta, a viral gene encoded by CpBV, is expressed at early and late parasitization periods, suggesting that it functions to manipulate the physiology of the parasitized host. This paper reports a physiological function of CpBV15beta as an immunosuppressive agent. The effect of CpBV15beta on cellular immunity was analyzed by assessing hemocyte-spreading behavior. Parasitization by C. plutellae caused altered behavior of hemocytes of P. xylostella, in which the hemocytes were not able to attach and spread on glass slides. CpBV15beta was expressed in Sf9 cells using a baculovirus expression system and purified from the culture media. When hemocytes of nonparasitized P. xylostella were incubated with purified CpBV15beta protein, spreading behavior was impaired in a dose-dependent manner at low micro-molar range. This inhibitory effect of CpBV15beta could also be demonstrated on hemocytes of a non-natural host, Spodoptera exigua. CpBV15beta protein significantly inhibited F-actin growth of hemocytes in response to an insect cytokine. Similarly, cycloheximide, a eukaryotic translation inhibitor, strongly inhibited the spreading behavior and F-actin growth of P. xylostella hemocytes. Under in vitro condition, hemocytes of nonparasitized P. xylostella released proteins into the surrounding medium. Upon incubation of hemocytes with either CpBV15beta or cycloheximide, their ability to release protein molecules was markedly inhibited. This study suggests that CpBV15beta suppresses hemocyte behavior by inhibiting protein translation.     

Effect of Campoletis sonorensis ichnovirus cys-motif proteins on Heliothis virescens larval development

Polydnaviruses are obligate symbionts of some parasitic hymenopteran wasps responsible for modifying the physiology of their host lepidopteran larvae to benefit the endoparasite. Injection of Campoletis sonorensis ichnovirus (CsIV) into Heliothis virescens larvae alters larval growth, development and immunity but genes responsible for alterations of host physiology are not well described. Recent studies of polydnavirus genomes establish that these genomes encode families of related genes expressed in parasitized larvae. Here we evaluate five members of the CsIV cys-motif gene family for their ability to inhibit growth and development of lepidopteran larvae. To study the function of cys-motif proteins, recombinant proteins were produced from baculovirus expression vectors and injected or fed to H. virescens larvae in diet. rVHv1.1 was identified as the most potent protein tested causing a significant reduction in growth of H. virescens and Spodoptera exigua larvae. H. virescens larvae ingesting this protein also exhibited delayed development, reductions in pupation and increased mortality. Increased mortality was associated with chronic sub-lethal baculovirus infections. Taken together, these data indicate that the cys-motif proteins have pleiotropic effects on lepidopteran physiology affecting both development and immunity.     

Development of the braconid wasp Cotesia flavipes in two Crambids, Diatraea saccharalis and Eoreuma loftini: Evidence of host developmental disruption

Cotesia flavipes is an important gregarious larval endoparasitoid of several crambid stem borers, including Diatraea saccharalis. The suitability of two crambid species, Eoreuma loftini and D. saccharalis, pests of sugarcane and rice in Texas, for C. flavipes development was tested. The effect of parasitization by C. flavipes on encapsulation response was assessed in vivo in both D. saccharalis and E. loftini. The results indicated that the parasitoid developed and emerged successfully in D. saccharalis larvae. Although E. loftini larvae were readily parasitized by C. flavipes parasitoids, no wasp larvae hatched from the eggs in this host because eggs were encapsulated by the host's hemocytes. The developmental fate of the E. loftini larvae with encapsulated parasitoids was variable. Most died as abnormal fifth instars or as post-wandering prepupae, while a few developed normally to the pupal stage. In vivo experiments, there was a significant reduction in the percent of beads encapsulated in parasitized larvae in both hosts. However, the percent of beads showing melanization decreased significantly in parasitized D. saccharalis larvae but did not differ significantly in parasitized or unparasitized E. loftini larvae. Our results showed that D. saccharalis is a suitable host for C. flavipes whereas E. loftini is an unsuitable host. This study indicated that lepidopteran stem borers that are taxonomically, behaviorally, and ecologically very similar can differ in their ability to encapsulate a parasitoid species.     

Immunoevasive property of a polydnaviral product, CpBV-lectin, protects the parasitoid egg from hemocytic encapsulation of Plutella xylostella (Lepidoptera: Yponomeutidae)

Immunosuppression is the main pathological symptom of the diamondback moth, Plutella xylostella (Lepidoptera: Yponomeutidae), parasitized by an endoparasitoid wasp, Cotesia plutellae (vestalis, Hymenoptera: Braconidae). C. plutellae bracovirus (CpBV), which is a symbiotic virus of C. plutellae, has been known to be the main parasitic factor in the host-parasitoid interaction. CpBV-lectin, encoded in the viral genome and expressed in P. xylostella during early parasitization stage, was suspected to play a role in immunoevasion of defense response. Here we expressed CpBV-lectin in Sf9 cells using a recombinant baculovirus for subsequent functional assays. The recombinant CpBV-lectin exhibited hemagglutination against vertebrate erythrocytes. Its hemagglutinating activity increased with calcium, but inhibited by adding EDTA, indicating its C-type lectin property. CpBV-lectin showed specific carbohydrate-binding affinity against N-acetyl glucosamine and N-acetyl neuraminic acid. The role of this CpBV-lectin in immunosuppression was analyzed by exposing hemocytes of nonparasitized P. xylostella to rat erythrocytes or FITC-labeled bacteria pretreated with recombinant CpBV-lectin, which resulted in significant reduction in adhesion or phagocytosis, respectively. The immunosuppressive activity of CpBV-lectin was further analyzed under in vitro encapsulation response of hemocytes against parasitoid eggs collected at 1- or 24-h post-parasitization. Hemocytic encapsulation was observed against 1-h eggs but not against 24-h eggs. When the 1-h eggs were pretreated with the recombinant CpBV-lectin, encapsulation response was completely inhibited, where CpBV-lectin bound to the parasitoid eggs, but not to hemocytes. These results suggest that CpBV-lectin interferes with hemocyte recognition by masking hemocyte-binding sites on the parasitoid eggs.     

A viral lectin encoded in Cotesia plutellae bracovirus and its immunosuppressive effect on host hemocytes

An endoparasitoid wasp, Cotesia plutellae, induces immunosuppression of the host diamondback moth, Plutella xylostella. To identify an immunosuppressive factor, the parasitized hemolymph of P. xylostella was separated into plasma and hemocyte fractions. When nonparasitized hemocytes were overlaid with parasitized plasma, they showed significant reduction in bacterial binding efficacy. Here, we considered a viral lectin previously known in other Cotesia species as a humoral immunosuppressive candidate in C. plutellae parasitization. Based on consensus regions of the viral lectins, the corresponding lectin gene was cloned from P. xylostella parasitized by C. plutellae. Its cDNA is 674 bp long and encodes 157 amino acid residues containing a signal peptide (15 residues) and one carbohydrate recognition domain. Open reading frame is divided by one intron (156 bp) in its genomic DNA. Amino acid sequence shares 80% homology with that of C. ruficrus bracovirus lectin and is classified into C-type lectin. Southern hybridization analysis indicated that the cloned lectin gene was located at C. plutellae bracovirus (CpBV) genome. Both real-time quantitative RT-PCR and immunoblotting assays indicated that CpBV-lectin showed early expression during the parasitization. A recombinant CpBV-lectin was expressed in a bacterial system and the purified protein significantly inhibited the association between bacteria and hemocytes of nonparasitized P. xylostella. In the parasitized P. xylostella, CpBV-lectin was detected on the surface of parasitoid eggs after 24 h parasitization by its specific immunostaining. The 24 h old eggs were not encapsulated in vitro by hemocytes of P. xylostella, compared to newly laid parasitoid eggs showing no CpBV-lectin detectable and easily encapsulated. These results support an existence of a polydnaviral lectin family among Cotesia-associated bracovirus and propose its immunosuppressive function.     

中红侧沟茧蜂多分DNA病毒基本特征研究

本文首次报道中红侧沟茧蜂 (Microplitismediator)雌蜂卵巢中存在多分DNA病毒 (MicroplitismediatorPlolyd navirus,MmPDV) ,初步研究了MmPDV形态和基本生理生化特征。利用蔗糖密度梯度超速离心分离纯化了MmPDV粒子 ,电镜负染显示PDV粒子分三段 ,带有一明显的尾部结构 ,大小约为 130× 35nm ;SDS PAGE电泳条带较多 ,至少可以分辨出 2 6个电泳条带 ,表明病毒粒子衣壳蛋白复杂 ;琼脂糖凝胶电泳显示MmPDV基因组至少由大小不同、丰度不等的 14个DNA分子组成 ,用 6种内切酶 (EcoRI,HindIII,BssHII,PstI,BamHI,BglI)酶切MmPDV基因组后 ,估算出MmPDV基因组大小约为 10 8kb。用雌蜂输卵管萼液注射小地老虎幼虫 ,注射后的小地老虎体重和龄期发育动态表明 ,MmPDV具有抑制寄主生长发育的生理功能     

Improved insecticidal activity of a genetically modified baculovirus expressing the immunosuppressive CrV1 protein from a polydnavirus against Spodoptera exigua

Recombinant baculoviruses could be used as biological insecticides through the introduction and expression of exogenous genes (such as those coding for proteins) that interfere with metabolism, metamorphosis (toxins, hormones, and enzymes), and immune system of the insects. The CrV1 secreted protein of Cotesia rubecula polydnavirus (PDV) is responsible for the actin depolymerisation in haemocytes and the abolishment of immune functions such as phagocytosis and cell spreading, thus allowing the successful embryonic development of the parasitoid wasp. CrV1 cDNA was cloned into C6 strain of Autographa californica multiple nucleopolyhedrovirus (AcMNPV-C6-CrV1) under p10 promoter to construct a recombinant virus. The recombinant virus was then tested against the insect pest Spodoptera exigua. The recombinant virus expressing CrV1 protein showed significantly lower LC₅₀ and shorter LT₅₀ as compared with the AcMNPV-C6 wild-type virus. The potential of recombinant baculoviruses expressing PDV genes in relation to their virulence is discussed.     

Origin and evolution of polydnaviruses by symbiogenesis of insect DNA viruses in endoparasitic wasps

During oviposition, many endoparasitic wasps inject virus-like particles into their insect hosts that enable these parasitoids to evade or directly suppress their hosts' immune system, especially encapsulation by hemocytes. These particles are defined as virions that belong to viruses of the two genera that comprise the family Polydnaviridae, bracoviruses (genus Bracovirus) transmitted by braconid wasps, and ichnoviruses (genus Ichnovirus) transmitted by ichneumonid wasps. Structurally, bracovirus virions resemble nudivirus and baculovirus virions (family Baculoviridae), and ichnovirus virions resemble those of ascoviruses (family Ascoviridae). Whereas nudiviruses, baculoviruses and ascoviruses replicate their DNA and produce progeny virions, polydnavirus DNA is integrated into and replicated from the wasp genome, which also directs virion synthesis. The structural similarity of polydnavirus virions to those of viruses that attack the wasps' lepidopteran hosts, along with polydnavirus transmission and replication biology, suggest that these viruses evolved from insect DNA viruses by symbiogenesis, the same process by which mitochondia and chloroplasts evolved from bacteria. Molecular evidence supporting this hypothesis comes from similarities among structural proteins of ascoviruses and the Campoletis sonorensis ichnovirus. Implications of this hypothesis are that polydnaviruses evolved from viruses, but are no longer viruses, and that DNA packaged into polydnavirus virions is not viral genomic DNA per se, but rather wasp genomic DNA consisting primarily of wasp genes and non-coding DNA. Thus, we suggest that a better understanding of polydnaviruses would result by viewing these not as viruses, but rather as a wasp organelle system that evolved to shuttle wasp genes and proteins into hosts to evade and suppress their immune response.