Synthesis of bluetongue virus (BTV) corelike particles by a recombinant baculovirus expressing the two major structural core proteins of BTV.

The L3 and M7 genes of bluetongue virus (BTV), which encode the two major core proteins of the virus (VP3 and VP7, respectively), were inserted into a baculovirus dual-expression transfer vector and a recombinant baculovirus expressing both foreign genes isolated following in vivo recombination with wild-type Autographa californica nuclear polyhedrosis virus DNA. Spodoptera frugiperda insect cells infected with the recombinant synthesized large amounts of BTV corelike particles. These particles have been shown to be similar to authentic BTV cores in terms of size, appearance, stoichiometric arrangement of VP3 to VP7 (ratio, 2:15), and the predominance of VP7 on the surface of the particles. In infected insect cells, the corelike particles were observed in paracrystalline arrays. The formation of these structures indicates that neither the BTV double-stranded viral RNA species nor the associated minor core proteins are necessary for assembly of cores in insect cells. Furthermore, the three BTV nonstructural proteins NS1, NS2, and NS3, are not required to assist or direct the formation of empty corelike particles from VP3 and VP7.     

Variation in Antiviral Protection Mediated by Different Wolbachia Strains in Drosophila simulans

Drosophila C virus (DCV) is a natural pathogen of Drosophila and a useful model for studying antiviral defences. The Drosophila host is also commonly infected with the widespread endosymbiotic bacteria Wolbachia pipientis. When DCV coinfects Wolbachia-infected D. melanogaster, virus particles accumulate more slowly and virus induced mortality is substantially delayed. Considering that Wolbachia is estimated to infect up to two-thirds of all insect species, the observed protective effects of Wolbachia may extend to a range of both beneficial and pest insects, including insects that vector important viral diseases of humans, animals and plants. Currently, Wolbachia-mediated antiviral protection has only been described from a limited number of very closely related strains that infect D. melanogaster. We used D. simulans and its naturally occurring Wolbachia infections to test the generality of the Wolbachia-mediated antiviral protection. We generated paired D. simulans lines either uninfected or infected with five different Wolbachia strains. Each paired fly line was challenged with DCV and Flock House virus. Significant antiviral protection was seen for some but not all of the Wolbachia strain-fly line combinations tested. In some cases, protection from virus-induced mortality was associated with a delay in virus accumulation, but some Wolbachia-infected flies were tolerant to high titres of DCV. The Wolbachia strains that did protect occurred at comparatively high density within the flies and were most closely related to the D. melanogaster Wolbachia strain wMel. These results indicate that Wolbachia-mediated antiviral protection is not ubiquitous, a finding that is important for understanding the distribution of Wolbachia and virus in natural insect populations.     

利用杆状病毒Bac-to-Bac系统在Sf9细胞中表达真菌细胞色素P450nor

利用BactoBac杆状病毒载体表达系统将真菌细胞色素P450nor基因克隆至转移载体pFastBac1中, 得到重组质粒pFastBacP450nor, 再将其转化进入含穿梭载体Bacmid的受体菌DH10Bac中发生转座作用, 得到含P450nor基因的重组穿梭载体rBacmid pAcP450nor。分离提取重组Bacmid DNA, 并转染培养的昆虫细胞Sf9, 得到重组病毒rAcp450nor。经酶切和PCR 鉴定, 细胞色素P450nor基因正确地插入到病毒基因组的多角体蛋白基因启动子下, SDSPAGE分析证明：表达蛋白的分子量为43kD左右。Western blotting分析结果表明：有一条特定的杂交带存在, 且分子量相同（约43kD）。进一步证明了含有真菌细胞色素P450nor基因的重组表达载体和重组病毒构建成功,并在昆虫细胞Sf9中实现了高效表达, 经MTT法测定表达的细胞色素P450nor具有还原NO的生物学活性。     

Characterization of Rice Black-Streaked Dwarf Virus- and Rice Stripe Virus-Derived siRNAs in Singly and Doubly Infected Insect Vector Laodelphax striatellus

Replication of RNA viruses in insect cells triggers an antiviral defense that is mediated by RNA interference (RNAi) which generates viral-derived small interfering RNAs (siRNAs). However, it is not known whether an antiviral RNAi response is also induced in insects by reoviruses, whose double-stranded RNA genome replication is thought to occur within core particles. Deep sequencing of small RNAs showed that when the small brown planthopper (Laodelphax striatellus) was infected by Rice black-streaked dwarf virus (RBSDV) (Reoviridae; Fijivirus), more viral-derived siRNAs accumulated than when the vector insect was infected by Rice stripe virus (RSV), a negative single-stranded RNA virus. RBSDV siRNAs were predominantly 21 and 22 nucleotides long and there were almost equal numbers of positive and negative sense. RBSDV siRNAs were frequently generated from hotspots in the 5′- and 3′-terminal regions of viral genome segments but these hotspots were not associated with any predicted RNA secondary structures. Under laboratory condition, L. striatellus can be infected simultaneously with RBSDV and RSV. Double infection enhanced the accumulation of particular genome segments but not viral coat protein of RBSDV and correlated with an increase in the abundance of siRNAs derived from RBSDV. The results of this study suggest that reovirus replication in its insect vector potentially induces an RNAi-mediated antiviral response.     

Phage formation in Staphylococcus muscae cultures. X. The relationship between virus synthesis,the release of bacterial ribonucleic acid,virus liberation,and cellular lysis

1. Under a variety of conditions in which cells are infected with one or a few virus particles and the host cells are killed, but no infective particles or virus material is formed as indicated by plaque count, one-step growth curve, or protein or desoxyribonucleic determinations, the cells neither lyse nor release ribonucleic acid into the medium. 2. The "killing" effect of S. muscae phage is separate from its lytic property. 3. The release of ribonucleic acid into the medium is not simply due to the killing of the cell by the virus, and ribonucleic acid is never found in the medium unless virus material is synthesized. 4. Infected cells of S. muscae synthesizing virus release ribonucleic acid into the medium before cellular lysis begins and before any virus is liberated. 5. The higher the phage yield the more ribonucleic acid is released into the medium before any virus is released. 6. Phage may be released from one strain of Staphylococcus muscae without cellular lysis, although bacterial lysis begins shortly after the virus is released. In another strain, infected under similar conditions, virus liberation occurs simultaneously with cellular lysis. 7. The viruses liberated from both bacterial strains appear to be the same in so far as they cannot be distinguished by serological tests, have the same plaque type and plaque size, and need the same amino acids added to the medium in order to grow. Furthermore, the virus liberated from one strain can infect and multiply in the other strain and vice versa. 8. It is suggested that virus synthesis, in S. muscae cells infected with one or a few phage particles, leads to a disturbance of the normal cellular metabolism, resulting in lysis of the host cell.     

Development of an insect vector cell culture and RNA interference system to investigate the functional role of fijivirus replication protein

An in vitro culture system of primary cells from white-backed planthopper, an insect vector of Southern rice black-streaked dwarf virus (SRBSDV), a fijivirus, was established to study replication of the virus. Viroplasms, putative sites of viral replication, contained the nonstructural viral protein P9-1, viral RNA, outer-capsid proteins, and viral particles in virus-infected cultured insect vector cells, as revealed by transmission electron and confocal microscopy. Formation of viroplasm-like structures in non-host insect cells upon expression of P9-1 suggested that the matrix of viroplasms observed in virus-infected cells was composed basically of P9-1. In cultured insect vector cells, knockdown of P9-1 expression due to RNA interference (RNAi) induced by synthesized double-stranded RNA (dsRNA) from the P9-1 gene strongly inhibited viroplasm formation and viral infection. RNAi induced by ingestion of dsRNA strongly abolished viroplasm formation, preventing efficient viral spread in the body of intact vector insects. All these results demonstrated that P9-1 was essential for viroplasm formation and viral replication. This system, combining insect vector cell culture and RNA interference, can further advance our understanding of the biological activities of fijivirus replication proteins.     

Yeast-like microorganisms in the scale insect Kermes quercus (Insecta,Hemiptera, Coccomorpha: Kermesidae). Newly acquired symbionts?

Scale insects, like other plant sap-consumers, are host to symbiotic microorganisms which provide them with the substances missing from their diet. In contrast to most scale insects, Kermes quercus (Linnaeus) was regarded as asymbiotic. Our histological and ultrastructural observations show that in the body of the feeding stages of K. quercus collected in two locations (Warsaw and Cracow), numerous yeast-like microorganisms occur. These microorganisms were localized in the cytoplasm of fat body cells. The yeast-like microorganisms were observed neither in other organs of the host insect nor in the eggs. These microorganisms did not cause any damage to the structure of the ovaries and the course of oogenesis of the host insect. The females infected by them produced about 1300 larvae. The lack of these microorganisms in the cytoplasm of eggs indicates that they are not transmitted transovarially from mother to offspring. Molecular analyses indicated that the microorganisms which reside in the body of K. quercus are closely related to the entomopathogenic fungi Cordyceps and Ophiocordyceps, which belong to the Sordariomycetes class within the Ascomycota. The role of yeast-like microorganisms to their host insects remains unknown; however, it has been suggested that they may represent newly acquired symbionts.     

Tubular Structure Induced by a Plant Virus Facilitates Viral Spread in Its Vector Insect

Rice dwarf virus (RDV) replicates in and is transmitted by a leafhopper vector in a persistent-propagative manner. Previous cytopathologic and genetic data revealed that tubular structures, constructed by the nonstructural viral protein Pns10, contain viral particles and are directly involved in the intercellular spread of RDV among cultured leafhopper cells. Here, we demonstrated that RDV exploited these virus-containing tubules to move along actin-based microvilli of the epithelial cells and muscle fibers of visceral muscle tissues in the alimentary canal, facilitating the spread of virus in the body of its insect vector leafhoppers. In cultured leafhopper cells, the knockdown of Pns10 expression due to RNA interference (RNAi) induced by synthesized dsRNA from Pns10 gene strongly inhibited tubule formation and prevented the spread of virus among insect vector cells. RNAi induced after ingestion of dsRNA from Pns10 gene strongly inhibited formation of tubules, preventing intercellular spread and transmission of the virus by the leafhopper. All these results, for the first time, show that a persistent-propagative virus exploits virus-containing tubules composed of a nonstructural viral protein to traffic along actin-based cellular protrusions, facilitating the intercellular spread of the virus in the vector insect. The RNAi strategy and the insect vector cell culture provide useful tools to investigate the molecular mechanisms enabling efficient transmission of persistent-propagative plant viruses by vector insects.     

Electron microscopy of the formation of wound tumor virus in abdominally inoculated insect vectors

Fifth-instar nymphs of Agallia constricta leafhoppers were injected abdominally with extracts from root tumors confining wound tumor virus (WTV). The insects were sacrificed at predetermined intervals, their internal organs dissected, fixed, embedded, sectioned, stained, and examined in a Siemens Elmiskop I. Sequential stages in virus development were reconstructed from consecutive samples of fatbody tissues. Changes resulting from the infection were: (i) a viroplasm, i.e., an accumulation of electron-dense aggregates; (ii) the appearance at the periphery of the viroplasm of a few fully formed virus particles recognized as virions; (iii) the formation of increasing numbers of individual virions, not only at the periphery but also in the viroplasm; (iv) the engulfing of virions within multimembranous structures; and (v) the formation of virus microcrystals either at the sites of former viroplasms, or at some distance. These morphological findings indicate that, following abdominal inoculation of WTV, the plant-pathogenic virus develops within the cytoplasmic matrix proper of insect vector cells. In addition to the fatbody tissues, WTV was detected in the epidermis, muscles, and trachea of abdominally inoculated insects, demonstrating the systemic invasion of the mechanically infected arthropod host. No virus was found in the gut tissues.     

Gene therapy for malignant glioma using Sindbis vectors expressing a fusogenic membrane glycoprotein

BACKGROUND: Malignant glioma has a dismal prognosis. It was previously shown that glioma cells are efficiently killed when they express a gene coding for a hyperfusogenic mutant of the gibbon ape leukemia virus envelope glycoprotein (GALV.fus). However, production of viral vectors expressing GALV.fus has proven problematic because the transgene is toxic to vector-producing cells of human origin. We reasoned that Sindbis-virus-based vectors might be ideal for GALV.fus gene transfer because high-titer stocks can easily be generated in hamster cells and Sindbis virus efficiently infects human tumor cells through the high-affinity 67 kDa laminin receptor. In addition, Sindbis virus nonstructural proteins are potent inducers of apoptosis, and Sindbis vector RNAs expressing fusogenic viral proteins have been shown to spread from cell-to-cell in membrane-formed infectious particles. METHODS: Sindbis virus replicon-containing particles were generated by co-transfecting vector and helper RNAs into baby hamster kidney (BHK-21) cells. Packaged beta-galactosidase and GALV.fus expressing Sindbis vectors were used to infect glioma cell lines, which were then compared for syncytial cytopathic effect, cell killing, and release of infectious virus-like particles containing the vector genome. Finally, the efficacy of GALV.fus and beta-galactosidase Sindbis vectors was compared in an orthotopic intracerebral U87 glioma xenograft model in nude mice. RESULTS: High-titer stocks (>10(9) infectious units (iu)/ml) of the GALV.fus and beta-galactosidase vectors were obtained. Glioma cells infected with the GALV.fus vector formed large syncytia which died rapidly by apoptosis and released infectious membrane-formed particles that could transfer vector genomes to uninfected cells. The GALV.fus vector had significantly greater antitumor therapeutic potency than the beta-galactosidase vector in the U87 glioma xenograft model. CONCLUSIONS: Sindbis vectors expressing GALV.fus can be packaged into infectious viral particles to high titer, they exhibit potent bystander cytopathic potential and are active against U87 glioma xenografts. Sindbis-virus-based replicons appear to be efficient vector systems for delivery and expression of fusogenic membrane glycoproteins.     

A Herpes Simplex Virus 2 Glycoprotein D Mutant Generated by Bacterial Artificial Chromosome Mutagenesis Is Severely Impaired for Infecting Neuronal Cells and Infects Only Vero Cells Expressing Exogenous HVEM

We constructed a herpes simplex virus 2 (HSV-2) bacterial artificial chromosome (BAC) clone, bHSV2-BAC38, which contains full-length HSV-2 inserted into a BAC vector. Unlike previously reported HSV-2 BAC clones, the virus genome inserted into this BAC clone has no known gene disruptions. Virus derived from the BAC clone had a wild-type phenotype for growth in vitro and for acute infection, latency, and reactivation in mice. HVEM, expressed on epithelial cells and lymphocytes, and nectin-1, expressed on neurons and epithelial cells, are the two principal receptors used by HSV to enter cells. We used the HSV-2 BAC clone to construct an HSV-2 glycoprotein D mutant (HSV2-gD27) with point mutations in amino acids 215, 222, and 223, which are critical for the interaction of gD with nectin-1. HSV2-gD27 infected cells expressing HVEM, including a human epithelial cell line. However, the virus lost the ability to infect cells expressing only nectin-1, including neuronal cell lines, and did not infect ganglia in mice. Surprisingly, we found that HSV2-gD27 could not infect Vero cells unless we transduced the cells with a retrovirus expressing HVEM. High-level expression of HVEM in Vero cells also resulted in increased syncytia and enhanced cell-to-cell spread in cells infected with wild-type HSV-2. The inability of the HSV2-gD27 mutant to infect neuronal cells in vitro or sensory ganglia in mice after intramuscular inoculation suggests that this HSV-2 mutant might be an attractive candidate for a live attenuated HSV-2 vaccine.     

Influence of a propagative plant virus on the fitness and wing dimorphism of infected and exposed insect vectors

To maximize fitness, plant pathogenic viruses may manipulate their arthropod vectors through direct and indirect (via the host plant) interactions. For many virus-vector-plant associations, insect feeding does not always lead to virus acquisition. In fact, many plant viruses, especially those that propagate into their vectors, are acquired at low rates. Although the majority of insects colonizing an infected plant escape from viral infection, they are still exposed to the indirect effects (i.e. the effect of plant metabolism modification following virus infection). Little information has been reported on the effects of plant viruses on insects that become infected versus those that do not (here referred to as “exposed”). The effect that the Maize mosaic virus (MMV) (Rhabdoviridae) exerts on the fitness and wing dimorphism of the planthopper vector, Peregrinus maidis (Hemiptera, Delphacidae), that developed on leaves from either young or old corn plants was examined. MMV exerted non-consistent to minimal direct effects on developmental time, longevity, nymphal mortality and fecundity. In addition, some small yet significant fitness costs were encountered by exposed planthoppers to escape MMV infection. Furthermore, a significantly higher proportion of macropters over brachypters were produced on MMV-infected old leaves compared with healthy leaves of a similar age. We conclude that the virus influences the dispersal of the vector, promoting a larger production of macropters at the costs of brachypters at a late stage of the plant infection. Because MMV infection in planthoppers did not segregate by wing morphotype, our results indicate that the dispersal of both infected and exposed planthoppers was a likely consequence of the indirect effects of MMV.     

Characterization of target cells for MCF viruses in AKR mice

The recombinant (MCF) class of murine leukemia virus appears to play an important role in lymphomagenesis in AKR and other mice. Although much effort has been extended in characterizing MCF viruses, relatively little is known about the cells they infect. I examined what cells were targets in AKR mice for both lymphomagenic and nonlymphomagenic MCF viruses. Lymphomagenic MCF viruses of thymic origin (AKR-247 and C58L1) were found to infect and replicate selectively in immature lymphocytes only present in thymic cortex, whereas nonlymphomagenic MCF viruses of splenic origin (C58v-1-C77 and C58v-2-C45) selectively infected and replicated in cells that appeared to B lymphocytes. Virus-binding studies suggested that neither T- nor B-lymphocyte tropisms were determined by selective attachment of virus to the respective cells. These findings demonstrate that in contrast with ecotropic viruses, which can infect many types of cells in the mouse, specific cellular tropisms can exist for MCF viruses, and that MCF infection, and therefore oncogenicity, is closely linked to cellular differentiation.     

Tumorigenicity of persistently infected tumors in nude mice is a function of both virus and host cell type.

Although BHK-21 cells persistently infected with wild-type vesicular stomatitis virus (VSV) are sensitive to natural killer (NK) cells and do not form tumors in athymic nude mice, BHK-21 cells persistently infected with a previously isolated mutant virus (VSV-P) are resistant to NK cells and form tumors in nude mice. We used this VSV-P mutant to persistently infect HeLa cells and mouse tumor cell lines. A mouse mastocytoma line (P815) persistently infected with VSV-P was similar to BHK-21 cells in that it was resistant to NK cell lysis and formed tumors in nude mice. However, neither HeLa cells nor mouse myeloma lines persistently infected with VSV-P were resistant to NK cell lysis in vitro, and neither formed tumors in nude mice. Rejection by nude mice of HeLa cells and mouse myeloma cell lines persistently infected with VSV-P could be ablated by rabbit antiserum to asialo-GM1, implicating NK cells in the in vivo rejection of these persistently infected tumors. These results suggest that NK cell recognition and killing of virus-infected cells in vivo and in vitro depend upon genetic contributions from both the virus and the host cell.     

Insect virus polyhedra, infectious protein crystals that contain virus particles

High-resolution atomic structures have been reported recently for two types of viral polyhedra, intracellular protein crystals produced by ubiquitous insect viruses. Polyhedra contain embedded virus particles and function as the main infectious form for baculoviruses and cypoviruses, two distinct classes of viruses that infect mainly Lepitoptera species (butterflies and moths). Polyhedra are extremely stable and protect the virus particles once released in the environment. The extensive crystal contacts observed in the structures explain the remarkable stability of viral polyhedra and provide hints about how these crystals dissolve in the alkaline midgut, releasing embedded virus particles to infect feeding larvae. The stage is now set to answer intriguing questions about the in vivo crystallization of polyhedra, how virus particles are incorporated into polyhedra, and what determines the size and shape of the crystals. Large quantities of polyhedra can be obtained from infected larvae and polyhedra can also be produced using insect cell expression systems. Modified polyhedra encapsulating other entities in place of virus particles have potential applications as a means to stabilize proteins such as enzymes or growth factors, and the extremely stable polyhedrin lattice may provide a framework for future engineered micro-crystal devices.     

Expression of the mouse c-abl type IV proto-oncogene product in the insect cell baculovirus system

The cellular gene c-abl is the normal homologue of the transforming gene (v-abl) within the genome of the Abelson leukaemia virus. The cDNA sequence coding for the cellular form of the murine abl gene (c-abl type IV) has been inserted into the baculovirus transfer vector, pAc36C, so that the c-abl gene is under the control of the polyhedrin promoter of Autographa californica nuclear polyhedrosis virus (AcNPV). Spodoptera frugiperda cells infected with the recombinant transfer vector in the presence of wild type AcNPV DNA yielded recombinant, polyhedrin negative virus that expressed moderate levesl of the c-Abl protein (representing approx. 0.5–1% of the stained cellular proteins as determined by densitometric scanning). The insect derived c-Abl protein was compared to the P210-BCR/ABL protein from K562 cells, a cell line derived from a patient with chronic myelogenous leukaemia. Antibodies raised againts synthetic peptides based on c-abl encoded peptides react with the insect derived c-Abl. In addition, the baculovirus derived c-Abl protein has a tyrosine kinase activity as demonstrated by phosphorylation of a synthetic polypeptide and also by autophosphorylation. Phosphoamino acid analysis of immunoprecipitated, autophosphorylated baculovirus derived c-Abl protein indicates that the majority of label incorporated is on the tyrosine residues. Immunofluorescence microscopy has been used to show that the majority of the c-Abl protein expressed in cells infected with recombinant virus is located in the nuclear and plasma membranes.     

Morphology and differential counts of hemocytes of healthy and wound tumor virus-infected Agallia constricta

Six types of hemocytes were found in Agallia constricta leafhoppers: plasmatocytes, spherule cells, granular hemocytes, adipohemocytes, oenocytoids, and prohemocytes. Plasmatocytes, spherule cells, and granular hemocytes accounted for 90–95% of all hemocytes in numphs and adult leafhoppers. As the insect aged from second- and third-instar nymphs to 7- and 8-week-old adults, there was a significant decrease in plasmatocytes in healthy leafhoppers compared to wound tumor virus-infected insects. In contradistinction, there were more granular and spherule hemocytes in healthy leafhoppers than in virus-infected ones as the insects aged. In general, there were more prohemocytes in infected than in healthy leafhoppers. Plasmatocytes from 4- to 8-week-old, infected leafhoppers contained large irregularly shaped, cytoplasmic inclusions. Electron microscopy of these cells showed that the inclusions were either large accumulations of wound tumor virus particles or virus-free electron dense bodies.     

表达绿色荧光蛋白的重组CVI988病毒的构建及特性

提取马立克氏病毒Ⅰ型疫苗毒株CVI988的总DNA为模板,利用PCR技术扩增出病毒生长非必需的US2基因并克隆入T—easy载体。将CMV启动子和增强子控制的含GFP基因表达盒克隆入US2基因中,成功构建了含GFP基因的转移质粒载体pGUS2GFP。用脂质体将其与CVI988株共转染CEF细胞,用96孔板稀释法得到纯化的表达绿色荧光蛋白的重组CVI988病毒株rCVIGFP,并分别测定其在体内和体外的生长情况。表达EGFP基因的重组病毒在细胞上生长曲线与亲本毒CVI988类似,体外实验表明,1日龄腹腔接种该重组毒后,可以从鸡体内分离到表达绿色荧光的病毒。     

Settling preferences of the whitefly vector Bemisia tabaci on infected plants varies with virus family and transmission mode

Virus infection may change not only the host‐plant phenotypic (morphological and physiological) characteristics, but can also modify the behavior of their insect vector in a mutualistic or rather antagonistic manner, to promote their spread to new hosts. Viruses differ in their modes of transmission and depend on vector behavior for successful spread. Here, we investigated the effects of the semi‐persistently transmitted Tomato chlorosis virus (ToCV, Crinivirus) and the persistent circulative Tomato severe rugose virus (ToSRV, Begomovirus) on alighting preferences and arrestment behavior of their whitefly vector Bemisia tabaci (Gennadius) (Hemiptera: Aleyrodidae) Middle East Asia Minor 1 (MEAM1) on tomato plants (Solanum lycopersicum L. cv. Santa Clara, Solanaceae). The vector alighting preferences between infected and uninfected plants in choice assays were apparently influenced by the presence of ToCV and ToSRV in the whiteflies or by their previous exposure to infected plants. The observed changes in vector behavior do not seem to benefit the spread of ToCV: non‐viruliferous insects clearly preferred mock‐inoculated plants, whereas ToCV‐viruliferous insects landed on mock‐inoculated and ToCV‐infected plants, indicating a partial change in insect behavior – ToCV was able to directly affect the preference of its vector B. tabaci, but this change in insect behavior did not affect the virus spread because viruliferous insects landed on mock‐inoculated and infected plants indistinctly. In contrast, ToSRV‐viruliferous insects preferred to land on mock‐inoculated plants, a behavior that increases the probability of spread to new host plants. In the arresting behavior assay, the majority of the insects remained on mock‐inoculated plants when released on them. A greater number of insects moved toward mock‐inoculated plants when initially released on ToCV‐ or ToSRV‐infected plants, suggesting that these viruses may repel or reduce the nutritional quality of the host plants for B. tabaci MEAM1.     

在昆虫细胞中同时表达蓝舌病毒VP3与VP7蛋白可装配成核心样颗粒

将蓝舌病毒（ＢＴＶ）１３型Ｓ７与Ｌ３基因同时插入杆状病毒双表达载体ｐＥａｓｔＢａｃＤｕａｌ,获得重组杆状病毒ｒｖＢａｃＢＴＶＰ３７。该病毒在昆虫细胞中同时高水平表达ＢＴＶ１３ ＶＰ３与ＶＰ７蛋白,可以高效自动装配出２０面体的６０￣７０ｎｍ空心颗粒。分析表明,所获颗粒为空心的ＢＴＶ核心样颗粒（ＣＬＰ）,其成分为ＶＰ３与ＶＰ７,不含ＢＴＶ其它任何蛋白与核酸。这种装配需要ＶＰ３与ＶＰ７的共同参与,二者缺