Resistance ofSpodoptera frugiperda [Lep.: Noctuidae] to a nuclear polyhedrosis virus in the field and laboratory

Median lethal doses (LD₅₀s) of nuclear polyhedrosis virus (NPV) were determined in neonatal offspring ofSpodoptera frugiperda (J. E. Smith) (Sf) larvae captured in southeastern Louisiana in 1981, 1982, and 1984. These LD₅₀s ranged from 1.8 to 16.3 polyhedral inclusion bodies (PIB)/insect. The LD₅₀s significantly (P<0.05) increased during the season of 1982 but had no pattern in 1981 or 1984. However, the Sf populations increased in heterogeneity of response to the NPV during all 3 years. The LD₅₀ increased from 4.1 to 18.7 PIB/insect in a Sf laboratory colony exposed to the NPV LD₈₀ for 7 generations, whereas in a control colony not exposed to NPV the LD₅₀ was 5.9 PIB/insect after 7 generations.     

Identification of bluetongue virus VP6 protein as a nucleic acid-binding protein and the localization of VP6 in virus-infected vertebrate cells.

Recently the insect baculovirus Autographa californica nuclear polyhedrosis virus (AcNPV) has been effectively adapted as a highly efficient vector in insect cells for the expression of various genes. A cDNA sequence of RNA segment 9 of bluetongue virus serotype 10 (BTV-10, an orbivirus member of the Reoviridae family) encoding a minor core protein (VP6) has been inserted into the BamHI site of the pAcYM1 transfer vector derived from AcNPV. Spodoptera frugiperda cells were cotransfected with the derived vector in the presence of authentic AcNPV DNA to produce recombinant viruses. These synthesized significant amounts of a protein (representing ca. 50% of the stained cellular protein) similar in size and antigenicity to the authentic BTV VP6. The expressed protein was identified as a nucleic acid-binding protein by using an RNA overlay-protein blot assay. A polyclonal anti-VP6 serum prepared by using the expressed VP6 protein has been used in an immunogold procedure to locate VP6 in BTV-infected mammalian cells. Gold was found to be associated with the matrix of virus inclusion bodies (VIB), with viruslike particles in the VIB, as well as with mature virion particles that were in close proximity to the VIB or were released from cells and adsorbed to cell surfaces. The recombinant virus antigen has also been used to identify antibodies to different BTV serotypes in infected sheep sera, indicating the potential of the expressed protein as a group-reactive antigen for the diagnosis of BTV infections.     

Expression of YAV proteins and vaccination against viral ascites among cultured juvenile yellowtail

Yellowtail ascites virus (YAV) is a member of the family Birnaviridae and causes viral ascites among juvenile yellowtail (Seriola quinqueradiata). We have reported the cloning and expression of two viral cDNAs, the first being segment A encoding a polyprotein of viral capsid proteins (VP2 and VP3) and a protease (NS), and the second being VP2-epitope encoding serotype-specific epitope region on VP2, using a baculovirus expression system. Another viral cDNA encoding a polyprotein of NS and VP3 was cloned and expressed in this study. For the expression of NS/VP3 (YAV nt 1626 to 3066) in insect cells a 31-kDa protein, corresponding to VP3 was detected, indicating an appropriate posttranslational processing of NS/VP3 polypeptide by NS protease itself. The analysis of the N-terminal amino acid sequence of this protein showed that NS protease may cleave an Ala-Ser bond. A study of the potential for vaccination of yellowtail fry by injection of insect cell lysates infected with baculovirus, containing either cDNA of segment A, VP2-epitope, or NS/VP3 was undertaken. Only a vaccination with cell lysates infected with a recombinant virus carrying the full length of YAV segment A gene demonstrated approximately the same effect as that of inactivated YAV. This result suggested that all proteins VP2, VP3, and NS are required for an effective vaccination.     

Replication of Heliothis zea nuclear polyhedrosis virus in cloned cell lines

Clones from two Heliothis zea (Lepidoptera:Noctuidae) ovarian cell lines, BCIRL-Hz-AM1 (AM1) and BCIRL-Hz-AM3 (AM3), were generated and their ability to produce H. zea nuclear polyhedrosis virus (HzSNPV) was compared. Titers of extracellular virus (ECV) ranged from 5.5 (AM3-F9) to 44.9 x 10(5) PFU/ml (AM1-A4), with the parental cell lines AM3 and AM1 producing 14.8 and 26.4 x 10(5) PFU/ml, respectively. Concentrations of polyhedral inclusion bodies (PIB) produced by the cloned lines ranged from 0.7 (AM3-F9) to 59.6 x 10(6) PIB/ml (AM1-B3), while the parental cell lines generated 6.5 (AM3) and 12.9 x 10(6) PIB/ml (AM1). The percentage of cells from the cloned lines that produced PIB ranged from 39 to 86.4% for AM3-F9 and AM1-A7, respectively, with the parental lines exhibiting 49.1% (AM3) and 75.3% (AM1) cells with PIB. The number of PIB per cell also differed markedly between cell lines, varying from 18.3 (AM3-F9) to 184.4 (AM1-B3) PIB/cell. The parental lines produced 57.3 (AM3) and 75.9 (AM1) PIB/cell. Thus, significant differences were seen in virus production (ECV, PIB) between parental cell lines, as well as between parental cell lines and their clones. In addition, cell lines were characterized with regard to their growth rates and isoenzyme patterns.     

Effects of temperature and lipophilic agents on poliovirus formation and RNA synthesis in a cell-free system.

The translation and primary processing events of poliovirus polyproteins in HeLa cell extracts were more efficient at 34 degrees C than at 30 or 36 degrees C. The cleavage products of P2 such as 2Apro, 2BC, and 2C appeared early in the reaction before the appearance of the cleavage products of P1 and of 3CDpro, an observation suggesting that P2 was cleaved in cis by 3CDpro. Proteolytic processing of the capsid precursor P1 into VP0, VP1, and VP3 was also more efficient at 34 degrees C than at either 30 or 32 degrees C. Surprisingly, processing of 3CDpro to 3Cpro and 3Dpol was almost completely inhibited at 36 degrees C. The synthesis of virus in the cell extract was greatly enhanced at 34 degrees C over that at 30 or 32 degrees C, whereas incubation at 36 degrees C yielded very little virus. Cerulenin, an inhibitor of lipid synthesis, did not appear to affect virus-specific translation or protein processing, but it almost completely inhibited viral synthesis in vitro. Oleic acid drastically inhibited in vitro translation at 100 microM and in vitro poliovirus synthesis at 25 microM. Addition of HeLa cell smooth membranes partially restored translation but not virus formation. Our observations suggest that in vitro translation, proteolytic processing, and virus formation require intact membranes. Analysis of the in vitro translation products revealed that viral RNA polymerase activity increased linearly during incubation of the translation mixture. RNA polymerase in the crude mixture was inhibited by oleic acid but not by cerulenin. Surprisingly, oleic acid had no direct effect on oligo(U)-primed, poly(A)-dependent poly(U) synthesis catalyzed by purified 3Dpol.     

Evidence of Pluronic F-68 direct interaction with insect cells: impact on shear protection, recombinant protein, and baculovirus production*

Pluronic F-68 has been widely used to protect animal cells from hydrodynamic stress, but its mechanism of action is still debatable. Published evidence indicates that Pluronic F-68 interacts with cells, yet scarce information exists of its effect on recombinant protein and virus production by insect cells. In this work, the effect of Pluronic F-68 on production of recombinant baculovirus and rotavirus protein VP7 was determined. Evidence of Pluronic F-68 direct interaction with Sf-9 insect cells also was obtained. Maximum recombinant VP7 concentration and yield increased 10x, whereas virus production decreased by 20x, in spinner flask cultures with 0.05% (w/v) Pluronic F-68 compared to controls lacking the additive. No differences were observed in media rheology, nor kinetics of growth and infection (as inferred from cell size) between both cultures. Hence, Pluronic F-68 influenced cell physiology independently of its shear protective effect. Cells subjected to a laminar shear rate of 3000 s(-1) for 15 min, without gas/liquid interfaces, were protected by Pluronic F-68 even after its removal from culture medium. Furthermore, the protective action was immediate in vortexed cells. The results shown here indicate that Pluronic F-68 physically interacts with cells in a direct, strong, and stable mode, not only protecting them from hydrodynamic damage, but also modifying their capacity for recombinant protein and virus production.     

Assembly of the herpes simplex virus procapsid from purified components and identification of small complexes containing the major capsid and scaffolding proteins

An in vitro system is described for the assembly of herpes simplex virus type 1 (HSV-1) procapsids beginning with three purified components, the major capsid protein (VP5), the triplexes (VP19C plus VP23), and a hybrid scaffolding protein. Each component was purified from insect cells expressing the relevant protein(s) from an appropriate recombinant baculovirus vector. Procapsids formed when the three purified components were mixed and incubated for 1 h at 37 degrees C. Procapsids assembled in this way were found to be similar in morphology and in protein composition to procapsids formed in vitro from cell extracts containing HSV-1 proteins. When scaffolding and triplex proteins were present in excess in the purified system, greater than 80% of the major capsid protein was incorporated into procapsids. Sucrose density gradient ultracentrifugation studies were carried out to examine the oligomeric state of the purified assembly components. These analyses showed that (i) VP5 migrated as a monomer at all of the protein concentrations tested (0.1 to 1 mg/ml), (ii) VP19C and VP23 migrated together as a complex with the same heterotrimeric composition (VP19C1-VP232) as virus triplexes, and (iii) the scaffolding protein migrated as a heterogeneous mixture of oligomers (in the range of monomers to approximately 30-mers) whose composition was strongly influenced by protein concentration. Similar sucrose gradient analyses performed with mixtures of VP5 and the scaffolding protein demonstrated the presence of complexes of the two having molecular weights in the range of 200,000 to 600,000. The complexes were interpreted to contain one or two VP5 molecules and up to six scaffolding protein molecules. The results suggest that procapsid assembly may proceed by addition of the latter complexes to regions of growing procapsid shell. They indicate further that procapsids can be formed in vitro from virus-encoded proteins only without any requirement for cell proteins.     

Influence of larval stage and virus inoculum on virus yield in insect host Neodiprion abietis (Hymenoptera: Diprionidae)

Virus yield produced by dead larvae of balsam fir sawfly, Neodiprion abietis (Harris) (Hymenoptera: Diprionidae), that had been infected at four different larval stages (second, third, fourth, or fifth instar) with two virus concentrations (10(5) polyhedral inclusion bodies (PIB) /ml or 10(7) PIB/ml), were analyzed and compared to determine the effects of instar and amount of virus inoculum on virus production. The results indicate that both larval stage and inoculation dosage significantly affect virus yield. On average, each dead larva produced 1.36-12.21 x 10(7) PIB, depending upon larval age and virus concentration of inoculation. Although each dead larva produced more PIB when it was inoculated in the fourth or fifth stage, inoculation of these larvae did not result in the highest virus yield because of low larval mortality. In terms of net virus return, third instars would maximize virus yield when they are inoculated with a virus concentration that can cause 95-100% larval mortality.     

DNA encapsidation by viruslike particles assembled in insect cells from the major capsid protein VP1 of B-lymphotropic papovavirus.

Capsids of polyomaviruses--small, nonenveloped DNA viruses--consist of the major structural protein VP1 and the minor structural proteins VP2 and VP3. The contributions of the individual capsid proteins to functions of the viral particle, such as DNA encapsidation, cell receptor attachment, entry, and uncoating, are still not clear. Here we show that viruslike particles assembled in nuclei of insect cells from VP1 of the monkey B-lymphotropic papovavirus (LPV) are sufficient to unspecifically encapsidate DNA. LPV VP1 expressed in large amounts in insect cells by a baculovirus vector assembled spontaneously in the nuclei to form viruslike particles. After metrizamide equilibrium density gradient purification and nuclease digestion, a fraction of these particles was shown to contain VP1-associated linear, double-stranded DNA with a predominant size of 4.5 kb. The fraction of DNA-containing VP1 particles increased with time and dose of baculovirus vector infection. The DNA-containing particles, further purified by sucrose gradient centrifugation, appeared as "full" particles in negative-staining electron microscopy. As shown by DNA hybridization, the encapsidated DNA consisted of insect cell and baculoviral sequences with no apparent strong homology to LPV sequences. Three non-LPV VP1-derived host proteins with apparent molecular masses of approximately 14, 15, and 16 kDa copurified with the DNA-containing particles and may represent insect cell histones encapsidated together with the DNA. A similar species of host DNA was also found in purified LPV wild-type virions. These data suggest that LPV VP1 alone can be sufficient to encapsidate linear DNA in a sequence-independent manner.     

Expression of largest RNA segment and synthesis of VP1 protein of bluetongue virus in insect cells by recombinant baculovirus: association of VP1 protein with RNA polymerase activity.

The bluetongue virus core particles have been shown to contain an RNA-directed RNA polymerase (1). To identify the protein responsible for the virion RNA polymerase activity, the complete 3.9 Kb DNA clone representing the largest RNA segment 1 (L1) of bluetongue virus (BTV-10) was placed under control of the polyhedrin promoter of Autographa californica nuclear polyhedrosis virus (AcNPV). The derived recombinant virus was used to infect Spodoptera frugiperda cells. As demonstrated by stained polyacrylamide gel electrophoresis and by the use of bluetongue virus antibody, infected insect cells synthesized the largest protein of BTV-10 (VP1, 150 k Da). Antibody raised in rabbit to recombinant VP1 protein recognized bluetongue virus VP1 protein. The recombinant virus infected cell lysate had significantly inducible levels of RNA polymerase enzymatic activity as determined by a poly (U)-oligo (A) polymerase assay. The availability of enzymatically active bluetongue virus RNA polymerase provides a system in which we can precisely delineate the role this protein plays in the regulation of bluetongue replication.     

Altering the expression kinetics of VP5 results in altered virulence and pathogenesis of herpes simplex virus type 1 in mice

While many herpes simplex virus (HSV) structural proteins are expressed with strict-late kinetics, the HSV virion protein 5 (VP5) is expressed as a "leaky-late" protein, such that appreciable amounts of VP5 are made prior to DNA replication. Our goal has been to determine if leaky-late expression of VP5 is a requirement for a normal HSV infection. It had been shown previously that recombinant viruses in which the VP5 promoter was replaced with promoters of other kinetic classes (including a strict late promoter) exhibited no alterations in replication kinetics or virus yields in vitro. In contrast, here we report that alterations in pathogenesis were observed when these recombinants were analyzed by experimental infection of mice. Following intracranial inoculation, a recombinant expressing VP5 from a strict-late promoter (U(L)38) exhibited an increased 50% lethal dose and a 10-fold decrease in virus yields in the central nervous system, while a recombinant expressing VP5 from an early (dUTPase) or another leaky-late (VP16) promoter exhibited wild-type neurovirulence. Moreover, following infection of the footpad, changing the expression kinetics of VP5 from leaky-late to strict-late resulted in 100-fold-less virus in the spinal ganglia during the acute infection than produced by either the parent virus or the rescued virus. These data indicate that the precise timing of appearance of the major capsid protein plays a role in the pathogenesis of HSV infections and that changing the expression kinetics has different effects in different cell types and tissues.     

Downstream processing of triple layered rotavirus like particles

Rotavirus like particles (RLPs) constitute a potential vaccine for the prevention of rotavirus disease, responsible for the death of more than half a million children each year. Increasing demands for pre-clinical trials material require the development of reproducible, scaleable and cost-effective purification strategies as alternatives to the traditional laboratory scale CsCl density gradient ultracentrifugation methods commonly used for the purification of these complex particles. Self-assembled virus like particles (VLPs) composed by VP2, VP6 and VP7 rotavirus proteins (VLPs 2/6/7) were produced in 5l scale using the insect cells/baculovirus expression system. A purification process using depth filtration, ultrafiltration and size exclusion chromatography as stepwise unit operations was developed. Removal of non-assembled rotavirus proteins, concurrently formed particles (RLP 2/6), particle aggregates and products of particle degradation due to shear was achieved. Particle stability during storage was studied and assessed using size exclusion chromatography as an analytical tool. Formulations containing either glycerol (10% v/v) or trehalose (0.5 M) were able to maintain 75% of intact triple layered VLPs, at 4 degrees C, up to 4 months. The overall recovery yield was 37% with removal of 95% of host cell proteins and 99% of the host cell DNA, constituting a promising strategy for the downstream processing of other VLPs.     

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.     

Processing of infectious bursal disease virus (IBDV) polyprotein and self-assembly of IBDV-like particles in Hi-5 cells

The capsid of infectious bursal disease virus (IBDV), with a size of 60-65 nm, is formed by an initial processing of polyprotein (pVP2-VP4-VP3) by VP4, subsequent assemblage of pVP2 and VP3, and the maturation of VP2. In Sf9 cells, the processing of polyprotein expressed was restrained in the stage of VP2 maturation, leading to a limited production of capsid, i.e., IBDV-like particles (VLPs). In the present study, another insect cell line, High-Five (Hi-5) cells, was demonstrated to efficiently produce VLPs. Meanwhile, in this system, polyprotein was processed to pVP2 and VP3 protein and pVP2 was further processed to the matured form of VP2. Consequently, Hi-5 cells are better in terms of polyprotein processing and formation of VLPs than Sf9. In addition to the processing of pVP2, VP3 was also degraded. With insufficient intact VP3 protein present for the formation of VLPs, the excessive VP2 form subviral particles (SVPs) with a size of about 25 nm. The ratio of VLPs to SVPs is dependent on the multiplicity of infections (MOIs) used, and an optimal MOI is found for the production of both particles. VLPs were separated from SVPs with a combination of ultracentrifugation and gel-filtration chromatography, and a large number of purified particles of both were obtained. In conclusion, the insect cell lines and MOIs were optimized for the production of VLPs, and pure VLPs with morphology similar to that of the wild-type viruses can be effectively prepared. The efficient production and purification of VLPs benefits not only the development of an antiviral vaccine against IBDV but also the understanding of the structure of this avian virus that is economically important.     

In vitro production studies with a wild-type Helicoverpa baculovirus

The potential use of a wild-type Helicoverpa baculovirus as a biopesticide, using insect cell culture for its production, has been investigated. A Helicoverpa zea cell line was adapted to grow in suspension culture using a serum-free medium, SF900II and serum supplemented SF900II. The serum supplemented cells were infected with a wild-type nuclear polyhedrosis virus of Helicoverpa armigera (HaNPV), at different stages of growth, in conditioned and tresh medium, to determine the effect of cell density on polyhedra production. Cultures infected at low cell densities, produced similar yields of virus (20–40 PIB/cell), irrespective of medium conditions. However, in infections which occurred at high cell densities, there was a 16-fold improvement in cell specific yields, when the spent medium was renewed with fresh medium prior to infection. Results indicated that only 60–70% of the viable cells in a culture produced polyhedra as a result of infections.     

Replication and infectivity of the single-embedded nuclear polyhedrosis virus, Baculovirus heliothis, in homologous cell lines

Three cell lines of Heliothis zea and one cell line of Heliothis virescens replicated the singleembedded, nuclear polyhedrosis virus (NPV) of H. Zea, (i.e., Baculovirus heliothis) with concomitant production of polyhedral inclusion bodies (PIB). Between 20 and 60% of the H. zea cells produced PIB, whereas only 3% of H. virescens cells were found to produce PIB. The H. zea cell lines produced 10 to 20 times more PIB than did the H. virescens cell line. The PIB from all cell lines produced typical symptoms of an NPV infection when bioassayed against larvae of H. zea. More than 99% of the total viral activity of the final whole culture was due to the PIB.     

Whole-genome expression profiling reveals that inhibition of host innate immune response pathways by Ebola virus can be reversed by a single amino acid change in the VP35 protein

Ebola hemorrhagic fever is a rapidly progressing acute febrile illness characterized by high virus replication, severe immunosuppression, and case fatalities of ca. 80%. Inhibition of phosphorylation of interferon regulatory factor 3 (IRF-3) by the Ebola VP35 protein may block the host innate immune response and play an important role in the severity of disease. We used two precisely defined reverse genetics-generated Ebola viruses to investigate global host cell responses resulting from the inhibition of IRF-3 phosphorylation. The two viruses encoded either wild-type (WT) VP35 protein (recEbo-VP35/WT) or VP35 with an arginine (R)-to-alanine (A) amino acid substitution at position 312 (recEbo-VP35/R312A) within a previously defined IRF-3 inhibitory domain. When sucrose-gradient purified virus was used for infection, host cell whole-genome expression profiling revealed striking differences in human liver cell responses to these viruses differing by a single amino acid. The inhibition of host innate immune responses by WT Ebola virus was so potent that little difference in interferon and antiviral gene expression could be discerned between cells infected with purified WT, inactivated virus, or mock-infected cells. However, infection with recEbo-VP35/R312A virus resulted in a strong innate immune response including increased expression of MDA-5, RIG-I, RANTES, MCP-1, ISG-15, ISG-54, ISG-56, ISG-60, STAT1, IRF-9, OAS, and Mx1. The clear gene expression differences were obscured if unpurified virus stocks were used to initiate infection, presumably due to soluble factors present in virus-infected cell supernatant preparations. Ebola virus VP35 protein clearly plays a pivotal role in the potent inhibition of the host innate immune responses, and the present study indicates that VP35 has a wider effect on host cell responses than previously shown. The ability to eliminate this inhibitory effect with a single amino acid change in VP35 demonstrates the critical role this protein must play in the severe aspects this highly fatal disease.     

The oligomerization domain of VP3, the scaffolding protein of infectious bursal disease virus,plays a critical role in capsid assembly

Infectious bursal disease virus (IBDV) capsids are formed by a single protein layer containing three polypeptides, pVP2, VP2, and VP3. Here, we show that the VP3 protein synthesized in insect cells, either after expression of the complete polyprotein or from a VP3 gene construct, is proteolytically degraded, leading to the accumulation of product lacking the 13 C-terminal residues. This finding led to identification of the VP3 oligomerization domain within a 24-amino-acid stretch near the C-terminal end of the polypeptide, partially overlapping the VP1 binding domain. Inactivation of the VP3 oligomerization domain, by either proteolysis or deletion of the polyprotein gene, abolishes viruslike particle formation. Formation of VP3-VP1 complexes in cells infected with a dual recombinant baculovirus simultaneously expressing the polyprotein and VP1 prevented VP3 proteolysis and led to efficient virus-like particle formation in insect cells.