On the classification and nomenclature of baculoviruses: a proposal for revision.

Recent evidence from genome sequence analyses demands a substantial revision of the taxonomy and classification of the family Baculoviridae. Comparisons of 29 baculovirus genomes indicated that baculovirus phylogeny followed the classification of the hosts more closely than morphological traits that have previously been used for classification of this virus family. On this basis, dipteran- and hymenopteran-specific nucleopolyhedroviruses (NPV) should be separated from lepidopteran-specific NPVs and accommodated into different genera. We propose a new classification and nomenclature for the genera within the baculovirus family. According to this proposal the updated classification should include four genera: Alphabaculovirus (lepidopteran-specific NPV), Betabaculovirus (lepidopteran-specific Granuloviruses), Gammabaculovirus (hymenopteran-specific NPV) and Deltabaculovirus (dipteran-specific NPV).

Measurement of membrane fusion activity from viral membrane fusion proteins based on a fusion-dependent promoter induction system in insect cells.

A number of viral membrane fusion proteins can be expressed alone on the surface of host cells, and then triggered to induce cell-to-cell fusion or syncytium formation. Although rapid and easily observed, syncytium formation is not easily quantified and differences in fusion activity are not easily distinguished or measured. To address this problem, we developed a rapid and quantitative cell-to-cell fusion system that is useful for comparative analysis and may be suitable for high throughput screening. In this system, expression of a reporter protein, enhanced green fluorescent protein (EGFP), is dependent on cell-to-cell fusion. Spodoptera frugiperda (Sf9) insect cells expressing a chimeric Lac repressor-IE1 protein were fused to Sf9 cells containing an EGFP reporter construct under the control of a responsive lac operator-containing promoter. Membrane fusion efficiency was measured from the resulting EGFP fluorescence activity. Sf9 cells expressing the Orgyia pseudotsugata multicapsid nucleopolyhedrovirus (OpMNPV) GP64 envelope fusion protein were used as a model to test this fusion assay. Subtle changes in fusion activities of GP64 proteins containing single amino acid substitutions in a putative membrane fusion domain were distinguished, and decreases in EGFP fluorescence corresponded to decreases in the hydrophobicity in the small putative membrane fusion domain.

Stable cell lines expressing baculovirus P35: resistance to apoptosis and nutrient stress, and increased glycoprotein secretion.

The baculovirus P35 protein is a caspase inhibitor that prevents the induction of apoptosis during infection of Sf21 cells by Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV). P35 inhibits the induction of apoptosis in a broad range of cells and circumstances. In this study, we examined the effects of constitutive cellular P35 expression on the response of cells to stressful culture conditions and on protein production in AcMNPV infected cells. Sf9 cell lines expressing AcMNPV P35 or an epitope-tagged P35 protein were generated using a double selection technique, involving selection in the antibiotic G418, followed by a second round of selection by exposure to actinomycin D, a potent inducer of apoptosis in Sf9 cells. Clonal cell lines were generated and examined for (1) resistance to actinomycin D induced apoptosis, (2) resistance to nutrient deprivation, and (3) baculovirus expression of intracellular and secreted proteins. When compared with Sf9 cells, two P35-expressing cell lines (Sf9P35AcV5-1 and Sf9P35AcV5-3) showed increased resistance to actinomycin D-induced apoptosis and a profound resistance to nutrient deprivation. When these cell lines were infected with a recombinant baculovirus expressing a secreted glycoprotein (secreted alkaline phosphatase), expression of the glycoprotein from these cells exceeded that from the parental Sf9 cells and was comparable to expression levels obtained from Tn5B1-4 cells, the best available cell line for high-level expression. Increased levels of protein secretion in Sf9P35AcV5-1 and Sf9P35AcV5-3 cells appear to result from a prolonged infection cycle and accumulation of the secreted glycoprotein.

A GP64-null baculovirus pseudotyped with vesicular stomatitis virus G protein.

The Autographa californica multiple nucleopolyhedrovirus (AcMNPV) GP64 protein is an essential virion protein that is involved in both receptor binding and membrane fusion during viral entry. Genetic studies have shown that GP64-null viruses are unable to move from cell to cell and this results from a defect in the assembly and production of budded virions (BV). To further examine requirements for virion budding, we asked whether a GP64-null baculovirus, vAc(64-), could be pseudotyped by introducing a heterologous viral envelope protein (vesicular stomatitis virus G protein [VSV-G]) into its membrane and whether the resulting virus was infectious. To address this question, we generated a stably transfected insect Sf9 cell line (Sf9(VSV-G)) that inducibly expresses the VSV-G protein upon infection with AcMNPV Sf9(VSV-G) and Sf9 cells were infected with vAc(64-), and cells were monitored for infection and for movement of infection from cell to cell. vAc(64-) formed plaques on Sf9(VSV-G) cells but not on Sf9 cells, and plaques formed on Sf9(VSV-G) cells were observed only after prolonged intervals. Passage and amplification of vAc(64-) on Sf9(VSV-G) cells resulted in pseudotyped virus particles that contained the VSV-G protein. Cell-to-cell propagation of vAc(64-) in the G-expressing cells was delayed in comparison to wild-type (wt) AcMNPV, and growth curves showed that pseudotyped vAc(64-) was generated at titers of approximately 10(6) to 10(7) infectious units (IU)/ml, compared with titers of approximately 10(8) IU/ml for wt AcMNPV. Propagation and amplification of pseudotyped vAc(64-) virions in Sf9(VSV-G) cells suggests that the VSV-G protein may either possess the signals necessary for baculovirus BV assembly and budding at the cell surface or may otherwise facilitate production of infectious baculovirus virions. The functional complementation of GP64-null viruses by VSV-G protein was further demonstrated by identification of a vAc(64-)-derived virus that had acquired the G gene through recombination with Sf9(VSV-G) cellular DNA. GP64-null viruses expressing the VSV-G gene were capable of productive infection, replication, and propagation in Sf9 cells.

A novel baculovirus envelope fusion protein with a proprotein convertase cleavage site.

The entry mechanism of Spodoptera exigua multicapsid nucleopolyhedrovirus (SeMNPV), a group II NPV, in cultured cells was examined. SeMNPV budded virus (BV) enters by endocytosis as do the BVs of the group I NPVs, Autographa californica (Ac) MNPV and Orgyia pseudotsugata (Op) MNPV. In group I NPVs, upon infection acidification of the endosome triggers fusion of the viral and endosomal membrane, which is mediated by the BV envelope glycoprotein GP64. However, the SeMNPV genome lacks a homolog of GP64 envelope fusion protein (EFP). A functional homolog of the OpMNPV GP64 EFP was identified in SeMNPV ORF8 (Se8; 76 kDa) and appeared to be the major BV envelope protein. Surprisingly, a 60-kDa cleavage product of this protein is present in the BV envelope. A furin-like proprotein convertase cleavage site (R-X-K/R-R) was identified immediately upstream of the N-terminus of the mature Se8 protein and this site was also conserved in the Lymantria dispar (Ld) MNPV homolog (Ld130) of Se8. Syncytium formation assays showed that Se8 and Ld130 alone were sufficient to mediate membrane fusion upon acidification of the medium. Furthermore, C-terminal GFP-fusion proteins of Se8 and Ld130 were primarily localized in the plasma membrane of insect cells. This is consistent with their fusogenic activity and supports the conclusion that the Se8 gene product is a functional homolog of the GP64 EFP.

A discrete stage of baculovirus GP64-mediated membrane fusion.

Viral fusion protein trimers can play a critical role in limiting lipids in membrane fusion. Because the trimeric oligomer of many viral fusion proteins is often stabilized by hydrophobic 4-3 heptad repeats, higher-order oligomers might be stabilized by similar sequences. There is a hydrophobic 4-3 heptad repeat contiguous to a putative oligomerization domain of Autographa californica multicapsid nucleopolyhedrovirus envelope glycoprotein GP64. We performed mutagenesis and peptide inhibition studies to determine if this sequence might play a role in catalysis of membrane fusion. First, leucine-to-alanine mutants within and flanking the amino terminus of the hydrophobic 4-3 heptad repeat motif that oligomerize into trimers and traffic to insect Sf9 cell surfaces were identified. These mutants retained their wild-type conformation at neutral pH and changed conformation in acidic conditions, as judged by the reactivity of a conformationally sensitive mAb. These mutants, however, were defective for membrane fusion. Second, a peptide encoding the portion flanking the GP64 hydrophobic 4-3 heptad repeat was synthesized. Adding peptide led to inhibition of membrane fusion, which occurred only when the peptide was present during low pH application. The presence of peptide during low pH application did not prevent low pH-induced conformational changes, as determined by the loss of a conformationally sensitive epitope. In control experiments, a peptide of identical composition but different sequence, or a peptide encoding a portion of the Ebola GP heptad motif, had no effect on GP64-mediated fusion. Furthermore, when the hemagglutinin (X31 strain) fusion protein of influenza was functionally expressed in Sf9 cells, no effect on hemagglutinin-mediated fusion was observed, suggesting that the peptide does not exert nonspecific effects on other fusion proteins or cell membranes. Collectively, these studies suggest that the specific peptide sequences of GP64 that are adjacent to and include portions of the hydrophobic 4-3 heptad repeat play a dynamic role in membrane fusion at a stage that is downstream of the initiation of protein conformational changes but upstream of lipid mixing.

Modulation of translational efficiency by contextual nucleotides flanking a baculovirus initiator AUG codon.

In a previous study of translational regulation of a baculovirus gene, we observed that translation initiated at an unexpectedly high efficiency from an AUG codon found in what was believed to be a poor context (M.-J. Chang and G. W. Blissard, 1997, J. Virol. 71, 7448-7460). In the current study, we examined the roles of nucleotides flanking a baculovirus AUG initiator codon in modulating translation initiation in lepidopteran insect cells. The roles of nucleotides flanking the AcMNPV gp64 initiator codon were examined by site-directed mutagenesis and functional assays in transfected Sf9 cells. To eliminate potential cis-acting sequences and effects, the gp64 initiator context was cloned in-frame with a chloramphenicol acetyl transferase reporter gene and under the control of a heterologous promoter. All possible single-nucleotide substitutions were generated in positions -6 to -1 and +4 to +6, relative to the A of the initiator AUG codon, which was designated +1. Constructs were transfected into lepidopteran cells and translation products were quantified by an enzyme-linked immunosorbent assay procedure. Substitutions of pyrimidines or other nucleotides at the -3 position resulted in little or no detectable effect on translation efficiency. In contrast, specific substitutions at the +4 and +5 positions resulted in approximately 2- to 3-fold increases in translation. Substitution of A in the +4 position resulted in an approximately 3-fold increase in translation, and substitution of any nucleotide for T in the +5 position resulted in approximately 1.9- to 2.8-fold increases. Substitutions at other positions (-6 to -1 and +6) resulted in no detectable increase or decrease in translation efficiency. These experimental results suggest an optimal initiator context of 5'-N N N N N N A U G A a/c/g N-3' for efficient translation initiation in lepidopteran cells. Consensus translation initiation contexts were generated from baculovirus genes and lepidopteran genes, then compared with the experimental results from the gp64 initiator context.

Host cell receptor binding by baculovirus GP64 and kinetics of virion entry.

GP64 is the major envelope glycoprotein from budded virions of the baculoviruses Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV) and Orgyia pseudotsugata multicapsid nucleopolyhedrovirus (OpMNPV). To examine the potential role of GP64 as a viral attachment protein in host cell receptor binding, we generated, overexpressed, and characterized a soluble form of the OpMNPV GP64 protein, GP64solOp. Assays for trimerization, sensitivity to proteinase K, and reduction by dithiothreitol suggested that GP64solOp was indistinguishable from the ectodomain of the wild-type OpMNPV GP64 protein. Virion binding to host cells was analyzed by incubating virions with cells at 4 degrees C in the presence or absence of competitors, using a single-cell infectivity assay to measure virion binding. Purified soluble GP64 (GP64solOp) competed with a recombinant AcMNPV marker virus for binding to host cells, similar to control competition with psoralen-inactivated wild-type AcMNPV and OpMNPV virions. A nonspecific competitor protein did not similarly inhibit virion binding. Thus specific competition by GP64solOp for virion binding suggests that the GP64 protein is a host cell receptor-binding protein. We also examined the kinetics of virion internalization into endosomes and virion release from endosomes by acid-triggered membrane fusion. Using a protease sensitivity assay to measure internalization of bound virions, we found that virions entered Spodoptera frugiperda Sf9 cells between 10 and 20 min after binding, with a half-time of approximately 12.5 min. We used the lysosomotropic reagent ammonium chloride to examine the kinetics of membrane fusion and nucleocapsid release from endosomes after membrane fusion. Ammonium chloride inhibition assays indicated that AcMNPV nucleocapsids were released from endosomes between 15 and 30 min after binding, with a half-time of approximately 25 min.

Requirement for GP64 to drive efficient budding of Autographa californica multicapsid nucleopolyhedrovirus.

Budded virions (BV) of Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV) contain a major envelope glycoprotein (GP64) that is present on the plasma membrane of infected cells. GP64 is acquired by virions during budding through the plasma membrane, the final step in assembly of the budded virion at the cell surface. Previous studies (S. A. Monsma, A. G. P. Oomens, and G. W. Blissard (1996). J. Virol. 70, 4607-4616) showed that insertional inactivation of the AcMNPV gp64 gene resulted in a virus unable to move from cell to cell and nonlethal to orally infected Trichoplusia ni larvae. To determine whether GP64 is involved in virion budding, we measured BV production from Sf9 cells infected with a gp64null virus. Sf9 cells infected with gp64null virus vAc64- were pulse labeled, and progeny BV were isolated on equilibrium sucrose gradients and quantified. BV production from vAc64- was reduced to approximately 2% of that from wild-type AcMNPV. Thus the GP64 protein is important for efficient virion budding. To determine whether the highly charged 7-amino acid cytoplasmic tail domain (CTD) of GP64 was required for virion production, we generated a series of GP64 constructs containing C-terminal truncations or substitutions. Modified forms of GP64 were analyzed in transfected cells and in recombinant viruses in which the wild-type gp64 gene was replaced with a modified gp64. Deletion of 1-7 amino acids from the CTD did not affect GP64 trimerization, protein transport to the cell surface, or membrane fusion activity. However, deletions of 11 or 14 amino acids, which removed the CTD and portions of the predicted transmembrane (TM) domain, were trimerized but were present at lower levels on the cell surface due to shedding of these truncated proteins. Comparisons of growth curves and quantitative measurements of labeled progeny BV production from recombinant viruses expressing either wild-type or mutant GP64 proteins showed that deletion of the 7-residue CTD only moderately reduced the production of infectious virions ( approximately 50%). However, deletions of the C terminal 11 or 14 amino acids had more substantial effects. Removal of the C terminal 11 amino acids reduced titers of infectious virus by 78-96% and labeled progeny virions were reduced by 91-92%. Removal of 14 amino acids from the C terminus resulted in an approximately 98% reduction in progeny BV and a virus that was apparently incapable of efficient propagation in cell culture. Thus the GP64 CTD is not essential for production of infectious BV, but removal of the CTD results in a measurable reduction in budding efficiency. Deletion of the CTD plus small portions of the transmembrane domain resulted in shedding of GP64, reduced surface levels, and a dramatic reduction in the production of BV. Together, these data indicate that GP64 is an important and limiting factor in BV production.

Identification of two independent transcriptional activation domains in the Autographa californica multicapsid nuclear polyhedrosis virus IE1 protein.

The Autographa californica multicapsid nuclear polyhedrosis virus immediate-early protein, IE1, is a 582-amino-acid phosphoprotein that regulates the transcription of early viral genes. Deletion of N-terminal regions of IE1 in previous studies (G. R. Kovacs, J. Choi, L. A. Guarino, and M. D. Summers, J. Virol. 66:7429-7437, 1992) resulted in the loss of transcriptional activation, suggesting that this region may contain an acidic activation domain. To identify independently functional transcriptional activation domains, we developed a heterologous system in which potential regulatory domains were fused with a modified Escherichia coli Lac repressor protein that contains a nuclear localization signal (NLacR). Transcriptional activation by the resulting NLacR-IE1 chimeras was measured with a basal baculovirus early promoter containing optimized Lac repressor binding sites (lac operators). Chimeras containing IE1 peptides dramatically activated transcription of the basal promoter only when lac operator sequences were present. In addition, transcriptional activation by NLacR-IE1 chimeras was allosterically regulated by the lactose analog, isopropyl-beta-D-thiogalactopyranoside (IPTG). For a more detailed analysis of IE1 regulatory domains, the M1 to T266 N-terminal portion of IE1 was subdivided (on the basis of average amino acid charge) into five smaller regions which were fused in various combinations to NLacR. Regions M1 to N125 and A168 to G222 were identified as independent transcriptional activation domains. Some NLacR-IE1 chimeras exhibited retarded migration in sodium dodecyl sulfate-polyacrylamide gel electrophoresis gels. As with wild-type IE1, this aberrant gel mobility was associated with phosphorylation. Mapping studies with the NLacR-IE1 chimeras indicate that the M1 to A168 region of IE1 is necessary for this phosphorylation-associated effect.

Baculovirus gp64 gene expression: negative regulation by a minicistron.

Small upstream open reading frames (ORFs) or minicistrons located in the 5' leader of eukaryotic mRNAs have been shown to play a role in translational regulation of some eukaryotic genes, particularly mammalian proto-oncogenes. A survey of the baculovirus Autographa californica multicapsid nuclear polyhedrosis virus genome suggests that at least 10 transcripts from late genes contain potential minicistrons, and at least three of these minicistrons appear to be conserved in homologous genes of the related Orygia pseudotsugata MNPV. The position of the minicistron from one of these genes, gp64, is also conserved in gp64 genes from several baculoviruses, suggesting a potential regulatory function. To identify the potential role of the gp64 minicistron in regulating translation from gp64 late mRNAs, we generated a series of recombinant viruses containing the gp64 promoter and minicistron in combination with a chloramphenicol acetyltransferase reporter gene (cat) inserted into the polyhedrin locus. We first fused a cat reporter in frame with the minicistron coding region to demonstrate that the minicistron initiator ATG was in a context suitable for translational initiation. In subsequent experiments, a cat reporter was fused in frame to the downstream gp64 ORF, and various constructs containing point mutations that inactivated the minicistron were examined. Translational efficiency in the presence and absence of the minicistron was measured by quantitative analysis of gp64-cat RNA and the GP64-CAT protein. In the absence of a functional minicistron, translational efficiency from the downstream gp64-cat reporter ORF increased. Surprisingly, single-point mutations that inactivated the minicistron initiator ATG also resulted in utilization of an upstream in-frame ATG that is found within the minicistron coding region and that is in a poor translational initiation context. Double-point mutation constructs that inactivated both the minicistron initiator ATG and the upstream in-frame ATG also resulted in increased translational efficiency from the downstream gp64-cat ORF. Thus, the gp64 minicistron serves as a negative regulatory element that decreases translation of the gp64 ORF on late mRNAs.

Late promoter selection in the baculovirus gp64 envelope fusion protein gene.

The upstream promoter region of the Autographa californica multicapsid nuclear polyhedrosis virus (AcMNPV) gp64 gene contains five copies of TAAG, the conserved sequence found at the transcriptional initiation sites of almost all baculovirus late genes. In AcMNPV-infected Sf9 cells, late transcription initiation is detected from only two upstream TAAG sites and not from three downstream TAAG sites. To examine several models for preferential TAAG site utilization, we constructed a series of recombinant AcMNPV baculoviruses that contain promoter region sequences from the gp64 gene fused to a chloramphenicol acetyl transferase reporter gene. Promoter-reporter constructs were inserted in the polyhedrin locus. To test a scanning model in which TAAG sites are sequentially selected according to their location in the region, we generated recombinant viruses in which the highly transcribed sites were inactivated by point mutations. Transcription from the mutant promoter constructs was compared qualitatively and quantitatively to transcription from the wild-type gp64 promoter. Inactivation of the upstream TAAG sites did not result in increased transcription from the downstream TAAG sites, suggesting that immediate context, rather than position, determines promoter utilization. To test this hypothesis, we made a series of minimal promoter constructs containing decreasing quantities of the sequences immediately flanking one of the active gp64 TAAG sites. Reporter constructs containing a gp64 TAAG site and > or = 12 bp of flanking sequence on both sides were transcribed at near wild-type levels. Constructs with less flanking sequence (9 or 6 bp of flanking sequence) were accurately transcribed, but at substantially lower levels, and transcription was not detected from constructs containing only 3 bp of flanking sequence. These results suggest that nucleotides immediately flanking the TAAG site (4-6 bp) are necessary for basal promoter activity while additional flanking sequences (> or = 12 bp) are required for late promoter activation and regulation. To further examine late promoter selection, we constructed recombinant AcMNPV baculoviruses that contain heterologous late promoters from the gp64 gene of the related virus Orgyia pseudotsugata MNPV (OpMNPV). TAAG sites that serve as functional late promoters in OpMNPV were found to mediate transcription initiation at only basal levels in the context of the AcMNPV genome, suggesting that late promoter activation may be virus specific within the family Baculoviridae.

The GP64 envelope fusion protein is an essential baculovirus protein required for cell-to-cell transmission of infection.

To demonstrate the essential nature of the baculovirus GP64 envelope fusion protein (GP64 EFP) and to further examine the role of this protein in infection, we inactivated the gp64 efp gene of Autographa californica multicapsid nuclear polyhedrosis virus (AcMNPV) and examined the biological properties of this virus in vivo. To provide GP64 EFP during construction of the recombinant GP64 EFP-null AcMNPV baculovirus, we first generated a stably transfected insect cell line (SfpOP64-6) that constitutively expressed the GP64 EFP of Orgyia pseudotsugata multicapsid nuclear polyhedrosis virus (OpMNPV). The AcMNPV gp64 efp gene was inactivated by inserting the bacterial lacZ gene in frame after codon 131 of the gp64 efp gene. The inactivated gp64 gene was cloned into the AcMNPV viral genome by replacement of the wild-type gp64 efp locus. When propagated in the stably transfected insect cells (Sf9OP64-6 cells), budded virions produced by the recombinant AcMNPV GP64 EFP-null virus (vAc64z) contained OpMNPV GP64 EFP supplied by the Sf9OP64-6 cells. Virions propagated in Sf9OP64-6 cells were capable of infecting wild-type Sf9 cells, and cells infected by vAc64z exhibited a blue phenotype in the presence of X-Gal (5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside). Using cytochemical staining to detect vAc64z infected cells, we demonstrated that this GP64 EFP-null virus is defective in cell-to-cell propagation in cell culture. Although defective in cell-to-cell propagation, vAc64z produces occlusion bodies and infectious occlusion-derived virions within the nucleus. Occlusion bodies collected from cells infected by vAc64z were infectious to midgut epithelial cells of Trichoplusia ni larvae. However, in contrast to infection by a control virus, infection by vAc64z did not proceed into the hemocoel. Analysis of vAc64z occlusion bodies in a standard neonate droplet feeding assay showed no virus-induced mortality, indicating that occluded virions produced from vAc64z could not initiate a productive (lethal) infection in neonate larvae. Thus, GP64 EFP is an essential virion structural protein that is required for propagation of the budded virus from cell to cell and for systemic infection of the host insect.

Baculovirus--insect cell interactions.

Baculovirus interactions with host cells range from the physical interactions that occur during viral binding and entry, to the complex and subtle mechanisms that regulate host gene expression and modify and regulate cellular and organismal physiology and defenses. Fundamental studies of baculovirus biochemistry and molecular biology have yielded many interesting and important discoveries on the mechanisms of these virus-host interactions. Information from such studies has also resulted in exciting new strategies for environmentally sound insect pest control, and in the development and improvement of a valuable eukaryotic expression vector system. In addition a number of important and valuable model biological systems have emerged from studies of baculoviruses. These include robust systems for studies of eukaryotic transcription, viral DNA replication, membrane fusion, and apoptosis. Because functions have been identified for only a small number of baculovirus genes, we can expect many exciting new discoveries in the future and an unfolding of the complex and intricate relationship between baculoviruses and insect cells.

The baculovirus GP64 envelope fusion protein: synthesis, oligomerization, and processing.

The baculovirus GP64 envelope fusion protein (GP64 EFP) is a class I integral membrane protein that enters the secretory pathway and is oligomerized and extensively processed during transport to the plasma membrane. The kinetics of GP64 EFP biosynthesis, oligomerization, and processing in Orgyia pseudotsugata multicapsid nuclear polyhedrosis virus (OpMNPV)-infected Lymantria dispar cells were examined by pulse label, pulse-chase, and immunoprecipitation experiments. Relative rates of GP64 EFP synthesis in OpMNPV-infected L. dispar cells were examined at various times throughout the infection cycle. Using pulse labeling and immunoprecipitation, GP64 EFP synthesis was detected within 2 hr p.i., and the maximal rate of synthesis was observed in the period of 24-26 hr p.i., a time coincident with the onset of high level production of budded virus in OpMNPV-infected L. dispar cells. To determine the oligomeric structure of GP64 EFP, a soluble form of OpMNPV GP64 EFP was produced and examined by a combination of gel filtration chromatography, nonreducing SDS-PAGE, and mass spectrometry. Oligomeric GP64 EFP was identified as a trimeric molecule, that migrates as two discrete bands on nonreducing SDS-PAGE. Pulse-chase studies, performed at both early (12 hr p.i.) and late (36 hr p.i.) stages of the infection cycle, showed that GP64 EFP oligomerization is complete within 15 min after synthesis. Efficiency of oligomerization however was relatively low, with less than 33% of the synthesized GP64 EFP converted to trimers. The majority of monomeric GP64 EFP remaining in the cell appeared to be degraded within 30 to 45 min after synthesis. Analysis of the kinetics of carbohydrate processing at early (12 hr p.i.) and late (36 hr p.i.) times postinfection showed that for both early and late phases of infection, carbohydrate was rapidly added, and processing began between 10 and 20 min after GP64 EFP synthesis. Although carbohydrate processing was completed within approximately 90 min after synthesis during the early phase, the same process required approximately 150 min during the late phase. Thus, carbohydrate processing appeared to become less efficient as infection progressed. These studies thus show that GP64 EFP undergoes a rapid but inefficient oligomerization step that results in a homotrimeric structure for GP64 EFP. While carbohydrate addition is rapid, carbohydrate processing requires prolonged periods of time (with half-times of 45 to 75 min) and appears to become less efficient during the late phase of the infection.

Identification of a membrane fusion domain and an oligomerization domain in the baculovirus GP64 envelope fusion protein.

The baculovirus GP64 envelope fusion protein (GP64 EFP) is the major envelope glycoprotein of the budded virion and has been shown to mediate acid-triggered membrane fusion both in virions and when expressed alone in transfected cells. Using site-directed mutagenesis and functional assays for oligomerization, transport, and membrane fusion, we localized two functional domains of GP64 EFP. To identify a fusion domain in the GP64 EFP of the Orgyia pseudotsugata multiple nuclear polyhedrosis virus (OpMNPV), we examined two hydrophobic regions in the GP64 EFP ectodomain. Hydrophobic region I (amino acids 223 to 228) is a cluster of 6 hydrophobic amino acids exhibiting the highest local hydrophobicity in the ectodomain. Hydrophobic region II (amino acids 330 to 338) lies within a conserved region of GP64 EFP that contains a heptad repeat of leucine residues and is predicted to form an amphipathic alpha-helix. In region I, nonconservative amino acid substitutions at Leu-226 and Leu-227 (at the center of the hydrophobic cluster) completely abolished fusion activity but did not prevent GP64 EFP oligomerization or surface localization. To confirm the role of region I in membrane fusion activity, we used a synthetic 21-amino-acid peptide to generate polyclonal antibodies against region I and demonstrated that antipeptide antibodies were capable of both neutralizing membrane fusion activity and reducing infectivity of the virus. In hydrophobic region II, mutations were designed to disrupt several structural characteristics: a heptad repeat of leucine, a predicted alpha-helix, or the local hydrophobicity along one face of the helix. Single alanine substitutions for heptad leucines did not prevent oligomerization, transport, or fusion activity. However, multiple alanine substitutions or proline (helix-destabilizing) substitutions disrupted both oligomerization and transport of GP64 EFP. In addition, a deletion that removed region II and the predicted alpha-helix was defective for oligomerization, whereas a larger deletion that retained region II and the predicted helix was oligomerized. These results indicate that region II is required for oligomerization and transport and suggest that the predicted helical structure of this region may be important for this function. Thus, by using mutagenesis, functional assays, and antibody inhibition, two functional domains were localized within the baculovirus GP64 EFP: a fusion domain located at amino acids 223 to 228 and an oligomerization domain located at amino acids 327 to 335 within a predicted amphipathic alpha-helix.

Overlapping TATA-dependent and TATA-independent early promoter activities in the baculovirus gp64 envelope fusion protein gene.

In previous studies to characterize basal and activated transcription from the early promoter of the gp64 envelope fusion protein (efp) gene of the Orgyia pseudotsugata multicapsid nuclear polyhedrosis virus, the TATA box was identified as a functional element, essential for basal transcription from a minimal promoter construct. In the current study, we used discrete deletions and multiple point mutations that removed the functional TATA box from larger promoter constructs of the gp64 efp gene to reveal an overlapping TATA-independent transcriptional activity. TATA-independent transcriptional activity was inhibited in vitro by alpha-amanitin but not by tagetitoxin, demonstrating that like the TATA-dependent activity, the TATA-independent activity is mediated by RNA polymerase II. Using constructs in which the TATA box (TATATAA) was destroyed by substitution mutations, we identified four elements that are required for the TATA-independent activity. Two of the required elements, GATA (at -114) and CACGTG (at -104), were previously shown to specifically bind host transcription factors and activate transcription from the TATA-dependent wild-type gp64 efp promoter. The role of the early start site consensus CAGT sequence in TATA-independent transcription was also examined. Single-nucleotide substitution mutations in the CAGT sequence indicated that certain nucleotides within the CAGT start site were essential. In addition to the start site sequence and two upstream elements, a fourth essential element was identified in the 5' untranslated leader region (5'UTR). While the 5'UTR was not necessary for TATA-dependent transcription, deletion of a 10-bp 5'UTR sequence resulted in the loss of TATA-independent transcriptional activity. Although necessary, neither the GATA, CACGTG, start site region, nor 5'UTR element was alone sufficient for accurately initiated TATA-independent transcription from the consensus CAGT start site. Thus, the gp64 efp early promoter contains overlapping TATA-dependent and TATA-independent transcriptional activities. A number of common sequence elements (GATA, CACGTG, and start site CAGT) are involved in both of these activities, while one element (in the 5'UTR) is required only in the TATA-independent context.

A baculovirus gp64 early promoter is activated by host transcription factor binding to CACGTG and GATA elements.

The early promoter of the Orgyia pseudotsugata multicapsid nuclear polyhedrosis virus gp64 gene is active when transfected into several insect cell lines and does not require viral gene products for transcription in uninfected cells. Because previous studies have shown that the gp64 early promoter is activated above basal levels in uninfected cells, host transcription factors are likely to play a role in gp64 activation at early times postinfection. By using nuclear extracts from uninfected Sf9 cells for electrophoretic mobility shift analysis of gp64 regulatory regions, host nuclear proteins were shown to bind specifically to the upstream regulatory region of the gp64 early promoter. Host factor binding was mapped to a 24-bp sequence centered approximately 35 bp upstream of the TATA box. Two consensus eukaryotic transcription factor-binding site motifs, GATA and CACGTG, were identified within the 24-bp sequence. Competition assays using oligonucleotides containing either a GATA or a CACGTG motif and similar oligonucleotides with point mutations in these sites showed that each site is required for binding host transcription factors. To investigate the functional significance of host factor binding to GATA and CACGTG motifs, constructs containing point mutations in these motifs were examined in transient expression assays. Mutations in either or both GATA and CACGTG sites decreased reporter activity in transient expression assays, suggesting that binding of host transcription factors to these motifs is important in transcriptional regulation of the gp64 early promoter.

Baculovirus gp64 envelope glycoprotein is sufficient to mediate pH-dependent membrane fusion.

The baculovirus gp64 envelope glycoprotein is a major component of the envelope of the budded virus (BV) and is involved in BV entry into the host cell by endocytosis. To determine whether gp64 alone was sufficient to mediate membrane fusion, the Orgyia pseudotsugata multicapsid nuclear polyhedrosis virus gp64 protein was transiently expressed in uninfected insect cells. Cells expressing the baculovirus gp64 protein were examined for membrane fusion activity by using a syncytium formation assay under various conditions of exposure to low pH. Cells expressing the gp64 protein mediated membrane fusion and syncytium formation in a pH-dependent manner. A pH of 5.5 or lower was required to induce membrane fusion. In addition, exposure of gp64-expressing cells to low pH for as little as 5 s was sufficient to induce gp64-mediated syncytium formation. These studies provide direct evidence that gp64 is a pH-dependent membrane fusion protein and suggest that gp64 is the protein responsible for fusion of the virion envelope with the endosome membrane during BV entry into the host cell by endocytosis.

A synthetic early promoter from a baculovirus: roles of the TATA box and conserved start site CAGT sequence in basal levels of transcription.

Many baculovirus early genes and insect genes transcribed by RNA polymerase II have a conserved transcription start site sequence (CAGT) located downstream of a consensus TATA box. To examine the functions and interactions of these two motifs in initiating accurately positioned basal transcription, a 43-nt synthetic promoter was synthesized from the TATA box and start site sequences of the gp64 early promoter from the Orgyia pseudotsugata multicapsid nuclear polyhedrosis virus (OpMNPV). The synthetic promoter initiated accurately and was also transactivated by the baculovirus transcriptional activator, IE1. To determine the roles of sequences within the 43-nt synthetic promoter, a series of linker-scanning and spacing mutations were analyzed for transcriptional activity, start site selection, and transactivation. Linker-scanning mutations were examined in vivo by transient expression and reporter gene assays. To examine transcription start site selection, promoter constructs were used for in vitro transcription in nuclear extracts from uninfected Spodoptera frugiperda (Sf9) cells. In vivo and in vitro analyses show that the TATA box, and not the start site CAGT, is the primary element controlling start site selection. Substitution of the conserved start site CAGT sequence resulted in a reduction of both reporter gene activity and in vitro transcripts, although transcripts initiated accurately. Data from linker-scanning and spacing mutations indicate that the conserved start site CAGT sequences are not required for accurate initiation but sequences at the start site play an important role in initiation efficiency.