Interactions of recombinant and wild-type baculoviruses with classical insecticides and pyrethroid-resistant tobacco budworm (Lepidoptera: Noctuidae)

In tests with neonate Heliothis virescens (F.), we characterized interactions of all combinations of a recombinant Autographa californica (Speyer) nuclear polyhedrosis virus (AcAaIT) that expresses an insect-selective neurotoxin (AaIT) and wild-type AcNPV when combined with low concentrations of several conventional insecticides. All combinations of the recombinant virus AcAaIT and insecticides showed a positive interaction (decrease in the median lethal time (LT50) compared with the LT50 for either component alone). A type II pyrethroid (cypermethrin, which modifies currents of sodium channels) and a carbamate (methomyl, an inhibitor of acetylcholinesterase) were synergistic in combination with AcAaIT. Other insecticides also showed a positive interaction when tested in combination with the recombinant virus, but joint activity was slightly antagonistic (i.e., less than predicted activity when combined) with wild-type AcNPV. We also characterized the effectiveness of AcAaIT against pyrethroid-resistant H. virescens larvae. Our results show that a resistant strain of H. virescens is more sensitive to the recombinant virus compared with a susceptible strain. Results of these studies should be useful in planning of future field trials to increase the effectiveness of nuclear polyhedrosis viruses and to manage resistance to pyrethroids and other insecticides.

Use of baculoviruses as biological insecticides

Naturally occurring baculoviruses can be used to control a wide range of insect pests. Most baculoviruses are used as biopesticides, that is, they are sprayed onto high-density pest populations in a manner akin to the use of synthetic chemical pesticides. However, other strategies that use the biological features of the viruses are also possible and should increase as we expand our knowledge of baculovirus ecology. In order to develop a baculovirus control program, several areas need to be studied before progressing to large scale field studies and commercialization. These range from laboratory efficacy testing and the development of production systems to detailed study of pest behavior and the development of appropriate application strategies.

A physical map of the Mamestra configurata nucleopolyhedrovirus genome and sequence analysis of the polyhedrin gene

The genome structure of a nucleopolyhedrovirus (NPV) isolated from the bertha armyworm, Mamestra configurata Walker (Lepidoptera: Noctuidae) (MacoNPV) was analysed with six restriction endonucleases (REN): BamHI, EcoRI, HindIII, PstI, SmaI and Xhol. More than 70 MacoNPV REN fragments were cloned into plasmids pUC18 and pBluescript SK(+). The physical map with 112 restriction sites for the above REN was constructed using double digests and Southern blot hybridization analysis of the MacoNPV DNA clones. The size of the DNA genome of the MacoNPV-90/2 isolate used for this study was estimated at 156 kbp based on REN fragment sizes. The position of the polyhedrin gene, which has by convention been used as the zero point of the REN maps of NPV, was determined by hybridizing the Autographa californica multicapsid nucleopolyhedrovirus HindIII-V fragment clone, which contains most of the polyhedrin gene, with genomic blots of MacoNPV. The cloned MacoNPV fragments identified as containing the polyhedrin gene were sequenced and an ORF coding for a 246 amino acid polypeptide with 98.7% sequence identity with Panolis flammea nucleopolyhedrovirus (PaflNPV) polyhedrin protein was identified. The putative polyhedrin gene sequence had 97.2% and 91.2% identity with the PaflNPV and Mamestra brassicae multicapsid nucleopolyhedrovirus polyhedrin gene sequences, respectively, and also contained an upstream region identical to the highly conserved 12 bp consensus sequence TGTAAGT-AATTT typical of NPV very late genes.

[Comparative characteristics of nuclear polyhedrosis virus isolates from gypsy moth Lymantria dispar L]

Eight strains of Gypsy moth nuclear polyhedrosis virus (NPV) were isolated from dead larvae in Kirghizia and Tyumen and Novosibirsk districts. The strains were characterized in terms of polyhedron morphology, biological activity, virus production, and restriction analysis of DNA. The isolated strains did not differ in size or shape of polyhedrons. NPV strain NSHN-2 was characterized by the highest biological activity (LD50 = 1.2 +/- 0.4) x 10(4) and maximum production: 7.3 x 10(8) PIB/larva in comparison with the rest isolated strains. This strain is proposed for the manufacture of an insecticide.

Nucleopolyhedrovirus interactions with their insect hosts

It is clear from this brief review that our understanding of the molecular cross-talk between insects and their baculovirus pathogens is still very limited. Studies in cell culture have taught us a great deal about the basic baculovirus molecular machinery and how it is regulated, and in many cases this information has been predictive of what occurs in infected insects. Frequently, however, studies in cell culture do not adequately predict the infection process in insect hosts, as demonstrated by viral mutants (some of which were discussed in this review) that behave identically to wild-type virus in cell culture but differ markedly in larvae. More baculovirus studies, therefore, need to be conducted in vivo if we are to improve our understanding of the complex interactions between baculoviruses and their hosts. Conducting baculovirus studies in insects (or at least in primary cell culture) also offers the opportunity to address questions that reach beyond the baculovirus community in significance. For example, almost all of our knowledge of viral fusion mechanisms comes from infection of cells in culture where the pH is neutral or acidic and the temperature is constant at 27 degrees or 37 degrees C. An answer to the question of how the ODV envelope fuses with the microvillar membrane of columnar epithelial cells in the highly alkaline midgut environment at low temperatures will not only be important for an improved understanding of baculovirus infection in the natural world, but will also constitute a new chapter on viral entry mechanisms. Similarly, the answer to the question of how baculovirus nucleocapsids move basally within microvilli promises to involve factors and/or a mechanism not yet described by cell biologists, and so will constitute a valuable contribution to both baculovirology and cell biology. There are many more such examples of biological mechanisms that can be uniquely explored within the context of baculoviruses and their insect hosts, some of which have been highlighted in this review. As more and more young investigators realize the importance of combining a knowledge of virology, molecular technology, and insect biology, however, many of the outstanding mysteries will be solved.

A new small RNA virus persistently infecting an established cell line of Galleria mellonella, induced by a heterologous infection

A persistent infection in a Galleria mellonella cell line was revealed when infected with a maize stem borer picorna-like virus isolated on Sesamia cretica (MSBV). The new virus, completely different from the MSBV, is designated as G. mellonella cell line virus (GmclV), induces spectacular cytopathic effects, and is also considered efficient in vivo. The GmclV is a 29-nm-diameter isometric virus, with single-strand RNA of 2.9 x 10(6) Da molecular weight with a poly(A) tract. Its capsid is constituted of only two major polypeptides, of 34,500 and 32,500 Da, and no minor bands could be detected. The characteristics of the GmclV do not permit us to classify it with assurance. Even though it has not yet been identified as a picornavirus, it can be classified in the small RNA virus group of the Picornaviridae. G. mellonella represents a very interesting model, owing to the fact that two different persistent viruses belonging to the same family were isolated in vivo and in vitro, to further the understanding of the general phenomenon of persistency and induction.

Organization and molecular characterization of genes in the polyhedrin region of the Anagrapha falcifera multinucleocapsid NPV

A multinucleocapsid nuclear polyhedrosis virus (MNPV) isolated from the celery looper, Anagrapha falcifera, has been proposed as a new virus based on differences in virulence and DNA fragment profiles between this isolate and the Autographa californica MNPV, the MNPV type species. In the present study, we examined the relatedness of the AfMNPV and AcMNPV genomes by (1) Southern hybridization, (2) comparison of their genetic organization in the polyhedrin gene region (AcMNPV EcoRI-I fragment), and (3) comparison of the nucleotide and deduced amino acid sequences of eight viral genes in this region. Both DNAs hybridized strongly to one another in reciprocal hybridization experiments under stringent conditions, and physical mapping showed that gene order was conserved between the two viruses in the polyhedrin gene region, though the ORF 984 and ctl genes were absent from this region in the AfMNPV. Gene and deduced amino acid sequences for p78, protein tyrosine phosphatase, protein kinase, lef-2, and ORFs 327, 453 and 603, showed identity between the two viruses of greater than 91%. The sequences for the gp64 gene, located on a different EcoRI fragment, were also compared and had a nucleotide sequence identity of 97%, and amino acid sequence identity of greater than 98%. The polyhedrin gene showed the least relatedness between the two viruses, with a nucleotide sequence identity of 80%, and a deduced amino acid sequence identity of 90%. Based on these results, we conclude that the AfMNPV should be considered a variant of the AcMNPV. These results also indicate that caution must be used in basing phylogenetic relationships of NPVs on analysis of a single gene, especially the polyhedrin gene, as is the current practice.

Glycosylation, palmitoylation, and localization of the human D2S receptor in baculovirus-infected insect cells

In order to evaluate the baculovirus expression system as a means for high-yield production of homogeneous D2S receptor, we have expressed various D2S receptor constructs in two Spodoptera frugiperda cell lines, a Trichoplusia ni and a Mammestra brassicae cell line. To improve expression yield, the environment of the polyhedrin gene translational initiation site was retained by fusing the first 12 codons of the polyhedrin gene to the 5'-end of the D2S receptor coding sequence. The pharmacological profile of the expressed D2S receptor was similar to that reported for neuronal D2 receptors. Sf9 and Tn cells were best suited for overexpression, yielding about 2 x 10(6) and 4 x 10(6) receptors/cell, respectively, corresponding to 6 pmol/mg of cell protein in Sf9 cells and 10 pmol/mg of cell protein in Tn cells. We have developed a D2 receptor-specific anti-peptide antibody to study glycosylation, palmitoylation, and localization of the heterologously produced receptor. Immunoprecipitation of digitonin/cholate-solubilized receptor from control and tunicamycin-treated Sf9, Tn, and Mb cells revealed an apparent molecular mass of 47-48 kDa for the glycosylated receptor and of 39-40 kDa for the unglycosylated receptor. Although pulse-chase studies showed that glycosylation occurred rapidly and efficiently, the glycosylated receptor only constituted a small fraction of the overall produced receptor protein, which was mainly located intracellularly. The glycosylation of the receptor was of the high-mannose-type in contrast to the complex-type glycosylation found in native tissue. The glycosylated D2S receptor was palmitoylated. Glycosylation, however, was not a prerequisite for palmitoylation which was insensitive to tunicamycin, brefeldin A, and monensin. NH2-terminal addition of the signal sequence of prepromelittin to the D2S receptor increased expression levels 2-3-fold and significantly enhanced membrane insertion and processing, resulting in increased targeting of the synthesized receptor to the plasma membrane.

Characterization of the ecdysteroid UDP-glucosyltransferase gene from Mamestra brassicae nucleopolyhedrovirus

The ecdysteroid UDP-glucosyltransferase (egt) gene of Mamestra brassicae multinucleocapsid nucleopolyhedrovirus (MbMNPV) has been cloned and characterized. MbMNPV egt potentially encodes a protein of 528 amino acids. Analysis of the substrate specificity of the MbMNPV EGT protein showed that it mirrors that of Autographa californica MNPV (AcMNPV) EGT. MbMNPV EGT also appears to be secreted from infected cells. Confirmation that the cloned gene encodes an active EGT was obtained by transient expression assays. Phylogenetic trees of NPVs were generated based on the alignment of baculovirus EGT sequences. These phylogenies support the classification of MbMNPV as a group II NPV that is most closely related to Spodoptera exigua MNPV. Comparison of the EGT-based phylogenies with polyhedrin/granulin-based phylogenies shows that the position of AcMNPV is different in the two trees, possibly indicating that AcMNPV acquired its polyhedrin gene by recombination with another virus.

Glycosylation in lepidopteran insect cells: identification of a beta 1-->4-N-acetylgalactosaminyltransferase involved in the synthesis of complex-type oligosaccharide chains

The choice for a heterologous expression system to produce glycoprotein therapeutics highly depends on its potential to perform mammalian-like posttranslational modifications such as glycosylation. To gain more insight into the glycosylation potential of the baculovirus mediated insect cell expression system, we have studied the expression of glycosyltransferases involved in complex-type N-glycosylation. Lepidopteran insect cell lines derived from Trichoplusia ni, Spodoptera frugiperda, and Mamestra brassicae were found to express a beta 1-->4- N-acetylgalactosaminyltransferase (beta 4-GalNAcT) that catalyzes the transfer of GalNAc from UDP-GalNAc to oligosaccharides and glycoproteins carrying a terminal beta-linked GlcNAc residue. These results suggest that Lepidopteran insect cells are capable of synthesizing complex-type carbohydrate chains containing GalNAc beta 1-->4GlcNAc (LacdiNAc) units. Baculovirus infection of the cells, however, resulted in a decrease in the activity of beta 4-GalNAcT from 80 to <1 pmol.min-1 mg-1 protein within 48 h post infection. Furthermore, considerable beta-N-acetylgalactosaminidase and beta-N-acetylglucosaminidase activity was observed in insect cells, whether or not infected with baculovirus, as well as in the culture medium. These enzyme activities could be responsible for degradation of complex-type oligosaccharide chains containing LacdiNAc units. Our findings provide an enzymatic basis for the observation that most recombinant glycoproteins produced by baculovirus infected insect cells carry oligomannosidic-type N-linked glycans, in spite of the fact that uninfected insect cells have the potential for the synthesis of mammalian-like complex-type glycans.

Genetic variability of four natural isolates of the Stilpnotia salicis multiple-enveloped nuclear polyhedrosis virus

Viral genome DNA from four different multiple-enveloped nuclear polyhedrosis virus isolates, obtained from naturally infected larvae of satin moth (Stilpnotia salicis), a pest of poplar tree (Populus) was analysed. Larvae were collected over a period of 11 years, from 1978 to 1989. The genomic DNA restriction patterns pointed to heterogeneity of these wild-type viruses. The differences observed in isolates of several years revealed limited restriction fragment length polymorphism and showed that these viruses contained distinct, but closely related genotypes. The genome size of SsMNPV was established as 128-134 kb, based on HindIII and SacI restriction analysis.

Nucleotide sequence of a 1446 base pair SalI fragment and structure of a novel early gene of Leucania separata nuclear polyhedrosis virus

A 1446 bp SalI fragment of LsNPV was sequenced by the silver staining method, and two large open reading frames (ORFs, ORF1 and ORF2) were found, both contain typical characteristics of the 5' regulatory elements of baculovirus early genes. ORF1 is 345 bp long with the capacity to encode a putative protein of 114 amino acid residues with MW about 13 kDa and was designated p13 gene, ORF2 comprises 248 bp from the 3' end of the fragment. In the untranslated region (UTR) of ORF1, a 33 bp mini cistron (ORF3), a core recognition sequence (CGTCG) for many bHLHzip transcription factors and a late promoter sequence TTAAG are present. In the UTR of ORF2, two host transcription factor binding elements (CACGTG and GATA motif) and two CGT motifs were found. Some regular leucine zipper-like structures, designated leucine trans-conformation structure and LVT repeat, were found near the N-terminus and the middle of p13 protein. The leucine trans-conformation structure that is near the N-terminus consists of 4 leucines and 7 other amino acids between every two leucines, and every leucine is located at a conformation shift point of the predicted secondary structure of the p13 protein. In LVT repeat, L-6aa-V-6aa-T-6aa is repeated once. The functions of those structures remain unclear, and the two ORFs, not found in the genome of Autographa californica nuclear polyhedrosis virus, are possibly two new genes.

Biochemical analysis of the N-glycosylation pathway in baculovirus-infected lepidopteran insect cells

The baculovirus-insect cell system is used routinely for foreign glycoprotein production, but the precise nature of the N-glycosylation pathway in this system remains unclear. Some studies indicate that these cells cannot process N-linked oligosaccharides to complex forms containing outer-chain galactose and sialic acid, while others indicate that they can. In this study, we used the major virion envelope glycoprotein of the baculovirus Autographa california multicapsid nuclear polyhedrosis virus (AcMNPV) to probe the N-glycosylation pathway in baculovirus-infected lepidopteran insect cells. The results showed that gp64 contained mannose, fucose, and probably N-acetylglucosamine, but no detectable galactose or sialic acid. These same results were observed with gp64 produced in any one of three different lepidopteran insect cell lines derived from Spodoptera frugiperda, Trichoplusia ni, or Estigmene acrea, whether it was produced at relatively earlier or later times after infection. These results indicated that the gp64 produced in AcMNPV-infected lepidopteran insect cells lacks complex N-linked oligosaccharides containing outer-chain galactose and sialic acid. By contrast, gp64 produced in mammalian cells contained both galactose and sialic acid, and endoglycosidase digestions revealed that these sugars were constituents of N-linked, not O-linked, oligosaccharides. This showed that at least one N-linked side chain on gp64 has the potential to be processed to a complex form. Together, these results suggest either that AcMNPV-infected lepidopteran insect cells are unable to convert any of the N-linked side chains on gp64 to complex structures or that outer-chain galactose and sialic acid residues are added to gp64 and then removed by cellular or viral exoglycosidases.

The effect of inhibitors on the growth of the entomopoxvirus from Amsacta moorei in Lymantria dispar (gypsy moth) cells

Within the family of Poxviridae, the entomopoxviruses are the most distant relatives of the more well-known and intensively studied orthopoxviruses (vaccinia and variola). The growth of the entomopoxvirus from Amsacta moorei (AmEPV) has been characterized in cell culture and compared to that of vaccinia virus (VV), the prototypic orthopoxvirus. The overall characteristics of infected cell cultures were generally similar between the two viruses. One striking difference noted was the apparent absence of proteolytic processing of late AmEPV viral proteins, a hallmark of vertebrate poxvirus infections associated with viral morphogenesis. AmEPV, like VV, was found to be sensitive to all the inhibitors of viral infection tested including phosphonoacetic acid, 1-beta-D-arabinofuranosylcytosine, and isatin-beta-thiosemicarbazone (IBT), a compound associated with the rather specific inhibition of vertebrate poxviruses. While both VV and AmEPV are inhibited by IBT, the inhibition of AmEPV, unlike that of VV, is not accompanied by either a breakdown of ribosomal RNA or a global inhibition of late viral protein synthesis. Instead, in the presence of IBT, AmEPV enveloped, immature virions form devoid of a well-differentiated core, which unlike mature virions fail to insert into occlusion bodies.

Developmental resistance in fourth instar Trichoplusia ni orally inoculated with Autographa californica M nuclear polyhedrosis virus

Larvae of lepidopteran insects commonly become increasingly resistant to baculovirus infections as they age. The mechanism responsible for this development resistance is not known, but the phenomenon does not occur if the viral inoculum is administered intrahemocoelically instead of orally, which is the natural route of infection. This observation indicates that the factors mediating developmental resistance are operative during infection of the primary target tissue, the larval midgut, and not during subsequent systemic infection. To learn more about the mechanism of developmental resistance, we orally inoculated four cohorts of fourth instar Trichoplusia ni larvae with a recombinant of Autographa californica M nuclear polyhedrosis virus expressing a reporter gene. While these cohorts differed only by a few hours in age, we found increasing resistance to infection in successively older cohorts. By assessing the presence and location of infected cells at intervals during the first 48 hr after inoculation, we identified two key factors relevant to the resistance pattern among the developmental cohorts. These factors were: (i) an age-dependent rate of establishing and/or sloughing infected midgut cells and (ii) the ability of fourth instar T. ni to completely clear infection of the midgut epithelium by ecdysis to the fifth instar.

The Melolontha melolontha entomopoxvirus (MmEPV) fusolin is related to the fusolins of lepidopteran EPVs and to the 37K baculovirus glycoprotein

We have cloned and sequenced a 1.7-kbp DNA fragment of the MmEPV genome encompassing the major polypeptide of the spindle-shaped inclusions gene termed fusolin. The sequence contained a single open reading frame of 1203 nt capable of coding for a polypeptide of 45.8 kDa. The 13 N-terminal amino acid (aa) residues were hydrophobic and could act as a signal peptide. The aa sequence also contained 13 cysteine residues very likely involved in paracrystal formation. This sequence showed significant homologies with the fusolins of two lepidopteran EPVs, the Choristoneura biennis EPV (CbEPV) and the Heliothis armigera EPV, and also with the 37K glycoproteins of Autographa californica and Orgyia pseudotsugata baculoviruses. No homology was found between the MmEPV fusolin and the 100K MmEPV spherulin, nor with the 110K polypeptide of the CbEPV and Amsacta moorei EPV spheroidins. These data were confirmed by Western blot analysis. Transfection of vaccinia-infected mammalian cells with a plasmid encompassing the fusolin sequence plus the upstream regulatory region resulted in transient expression of the gene. This indicated that the vaccinia transcription machinery is able to transcribe the fusolin gene. The fusolin was also expressed in insect cells via a recombinant baculovirus.

The larger genomic RNA of Helicoverpa armigera stunt tetravirus encodes the viral RNA polymerase and has a novel 3'-terminal tRNA-like structure

In this paper we report the complete nucleotide sequence of the larger segment (5312 nucleotides) of the bipartite RNA genome of Helicoverpa armigera stunt tetravirus (HaSV). HaSV therefore becomes the first member of the Tetraviridae, a virus family with a host range restricted to lepidopteran insects, whose genome has been completely sequenced. HaSV RNA 1 encodes a 187K protein which includes three domains conserved in RNA-dependent RNA polymerases of RNA viruses in the alpha-like superfamily. Analysis of the replicase sequence confirms the status of the Tetraviridae as a distinct family within this superfamily, which includes animal, plant, and insect viruses, and shows the least-distantly related replicase for all three domains to be that of the hepatitis E virus. Another feature of the nonpolyadenylated HaSV genomic RNAs is a well-conserved 3'-terminal tRNA-like structure, the first such structure discerned in an animal virus. However, in contrast to the tRNA-like structures on some plant virus RNAs, the HaSV structure, which has a valine anticodon (CAU), appears to form without a pseudoknot and therefore resembles authentic tRNA(Val) more closely than do the plant viral structures. The implications of these observations for our understanding of RNA virus evolution are discussed.

TCl4.7: a novel lepidopteran transposon found in Cydia pomonella granulosis virus

After the co-infection of larvae of the lepidopteran Cryptophlebia leucotreta with the two baculoviruses C. leucotreta granulosis virus and Cydia pomonella granulosis virus (CIGV and CpGV, respectively), three CpGV mutants and one CIGV mutant carrying insertions of 0.9 to 4.7 kb have been isolated. By cloning, sequencing, and hybridization analysis, one of these insertions was identified as a transposon-like element derived from the C. leucotreta genome. This element, called TCl4.7, was found in the genome of CpGV which naturally replicates in C. pomonella. Sequence analysis suggested that TCl4.7 is 4726 bp in size, flanked by imperfect inverted terminal repeats of 29 bp, and integrated into the target dinucleotide TA. TCl4.7 encompasses an open reading frame sharing homologies to transposase genes of the Tc1-related transposable elements found in Caenorhabditis and in Drosophila species. The open reading frame might represent a pseudogene since it is missing an ATG start codon. The integration site of TCl4.7 is located in a non-protein-coding region of the CpGV genome at m.u. 9.5. In bioassays the TCl4.7-carrying virus and all the other mutants except for one showed LC50 values similar to those of CpGV and CIGV. This is the first report of the horizontal escape of a transposable element during the in vivo infection of lepidopteran larvae by granulosis viruses.

Expression of polydnavirus genes from the parasitoid wasp Cotesia kariyai in two noctuid hosts

DNA purified from polydnavirus particles isolated from the parasitoid wasp Cotesia kariyai contained double-stranded closed circular molecules which were polydisperse in molecular weight. 2 days after viral injection into the host armyworm larvae viral DNA was detected in all tested larval tissues, including haemocytes, fat body, nerve cord and brain. Viral transcripts were also observed in all the tissues of virus-injected larvae. The most specific tissue was haemocytes because more viral DNA and RNA was detected than in the other tissues. Viral transcripts were not detected in haemocytes of virus-injected larvae of common cutworm. The present data suggest that C. kariyai virus (CkV) gene expression occurs species-specifically, although viral DNA can be detected in all tested tissues of the habitual host armyworm.