Helicoverpa armigera nucleopolyhedrovirus ORF80 encodes a late, nonstructural protein

The Helicoverpa armigera nucleopolyhedrovirus (HearNPV) ORF80 (ha80) has 765 bp encoding a protein with approximately 254 amino acids and a predicted molecular weight of 30.8 kDa. Homologues of ha80 are found in most baculovirus sequences, including those from lepidopteran NPVs, lepidopteran granuloviruses (GVs), hymenopteran baculoviruses, and one dipteran baculovirus, yet their functions remain unclear. In this study we characterized ha80, and showed that it was transcribed late in infected host cells (HzAM1). The product of ha80 was a 31 kDa protein that was not a structural protein of budded virus (BV) or occlusion-derived virus (ODV) particles. Ha80 was first detected in the cytoplasm of infected HzAM1 cells at 12 h p.i., and was observed in the nucleus at later stages of infection, suggesting that it may be involved in transporting viral proteins into the host cell nucleus or play its roles in the nucleus.     

N-terminal polyhedrin sequences and occludedBaculovirus evolution

Summary A phylogenetic tree for occluded baculoviruses was constructed based on the N-terminal amino acid sequence of occlusion body proteins from six baculoviruses including three lepidopteran nuclear polyhedrosis viruses (NPVs), [two unicapsid (Bombyx mori andOrgyia pseudotsugata) and one multicapsid (Orgyia pseudotsugata)]; one granulosis virus (Pieris brassicae); and NPVs from a hymenopteran (Neodiprion sertifer) and a dipteran (Tipula paludosa). Amino acid sequence data for theB. mori NPV were from a report by Sere-bryani et al. (1977) and that for theO. pseudotsugata NPVs were reported previously by us (Rohrmann et al. 1979). The other N-terminal amino acid sequences are presented in this paper. The phylogenetic relationships determined based on the molecular evolution of polyhedrin were also investigated by antigenic comparisons of the proteins using a solid phase radioimmune assay. The results indicate that the lepidopteran NPVs are the most closely related of the above group of viruses and are related to these viruses in the following order:N. sertifer NPV,P. brassicae granulosis virus, andT. paludosa NPV. These data, in conjunction withBaculovirus distribution and evidence concerning insect phylogeny, suggest that theBaculovirus have an ancient association with insects and may have evolved along with them.     

A review of safety tests on baculoviruses

In the late 1960's the degree of safety testing required of new candidate pesticides reached a climax. During this period, the nuclear polyhedrosis virus (NPV) ofHeliothis zea (Boddie) underwent a series of tests as thorough as those required for chemicals by the Environmental Protection Agency (E.P.A.) in the U.S.A. and by guidelines recommended by W.H.O. These included long term carcinogenicity and teratogenicity tests, tests on primates and tests on man. Indeed, the tests were far more demanding than the tests for chemicals because they examined the possibility of infection of test animals by the insect viruses. They led to the registration of a pioneer viral insecticide containing this NPV produced in caterpillars. Two other products from Lepidoptera, containing NPVs ofOrgyia pseudotsugata (McDunn) andLymantria dispar L. have satisfied the E.P.A. registration requirements. The NPV ofNeodiprion sertifer (Geoffr.) (Hym.) has proved harmless in extensive tests, including long term tests. Another 3 NPVs, those ofAutographa californica (Speyer)Spodoptera littoralis Boisd. andS. exempta (Walk.) passed tests not including the long term tests. Also a non-occluded baculovirus of a coleopteran,Oryctes rhinoceros L., has passed extensive pathogenicity tests and tests in cell lines. A number of other NPVs have been partially tested and limited tests have been made on 2 granulosis viruses (GV). The NPVs proved harmless to—and unable to replicate in—microorganisms, non-insect invertebrate cell lines vertebrate cell lines, vertebrates, plants and non-arthropod invertebrates. Replication was unusual in insects outside the insect family in which the virus was first found. GVs occur only in Lepidoptera, most are believed to be very specific and none have replicated in cell lines from insects or other animals. In addition, the rapidly expanding discipline of Invertebrate Pathology has failed to find incidence of NPVs and GVs infecting hosts outside the above stated host ranges. This is in reality a vast body of evidence matched only in extent by the absence of incidence of NPVs and GVs from the publications of medical, veterinary and phytopathology science. This evidence, and the accrued data from specific safety testing, gives increasing confidence that individual NPVs and GVs of Lepidoptera and Hymenoptera are very specific. This confidence suggests that new NPVs and GVs in these orders need be subjected only to a reduced range of the more challenging tests and to tests designed to reveal harm originating from the insect species used for virus production and from contaminants.     

Application of a novel radioimmunoassay to identify baculovirus structural proteins that share interspecies antigenic determinants

Immunological comparisons were made of baculovirus structural proteins by using a modification of the radioimmunological techniques described by Renart et al. (Proc. Natl. Acad. Sci. U.S.A. 76: 3116-3120, 1979) and Towbin et al. (Proc. Natl. Acad. Sci. U.S.A. 76: 4350-4354, 1979). Viral proteins were electrophoresed in polyacrylamide gels, transferred to nitrocellulose, and incubated with viral antisera, and the antibodies were detected with ¹²⁵I-labeled Staphylococcus aureus protein A. Antisera were prepared to purified and intact virions from five baculoviruses: Autographa californica, Porthetria dispar, Trichoplusia ni, and Heliothis zea nuclear polyhedrosis viruses (NPVs) and T. ni granulosis virus (GV). These antisera were tested against the virion structural polypeptides of 17 different species of baculoviruses. Specific multiple-nucleocapsid NPV (MNPV), single-nucleocapsid NPV (SNPV), and GV virion polypeptides were shown to have similar antigenic determinants and thus be immunologically related. The molecular weights of the virion polypeptides with cross-reacting antigenic determinants were identified. Antisera prepared to purified A. californica and H. zea MNPV polyhedrin (the occlusion body protein from NPVs) recognized antigenic determinants on all the polyhedrins and granulins (occlusion body protein from GVs) that were tested. No immunological relationship was detected between A. californica MNPV polyhedrin and any of the A. californica MNPV virion structural polypeptides present on either the virus isolated from occlusion bodies or A. californica MNPV extracellular virus from infected-cell cultures.     

Formation of rhinovirus-soluble ICAM-1 complexes and conformational changes in the virion.

Viral receptors serve both to target viruses to specific cell types and to actively promote the entry of bound virus into cells. Human rhinoviruses (HRVs) can form complexes in vitro with a truncated soluble form of the HRV cell surface receptor, ICAM-1. These complexes appear to be stoichiometric, with approximately 60 ICAM molecules bound per virion or 1 ICAM-1 molecule per icosahedral face of the capsid. The complex can have two fates, either dissociating to yield free virus and free ICAM-1 or uncoating to break down to an 80S empty capsid which has released VP4, viral RNA, and ICAM-1. This uncoating in vitro mimics the uncoating of virus during infection of cells. The stability of the virus-receptor complex is dependent on temperature and the rhinovirus serotype. HRV serotype 14 (HRV14)-ICAM-1 complexes rapidly uncoat, HRV16 forms a stable virus-ICAM complex which does not uncoat detectably at 34 degrees C, and HRV3 has an intermediate phenotype. Rhinovirus can also uncoat after exposure to mildly acidic pH. The sensitivities of individual rhinovirus serotypes to ICAM-1-mediated virus uncoating do not correlate with uncoating promoted by incubation at low pH, suggesting that these two means of virus destabilization occur by different mechanisms. Soluble ICAM-1 and low pH do not act synergistically to promote uncoating. The rate of uncoating does appear to be inversely related to virus affinity for its receptor.     

Polypeptide analysis of genotypic variants of occluded Heliothis spp. baculoviruses

The structural polypeptides of 12 baculovirus isolates which included nuclear polyhedrosis viruses (NPVs) and granulosis viruses (GVs) obtained from four different species of the insect genus Heliothis collected in different geographical regions of the world were characterized using sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The matrix proteins were compared according to their molecular weights and peptide profiles produced after limited proteolysis. Examination of the matrix and virion polypeptide profiles revealed three major polypeptide phenotypes which corresponded to the three baculovirus morphological groups; singly embedded nuclear polyhedrosis viruses (SNPVs), multiply embedded nuclear polyhedrosis viruses (MNPVs), and granulosis viruses (GVs). Enveloped nucleocapsid polypeptide profiles of isolates within each NPV phenotype differed in only one polypeptide whereas the two GV isolates differed by as many as five polypeptides. Nucleocapsid polypeptide profiles of isolates within each of the NPV subgroups were identical while those profiles from the GV nucleocapsids differed slightly in molecular weight of one polypeptide.     

Effects of Recombinant Baculoviruses on Three Nontarget Heliothine Predators

Genetically engineered baculoviruses, relative to their wild-type progenitors, have successfully improved the time-to-kill of these arthropod-specific biopesticides. Beneficial arthropods that prey on targeted pest insects are likely the first nontarget organisms to be adversely affected by the applications of such biopesticides. The goals of this project were to assess potential risks of the recombinant baculoviruses on Solenopsis invicta, Geocoris punctipes, and Hippodamia convergens, all of which are common predators of heliothines in Texas cotton. Four recombinant Autographa californica nuclear polyhedrosis viruses (AcNPV), one Helicoverpa zea nuclear polyhedrosis virus (HzNPV), and two corresponding wild-type NPVs were used in this risk assessment study. Risks associated with these baculoviruses were determined by possible shifts in predator life history traits (rate of food consumption, travel speed, fecundity, and survival) when fed prey infected with recombinant viruses compared to prey infected with wild-type viruses or to healthy prey. We also tested for possible transmission of these viruses by predators using the polymerase chain reaction (PCR). No significant shifts in life history characteristics were detected in predators fed Heliothis virescens larvae infected with any of the seven viruses. Viral DNA was discovered using PCR in 2.3% of fire ant workers, but not from any of the queens or eggs. In G. punctipes, 13.4% of adults and 0.5% of eggs scored positive for viruses. Twelve percent of H. convergens adults were found PCR positive. Residency in all three predators tested provides a pathway which could increase the persistence of recombinant viral particles in the environment and thus may produce an indeterminable amount of risk associated with their inadvertent movement.     

Host range and virulence of five baculoviruses from lepidopterous hosts

The host range and virulence of five insect baculoviruses (two multiply-enveloped nuclear polyhedrosis viruses (MNPVs) from Agrotis segetum and Mamestra brassicae; one singly-enveloped NPV from Plusia gamma and two granulosis viruses (GVs) from A. segetum and Pieris brassicae) were studied for seven lepidopterous pests of temperate agriculture (A. segetum, Agrotis exclamationis, Lacanobia oleracea, M. brassicae, Noctua pronuba, P. gamma and Pieris rapae). None of the viruses killed all species but M. brassicae MNPV failed to infect only P. rapae. The other viruses were restricted to the homologous host, or members of its genus or subfamily. In all examples except A. segetum GV, the median lethal dose for the most susceptible host, was less than 22 virus inclusion bodies and median lethal times for all infections ranged from 5·5 to 16·6 days. The low susceptibility of A. segetum and other noctuids to GV infections is discussed in relation to the structure of inclusion bodies and the nature of the infectious unit in baculoviruses.     

杆状病毒与昆虫宿主相互作用的研究进展

杆状病毒与昆虫宿主相互作用是一种基本的分子和生态问题, 不仅在农业上, 而且在真核表达系统、 基因治疗、 蛋白表面展示 系统以及基因工程疫苗等方面都有重要的实际应用。杆状病毒还是一种很有潜力的病毒杀虫剂, 而且对环境来说是安全的。研究这些相互 作用也产生了许多重要和有价值的发现。杆状病毒生命循环中存在两种不同形式的病毒, 即包埋型病毒粒子(occlusion derived virus, ODV) 和出芽型病毒粒子(budded virus, BV)。ODV包裹于多角体中, 主要负责宿主的原发感染; 而BV由感染的宿主细胞释放后引发继发 感染。病毒侵染起始于敏感的昆虫宿主食用了污染包涵体病毒的植物。在宿主中肠的碱性环境中, 多角体溶解释放ODV, ODV与宿主肠道 柱状上皮细胞细胞膜融合, 通过内吞体进入细胞。之后核衣壳从内吞体中逃脱并被转运到细胞核。病毒转录和复制在细胞核进行, 新生 的BV粒子从基底膜出芽引起全身感染。杆状病毒与宿主细胞相互作用包括从病毒结合和进入时的相互作用, 到宿主基因表达调节, 以及 修饰与调节细胞和机体所发生的生理和防御的相互作用的复杂和微妙的机制。本文主要以杆状病毒侵染昆虫宿主的过程为线索, 总结和评 述了杆状病毒与昆虫宿主相互作用方面研究的最新进展, 特别是杆状病毒基因在病毒入侵过程中所起的作用。     

Persistence of insect viruses in field populations of alfalfa insects

The persistence of viruses of five insects was observed in alfalfa fields. The insects were Autographa californica, Colias eurytheme, Pseudaletia unipuncta, Spodoptera exigua, and Trichoplusia ni. The isolated viruses were the granulosis (GV), the cytoplasmic-polyhedrosis (CPV), and the nuclear-polyhedrosis (NPV) viruses. The viruses persisted in the soil, on the alfalfa foliage, and in alternate hosts. In the soil, the viruses persisted even during the winter months when no foliage remained on the plants. Alfalfa sprouts harboring virus-infected larvae of C. eurytheme and S. exigua produced virus infections in larvae of these insects, but those with larvae of A. californica and P. unipuncta did not cause virus infection. The GVs and CPVs isolated from these insects were transmitted to nearly all of the other four species, but the NPVs appeared to be host specific.     

Molecular dissection of <Emphasis Type="Italic">Bombyx mori</Emphasis> nucleopolyhedrovirus <Emphasis Type="Italic">orf8</Emphasis> gene

Viruses including baculoviruses are obligatory parasites, as their genomes do not encode all the proteins required for replication. Therefore, viruses have evolved to exploit the behavior and the physiology of their hosts and often coevolved with their hosts over millions of years. Recent comparative analyses of complete genome sequences of baculoviruses revealed the patterns of gene acquisitions and losses that have occurred during baculovirus evolution. In addition, knowledge of virus genes has also provided understanding of the mechanism of baculovirus infection including replication, species-specific virulence and host range. The Bm8 gene of Bombyx mori nucleopolyhedrovirus (NPV) and its homologues are found only in group I NPV genomes. The Autographa californica NPV Ac16 gene is a homologue of Bm8 and, encodes a viral structural protein. It has been shown that Bm8/Ac16 interacts with baculoviral and cellular proteins. Bm8/Ac16 interacts with baculoviral IE1 that is facilitated by coiled coil domains, and the interaction with IE1 is important for Bm8 function. Ac16 also forms a complex with viral FP25 and cellular actin and associates with membranes via palmitoylation. These data suggested that this gene family encodes a multifunctional protein that accomplishes specific needs of group I NPVs.      

Identification of the lymantria dispar nucleopolyhedrovirus envelope fusion protein provides evidence for a phylogenetic division of the Baculoviridae

The complete genome sequences of a number of diverse members of the Baculoviridae including both nucleopolyhedroviruses (NPVs) and granuloviruses (GVs) revealed that they lack a homolog of GP64, the envelope fusion protein of the budded form of Autographa californica multinucleocapsid NPV (AcMNPV) and its close relatives. Computer-assisted analyses of the genome of one of these viruses, Lymantria dispar MNPV (LdMNPV), revealed a single open reading frame (ld130) whose product had the predicted properties of a membrane protein. Characterization of the localization of the products of the full-length ld130 gene and of an ld130-enhanced green fluorescent protein gene (egfp) fusion using both immunofluorescence and fluorescence microscopy revealed that LD130 accumulates at the plasma membranes of cells infected with LdMNPV or transfected with ld130-egfp. In addition, cells transfected with either ld130 or ld130-egfp or infected with wild-type virus undergo membrane fusion at pH 5. Western blot analyses indicate that LD130 is present in infected cells as an 83-kDa protein and is also present in budded virions as a protein doublet containing bands of 81 and 83 kDa. Tunicamycin treatment of infected cells resulted in an immunoreactive band of about 72 kDa, indicating that LD130 is N-glycosylated. Whereas the distribution of gp64 appears to be confined to a relatively closely related group of NPVs, homologs of ld130 are present in a diverse number of both NPVs and GVs. This suggests that LD130 may be the primordial baculovirus envelope fusion protein.     

Infection of its lepidopteran host by the Helicoverpa armigera stunt virus (Tetraviridae)

Techniques of microscopy and histopathology were employed to study the positive-sense, single-stranded RNA virus, the Helicoverpa armigera stunt virus (HaSV; omegatetravirus, Tetraviridae) infecting its caterpillar host. Infection of the virus per os during the first three instars of larval development is virulent and leads to rapid stunting and mortality. In contrast, no detectable symptoms occur in later larval development, signifying a high degree of developmental resistance. A quantitative study of cell populations in the host midgut during this time showed that increased cell numbers during development alone could not account for the increase in resistance. HaSV infection was restricted to the midgut and three of its four cell types. In younger larvae, the virus initiated its infection in closely situated foci that appeared to expand to link with others to cover larger areas of the midgut. The midgut cells of the infected larvae responded with an increased rate of sloughing to an extent rendering the midgut incapable of maintenance or recovery of normal function. In contrast, infection of older larvae by HaSV did not lead to overt pathology although foci of HaSV infection were detected in their midguts. However, the foci were more sparsely situated, failed to expand, and eventually disappeared, presumably due to cell sloughing. These observations indicate that cell sloughing is an immune response existing throughout larval development but midguts of older larvae have an additional mechanism to account for the increased resistance. This second mechanism results in midgut cells becoming more refractory to infection and, combined with cell sloughing, allows the midguts of older larvae to recover more readily from HaSV infection. These two mechanisms are similar to those seen with host responses to baculoviruses, which display developmental resistance to a lesser degree against more general infections. HaSV remaining in the midgut appears to amplify the degree of developmental resistance.     

Virus particle packaging in baculovirus and cytoplasmic polyhedrosis virus inclusion bodies

The structure of the inclusion bodies (IBs) of three multiply enveloped nuclear polyhedrosis viruses (MNPVs), one singly enveloped NPV (SNPV), two granulosis viruses (GVs) and one cytoplasmic polyhedrosis virus (CPV) were compared. A method was devised to calculate the numbers of virus particles and nucleocapsids in IBs using data from light microscopy and thin sections. The three MNPVs, from Agrotis segetum (English and Polish virus isolates) and Mamestra brassicae had similar concentrations of virus particles ranging from 17.3 to 19.6 per μm³ of IB. Plusia gamma SNPV had a higher density of 59.6 virus particles per μm³ of IB, which partly compensated for its having smaller IBs (mean volume 0.65 μm³) than the MNPVs (2.60–9.71 μm³). The English A. segetum MNPV isolate had the most nucleocapsids in each virus particle (mean, 4.04) and the largest IBs (mean volume, 9.71 μm³), giving 674 nucleocapsids per IB on average. The GVs, from A. segetum and Pieris brassicae, mainly contained one nucleocapsid per IB. P. gamma CPV IBs had a much higher density of virus particles than the baculoviruses (260 per μm³ compared with 17–60 per μm³). These data are discussed in relation to the biological properties of these viruses, and possible adaptational advantages of alternative IB designs are considered.     

Ascovirus and its evolution

Ascoviruses, iridoviruses, asfarviruses and poxviruses are all cytoplasmic DNA viruses. The evolutionary origins of cytoplasmic DNA viruses have never been fully addressed. Morphological, genetic and molecular data were used to test if all four cytoplasmic virus families (Ascoviridae, Iridoviridae, Asfarviridae, and Poxvirirdae) evolved from nuclear replicating baculoviruses and how the four virus groups are related. Molecular phylogenetic analyses using DNA polymerase predicted that cytoplasmic DNA viruses might have evolved from nuclear replicating baculoviruses, and that poxviruses and asfarviruses share a common ancestor with iridoviruses. These three cytoplasmic viruses again shared a common ancestor with ascoviruses. Morphological and genetic data predicted the same evolutionary trend as molecular data predicted. A genome sequence comparison showed that ascoviruses have more baculovirus protein homologues than do iridoviruses, which suggested that ascoviruses have evolved from baculoviruses and iridoviruses evolved from ascoviruses. Poxviruses showed genetic and morphological similarity to other cytoplamic viruses, such as ascoviruses, suggesting it has undergone reticulate evolution via hybridization, recombination and lateral gene transfer with other viruses. Within the ascovirus family, we tested if molecular phylogenetic analyses agree with biological inference; that is, ascovirus had an evolutionary trend of increasing genome size, expanding host range and widening tissue tropism for these viruses. Both molecular and biological data predicted this evolutionary trend. The phylogenetic relationship among the four species of ascovirus was predicted to be that TnAV-2 and HvAV-3 shared a common ancestor with SfAV-1 and the three virus species again shared a common ancestor with DpAV-4.      

A new continuous cell line from larval hemocytes of Spodoptera litura (F.).

A new cell line has been established from larval hemocytes of the moth, S. litura (tobacco cut worm). It took 147 days to form a monolayer and one year for the first 17 passages. At present, the culture is at 86th passage level and is designated NIV-SU-1095. Three cell types could be distinguished, viz. plasmatocytes (53%), prohemocytes (36%) and granular hemocytes (11%). The chromosome number was very high, 74% metaphase cells showed more than 100 chromosomes. The cells could be cryopreserved. The cells were susceptible to the baculoviruses, Autographa californica nuclear polyhedrosis virus and S. litura nuclear polyhedrosis virus (SLNPV). Plaques could be observed on 7th post infection day with SLNPV. Six cloned cell lines have been developed of which clone II-1F was more sensitive to both the baculoviruses compared to the original cell line.     

Structural divergence among genomes of closely related baculoviruses and its implications for baculovirus evolution

Baculoviruses are members of a large, well-characterized family of dsDNA viruses that have been identified from insects of the orders Lepidoptera, Hymenoptera, and Diptera. Baculovirus genomes from different virus species generally exhibit a considerable degree of structural diversity. However, some sequenced baculovirus genomes from closely related viruses are structurally very similar and share overall nucleotide sequence identities in excess of 95%. This review focuses on the comparative analysis of partial and complete nucleotide sequences from two groups of closely related baculoviruses with broad host ranges: (a) group I multiple nucleopolyhedroviruses (MNPVs) from a cluster including Autographa californica (Ac)MNPV, Rachiplusia ou (Ro)MNPV, and Plutella xylostella (Plxy)MNPV; and (b) granuloviruses (GVs) from a cluster including Xestia c-nigrum (Xecn)GV and Helicoverpa armigera (Hear)GV. Even though the individual viruses in these clusters share high nucleotide sequence identities, a significant degree of genomic rearrangement (in the form of insertions, deletions, and homologous recombination resulting in allelic replacement) is evident from alignments of their genomes. These observations suggest an important role for recombination in the early evolution and biological characteristics of baculoviruses of these two groups.     

AN ELECTRON MICROSCOPE STUDY OF THE DEVELOPMENT OF SV40 VIRUS

Kidney cells, predominantly from Cercopithecus monkeys but also from baboons, were infected in vitro with the SV40 virus. The infectious cycle was studied with the electron microscope by means of thin sections of cells fixed from 3 hours up to 11 days after infection. The frequency of virus formation and various nuclear and cytoplasmic lesions in relation to the infection are described. The virus particles appear in the nucleus in close contact with the chromatin. In a small number of cells they have been observed as early as 10 to 12 hours after infection, but most often they appear 24 to 48 hours afterward. Their mean diameter is 33 mµ. They have no membrane and are frequently arranged as crystal-like structures. In addition to the appearance of virus, one observes various lesions in the nucleoplasm and particularly in the nucleolus, which shows an early hypertrophy and produces unusual, dense condensations in contact with the nucleolonema. The importance of these nucleolar lesions and the relationship between the SV40 virus and the polyoma, common wart, and Shope papilloma viruses are discussed.     

Nucleotide sequence and molecular characterization of the structural glycoprotein gp41 gene homologue of <Emphasis Type="Italic">Spodoptera litura</Emphasis> nucleopolyhedrosis virus (SpltNPV-I)

The structural glycoprotein gene gp41 homologue of Spodoptera litura nucleopolyhedrosis virus (SpltNPV-I *) was identified in the 4.0 kb EcoRI-L fragment of the viral genome. The nucleotide sequence of 2063 bp of this fragment revealed an open reading frame of 1014 nucleotides to encode a polypeptide of 337 amino acids. Analysis of nucleotide and deduced amino acid sequences of the putative ORF indicated its identity with gp41 protein of other baculoviruses sharing maximum homology with that of Spodoptera frugiperda nucleopolyhedrosis virus (SfNPV). The coding sequence was preceded by an AT-rich region containing the consensus baculoviral late promoter motif RTAAG. The putative SpltNPV gp41 ORF was abundantly expressed as a 37 kDa apoprotein in E. coli and as a 50 kDa glycoprotein in Sf9 cells. The recombinant protein expressed in insect cells was glycosylated (20%) and has GlcNAc as the terminal sugar. The gene is conserved among baculoviruses and places SpltNPV-I close to Spodoptera frugiperda and Spodoptera exigua NPVs in phylogenetic tree.Assigned GenBank accession no. for the nucleotide sequence data is AF445192.abbreviated as SlNPV in earlier publications and GenBank