A Few-Polyhedra Mutant and Wild-Type Nucleopolyhedrovirus Remain as a Stable Polymorphism during Serial Coinfection in Trichoplusia ni

Few-polyhedra (FP) mutants of nucleopolyhedroviruses (NPVs) are a well-known phenomenon during serial passage of virus in cell culture. Under these circumstances such mutants produce low yields of occlusion bodies (OBs) and poorly occlude virions, but they are selected for through advantageous rates of budded virus replication. Spontaneous insertion of transposable elements originating from host cell DNA into the viral fp25 gene has been shown to be a common cause of the phenotype. A model of NPV population genetics predicts that mutants with these characteristics might persist within stable polymorphisms in viral populations during serial passage of virus in vivo. However, this hypothesis was previously untested, and FP mutants have not been recovered from field isolates of NPVs. We isolated and characterized an FP mutant that arose during routine passage of Autographa californica multinucleocapsid NPV (AcMNPV) in cell culture and identified a transposable element within the fp25 gene. We tracked the fates of coinfecting wild-type and FP mutant AcMNPV strains through serial passage in fifth-instar Trichoplusia ni larvae. The levels of both strains remained stable during successive rounds of infection. We applied the data obtained to a model of NPV population genetics in order to derive the frequency distribution of the multiplicity of cell infection in infected insects and estimated that 4.3 baculovirus genomes per OB-producing cell would account for this equilibrium.     

Persistence of an occlusion-negative recombinant nucleopolyhedrovirus in Trichoplusia ni indicates high multiplicity of cellular infection.

We use data from the serial passage of co-occluded recombinant Autographa californica nuclear polyhedrosis virus (AcMNPV) to estimate the viral multiplicity of infection of cells within infected insects. Co-occlusion, the incorporation of wild-type and mutant virus genomes in the same occlusion body, has been proposed as a strategy to deliver genetically modified viruses as insecticides in a way that contains their spread in the environment. It may also serve as a means whereby naturally occurring mutant forms of NPVs can be maintained in a stable polymorphism. Here, a recombinant strain of AcMNPV was constructed with a deletion of its polyhedrin gene, rendering it incapable of producing occlusion bodies (i.e., occlusion negative). This was co-occluded with wild-type AcMNPV and used to infect fifth-instar Trichoplusia ni larvae. The fate of both genotypes was monitored over several rounds of insect infection. Levels of the occlusion-negative virus genome declined slowly over successive rounds of infection. We applied these data to a model of NPV population genetics to derive an estimate of 4.3 +/- 0.3 viral genomes per occlusion body-producing cell.     

苜蓿丫纹夜蛾核型多角体病毒fp25k基因的改造及用于稳定转化Sf9昆虫细胞系

【目的】苜蓿丫纹夜蛾核型多角体病毒(Autographa californica multicapsid nucleopolyhedrovirus, AcMNPV)在昆虫细胞中连续传代以后,会出现从多多角体表型到少多角体表型的转变,这种转变与一个编码25 kDa蛋白的基因（few polyhedra, fp25k）突变失活有关。杆状病毒的fp25k基因突变后产生的包涵体（多角体）衍生病毒粒子变少而出芽型病毒粒子增加,会降低外源基因在杆状病毒表达系统中的表达。本研究拟改造fp25k并构建能持续表达FP25K蛋白的转基因昆虫细胞,以克服杆状病毒, fp25k基因易突变导致的表达系统缺陷。【方法】本实验通过改造杆状病毒, fp25k基因在细胞传代过程中容易产生突变的位点,得到 mfp25k,并将mfp25k构建到pIZT/V5-His载体上,重组载体转染Sf9细胞,通过Zeocin抗性筛选逐步淘汰未成功转化的Sf9细胞。【结果】成功改造AcMNPV的, fp25k基因的TTAA位点,得到pIZT-mfp25k重组载体。重组载体成功转染Sf9细胞,通过Zeocin抗性筛选后获得基因组中带有mfp25k的Sf9-mfp25k稳定的转基因细胞系。用AcMNPV的fp25k突变型病毒AcP2感染转基因Sf9-mfp25k昆虫细胞系与正常Sf9细胞,发现转基因Sf9-mfp25k昆虫细胞系表达的FP25K蛋白可弥补病毒, fp25k基因突变的缺陷。【结论】建立的Sf9-mfp25k转基因昆虫细胞系通过细胞表达FP25K蛋白,可以弥补因杆状病毒fp25k基因突变产生的缺陷。研究结果为构建稳定的杆状病毒 昆虫细胞表达系统提供了新途径。     

Persistence of an Occlusion-Negative Recombinant Nucleopolyhedrovirus in Trichoplusia ni Indicates High Multiplicity of Cellular Infection

We use data from the serial passage of co-occluded recombinant Autographa californica nuclear polyhedrosis virus (AcMNPV) to estimate the viral multiplicity of infection of cells within infected insects. Co-occlusion, the incorporation of wild-type and mutant virus genomes in the same occlusion body, has been proposed as a strategy to deliver genetically modified viruses as insecticides in a way that contains their spread in the environment. It may also serve as a means whereby naturally occurring mutant forms of NPVs can be maintained in a stable polymorphism. Here, a recombinant strain of AcMNPV was constructed with a deletion of its polyhedrin gene, rendering it incapable of producing occlusion bodies (i.e., occlusion negative). This was co-occluded with wild-type AcMNPV and used to infect fifth-instar Trichoplusia ni larvae. The fate of both genotypes was monitored over several rounds of insect infection. Levels of the occlusion-negative virus genome declined slowly over successive rounds of infection. We applied these data to a model of NPV population genetics to derive an estimate of 4.3 ± 0.3 viral genomes per occlusion body-producing cell.     

Kinetic characterization of the group II Helicoverpa armigera nucleopolyhedrovirus propagated in suspension cell cultures: implications for development of a biopesticides production process

Large-scale commercialization of baculovirus biopesticides for the control of insect pests requires a cell culture production process, and knowledge of the infection kinetics is a vital prerequisite for process optimization. Well-characterized kinetic parameters have so far only been reported for the commercially established recombinant Autographa californica nucleopolyhedrovirus (AcMNPV), a Group I NPV. In this work, key infection kinetic parameters of the Group II NPV Helicoverpa armigera nucleopolyhedrovirus (HaSNPV), and its Few Polyhedra (FP) mutant, were well characterized for the first time, in suspension HzAM1 insect cell cultures, to facilitate the scale-up of an HaSNPV-based biopesticide. The FP mutant had a selective advantage over wild-type HaSNPV in cell cultures, and the kinetic analysis showed that this was due to a superior budding rate, rather than a faster binding rate (BR) or longer budding duration. Another finding was that wild-type HaSNPV had very poor infection kinetics when compared with AcMNPV, exhibiting an 18-fold lower BR, a more than 50-fold lower budding rate, and a 60-fold lower extracellular/total progeny virus ratio. Such poor infection kinetics have serious implications during scale-up of an HaSNPV biopesticide production process, including the requirement for large volumes of virus inocula and the difficulty of achieving synchronous infections. Groups I and II NPVs may have very different infection kinetics because of their different envelope fusion proteins. This study is the first to compare the two groups of NPVs in terms of well-characterized cell-specific infection kinetics, and the findings may indicate a phylogenetic basis for kinetic differences.     

Effect of time of harvest of budded virus on the selection of baculovirus FP mutants in cell culture

Rapid formation and selection of FP (few polyhedra) mutants occurs during serial passaging of Helicoverpa armigera nucleopolyhedrovirus (HaSNPV) in insect cell culture. The production of HaSNPV for use as biopesticides requires the passaging of the virus over a number of passages to produce enough virus inoculum for large-scale fermentation. During serial passaging in cell culture, FP mutants were rapidly selected, resulting in declined productivity and reduced potency of virus. Budded virus (BV) is usually harvested between 72 and 96 h postinfection (hpi) in order to obtain a high titer virus stock. In this study, the effect of time of harvest (TOH) for BV on the selection rate of HaSNPV FP mutants during serial passaging was investigated. BV were harvested at different times postinfection, and each series was serially passaged for six passages. The productivity and percentage of FP mutants at each passage were determined. It was found that the selection of FP mutants can be reduced by employing an earlier TOH for BV. Serial passaging with BV harvested at 48 hpi showed a slower accumulation of FP mutants compared to that of BV harvested after 48 hpi. Higher cell specific yields were also maintained when BV were harvested at 48 hpi. When BV that were formed between 48 and 96 hpi were harvested and serially passaged, FP mutants quickly dominated the virus population. This suggests that the BV formed and released between 48 and 96 hpi are most likely from FP mutant infected cells.     

Accumulation of few-polyhedra mutants upon serial passage of Anticarsia gemmatalis multiple nucleopolyhedrovirus in cell culture

Anticarsia gemmatalis nucleopolyhedrovirus (AgMNPV) has been widely used to control the velvetbean caterpillar, Anticarsia gemmatalis, in Brazil. To date, AgMNPV has been produced by larval infection and, due to in vivo production limitations and the continuing high demand for the biopesticide, attempts should be made to develop in vitro production of this virus. In order to investigate the effects caused by serial passage of AgMNPV in cell culture, we carried out a total of ten passages and analyzed the morphological and the genomic changes of the virus. After six passages, the many-polyhedra (MP) phenotype started to switch to the few-polyhedra (FP) phenotype which rapidly accumulated in the virus population. Ultrastructural analysis showed typical signs of FP mutant formation such as decrease in the number of polyhedra per cell, polyhedra aberrant morphology and low numbers of virions occluded in the protein matrix. Also enhanced BV production was observed from the fifth passage indicating that FP mutants were becoming predominant in comparison to the wild type virus. Restriction endonuclease analysis of the viral DNA revealed that lower and higher passages had similar profiles indicating that there were no large insertions or deletions or rearrangements in their genomes and indicating the generation of FP mutants instead of defective interfering viruses.     

Strain selection during serial passage of Trichoplusia in nuclear polyhedrosis virus.

Two strains of a nuclear polyhedrosis virus (NPV) of Trichoplusia ni were isolated on the basis of plaque morphology. They are designated as MP (having greater than 30 polyhedra per nucleus) and FP (having fewer than 10 polyhedra per nucleus). Serial, undiluted passage of plaque, purified MP nonoccluded. Virus (NOV) in tissue culture led to the production of the FP phenotype detectable at passage 9. With continued serial, undiluted passage, FP became the predominant strain. Comparative growth curves showed that FP NOV are released faster than MP NOV. MP morphology was not observed after 14 serial, undiluted passages of plaque-purified FP. By the plaque neutralization assay, NOV from both strains of virus was neutralized by the homologus and heterologous antisera. The FP phenotype was observed when FP virus was grown in culture at 17, 22, and 27 C. Hence, the FP phenotype was not considered to be the result of temperature-inhibited crystallization of polyhedrin under standard tissue culture conditions. The NOV of both strains killed insects when injected directly into the hemocoele of T. ni larvae. Only MP inclusion bodies were virulent per os. The FP inclusion bodies fed to cabbage looper larvae did not kill, and no infectious agent could be detected in the hemolymph. Electron micrographs of MP polyhedra showed bundles of nucleocapsids of normal length within the polyhedra, whereas FP polyhedra contained heterogeneous, electron-dense material, which could account for their lack of pathogenicity.     

Replication and passage of alfalfa looper nuclear polyhedrosis virus plaque variants in cloned cell cultures and larval stages of four host species

As alfalfa looper nuclear polyhedrosis virus (NPV) was serially passed through TN-368 cell cultures, the percentage of the cell population that developed infection with the MP variant decreased, while cells infected with FP variant increased. The MP variant was more virulent to Trichoplusia ni than the FP variant. Cells from the TN-368 cell line and strains derived from single cells were infected with isolated MP plaques. The viral progeny remained homogenous after one or occasionally two passages in cultured TN-368 cells. However, further serial passes in TN-368 cells or one pass in cell strains resulted in loss of the homogeneity, and the FP variant was detected. Four species of Lepidopterous larvae were also infected with the MP variant. Both variants were detected in viral progeny from diseased larvae.     

Enhancement of polyhedrin nuclear localization during baculovirus infection.

Polyhedrin is the major component of the nuclear viral occlusions produced during replication of the baculovirus Autographa californica multicapsid nuclear polyhedrosis virus (AcMNPV). Since viral occlusions are responsible for the horizontal transmission of AcMNPV in nature, the biosynthesis, localization, and assembly of polyhedrin are important events in the viral replication cycle. We recently defined the sequence requirements for nuclear localization and assembly of polyhedrin. In this study, we examined the localization of polyhedrin at different times of infection. The results showed that nuclear localization of polyhedrin becomes more efficient as the occlusion phase of infection progresses. Several different factors were identified that might contribute to this overall effect, including a higher rate of polyhedrin nuclear localization and a higher rate of polyhedrin biosynthesis. We also examined the biosynthesis and processing of polyhedrin in cells infected with an AcMNPV few polyhedra (FP) mutant, which produces smaller numbers of viral occlusions that contain few or no virions. Compared with wild type, the FP mutant produced polyhedrin more slowly and localized it to the nucleus less efficiently at the beginning of the occlusion phase of infection (24 h postinfection). This supported the idea that the efficiency of polyhedrin nuclear localization is tightly coupled to its rate of biosynthesis. It also revealed that expression of the viral 25K gene, which is inactivated in the FP mutant, is directly or indirectly associated with an enhancement of polyhedrin biosynthesis and nuclear localization at the beginning of the occlusion phase of infection. This enhancement effect appears to be necessary to ensure the normal assembly of viral occlusions.     

Group Ⅰ but not Group Ⅱ NPV induces antiviral effects in mammalian cells

Nucleopolyhedrovirus (NPV) is divided into Group Ⅰ and Group Ⅱ based on the phylogenetic analysis. It has been reported that Group Ⅰ NPVs such as Autographa californica multiple NPV (AcMNPV) can transduce mammalian cells, while Group Ⅱ NPVs such as Helicoverpa armigera single NPV (HaSNPV) cannot. Here we report that AcMNPV was capable of stimulating antiviral activity in human hepatoma cells (SMMC-7721) manifested by inhibition of Vesicular Stomatitis virus (VSV) replication. In contrast, the HaSNPV and the Spodoptera exigua multiple NPV (SeMNPV) of group Ⅱ had no inhibitory effect on VSV. Recombinant AcMNPV was shown to induce interferons alpha/beta even in the absence of transgene expression in human SMMC-7721 cells, while it mediated transgene expression in BHK and L929 mammalian cells without an ensuing antiviral activity.     

Ac23, an envelope fusion protein homolog in the baculovirus Autographa californica multicapsid nucleopolyhedrovirus,is a viral pathogenicity factor

Viral envelope fusion proteins are important structural proteins that mediate viral entry and may affect or determine the host range of a virus. The acquisition, exchange, and evolution of such envelope proteins may dramatically affect the success and evolutionary divergence of viruses. In the family Baculoviridae, two very different envelope fusion proteins have been identified. Budded virions of group I nucleopolyhedroviruses (NPVs) such as the Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV), contain the essential GP64 envelope fusion protein. In contrast group II NPVs and granuloviruses have no gp64 gene but instead encode a different envelope protein called F. F proteins from group II NPVs can functionally substitute for GP64 in gp64null AcMNPV viruses, indicating that GP64 and these F proteins serve a similar functional role. Interestingly, AcMNPV (and other gp64-containing group I NPVs) also contain an F gene homolog (Ac23) but the AcMNPV F homolog cannot compensate for the loss of gp64. In the present study, we show that Ac23 is expressed and is found in budded virions. To examine the function of F protein homologs from the gp64-containing baculoviruses, we generated an Ac23null AcMNPV genome by homologous recombination in E. coli. We found that Ac23 was not required for viral replication or pathogenesis in cell culture or infected animals. However, Ac23 accelerated the mortality of infected insect hosts by approximately 28% or 26 h. Thus, Ac23 represents an important viral pathogenicity factor in larvae infected with AcMNPV.     

Group I but not Group II NPV induces antiviral effects in mammalian cells

Nucleopolyhedrovirus(NPV) is divided into Group I and Group II based on the phy-logenetic analysis.It has been reported that Group I NPVs such as Autographa californica multiple NPV(AcMNPV) can transduce mammalian cells,while Group II NPVs such as Helicoverpa armigera single NPV(HaSNPV) cannot.Here we report that AcMNPV was capable of stimulating antiviral ac-tivity in human hepatoma cells(SMMC-7721) manifested by inhibition of Vesicular Stomatitis virus(VSV) replication.In contrast,the HaSNPV and the Spodoptera exigua multiple NPV(SeMNPV) of group II had no inhibitory effect on VSV.Recombinant AcMNPV was shown to induce interferons al-pha/beta even in the absence of transgene expression in human SMMC-7721 cells,while it mediated transgene expression in BHK and L929 mammalian cells without an ensuing antiviral activity.     

Pivotal role of the non-hr origin of DNA replication in the genesis of defective interfering baculoviruses

The generation of deletion mutants, including defective interfering viruses, upon serial passage of Spodoptera exigua multicapsid nucleopolyhedrovirus (SeMNPV) in insect cell culture has been studied. Sequences containing the non-homologous region origin of DNA replication (non-hr ori) became hypermolar in intracellular viral DNA within 10 passages in Se301 insect cells, concurrent with a dramatic drop in budded virus and polyhedron production. These predominant non-hr ori-containing sequences accumulated in larger concatenated forms and were generated de novo as demonstrated by their appearance and accumulation upon infection with a genetically homogeneous bacterial clone of SeMNPV (bacmid). Sequences were identified at the junctions of the non-hr ori units within the concatemers, which may be potentially involved in recombination events. Deletion of the SeMNPV non-hr ori using RecE/RecT-mediated homologous ET recombination in Escherichia coli resulted in a recombinant bacmid with strongly enhanced stability of virus and polyhedron production upon serial passage in insect cells. This suggests that the accumulation of non-hr oris upon passage is due to the replication advantage of these sequences. The non-hr ori deletion mutant SeMNPV bacmid can be exploited as a stable eukaryotic heterologous protein expression vector in insect cells.     

Transposon mutagenesis of baculoviruses: analysis of TFP3 lepidopteran transposon insertions at the FP locus of nuclear polyhedrosis viruses

We report the complete sequences of two representatives of the TFP3 transposable element family of the lepidopteran, Trichoplusia ni. These elements were isolated as insertions mobilized from the Lepidopteran host genome into two closely related nuclear polyhedrosis viruses (NPV) during infection. Both elements inserted within the 500-bp FP locus of the respective viral genomes (map units 36.0 to 37.0), causing a distinctive plaque morphology phenotype and the loss of a 25-kDa viral-specific protein. Both insertions occurred at the identical TTAA target site in the respective genomes, in the same relative orientation, and are flanked by 15-bp imperfect inverted repeats. The inserted elements interrupt the 25K open reading frame (ORF). One of these FP mutants undergoes spontaneous reversion. Sequence analysis at the excision site of a spontaneous revertant demonstrates that the TFP3 elements are capable of precise excision, restoring the expression of the 25-kDa protein. We also compare the sequences of the 25K genes of the Autographa californica and Galleria mellonella viruses (AcMNPV and GmMNPV, respectively). The 25K gene sequences diverge in five areas, resulting in an additional EcoRV and TaqI site within the GmMNPV 25K gene, and extension of the ORF for an additional 2 amino acids at the C-terminus of the predicted GmMNPV 25 kDa protein. The phenomenon of transposon mutagenesis of Baculovirus genomes provides a unique opportunity for analysis of transposon mobility.     

Group I but not Group II NPV induces antiviral effects in mammalian cells

Nucleopolyhedrovirus (NPV) is divided into Group I and Group II based on the phylogenetic analysis. It has been reported that Group I NPVs such as Autographa californica multiple NPV (AcMNPV) can transduce mammalian cells, while Group II NPVs such as Helicoverpa armigera single NPV (HaSNPV) cannot. Here we report that AcMNPV was capable of stimulating antiviral activity in human hepatoma cells (SMMC-7721) manifested by inhibition of Vesicular Stomatitis virus (VSV) replication. In contrast, the HaSNPV and the Spodoptera exigua multiple NPV (SeMNPV) of group II had no inhibitory effect on VSV. Recombinant AcMNPV was shown to induce interferons alpha/beta even in the absence of transgene expression in human SMMC-7721 cells, while it mediated transgene expression in BHK and L929 mammalian cells without an ensuing antiviral activity.     

Infectivity and mode of action of Baculoviruses

The genus Baculovirus contains three subgroups of viral types: (1) nuclear polyhedrosis viruses (NPVs), (2) granulosis viruses (GVs), and (3) nonoccluded baculoviruses. While little information is available for viruses from the third subgroup, several aspects of the infectivity and mode of action of NPVs and GVs have been studied. The most common route of entry of a virus into an insect host is per os, and both virus types enter midgut cells (primary site of infection) by membrane fusion. However, two distinct mechanisms of virus uncoating occur among the baculoviruses: NPVs uncoat within the nucleus, whereas GVs uncoat at the nuclear pore complex. Baculoviruses of subgroup 3 appear to uncoat by either mechanism. In addition to replicating within the nucleus, NPV inoculum virus may pass through the intestinal epithelium immediately after ingestion, thereby establishing a systemic infection of the hemocoel prior to virus replication in midgut cells. The GVs do not appear to pass through midgut cells as rapidly as NPVs and in general, the developmental cycle of GVs is longer than that of NPVs. NPVs have been grown in cell culture while GVs have not.     

Properties of a unique mutant of Helicoverpa armigera single-nucleocapsid nucleopolyhedrovirus that exhibits a partial many polyhedra and few polyhedra phenotype on extended serial passaging in suspension cell cultures

Summary Serial passaging of wild-type Helicoverpa armigera single-nucleocapsid nucleopolyhedrovirus (HaSNPV) in H. zea (Hz-AM1) insect cell cultures results in rapid selection for the few polyhedra (FP) phenotype. A unique HaSNPV mutant (ppC19) was isolated through plaque purification that exhibited a partial many polyhedra (MP) and FP phenotype. On serial passaging in suspension cell cultures, ppC19 produced fivefold more polyhedra than a typical FP mutant (FP8AS) but threefold less polyhedra than the wild-type virus. Most importantly, the polyhedra of ppC19 exhibited MP-like virion occlusion. Furthermore, ppC19 produced the same amount of budded virus (BV) as the FP mutant, which was fivefold higher than that of the wild-type virus. This selective advantage was likely to explain its relative stability in polyhedra production for six passages when compared with the wild-type virus. However, subsequent passaging of ppC19 resulted in a steep decline in both BV and polyhedra yields, which was also experienced by FP8AS and the wild-type virus at high passage numbers. Genomic deoxyribonucleic acid profiling of the latter suggested that defective interfering particles (DIPs) were implicated in this phenomenon and represented another undesirable mutation during serial passaging of HaSNPV. Hence, a strategy to isolate HaSNPV clones that exhibited MP-like polyhedra production but FP-like BV production, coupled with low multiplicities of infection during scale-up to avoid accumulation of DIPs, could prove commercially invaluable.