Genetic variation and virulence of Autographa californica multiple nucleopolyhedrovirus and Trichoplusia ni single nucleopolyhedrovirus isolates

To determine the genetic diversity within the baculovirus species Autographa calfornica multiple nucleopolyhedrovirus (AcMNPV; Baculoviridae: Alphabaculovirus), a PCR-based method was used to identify and classify baculoviruses found in virus samples from the lepidopteran host species A. californica, Autographa gamma, Trichoplusia ni, Rachiplusia ou, Anagrapha falcifera, Galleria mellonella, and Heliothis virescens. Alignment and phylogenetic inference from partial nucleotide sequences of three highly conserved genes (lef-8, lef-9, and polh) indicated that 45 of 74 samples contained isolates of AcMNPV, while six samples contained isolates of Rachiplusia ou multiple nucleopolyhedrovirus strain R1 (RoMNPV-R1) and 25 samples contained isolates of the species Trichoplusia ni single nucleopolyhedrovirus (TnSNPV; Alphabaculovirus). One sample from A. californica contained a previously undescribed NPV related to alphabaculoviruses of the armyworm genus Spodoptera. Data from PCR and sequence analysis of the ie-2 gene and a region containing ORF ac86 in samples from the AcMNPV and RoMNPV clades indicated a distinct group of viruses, mostly from G. mellonella, that are characterized by an unusual ie-2 gene previously found in the strain Plutella xylostella multiple nucleopolyhedrovirus CL3 (PlxyMNPV-CL3) and a large deletion within ac86 previously described in the AcMNPV isolate 1.2 and PlxyMNPV-CL3. PCR and sequence analysis of baculovirus repeated ORF (bro) genes revealed that the bro gene ac2 was split into two separate bro genes in some samples from the AcMNPV clade. Comparison of sequences in this region suggests that ac2 was formed by a deletion that fused the two novel bro genes together. In bioassays of a selection of isolates against T. ni, significant differences were observed in the insecticidal properties of individual isolates, but no trends were observed among the AcMNPV, TnSNPV, or RoMNPV groups of isolates. This study expands on what we know about the variation of AcMNPV, AcMNPV-like and TnSNPV viruses, provides novel information on the distinct groups in which AcMNPV isolates occur, and contributes to data useful for the registration, evaluation, and improvement of AcMNPV, AcMNPV-like, and TnSNPV isolates as biological control agents.     

Effect of a nuclepolyhedrovirus of Autographa californica expressing the enhancin gene of Trichoplusia ni granulovirus on T. ni larvae

A recombinant Autographa californica nucleopolyhedrovirus (AcMNPV) strain showing higher virulence against Trichoplusia ni larvae than the wild-type virus was developed. The 'enhancin' (VEF) gene of T. ni granulovirus (TnGV) and the AcMNPV polyhedrin gene were cloned into the baculovirus transfer vector pAcUW31. This plasmid and AcMNPV BacPAK6 DNA were co-transfected into the BTI-Tn5B1-4 cell line. A recombinant AcMNPV strain (BacVEFPol) was purified, amplified, and bioassayed against T. ni first instar larvae. Its estimated LC₅₀ (0.184 OB/mm²) was 2.18 times lower than the LC₅₀ estimated for the wild-type AcMNPV (0.402 OB/mm²). Likewise, an LT₅₀ of 67.7 h was estimated for the recombinant AcMNPV strain while the LT₅₀ of wild-type AcMNPV was estimated at 81.9 h. This indicates a 17.4% reduction of the time required to kill the larvae. The higher virulence of the recombinant strain, evidenced by its LC₅₀ and LT₅₀ values being lower than those of the wild-type strain, indicates that the VEF protein is expressed properly and may be occluded in the OBs.     

Concomitant primary infection of the midgut epithelial cells and the hemocytes of Trichoplusia ni by Autographa californica nucleopolyhedrovirus

We have constructed a modified Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV) to express the green fluorescent protein (GFP) under the polyhedrin promoter and used it to study the infection process of AcMNPV in Trichoplusia ni larvae. T. ni larvae that ingested the virus showed localized expression of GFP in the midgut epithelial cells and the hemocytes at 12 h post infection (hpi). The presence of GFP-related fluorescence in the midgut columnar cells indicated that the virus was not only replicating, but also synthesizing the late viral proteins. Studies using the transmission electron microscope showed that the virus infected the midgut columnar cells. At the same time a proportion of the parental virus travelled through the midgut epithelial layer, possibly utilizing the plasma membrane reticular system, entered the hemocoel and infected the hemocytes. This resulted in the simultaneous infection of the midgut epithelial cells and the hemocytes. Subsequently, the budded virus (BV) released from the infected hemocytes into the hemolymph caused secondary infection within the tracheal epithelial cells. The virus then rapidly spread through the tracheal system allowing the infection of a variety of other tissues such as the epidermis and the fat body.     

Rate of increase of Autographa californica nuclear polyhedrosis virus in Trichoplusia ni larvae determined by DNA:DNA hybridization

The rate of increase and doubling time of the HOB clone of Autographa californica nuclear polyhedrosis virus (AcMNPV-HOB) in neonate Trichoplusia ni larvae was determined by measuring the increase in viral DNA through time following inoculation with average doses of 50 or 17,400 occlusion bodies per larva. Changes in total DNA and viral DNA through time were followed by fluorescence spectroscopy and quantitative slot-blot DNA:DNA hybridization, respectively. Total DNA content (i.e., larval DNA and viral DNA) of larvae infected with the intermediate dose lagged behind that of noninfected larvae 30 hr post-inoculation (p.i), reached a maximum at 51 hr p.i., and stayed constant thereafter. The total DNA content of larvae inoculated with the high dose lagged behind that of the control group from 18 hr p.i. and increased slowly until death of the larvae (ca. 48 hr p.i.). The amount of viral DNA in larvae inoculated with the intermediate dose increased exponentially between 15 and 42 hr p.i., reached a maximum at 48 hr p.i., and stayed constant until 68 hr p.i., by which time most larvae had died. The amount of viral DNA in larvae inoculated with the high dose did not increase exponentially; initially the rate of increase was the same as that for larvae inoculated with the intermediate dose but became progressively lower after 13 hr p.i. Calculations of the rate of increase for AcMNPV-HOB in neonate T. ni larvae inoculated with the intermediate dose and incubated at 29 degrees C resulted in a value of 0.264 hr-1 (doubling time: 2.63 hr).(ABSTRACT TRUNCATED AT 250 WORDS)     

Transgenic protein production in silkworm silk glands requires cathepsin and chitinase of Autographa californica multicapsid nucleopolyhedrovirus

The silkworm Bombyx mori represents an established in vivo system for the production of recombinant proteins. Baculoviruses have been extensively investigated and optimised for the expression of high protein levels inside the haemolymph of larvae and pupae of this lepidopteran insect. Current technology includes deletion of genes responsible for the activity of virus-borne proteases, which in wild-type viruses, cause liquefaction of the host insect and enhance horizontal transmission of newly synthesised virus particles. Besides the haemolymph, the silk gland of B. mori provides an additional expression system for recombinant proteins. In this paper, we investigated how silk gland can be efficiently infected by a Autographa californica multicapsid nuclear polyhedrosis virus (AcMNPV). We demonstrated that the viral chitinase and the cysteine protease cathepsin are necessary to permit viral entry into the silk gland cells of intrahaemocoelically infected B. mori larvae. Moreover, for the first time, we showed AcMNPV crossing the basal lamina of silk glands in B. mori larvae, and we assessed a new path of infection of silk gland cells that can be exploited for protein production.     

Differentiation of Trichoplusia ni MEV and Autographa californica MEV by macrophage migration inhibition tests

The macrophage migration inhibition test (MMI), an in vitro correlate of delayed hypersensitivity, was found to be an effective means of differentiating Trichoplusia ni and Autographa californica multiple embedded nuclear polyhedrosis viruses (NPV). Peritoneal exudate cells from guinea pigs sensitized to virions of T. ni NPV demonstrated significantly different MMI when challenged with T. ni vs A. californica virions. Similarly, when virions of A. californica NPV were employed as the sensitizing antigen, different percentages of MMI were observed in the homologuus versus heterologous challenges.The susceptibility of the fall armyworm, Spodoptera frugiperda, to these two pathogens was very similar as revealed by a comparison of LD₅₀'s, slopes, and fiducial limits of dose-mortality regression lines. In contrast, the cabbage looper, T. ni, was much more susceptible to A. californica NPV.The polyhedral sizes, shapes, and virion occlusion patterns of the two species of NPV were virtually indistinguishable.     

Dissolution of Autographa californica nuclear polyhedrosis virus polyhedra by the digestive fluid of Trichoplusia ni (Lepidoptera:Noctuidae) larvae

The dissolution of polyhedra of Autographa californica nuclear polyhedrosis virus by digestive fluid collected from 5th stage Trichoplusia ni larvae was studied in vitro. Observations were made at timed intervals using phase contrast microscopy, and scanning and transmission electron microscopy. Dissolution occurred rapidly and in a detectable sequence. Under phase contrast, most polyhedra lost their refringence by 0.5 min. The polyhedra became rounded in appearance with small protuberances on the surface and Brownian movement was observed within. After 1 min, the envelope of most polyhedra had ruptured, releasing the enclosed virions. The protuberances were also observed under the scanning electron microscope after digestion for 0.5 min. Many shell fragments devoid of internal contents were seen after more lengthy digestion. Internal structural changes were revealed by electron microscopy. After 1 min of exposure, polyhedra were observed in all stages of dissolution. By 3 min, only virions, scattered about in heterogeneous material, could be distinguished.     

Abnormal formation of polyhedra resulting from a single mutation in the polyhedrin gene of Autographa californica multicapsid nucleopolyhedrovirus

A spontaneous mutant that produces a single abnormally large cubic polyhedron per infected cell was isolated from a polyhedra-positive recombinant Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV). Both wild-type and mutant virus produce two forms of virus particles, budded virions and occluded virions. However, occluded virions are not found within the polyhedra of cells infected with mutant virus, as with the wild-type virus. These large cubic polyhedra do not have the typical lattice-like structure normally seen in wild-type polyhedra and are noninfectious. Spodoptera frugiperda 9 (SF9) cells which were infected with this virus had low infectivity to larvae. No significant alterations were found in the viral genome by restriction enzyme analysis, and no mutations were found in the 25K gene. A single point mutation resulting in an amino acid change of Gly25 to Asp was identified in the polyhedrin gene. A transfer vector containing the entire polyhedrin gene including the point mutation was constructed and used to cotransfect Sf9 cells with a polyhedron-negative recombinant virus. Large cubic polyhedra were once again observed, confirming that the Gly25 to Asp mutation is responsible for the formation of abnormal polyhedra.     

Multiple Nucleocapsid Packaging of Autographa californica Nucleopolyhedrovirus Accelerates the Onset of Systemic Infection in Trichoplusia ni

Among the nucleopolyhedroviruses (Baculoviridae), the occlusion-derived virus (ODV), which initiates infection in host insects, may contain only a single nucleocapsid per virion (the SNPVs) or one to many nucleocapsids per virion (the MNPVs), but the significance of this difference is unclear. To gain insight into the biological relevance of these different packaging strategies, we compared pathogenesis induced by ODV fractions enriched for multiple nucleocapsids (ODV-M) or single nucleocapsids (ODV-S) of Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV) containing a β-galactosidase reporter gene. In time course experiments wherein newly molted fourth-instar Trichoplusia ni were challenged with doses of ODV-S or ODV-M that yielded the same final mortality (~70%), we characterized viral foci as either being restricted to the midgut or involving tracheal cells (the secondary target tissue, indicative of systemic infection). We found that while the timing of primary infection by ODV-S and ODV-M was similar, ODV-S established significantly more primary midgut cell foci than ODV-M, but ODV-M infected tracheal cells at twice the rate of ODV-S. The more efficient establishment of tracheal infections by ODV-M decreased the probability that infections were lost by midgut cell sloughing, explaining why higher numbers of primary infections established by ODV-S within larvae were needed to achieve the same final mortality. These results showed that the multiple nucleocapsid packaging strategy of AcMNPV accelerates the onset of irreversible systemic infections and may indicate why MNPVs have wider individual host ranges than SNPVs.     

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.     

Palmitoylation of the Autographa californica multicapsid nucleopolyhedrovirus envelope glycoprotein GP64: mapping,functional studies,and lipid rafts

Budded virions (BV) of the baculovirus Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV) contain a major envelope glycoprotein known as GP64, which was previously shown to be palmitoylated. In the present study, we used truncation and amino acid substitution mutations to map the palmitoylation site to cysteine residue 503. Palmitoylation of GP64 was not detected when Cys503 was replaced with alanine or serine. Palmitoylation-minus forms of GP64 were used to replace wild-type GP64 in AcMNPV, and these viruses were used to examine potential functions of GP64 palmitoylation in the context of the infection cycle. Analysis by immunoprecipitation and cell surface studies revealed that palmitoylation of GP64 did not affect GP64 synthesis or its transport to the cell surface in Sf9 cells. GP64 proteins lacking palmitoylation also mediated low-pH-triggered membrane fusion in a manner indistinguishable from that of wild-type GP64. Cells infected with viruses expressing palmitoylation-minus forms of GP64 produced infectious virions at levels similar to those from cells infected with wild-type AcMNPV. In combination, these data suggest that virus entry and exit in Sf9 cells were not significantly affected by GP64 palmitoylation. To determine whether GP64 palmitoylation affected the association of GP64 with membrane microdomains, the potential association of GP64 with lipid raft microdomains was examined. These experiments showed that: (i) AcMNPV-infected Sf9 cell membranes contain lipid raft microdomains, (ii) GP64 association with lipid rafts was not detected in infected Sf9 cells, and (iii) GP64 palmitoylation did not affect the apparent exclusion of GP64 from lipid raft microdomains.     

Comparison of wild type and genetically engineered nuclear polyhedrosis viruses of Autographa californica for mortality, virus replication and polyhedra production in Trichoplusia ni larvae

Virus replication and polyhedra production of two polyhedron-positive recombinant nuclear polyhedrosis viruses of Autographa californica, AcJHE.KK and AcAaIT which encode juvenile hormone esterase and scorpion toxin, respectively, were compared with those of a plaque purified wild-type nuclear polyhedrosis virus, AcMNPV-C6, in Trichoplusia ni larvae. Though average times required to kill the T. ni larvae increased with the age of the larvae, killing time by either recombinant virus was significantly shorter than that by wild-type virus. Killing time was reduced ca. 30% for AcAaIT-infected larvae and 5 to 8% for AcJHE.KK-infected larvae as compared to that for AcMNPV-C6-infected larvae. The average weight of larvae infected with AcAaIT was significantly lower than that of larvae infected with AcJHE.KK and AcMNPV-C6. The mean numbers of polyhedra produced in each larva inoculated with AcAaIT and AcJHE.KK were ca. 20% and 60%, respectively, of those for AcMNPV-C6. Total virus titers in AcMNPV-C6-infected larvae were significantly higher than those in AcJHE.KK- and AcAaIT-infected larvae until 2 days post infection.     

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.     

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。     

The effect of host plant species on performance and movement behaviour of the cabbage looper Trichoplusia ni and their potential influences on infection by Autographa californica multiple nucleopolyhedrovirus

• 1 Cabbage loopers Trichoplusia ni (Hübner) (Lepidoptera: Noctuidae) are serious pests in greenhouses growing tomatoes, cucumbers and bell peppers. A potential microbial control, now in development, is the broad host‐range virus Autographa californica multiple nucleopolyhedrovirus (AcMNPV).
• 2 The relationships between the three host plants and the feeding behaviour, larval movement and performance of cabbage looper larvae that might relate to their interaction with AcMNPV applications were investigated.
• 3 Larvae reared on cucumber plants consumed approximately ten‐fold more leaf area than larvae reared on pepper plants and almost five‐fold more than larvae reared on tomato plants. This could influence the amount of AcMNPV consumed if it were used as a microbial spray because increased consumption can be associated with increased probability of infection. Survival from neonate to pupa also varied, with the greatest being on cucumber, followed by tomato and pepper plants. Larvae fed cucumber were approximately four‐fold heavier than larvae fed tomato and over 15‐fold heavier than larvae fed pepper plants.
• 4 The distribution of larvae on plants in commercial greenhouses where a single crop was being grown also varied with food plant with 73% being found on the bottom and middle portions of tomato plants and 87% occurring in the top portions of pepper plants. Larvae tended to be distributed on the middle portion of cucumber plants, the lower portion of tomato plants and the top portion of pepper plants. Larval movement did not vary between AcMNPV‐infected and uninfected controls.
• 5 It is predicted that the higher leaf area consumption and location of larvae in the middle portion of cucumber plants may make them more susceptible to viral sprays. Furthermore, given their greater survival than larvae fed tomato and pepper, there may be a greater need for virus applications.