Eclipse period of baculovirus infection in larvae of the armyworm, Pseudaletia unipuncta

Two strains of a nuclear polyhedrosis virus (baculovirus) infect larvae of the armyworm, Pseudaletia unipuncta. The hypertrophy strain (HNPV) produces a gradient of infected epithelial cells along the tracheae indicating the movement of infectious material to adjacent cells. Cytopathology of the eclipse period up to the appearance of the virogenic stroma has been separated into three phases during which the chromatin disappears and is replaced by dense interconnected strands of fibrils and dense punctate bodies. Cellular hypertrophy occurs in phase 1 and the virogenic stroma appears in phase 3. The typical strain (TNPV) does not produce structures comparable to those of HNPV infection.     

Acylamines enhance the infection of a baculovirus of the armyworm, Pseudaletia unipuncta (Noctuidae,Lepidoptera)

The acylamines (cationic detergents) enhance the infection of a nuclear polyhedrosis virus (NPV) in larvae of the armyworm, Pseudaletia unipuncta. Those with 6 carbons (hexylamine) or 12 carbons (dodecylamine) in the acyl group are more effective in enhancing the NPV than those with 4, 8, or 10 carbons. Hexylamine and dodecylamine increase the rate of infection beyond the 50% level (ID₅₀) by 10 to 100 times when based on the concentration of the virus polyhedra (inclusion bodies).     

Site of action of a synergistic factor of a granulosis virus of the armyworm, Pseudaletia unipuncta

A synergistic factor (SF), which is present in the capsule matrix protein of a granulosis virus of the armyworm, Pseudaletia unipuncta, enhances baculovirus infection in armyworm larvae. The site of action of the SF was investigated. The oral inoculation of SF did not enhance the infectious hemolymph virions which had been inoculated into the hemocoel. The SF also did not enhance the infection of purified enveloped virions when both virus and SF were inoculated into the hemocoel, but enhancement occurred when they were inoculated orally. Thus, the activity of the SF was confined to the midgut lumen. Observations with ferritin-conjugated antibody indicated that the site of action of SF was the cell membrane of the microvillus. There were more ferritin particles attached to midgut cell membranes of larvae inoculated orally with SF than to those of control larvae inoculated with buffer.     

Protein components of two strains of granulosis virus of the armyworm, Pseudaletia unipuncta (Lepidoptera,Noctuidae)

A synergistic Hawaiian (GVH) and a nonsynergistic Oregonian (GVO) strain of a granulosis virus (GV) infect the armyworm, Pseudaletia unipuncta. The protein components of the enveloped virions and of the capsule (inclusion body) were compared between the two strains. When the enveloped virions of both strains were analyzed by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis, the protein patterns were similar except for minor peaks in the higher molecular weight region. On the other hand, the capsule proteins differed between the two strains when examined with immunoelectrophoresis and SDS-polyacrylamide gel electrophoresis. The capsule proteins of GVH were composed of two major proteins, one a structural protein and the other the protein of the synergistic factor. The capsule protein of GVO, however, had only the structural protein. The rocket immunoelectrophoresis and affinity chromatography indicated that the structural proteins of the two strains were partially dissimilar. The molecular weight of the structural protein of GVO was 29,100 ± 500 and that of GVH was 28,700 ± 500. The amount of synergistic factor in a GVH capsule was about 5% of the dissolved capsule components.     

Unique virus morphogenesis and cytopathology of a baculovirus (hypertrophy strain) in larva of the armyworm,Pseudaletia unipuncta

Nuclear polyhedrosis in tracheal cells caused by the hypertrophy strain of a nuclear polyhedrosis virus (HNPV) has many morphological and developmental features that distinguish it from that caused by the typical strain (TNPV). The most obvious difference is the morphogenic sequence due to the relatively slow virogenic development in HNPV-infected cells, in which are found extensive membranous profiles similar to viral envelopes, electron dense granules, large fibrous bodies, and microtubules. These structures also occur in TNPV-infected cells but are far less abundant and conspicuous. Fibrous bodies found in the cytoplasm and nucleus appear to be morphologically identical. Cellular distortion in a hypertrophied tracheal cell is seen as tearing of mestracheon folds between cells, separation of septate desmosomes, and attenuation in the cellular sheath.     

Modelling baculovirus infection of insect cells in culture

Conclusions Infection of insect cells with baculovirus is a potentially attractive means for producing both viral insecticides and recombinant proteins. The continuation of mathematical modelling studies such as those reviewed in this paper are essential in order to realise the full potential of the system. Through mathematical models it is possible to predict complex behaviours such as those observed when infecting cells at low MOI or when propagating virus in a continuous culture system. A purely empirical analysis of the same phenomena is very difficult if not impossible.The present three models are — despite their complexity and the effort that has gone into developing them — all first generation models. They summarise, to a large extent, our present quantitative understanding of the interaction between baculovirus and insect cells, when looked upon as a black box system. The binding and initial infection processes are still quantitatively poorly understood and further work in this area is much needed. On the longer term, a second generation of models is likely to consider interior processes such as viral DNA and RNA accumulation in much more detail using a structured model of the infection cycle.     

Pathological response of the parasitoid, Glyptapanteles militaris, to nuclear polyhedrosis virus-infected armyworm hosts

The development of the embryonic and larval stages of the internal gregarious parsitoid, Glyptapanteles (=Apanteles) militaris, is adversely affected by the hypertrophy strain of a nuclear polyhedrosis virus in the armyworm, Pseudaletia unipuncta. The initial effects are cessation of parasitoid growth and general tissue disruption, followed by the melanization of parasitoid tissues. Melanization spreads from the parasitoids' caudal vesicle throughout the body, culminating in eventual encapsulation in virus-infected hosts. Parasitoids in armyworm hosts infected with the typical strain of nuclear polyhedrosis virus exhibited no abnormal development.     

Ionic conditions affecting the release and absorption of an alkaline protease associated with the occlusion bodies of insect baculoviruses

Nearly all of the alkaline protease found in the occlusion bodies of baculoviruses (polyhedra for nuclear polyhedrosis and capsules for granulosis viruses) (Baculovirus, subgroup A and B, family Baculoviridae) can be specifically extracted under high ionic concentration. The extraction is directly proportional to the concentrations of NaCl up to 0.25 m. It is not dependent on pH, species of ions, temperature, and incubation time. The protease is reabsorbed under low ionic concentration by protease-extracted and by heat-treated capsules and polyhedra. The protease from Streptomyces griseus is not absorbed. This indicates that the occlusion body proteins have distinct affinity for certain alkaline proteases.     

Production of adeno-associated viral vectors in insect cells using triple infection: optimization of baculovirus concentration ratios

The production of viral vectors or virus-like particles for gene therapy or vaccinations using the baculovirus expression system is gaining in popularity. Recently, reports of a viral vector based on adeno-associated virus (AAV) produced in insect cells using the baculovirus expression vector system have been published. This system requires the triple infection of cells with baculovirus vectors containing the AAV gene for replication proteins (BacRep), the AAV gene for structural proteins (BacCap), and the AAV vector genome (BacITR). A statistical approach was used to investigate the multiplicities of infection of the three baculoviruses and the results were extended to the production of AAVs containing various transgenes. Highest AAV yields were obtained when BacRep and BacCap, the baculovirus vectors containing genes that code for proteins necessary for the formation of the AAV vector, were added in equal amounts at high multiplicities of infection. These combinations also resulted in the closest ratios of infectious to total AAV particles produced. Overexpression of the AAV structural proteins led to the production of empty AAV capsids, which is believed to overload the cellular machinery, preventing proper encapsidation of the AAV vector transgene, and decreased the viability of the insect cells. Delaying the input of BacCap, to reduce the amount of capsids produced, resulted in lower infectious AAV titers then when all three baculoviruses were put into the system at the same time. The amount of BacITR added to the system can be less than the other two without loss of AAV yield.     

Dosage-mortality and time-mortality responses of the armyworm Spodoptera exempta to a nuclear polyhedrosis virus

Third-instar Spodoptera exempta larvae were fed on young maize leaves treated with 20 μl of polyhedral inclusion body (PIB) suspension of concentrations that varied from 1.6 × 10² to 1.6 × 10⁹ PIBs/ml. Daily observations were kept on mortality rates. A probit analysis on the results gave an LD₅₀ value of 48.4 PIBs/larva (lower and upper fiducial limits 39.2 and 59.4 PIBs/larva, respectively), and an LT₅₀ that varied from 146.2 to 221.3 hr, depending on the dosage. LD and LT values obtained show the high pathogenicity of S. exempta nuclear polyhedrosis virus to its host.     

Expression and purification of the matrix protein of Nipah virus in baculovirus insect cell system

Nipah virus (NiV) causes fatal respiratory illness and encephalitis in humans and animals. The matrix (M) protein of NiV plays an important role in the viral assembly and budding process. Thus, an access to the NiV M protein is vital to the design of viral antigens as diagnostic reagents. In this study, recombinant DNA technology was successfully adopted in the cloning and expression of NiV M protein. A recombinant expression cassette (baculovirus expression vector) was used to encode an N‐terminally His‐tagged NiV M protein in insect cells. A time‐course study demonstrated that the highest yield of recombinant M protein (400–500 μg) was expressed from infected cells 3 days after infection. A single‐step purification method based on metal ion affinity chromatography was established to purify the NiV M protein, which successfully yielded a purity level of 95.67% and a purification factor of 3.39. The Western blotting and enzyme‐linked immunosorbent assay (ELISA) showed that the purified recombinant M protein (48 kDa) was antigenic and reacted strongly with the serum of a NiV infected pig. © 2015 American Institute of Chemical Engineers Biotechnol. Prog., 32:171–177, 2016     

Virus-like particle production at low multiplicities of infection with the baculovirus insect cell system

The baculovirus insect cell expression system (BEVS) was used for the production of self-forming Porcine parvovirus-like particles (VLPs) in serum-free medium. A low multiplicity of infection (MOI) strategy was used to overcome an extra virus amplification step, undesirable in industrial production, and to minimize the virus passage effect. It was confirmed that the time of infection (TOI) and MOI are dependent variables. Higher cell densities were obtained at low MOIs, keeping a constant TOI; however, both volumetric and specific productivities were lower. In synchronous infection, at high MOI, the specific productivity decreased when the cells were infected in the late phase of growth. Product degradation due to cell lysis strongly influenced the optimal time of harvest (TOH). Time of harvest was found to be highly dependent on the MOI, and a direct relationship with the cell yield was obtained.Analysis of the culture medium reveals that glutamine depletion occurs in the late phase of the growth. Supplementation of glutamine to uninfected cell cultures resulted in an increased cell yield. Its addition to cultures infected in the middle phase of the growth curve was also able to restore the productivity levels, but addition to cells in their stationary phase caused no observable effect on product expression. The study clearly shows that for a specific TOI it is not obvious what the correct MOI should be to obtain the best volumetric productivity.     

利用多基因缺失型杆状病毒在昆虫细胞中生产腺相关病毒

腺相关病毒(adeno-associated virus, AAV)是基因治疗领域最常使用的病毒载体之一,产量低、成本高是该产业面临的关键瓶颈问题。本研究旨在基于多基因缺失型杆状病毒,建立双病毒感染昆虫细胞以生产AAV的技术体系。首先,进行AAV生产用多基因缺失型重组杆状病毒的构建和扩增,并检测杆状病毒滴度及其感染细胞的效果;然后,使用双杆状病毒共感染昆虫细胞,并优化感染条件;最后,基于优化条件进行AAV生产,并检测评估产量、质量等相关指标。结果表明,AAV生产用多基因缺失型杆状病毒滴度较野生型无差异,感染后细胞存活率下降明显减缓。使用双病毒路线进行AAV优化生产,Bac4.0-1的基因组滴度为1.63×10¹¹ VG/mL,Bac5.0-2的基因组滴度为1.02×10¹¹ VG/mL,较野生型产量分别提升了240%和110%。电镜下,3组均具有正常的AAV病毒形态,且转导活性相近。本研究建立了基于多基因缺失型杆状病毒感染昆虫细胞的AAV生产体系,显著提高了AAV产量,具有一定的应用价值。     

Transmission of nuclear polyhedrosis virus in laboratory population of the armyworm, Mythimna (Pseudaletia) separata

Armyworm, Mythimna (Pseudaletia) separata, a serious pest of 12 agricultural crops, was artificially infected with its nuclear polyhedrosis virus to study the modes of virus transmission among the laboratory population. Virus transmitted by transovum and transovarial modes passed through polyhedra-fed moths to their progeny.     

Overproduction of the protein encoded by the maize transposable element Ac in insect cells by a baculovirus vector

Summary The polypeptide encoded in the Activator (Ac) element of Zea mays L. has been expressed in Spodoptera frugiperda insect cells using plasmids which carry the strong polyhedrin promoter of the baculovirus Autographa californica nuclear polyhedrosis virus (AcNPV). Recombinant AcNPVs with the Ac-cDNA integrated and under the control of the viral polyhedrin promoter have been isolated and their genomes have been partly characterized as to the location of the foreign DNA insert. Upon infection of S. frugiperda cells with the recombinant AcNPV, maize Ac element specific messenger RNAs, as well as a newly synthesized polypeptide with an apparent molecular weight of about 116 kDa, have been detected in extracts of recombinant infected cells. This polypeptide is absent from extracts of wild-type infected cells expressing the polyhedrin polypeptide which can be recognized by the presence of nuclear inclusion bodies. Recombinant infected cells lack this protein. The Ac specific polypeptide is detected by antisera, which have been raised against fusion proteins containing Ac sequences synthesized in Escherichia coli, both in immunoprecipitation and in Western blotting experiments. The Ac specific protein is a nuclear phosphoprotein and represents about 1%–2% of the newly synthesized protein.     

Biochemical properties of viral envelopes of insect baculoviruses and their role in infectivity

The enveloped virions of a nuclear polyhedrosis virus (NPV) and those of a granulosis virus (GV) of the armyworm, Pseudaletia unipuncta, were isolated and purified from their inclusion bodies. The enveloped virion of NPV contained a large amount of phosphatidyl choline which was not detected in that of GV. The total electric charges distributed on the surface of the envelopes of NPV and GV were negative in neutral and alkaline solutions. Although there was little difference in charges between NPV and GV, the charge was less negative in NPV than in GV. When the negative charges were neutralized by cationic detergents, the NPV infectivity was enhanced.     

The indirect effects of multiplicity of infection on baculovirus expressed proteins in insect cells: secreted and non-secreted products

The baculovirus expression vector system was employed to produce human apolipoprotein E and β-galactosidase in order to study the effect of multiplicity of infection on secreted and non-secreted recombinant protein production. Prior knowledge of the influence of other cell culture and infection parameters, such as the cell density at time of infection and the time of harvest, allowed determination of the direct and indirect influences of multiplicity of infection on recombinant protein synthesis and degradation in insect cells. Under non-limited, controlled conditions, the direct effect of multiplicity of infection (10⁻¹−10 pfu/cell) on specific recombinant product yields of non-secreted β-galactosidase was found to be insignificant. Instead, the observed increased in accumulated product was directly correlated to the total number of infected cells during the production period and therefore ultimately dependent on an adequate supply of nutrients. Only the timing of recombinant virus and protein production was influenced by, and dependent on the multiplicity of infection. Evidence is presented in this study that indicates the extremely limited predictability of post-infection cell growth at very low multiplicities of infection of less than 0.1 pfu/cell. Due to the inaccuracy of the current virus quantification techniques, combined with the sensitivity of post-infection cell growth at low MOI, the possibility of excessive post-infection cell growth and subsequent nutrient limitation was found to be significantly increased. Finally, as an example, the degree of product stability and cellular and viral protein contamination at low multiplicity of infection is investigated for a secreted recombinant form of human apolipoprotein E. Comparison of human apolipoprotein E production and secretion at multiplicities of infection of 10⁻⁴−10 pfu/cell revealed increased product degradation and contamination with intracellular proteins at low multiplicities of infection. This revised version was published online in July 2006 with corrections to the Cover Date.     

A mathematical model of baculovirus infection on insect cells at low multiplicity of infection

The expression efficiency of the insect cells-baculovirus system used for insecticidal virus production and the expression of medically useful foreign genes is closely related with the dynamics of infection. The present studies develop a model of the dynamic process of insect cell infection with baculovirus at low multiplicity of