Canine parvovirus (CPV) remains a leading infectious cause of death in canines, especially in young puppies. Though vaccination is being carried out regularly, immunization failures occur, and puppies may be exposed to infection. Virus-like particles (VLPs) act like a subunit vaccine, mimicking the structure of authentic viruses. Therefore, VLPs have the potential to be used as vaccine candidates. Since Viral Protein 2 (VP2), a major structural protein of CPV, is the crucial antigen for CPV, the purpose of this study was to produce a recombinant VP2 of new canine parvovirus-2a using the baculovirus expression system in SF9 insect cells. The results revealed that recombinant VP2 assembles to form VLPs with antigenic properties similar to those of natural CPV, the recombinant VLP can produce a hemagglutination assay (HA) titer (1:210) in SF9 cells. Expression of the recombinant 6-His-tagged VP2 in SF9 cells was confirmed by western blotting. These findings suggest that the recombinant VP2 expressed in this study could be used as an efficient subunit vaccine against CPV infection.

The baculovirus expression vector system (BEVS) is an effective and widely used method for the production of recombinant proteins in insect cells or larvae. However, the expression efficiency of foreign proteins using the polyhedrin promoter could not obtain the protein yields observed for native polyhedrin. To enhance the production efficiency of foreign protein in baculovirus expression system, the effects of various polyhedrin fragments were investigated by fusion expressing them with the enhanced green fluorescent protein (EGFP). Among the fusion-expressed protein in nucleus and cytoplasm, the most hyper-expression was observed in the fusion of amino acids 19 to 110 and 32 to 59 of polyhedrin. Additionally, the several proteins expressed by the partial polyhedrin-fused expression system was markedly increased. However, we identified that hyper-expression of target protein varied depending on the partial polyhedrin. Therefore, we constructed the virus inducible partial polyhedrin fusion transient expression system. This system amenable for screening of suitable partial polyhedrin to produce the target protein. The present study suggests a new option for higher expression of useful foreign recombinant protein using the partial polyhedrin fusion expression in baculovirus.

A novel recombinant bacmid, bEasyBac, that enables the easy and fast generation of pure recombinant baculovirus without any purification step was constructed. In bEasyBac, attR recombination sites were introduced to facilitate the generation of a recombinant viral genome by in vitro transposition. Moreover, the extracellular RNase gene from Bacillus amyloliquefaciens, barnase, was expressed under the control of the Cotesia plutellae bracovirus early promoter to negatively select against the non-recombinant background. The bEasyBac bacmid could only replicate in host insect cells when the barnase gene was replaced with the gene of interest by in vitro transposition. When bEasyBac was transposed with pDualBac-EGFP, the resulting recombinant virus, AcEasy-EGFP, showed comparable levels of EGFP expression efficiency to the plaque-purified recombinant virus AcEGFP, which was constructed using the bAcGOZA system. In addition, no non-recombinant backgrounds were detected in unpurified AcEasy-EGFP stocks. Based on these results, a high-throughput system for the generation of multiple recombinant viruses at a time was established.

A novel recombinant baculovirus, NeuroBactrus, was constructed to develop an improved baculovirus insecticide with additional beneficial properties, such as a higher insecticidal activity and improved recovery, compared to wild-type baculovirus. For the construction of the NeuroBactrus, the Bacillus thuringiensis cry1-5 crystal protein gene was introduced into the Autographa californica nucleopolyhedrovirus(AcMNPV) genome by fusion of polyhedrin-cry1-5-polyhedrin under the control of the polyhedrin promoter. In the opposite direction, an insect-specific neurotoxin gene, AaIT, from Androctonus australis was introduced under the control of an early promoter from Cotesia plutellae bracovirus by fusion of a partial fragment of orf603. The Polyhedrin-Cry1-5-Polyhedrin fusion protein expressed by the NeuroBactrus was not only occluded into the polyhedra, but it was also activated by treatment with trypsin, resulting in an approximately 65-kDa active toxin. In addition, qPCR revealed that the neurotoxin was expressed from the early phase of infection. The NeuroBactrus showed a high level of insecticidal activity against Plutella xylostella larvae and a significant reduction in the median lethal time(LT50) against Spodoptera exigua larvae compared to those of wild-type AcMNPV. Re-recombinant mutants derived from NeuroBactrus in which AaIT and/or cry1-5 were deleted were generated by serial passages in vitro. Expression of the foreign proteins(Bt toxin and AaIT) was continuously reduced during the serial passage of the NeuroBactrus. Moreover, polyhedra collected from S. exigua larvae infected with the serially passed NeuroBactrus showed insecticidal activity similar to that of wild-type AcMNPV. These results suggested that the NeuroBactrus could be recovered to wild-type AcMNPV through serial passaging.

The silkworm-baculovirus expression system has distinct advantages, such as a high yield and safe usage in vertebrates. Here, we report a novel strategy for the large-scale production of a classical swine fever virus (CSFV) envelope glycoprotein E2 in the larvae of a baculovirus-infected silkworm, Bombyx mori. We constructed a recombinant B. mori nucleopolyhedrovirus (BmNPV) that expressed recombinant polyhedra together with the N-terminal 179 amino acids of CSFV E2 (E2ΔC). BmNPV-E2ΔC-infected silkworm larvae expressed native polyhedrin and approximately 44-kDa fusion protein that was detected using both anti-polyhedrin and anti-CSFV E2 antibodies. Electron and confocal microscopy both demonstrated that the recombinant polyhedra contained both the fusion protein and native polyhedrin were morphologically normal and contained CSFV E2ΔC. The CSFV E2ΔC antigen produced in BmNPV-E2ΔC-infected silkworm larvae reached 0.68 mg per ml of hemolymph and 0.53 mg per larva at 6 days post-infection. Six-week-old female BALB/c mice that were immunized with the E2ΔC protein purified from solubilized recombinant polyhedraelicited CSFV E2 antibodies, which indicated that the CSFV E2ΔC protein from recombinant polyhedra was immunogenic. The virus neutralization test showed that the serum from mice that were treated with E2ΔC protein from recombinant polyhedra contained significant levels of virus neutralization activity. These results demonstrate that the present strategy can be used for the large-scale production of CSFV E2 antigen.

Polyhedrin is the major component of the nuclear viral occlusions produced during replication of the baculovirus Autographa californica multicapsid nuclear polyhedrosis virus (AcMNPV). To enhance the expression level of baculovirus vector system, we constructed several fusion vectors using various fragments of the polyhedrin. The polyhedrin fragments were genetically fused to the enhanced green fluorescent protein (eGFP) under the control of polyhedrin promoter, and their expressions were analyzed in Sf21 insect cells. Expression of the fusion protein was identified by SDS-PAGE and Western blot analysis using anti-GFP and anti-Polyhedrin. The expression level of eGFP was markedly increased by the fusion of partial polyhedrin. Also, the fluorescence intensity of fusion proteins was higher than that of non-fusion protein. Confocal laser scanning microscopy demonstrated that fusion proteins were localized to the cytosol or nucleus of insect cells. In additional, the glycoprotein E2 (gE2) of classical swine fever virus (CSFV) expressed by the these vectors was dramatically increased and its immunogenicity was proofed using experimental animal guinea pigs that were immunized with the partial polyhedrin containing gE2. This study provides a new option for the higher expression of useful foreign recombinant protein by using the partial polyhedrin in BEVS.

A novel recombinant baculovirus, NeuroBactrus, was constructed to develop an improved baculovirus insecticide with additional beneficial properties such as higher insecticidal activity and recovery to wild-type baculovirus. For this, Bacillus thuringiensis crystal protein gene (cry1-5) was introduced into Autographa californica nucleopolyhedrovirus (AcMNPV) genome by fusion of polyhedrincry1- 5-polyhedrin under the control of poyhedrin gene promoter. In the opposite direction of this fusion gene, an insect-specific neurotoxin gene (AaIT) under the control of early promoter from Cotesia plutellae bracovirus was introduced by fusion of orf603 partial fragment. Western hybridization and confocal microscopy revealed that AaIT neurotoxin and Polyhedrin-Cry1-5-Polyhedrin fusion protein expressed by the NeuroBactrus and that the fusion protein occluded into the polyhedra. In addition, the fusion protein was activated as about 65 kDa of crystal protein when treated with trypsin. The NeuroBactrus showed high level of insecticidal activity against Plutella xylostella larvae and significant reduction in median lethal time (LT50) against Spodoptera exigua larvae compared to those of wild-type AcMNPV. Re-recombinants derived from the NeuroBactrus, NBt-Del5 (deleted cry1-5), NBt-DelA (deleted AaIT) and NBt-Del5A (deleted cry1-5 and AaIT; wild-type baculovirus) were generated in serial passages in vitro and in vivo. These results suggested that the NeuroBactrus could be transferred to wild-type baculovirus along with serial passages by the homologous recombination between two polyhedrin genes and two partial orf603 fragments.

To develop an advanced baculovirus insecticide with additional advantages, such as higher toxicity and recovering to wild-type baculovirus, a novel recombinant baculovirus, NeuroBactrus was constructed. Bacillus thuringiensis crystal protein gene (cry1-5) and an insect-specific neurotoxin gene (AaIT) were introduced into Autographa californica nucleopolyhedrovirus genome by fusion of polyhedrin-cry1-5-polyhedrin under the control of poyhedrin gene promoter, and by fusion of orf603 partial genes and AaIT under the control of early promoter of ORF3006 from Cotesia plutellae bracovirus. About 150 kDa of Polyhedrin-Cry1-5-Polyhedrin fusion protein expressed by NeuroBactrus was occluded into the polyhedra, and activated as about 65 kDa of crystal protein when treated with trypsin. RT-PCR analysis indicated that transcription of AaIT gene occurs by 2 h postinfection (p.i.) and increased at 16 h p.i.. NeuroBactrus showed high toxicity against Plutella xylostella larvae and significant reduction in median lethal time (LT50) against Spodoptera exigua larvae compared to those of wild-type AcNPV. Re-recombinants derived from NeuroBactrus, NBt-Del5 (deleted cry1-5), NBt-DelA (deleted AaIT) and NBt-Del5A (deleted cry1-5 and AaIT; wild-type baculovirus) were generated in serial passages in vitro. This result showed that the NeuroBactrus could be transferred to wild-type baculovirus along with serial passages by the homologous recombination between two polyhedrin genes and two partial orf603 genes.

To develop an improved baculovirus insecticide with additional advantages, a novel recombinant baculovirus, AcB5B-AaIT was constructed. B. thuringiensis crystal protein gene (cry1-5) and insect-specific neurotoxin gene (AaIT) were introduced into Autographa californica nucleopolyhedrovirus genome by fusion of polyhedrin-cry1-5-polyhedrin under the control of polyhedrin (polh) gene promoter, and AaIT under the control of early promoter of ORF3004 from Cotesia plutellae bracovirus, respectively. About 150 kDa of Polyhedrin-Cry1-5-Polyhedrin fusion protein expressed by AcB5B-AaIT was occluded into the polyhedra produced by the recombinant virus, and activated as about 65 kDa of crystal protein when treated with gut-juice of Bombyx mori. The AcB5B-AaIT showed about 50% reduced LT50 value compared to that of the recombinant virus, Ap1Ac, expressing Cry1Ac against Plutella xylostella larvae. In addition, Spodoptera exigua larvae fed the recombinant polyhedra of AcB5B-AaIT showed about 4 fold higher refusing diet effect compared S. exigua larvae fed the recombinant polyhedra of the recombinant virus, Ap1C, expressing Cry1C. AcB5B-AaIT could be transferred to wild-type baculovirus along with serial passage by the homologous recombination between two polyhedrin genes contained in polh-cry1-5-polh fusion protein gene. These results suggested that the novel recombinant baculovirus, AcB5B-AaIT, could be applied as advanced viral insecticide.