Microneme-located VP2 in Eimeria acervulina elicits effective protective immunity against infectious bursal disease virus

Using transgenic Eimeria spp. to deliver exogenous antigens is a viable option for developing multivalent live vaccines. Previous research revealed that the location of antigen expression in recombinant Eimeria dictates the magnitude and type of immune responses. In this study, we constructed genetically modified Eimeria acervulina that expressed VP2 protein, a protective antigen from infectious bursal disease virus (IBDV), on the surface or in the microneme of sporozoites. After vaccination, VP2-specific antibody was readily detected in specific pathogen-free chickens receiving transgenic E. acervulina parasites expressing VP2 in microneme, but animals vaccinated with which expressing VP2 on surface failed to produce detectable antibody after two times immunizations. Moreover, the bursal lesion of microneme-located VP2 transgenic E. acervulina immunized chickens was less severe compared with un-immunized animals after IBDV challenge infection. Therefore, genetically modified E. acervulina that express IBDV-derived VP2 in micronemes are effective in inducing specific antibody responses against VP2, while parasites that have VP2 expression on cell surface are not suitable. Thus, the use of Eimeria parasites as vaccine vectors needs to consider the proper targeting of exogenous immunogens. Our results have implications for the design of other vector vaccines.

Protein kinase Cdc7 supports viral replication by phosphorylating Avibirnavirus VP3 protein

IMPORTANCE

The Avibirnavirus infectious bursal disease virus is still an important agent which largely threatens global poultry farming industry economics. VP3 is a multifunctional scaffold structural protein that is involved in virus morphogenesis and the regulation of diverse cellular signaling pathways. However, little is known about the roles of VP3 phosphorylation during the IBDV life cycle. In this study, we determined that IBDV infection induced the upregulation of Cdc7 expression and phosphorylated the VP3 Ser13 site to promote viral replication. Moreover, we confirmed that the negative charge addition of phosphoserine on VP3 at the S13 site was essential for IBDV proliferation. This study provides novel insight into the molecular mechanisms of VP3 phosphorylation-mediated regulation of IBDV replication.

In vitro assembly of chimeric virus-like particles composed of a porcine circovirus 2b capsid protein and a B-cell epitope of infectious bursal disease virus

OBJECTIVES

To develop a method for in vitro assembly of recombinant proteins expressed in E. coli into chimeric virus-like particles (cVLPs).

RESULTS

A fusion protein (Bepi-Cap-A) between capsid protein (Cap) of PCV2b and B cell epitope (Bepi) of IBDV was expressed in E. Coli, and purified. For assembling them into cVLPs (Bepi-Cap-VLP), the Bepi-Cap-A was suspended in buffer C [0.03% ("%" stands for "v/v" unless otherwise indicated) polyethylene glycol, 0.4 M Tris, 10 mM β-mercaptoethanol, 5% glycerol, 0.02% (w/v) gellan gum, 0.1 M glycine, 0.03% Tween 80, 500 mM NaCl], and incubated. After centrifugation, the pellet was resuspended in buffer D [50 mM Na₂HPO₄, 50 mM NaH₂PO₄, 0.01% (w/v) gellan gum, 0.05 mM EDTA, 500 mM NaCl, 0.03% Tween 80, pH 6.5], and then dialyzed against dialysis buffer (50 mM Na₂HPO₄, 50 mM NaH₂PO₄, 500 mM NaCl, 0.03% Tween 80, pH 6.5). The procedure resulted in typical and immunogenic Bepi-Cap-VLP.

CONCLUSIONS

The data provide a method which is feasible for in vitro assembly of recombinant proteins into chimeric virus-like particles.

Avibirnavirus VP4 Protein Is a Phosphoprotein and Partially Contributes to the Cleavage of Intermediate Precursor VP4-VP3 Polyprotein

Birnavirus-encoded viral protein 4 (VP4) utilizes a Ser/Lys catalytic dyad mechanism to process polyprotein. Here three phosphorylated amino acid residues Ser538, Tyr611 and Thr674 within the VP4 protein of the infectious bursal disease virus (IBDV), a member of the genus Avibirnavirus of the family Birnaviridae, were identified by mass spectrometry. Anti-VP4 monoclonal antibodies finely mapping to phosphorylated (p)Ser538 and the epitope motif ⁵³⁰PVVDGIL⁵³⁶ were generated and verified. Proteomic analysis showed that in IBDV-infected cells the VP4 was distributed mainly in the cytoskeletal fraction and existed with different isoelectric points and several phosphorylation modifications. Phosphorylation of VP4 did not influence the aggregation of VP4 molecules. The proteolytic activity analysis verified that the pTyr611 and pThr674 sites within VP4 are involved in the cleavage of viral intermediate precursor VP4-VP3. This study demonstrates that IBDV-encoded VP4 protein is a unique phosphoprotein and that phosphorylation of Tyr611 and Thr674 of VP4 affects its serine-protease activity.

Infectious bursal disease virus VP5 polypeptide: a phosphoinositide-binding protein required for efficient cell-to-cell virus dissemination

Infectious bursal disease virus (IBDV), a member of the Birnaviridae family, is a major avian pathogen responsible for an immunosuppressive disease affecting juvenile chickens. The IBDV genome is formed by two dsRNA segments. The largest one harbors two partially overlapping open reading frames encoding a non-structural polypeptide, known as VP5, and a large polyprotein, respectively. VP5 is non-essential for virus replication. However, it plays a major role in IBDV pathogenesis. VP5 accumulates at the plasma membrane (PM) of IBDV-infected cells. We have analyzed the mechanism underlying the VP5 PM targeting. Updated topological prediction algorithm servers fail to identify a transmembrane domain within the VP5 sequence. However, the VP5 polycationic C-terminal region, harboring three closely spaced patches formed by two or three consecutive basic amino acid residues (lysine or arginine), might account for its PM tropism. We have found that mutations, either C-terminal VP5 deletions or replacement of basic amino acids by alanine residues, that reduce the electropositive charge of the VP5 C-terminus abolish PM targeting. Lipid overlay assays performed with an affinity-purified Flag-tagged VP5 (FVP5) protein version show that this polypeptide binds several phosphoinositides (PIP), exhibiting a clear preference for monophosphate species. Experiments performed with FVP5 mutant proteins lacking the polycationic domain demonstrate that this region is essential for PIP binding. Data gathered with IBDV mutants expressing C-terminal deleted VP5 polypeptides generated by reverse genetics demonstrate that the VP5-PIP binding domain is required both for its PM targeting in infected cells, and for efficient virus dissemination. Data presented here lead us to hypothesize that IBDV might use a non-lytic VP5-dependent cell-to-cell spreading mechanism.

Spatiotemporal Phylogenetic Analysis and Molecular Characterisation of Infectious Bursal Disease Viruses Based on the VP2 Hyper-Variable Region

Background

Infectious bursal disease is a highly contagious and acute viral disease caused by the infectious bursal disease virus (IBDV); it affects all major poultry producing areas of the world. The current study was designed to rigorously measure the global phylogeographic dynamics of IBDV strains to gain insight into viral population expansion as well as the emergence, spread and pattern of the geographical structure of very virulent IBDV (vvIBDV) strains.

Methodology/Principal Findings

Sequences of the hyper-variable region of the VP2 (HVR-VP2) gene from IBDV strains isolated from diverse geographic locations were obtained from the GenBank database; Cuban sequences were obtained in the current work. All sequences were analysed by Bayesian phylogeographic analysis, implemented in the Bayesian Evolutionary Analysis Sampling Trees (BEAST), Bayesian Tip-association Significance testing (BaTS) and Spatial Phylogenetic Reconstruction of Evolutionary Dynamics (SPREAD) software packages. Selection pressure on the HVR-VP2 was also assessed. The phylogeographic association-trait analysis showed that viruses sampled from individual countries tend to cluster together, suggesting a geographic pattern for IBDV strains. Spatial analysis from this study revealed that strains carrying sequences that were linked to increased virulence of IBDV appeared in Iran in 1981 and spread to Western Europe (Belgium) in 1987, Africa (Egypt) around 1990, East Asia (China and Japan) in 1993, the Caribbean Region (Cuba) by 1995 and South America (Brazil) around 2000. Selection pressure analysis showed that several codons in the HVR-VP2 region were under purifying selection.

Conclusions/Significance

To our knowledge, this work is the first study applying the Bayesian phylogeographic reconstruction approach to analyse the emergence and spread of vvIBDV strains worldwide.

[Characterization the immunogenicity of recombinant VP2 of infectious bursal disease virus containing N-terminal M2e of avian influenza virus]

OBJECTIVE

We developed subunit vaccines against H5 or H9 subtype avian influenza viruses (AIV) and infectious bursal disease viruses (IBDV). Viral protein 2 (VP2) of IBDV was used as cargo protein to display a 12-amino-acid (aa) immunodominant epitope derived from N-terminal M2 extracelluar domain (nM2e) of H5 or H9 subtype AIV.

METHODS

The aa and nucleotide sequence of nM2e was determined by comparing the available avian influenza vaccine strains and alignment the AIV sequence available in GenBank. One copy of H5 or H9 nM2e was inserted into P(BC) region of VP2 origin from IBDV B87 vaccine strain by fusion polymerase chain reaction. The VP2(BC)nM2e recombinants were cloned into Bac-to-Bac expression system and transfected to Sf9 cell. The expressed chimeric protein was characterized by indirect immunofluorescence assay and Western blotting, and subsequently was used as antigen to develop vaccine. The non-immunized chicken was given two injections with the vaccine at a 4-week interval. Serum against VP2 and nM2e was tested by indirect ELISA and virus neutralization in chick embryo fibroblast.

RESULTS

Both VP2(BC)nM2e recombinants were successfully constructed and expressed in Sf9 cell. Both chimeric proteins elicited antibody against VP2 and nM2e. The antibody level elicited by VP2(BC)nM2e(H5) vaccine was higher than that of VP2(BC)nM2e(H9).

CONCLUSION

Both chimeric proteins were immunigenic, and the efficacy of VP2(BC)nM2e(H5) was higher than VP2(BC)nM2e(H9) chicken.

Small interfering RNAs inhibit infectious bursal disease virus replication in Vero cells

Small interfering RNA (siRNA) molecules are considered to be a promising antiviral therapeutics. This study was performed to analyze the application of siRNA against infectious bursal disease virus (IBDV) replication. Two siRNAs were designed to target common coding sequences of four IBDV proteins. Corresponding vectors were constructed to express anti-IBDV short hairpin RNAs (shRNA) that were tested for their antiviral effect in Vero cells. The results showed that expressed shRNA inhibited the virus replication to a significant extent (92%) as determined by the virus titration in cell culture. This outcome demonstrated the effectiveness of RNA interference (RNAi) based mechanism against the IBDV in vitro.

[The expression of IBDV VP2 in chicken primary myoblast cells using the baculovirus vector]

OBJECTIVE

To construct the recombinant baculovirus expressing Infectious bursal disease (IBDV) VP2 gene in the chicken primary myoblast cells.

METHODS

A proteinase K digestion and phenol-chloroform extraction method was used to extract dsRNA genome from IBDV. VP2 gene was amplified by Reverse Transcription Polymerase Chain Reaction (RT-PCR) with the genome RNA as template. The pFastBac-pCMV-VP2 baculovirus transfer vector was constructed by inserting VP2 gene under the immediate-early promoter of cytomegalovirus. The VP2 recombinant bacmid was obtained by Bac-to-Bac system and transfected sf9 insect cell to acquire VP2 recombinant baculovirus. After amplification of recombinant baculovirus on cell passages, the recombinant virus was seeded on chicken primary myoblast cells with 50 multiplicity of infection (MOI), and the cells were harvested at 72 hours after infection.

RESULTS

Sodium Dodecyl Sulphate Poly-Acrylamide Gel Electrophoresis (SDS-PAGE) and Western blot results showed that the VP2 gene was successfully expressed in chicken primary myoblast cells. The product was a 48kDa protein and could be recognized by anti-IBDV serum.

CONCLUSION

The recombinant baculovirus could efficiently delivery IBDV VP2 gene into chicken primary cells and that CMV, a mammalian-cell-active promoter, was functional in chicken primary cells and could direct the expression of VP2 antigen protein. The research can be a potential basis for the development of baculovirus vector vaccines for IBDV and other avian infectious disease.

The capsid protein of infectious bursal disease virus contains a functional alpha 4 beta 1 integrin ligand motif

Infectious bursal disease virus (IBDV), a member of the dsRNA Birnaviridae family, is an important immunosuppressive avian pathogen. We have identified a strictly conserved amino acid triplet matching the consensus sequence used by fibronectin to bind the alpha 4 beta 1 integrin within the protruding domain of the IBDV capsid polypeptide. We show that a single point mutation on this triplet abolishes the cell-binding activity of IBDV-derived subviral particles (SVP), and abrogates the recovering of infectious IBDV by reverse genetics without affecting the overall SVP architecture. Additionally, we demonstrate that the presence of the alpha 4 beta 1 heterodimer is a critical determinant for the susceptibility of murine BALB/c 3T3 cells to IBDV binding and infectivity. Our data suggests that the IBDV might also use the alpha 4 beta 1 integrin as a specific binding receptor in avian cells.

Strong and heterogeneous adsorption of infectious bursal disease VP2 subviral particle with immobilized metal ions dependent on two surface histidine residues

VP2, the single outer protein of infectious bursal disease virus capsid, can self-assemble into T = 1 subviral particle (SVP), which can be efficiently purified by immobilized metal ion affinity chromatography (IMAC). In this study, a systemic investigation of the adsorption behavior of VP2 SVP on Ni-NTA resin was performed to identify that His253 and His249 on the surface of SVP are the key factors accounted for the strong and heterogeneous interaction. First, an untagged VP2-441 SVP was constructed, expressed, and purified by IMAC to demonstrate that SVP can interact with immobilized Ni2+ ions on NTA resin without an inserted His tag. Second, equilibrium adsorption studies were used to demonstrate that SVP has a higher affinity to the immobilized Ni2+ ions than a model protein, bovine serum albumin, although the maximum amount of SVP bound per volume resin is limited by the pore size of the resin as verified by confocal microscopic analysis. Third, based on structural analysis and computer modeling, His253 and His249 on the surface of SVP are responsible for a strong heterogeneous and multiple adsorption with the immobilized Ni2+ ions; and this was confirmed by a point-mutation experiment. This is the first example to elucidate the interaction between the immobilized metal ions and viral particles at molecular level. A detailed understanding of SVP-immobilized metal ion interactions can provide useful strategies for engineering icosahedral protein nanoparticles to achieve a simple and one-step purification by IMAC.

Oral immunization with transgenic rice seeds expressing VP2 protein of infectious bursal disease virus induces protective immune responses in chickens

The expression of infectious bursal disease virus (IBDV) host-protective immunogen VP2 protein in rice seeds, its immunogenicity and protective capability in chickens were investigated. The VP2 cDNA of IBDV strain ZJ2000 was cloned downstream of the Gt1 promoter of the rice glutelin GluA-2 gene in the binary expression vector, pCambia1301-Gt1. Agrobacterium tumefaciens containing the recombinant vector was used to transform rice embryogenic calli, and 121 transgenic lines were obtained and grown to maturity in a greenhouse. The expression level of VP2 protein in transgenic rice seeds varied from 0.678% to 4.521% microg/mg of the total soluble seed protein. Specific pathogen-free chickens orally vaccinated with transgenic rice seeds expressing VP2 protein produced neutralizing antibodies against IBDV and were protected when challenged with a highly virulent IBDV strain, BC6/85. These results demonstrate that transgenic rice seeds expressing IBDV VP2 can be used as an effective, safe and inexpensive vaccine against IBDV.

[Identification of VP3 antigenic epitopes of infectious bursal disease virus]

Infectious bursal disease virus(IBD) causes infectious bursal disease (IBD), which infects bursal of chicken and can evoke immune suppression. This study identified the antigenic epitopes of four McAbs to IBDV VP3(HRB-3F, HRB-7B, HRB-7C and HRB-10E)with pepscan. A set of 17 partially overlapping or consecutive peptides (P1-P17) spanning VP3 were expressed for epitope screening by pepscan. Finally, two antigenic epitopes, 109-119aa and 177-190aa of IBDV VP3, were identified by Western blot and ELISA. The peptides on epitopes could react with IBDV, and they had better immunnogenicity. The sequences of epitopes were compared with that of several other IBDV strains in the same region, and was found they were totally homologous. This study showed the two epitopes were novel conserved linear B cell epitopes on the VP3 of IBDV. This study provides basis for the development of immunity-based prophylactic, therapeutic and diagnostic measures for control of IBD and further for structural and functional analysis of IBDV.

Infectious bursal disease virus capsid assembly and maturation by structural rearrangements of a transient molecular switch

Infectious bursal disease virus (IBDV), a double-stranded RNA (dsRNA) virus belonging to the Birnaviridae family, is an economically important avian pathogen. The IBDV capsid is based on a single-shelled T=13 lattice, and the only structural subunits are VP2 trimers. During capsid assembly, VP2 is synthesized as a protein precursor, called pVP2, whose 71-residue C-terminal end is proteolytically processed. The conformational flexibility of pVP2 is due to an amphipathic alpha-helix located at its C-terminal end. VP3, the other IBDV major structural protein that accomplishes numerous roles during the viral cycle, acts as a scaffolding protein required for assembly control. Here we address the molecular mechanism that defines the multimeric state of the capsid protein as hexamers or pentamers. We used a combination of three-dimensional cryo-electron microscopy maps at or close to subnanometer resolution with atomic models. Our studies suggest that the key polypeptide element, the C-terminal amphipathic alpha-helix, which acts as a transient conformational switch, is bound to the flexible VP2 C-terminal end. In addition, capsid protein oligomerization is also controlled by the progressive trimming of its C-terminal domain. The coordination of these molecular events correlates viral capsid assembly with different conformations of the amphipathic alpha-helix in the precursor capsid, as a five-alpha-helix bundle at the pentamers or an open star-like conformation at the hexamers. These results, reminiscent of the assembly pathway of positive single-stranded RNA viruses, such as nodavirus and tetravirus, add new insights into the evolutionary relationships of dsRNA viruses.

An improved method for infectious bursal disease virus rescue using RNA polymerase II system

Reverse genetics system is an excellent platform to research the construction and function of viruses. Genome modification, such as gene recombination, mosaicism, and mutation may interfere with replication, assembly and release of viruses. An efficient, convenient and economical method of virus rescue is undoubtedly required for elevating the efficiency of rescuing crippled virus. In this study, we developed a method to rescue infectious bursal disease virus (IBDV) using RNA polymerase II. The genome of IBDV Gt strain, flanked by hammerhead ribozyme and hepatitis delta ribozyme sequences, were cloned downstream of the cytomegalovirus enhancer and the beta chicken actin promoter of the vector pCAGGS. Through direct transfection in various cell lines, IBDV could be rescued efficiently. The RNA polymerase II-based reverse genetics system is efficient, stable, convenient, and fit to various cells. The system not only provides the basis of the gene function research of IBDV, but is also useful for reverse genetics research of other birnaviridae viruses.

Processing of infectious bursal disease virus (IBDV) polyprotein and self-assembly of IBDV-like particles in Hi-5 cells

The capsid of infectious bursal disease virus (IBDV), with a size of 60-65 nm, is formed by an initial processing of polyprotein (pVP2-VP4-VP3) by VP4, subsequent assemblage of pVP2 and VP3, and the maturation of VP2. In Sf9 cells, the processing of polyprotein expressed was restrained in the stage of VP2 maturation, leading to a limited production of capsid, i.e., IBDV-like particles (VLPs). In the present study, another insect cell line, High-Five (Hi-5) cells, was demonstrated to efficiently produce VLPs. Meanwhile, in this system, polyprotein was processed to pVP2 and VP3 protein and pVP2 was further processed to the matured form of VP2. Consequently, Hi-5 cells are better in terms of polyprotein processing and formation of VLPs than Sf9. In addition to the processing of pVP2, VP3 was also degraded. With insufficient intact VP3 protein present for the formation of VLPs, the excessive VP2 form subviral particles (SVPs) with a size of about 25 nm. The ratio of VLPs to SVPs is dependent on the multiplicity of infections (MOIs) used, and an optimal MOI is found for the production of both particles. VLPs were separated from SVPs with a combination of ultracentrifugation and gel-filtration chromatography, and a large number of purified particles of both were obtained. In conclusion, the insect cell lines and MOIs were optimized for the production of VLPs, and pure VLPs with morphology similar to that of the wild-type viruses can be effectively prepared. The efficient production and purification of VLPs benefits not only the development of an antiviral vaccine against IBDV but also the understanding of the structure of this avian virus that is economically important.

Real-time RT-PCR analysis of two epitope regions encoded by the VP2 gene of infectious bursal disease viruses

Infectious bursal disease virus (IBDV) causes an immunosuppressive disease in chickens and leads to severe economic losses in the poultry industry. Vaccination may not be effective if there is exposure of the vaccinated flock to a different antigenic subtype, which reinforces the importance of identification of new IBDV variants. The virus outer capsid is constituted of VP2, in which the major neutralizing epitopes are located. Forty-eight bursa samples collected from IBDV infected commercial broiler flocks in the US were analyzed by real-time RT-PCR using probes designed for two epitope regions of VP2 denominated minor peak 1 and peak B. It was observed that 23, 48 and 44 samples tested with the minor peak probes Del-E, STC and F15, respectively, had a lower melting temperature (Tm) than expected. Furthermore, 44, 41 and 48 samples tested with the Del-E, STC and F15 peak B probes, respectively, had a lower Tm compared to the control, which indicates the presence of one or more nucleotide mutations in the samples. This fact was confirmed by nucleotide sequencing which also demonstrated that most mutations resulted in amino acid substitutions. Real-time RT-PCR can be a useful tool to assist in the development of more effective vaccination strategies.

Characterization of particles formed by the precursor protein VPX of infectious bursal disease virus in insect Hi-5 cells: implication on its proteolytic processing

The precursor (VPX) of host immunogen VP2 protein for infectious bursal disease virus (IBDV) was expressed in insect Sf9 and Hi-5 cells, and the types of particles generated as well as the immunogenicity induced by these particles were examined. Recombinant VPXH (rVPXH) protein, expressed in Hi-5 cells at an expression level 4x higher than in Sf9 cells, was efficiently processed by proteases to yield VP2-like proteins with corresponding molecular weight, a phenomenon not observed previously. At least three structures of particles were observed for VPXH and VP2-like proteins purified by immobilized metal-ion affinity chromatography (MAC). In addition to the two previously identified twisted tubular and isometric particle structures, there was a new one: icosahedral particles of approximately 25 nm in diameter. The purified particles were further separated by gel-filtration chromatography (GFC) linking with HPLC, which was able to resolve the isometric from icosahedral particles better than ultracentrifugation. Chromatographic results indicate that rVPXH protein mainly involved in the formation of the isometric particle structure and occasionally twisted tubular structure, and the icosahedral particles were formed by the degraded products of rVPXH (VP2-like proteins). Thus, by combining IMAC and GFC, it was shown that VPX was processed efficiently to yield VP2-like protein that could form small virus-like particles in Hi-5 cells. Finally, we demonstrated that virus-neutralizing antibodies were induced when susceptible chickens were vaccinated with the IMAC-purified rVPXH protein (40 microg per bird). This indicates that these particles are highly immunogenic and might serve as an alternative vaccine candidate for the development of IBDV subunit vaccine.

Assessment of genetic, antigenic and pathotypic criteria for the characterization of IBDV strains

The aim of this work was the selection and comparison of representative infectious bursal disease virus (IBDV) strains. Nine strains of IBDV, isolated at different times and from different geographic regions of Europe and China, were characterized. Batches of all strains were prepared following standardized protocols and checked for the absence of contaminating viruses. Criteria used for their characterization were: (i) the nucleotide sequence of the VP2 variable region, (ii) binding to a panel of neutralizing monoclonal antibodies in antigen capture enzyme-linked immunosorbent assays, and (iii) virulence in specific pathogen free chickens after infection with a standardized number of median embryo infective doses. Based on the first two criteria, two of nine strains were classified as classical virulent (cv) IBDV (F52/70, Cu-1wt), and five as very virulent (vv) IBDV (849VB, 96108, HK46, GX, Harbin). Remarkably, although a clear-cut difference was demonstrable between European cvIBDV (F52/70 and Cu-1wt) and vvIBDV (849VB and 96108) strains, there was a continuum in the pathogenicity of Chinese vvIBDVs. Our results indicate the probable existence of differences in virulence within IBDV lineages determined on the basis of antigenic typing using monoclonal antibodies and the alignment of the VP2 sequences. This indicates limitations in the analysis of IBDV pathotypes based on the VP2 variable region and emphasizes that these criteria may not be sufficient for the classification of IBDV strains.

Early and transient induction of nitric oxide (NO) in infectious bursal disease virus infection is T-cell dependent: a study in cyclosporin-A treated chicken-model

The level of nitric oxide (NO) in the supernatants of mitogen (PHA) stimulated lymphocyte cultures from infectious bursal disease (IBD) virus infected T-cell suppressed and immune competent chickens was monitored. The immune competent chickens when infected with IBD virus showed 4-6 folds increased levels of NO as compared to uninfected chickens. The levels of NO in T-cell suppressed chickens were comparable to uninfected control chickens, in spite of markedly increased hemorrhage suggesting that the muscular hemorrhage observed in IBD in not solely and directly related with NO production. The immune suppressed chickens that did not induce NO production after IBD virus infection showed more severe lesions and supported enhanced virus replication. Taken together it may be suggested that NO production after IBD virus infection, may exert antiviral effect since the immune-suppressed chickens that failed to induce NO showed more severe disease and higher magnitude of virus replication, but does not seem to correlate with the hemorrhagic lesions which in fact may be as a result of the net outcome of various host-factors and the determinants responsible for virus virulence and virus clearance.

Infectious bursal disease virus polyprotein expression arrests growth and mitogenic stimulation of B lymphocytes

Infectious bursal disease virus (IBDV) causes lymphocytolysis and immunosuppression in infected poultry. The IBDV genome encodes a polyprotein VP243 that is post-translationally cleaved by the VP4 protease into the two structural proteins pVP2 and VP3. The objective of the present study was to determine if IBDV polyprotein induced suppression of bursal B lymphocyte growth and their capacity for proliferation. Bursal B cells were examined both for chickens infected with IBDV and for chickens orally inoculated with a DNA construct expressing IBDV VP243 polyprotein. Bursae were collected at 0, 12, 24 and 48 hours after inoculation. Proliferation of bursal B cells (purified AvBu1(+) cells) in response to concanavalin A mitogenic stimulation was significantly suppressed by infection at 1 day old with either the classical STC or variant E strains of IBDV. Oral administration of DNA constructs expressing the IBDV VP243 polyprotein from either the classical STC or variant E strains in the pCR3.1 vector resulted in persistent, moderate levels of construct in the bursa until at least 48 hours after inoculation. The VP243 DNA construct similarly induced suppression of proliferation for bursal lymphocytes independently of the virus infection. Expression of VP243 polyprotein in transiently transfected DT40 B lymphocyte culture also suppressed cell growth and proliferative responses to mitogen stimulation. Polyprotein expression did not affect cell viability and suppression of proliferation probably occurred by means of cell cycle arrest. The expression of the mature viral proteins VP2, VP4 or VP3 did not change the rate of cell proliferation or response of B cell cultures to mitogen. The results suggested that IBDV polyprotein is a mediator of immunosuppression.

[Expression of the infectious bursal disease virus polyprotein in Vero cells using attenuated Salmonella typhimurium as transgenic carrier]

To examine if polyprotein gene (VP2/VP4/VP3) of Infectious Bursal Disease Virus (IBDV) could be delivered into mammalian cells and expressed using attenuated Salmonella typhimurium as vector. The IBDV polyprotein gene was amplified by RT-PCR and inserted in to pCI, an eukaryotic expression plasmid. The resulting recombinant pCI-VP2/VP4/VP3 was transformed by electroporation into attenuated Salmonella typhimurium strain ZJ111 (dam- and phoP-), which was then use to transfect the Vero cells. Gene specific RT-PCR revealed that VP2/VP4/VP3 was transcribed into mRNA in the Vero cells. Indirect immunofluorscence assay, SDS-PAGE and Western-blot analysis showed that VP2/VP4/VP3 was expressed and the product was immuno-reactive with anti-IBDV serum. This work provides essential precondition for developing a new oral DNA vaccine against IBDV.

The C-terminal domain of the pVP2 precursor is essential for the interaction between VP2 and VP3, the capsid polypeptides of infectious bursal disease virus

The interaction between the infectious bursal disease virus (IBDV) capsid proteins VP2 and VP3 has been analyzed in vivo using baculovirus expression vectors. Data presented here demonstrate that the 71-amino acid C-terminal-specific domain of pVP2, the VP2 precursor, is essential for the establishment of the VP2-VP3 interaction. Additionally, we show that coexpression of the pVP2 and VP3 polypeptides from independent genes results in the assembly of virus-like particles (VLPs). This observation demonstrates that these two polypeptides contain the minimal information required for capsid assembly, and that this process does not require the presence of the precursor polyprotein.

Expression of VP2 gene protein of infectious bursal disease virus detected in Korea

The VP2 gene DNA (1.4 kb in approximate) of a very virulent infectious bursal disease virus (vvIBDV) Chinju strain detected in Chinju, Korea was cloned into the bacmid, a baculovirus shuttle vector, through transposition of the gene from initially cloned pFastBacHTa plasmid, a baculovirus expression vector, and was subsequently expressed in Spodoptera frugiperda (Sf) cells. Biological properties of the expressed VP2 subunit protein were characterized to aid in the development of genetically engineered diagnostic reagents and vaccines against the vvIVDV. When the VP2 DNA-recombinant bacmid was transfected and propagated in the Sf cells, the cells showed no occlusion formation, which is a positive evidence for the insertion of the VP2 DNA into the polyhedrin gene of the bacmid, whereas the occlusions were observed in the cells infected by the Autographa californica nuclear polyhedrosis virus, a wild baculovirus. The expression of VP2 DNA was identified by strong positive reaction in fluorescent antibody test using chicken anti-IBDV serum. The VP2 protein was determined as a polypeptide band with Mr of 48 kDa by the sodium dodecyl-polyacrylamide gel electrophoresis for the lysate of the Sf cells infected with the recombinant bacmid. The VP2 protein was successfully purified from the cell lysate by Ni-NTA affinity chromatography. The expressed VP2 subunit protein reacted specifically with chicken anti-IBDV serum in Western blotting.

Homotypic interactions of the infectious bursal disease virus proteins VP3, pVP2, VP4, and VP5: mapping of the interacting domains

Infectious bursal disease virus (IBDV), a nonenveloped double-stranded RNA virus of chicken, encodes five proteins. Of these, the RNA-dependent RNA polymerase (VP1) is specified by the smaller genome segment, while the large segment directs synthesis of a nonstructural protein (VP5) and a structural protein precursor from which the capsid proteins pVP2 and VP3 as well as the viral protease VP4 are derived. Using the recently redefined processing sites of the precursor, we have reevaluated the homotypic interactions of the viral proteins using the yeast two-hybrid system. Except for VP1, which interacted weakly, all proteins appeared to self-associate strongly. Using a deletion mutagenesis approach, we subsequently mapped the interacting domains in these polypeptides, where possible confirming the observations made in the two-hybrid system by performing coimmunoprecipitation analyses of tagged protein constructs coexpressed in avian culture cells. The results revealed that pVP2 possesses multiple interaction domains, consistent with available structural information about this external capsid protein. VP3-VP3 interactions were mapped to the amino-terminal part of the polypeptide. Interestingly, this domain is distinct from two other interaction domains occurring in this internal capsid protein: while binding to VP1 has been mapped to the carboxy-terminal end of the protein, interaction with the genomic dsRNA segments has been suggested to occur just upstream thereof. No interaction sites could be assigned to the VP4 protein; any deletion applied abolished its self-association. Finally, one interaction domain was detected in the central, most hydrophobic region of VP5, supporting the idea that this virulence determinant may function as a membrane pore-forming protein in infected cells.

The oligomerization domain of VP3, the scaffolding protein of infectious bursal disease virus, plays a critical role in capsid assembly

Infectious bursal disease virus (IBDV) capsids are formed by a single protein layer containing three polypeptides, pVP2, VP2, and VP3. Here, we show that the VP3 protein synthesized in insect cells, either after expression of the complete polyprotein or from a VP3 gene construct, is proteolytically degraded, leading to the accumulation of product lacking the 13 C-terminal residues. This finding led to identification of the VP3 oligomerization domain within a 24-amino-acid stretch near the C-terminal end of the polypeptide, partially overlapping the VP1 binding domain. Inactivation of the VP3 oligomerization domain, by either proteolysis or deletion of the polyprotein gene, abolishes viruslike particle formation. Formation of VP3-VP1 complexes in cells infected with a dual recombinant baculovirus simultaneously expressing the polyprotein and VP1 prevented VP3 proteolysis and led to efficient virus-like particle formation in insect cells.

Identification and molecular characterization of the RNA polymerase-binding motif of infectious bursal disease virus inner capsid protein VP3

Infectious bursal disease virus (IBDV), a member of the Birnaviridae family, is the causative agent of one of the most important infectious poultry diseases. Major aspects of the molecular biology of IBDV, such as assembly and replication, are as yet poorly understood. We have previously shown that encapsidation of the putative virus-encoded RNA-dependent RNA polymerase VP1 is mediated by its interaction with the inner capsid protein VP3. Here, we report the characterization of the VP1-VP3 interaction. RNase A treatment of VP1- and VP3-containing extracts does not affect the formation of VP1-VP3 complexes, indicating that formation of the complex requires the establishment of protein-protein interactions. The use of a set of VP3 deletion mutants allowed the mapping of the VP1 binding motif of VP3 within a highly charged 16-amino-acid stretch on the C terminus of VP3. This region of VP3 is sufficient to confer VP1 binding activity when fused to an unrelated protein. Furthermore, a peptide corresponding to the VP1 binding region of VP3 specifically inhibits the formation of VP1-VP3 complexes. The presence of Trojan peptides containing the VP1 binding motif in IBDV-infected cells specifically reduces infective virus production, thus showing that formation of VP1-VP3 complexes plays a critical role in IBDV replication.

Characterization of the RNA-binding activity of VP3, a major structural protein of Infectious bursal disease virus

Infectious bursal disease virus (IBDV) is the agent of an immune-depressive disease affecting the poultry industry worldwide. Infection of IBDV leads to expression of five mature virus-encoded proteins. Proteolytic processing of the virus-encoded polyprotein generates VP3 which coats the inner surface of the IBDV capsid. In this report, we describe the characterization of the RNA-binding activity of VP3. For these studies, the VP3 coding region was fused to a histidine tag and expressed in insect cells using a recombinant baculovirus. The histidine-tagged VP3 was affinity-purified and used to study its ability to bind RNA molecules using three complementary methods: (i) Northwestern blotting; (ii) binding of VP3 protein-RNA complexes to nitrocellulose membranes; and (iii) electrophoretic mobility shift assays. The results demonstrated that VP3 efficiently bound ssRNA and dsRNA. Under the experimental conditions used in this study, the formation of VP3-RNA complexes did not depend upon the presence of specific RNA sequences. A series of histidine-tagged VP3 deletion mutants spanning the whole VP3 coding region were generated. The use of these mutants revealed that the VP3 RNA-binding domain layed in a highly conserved 69 aa stretch close to the N-terminus of the protein.

Infectious bursal disease virus capsid protein VP3 interacts both with VP1, the RNA-dependent RNA polymerase, and with viral double-stranded RNA

Infectious bursal disease virus (IBDV) is a double-stranded RNA (dsRNA) virus of the Birnaviridae family. Its two genome segments are encapsidated together with multiple copies of the viral RNA-dependent RNA polymerase, VP1, in a single-shell capsid that is composed of VP2 and VP3. In this study we identified the domains responsible for the interaction between VP3 and VP1. Using the yeast two-hybrid system we found that VP1 binds to VP3 through an internal domain, while VP3 interacts with VP1 solely by its carboxy-terminal 10 amino acids. These results were confirmed by using a reverse-genetics system that allowed us to analyze the interaction of carboxy-terminally truncated VP3 molecules with VP1 in infected cells. Coimmunoprecipitations with VP1- and VP3-specific antibodies revealed that the interaction is extremely sensitive to truncation of VP3. The mere deletion of the C-terminal residue reduced coprecipitation almost completely and also fully abolished production of infectious virions. Surprisingly, these experiments additionally revealed that VP3 also binds to RNA. RNase treatments and reverse transcription-PCR analyses of the immunoprecipitates demonstrated that VP3 interacts with dsRNA of both viral genome segments. This interaction is not mediated by the carboxy-terminal domain of VP3 since C-terminal truncations of 1, 5, or 10 residues did not prevent formation of the VP3-dsRNA complexes. VP3 seems to be the key organizer of birnavirus structure, as it maintains critical interactions with all components of the viral particle: itself, VP2, VP1, and the two genomic dsRNAs.

The capsid of infectious bursal disease virus contains several small peptides arising from the maturation process of pVP2

The capsid proteins VP2 and VP3 of infectious bursal disease virus, a birnavirus, are derived from the processing of a large polyprotein: NH2-pVP2-VP4-VP3-COOH. Although the primary cleavage sites at the pVP2-VP4 and VP4-VP3 junctions have been identified, the proteolytic cascade involved in the processing of this polyprotein is not yet fully understood, particularly the maturation of pVP2. By using different approaches, we showed that the processing of pVP2 (residues 1 to 512) generated VP2 and four small peptides (residues 442 to 487, 488 to 494, 495 to 501, and 502 to 512). We also showed that in addition to VP2, at least three of these peptides (residues 442 to 487, 488 to 494, and 502 to 512) were associated with the viral particles. The importance of the small peptides in the virus cycle was assessed by reverse genetics. Our results showed that the mutants lacking the two smaller peptides were viable, although the virus growth was affected. In contrast, deletions of the domain 442 to 487 or 502 to 512 did not allow virus recovery. Several amino acids of the peptide 502 to 512 appeared essential for virus viability. Substitutions of the P1 and/or P1" position were engineered at each of the cleavage sites (P1-P1": 441-442, 487-488, 494-495, 501-502, and 512-513). Most substitutions at the pVP2-VP4 junction (512-513) and at the final VP2 maturation cleavage site (441-442) were lethal. Mutations of intermediate cleavage sites (487-488, 494-495, and 501-502) led to viable viruses showing different but efficient pVP2 processing. Our data suggested that while peptides 488 to 494 and 495 to 501 play an accessory role, peptides 442 to 487 and 502 to 512 have an unknown but important function within the virus cycle.

The maturation process of pVP2 requires assembly of infectious bursal disease virus capsids

Infectious bursal disease virus (IBDV) is a nonenveloped avian virus with a two-segment double-stranded RNA genome. Its T=13 icosahedral capsid is most probably assembled with 780 subunits of VP2 and 600 copies of VP3 and has a diameter of about 60 nm. VP1, the RNA-dependent RNA polymerase, resides inside the viral particle. Using a baculovirus expression system, we first observed that expression of the pVP2-VP4-VP3 polyprotein encoded by the genomic segment IBDA results mainly in the formation of tubules with a diameter of about 50 nm and composed of pVP2, the precursor of VP2. Very few virus-like particles (VLPs) and VP4 tubules with a diameter of about 25 nm were also identified. The inefficiency of VLP assembly was further investigated by expression of additional IBDA-derived constructs. Expression of pVP2 without any other polyprotein components results in the formation of isometric particles with a diameter of about 30 nm. VLPs were observed mainly when a large exogeneous polypeptide sequence (the green fluorescent protein sequence) was fused to the VP3 C-terminal domain. Large numbers of VLPs were visualized by electron microscopy, and single particles were shown to be fluorescent by standard and confocal microscopy analysis. Moreover, the final maturation process converting pVP2 into the VP2 mature form was observed on generated VLPs. We therefore conclude that the correct scaffolding of the VP3 can be artificially induced to promote the formation of VLPs and that the final processing of pVP2 to VP2 is controlled by this particular assembly. To our knowledge, this is the first report of the engineering of a morphogenesis switch to control a particular type of capsid protein assembly.

Site-directed mutagenesis of Avibirnavirus VP4 gene

Virus protein VP4 of infectious bursal disease virus (IBDV) is a protease which separates VPX and VP3 from the polyprotein. We studied the importance of serine and aspartic acid on cleavage at the VPX/VP4 junction and analysed the role of the proposed H547, D590, and S653 catalytic site using five different mutations on VP4. Our results suggest that the replacement of serine by lysine in AXAAS motifs in serotype II IBDV influences polyprotein (PP) processing by VP4 and also indicate the presence of an alternative cleavage site. Mutation on D ((510)TLAADK(515)) prevented the cleavage at the VPX/VP4 junction, but we have found that independently of the importance of those alanines in LAA, D has an important role as part of the cleavage site. Replacement of histidine by proline H547P completely abolished PP processing. Mutation on D590 induced a partial PP processing when it was replaced by proline and the replacement of serine by proline at S653P induced a prominent change in PP processing. These results permit us to conclude that IBDV VP4 has the ability to act according to structural and topographical changes during translational and posttranslational processes and allow multiple hit sites, which serve to increase effectiveness.

Effect of MOI ratio on the composition and yield of chimeric infectious bursal disease virus-like particles by baculovirus co-infection: deterministic predictions and experimental results

Virus-like particles (VLPs) are empty particles consisting of virus capsid proteins that closely resemble native virus but are devoid of the native viral nucleic acids and therefore have attracted significant attention as noninfectious vaccines. A recombinant baculovirus, vIBD-7, which encodes the structural proteins (VP2, VP3, and VP4) of infectious bursal disease virus (IBDV), produces native IBD VLPs in infected Spodoptera frugiperda insect cells. Another baculovirus, vEDLH-22, encodes VP2 that is fused with a histidine affinity-tag (VP2H) at the C-terminus. By co-infection with these two baculoviruses, hybrid VLPs with histidine tags were formed and purified by immobilized metal affinity chromatography (Hu et al., 1999). Also, we demonstrated that varying the MOI ratio of these infecting viruses altered the extent of VP2H incorporated into the particles. A dynamic mathematical model that described baculovirus infection and VLP synthesis (Hu and Bentley, 2000) was adapted here for co-infection and validated by immunofluorescence labeling. It was shown to predict the VLP composition as a dynamic function of MOI. A constraint in the VP2H content incorporated into the particles was predicted and shown by experiments. Also, the MOI ratio of both infecting viruses was shown to be the major factor influencing the composition of the hybrid particles and an important factor in determining the overall yield. ELISA results confirmed that VP2H was exhibited to a varied extent on the outer surface of the particles. This model provides insight on the use of virus co-infection in virus-mediated recombinant protein expression systems and aids in the optimization of chimeric VLP synthesis.

Detection of cell membrane proteins that interact with virulent infectious bursal disease virus

To detect the molecules that interact with infectious bursal disease virus (IBDV), the chicken B lymphoblastoid cell line, LSCC-BK3, which is permissive for virulent IBDV infection was investigated. The sodium dodecyl sulfate-solubilized plasma membrane fraction from the cells was subjected to a virus overlay protein binding assay. The IBDV specifically bound to proteins in LSCC-BK3 plasma membranes with molecular weights of 70, 82 and 110 kDa. This is the first report to demonstrate cellular molecules that interact with virulent IBDV.

Isolation of monoclonal antibodies that inhibit the binding of infectious bursal disease virus to LSCC-BK3 cells

Three hybridoma cell lines producing monoclonal antibodies (MAbs) against LSCC-BK3 cells which are susceptible to infectious bursal disease virus (IBDV) infection were produced and characterized. The MAbs, designated T7, Q11 and Q13, inhibited the attachment of IBDV to LSCC-BK3 cells. Furthermore, these MAbs bound to LSCC-BK3 but not to nonpermissive cells in flow cytometry. MAb T7 detected a 110-kDa membrane protein of LSCC-BK3 cells, whereas Q11 and Q13 reacted with membrane proteins of molecular weights 58-, 85-, 90- and 110-kDa. These observations imply that the 110-kDa protein recognized by all the MAbs is associated with IBDV binding. The MAbs established in this study are useful for studying the interaction between IBDV and its target cell.

Effects of hydrostatic pressure on the structure and biological activity of infectious bursal disease virus

The effects of high hydrostatic pressure on the structure and biological activity of infectious bursal disease virus (IBDV), a commercially important pathogen of chickens, were investigated. IBDV was completely dissociated into subunits at a pressure of 240 MPa and 0 degrees C revealed by the change in intrinsic fluorescence spectrum and light scattering. The dissociation of IBDV showed abnormal concentration dependence as observed for some other viruses. Electron microscopy study showed that morphology of IBDV had an obvious change after pressure treatment at 0 degrees C. It was found that elevating pressure destroyed the infectivity of IBDV, and a completely pressure-inactivated IBDV could be obtained under proper conditions. The pressure-inactivated IBDV retained the original immunogenic properties and could elicit high titers of virus neutralizing antibodies. These results indicate that hydrostatic pressure provides a potential physical means to prepare antiviral vaccine.

Role of Ser-652 and Lys-692 in the protease activity of infectious bursal disease virus VP4 and identification of its substrate cleavage sites

The polyprotein of infectious bursal disease virus (IBDV), an avian birnavirus, is processed by the viral protease, VP4. Previous data obtained on the VP4 of infectious pancreatic necrosis virus (IPNV), a fish birnavirus, and comparative sequence analysis between IBDV and IPNV suggest that VP4 is an unusual eukaryotic serine protease that shares properties with prokaryotic leader peptidases and other bacterial peptidases. IBDV VP4 is predicted to utilize a serine-lysine catalytic dyad. Replacement of the members of the predicted catalytic dyad (Ser-652 and Lys-692) confirmed their indispensability. The two cleavage sites at the pVP2-VP4 and VP4-VP3 junctions were identified by N-terminal sequencing and probed by site-directed mutagenesis. Several additional candidate cleavage sites were identified in the C-terminal domain of pVP2 and tested by cumulative site-directed mutagenesis and expression of the mutant polyproteins. The results suggest that VP4 cleaves multiple (Thr/Ala)-X-Ala downward arrowAla motifs. A trans activity of the VP4 protease of IBDV, and also IPNV VP4 protease, was demonstrated by co-expression of VP4 and a polypeptide substrate in Escherichia coli. For both proteases, cleavage specificity was identical in the cis- and trans-activity assays. An attempt was made to determine whether VP4 proteases of IBDV and IPNV were able to cleave heterologous substrates. In each case, no cleavage was observed with heterologous combinations. These results on the IBDV VP4 confirm and extend our previous characterization of the IPNV VP4, delineating the birnavirus protease as a new type of viral serine protease.

Interactions in vivo between the proteins of infectious bursal disease virus: capsid protein VP3 interacts with the RNA-dependent RNA polymerase, VP1

Little is known about the intermolecular interactions between the viral proteins of infectious bursal disease virus (IBDV). By using the yeast two-hybrid system, which allows the detection of protein-protein interactions in vivo, all possible interactions were tested by fusing the viral proteins to the LexA DNA-binding domain and the B42 transactivation domain. A heterologous interaction between VP1 and VP3, and homologous interactions of pVP2, VP3, VP5 and possibly VP1, were found by co-expression of the fusion proteins in Saccharomyces cerevisiae. The presence of the VP1-VP3 complex in IBDV-infected cells was confirmed by co-immunoprecipitation studies. Kinetic analyses showed that the complex of VP1 and VP3 is formed in the cytoplasm and eventually is released into the cell-culture medium, indicating that VP1-VP3 complexes are present in mature virions. In IBDV-infected cells, VP1 was present in two forms of 90 and 95 kDa. Whereas VP3 initially interacted with both the 90 and 95 kDa proteins, later it interacted exclusively with the 95 kDa protein both in infected cells and in the culture supernatant. These results suggest that the VP1-VP3 complex is involved in replication and packaging of the IBDV genome.

Enhancing yield of infectious Bursal disease virus structural proteins in baculovirus expression systems: focus on media, protease inhibitors, and dissolved oxygen

Structural proteins of the poultry pathogen, infectious bursal disease virus (IBDV), were expressed in the baculovirus/insect cell expression system. To date, several reports have indicated that animal virus structural proteins are expressed only at low yield in this system. In this article, several factors were examined to enhance yield. These include medium, dissolved oxygen level, and the addition (in vivo and in vitro) of protease inhibitors. Specifically, two media were compared, and SF-900 II was superior to Ex-Cell 401 for cell growth and IBDV protein expression. A cocktail of protease inhibitors including phenylmethyl sulfonyl fluoride (PMSF), leupeptin, and ethylenediamine tetraacetic acid (EDTA) minimized proteolysis in vitro. Also, aprotinin and pepstatin A deterred product degradation in vivo and increased the product yield nearly 2-fold. Finally, in 3 L bioreactors, a dissolved oxygen tension of 50% DO (air saturation) was optimal. Results demonstrated that several relatively simple adjustments to the baculovirus system significantly improved the yield of IBD virus structural proteins.

Proteolytic processing in infectious bursal disease virus: identification of the polyprotein cleavage sites by site-directed mutagenesis

The infectious bursal disease virus (IBDV), a member of the Birnaviridae family, is the causative agent of an immune depressive disease that affects domesticated and wild avian species. The expression strategy of IBDV includes the synthesis of a 110-kDa polyprotein containing the capsid precursor polypeptides. The polyprotein is autocatalitically processed rendering three polypeptides: NH2-VPX-VP4-VP3-COOH. We have carried out a systematic analysis, using a series of plasmids encoding polyproteins containing either deletions or single amino acid substitutions, to identify the processing sites. The results obtained showed the existence of two sites, 511LAA513 and 754MAA756, that are essential for the processing of the VPX-VP4 and VP4-VP3 precursors, respectively. These sequences are highly conserved among IBDV strains form serotypes 1 and 2. A secondary VPX-VP4 processing site was detected in a 19-amino acid stretch located upstream of the 511LAA513 site. Analyses using versions of the 754MAA756 VP4-VP3 processing site containing conservative and nonconservative amino acid substitutions demonstrated that the specificity of the cleavage is dictated by the conserved AA dipeptide.

Fluorescence spectroscopy monitoring of the conformational restraint of formaldehyde- and glutaraldehyde-treated infectious bursal disease virus proteins

Interaction of native proteinaceous antigens during the recognition and the effector phases of an immune response leads to antigenic conformational modifications which may elicit additional specific immune response. Protein cross-linking and conformation restraining formaldehyde and glutaraldehyde have been extensively used in vaccine preparation, but the relative efficiencies of conformational restraint at concentrations similar to those used in vaccine preparation have not been investigated. We addressed this issue by comparing the extent of conformational restraint of virus proteins in formaldehyde- and glutaraldehyde-treated virus preparations by monitoring the fluorescence intensities (I320) of infectious bursal disease virus preparations (IBDV) and those of untreated virus during thermal denaturation. Formaldehyde was found to cause no detectable conformational restraint at 0.01% and only very weak restraint at 1%, while glutaraldehyde caused very strong conformational restraint at 0.01%. It is proposed how conformational restraint of proteinaceous antigens may alter ensuing immunity.

Infectious bursal disease virus polyprotein processing does not involve cellular proteases

The larger genome segment, segment A, of infectious bursal disease virus (IBDV) encodes VP2, VP3 and VP4 as a precursor polyprotein. The viral protease, VP4, is responsible for self-processing of the polyprotein, however, there are additional secondary precursor products such as VPX whose further processing has not been defined. Expression of IBDV cDNAs in vitro with rabbit reticulocyte lysates in a coupled transcription-translation system and in the Sindbis virus expression system (with BHK-21 and Vero cell cultures) were used to study processing of the polyprotein. In both expression systems, we identified three main gene products with molecular masses of 48, 34, and 30.5 kDa corresponding to VPX, VP3, and VP4, respectively, as found in IBDV-infected Vero cell cultures, although the amount of each product was variable. A translational time course of the polyprotein gene and analyses of products specified by various sub-clones of the full-length cDNA were used to distinguish primary processing products of translation from secondary products generated by proteolytic processing during in vitro coupled transcription-translation expression. The VPX, VP3 and VP4, which are the primary processing products, first appeared after 20 min of incubation and their production was maximum by 75 min of the coupled transcription-translation reaction. Cycloheximide chases demonstrated that there is no secondary processing of VPX (or VP3 and VP4). Thus VP2, the major capsid protein in virions, was not detected either in translation products of rabbit reticulocyte lysates or in lysates of Sindbis virus recombinant-infected cell cultures indicating the absence of secondary processing of VPX to VP2 during foreign expression of the segment A cDNA. We conclude that VPX maturation to VP2 does not involve cellular proteases.

Restriction fragment length polymorphisms in the VP2 gene of infectious bursal disease viruses

Infectious bursal disease viruses (IBDVs) were examined for restriction fragment length polymorphisms in a fraction of the VP2 gene with the use of the reverse transcriptase/polymerase chain reaction-restriction fragment length polymorphism (RT/PCR-RFLP) assay. The restriction enzymes BstNI and Mbol were used to obtain RFLP results. A third enzyme, StyI, was tested, but its utility for differentiation of IBDV strains was limited. Thirteen vaccine viruses and five IBDV strains that were previously characterized were placed into five molecular groups. Two groups contained viruses described as being classic strains, and two groups contained viruses described as being variant strains. The fifth group contained both classic and variant strains. The RFLP observed for the serotype 2 IBDV strain OH was unlike any of the RFLPs observed in viruses in the five molecular groups. Seven IBDV strains from commercially reared chickens in the United States, Mexico, Puerto Rico, and Thailand were tested in the RT/PCR-RFLP assay to determine if they were similar to the commercial IBDV vaccine strains tested. These viruses were selected because they were associated with lesions in the bursa of chickens that should have been protected by maternal antibodies or active immunity. Each of the viruses tested contained a unique RFLP compared with the IBDV strains and vaccine viruses examined in this study and, thus, did not fit into any of the five molecular groups. These viruses also were distinguishable from each other.

Expression of MD infectious bursal disease viral proteins in baculovirus

Genomic segment A of the variant infectious bursal disease virus (IBDV) strain MD was amplified by reverse transcriptase/polymerase chain reaction and further characterized by baculovirus expression. Three different baculovirus clones were constructed containing the genes encoding VP2, VP2/VP4, and the complete polyprotein cloned into the baculovirus transfer vector pVL1392. Baculovirus recombinants were identified by dot blot hybridization and were plaque purified three times. Baculovirus expression of the recombinants produced IBDV-specific proteins that were comparable in molecular size to native MD IBDV viral proteins VPX (48 kD), VP2 (45 kD), VP3 (32 kD), and VP4 (28 kD) as determined by sodium dodecyl sulfare-polyacrylamide gel electrophoresis and western immunoblot analysis. All three recombinants produced a 48-kD protein that possibly represents VPX, the precursor product of VP2. In addition to the 48-kD protein, the VP2/VP4 recombinant produced an IBDV-specific protein corresponding to the 28-kD VP4. The baculovirus-expressed polyprotein gene produced, in addition to the 48-kD protein, a 32-kD (VP3) IBDV-specific protein and a 29-kD protein that migrated slightly slower than MD VP4. The baculovirus-expressed proteins were used as antigens in an indirect enzyme-linked immunosorbent assay (ELISA). The ELISAs detected antibodies against the variant IBDV strains MD, GLS, and IN and the classic IBDV strains SAL and STC but did not detect antibodies against the variant Del-A and classic IBDV strain BVM or the serotype 2 IBDV strain OH.

Evidence that virion-associated VP1 of avibirnaviruses contains viral RNA sequences

The VP1 encoded by genomic segment B of birnaviruses is generally known to exist as a genome-linked protein (VPg) and as a "free" polypeptide of 90 kDa in virus particles. The guanylylation activity associated with infectious bursal disease virus (IBDV) was demonstrated by incubating purified virus in presence of [alpha 32P] GTP; optimum activity in the 90 kDa form of VP1 was seen in low salt concentration in the presence of 4 mM magnesium ions over a wide range of incubation temperatures. The IBDV VP1 was shown to lack guanyl transferase activity. Northwestern (RNA-protein) blot analysis of purified virus using a radiolabelled cDNA probe consisting of 3' and 5' ends of genomic segment B indicated that both forms of virion-associated VP1 contained viral RNA sequences of which those linked to VPg corresponded to the two genome segments and those linked to the 90 kDa VP1 were probably a short oligonucleotide of the terminal viral RNA sequences.

Insect cell-derived VP2 of infectious bursal disease virus confers protection against the disease in chickens

Infectious bursal disease virus (IBDV) has become a major problem in recent years. Conventional vaccines make use of attenuated or inactivated viral strains, but these are gradually losing their effectiveness. We investigated the possibility of using purified VP2, a subunit of IBDV structural protein expressed in insect cells, as a vaccine. The VP2 gene was cloned into pAcYM1. The cloned gene was expressed in a baculovirus system, giving rise to a high quantity of recombinant VP2 (rVP2) protein. The length of the VP2 is 453 amino acids, and it contains two additional amino acids of the baculovirus at the carboxyl terminus. The molecular mass of the protein is about 48 kD. The rVP2 protein reacted with antibodies raised against viral VP2 and had a similar molecular weight. This protein was tested in a controlled vaccination experiment and compared with an inactivated commercial vaccine. High levels of antibodies were raised by the vaccinated birds. The vaccinated birds were challenged with a pathogenic viral strain. rVP2-vaccinated chickens exhibited high resistance to the virus. No mortality or weight changes in the bursa of Fabricius were observed in the vaccinated birds, whereas in the negative control birds, vaccinated with phosphate buffer, up to 50% mortality was found. Higher levels of antibodies were found by enzyme-linked immunosorbent assay in birds vaccinated with rVP2 compared with those vaccinated with the commercial vaccine. This study suggests the potential use of the isolated rVP2 as a subunit vaccine.

Expression and RNA dependent RNA polymerase activity of birnavirus VP1 protein in bacteria and yeast

Birnaviruses typically encode a polyprotein that is the precursor to the structural proteins of the virus and a protein of rare abundance, VP1, that is the putative dsRNA replicase and/or transcriptase. We have reconstructed the VP1 gene of IBDV from a library of cDNA clones and expressed the gene in Escherichia coli and in Saccharomyces cerevisiae. We could not detect an RNA polymerase activity associated with E. coli-derived VP1, and neither could we promote the yeast-derived VP1 to replicate exogenous IBDV dsRNA. However, the yeast-derived VP1 was shown to have an actinomycin-insensitive RNA polymerase activity that can recognise an endogenous template in S. cerevisiae. Our work suggests that further studies on birnavirus replication may be best addressed using an S. cerevisiae expression system.

Sequence analysis and expression of the host-protective immunogen VP2 of a variant strain of infectious bursal disease virus which can circumvent vaccination with standard type I strains

The host-protective antigen VP2 of a variant strain of infectious bursal disease virus (IBDV) which emerged from a vaccinated flock and is able to circumvent vaccination with classic type I strains of IBDV, was cloned and its nucleotide sequence determined. Virus-neutralizing monoclonal antibodies (MAbs) raised against the Australian 002-73 strain of IBDV did not react or reacted only very weakly with the expression product of the variant virus. The deduced amino acid sequence of VP2 from the variant strain differed in 17 residues from that of the Australian strain and in eight positions from a consensus sequence compiled from six type I strains of IBDV. All the amino acid changes mapped within the central, variable region of VP2, which forms the conformational epitope recognized by virus-neutralizing MAbs. Changes in the two hydrophilic regions at either end of this fragment were unique to the variant virus and were crucial for its ability to escape the virus-neutralizing antibodies induced by vaccination with a standard type I vaccine.

Birnavirus precursor polyprotein is processed in Escherichia coli by its own virus-encoded polypeptide

The cDNA fragment of the large RNA segment of infectious bursal disease virus 002-73, when expressed in Escherichia coli, produces precursor polyprotein (N-VP2-VP4-VP3-C), most of which is then processed to generate constituent polypeptides. Using cDNA fragments containing site-specific mutations and two monoclonal antibodies that are specific to VP2 and VP3 of mature virus particles, we demonstrated that the VP4 protein is involved in processing of the precursor polyprotein to generate VP2 and VP3 and excluded the possibility of internal initiation for the generation of VP3.

Deletion mapping and expression in Escherichia coli of the large genomic segment of a birnavirus

The large genomic segment of infectious bursal disease virus encodes a polyprotein in which the viral polypeptides are present in the following order: N-VP2-VP4-VP3-C. Expression in Escherichia coli of the large segment results in the processing of the polyprotein. The expression product reacts with a virus neutralizing and protective monoclonal antibody that recognizes a conformational epitope on the surface of the virus. Different regions of the large genomic segment were deleted at defined restriction sites and the truncated fragments were ligated to various expression vectors for high-level expression in E. coli. The expressed proteins were probed with three different monoclonal antibodies that recognize epitopes encoded by different regions of the large genomic segment. These deletion mapping studies suggest that VP4 is involved in the processing of the precursor polyprotein, and the conformational epitope recognized by the virus neutralizing monoclonal antibody is present within VP2.