Intracellular cleavage of sigmaA protein of avian reovirus.

By Western blot analyzes of expression of avian reovirus proteins, one unknown fragment was detected by an anti-sigmaA monoclonal antibody in virus-infected cells lysate. It was interesting to note that RNA interference against sigmaA resulted in the suppression of the unknown fragment. Using various lengths of sigmaA constructs conjugated with different tags, we present evidences to demonstrate that the fragment comes from the cleavage of sigmaA and is the larger carboxyl-terminus, termed sigmaAC. Cleavage of sigmaA simultaneously produces a smaller amino-terminus, named sigmaAN. sigmaAC could be seen early in viral infection and accumulated with time and dose of infection, indicating that the derived products are not just transient intermediates of protein degradation. The same type of cleaved products were also observed in different genotypes and serotypes of ARV as well as in different cell lines, suggesting that this intracellular modification of sigmaA is common to all ARVs. Similar localization of sigmaAC in both cytosol and nucleus with sigmaA suggested that further modification of sigmaA may be important for its function. Our evidences suggest that besides the outer capsid protein muB, sigmaA may also have post-translational cleavage which has never been reported before even in related mammalian reovirus.

AMP-activated protein kinase facilitates avian reovirus to induce mitogen-activated protein kinase (MAPK) p38 and MAPK kinase 3/6 signalling that is beneficial for virus replication.

Stimulated by energetic stress, AMP-activated protein kinase (AMPK) controls several cellular functions. It was discovered here that infection of Vero cells with avian reovirus (ARV) upregulated AMPK and mitogen-activated protein kinase (MAPK) p38 phosphorylation in a time- and dose-dependent manner. Being an energy status sensor, AMPK is potentially an upstream regulator of MAPK p38. Treatment with 5-amino-4-imidazolecarboxamide ribose (AICAR), a well-known activator of AMPK, induced phosphorylation of MAPK p38. Unlike AICAR, wortmannin or rapamycin did not induce phosphorylation of MAPK p38, suggesting that mTOR inhibition is not a determining factor in MAPK p38 phosphorylation. Inhibition of AMPK by compound C antagonized the effect of AICAR on MAPK p38 in Vero cells. Specific inhibition of AMPK by small interfering RNA or compound C also suppressed ARV-induced phosphorylation of MAPK kinase (MKK) 3/6 and MAPK p38 in Vero and DF-1 cells, thereby providing a link between AMPK signalling and the MAPK p38 pathway. The mechanism of ARV-enhanced phosphorylation of MKK 3/6 and MAPK p38 in cells was not merely due to glucose deprivation, a probable activator of AMPK. In the current study, direct inhibition of MAPK p38 by SB202190 decreased the level of ARV-induced syncytium formation in Vero and DF-1 cells, and decreased the protein levels of ARV sigma A and sigma C and the progeny titre of ARV, suggesting that activation of MAPK p38 is beneficial for ARV replication. Taken together, these results suggested that AMPK could facilitate MKK 3/6 and MAPK p38 signalling that is beneficial for ARV replication. Although well studied in energy metabolism, this study provides evidence for the first time that AMPK plays a role in modulating ARV and host-cell interaction.

Baculovirus surface display of sigmaC and sigmaB proteins of avian reovirus and immunogenicity of the displayed proteins in a mouse model.

Avian reovirus (ARV), an important pathogen in poultry, causes arthritis, chronic respiratory disease, and malabsorption syndrome that cause considerable economic losses to the poultry industry. In present study, we have succeeded in construction of a universal baculovirus surface display system (UBSDS) that can display different foreign proteins on the envelope of baculovirus. Sequences encoding the signal peptide (SS), transmembrane domain (TM), and cytoplasmic domain (CTD) derived from the gp64 protein of baculovirus and histidine tag, respectively were inserted into the pBacCE vector. Four restriction enzyme sites between the histidine tag and gp64 transmembrane domain were established for expression of different foreign proteins. The transmembrane domain and CTD of gp64 in the platform were designed in order to improve stability and quantity of foreign proteins on the envelope of baculovirus. The sigmaC and sigmaB proteins of ARV are known to elicit neutralizing antibodies against ARV. The UBSDS was therefore used to express sigmaC and sigmaB proteins on the envelope of baculovirus. Two recombinant baculoviruses BacSC-sigmaC and BacSC-sigmaB have been successfully constructed. After infection, both His6-tagged recombinant sigmaC (rsigmaC) and sigmaB (rsigmaB) proteins were displayed on the envelope of recombinant baculoviruses and the recombinant viral proteins were anchored on the plasma membrane of Sf-9 cells, as revealed by immunofluorescence staining (IFS) and confocal microscopy. The antigenicity of rsigmaC and rsigmaB proteins was demonstrated by Western blotting assay. Immunogold electron microscopy demonstrated that both recombinant viruses displayed rsigmaC and rsigmaB proteins on the viral surface. Immunization of BALB/c mice with recombinant viruses, demonstrated that serum from the BacSC-sigmaC and BacSC-sigmaB treated models had significant higher levels of virus neutralization activities than the control groups. This demonstrates that the recombinant baculoviruses BacSC-sigmaC and BacSC-sigmaB can be a potential vaccine against ARV infections.

Development of a reliable assay protocol for identification of diseases (RAPID)-bioactive amplification with probing for detection of avian reovirus.

Avian reovirus (ARV) causes several disease syndromes in poultry including arthritis, malabsorption syndrome and chronic respiratory disease that result in major economic losses. Early detection is very important for the control of the ARV-induced infections. This study was therefore aimed at developing a reliable assay protocol for identification of diseases (RAPID)-bioactive amplification with probing (BAP) assay for detection of ARV. This assay combines nested polymerase chain reaction (PCR) and magnetic bead-based DNA probing systems greatly increasing its sensitivity and specificity. Alignment of ARV S2 gene from different ARV genotypes and serotypes was done to find the highly conserved regions for primer and probe design. Two reverse transcription (RT)-PCR primer pairs, six nested PCR primer pairs, and one magnetic probe were tested to find the most specific ones for ARV detection. The optimal conditions for RT-PCR, nested PCR, and hybridization of magnetic probe were established. The optimal annealing temperatures for RT-PCR and nested PCR were 62.1 and 54.8 degrees C, respectively. The optimal hybridization temperature was 51.2 degrees C using hybridization buffer (5x SSC and 0.5% SDS). The sensitivity of the kit was 5 copies/microl of ARV genomic RNA. The kit was very specific as all negative controls failed to show any positive reactions. The kit shows good reproducibility with intra- and inter-assay coefficient of variation (CV) of 1.3 and 1.7%, respectively. In addition, different serotypes and genotypes of ARV were tested by RAPID-BAP assay to estimate the practicability of the kit in clinical samples. All of ARV serotypes and genotypes tested could be detected by this kit proving that the kit is suitable for clinical application.

Suppression of protein expression of three avian reovirus S-class genome segments by RNA interference.

RNA interference was used to suppress protein expression of three S-class genome segments of avian reovirus (ARV). Viral progeny titer was successfully down-regulated by RNA interference. Suppression of S1 genome segment, which has three open reading frames, not only decreased the expression level of the structural protein sigmaC but also reduced cell fusion and the level of Ser(15)-phosphorylated p53 protein caused by the nonstructural proteins p10 and p17, respectively. Suppression of S2 or S4 genome segment by RNA interference could also reduce the expression level of sigmaA or sigmaNS. Interestingly, suppression of sigmaNS resulted in down regulation of the expression of other viral products. In terms of variability of different genes among viral strains and of the impact after their suppression, it seems that the viral products involved in construction of viroplasm or core particles, like sigmaNS, are considerable choices to efficiently inhibit ARV multiplication by RNA interference. Using a GFP reporter system, it was discovered that ARV could not inhibit activated RNA interference, suggesting that RNA interference may be used in the suppression of ARV infection.

Apoptosis induction by avian reovirus through p53 and mitochondria-mediated pathway.

Although induction of apoptosis by avian reovirus has been demonstrated in primary chicken embryonic fibroblast and several cell lines, to date, the potential significance of avian reovirus (ARV)-induced apoptosis and its pathways in cultured cells are still largely unknown. We now provide the first evidence of upregulation of p53 and Bax and specifically for Bax translocation from cytosol to mitochondria following infection with a cytoplasmically replicating RNA virus. Bax translocation to the mitochondria led to the release of mitochondrial proapoptic factors cytochrome c and Smac/DIABLO from mitochondria to the cytosol, but not the release of apoptosis-inducting factor. Activation of caspases-9 and -3 which cleaves the enzyme poly(ADP-ribose) polymerase in ARV-infected BHK-21 cells was also detected. Internucleosomal DNA cleavage was prevented by caspase inhibitors, further demonstrating that ARV-induced apoptosis was executed through caspase-dependent mechanisms. Stable expression of human bcl-2 in BHK-21 cells not only blocked ARV-induced apoptosis and DNA fragmentation but also reduced the level of infectious virus production and its spread in BHK-21 cells infected with ARV at a low multiplicity of infection. All our data suggest that p53 and the mitochondria-mediated pathway played an important regulatory role in ARV-induced apoptosis in BHK-21 cells. To further study the pathogenesis of ARV infection, a dual-labeling assay was used for the simultaneous detection of cells containing viral antigen and apoptotic cells. Dual-labeling assay revealed that the majority of antigen-expressing cells were not apoptotic. Remarkably, some apoptotic but non-antigen-expressing cells were frequently located in the vicinity of antigen-expressing cells. Syncytium formation in ARV-infected BHK-21 cells undergoing apoptosis, was apparent in large syncytia at late infection times, indicating a correlation between virus replication and apoptosis in cultured cells.

Development and characterization of monoclonal antibodies against avian reovirus sigma C protein and their application in detection of avian reovirus isolates.

Avian reovirus (ARV) is a non-enveloped virus with a segmented double-stranded RNA genome surrounded by a double icosahedral capsid shell. ARVs are associated with viral arthritis, immunosuppression, and enteric diseases in poultry. The sigma C protein was involved in induction of apoptosis and neutralization antibody. In the present study, sigma C-His protein was expressed in Sf9 insect cells and purified by immobilized metal affinity chromatography. Eight monoclonal antibodies (mAbs) against sigma C-His and three mAbs against His were screened from hybridoma cells produced by fusion of splenocytes from immunized mice with NS1 myeloma cells. Among the eight mAbs against sigma C protein, all belonged to the IgG isotype except three for IgM. It was discovered that all anti-His mAbs were mixtures of IgG and IgM isotypes. mAbs reacted with sigma C-His protein in a conformation-independent manner based on dot blot and western blotting assays. The competitive binding assay indicated that all mAbs recognized the same epitope on sigma C protein that was conserved in different isolates. Compared with the commercial anti-ARV S1133 polyclonal antibody, mAb (D15) had universal reactivity to all serotypes or genotypes of ARVs tested. This monoclonal antibody may therefore be useful for the development of an antigen-capture enzyme-linked immunosorbent assay for rapid detection of field isolates.

Epitope mapping and functional analysis of sigma A and sigma NS proteins of avian reovirus.

We have previously shown that avian reovirus (ARV) sigmaA and sigmaNS proteins possess dsRNA and ssRNA binding activity and suggested that there are two epitopes on sigmaA (I and II) and three epitopes (A, B, and C) on sigmaNS. To further define the location of epitopes on sigmaA and sigmaNS proteins and to further elucidate the biological functions of these epitopes by using monoclonal antibodies (MAbs) 62, 1F9, H1E1, and 4A123 against the ARV S1133 strain, the full-length and deletion fragments of S2 and S4 genes of ARV generated by polymerase chain reaction (PCR) were cloned into pET32 expression vectors and the fusion proteins were overexpressed in Escherichia coli BL21 strain. Epitope mapping using MAbs and E. coli-expressed deletion fragments of sigmaA and sigmaNS of the ARV S1133 strain, synthetic peptides, and the cross reactivity of MAbs to heterologous ARV strains demonstrated that epitope II on sigmaA was located at amino acid residues 340QWVMAGLVSAA350 and epitope B on sigmaNS at amino acid residues 180MLDMVDGRP188. The MAbs (62, 1F9, and H1E1) directed against epitopes II and B did not require the native conformation of sigmaA and sigmaNS, suggesting that their binding activities were conformation-independent. On the other hand, MAb 4A123 only reacted with complete sigmaNS but not with truncated sigmaNS fusion proteins in Western blot, suggesting that the binding activity of MAb to epitope A on sigmaNS was conformation-dependent. Amino acid sequence analysis and the binding assays of MAb 62 to heterologous ARV strains suggested that epitope II on sigmaA was highly conserved among ARV strains and that this epitope is suitable as a serological marker for the detection of ARV antibodies following natural infection in chickens. On the contrary, an amino acid substitution at position 183 (M to V) in epitope B of ARV could hinder the reactivity of the sigmaNS with MAb 1F9. The sigmaNS of ARV with ssRNA-binding activity could be blocked by monoclonal antibody 1F9. The epitope B on sigmaNS is required for ssRNA binding because its deletion fully abolished the ssRNA binding activity of sigmaNS.

Secreted expression of the VP2 protein of very virulent infectious bursal disease virus in the methylotrophic yeast Pichia pastoris.

The VP2-encoding gene of very virulent infectious bursal disease virus (vvIBDV) was amplified using reverse transcription (RT)-polymerase chain reaction (PCR) and inserted into pPICZalphaA vector. Recombinant plasmid DNA was integrated into the chromosome of the transformed Pichia pastoris by electroporation and expressed protein identified by SDS-PAGE and Western blotting. High-level secreted expression was performed by determining the Mut+ phenotype and secreting multi-copy integrants in the recombinant yeast. A recombinant protein of approximately 67 kDa was secreted into the supernatant from the yeast when induced with methanol. The expressed supernatant was bound with chicken anti-IBDV polyclonal antibodies. Western blotting with antibodies against vvIBDV indicated that the recombinant VP2 protein retained its antigenicity. High-level production (10 mg/100 ml) of the recombinant VP2 protein indicated that P. pastoris was an efficent expression system for vvIBDV VP2 protein.

Rapid characterization of avian reoviruses using phylogenetic analysis, reverse transcription-polymerase chain reaction and restriction enzyme fragment length polymorphism.

A reverse transcription-polymerase chain reaction is described, which amplified the full-length sigmaC-encoding and sigmaNS-encoding genes of avian reovirus (ARV). DNA fragments of 1022 and 1152 base pairs were amplified among ARV isolates, respectively, indicating that there were no apparent deletions or insertions in these regions. Fragments amplified from vaccine strains and field isolates were digested with five different restriction enzymes Bcn I, Hae III, Taq I, Dde I, and Hinc II, respectively. Restriction fragment profiles observed on polyacrylamide gels showed heterogeneity between vaccine and Taiwanese isolates. All ARV isolates tested showed different restriction enzyme cleavage patterns and could be clearly distinguished. The strain-typing based on the cleavage sites in the sigmaC-encoding gene of ARV showed that viruses could be classified into four distinct groups. A phylogenetic tree based on the nucleotide sequences of the sigmaC-encoding gene revealed that Taiwanese ARV isolates were classified into four distinct groups, indicating that the genotyping is consistent with typing based on restriction enzyme fragment length polymorphism of the sigmaC-encoding gene of ARV. The results suggested that polymerase chain reaction followed by restriction enzyme analysis provided a simple and rapid approach for characterization of ARV isolates. Also, it is possible to determine whether a new variant strain has been introduced into a flock or a given virus strain has spread from one flock to another.

Avian reovirus sigmaC protein induces apoptosis in cultured cells.

The avian reovirus (ARV) infection is associated with various disease conditions in poultry. However, the pathogenesis mechanisms are poorly characterized. In the present study, we clearly demonstrated that the sigmaC of ARV S1133 strain induced apoptosis in both BHK-21 and Vero cells. Five kinds of assays for apoptosis were used in analyzing ARV-infected BHK-21 and Vero cells: (1) assay for DNA ladders, (2) ELISA detection of cytoplasmic histone-associated DNA fragments, (3) nuclear staining with acridine orange, (4) Western blot, Northern blot, and immunofluorescent assay (IFA), and (5) flow cytometric analysis. The sigmaC protein of ARV could elicit apoptosis occurring in a dose- and time-dependent manner. The current results further our understanding of the function of sigmaC in cultured cells and suggest that sigmaC is a viral-encoded apoptin and possesses apoptosis-inducing ability. Furthermore, deletion analysis of the ARV sigmaC protein suggests that the carboxyl-terminus of sigmaC is important in mediating sigmaC-induced apoptosis because its deletion abolished the induction of apoptosis.

Molecular evolution of avian reovirus: evidence for genetic diversity and reassortment of the S-class genome segments and multiple cocirculating lineages.

Nucleotide sequences of the S-class genome segments of 17 field-isolates and vaccine strains of avian reovirus (ARV) isolated over a 23-year period from different hosts, pathotypes, and geographic locations were examined and analyzed to define phylogenetic profiles and evolutionary mechanism. The S1 genome segment showed noticeably higher divergence than the other S-class genes. The sigma C-encoding gene has evolved into six distinct lineages. In contrast, the other S-class genes showed less divergence than that of the sigma C-encoding gene and have evolved into two to three major distinct lineages, respectively. Comparative sequence analysis provided evidence indicating extensive sequence divergence between ARV and other orthoreoviruses. The evolutionary trees of each gene were distinct, suggesting that these genes evolve in an independent manner. Furthermore, variable topologies were the result of frequent genetic reassortment among multiple cocirculating lineages. Results showed genetic diversity correlated more closely with date of isolation and geographic sites than with host species and pathotypes. This is the first evidence demonstrating genetic variability among circulating ARVs through a combination of evolutionary mechanisms involving multiple cocirculating lineages and genetic reassortment. The evolutionary rates and patterns of base substitutions were examined. The evolutionary rate for the sigma C-encoding gene and sigma C protein was higher than for the other S-class genes and other family of viruses. With the exception of the sigma C-encoding gene, which nonsynonymous substitutions predominate over synonymous, the evolutionary process of the other S-class genes can be explained by the neutral theory of molecular evolution. Results revealed that synonymous substitutions predominate over nonsynonymous in the S-class genes, even though genetic diversity and substitution rates vary among the viruses.

Detection of infectious bronchitis virus by multiplex polymerase chain reaction and sequence analysis.

A multiplex reverse transcription-polymerase chain reaction (RT-PCR) was developed to amplify the S1 and S2 genes of vaccine and recent Taiwanese isolates of infectious bronchitis virus (IBV). DNA fragments of 228 and 400 base pairs in length were amplified among IBV isolates in multiplex PCR, suggesting that there were no apparent deletions or insertions in these regions. No PCR products were amplified from unrelated avian viruses and negative controls. The results suggested that multiplex PCR provided a specific and sensitive approach for identification of IBV isolates. Sequence analysis of the hypervariable region (HVR) of S1 gene exhibited high variations among Taiwanese IBV isolates. The TWI and TWII groups were about 84-98 and 94-99% identity within the groups. American strains were most divergent sharing only 60% homology with TWI and TWII Taiwanese strains. The Mass group varied 0-10% among each other and had over 70% homology with TWI and TWII Taiwanese strains. A phylogenetic tree based on the nucleotide sequences of the HVR of S1 gene revealed that Taiwanese IBV isolates had evolved into three groups (TWI, TWII, and Mass). This suggested that there were multiple groups of viruses cocirculating in Taiwan.