Evidence of nucleotidyl phosphatase activity associated with core protein sigma A of avian reovirus S1133

Gallus NME/NM23 nucleoside diphosphate kinase 2 interacts with viral σA and affects the replication of avian reovirus

Our present study aimed to identify host cell proteins that may interact with avian reovirus (ARV) σA protein and their potential effect on ARV replication. The ARV structural protein σA has been demonstrated to suppress interferon production and confirmed to activate the PI3K/Akt pathway. However, host cell factors interacting with σA to affect ARV replication remain unknown. In current study, a cDNA library of chicken embryo fibroblasts (CEFs) was constructed, and host cell proteins interacting with σA were screened by a yeast two-hybrid system. We identified four candidate cellular proteins that interact with ARV σA protein. Among them, Gallus NME/NM23 nucleoside diphosphate kinase 2 (NME2) was further validated as a σA-binding protein through co-immunoprecipitation. The key interaction domain was identified at amino acids (aa) 121-416 in NME2 and at aa 71-139 in σA, respectively. We demonstrated that overexpression of NME2 substantially inhibited ARV replication. In addition silencing NME2 by small interfering RNAs (siRNAs) resulted in marked enhancement of ARV replication. Our work has demonstrated that NME2 is a σA-binding protein that may affect ARV replication in CEF cells.

Sequencing and phylogenetic analysis of an avian reovirus genome

Avian reovirus infection causes considerable economic loss to the commercial poultry industry. Live-attenuated vaccine strain S1133 (v-S1133, derived from parent strain S1133) is considered the safest and most effective vaccine and is currently used worldwide. To identify the genes responsible for its attenuation, DNA sequences of open reading frames (ORF) of S1133 and its parent strains S1133, 1733, 526, and C78 along with three field isolates (GuangxiR1, GuangxiR2, and GX110058) and one isolate (GX110116) from a vaccinated chicken were performed. The sequence data were compared with available sequences in nucleotide sequence databases of American (AVS-B, 138, 176) and Chinese (C-98 and T-98) origin. Sequence analysis identified that several v-S1133 specific nucleotide substitutions existed in the ORFs of λA, λB, λC, μA, μB, μNS, σA, σB, and σNS genes. The v-S1133 strain could be differentiated from the field-isolated strains based on single nucleotide polymorphisms. Phylogenetic analysis revealed that v-S1133 shared the highest sequence homologies with S1133 and reovirus isolates from China, grouped together in one cluster. Chinese isolates were clearly more distinct from the American reovirus AVS-B strain, which is associated with runting-stunting syndrome in broilers.

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.

Conserved structure/function of the orthoreovirus major core proteins

Orthoreoviruses are infectious agents with genomes of 10 segments of double-stranded RNA. Detailed molecular information is available for all 10 segments of several mammalian orthoreoviruses, and for most segments of several avian orthoreoviruses (ARV). We, and others, have reported sequences of the L2, all S-class, and all M-class genome segments of two different avian reoviruses, strains ARV138 and ARV176. We here determined L1 and L3 genome segment nucleotide sequences for both strains to complete full genome characterization of this orthoreovirus subgroup. ARV L1 segments were 3958 nucleotides long and encode lambda A major core shell proteins of 1293 residues. L3 segments were 3907 nucleotides long and encode lambda C core turret proteins of 1285 residues. These newly determined ARV segments were aligned with all currently available homologous mammalian reovirus (MRV) and aquareovirus (AqRV) genome segments. Identical and conserved amino acid residues amongst these diverse groups were mapped into known mammalian reovirus lambda 1 core shell and lambda 2 core turret proteins to predict conserved structure/function domains. Most identical and conserved residues were located near predicted catalytic domains in the lambda-class guanylyltransferase, and forming patches that traverse the lambda-class core shell, which may contribute to the unusual RNA transcription processes in this group of viruses.

Avian reovirus L2 genome segment sequences and predicted structure/function of the encoded RNA-dependent RNA polymerase protein

Background

The orthoreoviruses are infectious agents that possess a genome comprised of 10 double-stranded RNA segments encased in two concentric protein capsids. Like virtually all RNA viruses, an RNA-dependent RNA polymerase (RdRp) enzyme is required for viral propagation. RdRp sequences have been determined for the prototype mammalian orthoreoviruses and for several other closely-related reoviruses, including aquareoviruses, but have not yet been reported for any avian orthoreoviruses.

Results

We determined the L2 genome segment nucleotide sequences, which encode the RdRp proteins, of two different avian reoviruses, strains ARV138 and ARV176 in order to define conserved and variable regions within reovirus RdRp proteins and to better delineate structure/function of this important enzyme. The ARV138 L2 genome segment was 3829 base pairs long, whereas the ARV176 L2 segment was 3830 nucleotides long. Both segments were predicted to encode λB RdRp proteins 1259 amino acids in length. Alignments of these newly-determined ARV genome segments, and their corresponding proteins, were performed with all currently available homologous mammalian reovirus (MRV) and aquareovirus (AqRV) genome segment and protein sequences. There was ~55% amino acid identity between ARV λB and MRV λ3 proteins, making the RdRp protein the most highly conserved of currently known orthoreovirus proteins, and there was ~28% identity between ARV λB and homologous MRV and AqRV RdRp proteins. Predictive structure/function mapping of identical and conserved residues within the known MRV λ3 atomic structure indicated most identical amino acids and conservative substitutions were located near and within predicted catalytic domains and lining RdRp channels, whereas non-identical amino acids were generally located on the molecule's surfaces.

Conclusion

The ARV λB and MRV λ3 proteins showed the highest ARV:MRV identity values (~55%) amongst all currently known ARV and MRV proteins. This implies significant evolutionary constraints are placed on dsRNA RdRp molecules, particularly in regions comprising the canonical polymerase motifs and residues thought to interact directly with template and nascent mRNA. This may point the way to improved design of anti-viral agents specifically targeting this enzyme.

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.

Avian reovirus core protein μA expressed in Escherichia coli possesses both NTPase and RTPase activities

Analysis of the amino acid sequence of core protein μA of avian reovirus has indicated that it may share similar functions to protein μ2 of mammalian reovirus. Since μ2 displayed both nucleotide triphosphatase (NTPase) and RNA triphosphatase (RTPase) activities, the purified recombinant μA ( μA) was designed and used to test these activities. μA was thus expressed in bacteria with a 4.5 kDa fusion peptide and six His tags at its N terminus. Results indicated that  μA possessed NTPase activity that enabled the protein to hydrolyse theβ–γphosphoanhydride bond of all four NTPs, since NDPs were the only radiolabelled products observed. The substrate preference was ATP>CTP>GTP>UTP, based on the estimatedkcatvalues. Alanine substitutions for lysines 408 and 412 (K408A/K412A) in a putative nucleotide-binding site of  μA abolished NTPase activity, further suggesting that NTPase activity is attributable to protein  μA. The activity of  μA is dependent on the divalent cations Mg2+or Mn2+, but not Ca2+or Zn2+. Optimal NTPase activity of  μA was achieved between pH 5.5 and 6.0. In addition,  μA enzymic activity increased with temperature up to 40 °C and was almost totally inhibited at temperatures higher than 55 °C. Tests of phosphate release from RNA substrates with  μA or K408A/K412A  μA indicated that  μA, but not K408A/K412A  μA, displayed RTPase activity. The results suggested that both NTPase and RTPase activities of  μA might be carried out at the same active site, and that protein μA could play important roles during viral RNA synthesis.

Avian reovirus: Structure and biology

Avian reoviruses are important pathogens that cause considerable losses to the poultry industry, but they have been poorly characterized at the molecular level in the past, mostly because they have been considered to be very similar to the well-studied mammalian reoviruses. Studies performed over the last 20 years have revealed that avian reoviruses have unique properties and activities, different to those displayed by their mammalian counterparts, and of considerable interest to molecular virologists. Notably, the avian reovirus S1 gene is unique, in that it is a functional tricistronic gene that possesses three out-of-phase and partially overlapping open reading frames; the identification of the mechanisms that govern the initiation of translation of the three S1 cistrons, and the study of the properties and activities displayed by their encoded proteins, are particularly interesting areas of research. For instance, avian reoviruses are one of the few nonenveloped viruses that cause cell-cell fusion, and their fusogenic phenotype has been associated with a nonstructural 10 kDa transmembrane protein, which is expressed by the second cistron of the S1 gene; the small size of this atypical fusion protein offers an interesting model for studying the mechanisms of cell-cell fusion and for identifying fusogenic domains. Finally, avian reoviruses are highly resistant to interferon, and therefore they may be useful for investigating the mechanisms and strategies that viruses utilize to counteract the antiviral actions of interferons.

Sequences of avian reovirus M1, M2 and M3 genes and predicted structure/function of the encoded mu proteins

We report the first sequence analysis of the entire complement of M-class genome segments of an avian reovirus (ARV). We analyzed the M1, M2 and M3 genome segment sequences, and sequences of the corresponding muA, muB and muNS proteins, of two virus strains, ARV138 and ARV176. The ARV M1 genes were 2,283 nucleotides in length and predicted to encode muA proteins of 732 residues. Alignment of the homologous mammalian reovirus (MRV) mu2 and ARV muA proteins revealed a relatively low overall amino acid identity ( approximately 30%), although several highly conserved regions were identified that may contribute to conserved structural and/or functional properties of this minor core protein (i.e. the MRV mu2 protein is an NTPase and a putative RNA-dependent RNA polymerase cofactor). The ARV M2 genes were 2158 nucleotides in length, encoding predicted muB major outer capsid proteins of 676 amino acids, more than 30 amino acids shorter than the homologous MRV mu1 proteins. In spite of the difference in size, the ARV/MRV muB/mu1 proteins were more conserved than any of the homologous proteins encoded by other M- or S-class genome segments, exhibiting percent amino acid identities of approximately 45%. The conserved regions included the residues involved in the maturation- and entry- specific proteolytic cleavages that occur in the MRV mu1 protein. Notably missing was a region recently implicated in MRV mu1 stabilization and in forming "hub and spokes" complexes in the MRV outer capsid. The ARV M3 genes were 1996 nucleotides in length and predicted to encode a muNS non-structural protein of 635 amino acids, significantly shorter than the homologous MRV muNS protein, which is attributed to several substantial deletions in the aligned ARV muNS proteins. Alignments of the ARV and MRV muNS proteins revealed a low overall amino acid identity ( approximately 25%), although several regions were relatively conserved.

Development of a quantitative Light Cycler real-time RT-PCR for detection of avian reovirus

A robust, ultrasensitive, and accurate quantitative assay was developed for avian reovirus (ARV) with the Light Cycler SYBR Green-based real-time reverse transcription-PCR (real-time LC RT-PCR). The assay exhibited high specificity as all negative controls and other avian pathogens, such as Newcastle disease virus (NDV), infectious bronchitis virus (IBV), infectious bursal disease virus (IBDV), avian influenza virus (AIV), and mycoplasma synovia (MS), failed to show any positive detection. A minimum of 39 copies/microl of ARV genomic RNA could be detected by the assay. By dilution analysis, the real-time LC RT-PCR developed in this study was 3-log more sensitive than the conventional RT-PCR for the detection of ARV. The vaccine and field isolates of ARV were detected by the real-time LC RT-PCR. As a result of the high sensitivity and specificity of the assay with a relatively rapid and simple procedure, the real-time LC RT-PCR will be useful as a routine assay for the clinical diagnosis of ARV infection.

Avian reovirus nonstructural protein microNS forms viroplasm-like inclusions and recruits protein sigmaNS to these structures

The M3 genome segment of avian reovirus 1733, which encodes the nonstructural protein microNS, is 1996 nucleotides long and contains a long open reading frame that is predicted to encode a polypeptide of 635 amino acid residues. Examination of the deduced amino acid sequence of microNS revealed the presence of two regions near its carboxyl terminus with a high probability of forming alpha-helical coiled coils. Expression of the M3 gene in both infected and transfected cells revealed that this gene specifies two protein isoforms that are recognized by a microNS-specific antiserum. Only the larger microNS isoform, but not the smaller one, interacts with the nonstructural protein sigmaNS in infected cells, suggesting that the two isoforms play different roles during avian reovirus infection. In the second part of this study, we show that microNS and the nonstructural protein sigmaNS colocalize throughout the viral life cycle in large and small phase-dense globular cytoplasmic inclusions, which are believed to be the sites of viral replication and assembly. Individual expression of these proteins in transfected cells of avian and mammalian origin revealed that while microNS is able to form inclusions in the absence of other viral proteins, sigmaNS distributes diffusely throughout the cytoplasm in the absence of microNS. These data suggest that microNS is the minimal viral factor required for inclusion formation during avian reovirus infection. On the other hand, our findings that sigmaNS associates with microNS in infected cells, and that sigmaNS colocalizes with microNS in viroplasm-like inclusions when the two proteins are coexpressed in transfected cells, suggest that microNS mediates the association of sigmaNS to inclusions in avian reovirus-infected cells.