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

Detection of avian reovirus (ARV) by ELISA based on recombinant σB, σC and σNS full-length proteins and protein fragments

Introduction. Avian reovirus (ARV) is associated with arthritis/tenosynovitis and malabsorption syndrome in chickens. The σC and σB proteins, both exposed to the virus capsid, are highly immunogenic and could form the basis for diagnostic devices designed to assess the immunological status of the flock.Gap Statement. Commercial ARV ELISAs cannot distinguish between vaccinated and infected animals and might not detect circulating ARV strains.Aim. We aimed to develop a customized test to detect the circulating field ARV strains as well as distinguish between vaccinated and unvaccinated animals.Methodology. We developed ELISA assays based on recombinant (r) σB, σC and the nonstructural protein σNS and tested them using antisera of vaccinated and unvaccinated chickens as well as negative controls. Fragments of σB and σC proteins were also used to study regions that could be further exploited in diagnostic tests.Results. Vaccinated and unvaccinated birds were positive by commercial ELISA, with no difference in optical density values. In contrast, samples of unvaccinated animals showed lower absorbance in the rσB and rσC ELISA tests and higher absorbance in the rσNS ELISA test than the vaccinated animals. Negative control samples were negative in all tests. Fragmentation of σB and σC proteins showed that some regions can differentiate between vaccinated and unvaccinated animals. For example, σB amino acids 128-179 (σB-F4) and σC amino acids 121-165 (σC-F4) exhibited 85 and 95% positivity among samples of vaccinated animals but only 5% and zero positivity among samples of unvaccinated animals, respectively.Conclusion. These data suggest that unvaccinated birds might have been exposed to field strains of ARV. The reduction in absorbance in the recombinant tests possibly reflects an increased specificity of our test since unvaccinated samples showed less cross-reactivity with the vaccine proteins immobilized on ELISAs. The discrepant results obtained with the protein fragment tests between vaccinated and unvaccinated animals are discussed in light of the diversity between ARV strains.

Molecular Detection and Genetic Characterization of Vertically Transmitted Viruses in Ducks

To investigate the distribution and genetic variation in four vertically transmitted duck pathogens, including duck hepatitis B virus (DHBV), duck circovirus (DuCV), duck hepatitis A virus 3 (DHAV-3), and avian reoviruses (ARV), we conducted an epidemiology study using PCR and RT-PCR assays on a duck population. We found that DHBV was the most prevalent virus (69.74%), followed by DuCV (39.48%), and then ARV (19.92%) and DHAV-3 (8.49%). Among the 271 duck samples, two, three or four viruses were detected in the same samples, indicating that the coinfection of vertical transmission agents is common in ducks. The genetic analysis results showed that all four identified DuCV strains belonged to genotype 1, the DHAV-3 strain was closely clustered with previously identified strains from China, and the ARV stain was clustered under genotype 1. These indicate that different viral strains are circulating among the ducks. Our findings will improve the knowledge of the evolution of DuCV, DHAV-3, and ARV, and help choose suitable strains for vaccination.

Avian Reoviruses in Poultry Farms from Brazil

Avian reovirus (ARV) is highly disseminated in commercial Brazilian poultry farms, causing arthritis/tenosynovitis, runting-stunting syndrome, and malabsorption syndrome in different meat- and egg-type birds (breeders, broilers, grillers, and layers). In Brazil, ARV infection was first described in broilers in the 1970s but was not considered an important poultry health problem for decades. A more concerning outcome of field infections has been observed in recent years, including condemnations at slaughterhouses because of the unsightly appearance of chicken body parts, mainly the legs. Analyses of the performance of poultry flocks have further evidenced economic losses to farms. Genetic and antigenic characterization of ARV field strains from Brazil demonstrated a high diversity of lineages circulating in the entire country, including four of the five main phylogenetic groups previously described (I, II, III, and V). It is still unclear if all of them are associated with different diseases affecting flocks' performance in Brazilian poultry. ARV infections have been controlled in Brazilian poultry farms by immunization of breeders and young chicks with classical commercial live vaccine strains (S1133, 1733, 2408, and 2177) used elsewhere in the Western Hemisphere. However, genetic and antigenic variations of the field isolates have prevented adequate protection against associated diseases, so killed autogenous vaccines are being produced from isolates obtained on specific farms. In conclusion, ARV field variants are continuously challenging poultry farming in Brazil. Epidemiological surveillance combined with molecular biological analyses from the field samples, as well as the development of vaccine strains directed toward the ARV circulating variants, are necessary to control this economically important poultry pathogen.

Genetic Analysis of Avian Reovirus Isolated from Chickens in Japan

Sigma C protein-coding sequences have been used to phylogenetically classify avian reovirus (ARV) strains. However, the relationship between serotype and phylogenetic cluster classification of the five prototype serotype strains of ARV in Japan has not been established. Thus, we used sigma C protein-coding sequences to characterize avian reoviruses (ARVs) isolated from chickens with tendonitis in Japan together with the five prototype serotype strains of ARV in Japan. Phylogenetic analysis of ARVs based on the sigma C protein-coding sequences revealed that the five prototype serotype strains of ARV were each classified into different, independent clusters. Two field isolates (JP/Tottori/2016 and JP/Nagasaki/2017) that were isolated from chickens with arthritis/tenosynovitis were classified into different clusters. JP/Tottori/2016 was classified into cluster VI with the CS-108 strain, and JP/Nagasaki/2017 was classified into cluster I with strain TS-142. Serologically, JP/Tottori/2016 was well-neutralized by antisera against the CS-108 strain, whereas JP/Nagasaki/2017 cross-reacted with antisera against both the CS-108 and TS-142 strains. Embryo lethality test revealed that the two field isolates induced 80% and 67% embryo mortality, respectively, whereas the five prototype strains induced 0%-33% embryo mortality. Our findings will contribute to understanding the characteristics of ARV strains in Japan.

Genotypic characterization and molecular evolution of avian reovirus in poultry flocks from Brazil

Avian reovirus (ARV) is one of the main causes of infectious arthritis/tenosynovitis and malabsorption syndrome (MAS) in poultry. ARVs have been disseminated in Brazilian poultry flocks in the last years. This study aimed to genotype ARVs and to evaluate the molecular evolution of the more frequent ARV lineages detected in Brazilian poultry-producing farms. A total of 100 poultry flocks with clinical signs of tenosynovitis/MAS, from all Brazilian poultry-producing regions were positive for ARV by PCR. Seventeen bird tissues were submitted to cell culture and ARV RNA detection/genotyping by two PCRs. The phylogenetic classification was based on σC gene alignment using a dataset with other Brazilian and worldwide ARVs sequences. ARVs were specifically detected by both PCRs from the 17 cell cultures, and σC gene partial fragments were sequenced. All these sequences were aligned with a total of 451 ARV σC gene data available in GenBank. Phylogenetic analysis demonstrated five well-defined clusters that were classified into lineages I, II, III, IV, and V. Three lineages could be further divided into sub-lineages: I (I vaccine, Ia, Ib), II (IIa, IIb, IIc) and IV (IVa and IVb). Brazilian ARVs were from four lineages/sub-lineages: Ib (48.2%), IIb (22.2%), III (3.7%) and V (25.9%). The Bayesian analysis demonstrated that the most frequent sub-lineage Ib emerged in the world around 1968 and it was introduced into Brazil in 2010, with increasing spread soon after. In conclusion, four different ARV lineages are circulating in Brazilian poultry flocks, all associated with clinical diseases. RESEARCH HIGHLIGHTS One-hundred ARV-positive flocks were detected in all main poultry-producing regions from Brazil. A large dataset of 468 S1 sequences was constructed and divided ARVs into five lineages. Four lineages/sub-lineages (Ib, IIb, III and V) were detected in commercial poultry flocks from Brazil. Brazilian lineages shared a low identity with the commercial vaccine lineage (I vaccine). Sub-lineage Ib emerged around 1968 and was introduced into Brazil in 2010.

Phenotypic, genotypic and antigenic characterization of emerging avian reoviruses isolated from clinical cases of arthritis in broilers in Saskatchewan, Canada

In recent years, emerging strains of pathogenic arthrogenic avian reovirus (ARV) have become a challenge to the chicken industry across USA and Canada causing significant economic impact. In this study, we characterized emerging variant ARV strains and examined their genetic and antigenic relationship with reference strains. We isolated 37 emerging variant ARV strains from tendons of broiler chickens with clinical cases of arthritis/tenosynovitis at commercial farms in Saskatchewan, Canada. Viral characterization using immunocytochemistry, gold-immunolabeling and electron microscopy revealed distinct features characteristic of ARV. Polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) analyses of the viral Sigma C gene revealed genetic heterogeneity between the field isolates. On phylogenetic analyses, the Sigma C amino acid sequences of the isolates were clustered into four distinct genotypic groups. These ARV field strains were genetically diverse and quite distant from the vaccine and vaccine related field strains. Antibodies produced against a commercial Reo 2177 ® vaccine did not neutralize these variants. Moreover, structure based analysis of the Sigma C protein revealed significant antigenic variability between the cluster groups and the vaccine strains. To the best of our knowledge, this is the first report on the genetic, phenotypic and antigenic characterization of emerging ARVs in Canada.

Genotyping and Classification of Tunisian Strains of Avian Reovirus using RT-PCR and RFLP Analysis

Since 1998, avian reovirus (ARV) infection has been detected in broiler and breeding chicken flocks in Tunisia. The genotype of avian reoviruses was established using simple and rapid approaches. Reverse transcription PCR (RT-PCR) on both sigma C (σC) and sigma B (σB)-encoding genes followed by restriction fragment length polymorphism (RFLP) analyses were used to better characterize Tunisian isolated strains. The RT-PCR amplified fragments of 738 and 540 bp for σC- and σB-encoding genes, respectively, of 15 ARV Tunisian strains. DNA fragments amplified from S 1133 vaccine and isolated strains were digested with different restrictions enzymes. RFLP on the σC gene indicated that the field isolates and the S 1133 vaccine strain have identical profiles when separately digested with TaqI, PstI, DdeI, and HincII. Considering the σB gene, RFLP profiles were identical with RsaI, BclI, DpnII, and NciI restriction enzymes for all the strains. However, using MseI and AciI enzymes, it was shown that all tested isolates could be clearly distinguished from the vaccine strain. ARV strains could be classified in groups with strong relatedness. Strain-typing based on cleavage site results are in agreement with ARV clustering based on nucleotide sequences of both the σC and σB genes. RT-PCR-RFLP provides a simple and a rapid approach for genotyping ARV isolates, especially when a large number of isolates are being studied. Additionally, this approach may also determine whether a new variant strain has been introduced into a flock or if a given virus strain is being spread from one flock to another.

RhoA/ROCK1 regulates Avian Reovirus S1133-induced switch from autophagy to apoptosis

BACKGROUND

Autophagy is an essential process in the control of cellular homeostasis. It enables cells under certain stress conditions to survive by removing toxic cellular components, and may protect cells from apoptosis. In the present study, the signaling pathways involved in ARV S1133 regulated switch from autophagy to apoptosis were investigated.

RESULTS

ARV S1133 infection caused autophagy in the early to middle infectious stages in Vero and DF1 cells, and apoptosis in the middle to late stages. Conversion of the autophagy marker LC3-I to LC3-II occurred earlier than cleavage of the apoptotic marker caspase-3. ARV S1133 also activated the Beclin-1 promoter in the early to middle stages of infection. Levels of RhoA-GTP and ROCK1 activity were elevated upon ARV S1133 infection, while inhibition of RhoA and ROCK1 reduced autophagy and subsequent apoptosis. Conversely, inhibition of caspase-3 did not affect the level of autophagy. Beclin-1 knockdown and treatment with autophagy inhibitors, 3-MA and Bafilomycin A1, suppressed ARV S1133-induced autophagy and apoptosis simultaneously, suggesting the shift from autophagy to apoptosis. A co-immunoprecipitation assay demonstrated that the formation of a RhoA, ROCK1 and Beclin-1 complex coincided with the induction of autophagy.

CONCLUSION

Our results demonstrate that RhoA/ROCK1 signaling play critical roles in the transition of cell activity from autophagy to apoptosis in ARV S1133-infected cells.

One-step real-time reverse transcription-PCR for the detection of turkey reoviruses

During late 2010 and early 2011, an unusual problem of lameness and swollen hock joints in commercial turkeys was reported in the upper Midwest, which continues to this day. The disease caused substantial economic losses to turkey producers. Reovirus was isolated from tendons and joint fluids of lame turkeys submitted to the Minnesota Veterinary Diagnostic Laboratory. This study was undertaken to develop a TaqMan real-time reverse transcription-PCR (rRT-PCR) assay for the early detection of turkey reoviruses (both enteric and lameness strains). A primer probe set was designed from the conserved region of the S4 segment of the turkey reovirus genome. The newly developed rRT-PCR was specific for the detection of turkey reoviruses. The detection limit of this assay was 10 genome copies per reaction. For the TARV-MN4 strain of turkey arthritis reovirus, one 50% tissue culture infectious dose was equivalent to 11.6 +/- 0.2 genome copies. The highest coefficient of variation for intraexperimental and interexperimental variability was 0.08 and 0.06, respectively, indicating the reproducibility of the assay. This new test should be useful for the detection of turkey enteric and arthritis reoviruses.

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.

Molecular characterization of avian reovirus isolates in Tunisia

BACKGROUND

Genotype analyses of avian reoviruses isolated from organ samples collected from chickens with suspicious clinical symptoms, between 1997-2008, was based on sequences for both σC and σB genes and aligned with those published in the Genbank, making it possible to carry out studies of molecular classification and relationships.

METHODS

The full length of the known variable protein σC and part of the σB encoding genes, were amplified with RT-PCR, using conserved primers. PCR products were sequenced and the sequences were analyzed and aligned with avian reovirus sequences from the Genbank database.

RESULTS

The sequences of σC-encoding genes of all the isolated strains indicated their close relationship with the American, Chinese and Indian strains. Taking the American strain S1133 as a reference, the two Tunisian isolates 97.1 and 97.2 showed some nucleotide substitutions. For isolate 97.1, the substitution was silent whereas for strain 97.2 the mutation was at the first position of the corresponding codon and induced the substitution of the amino acid encoded. For the σB-encoding gene, the sequences of the Tunisian strains showed mutations at positions two or three of the corresponding codons, inducing substitutions of amino acids at these positions. The phylogenic trees based on σC and σB encoding genes indicated closer relationship between Tunisian, American and Taiwanese isolates of genotype I.

CONCLUSION

Our study describes the genotype of avian reoviruses that are not yet well characterized genetically. The characterization and classification of these viruses might be significant for understanding the epidemiology of malabsorption syndrome and viral arthritis, and improving our knowledge of the genotype of strains circulating in Tunisian flocks. Furthermore, the study of their variable pathogenicity could be extremely important in the choice of the appropriate vaccine strain to control disease.

The genomic constellation of a novel avian orthoreovirus strain associated with runting-stunting syndrome in broilers

Avian orthoreoviruses (ARVs) are responsible for considerable economic losses in broiler chickens; yet, the genetic characterization of most ARV strains is limited to a few genes, and the full coding region has been determined for only S1133 and 138, two ARV strains associated with tenosynovitis. Recently, in parts of the United States, ARVs with novel neutralization antigen type were isolated from chickens afflicted with runting-stunting syndrome. One such strain, AVS-B, was selected for full genome sequencing and phylogenetic analysis. The complete genome was 23,494 bp in size and included 12 open reading frames. The lengths of the coding regions, as well as those of the 5' and 3' ends, were fairly well conserved between AVS-B and other reference strains. In pairwise comparisons to the S1133 and 138 strains, the AVS-B strain shared a wide range of sequence identities along each genome segment, i.e., a range of 54-55% for the σC coding region of S1 genome segment and 91-93% for the S2 genome segment. Phylogenetic analyses of individual genes of AVS-B did not identify any single common ancestor among more completely characterized ARV strains for which sequence data are available. One exception to this lack of identity was strain 138, which shared 90-93% nt identity with AVS-B along seven of ten genome segments; only M2, M3, and S1 segments of these strains shared lower sequence identities. Collectively, our analyses indicated that multiple reassortment events and strong divergence caused by the accumulation of point mutations could have led to the observed assortment and genetic heterogeneity of the AVS-B genome.

Proteasome inhibition reduces avian reovirus replication and apoptosis induction in cultured cells

The interplay between avian reovirus (ARV) replication and apoptosis and proteasome pathway was studied in cultured cells. It is shown that inhibition of the proteasome did not affect viral entry and host cell translation but had influence on ARV replication and ARV-induced apoptosis. Evidence is provided to demonstrate that ubiquitin-proteasome blocked ARV replication at an early step in viral life cycle. However, viral transcription and protein translation were also reduced markedly after addition of proteasome inhibitor MG132. Treatment of BHK-21 cells with the MG132 markedly decreased virus titer as well as prevented virus-induced apoptosis. The expression of ARV proteins sigmaC, sigmaA, and sigmaNS was also reduced markedly, suggesting that suppression of virus replication is due to down-regulation of these ARV proteins by ubiquitin-proteasome system. MG132 was also shown to suppress ARV sigmaC-induced phosphrylation of p53 on serine 46, caspase 3 activities, and DNA fragmentation leading to complete inhibition of ARV-induced apoptosis.

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-induced apoptosis related to tissue injury

Apoptosis plays an important role in pathogenesis of many viral infections. Infection of chicken with avian reovirus S1133 causes tissue injury related to virus-induced apoptosis. To determine whether avian reovirus (ARV) induced apoptosis in chicken tissues, six 3-week-old specific pathogen free White Leghorn chicks were inoculated with ARV S1133. Tissues were dual-labelled for the simultaneous detection of viral antigen containing and apoptotic cells. DNA laddering was detected in ARV-infected but not mock-infected chicken tissues. Dual-labelling assay revealed that the majority of antigen-expressing cells were not apoptotic. Surprisingly, some apoptotic but non-antigen-expressing cells were frequently located in the vicinity of antigen-expressing cells. Syncytium formation in ARV-infected chicken tissues undergoing apoptosis was apparent, suggesting a correlation between virus replication and apoptosis in chicken tissues.

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 σC 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.

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.

Sequence and phylogenetic analysis of P10- and P17-encoding genes of avian reovirus

Avian reovirus (ARV) causes viral arthritis, chronic respiratory diseases, and malabsorption syndrome. The P10 protein is a viroporin and induces cell fusion, whereas the biological function of P17 protein is completely unknown. In this study, the nucleotide sequences of the P10- and P17-encoding genes from 17 field isolates and vaccine strains of ARV isolated over a 23-year period from distinct geographic locations were analyzed to define phylogenetic profiles and to study sequence variability and genetic evolution. These genes displayed the signs of a high level of sequence divergence and have evolved into five distinct lineages, respectively. The P17-encoding gene showed higher sequence divergence than that of P10-encoding gene. Our results indicated that synonymous substitutions predominate over nonsynonymous substitutions in both genes. Comparison of P10 and P17 gene phylograms with those of S-class genes revealed distinct evolutionary patterns, indicating that P10 and P17 evolve in an independent manner. Comparative sequence analysis also showed extensive sequence divergence between ARV and other orthoreoviruses. The phylogenetic analysis of P10- and P17-encoding genes revealed that diversity within both genes is neither dependent of viral serotypes nor correlated with the disease states caused by avian reovirus.

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.

Application of RT-PCR for the detection of avian reovirus contamination in avian viral vaccines

An efficient procedure for the detection of avian reovirus (ARV)-specific RNA sequences in veterinary immunological medicinal products using reverse transcriptase polymerase chain reaction (RT-PCR) is described. Four ARV vaccine strains (1133, 1733, 2408 and Olson WVU2937), two ATCC strains (VR826 and VR856) as well as several ARV field isolates obtained from domestic, wild and pet birds could be easily detected with S2- and S4-specific primers. The identity of the amplified fragments was confirmed by restriction endonuclease analysis and sequence analysis. Furthermore, not only the starting substrates used for the production of a vaccine, but also additives and the manufacturing process (matrix effects) can influence the results. These RT-PCRs have been useful for screening poultry vaccines for extraneous ARV in the quality control of biologicals used in veterinary medicine.