The sequence and phylogenetic analysis of avian reovirus genome segments M1, M2, and M3 encoding the minor core protein muA, the major outer capsid protein muB, and the nonstructural protein muNS.

The sequences and phylogenetic analyses of the M-class genome segments of 12 avian reovirus strains are described. The S1133 M1 genome segment is 2283 base pairs long, encoding a protein muA consisted of 732 amino acids. Each M2 or M3 genome segment of 12 avian reovirus strains is 2158 or 1996 base pairs long, respectively, encoding a protein muB or muNS consisted of 676 and 635 amino acids, respectively. The S1133 genome segment has the 5' GCUUUU terminal motif, but each M2 and M3 genome segment displays the 5' GCUUUUU terminal motif which is common to other known avian reovirus genome segments. The UCAUC 3'-terminal sequences of the M-class genome segments are shared by both avian and mammalian reoviruses. Noncoding regions of both 5'- and 3'-termini of the S1133 M1 genome segment consist of 12 and 72 nucleotides, respectively, those of each M2 genome segment consist of 29 and 98 nucleotides, respectively, and those of each M3 genome segment are 24 and 64 nucleotides, respectively. Analysis of the average degree of the M-class gene and the deduced mu-class protein sequence identities indicated that the M2 genes and the muB proteins have the greatest level of sequence divergence. Computer searches revealed that the muA possesses a sequence motif (NH(2)-Leu-Ala-Leu-Asp-Pro-Pro-Phe-COOH) (residues 458-464) indicative of N-6 adenine-specific DNA methylase. Examination of the muB amino acid sequences indicated that the cleavage site of muB into muBN and muBC is between positions 42 and 43 near the N-terminus of the protein, and this site is conserved for each protein. During in vitro treatment of virions with trypsin to yield infectious subviral particles, both the N-terminal fragment delta and the C-terminal fragment phi were shown to be generated. The site of trypsin cleavage was identified in the deduced amino acid sequence of muB by determining the amino-terminal sequences of phi proteins: between arginine 582 and glycine 583. The predicted length of delta generated from muBC is very similar to that of delta generated from mammalian reovirus mu1C. Taken together, protein muB is structurally, and probably functionally, similar to its mammalian homolog, mu1. In addition, two regions near the C-terminal and with a propensity to form alpha-helical coiled-coil structures as previously indicated are observed for each protein muB. Phylogenetic analysis of the M-class genes revealed that the predicted phylograms delineated 3 M1, 5 M2, and 2 M3 lineages, no correlation with serotype or pathotype of the viruses. The results also showed that M2 lineages I-V consist of a mixture of viruses from the M1 and M3 genes of lineages I-III, reflecting frequent reassortment of these genes among virus strains.

Avian reovirus replication in mononuclear phagocytes in chicken footpad and spleen after footpad inoculation.

Circulating monocytes and tissue macrophages were suggested to be susceptible to avian reovirus (ARV) infection. To determine if ARV infects and replicates in mononuclear phagocytes (KUL01-positive cells), we infected 3-day-old specific-pathogen-free chickens with ARV strain 2408 by inoculation of the left footpad. The left footpads and spleens were collected for analysis at 1.5 and 2.5 d after inoculation. Replication of ARV in the footpad and spleen was demonstrated by detection of the viral protein σNS using immunohistochemical testing and viral S1 RNA expression by real-time quantitative polymerase chain reaction (qPCR). Furthermore, immunofluorescent double-staining assay of cytocentrifuged cells and cryosections of the footpad and spleen for the viral protein σNS and the surface marker recognized by monoclonal antibody (MAb) KUL01 indicated that KUL01-positive cells costained with MAb H1E1, which recognizes ARV protein σNS. In addition, more ARV S1 RNA was measured by qPCR in the KUL01-positive cell samples prepared from the footpad or spleen 1.5 d after inoculation compared with non-KUL01-positive cell samples. The amounts of ARV S1 RNA in the spleen were significantly lower (P < 0.05) than the amounts in the footpad 1.5 d after inoculation. The results suggest that ARV infects mononuclear phagocytes and then replicates within these cells before migrating to the spleen, where it infects and replicates in KUL01-positive cells.

Il a été suggéré que les monocytes circulants et les macrophages tissulaires étaient sensibles à une infection par le reovirus aviaire (ARV). Afin de déterminer si l'ARV infecte et se réplique dans les phagocytes mononucléaires (cellules KUL01-positives), nous avons infecté des poussins exempts d'agents pathogènes spécifiques âgés de 3 j avec la souche 2408 d'ARV par inoculation dans le coussinet plantaire gauche. Les coussinets plantaires et les rates furent prélevés pour analyse aux jours 1,5 et 2,5 suivant l'inoculation. La réplication d'ARV dans le coussinet plantaire et la rate fut démontrée par détection de la protéine virale σNS par épreuve immunohistochimique et l'expression d'ARN S1 viral par réaction d'amplification en chaîne par la polymérase en temps réel (qPCR). De plus, l'épreuve d'immunofluorescence par double coloration de cellules cytocentrifugées et de coupes congelées du coussinet plantaire et de la rate pour la protéine virale σNS et le marqueur de surface reconnu par l'anticorps monoclonal (AcMo) KUL01 indiquait que les cellules positives pour KUL01se co-coloraient avec l'AcMo H1E1, qui reconnait la protéine σNS de l'ARV. Également, plus d'ARN S1 d'ARV était mesuré par qPCR dans les échantillons de cellules KUL01 positives préparés à partir de coussinets plantaires ou de rates 1,5 j après l'inoculation comparativement à des échantillons de cellules KUL01 négatives. Les quantités d'ARN S1 d'ARV dans la rate étaient significativement plus basses (P < 0,05) que les quantités dans les coussinets plantaires 1,5 j après l'inoculation. Les résultats suggèrent que l'ARV infecte les phagocytes mononucléaires et par la suite se répliquent dans ces cellules avant de migrer à la rate, où il infecte et se réplique dans les cellules KUL01-positives.(Traduit par Docteur Serge Messier).

Potentiation of cell-mediated immune responses against recombinant HN protein of Newcastle disease virus by recombinant chicken IL-18.

In this study, recombinant fowlpox viruses (rFPV/HN) expressing Newcastle disease virus (NDV) HN protein and rFPV/HN/chIL-18 co-expressing chicken IL-18 (chIL-18) and HN protein have been constructed and characterized. The co-expressed rHN/chIL-18 antigen or rchIL-18, expressed by our previous construct rFPV/chIL-18 and co-administered with NDV rHN, was assessed for its immunostimulatory activities and protection against NDV challenge in 2-week-old chickens. Chickens were vaccinated, intramuscularly, with various amounts of rHN or rHN/chIL-18 mixed with mineral oil. Production of hemagglutination-inhibition (HI) antibody depended on the concentration of the injected rHN or rHN/chIL-18. The lower HI antibody titers were obtained in chickens group rHN/chIL-18/6 and rHN/chIL-18/7, receiving 50 ng rHN/16.5 ng chIL-18 with mineral oil and 20 ng rHN/6.6 ng chIL-18 with mineral oil, respectively, compared to those in chickens rHN/6 and rHN/7, respectively receiving 50 ng and 20 ng rHN with mineral oil alone. However, the same protection rates were obtained from chickens in groups rHN/chIL-18/6 and rHN/6. Chicken groups rHN/chIL-18/7 and rHN/chIL-18/8 showed higher protective achievements than those in groups rHN/7 and rHN/8, respectively. When rchIL-18 was co-injected with 20ng rHN plus mineral oil, low level of HI antibody titer was produced; whereas, higher level of IFN-γ production and full protection rates were obtained. On the other hand, lower levels of IFN-γ production and lower protection rate (67%) were obtained in chickens injected with the same amount of rHN with mineral oil alone. Similar results were obtained when 10 ng rHN was used. Thus, when the concentration of rHN decreased to 50 ng or less, rchIL-18 reduced HI antibody production. The increase in IFN-γ production suggested that the enhancement of the cell-mediated immunity might confer the protection from NDV challenge, even accompanied with low HI antibody induction.

Adjuvant activity of chicken interleukin-12 co-administered with infectious bursal disease virus recombinant VP2 antigen in chickens.

A recombinant fowlpox virus (rFPV/VP2) expressing infectious bursal diseases virus (IBDV) VP2 gene has been constructed. After purification and identification of rFPV/VP2, the adjuvant activity of the recombinant chicken IL-12 (rchIL-12), synthesized by our previous construct of rFPV/chIL-12, in rFPV/VP2-expressed rVP2 antigen was assessed in one-week-old specific-pathogen free chickens. The results indicated that rchIL-12 alone or rchIL-12 plus mineral oil (MO) co-administered with rVP2 antigen significantly enhanced the production of serum neutralization (SN) antibody against IBDV, compared to those with MO alone. The SN titers in groups receiving rVP2 antigen with MO alone were more inconsistent after vaccination. On the other hand, rchIL-12 significantly stimulated IFN-γ production in serum and in splenocyte cultured supernatant, suggesting that rchIL-12 alone or plus MO significantly induced a cell-mediated immune response. Finally, bursal lesion protection from very virulent IBDV (vvIBDV) challenge in chickens receiving rVP2 antigen with rchIL-12 alone or plus MO was much more effective than that with MO alone at two weeks after boosting. Taken together, rchIL-12 alone augmented in vivo the induction of a primary and also a secondary SN antibody production and a cell-mediated immunity against IBDV rVP2 antigen, which conferred the enhancement of bursal lesion protective efficacy from vvIBDV challenge. These data indicated that a potential for chIL-12 as immunoadjuvant for chicken vaccine development such as IBDV rVP2 antigen.

Immunoadjuvant activities of a recombinant chicken IL-12 in chickens vaccinated with Newcastle disease virus recombinant HN protein.

Recombinant fowlpox virus (rFPV/HN) expressing Newcastle disease virus (NDV) HN gene and rFPV/HN/chIL-12 co-expressing chicken IL-12 (chIL-12) and HN (rHN/chIL-12) genes have been characterized. rHN/chIL-12 or rchIL-12, expressed by our previous construct rFPV/chIL-12, co-administered with rHN was assessed for adjuvant activities of chIL-12. Chickens were vaccinated with various amounts of rHN/chIL-12 mixed with mineral oil (MO), intramuscularly. Levels of hemagglutination-inhibition (HI) antibody production depended on the concentration of the injected rHN or rHN/chIL-12. The lower HI antibody titers were obtained in chicken groups rHN/chIL-12/7-rHN/chIL-12/9, receiving 60ng rHN/8ng chIL-12 with MO, 30ng rHN/4ng chIL-12 with MO or 15ng rHN/2ng chIL-12 with MO, respectively, compared to those in chicken groups rHN/7-rHN/9, receiving rHN with MO alone. However, chickens in group rHN/chIL-12/7 or rHN/chIL-12/8 and rHN with MO alone showed the same effective protection. Chicken group rHN/chIL-12/9 was even more protective than that in group rHN/9. When rchIL-12 was co-injected with 15ng rHN plus MO, chickens produced low levels of HI antibody titers; while higher levels of IFN-γ production and an effective protection rate (83%) were obtained. On the other hand, low levels of IFN-γ production and low protection response (50%) were obtained in chickens injected with rHN with MO alone. Taken together, when the concentration of rHN decreased to certain levels, rchIL-12 reduced HI antibody production. The increase in the induction of IFN-γ production might suggest the enhancement of the cell-mediated immunity which conferred the protection from the NDV challenge.