Molecular characterization of a unique variant of avian infectious bronchitis virus in Tunisia.

Avian infectious bronchitis virus (IBV) is responsible of significant economic losses for poultry industry around the world, through evolution of its pathogenicity, inadequacy of vaccines, and virus evasion. Such evasion is related to the unstable nature of its RNA, in particular the S glycoprotein encoding gene, which raises great challenges with regard to the control of the disease, along with the lack of proof reading mechanisms of the RNA polymerase. The emergence of new variants might be a reason for the endemic outbreaks that are being reported in Tunisia, in addition to poor vaccination techniques and ineffective prophylactic programs. In the present study, partial nucleotide sequences of the S1 glycoprotein gene and the 3'-untranslated region (UTR) of 2 Tunisian isolates, TN1011/16 and TN1012/16, identified in 2016, were determined. Specific mutations were found in S1 gene as well as in 3'UTR region. Phylogenetic analysis of the S1 nucleotide sequences showed that both isolates are closely related to the Algerian strains, and formed a common cluster within the genotype I. In addition, these isolates were non-recombinant ones, confirming that they are unique variants. Based on their S1 gene sequences, TN1011/16 and TN1012/16 strains were distant from the H120 vaccine strain, commercially used in Tunisia along with the variant vaccine 793B type (4/91). A comparison between nucleotide sequences of their 3'UTR region and S1 gene showed a difference in IBV classification. The obtained results have confirmed that the IBVsequence continues to drift and brings valuable information in relation with its evolution, vaccine development and better control of the disease.

S1 gene sequence analysis of new variant isolates of avian infectious bronchitis virus in Tunisia.

PURPOSE: Tissue samples were collected from suspected broiler flocks showing respiratory signs to identify infectious bronchitis virus (IBV), characterize emerging field strains, and study their relationships with the Massachusetts H120 strain, the only IB vaccine used in Tunisia. SAMPLES AND METHODS: Several IBV isolates were identified from field samples collected from flocks located in different regions in the northeast of Tunisia. The IBV isolates were characterized and compared to commonly used vaccine strains (including 793B, D274, and H120 types), other reference IBV strains from Europe, and the recently characterized Tunisian field variants TN20/00, TN200/01, and TN335/01. Reverse transcription-polymerase chain reaction and nucleotide sequencing analyses of the hypervariable regions of the S1 gene were carried out. RESULTS: Four new IBV variants were isolated during the period 2007-10 and were designated TN295/07, TN296/07, TN556/07, and TN557/07. The amino acid sequence data showed 100% similarity between TN295/07 and TN296/07, suggesting that these two isolates are identical and belong to the same genotype. Similar results were demonstrated for TN556/07 and TN557/07. Sequence identity values indicated that TN296/07 and TN556/07 share 55% amino acid homologies between each other, but are very different from the reference IBV serotypes, in particular the H120 strain. It was also shown that they have 50%-77% similarities with the Tunisian virus isolated between 2000 and 2001. Phylogenetic clustering allowed classification of these Tunisian isolates as new genotypes that are closer to TN200/01, TN335/01 Tunisian field variants, and Italy02 variant than MassH120 vaccine strain. CONCLUSION: S1 sequence analyses confirmed the cocirculation of H120 vaccine strain with novel IBV variants isolated from Tunisian field.