ObjectiveEstimate the seroprevalence of influenza A virus in various commercial poultry farms and evaluate specific risk factors as well as analyze their genetic nature using molecular assays.Materials and MethodsThis report summarizes the findings of a national survey realized from October 2010 to May 2011 on 800 flocks in 20 governorates. Serum samples were screened for the presence of specific influenza virus antibodies using cELISA test. Additionally, swab samples were tested by real time and conventional RT-PCR and compared with results obtained by others assays. Phylogenetic and genetic analyses of the glycoproteins were established for some strains.ResultsOut of the 800 chicken and turkey flocks tested by cELISA, 223 showed positive anti-NP antibodies (28.7%, 95% CI: 25.6–32.1). Significantly higher seroprevalence was found among the coastal areas compared to inland and during the autumn and winter. Broiler flocks showed significantly lower seroprevalence than layers and broiler breeders. The influenza virus infection prevalence increased after the laying phase among layer flocks. In addition, AIV seropositivity was significantly associated with low biosecurity measures. The Ag EIA and rRT-PCR tests revealed significantly higher numbers of AI positive samples as compared to cell cultures or egg inoculation. All new strains were subtyped as H9N2 by real time and conventional RT-PCR. Drift mutations, addition or deletion of glycosylation sites were likely to have occurred in the HA and NA glycoproteins of Tunisian strains resulting in multiple new amino acid substitutions. This fact may reflect different evolutionary pressures affecting these glycoproteins. The role of these newly detected substitutions should be tested.ConclusionOur findings highlight the potential risk of AIV to avian health. Strict enforcement of biosecurity measures and possible vaccination of all poultry flocks with continuous monitoring of poultry stations may ensure reduction of AIV prevalence and avoid emergence of more pathogenic strains.
Three infectious bronchitis virus (IBV) strains, isolated from suspected Tunisian broiler flocks, were characterized as variant viruses using genotyping and serotyping techniques. They were compared with commonly used vaccine strains, including 793/B, D274, and Massachusetts types. Reverse transcription-PCR-restriction fragment length polymorphism, nucleotide sequencing, and GenBank BLAST database analyses of the hypervariable region of the S1 subunit of the virus spike gene showed that the three isolates, designated TN20/00, TN200/01, and TN335/01, share from 64% to 82% homologies between each other but are very different from the H120 strain, the only infectious bronchitis vaccine used in Tunisia. In addition, they showed from 57% to 78% similarities with the European genotypes, including D274 and 793/B. Phylogenetic data allowed classification of the three Tunisian isolates as new genotypes placed inside the same genetic group as the CR88121 and D274 genotypes but very distant from the Massachusetts genotype. Cross-virus neutralization tests confirmed the genotyping results and showed that both TN200/01 and TN335/01 isolates are serologically related, whereas the TN20/00 is closer to TN335/01 than to TN200/01. Moreover, all three Tunisian isolates are closely related to the European variant serotypes, including the CR88121 and the D274 strains, but none is serologically related to the H120 vaccine strain. These data demonstrated, for the first time in Tunisia, the cocirculation of IBV variant serotypes along with the Massachusetts type, causing severe clinical diseases and high economic losses to the poultry industry.
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.
BackgroundGenotype 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.MethodsThe 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.ResultsThe 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.ConclusionOur 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.
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