Chickens Expressing IFIT5 Ameliorate Clinical Outcome and Pathology of Highly Pathogenic Avian Influenza and Velogenic Newcastle Disease Viruses.

Innate antiviral immunity establishes first line of defense against invading pathogens through sensing their molecular structures such as viral RNA. This antiviral potential of innate immunity is mainly attributed to a myriad of IFN-stimulated genes (ISGs). Amongst well-characterized ISGs, we have previously shown that antiviral potential of chicken IFN-induced proteins with tetratricopeptides repeats 5 (chIFIT5) is determined by its interaction potential with 5'ppp containing viral RNA. Here, we generated transgenic chickens using avian sarcoma-leukosis virus (RCAS)-based gene transfer system that constitutively and stably express chIFIT5. The transgenic chickens infected with clinical dose (EID50 104 for HPAIV and 105 EID50 for vNDV) of high pathogenicity avian influenza virus (HPAIV; H5N1) or velogenic strain of Newcastle disease virus (vNDV; Genotype VII) showed marked resistance against infections. While transgenic chickens failed to sustain a lethal dose of these viruses (EID50 105 for HPAIV and 106 EID50 for vNDV), a delayed and lower level of clinical disease and mortality, reduced virus shedding and tissue damage was observed compared to non-transgenic control chickens. These observations suggest that stable expression of chIFIT5 alone is potentially insufficient in providing sterile protection against these highly virulent viruses; however, it is sufficient to ameliorate the clinical outcome of these RNA viruses. These findings propose the potential of innate immune genes in conferring genetic resistance in chickens against highly pathogenic and zoonotic viral pathogens causing sever disease in both animals and humans.

Infectivity of wild bird-origin avian paramyxovirus serotype 1 and vaccine effectiveness in chickens.

Newcastle disease virus, a prototype avian paramyxovirus serotype 1 (APMV-1), causes economically devastating disease in avian species around the world. Newcastle disease is enzootic in Pakistan and recurrent outbreaks are frequent in multiple avian species even after continuous and extensive use of vaccines. A number of APMV-1 and pigeon paramyxovirus serotype 1 (PPMV-1) strains have been isolated and genetically characterized in recent years. However, the impact of recently characterized wild bird-origin APMVs in domestic poultry, and the potency of routinely used vaccines against these novel and genetically diverse viruses remain unknown. Here, we applied next-generation sequencing for unbiased complete genome characterization of APMV-1 and PPMV-1 strains isolated from clinically diseased peacocks (Pavocristatus) and pigeons (Columbalivia), respectively. Global phylodynamics and evolutionary analysis demonstrates Pigeon/MZS-UVAS-Pak/2014 is clustered into lineage 4 (or genotype VI) and Peacock/MZS-UVAS-Pak/2014 into lineage 5 (or genotype VII). The genomes of both isolates encoded for polybasic residues (112RRQKR↓F117) at the fusion protein cleavage motif along with a number of important substitutions in the surface glycoproteins compared with the vaccine strains. Clinicopathological and immunological investigations in domesticated chickens indicate that these isolates can potentially transmit between tested avian species, can cause systemic infections, and can induce antibodies that are unable to prevent virus shedding. Collectively, the data from these genomic and biological assessments highlight the potential of wild birds in transmitting APMVs to domesticated chickens. The study also demonstrates that the current vaccine regimens are incapable of providing complete protection against wild bird-origin APMVs and PPMVs.