Genetic and biological characterizations of a Newcastle disease virus from swine in China

Epitope Peptide-Based Predication and Other Functional Regions of Antigenic F and HN Proteins of Waterfowl and Poultry Avian Avulavirus Serotype-1 Isolates From Uganda

Uganda is a Newcastle disease (ND) endemic country where the disease is controlled by vaccination using live LaSota (genotype II) and I₂ (genotype I) vaccine strains. Resurgent outbreak episodes call for an urgent need to understand the antigenic diversity of circulating wild Avian Avulavirus serotype-1 (AAvV-1) strains. High mutation rates and the continuous emergence of genetic and antigenic variants that evade immunity make non-segmented RNA viruses difficult to control. Antigenic and functional analysis of the key viral surface proteins is a crucial step in understanding the antigen diversity between vaccine lineages and the endemic wild ND viruses in Uganda and designing ND peptide vaccines. In this study, we used computational analysis, phylogenetic characterization, and structural modeling to detect evolutionary forces affecting the predicted immune-dominant fusion (F) and hemagglutinin-neuraminidase (HN) proteins of AAvV-1 isolates from waterfowl and poultry in Uganda compared with that in LaSota vaccine strain. Our findings indicate that mutational amino acid variations at the F protein in LaSota strain, 25 poultry wild-type and 30 waterfowl wild-type isolates were distributed at regions including the functional domains of B-cell epitopes or N-glycosylation sites, cleavage site, fusion site that account for strain variations. Similarly, conserved regions of HN protein in 25 Ugandan domestic fowl isolates and the representative vaccine strain varied at the flanking regions and potential linear B-cell epitope. The fusion sites, signal peptides, cleavage sites, transmembrane domains, potential B-cell epitopes, and other specific regions of the two protein types in vaccine and wild viruses varied considerably at structure by effective online epitope prediction programs. Cleavage site of the waterfowl isolates had a typical avirulent motif of ¹¹¹GGRQGR'L¹¹⁷ with the exception of one isolate which showed a virulent motif of ¹¹¹GGRQKR'F¹¹⁷. All the poultry isolates showed the ¹¹¹GRRQKR'F¹¹⁷ motif corresponding to virulent strains. Amino acid sequence variations in both HN and F proteins of AAvV-1 isolates from poultry, waterfowl, and vaccine strain were distributed over the length of the proteins with no detectable pattern, but using the experimentally derived 3D structure data revealed key-mapped mutations on the surfaces of the predicted conformational epitopes encompassing the experimental major neutralizing epitopes. The phylogenic tree constructed using the full F gene and partial F gene sequences of the isolates from poultry and waterfowl respectively, showed that Ugandan ND aquatic bird and poultry isolates share some functional amino acids in F sequences yet do remain unique at structure and the B-cell epitopes. Recombination analyses showed that the C-terminus and the rest of the F gene in poultry isolates originated from prevalent velogenic strains. Altogether, these could provide rationale for antigenic diversity in wild ND isolates of Uganda compared with the current ND vaccine strains.

Zoonotic potential of Newcastle disease virus: Old and novel perspectives related to public health

Newcastle disease virus (NDV) has a worldwide distribution, causing lethal infection in a wide range of avian species. Affected birds develop respiratory, digestive and neurologic symptoms with profound immunosuppression. Mild systemic Newcastle disease (ND) infection restricted to the respiratory and neurological systems can be observed in humans and other non-avian hosts. Evidence of ND infection and its genome-based detection have been reported in Bovidae (cattle and sheep), Mustelidae (mink), Cercetidae (hamster), Muridae (mice), Leporidae (rabbit), Camelidae (camel), Suidae (pig), Cercophithecidae (monkeys) and Hominidae (humans). Owing to frequent ND outbreaks in poultry workers, individuals engaged in the veterinary field, including poultry production or evisceration and vaccine production units have constantly been at a much higher risk than the general population. A lethal form of infection has been described in immunocompromised humans and non-avian species including mink, pig and cattle demonstrating the capability of NDV to cross species barriers. Therefore, contact with infectious material and/or affected birds can pose a risk of zoonosis and raise public health concerns. The broad and expanding host range of NDV and its maintenance within non-avian species hampers disease control, particularly in disease-endemic settings.

A comparative phylogenomic analysis of avian avulavirus 1 isolated from non-avian hosts: conquering new frontiers of zoonotic potential among species

A number of avian avulavirus 1 (AAvV 1) isolates have been reported from avian and non-avian hosts worldwide with varying clinical consequences. In this regard, robust surveillance coupled with advanced diagnostics, genomic analysis, and disease modelling has provided insight into the molecular epidemiology and evolution of this virus. The genomic and evolutionary characteristics of AAvV 1 isolates originating from avian hosts have been well studied, but those originating from non-avian hosts have not. Here, we report a comparative genomic and evolutionary analysis of so-far reported AAvV 1 isolates originating from hosts other than avian species (humans, mink and swine). Phylogenetic analysis showed that AAvV 1 isolates clustered in five distinct genotypes (I, II, VI, VII and XIII). Further analysis revealed clustering of isolates into clades distant enough to be considered distinct subgenotypes, along with a few substitutions in several significant motifs. Although further investigation is needed, the clustering of AAvV 1 strains isolated from non-avian hosts into novel subgenotypes and the presence of substitutions in important structural and biological motifs suggest that this virus can adapt to novel hosts and therefore could have zoonotic potential.

The Natural Compound Homoharringtonine Presents Broad Antiviral Activity In Vitro and In Vivo

To complement traditional antivirals, natural compounds that act via host targets and present high barriers to resistance are of increasing interest. In the work reported here, we detected that homoharringtonine (HHT) presents effective antiviral activity. HHT completely inhibited infections of vesicular stomatitis virus (VSV), Newcastle disease virus (NDV), and porcine epidemic diarrhea virus (PEDV) at concentrations of 50, 100, and 500 nM in cell cultures, respectively. Treatment with HHT at doses of 0.05 or 0.2 mg/kg significantly reduced viral load and relieved severe symptoms in PEDV- or NDV-infected animals. HHT treatment, however, moderately inhibited avian influenza virus (AIV) infection, suggesting its potent antiviral action is restricted to a number of classes of RNA viruses. In this study, we also observed that HHT actively inhibited herpes simplex virus type 1 (HSV-1) replication with a 50% inhibitory concentration (IC50) of 139 nM; the treatment with HHT at 1000 nM led to reductions of three orders of magnitude. Moreover, HHT antagonized the phosphorylation level of endogenous and exogenous eukaryotic initiation factor 4E (p-eIF4E), which might regulate the selective translation of specific messenger RNA (mRNA). HHT provides a starting point for further progress toward the clinical development of broad-spectrum antivirals.

Characterization of Colombian serotype 1 avian paramyxoviruses, 2008-2010

Newcastle disease (ND) still remains one of the most important diseases affecting domestic poultry in Colombia. Here, for the first time, we report on the molecular characterization of 12 virulent and 12 avirulent or lentogenic avian paramyxovirus type 1 (APMV-1) strains that were isolated from commercial, backyard, and game poultry in Colombia from 2008 to 2010. The 12 virulent isolates had a fusion (F) protein cleavage site with basic amino acids at positions 113, 115, and 116 and a phenylalanine at position 117 (¹¹²RRQKR*F¹¹⁷), characteristic of virulent strains. The remaining 12 isolates had the F protein cleavage sites ¹¹²GKQGR*L¹¹⁷ or ¹¹²GRQGR*L¹¹⁷ typical of avirulent or lentogenic APMV-1 strains. Phylogenetic analysis of full-length F genes of all isolates was performed, and based on the recently proposed criteria for classification of APMV-1 strains, the 24 Colombian isolates were found to belong to class II viruses and clustered into four different genotypes. Ten virulent isolates clustered with genotype VII (sub-genotype VIId), seven lentogenic strains within genotype II, five lentogenic strains with genotype I (sub-genotype Ia), and two virulent isolates within genotype XII. Our data provide essential information on the genetic diversity of AMPV-1 isolates circulating in Colombia.

Cellular protein GLTSCR2: A valuable target for the development of broad-spectrum antivirals

Viral infection induces translocation of the nucleolar protein GLTSCR2 from the nucleus to the cytoplasm, resulting in attenuation of the type I interferon IFN-β. Addressing the role of GLTSCR2 in viral replication, we detect that knocking down GLTSCR2 by shRNAs results in significant suppression of viral replication in mammalian and chicken cells. Injection of chicken embryo with the GLTSCR2-specific shRNA-1370 simultaneously or 24 h prior to infection with Newcastle disease virus (NDV) substantially reduces viral replication in chicken embryo fibroblasts. Injection of shRNA-1370 into chicken embryo also reduces the replication of avian influenza virus (AIV). In contrast, GLTSCR2-derived protein G4-T, forming α-helical dimers, increases replication of seven various DNA and RNA viruses in cells. Our studies reveal that alteration of the function of cellular GLTSCR2 plays a role in supporting viral replication. GLTSCR2 should be seriously considered as a therapeutic target for developing broad spectrum antiviral agents to effectively control viral infection.

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G4-T, a protein that mimics GLTSCR2, folds in an α-helical dimer structure.

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G4-T suppresses type I IFN antiviral response.

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G4-T promotes efficient proliferation of DNA and RNA viruses belonging to 7 families.

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GLTSCR2-specific shRNA reduces the infection of viruses in mammalian and chicken cells.

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Injection of GLTSCR2-specific shRNA into chicken embryo reduces the replication of NDV and AIV.

Genetic characterization and pathogenicity assessment of Newcastle disease virus isolated from wild peacock

The continued spread and occurrence of Newcastle disease virus (NDV) has posed potential threat to domestic poultry industry around the globe. Mainly, wild avian species has always been implicated for the natural reservoir for virus and spread of the disease. In the present study, we report the isolation of Newcastle disease virus (NDV/Peacock/India/2012) in necropsy brain tissue sample of wild peacock from North India. Complete genome of the virus was found to be 15,186 nucleotides (nts) with six genes in order of 3'-N-P-M-F-HN-L-5', which was limited by 55-nts leader region at the 3' end and a 114-nts trailer sequence at 5' end. Sequence analysis of fusion protein revealed the dibasic amino acid cleavage site (112)R-R-Q-K-R-F(117), a characteristic motif of virulent virus. Phylogenetic analysis placed the isolate in genotype II of Newcastle disease virus showing the lowest mean percent divergence (6 %) with other genotype II counterparts. The isolate was characterized as mesogenic (intermediate pathotype) based on the mean death time (63 h) in embryonated chicken eggs and the intra-cerebral pathogenicity index (1.40) in day-old chicks. The report emphasizes the dynamic ecology of NDV strains circulating in a wild avian host during the outbreak of 2012 in North India. Further the genotypic and pathotypical characterizations of the isolate could help in development of homologous vaccine against NDV strain circulating in avian population.

Genomic characterisation of a lentogenic Newcastle disease virus strain HX01 isolated from sick pigs in China

This paper describes the complete genome sequence of HX01, an isolate of the Newcastle disease virus (NDV) collected from a swine disease outbreak. The genome is 15,186 nt long and consists of six genes in the order of 3'-NP-P-M-F-HN-L-5'. This genome has the same length as the old NDV genotypes (I-IV), whereas the new NDV genotypes (V-IX) are 15,192 nt long. Compared with the genomic sequences of the reference NDV strains, the HX01 genome is highly similar to the genome of other NDV strains. However, some unique features of the HN gene were found in HX01. HX01 possesses the motif (112)G-R-Q-G-R-L(117) at the fusion protein cleavage site, which is typical of lentogenic strains. Pathogenicity tests based on the mean death time and the intracerebral pathogenicity index also revealed the isolate's lentogenic character. Phylogenetic analysis based on the variable region of the F gene (nt 47-420) revealed that HX01 was clustered to genotype II within class II NDV. Genetically, HX01 has a high similarity with the La Sota vaccine strain based on the single gene or complete genomic but is far different from the prevalent genotype VIId NDV which circulates in fowls and waterfowls in mainland China.