Molecular study of the quasispecies evolution of a typical pigeon paramyxovirus type 1 after serial passages in pigeons by contact

Experimental infection with Brazilian Newcastle disease virus strain in pigeons and chickens

This study was designed with the goal of adding as much information as possible about the role of pigeons (Columba livia) and chickens (Gallus gallus) in Newcastle disease virus epidemiology. These species were submitted to direct experimental infection with Newcastle disease virus to evaluate interspecies transmission and virus-host relationships. The results obtained in four experimental models were analyzed by hemagglutination inhibition and reverse transcriptase polymerase chain reaction for detection of virus shedding. These techniques revealed that both avian species, when previously immunized with a low pathogenic Newcastle disease virus strain (LaSota), developed high antibody titers that significantly reduced virus shedding after infection with a highly pathogenic Newcastle disease virus strain (São Joao do Meriti) and that, in chickens, prevent clinical signs. Infected pigeons shed the pathogenic strain, which was not detected in sentinel chickens or control birds. When the presence of Newcastle disease virus was analyzed in tissue samples by RT-PCR, in both species, the virus was most frequently found in the spleen. The vaccination regimen can prevent clinical disease in chickens and reduce viral shedding by chickens or pigeons. Biosecurity measures associated with vaccination programs are crucial to maintain a virulent Newcastle disease virus-free status in industrial poultry in Brazil.

Genome-wide association study of antibody level response to NDV and IBV in Jinghai yellow chicken based on SLAF-seq technology

Newcastle disease (ND) and avian infectious bronchitis (IB) are contagious diseases of chickens. To identify genes associated with antibody levels against ND and IB, a genome-wide association study was performed using specific-locus amplified fragment sequencing (SLAF-seq) technology in Jinghai yellow chickens. This determined six single-nucleotide polymorphisms (SNPs) that were associated with antibody levels against Newcastle disease virus (NDV): rsZ2494661, rsZ2494710, rs1211307701, rs1211307711, rs1218289310 and rs420701988. Of these, rsZ2494661 and rsZ2494710 reached the 5 % Bonferroni genome-wide significance level (5.5E-07) and they were both 134.7 kb downstream of the SETBP1 gene. The remaining four SNPs had 'suggestive' genome-wide significance levels (1.1E-05) and they were within or near the Plexin B1, LRRN1 and PDGFC genes. IB had two SNPs associated with antibody levels: rs149988433 and rs16170823; both reached chromosome-wide significance levels and they were near the USP7 and TRIM27 genes, respectively. Bioinformatics, GO annotation and pathway analysis indicated that five of these genes (Plexin B1, TRIM27, PDGFC, SETBP1 and USP7) may be important for the generation of protective antibodies against NDV and infectious bronchitis virus (IBV). This paves the way for further research on host immune responses against NDV.

Phylogenetic characterization and virulence of two Newcastle disease viruses isolated from wild birds in China

Wild birds are considered as a natural reservoir of Newcastle disease virus (NDV). However, there is no information about genotype IX NDV from wild birds, especially from Columbiformes. In this study, two genotype IX NDV viruses were isolated from wild birds. One was from Eurasian Blackbird, while the other was from Spotted-necked dove. After purification by plaque technique, complete genomes of both viruses were sequenced. Phylogenetic analysis of partial fusion (F) gene and complete genome indicated both strains belonged to genotype IX. Based on intracerebral pathogenicity index (ICPI), the virus from Eurasian Blackbird was velogenic virus, while the strain from Spotted-necked dove was lentogenic virus. However, both strains showed one of velogenic cleavage sites. In addition, the strain from Eurasian Blackbird showed greater replication ability and generated larger fusion foci in vitro than that of strain from Spotted-necked dove. Comparing all the corresponding protein sequences of both strains, there were only 9 different amino acid residues between them. Furthermore, after analysis of these differences, the information about lentogenic NDV with multi-basic cleavage site was presented.

Partial characterisation of five cloned viruses differing in pathogenicity, obtained from a single isolate of pigeon paramyxovirus type 1 (PPMV-1) following passage in fowls' eggs

Viruses with intracerebral pathogenicity indices (ICPIs) of 0.025, 0.55, 1.013 and 1.3. were cloned from a PPMV-1 isolate with an ICPI of 0.32 by passage in embryonated fowls' eggs. Deduced amino acid sequences of the haemagglutinin-neuraminidase (HN) and precursor fusion proteins (F0) showed them to have only a single amino acid difference: those with an ICPI value <0.7 had proline at amino acid position 453 of the F0 protein, and those with an ICPI value >0.7 contained a serine. The virus with an ICPI of 0.025 was further passaged, and the ICPI of non-cloned virus increased to 0.76/0.79, which was then reduced to 0.49 on cloning. The proline at residue 453 was retained, but there were two nucleotide changes in the virus of ICPI 0.49, T --> C at position 1769 in the untranslated region of the fusion gene and G --> A at position 437 of the HN gene, resulting in the amino acid change G --> R at position 116 in the HN protein.

Characterization of Pigeon-Origin Newcastle Disease Virus Isolated in China

Fourteen pigeon-origin Newcastle disease virus (NDV) isolates were obtained from sick pigeons in China between 1996 and 2005. The mean death time (MDT) of embryonated eggs and the intracerebral pathogenicity indices (ICPI) were tested to determine the virulence of the field isolates. The result indicated that most isolates were proved to be mesogenic (MDT 60-90 hr and ICPI > 1.2). The main function regions of F protein gene of the isolates were amplified and sequenced for phylogenetic and residue substitutive analysis. The fusion protein cleavage site sequences of most isolates had multiple basic amino acids R/KRQKRF at positions 112-116 and a phenyl alanine at position 117, characteristic of velogenic isolates. In the phylogenetic tree, the majority of the isolates were clustered into a single genetic lineage, termed genotype VIb, and were typical pigeon paramyxovirus type 1, whereas a small number of recent isolates (three strains) were grouped into genotype VIId, a predominant genotype responsible for most Newcastle disease outbreaks in chickens and geese since the end of last century. One isolate, PK9901, was proved to be a lentogenic strain, of genotype II NDV, to which the vaccine strain La Sota belongs.

Coronaviruses in poultry and other birds

The number of avian species in which coronaviruses have been detected has doubled in the past couple of years. While the coronaviruses in these species have all been in coronavirus Group 3, as for the better known coronaviruses of the domestic fowl (infectious bronchitis virus [IBV], in Gallus gallus), turkey (Meleagris gallopavo) and pheasant (Phasianus colchicus), there is experimental evidence to suggest that birds are not limited to infection with Group 3 coronaviruses. In China coronaviruses have been isolated from peafowl (Pavo), guinea fowl (Numida meleagris; also isolated in Brazil), partridge (Alectoris) and also from a non-gallinaceous bird, the teal (Anas), all of which were being reared in the vicinity of domestic fowl. These viruses were closely related in genome organization and in gene sequences to IBV. Indeed, gene sequencing and experimental infection of chickens indicated that the peafowl isolate was the H120 IB vaccine strain, while the teal isolate was possibly a field strain of a nephropathogenic IBV. Thus the host range of IBV does extend beyond the chicken. Most recently, Group 3 coronaviruses have been detected in greylag goose (Anser anser), mallard duck (Anas platyrhynchos) and pigeon (Columbia livia). It is clear from the partial genome sequencing of these viruses that they are not IBV, as they have two additional small genes near the 3' end of the genome. Twenty years ago a coronavirus was isolated after inoculation of mice with tissue from the coastal shearwater (Puffinus puffinus). While it is not certain whether the virus was actually from the shearwater or from the mice, recent experiments have shown that bovine coronavirus (a Group 2 coronavirus) can infect and also cause enteric disease in turkeys. Experiments with some Group 1 coronaviruses (all from mammals, to date) have shown that they are not limited to replicating or causing disease in a single host. SARS-coronavirus has a wide host range. Clearly there is the potential for the emergence of new coronavirus diseases in domestic birds, from both avian and mammalian sources. Modest sequence conservation within gene 1 has enabled the design of oligonucleotide primers for use in diagnostic reverse transcriptase-polymerase chain reactions, which will be useful for the detection of new coronaviruses.