Elution time of velogenic, mesogenic and lentogenic strains of Newcastle disease virus was determined. The differences in their elution time were also calculated. Four samples, each of a velogenic strain (VGF2), a mesogenic strain (Komarov) and a lentogenic strain (LaSota) were used for hemagglutination test with 0.6% chicken red blood cells. The time it took for wells of the end hemagglutination points (highest dilution that gave agglutination) to elute was recorded as elution time for each sample. The mean elution time of the three strains of Newcastle disease virus differed significantly (p < 0.05). The velogenic strain gave the highest mean elution time of 118 min, followed by the mesogenic strain with 59 min and the lentogenic strain with 25 min. Based on this result it appears that elution time could form a basis for rough characterization of isolates of Newcastle disease virus into the three major strains.
Animals ; Chickens/blood ; Erythrocytes/*virology ; Hemagglutination Tests ; *Hemagglutination, Viral ; Newcastle disease virus/isolation&purification/*pathogenicity

Two hundred thirty specimens of wild birds were collected from some areas in Heilongjiang Province during the period of 2003~2004, including two batches of specimens collected randomly from a same flock of mallards in Zhalong Natural Reserve in August and December, 2004, respectively. Primary virus isolation and identification for avian influenza virus (AIV) and Newcastle disease virus (NDV) were performed. The results showed that only two specimens of young mallards collected from Zhalong Natural Reserve in August, 2004 were positive to AIV (isolation rate 0.9%), and one strain (D57) of these two virus isolates was identified to be H9 subtype by hemagglutination inhibition test. Meanwhile, the two batches of blood serum samples of mallards from Zhalong were also examined for antibodies against AIV and NDV. Among 38 blood serum samples collected in August, antibodies against the hemagglutinin of H1, H3, H5, H6 and H9 subtypes of AIV were found in 1, 0, 2, 0 and 8 samples, respectively; and 11 samples were found with antibody against NDV. Whereas the NDV isolation in both two batches of specimens of mallard was negative, all of the 32 blood serum samples collected in December were negative for antibodies against AIV and NDV.
Animals ; Animals, Wild/*virology ; Antibodies, Viral/isolation&purification ; Birds/virology ; China/epidemiology ; Hemagglutination Tests ; Influenza A virus/*isolation&purification ; Influenza in Birds/epidemiology/immunology/*virology ; Newcastle Disease/epidemiology/immunology/*virology ; Newcastle disease virus/*isolation&purification ; Reverse Transcriptase Polymerase Chain Reaction

The purpose of this study is trying to analysis the homology between four lentogenic Class I genotype 3 Newcastle disease virus isolates from different hosts with NDV strain NDV 08-004, which was the first obtained complete genome sequence virus of class I genotype 3. The full-length genome of NDV isolates, JS/3/09/Ch, ZJ/3/10/Ch, AH/2/10/Du and JS/9/08/Go,were determined by RT-PCR and then an alyzed. All the genomes are 15 198 nucleotides (nt) in length. Compared with the full genome sequences of Class II NDV stains (genotype IV-IX),four isolates has a 6-nt deletion in the non-coding region of nuclear phosphoprotein gene between nucleotides 1 640-1 641 and 12-nt insertion in the coding region of phospho protein gene between nucleotides 2 381-2 382. All the isolates have the motifs 112EQ/RQE/GRL117 at the cleavage site of the fusion protein, which is typical of lenogenic NDV strains, and it is in agreement with the result of pathogenic tests. The full-length genome of 4 genotype 3 NDV isolates shared 93% nucleotide identity with NDV08-004. The results of alignment of 6 viral genes showed that NP gene shared the highest identity (98.3%-96.4%) and P gene shared the lowest identity (96.1%-91.9%). The results show the following two points. First, it is concluded that the isolates from different hosts share the same genotype has the insignificant divergence in the genetic information. Second, it is proposed that the mutation rates of NP/F/L genes are lower than P/M/HN genes.
Animals ; Genome, Viral ; genetics ; Genomics ; Genotype ; Host Specificity ; genetics ; Newcastle disease virus ; classification ; genetics ; isolation & purification ; Phylogeny

Newcastle disease viruses (NDVs) cause systemic diseases in chickens with high mortality. However, little is known about persistence of NDVs in contaminated tissues from infected birds. In this study, we examined viral replication in the feather pulp of chickens inoculated with viscerotropic velogenic NDV (vvNDV) genotype VII. Reverse transcription real-time PCR and immunohistochemistry were used to investigate viral persistence in the samples. vvNDV was detected in the oropharynx and cloaca and viral antigens were detected in the feathers, suggesting that feathers act as sources of viral transmission.
Animals ; Antigens, Viral/analysis ; Chickens ; Cloaca/virology ; Feathers/*virology ; Microbial Viability ; Newcastle Disease/transmission/*virology ; Newcastle disease virus/isolation & purification/*physiology ; Oropharynx/virology ; Poultry Diseases/transmission/*virology ; Virus Replication/*physiology

An outbreak of fever and dyspnea with high incidence rate and case fatality rate occurred among pigs in a pigfarm in Jilin province, China, in 2000. The paramyxovirus-like particles could be observed in lungs, spleens and kidneys of the dead pigs under the transmission electron microscope. A Newcastle disease virus (NDV) isolate designated as JL01 was determined as the causal agent for the disease outbreak. The purified virus was reinoculated into pigs, and then the pigs infected with the virus showed similar symptoms, and the HI antibody of NDV could be detected from the reinoculated pigs. The MDT, ICPI and EID50 of the JL01 isolate was 55.2h, 1.60 and 10(-7.5)/0.1 mL respectively. The F gene of JL01 was cloned and sequenced, and the results showed that the identities of F gene shared by JL01 and avirulent NDV reference strains were from 91.5% to 98.5%, and could be ascribed to NDV genotype I. Thus, the swine NDV JL01 strain should be an avirulent strain with gene variation, but the virulence of JL01 was just the same as velogenic strains.
Animals ; Chickens ; Dogs ; Horses ; Mice ; Microscopy, Electron ; Newcastle Disease ; virology ; Newcastle disease virus ; classification ; genetics ; isolation & purification ; ultrastructure ; Phylogeny ; Polymerase Chain Reaction ; Rabbits ; Sequence Analysis, DNA ; Swine ; Swine Diseases ; virology ; Viral Proteins ; genetics

Three Newcastle disease virus (NDV) strains recovered from ND outbreaks in chickens and duck flocks in north china during 2009 to 2011 were completely sequenced and biologically characterized. All the strains were velogenic and had the velogenic motif 112R-R-Q-K-R-F117 which was consistent with the results of biological tests. Analysis of the variable region (nucleotide 47 to 420) of the F gene indicated that the three isolates belonged to genotype VII d. Cross hemagglutination inhibition test indicated that the antigen homology between three isolates and LaSota were 82.5%-89.4%, the homology between the two isolates from chicken was 90%. A cross-protection experiment in which specific-pathogen-free chickens vaccinated with LaSota were challenged by SDLY01 isolate showed that LaSota vaccine could provide complete protection against SDLY01, however virus discharge could be detected on fifth day. Challenge experiment in which Cherry Valley duck of 30 day old challenged with SD03 strain indicated that cherry valley duck had no disease in experiment period, but virus discharge could be detected from Larynx and cloaca until fifth day. Genome length of three NDV isolates was 15192bp and belonged to genotype VII d. Sequence analysis clarified that the whole genomic sequence of these three isolates shared high homology with NDV virus strains isolated from goose and duck over the same period, which elucidated that NDV isolated from goose, duck or chicken had close genetics and epidemiological relationship.
Amino Acid Sequence ; Animals ; Bird Diseases ; virology ; Chickens ; Columbidae ; Ducks ; Geese ; Genome, Viral ; Molecular Sequence Data ; Newcastle Disease ; virology ; Newcastle disease virus ; chemistry ; classification ; genetics ; isolation & purification ; Phylogeny ; Sequence Alignment ; Viral Proteins ; chemistry ; genetics

The plaque-forming characteristics of Newcastle disease viruses of chickens and geese source were compared on various cells. The result showed that there were obvious differences of plaque formation between F48E9 and NA-1 on Vero cells, chicken embryo fibroblast cells (CEF) and goose embryo fibroblast cells (GEF). The plaque-forming ability of NA-1 was higher than F48E9 on GEF, but lower than F48E9 on CEF. On Vero cells, the plaque-forming ability of NA-1 was slightly stronger than F48E9. It demonstrated that the plaque-forming characteristics were consistent with host tropism of virus. The morphogenesis of F48E9 and NA-1 on Vero cells was observed with transmission electron microscope. There were different replication processes between F48E9 and NA-1 on cells at different stages. NA-1 had stronger adaptability to host than F48E9 according to budding processes and envelope integrity.
Animals ; Cercopithecus aethiops ; Chick Embryo ; Chickens ; Geese ; Host-Pathogen Interactions ; Newcastle Disease ; virology ; Newcastle disease virus ; growth & development ; isolation & purification ; physiology ; ultrastructure ; Poultry Diseases ; virology ; Vero Cells ; Viral Plaque Assay

The full length of chicken interferon alpha (ChIFN-alpha) gene was amplified by the polymerase chain reaction (PCR) from total liver genome of Sanhuang meat-chicken and sequenced. The amplified gene was about 582bp. The coding region for mature protein (489bp) was subcloned into pET-28a(+). The recombinant plasmid pET-28a(+)-IFNalpha was identified by enzyme digestion and DNA sequencing. Data of SDS-PAGE and Western-blot indicated that a 22kD fusion protein was expressed in the form of inclusion bodies with good immunity. The purity of inclusion bodies was above 70% and that of protein purified by nickel affinity chromatography was 95%. The recombinant protein could inhibit H9N2 avian influenza virus (H9N2 AIV) replication on chick embryo fibroblast. 2 microg of recombinant IFN-alpha could completely protect Chick embryo from H9N2 AIV infection. The recombinant IFN-alpha can also delay Newcastle disease virus (NDV) replication on chick embryo for 12 approximately 48h. Chicken administered recombinant IFN-alpha can resist the H9N2 AIV infection. The bioactivities of recombinant IFN-alpha purified by affinity chromatograph were 20 times higher than that of inclusion bodies.
Animals ; Antiviral Agents ; pharmacology ; Blotting, Western ; Chick Embryo ; Cloning, Molecular ; Influenza A Virus, H9N2 Subtype ; drug effects ; Interferon Type I ; biosynthesis ; isolation & purification ; pharmacology ; Interferon-alpha ; genetics ; Newcastle disease virus ; drug effects ; Plasmids ; Recombinant Proteins