Role of fusion protein cleavage site in the virulence of Newcastle disease virus

Newcastle disease virus (NDV) causes a highly contagious and economically important disease in poultry. Viral determinants of NDV virulence are not completely understood. The amino acid sequence at the protease cleavage site of the fusion (F) protein has been postulated as a major determinant of NDV virulence. In this study, we have examined the role of F protein cleavage site sequence in NDV virulence using reverse genetics technology. The sequence G-R-Q-G-R present at the cleavage site of the F protein of avirulent strain LaSota was mutated to R-R-Q-K-R, which is present in the F cleavage site of neurovirulent strain Beaudette C (BC). The resultant mutated LaSota V.F. virus did not require exogenous protease for infectivity in cell culture, indicating that the F protein was cleaved by intracellular proteases. The virulence of the mutant and parental viruses was evaluated in vivo by intracerebral pathogenicity index (ICPI) and intravenous pathogenicity index (IVPI) tests in chickens. Our results showed that the modification of the F protein cleavage site resulted in a dramatic increase in virulence from an ICPI value of 0.00 for LaSota to a value of 1.12 for LaSota V.F. However, the ICPI value of LaSota V.F. was lower than that of BC, which had a value of 1.58. Interestingly, the IVPI tests showed values of 0.00 for both LaSota and LaSota V.F. viruses, compared to the IVPI value of 1.45 of BC. In vitro characteristics of the viruses were also studied. Our results demonstrate that the efficiency of cleavage of the F protein plays an important role if the NDV is delivered directly into the brains of chicks, but there could be other viral factors that probably affect peripheral replication, viremia, or entry into the central nervous system.     

Effect of host selective pressure on Newcastle disease virus virulence

Newcastle disease virus (NDV) causes an economically important disease that can vary from clinically inapparent to highly virulent forms. Generally, NDV strains isolated from wild birds are non-pathogenic for chicken. However, there are evidences supporting the fact that avirulent viruses maintained in feral birds could have caused outbreaks of virulent NDV in poultry. The strain-specific difference in virulence is determined by structural variations on the fusion glycoprotein (F). More basic amino acids are present in the F cleavage site of virulent strains. Nevertheless, other regions have been involved in virulence determination. When we subjected an avirulent NDV isolated from a wild bird to a host change we found that the virus arose was virulent for chicken. Nucleotide changes in the F protein cleavage site amino acid sequence and in the hemagglutinin-neuraminidase protein sequence are reported.     

Molecular Characterization of Virulent Newcastle Disease Virus Isolates from Chickens during the 1998 NDV Outbreak in Kazakhstan

Newcastle disease virus (NDV) infects domesticated and wild birds throughout the world and has the possibility to cause outbreaks in chicken flocks in future. To assess the evolutionary characteristics of 10 NDV strains isolated from chickens in Kazakhstan during 1998 we investigated the phylogenetic relationships among these viruses and viruses described previously. For genotyping, fusion (F) gene phylogenetic analysis (nucleotide number 47-421) was performed using sequences of Kazakhstanian isolates as compared to sequences of selected NDV strains from GenBank. Phylogenetic analysis showed that all newly characterized strains belonged to the genetic group designated as VIIb. All strains possessed a virulent fusion cleavage site (RRQRR/F) belonging to velogenic or mesogenic pathotypes with intracerebral pathogenicity indexes (ICPI) varying from 1.05 to 1.87.     

Evaluation of Newcastle disease virus chimeras expressing the Hemagglutinin-Neuraminidase protein of velogenic strains in the context of a mesogenic recombinant virus backbone

A major factor in the pathogenicity of Newcastle disease virus (NDV) is the amino acid sequence of the fusion protein cleavage site, but the role of other viral genes that contribute to virulence and different clinical forms of the disease remain undefined. To assess the role of other NDV genes in virus pathogenicity, a reverse genetics system was developed using the mesogenic NDV Anhinga strain to provide a backbone for generating gene mutations or gene exchanges in attempts to enhance or attenuate the virulence of that virus. Chimeras created by exchange of the Anhinga Hemagglutinin-Neuraminidase (HN) gene with HN genes of neurotropic and viscerotropic velogenic viruses produced no significant change in virus pathogenicity as assessed by conducting the mean death time and intracerebral pathogenicity index assays and by inoculation of susceptible day-old SPF chickens. Inclusion in the recombinant construct of homotypic F genes, obtained from the parental viruses, also failed to enhance the pathotype of the recombinant viruses to a velogenic pathotype. A HN gene exchange alone within the context of the NDV Anhinga backbone failed to increase virus virulence from mesogenic to velogenic pathotype and suggests a multigenic role for NDV pathogenicity.     

The avian response to Newcastle disease virus

Newcastle disease virus (NDV) is classified as a member of the superfamily Mononegavirales in the family Paramyxoviridae. This virus family is divided into two subfamilies, the Paramyxovirinae and the Pneumovirinae. In 1993 the International Committee on the Taxonomy of Viruses rearranged the order of the Paramyxovirus genus and placed NDV within the Rubulavirus genus among the Paramyxovirinae. The enveloped virus has a negative sense single-stranded RNA genome of 15,186 kb which codes for an RNA directed RNA polymerase, hemagglutinin-neuraminidase protein, fusion protein, matrix protein, phosphoprotein and nucleoprotein in the 5' to 3' direction. The virus has a wide host range with most orders of birds reported to have been infected by NDV. Isolates are characterized by virulence in chickens and are categorized into three main pathotypes depending on severity of disease. Lentogenic isolates are of low virulence while viruses of intermediate virulence are termed mesogenic. Highly virulent viruses that cause high mortality in birds are termed neurotropic or viscerotropic velogenic. Velogenic NDV are List A pathogens that require reporting to the Office of International Epizootics and outbreaks result in strict trade embargoes. The primary molecular determinant for NDV pathogenicity is the fusion protein cleavage site amino acid sequence. Vaccination for NDV is primarily by mass application of live-virus vaccines among commercial poultry. Although protection is measured by presence of antibodies to NDV, vaccinated B-cell depleted chickens are resistant to disease. Consequently, immune protection involves responses that are presently incompletely defined.     

Biological and molecular characterization of Indian isolates of Newcastle disease virus from pigeons

Five Newcastle disease virus (NDV) isolates from pigeons were characterized by biological and molecular methods. Four of the five isolates were found to be velogenic with high intracerebral pathogenicity indices (ICPI). The fusion protein cleavage site (FPCS) sequences of these isolates had multiple basic amino acids RRQKRF at positions 112-116 and a phenyl alanine at position 117 characteristic of velogenic isolates. Three of these velogenic isolates were phylogenetically related to mesogenic vaccine virus strain and the fourth one to a few exotic velogenic isolates. The lentogenic isolate obtained in this study was identical with the LaSota strain.     

Complete genome sequence of highly virulent neurotropic Newcastle disease virus strain Texas GB

Newcastle disease virus (NDV) strain Texas GB is a highly virulent neurotropic virus that is used as a standard vaccine challenge virus in the U.S. In this study, the complete genome sequence of strain Texas GB was determined and compared with the complete genome sequences of other NDV strains. The genome is 15,186 nucleotides (nt) long and consists of six genes in the order of 3′leader-N-P-M-F-HN-L-5′trailer. The genome contains a 55-nt leader sequence at the 3′ end and a 114-nt trailer sequence at the 5′ end. The intergenic sequences are 2, 1, 1, 31, and 47 nt between N/P, P/M, M/F, F/HN, and HN/L genes, respectively. The putative cleavage site of fusion protein showed amino acid sequence of R-R-Q-K-R↓F in position 112 to 117, which corresponds to those of virulent NDV strains. The phylogenetic analysis showed that strain Texas GB is closely related to the neurovirulent mesogenic strain Beaudette C (BC) and to NDV viruses isolated in China and Egypt than to other strains of NDV.     

Characterization of genotype IX Newcastle disease virus strains isolated from wild birds in the northern Qinling Mountains,China

This study was conducted to evaluate the virulence and evolution of genotype IX Newcastle disease virus (NDV) isolates obtained from wild birds in the northern Qinling Mountains of China. Five isolates were obtained from 374 larynx and cloacae swabs, which were collected from multiple asymptomatic wild bird species from August 2008 to July 2011, and were subsequently characterized by pathotype and genotype. Deduced amino acid sequences revealed that all five NDV isolates exhibited velogenic fusion protein cleavage sites motif ¹¹²R-R-Q-R-R-F¹¹⁷, shared as high as 99.8–99.9 % homology with each other, and varied in pathotype by intracerebral pathogenicity indices (ICPI) of 0.425–1.638. Phylogenetic analysis showed that all five isolates were clustered to genotype IX NDV. This is the first study to confirm multiple asymptomatic wild bird species as natural carriers of virulent genotype IX NDV. A novel NDV isolate from the Spotted-necked Dove (family Columbidae) exhibited discordance between its lentogenic ICPI and its virulent proteolytic cleavage site motif ¹¹²R-R-Q-R-R-F¹¹⁷. Although the five isolates underwent several amino acid mutations in the fusion protein, evidence of continuous evolutionary divergence did exist in the genotype IX NDV, which was always regarded as a conservative genotype.     

Nucleotide sequence of the envelope protein genes of a highly virulent, neurotropic strain of Newcastle disease virus

The envelope glycoproteins of Newcastle disease virus (NDV), hemagglutinin-neuraminidase (HN) and fusion (F) proteins, play important roles in determining the host immune response and the virulence of that particular virus strain. The complete nucleotide sequence of the HN and F genes of a highly neurovirulent strain of NDV (Texas G. B., 1948) was determined in an effort to study the molecular basis of this strain's neurotropic properties. Comparison of the predicted amino acid sequences for the HN and F among the American NDV strains revealed that the Texas G. B. and Beaudette C envelope genes are closely related to each other and are less closely related to the avirulent B1 Hitchner strain. We have found 11 amino acid changes in the predicted HN protein between the Beaudette C and Texas G. B. strain but only 2 conservative amino acid changes (amino acids 11 and 197) in the F protein between these two strains. Although the virulence of NDV strains has been related to sequences at the cleavage site of F0, the property of neurovirulence cannot depend solely upon these sequences because there are no sequence differences between the Beaudette C and Texas G. B. strains. We suggest that the neurovirulence phenotype could be due to the molecular properties of the HN protein; however, we cannot exclude the possibility that the two conservative amino acid differences between the two F proteins could also play a role in determining the phenotypic differences between these two virus strains.     

Effects of the HN gene C-terminal extensions on the Newcastle disease virus virulence

The hemagglutinin-neuraminidase (HN) of Newcastle disease virus (NDV) is a multifunctional protein that has receptor recognition, neuraminidase, and fusion promotion activities. Sequence analysis revealed that the HN gene of many extremely low virulence NDV strains encodes a larger open-reading frame (616 amino acids, aa) with additional 45 aa at its C-terminus when compared with that (571 aa) of virulent NDV strains. Therefore, it has been suspected that the 45 aa extension at the C-terminus of the HN may affect the NDV virulence. In this study, we generated an NDV mesogenic strain Anhinga-based recombinant virus with an HN C-terminal extension of 45 aa (rAnh-HN-ex virus) using reverse genetics technology. The biological characterization of the recombinant virus showed that the rAnh-HN-ex virus had similar growth ability to its parental virus rAnh-wt both in embryonating chicken eggs and DF-1 cells. However, the pathogenicity of this recombinant virus in embryonating chicken eggs and day-old chickens decreased, as evidenced by a longer mean death time and lower intracerebral pathogenicity index when compared with the parental virus. This is consistent with our previous finding that the recombinant LaSota virus with a 45-aa extension at its HN C-terminal was attenuated in chickens and embryonating eggs. These results suggest that the HN protein C-terminal extension may contribute to the reduced virulence in some low virulence NDV strains.     

Use of a heteroduplex mobility assay to detect differences in the fusion protein cleavage site coding sequence among Newcastle disease virus isolates

Newcastle disease virus (NDV) is an economically important pathogen of poultry that may cause clinical disease that ranges from a mild respiratory syndrome to a virulent form with high mortality, depending on an isolate's pathotype. Infections with virulent NDV strains are required to be reported by member nations to the Office of International Epizootes (OIE). The primary determinant for virulence among NDV isolates is the presence or absence of dibasic amino acids in the fusion (F) protein cleavage activation site. Along with biological virulence determinations as the definitive tests, OIE accepts reporting of the F protein cleavage site sequence of NDV isolates as a virulence criterion. Nucleotide sequence data for many NDV isolates recently isolated from infected chickens and other avian species worldwide have been deposited in GenBank. Consequently, viral genomic information surrounding the F protein cleavage site coding sequence was used to develop a heteroduplex mobility assay (HMA) to aid in further identification of molecular markers as predictors of NDV virulence. Using common vaccine strains as a reference, we were able to distinguish virulent viruses among NDV isolates that correlated with phylogenetic analysis of the nucleotide sequence. This technique was also used to examine NDV isolates not previously characterized. We were able to distinguish vaccine-like viruses from other isolates potentially virulent for chickens. This technique will help improve international harmonization of veterinary biologics as set forth by the OIE and the Veterinary International Cooperation on Harmonization of Technical Requirements of Veterinary Medicinal Products. Ultimately, the HMA could be used for initial screening among a large number of isolates and rapid identification of potentially virulent NDV that continue to threaten commercial poultry worldwide.     

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 ¹¹²R-R-Q-K-R-F¹¹⁷, 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.     

Evaluation of the molecular basis of pathogenicity of the variant Newcastle disease viruses termed “pigeon PMV-1 viruses”

Summary The amino acid sequence at the F2/F1 cleavage site was determined for 15 strains of the so-called pigeon PMV-1 (PPMV-1) variant of Newcastle disease virus (NDV) which showed close antigenic identity, determined by their reactions with a panel of 28 monoclonal antibodies, but considerable variation in their pathogenicity for chickens. Thirteen of the isolates possessed the motif¹¹²G-R-Q-K-R-F¹¹⁷. This motif was seen for one virus which had initially low pathogenicity and remained unaltered when virulence of the virus for chickens was increased by bird to bird passage. The two other viruses had the sequence¹¹²R-R-Q-K-R-F¹¹⁷ at the cleavage site which is more typical of virulent viruses, however, pathogenicity index tests indicated that these isolates were of moderate and low pathogenicity. The nucleotide sequence coding for the HN/HN0 extension region was determined for two of the PPMV-1 isolates. In both cases a stop codon was present indicating that the product for these viruses would be HN₅₇₁. We conclude that the wide variation in pathogenicity of the variant PPMV-1 for chickens is not related to variation in the amino acid motif at the F2/F1 cleavage site nor due to production of HN0 which may also influence pathogenicity. The high virulence of some of the viruses examined confirms that a double pair of basic amino acids in the region of the F2/F1 cleavage site is not necessary for the full expression of virulence.     

Complete genome sequence and molecular characterization of thermostable Newcastle disease virus strain TS09-C

A thermostable avirulent Newcastle disease virus (NDV) strain TS09-C was developed by serial passage of V4 strain in BHK-21 cells. The complete genome sequence of strain TS09-C was determined and compared with the sequences of other NDV isolates representing different thermostable phenotypes. The TS09-C genome was 15,186 nucleotides long and consisted of eight genes in the order of 3′-NP-P/V/W-M-F-HN-L-5′. High levels of nucleotide and amino acid sequence identity existed among the thermostable NDV isolates. Thermostable strains TS09-C, V4, I-2, and Ulster all belonged to genotype I. The F protein cleavage site of strain TS09-C was ¹¹²G-K-Q-R–R-L¹¹⁷, with an isolated basic amino acid and a pair of contiguous basic amino acids, differing from that of its parental V4 strain (¹¹²G-K-Q-G-R-L¹¹⁷). Our characterization of the complete genome of thermostable avirulent NDV strain TS09-C may facilitate the development of a thermostable NDV reverse genetic system and further study of the mechanism of thermostability of NDV.     

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

Summary 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.     

Sequence comparison between two quasi strains of H6N1 with different pathogenicity from a single parental isolate.

BACKGROUND AND PURPOSE: Relationships between gene change and virulence for hemagglutinin (HA) subtypes of avian influenza virus remain inconclusive. In this study, sequences of these nearly identical virus strains were obtained in order to elucidate the relationship between molecular determinants and virulence. METHODS: Two strains, with different virulence, of an H6N1 avian influenza virus were isolated from an infected chicken flock. Complete 8-gene fragments from the 2 strains were cloned and sequenced. Putative amino acid sequences were compared. RESULTS: Comparisons of the sequences from the 2 strains showed 0.65%, 0.79%, 0.28%, 1.23%, 0.80%, 0.20%, 0.43%, and 0.83% differences in PB2, PB1, PA, HA, NP, neuraminidase (NA), NS1 and NS2 proteins, respectively. The M1, M2, and PB1-F2 protein sequences from the strains were identical. The HA cleavage site of both strains contained a single R, despite their difference in virulence. Thus, the difference in virulence might be due to sequences other than the HA cleavage site. Most of the changes were in the HA2 part. The sequence immediately after the HA cleavage site was GILG in the non-virulent strain and GIFG in the virulent strain. The change from E to G at position 106 in the HA, near the receptor binding site, might influence the virulence. Other sequence changes likely to influence virulence were from K to R at position 291 (K291R) in NP protein and from P to T at position 101 (P101T) in NA protein. CONCLUSION: The amino acid changes identified in this study may be important in the virulence of influenza viruses.     

Genetic and antigenic analysis of Newcastle disease viruses from recent outbreaks in Taiwan.

Portions of the haemagglutinin-neuraminidase (HN) and fusion protein (F) genes of Newcastle disease virus (NDV) isolated from recent outbreaks in Taiwan were amplified and sequenced. These isolates were velogenic, based on the amino acid sequences of the F protein cleavage site and the mean death time in chicken embryos. All the recent viruses contained the amino acid sequences 112RRQKR116 for the C-terminus of the F2 protein. The serological relatedness of recent isolates was determined using a serum neutralization (SN) test. Relatedness values, determined by a cross-SN test, revealed that all belonged to a single serotype but could be classified into distinct subtypes, suggesting that antigenic variations occurred in these isolates. Phylogenetic trees based on the nucleotide sequences of the HN and F genes revealed that recent Taiwanese isolates had evolved into two groups. Antigenic analysis also suggested that there are at least two groups of NDVs involved in recent outbreaks and that these outbreaks in Taiwan might have been caused by co-circulation of multiple velogenic NDV strains.