Newcastle disease virus evolution. II. Lack of gene recombination in generating virulent and avirulent strains

Deduced amino acid sequences at the fusion protein cleavage site of Newcastle disease viruses showing variation in antigenicity and pathogenicity

The amino acid sequence at the F2/F1 cleavage site of the F0 fusion protein of 17 strains of Newcastle disease virus (NDV) was deduced from sequencing a 32 nucleotide area of the genome by reverse transcription and polymerase chain reaction (PCR) techniques. With the addition of sequences at the same area previously published for 9 other viruses comparisons were made of a total of 26 NDV strains and isolates (11 of low virulence, 15 of high virulence or mesogenic) covering ten antigenic groups determined by reactions with monoclonal antibodies. All the virulent viruses and the mesogenic strain Komarov showed the amino acid sequence 112R/K-R-Q-K/R-R116 for the C-terminus of the F2 protein and phenylalanine (F) at the N-terminus of the F1 protein, residue 117. The mesogenic isolate of the antigenic variant NDV responsible for the recent panzootic in racing pigeons, often termed "pigeon paramyxovirus type 1", examined in this study had the sequence 112G-R-Q-K-R-F117. The deduced amino acid sequence in the corresponding region of all viruses of low virulence was 112G/E-K/R-Q-G/E-R-L117. The virulent virus, PMV-1/chicken/Ireland/34/90 (34/90), which had a close antigenic relationship to a group of avirulent viruses, three of which were examined in the present study as representatives of the monoclonal antibody group H, showed between 4-6 nucleotide differences from these viruses in the 32 nucleotide region studied. These resulted in differences in the deduced amino acid sequence at residue 112 E-->K, 115 E-->K and 117-->F, giving 34/90 a typical virulent virus motif at the cleavage site. Despite the extremely small portion of the genome studied there were several areas which appeared characteristic for 34/90 and the three group H viruses of low virulence, which suggests that they may have arisen from the same gene pool.

Protease-dependent virus tropism and pathogenicity

Viral tissue tropism in a susceptible host is often determined by virus-receptor interactions. Nevertheless, closely related viruses utilizing the same receptor molecules can display striking differences in tropism, or a virus can cause a localized infection despite the widespread occurrence of the receptor. These events are now explained by another mechanism of tropism, in which host proteases play a major role by activating viral fusion glycoproteins.

A mutant CHO-K1 strain with resistance to Pseudomonas exotoxin A is unable to process the precursor fusion glycoprotein of Newcastle disease virus

RPE.40, a mutant strain of CHO-K1 cells isolated for resistance to Pseudomonas exotoxin A and cross-resistant to alphaviruses, is also highly resistant to virulent strains of Newcastle disease virus. The resistance of RPE.40 cells to Newcastle disease virus results from the failure to cleave the viral envelope precursor glycoprotein Fo to fusion glycoprotein F1 at the consensus sequence (Lys/Arg)-Arg-Gln-(Lys/Arg)-Arg.

Mammalian subtilisin-related proteinases in cleavage activation of the paramyxovirus fusion glycoprotein: superiority of furin/PACE to PC2 or PC1/PC3

The fusion glycoprotein precursor of Newcastle disease virus is ubiquitously cleaved in the constitutive secretory pathway if it possesses an oligobasic cleavage motif (RRQR/KR), whereas the precursor is refractory to cleavage if the motif is monobasic (GR/KQGR). We examined the cleavage activity of the mammalian subtilisin-related proteinases furin/PACE, PC2, and PC1/PC3, which are thought to be responsible for proprotein processing in either the constitutive (furin/PACE) or the regulated (PC2 and PC1/PC3) secretory pathway, for the viral precursors with different cleavage motifs. Only furin/PACE was fully capable of cleaving the precursors with the oligobasic motif. PC2 and PC1/PC3 were incapable or only partially capable of cleaving at this motif. None of the proteinases cleaved the monobasic motif. These results suggest involvement of furin/PACE in viral protein processing in the constitutive secretory pathway.

Intracellular processing of the paramyxovirus F protein: critical role of the predicted amphipathic alpha helix adjacent to the fusion domain

At a nonpermissive temperature, the group D temperature-sensitive mutants of Newcastle disease virus strain Australia-Victoria (AV) are defective in plaque formation, in inducing infected cells to fuse, and in incorporating the cleaved fusion glycoprotein, F1 + F2, into virus particles. In this study, the F protein of AV, expressed in chicken embryo cells, was able to complement these mutants in a plaque assay, identifying the F gene as the gene containing the group D temperature-sensitive lesions. The F genes of mutants D1, D2, and D3 were found to contain single mutations relative to the AV sequence, clustered within a predicted amphipathic alpha helix (AAH) adjacent to the hydrophobic amino terminus of F1. These mutant F proteins were inefficiently processed at the permissive temperature, a problem that was exacerbated at the nonpermissive temperature. Surprisingly, the AV F protein was also found to be partially temperature sensitive in processing. Its AAH is predicted to contain a break in the helix close to the D mutation sites, which are themselves predicted to further weaken the helix at this point. Interestingly, six revertants of the group D mutants were found to have an additional lesion in the AAH, repairing both the AV and mutant helices, resulting in a predicted perfect helix. The F protein of these revertants had overcome both the processing defects of the mutants and the temperature sensitivity of AV, indicating that the AAH region is critical for F protein processing. The lesions of a second group of revertants were localized within F2, suggesting an interaction with the F1 AAH region containing the original lesion.

Antipeptide antibodies for analysis of pathotype-specific variations in cleavage activation of the membrane glycoprotein precursors of Newcastle disease virus isolates in cultured cells

Antipeptide antibodies have been produced which target regions either side of the cleavage activation sites of Newcastle disease virus (NDV) membrane glycoprotein precursors. Use of complementary pairs of antibodies in Western blot analysis of mercaptoethanol-reduced extracts of NDV-infected BHK-21 cells enabled analysis of the susceptibilities of NDV fusion protein precursors (Fo-proteins) to cleavage activation in these cells. In addition, it was possible to determine whether or not isolates produce haemagglutinin-neuraminidase (HN)-proteins in precursor forms (HNo-proteins). This assay system has been evaluated with a series of Australian isolates of NDV with well defined virulence properties in order to validate its use in pathotyping NDV isolates. Less well defined isolates also produced data consistent with their biological properties and an isolate was characterised which, hitherto, was not known to be present in Australian poultry. The applicability of this assay system in fundamental studies of the processes of cleavage activation of NDV Fo- and HNo-proteins and formatting of the antisera into ELISA systems are discussed.

Isolation of factor Xa from chick embryo as the amniotic endoprotease responsible for paramyxovirus activation

In chick embryo, certain paramyxoviruses mainly target the chorioallantois and the allantoamnion and show no extensive further spreading in the other organs. This has been explained by the possible presence of an endoprotease activating the viral fusion glycoprotein precursor in the allantoic and the amniotic fluid, and its absence in other places or organs. We previously isolated such an endoprotease from the allantoic fluid and demonstrated its identity with the clotting factor Xa. Exactly the same endoprotease by all the criteria including the N-terminal amino acid sequence was now isolated from the amniotic fluid. Thus, the factor Xa seems to be a major host determinant of the viral tropism in chick embryo.

Evolution of the fusion protein gene of human parainfluenza virus 3

The nucleotide sequences of the fusion (F) gene of 15 clinical strains of human parainfluenza virus 3 (HPIV3) isolated between 1959 and 1987 were compared with the F gene sequence of the prototype strain, Wash/47885/57. Nucleotide sequence diversity was greatest in the noncoding regions of the F gene; however, regions believed to function as transcriptional signals were completely conserved. Amino acid sequences were highly conserved and all but a few amino acid substitutions were conservative in nature. Sequence comparisons indicate heterogeneity in HPIV3 F genes; however, a significant proportion of nucleotide changes are maintained after they first appear and seem to be accumulating with time. Phylogenetic analysis suggests that there are 2 lineages of HPIV3 in North America. The two lineages can be distinguished by specific amino acid differences in the F protein, which correlate with differences in antigenic properties and neutralization patterns of HPIV3. The pattern of HPIV3 evolution, based on the analysis of F gene sequences, most closely resembles that of influenza virus B, vesicular stomatitis virus and Newcastle disease virus.

Role of mass spectrometry in mapping strain variation and post-translational modifications of viral proteins

Enzymatically derived fragments of the nucleocapsid protein from one strain (V4) of the paramyxovirus, New castle disease virus (NDV), have been aligned with the sequence deduced for a related strain (D26) by gene sequence analysis. This process involved extensive use of fast atom bombardment (FAB) mass spectrometry of unfractionated tryptic digests and fragments separated from tryptic or AspN protease digests by high-performance liquid chromatography (HPLC). Amino acid analysis and stepwise Edman degradation sequence analysis were used to complement FAB mass spectral data or as alternatives where no ions were produced by FAB. The nature of biosynthetic processing and blockage (acetylation) at the N-terminus of the protein were confirmed using collision-induced dissociation. Data obtained by direct analysis of the V4 nucleocapsid protein facilitated mapping of sequence variations within the nucleocapsid protein of the antigenically distinct WA2116 strain of NDV. Most of the WA2116 protein was mapped by FAB mass spectrometric analysis of HPLC fractions, thus amino acid analysis or stepwise sequence analysis were only required where FAB mass spectral data were inconclusive or indicated amino acid variations. This approach to comparison of NDV nucleocapsid proteins is proposed as a general strategy for mapping strain variation and post-translational modifications of viral proteins.

Comparison of the positions and efficiency of cleavage activation of fusion protein precursors of virulent and avirulent strains of Newcastle disease virus: insights into the specificities of activating proteases

The F1- and F2-polypeptide components of in ovo activated fusion proteins of one virulent (AV or Australia-Victoria) strain, one low-virulence (EG or Eaves-Grimes) strain, and two avirulent (V4 or Queensland and WA2116) strains of Newcastle disease virus (NDV) were isolated and subjected to structural analysis. This included complementary application of amino acid analysis, fast atom bombardment-mass spectrometry, and N-terminal sequence analysis to fragments isolated from AspN protease digests of the F2-polypeptides using HPLC. As a result, the complete sequences of the F2-polypeptides were determined, including documentation of glycosylation of asparagine 54. The sequence of the cleavage-activation site of the WA2116 F0-protein was found to be distinctly different from this site in any other NDV F0-protein. Cleavage activation at the C termini of the F2-polypeptide regions was found to have occurred to approximately equivalent extents at arginines 82 and 85 of the AV and EG strains, but was restricted largely to arginine 85 of the V4 strain and completely to arginine 85 of the WA2116 strain. In each case cleavage activation was apparently succeeded by trimming of the basic residues from the newly formed C termini. Immunochemical analysis with antipeptide antisera showed that the extent of cleavage was influenced by amino acids adjacent to these arginines. These data provide insight into the substrate specificities of the enzymes involved in cleavage activation of the fusion protein precursors.

Evaluation of the antiviral effect of synthetic oligopeptides whose sequences are derived from paramyxovirus F1 N termini

We examined the antiviral effects of three oligopeptides, carbobenzoxy(Z)-D-Phe-Ile-Gly, Z-D-Leu-Ile-Gly and Z-D-Phe-Phe-Gly, which mimic the N-terminal regions of F1 glycoproteins of two Newcastle disease virus strains (Miyadera and D26) and Sendai virus, respectively. Only one of these peptides, Z-D-Phe-Phe-Gly, significantly and with a similar potency inhibited viruses of homologous and heterologous F1 N-terminal sequences, suggesting no strict sequence requirement for inhibition. Furthermore, the enveloped RNA viruses of several different families showed essentially the same sensitivity to the three peptides as the paramyxoviruses, while a non-enveloped RNA virus was not susceptible to any of them. In addition, the Z-D-Phe-Phe-Gly peptides was effective only when the virus particles had been pretreated before infection.

A host range mutant of Newcastle disease virus with an altered cleavage site for proteolytic activation of the F protein

The primary structure of the F protein of a host range mutant of the Ulster strain of Newcastle Disease virus (NDV) has been determined by nucleotide sequence analysis and compared to that of the wild type and other NDV strains. The cleavage site of the mutant had the sequence Gly-Lys-Gln-Arg-Arg as compared to two isolated basic amino acids [Gly-Lys(Arg)-Gln-Gly-Arg] with the apathogenic strains and two pairs of basic amino acids [Arg-Arg-Gln-Lys(Arg)-Arg] with the pathogenic strains. The data indicate that the cleavability of the F protein of NDV increases with the number of arginine and lysine residues at the cleavage site and that the susceptibility of the pathogenic strains to ubiquitous host proteases depends on both pairs of basic amino acids.

Newcastle disease virus evolution. I. Multiple lineages defined by sequence variability of the hemagglutinin-neuraminidase gene

We compared the hemagglutinin-neuraminidase gene sequence among 13 strains of Newcastle disease virus (NDV) isolated over the last 50 years. Although overall homology was remarkably high, the sequence variability demonstrated the existence of at least three distinct lineages, which must have co-circulated for considerable periods. The sequence variability also appears to reflect some accumulation of mutations over time. Strictly correlating with the lineages, the translation products could be classified into three size classes. One class lacked the interchain disulfide bond, and another represented unusual precursor protein of biologically inactive form. The lineages correlated to some extent with virulence and place of isolation of the strains. However, antigenic variations, which were neither cumulative nor progressive, did not correlate with the lineages. These analyses showing multiple lineages were greatly facilitated by a precise calculation of synonymous substitutions, which had been largely free from selective pressures and had occurred frequently and evenly throughout the coding region.