Transcriptive complex of Newcastle disease virus. I. Both L and P proteins are required to constitute an active complex

Gene expression of nonsegmented negative strand RNA viruses

Nonsegmented negative strand RNA viruses comprise major human and animal pathogens in nature. This class of viruses is ubiquitous and infects vertebrates, invertebrates, and plants. Our laboratory has been working on the gene expression of two prototype nonsegmented negative strand RNA viruses, vesicular stomatitis virus (a rhabdovirus) and human parainfluenza virus 3 (a paramyxovirus). An RNA-dependent RNA polymerase (L and P protein) is packaged within the virion which faithfully copies the genome RNA in vitro and in vivo; this enzyme complex, in association with the nucleocapsid protein (N), is also involved in the replication process. In this review, we have presented up-to-date information of the structure and function of the RNA polymerases of these two viruses, the mechanisms of transcription and replication, and the role of host proteins in the life-cycle of the viruses. These detailed studies have led us to a better understanding of the roles of viral and cellular proteins in the viral gene expression.

Purification, renaturation, and reconstituted protein kinase activity of the Sendai virus large (L) protein: L protein phosphorylates the NP and P proteins in vitro

Sodium dodecyl sulfate-solubilized Sendai virus large (L) protein was highly purified by a one-step procedure, using hydroxylapatite column chromatography. Monoclonal antibodies addressed to the carboxyl-terminal amino acid sequence of the L protein were used for monitoring L protein during purification. By removing sodium dodecyl sulfate from purified L protein, a protein kinase activity was successfully renatured. P and NP proteins served as its substrates. After immunoprecipitation with anti-L antibodies, the immunocomplex already showed protein kinase activity. In the presence of P protein, the NP protein was more highly phosphorylated. The results show that Sendai virus L protein possesses a protein kinase activity phosphorylating the other proteins of the viral nucleocapsid in vitro.

Sequence analysis of P gene of human parainfluenza type 2 virus: P and cysteine-rich proteins are translated by two mRNAs that differ by two nontemplated G residues

We cloned and sequenced the cDNAs against genomic RNA and mRNA for phosphoprotein (P) of human parainfluenza type 2 virus (PIV-2). cDNA clone from genomic RNA was 1439 nucleotides in length excluding poly(A) and was found to have two small open reading frames encoding proteins of 233 and 249 amino acids. Two different mRNA cDNA clones were obtained; that is, one mRNA contained a smaller reading frame coding 225 amino acids, V protein, and the other mRNA contained a larger reading frame coding 395 amino acids, P protein. Both mRNAs had G cluster in coding frame. The former mRNA contained seven G residues, and two extra G residues were inserted in the latter mRNA. Ten cDNA clones from the genomic RNA were identical and were composed of seven G residues, indicating that genomes analyzed here were a homogeneous population. Therefore, V protein is encoded by faithfully copied mRNA and P protein is translated from mRNA in which two additional G residues are nontemplately inserted immediately after seven genomically encoded G residues. The V and P proteins are amino coterminal proteins and have different C termini. The C terminus of V protein is cysteine-rich and bears some resemblance to metal-binding protein of the zinc finger-type motif. P protein sequence of PIV-2 showed high homologies with SV 5 (40.4%) and mumps virus (35.5%), and a moderate homology with Newcastle disease virus (20.6%). On the other hand, very little homology was found between PIV-2 and other paramyxoviruses including Sendai virus, PIV-3, and measles virus. The cysteine-rich region in V protein was found to be highly conserved in PIV-2, SV 5, and measles virus, suggesting that V protein of paramyxoviruses plays important roles in transcription and/or replication. The predicted cysteine-rich V protein was detected in virus-infected cells using antiserum directed against an oligopeptide specific for the predicted V polypeptide.

Sendai virus gene expression in lytically and persistently infected cells

Sendai virus RNA species were quantitated in lytically and persistently infected cultured cells by Northern blot hybridization to region- and strand-specific cloned cDNA probes. Levels of NP, P and M mRNA in lytically infected cells were equally high, but F and HN mRNA were present in about 3-fold, and L mRNA in 30-fold, lower amounts, reflecting transcriptional attenuation especially at the M-F and HN-L gene junction. Two persistently infected cell lines, which release only 1% of the virus particles of lytically infected cells, were shown to contain only 4- to 8-fold-less amounts of each viral mRNA and 2- to 3-fold-less genomic RNA than lytically infected cells. Additionally, transcription was neither defective nor more attenuated as compared to the lytical infection. Taken together the results suggest the existence of an additional regulatory mechanism for the virus release. A cell-associated state of infection therefore seems to be achievable by a relatively weak general reduction of the copy numbers of viral mRNA and genomic RNA.

Two nontemplated nucleotide additions are required to generate the P mRNA of parainfluenza virus type 2 since the RNA genome encodes protein V

The nucleotide sequence of the "P/V gene" of parainfluenza virus type 2 is presented. To determine the nature of any nontemplated additions of nucleotides that may arise during the synthesis of mRNA from this gene the polymerase chain reaction was used to amplify specific sequences of both genomic RNA and mRNA. These results demonstrated that the V protein is encoded by the genome while insertion of two nontemplated G residues are required to synthesize P mRNA. The predicted P protein has 44% identical amino acid homology with that of simian virus 5 and 37% with mumps virus; 25% of the amino acids is conserved between all three viruses.

Newcastle disease virus fusion protein expressed in a fowlpox virus recombinant confers protection in chickens

A cDNA copy of the RNA encoding the fusion (F) protein of Newcastle disease virus (NDV) strain Texas, a velogenic strain of NDV, was obtained and the sequence was determined. The 1,792-base-pair sequence encodes a protein of 553 amino acids which has essential features previously established for the F protein of virulent NDV strains. These include the presence of three strongly hydrophobic regions and pairs of dibasic amino acids in the pentapeptide Arg-Arg-Gln-Arg-Arg preceding the putative cleavage site. When inserted into a fowlpox virus vector, a glycosylated protein was expressed and presented on the surface of infected chicken embryo fibroblast cells. The F protein expressed by the recombinant fowlpox virus was cleaved into two polypeptides. When inoculated into susceptible birds by a variety of routes, an immunological response was induced. Ocular or oral administration of the recombinant fowlpox virus gave partial protection, whereas both intramuscular and wing-web routes of inoculation gave complete protection after a single inoculation.

Localization of nucleocapsid associated polypeptides in measles virus-infected cells by immunogold labelling after resin embedding

The nucleo-, phospho- and matrix protein of measles virus were localized at high resolution within infected cells by use of post-embedding immunogold labelling techniques. In general, labelling with monospecific antibodies as well as with a polyvalent rabbit anti-measles hyperimmune antiserum revealed measles virus polypeptides to be distributed non-randomly within infected cells with the label largely confined to specific sites, namely inclusions of nucleocapsids and assembled virus structures at the plasma membrane. Immunogold double labelling indicated that the phosphoprotein strictly co-localized with the nucleoprotein in cytoplasmic inclusions of nucleocapsids and in budding virions, whereas intranuclear inclusions of nucleocapsids were devoid of phosphoprotein labelling. Antibodies to the matrix protein clearly labelled assembled virus structures at the plasma membrane but exhibited no significant cytoplasmic or intranuclear reaction. The data indicate that the composition of nucleocapsids varies with the cellular compartment with which they are associated, supporting the view of a rapid assembly of paramyxovirus nucleocapsid polypeptides, and emphasize the proposed selective role of the matrix protein in virus assembly and budding at the plasma membrane.

Separate domains of Sendai virus P protein are required for binding to viral nucleocapsids

The role of Sendai virus P protein in viral RNA synthesis involves association with the nucleocapsid template. There is evidence that the carboxyl-terminal region of P protein is responsible for this association (K. W. Ryan and D. W. Kingsbury, 1988, Virology 167, 106-112). To define the P protein sequences involved more precisely, deletions were generated in a cDNA clone of the P gene. Proteins synthesized in vitro from these altered P genes were mixed with extracts from infected cells to determine if they could attach to nucleocapsids. Under conditions where full-size P protein was able to bind, a protein comprising the 95 carboxyl-terminal residues of P protein (Sendai virus X protein) did not bind. This indicated that other P protein residues were required, in addition to the 95 residues at the carboxyl-terminal end. To locate these other residues, P genes were constructed with overlapping deletions of sequences encoding the carboxyl-terminal 40% of the protein. Analysis of these deleted proteins revealed that the necessary residues were in two separate binding domains, amino acids 345 to 412 and 479 to 568 (the carboxyl-terminus). Deletion of the 66 residues between these regions did not affect attachment. Therefore, the formation of a functional binding site requires residues within two separate regions of P protein.

Rescue of Sendai virus from viral ribonucleoprotein-transfected cells by infection with recombinant vaccinia viruses carrying Sendai virus L and P/C genes

The Sendai virus ribonucleoprotein (RNP) showed only very low plaque-forming titers upon transfection and the virus yields after one-step growth were quite limited. We tried to enhance the Sendai virus yield by supplying the viral L and P/C gene products through vaccinia vectors. A combination of the recombinant vaccinia viruses carrying the L gene (Vac-HL) and the P/C gene (Vac-HPC), both of which were driven by the promoter of the vaccinia virus 7.5K protein gene, enhanced the yield only a little whereas another combination of Vac-HLd7.5, the L gene insert of which was driven by the promoter of the vaccinia virus thymidine kinase gene in place of the 7.5K promoter, and Vac-HPC greatly enhanced the Sendai virus yield. This seemed to correlate with the fact that the Vac-HL interfered with Sendai virus growth markedly while the Vac-HLd7.5 did not. These results strongly suggest that the L and P/C gene products act in cooperation as the RNA polymerase, and overproduction of the L protein is inhibitory for Sendai virus growth. This system seems to be of value as a tool for analyzing the functions of L and P/C genes of Sendai virus.

The Sendai virus nucleocapsid exists in at least four different helical states

Sendai virus nucleocapsids have been observed by electron microscopy to coexist in three different helical pitch conformations, 5.3, 6.8, and 37.5 nm. The 5.3- and 6.8-nm conformations are present both in uranyl acetate negatively stained preparations and in tantalum-tungsten metal-shadowed preparations, whereas the 37.5-nm conformation, which has not been previously reported, is present only in the shadowed preparations. The 5.3-nm pitch conformation appears to be a mixture of two discrete structural states, with a small difference in the twist of the structure between the two. We have used image reconstruction techniques on an averaged data set from eight negatively stained nucleocapsids to produce a three-dimensional reconstruction at 2.4-nm resolution of the structure in one of the 5.3-nm pitch states. There are 13.07 nucleocapsid protein (NP) subunits in each turn of the helix in this state. The helical repeat is 79.5 nm, containing 196 subunits in 15 turns of the left-handed 5.3-nm helix. The arrangement of subunits produces a 5.0-nm-diameter hollow core which forms an internal helical groove. The RNA accounts for about 3% of the mass of the nucleocapsid, and so its location is not conspicuous in the reconstruction. Because of the RNA remains associated with the NP subunits during mRNA transcription and genome replication, structural transitions in the nucleocapsid may determine the accessibility of the genome to polymerases. Alternatively, the large hollow core and internal helical groove we have reconstructed may allow access to the RNA even in the tightly coiled 5.3-nm pitch conformation.

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.

Sequence analysis of the mumps virus mRNA encoding the P protein

The nucleotide sequence of the mumps virus phospho- or polymerase-associated (P) protein mRNA has been determined by sequencing a full-length cDNA clone and confirmed by partially sequencing the mRNA and the genome. The mRNA contains 1311 nucleotides excluding the poly(A) and encodes a protein of 390 amino acids with a calculated molecular weight of 41,574. Three small polypeptides were seen in in vitro translation of viral mRNA and hybrid-selected P mRNA, possibly representing internal initiation in the same reading frame of the P protein. A second overlapping reading frame is predicted from the sequence which has a capacity to code for two polypeptides of 56 and 34 amino acids, respectively. Whether these two polypeptides are expressed in infected cells is not known. Comparison of the P protein sequence with that of Sendai virus, measles virus, parainfluenza virus type 3, and canine distemper virus (CDV) showed no distinct homology but comparison with the P protein of Newcastle disease virus (NDV) showed 25.6% homology.

Carboxyl-terminal region of Sendai virus P protein is required for binding to viral nucleocapsids

The Sendai virus P protein is a component of the viral nucleocapsid, where it participates in RNA synthesis. To identify domains of the protein involved in nucleocapsid recognition, deleted P protein molecules were generated from a cDNA clone of its gene. In vitro transcription of the complete gene and translation of the transcript generated a protein with electrophoretic mobility and immunoreactivity indistinguishable from those of authentic P protein. The in vitro product bound specifically to nucleocapsids when mixed with extracts from infected cells. However, a product lacking only 30 carboxyl-terminal amino acid residues (5% of the molecule) did not bind. Residues within a 195 amino acid region, adjacent to and overlapping by one amino acid with the carboxyl-terminal 30 residues, were also required for binding. No other protein region was required. Therefore, the 224-residue region which includes the carboxyl terminus appears to contain the nucleocapsid attachment site, and the 30 terminal residues either form part of the site or are required to maintain an active conformation.

Two mRNAs that differ by two nontemplated nucleotides encode the amino coterminal proteins P and V of the paramyxovirus SV5

The "P" gene of the paramyxovirus SV5 encodes two known proteins, P (Mr approximately equal to 44,000) and V (Mr approximately equal to 24,000). The complete nucleotide sequence of the "P" gene has been obtained and is found to contain two open reading frames, neither of which is large enough to encode the P protein. We have shown that the P and V proteins are translated from two mRNAs that differ by the presence of two nontemplated G residues in the P mRNA. These two additional nucleotides convert the two open reading frames to one of 392 amino acids. The P and V proteins are amino coterminal and have 164 amino acids in common. The unique C terminus of V consists of a cysteine-rich region that resembles a cysteine-rich metal binding domain. An open reading frame that contains this cysteine-rich region exists in all other paramyxovirus "P" gene sequences examined, which suggests that it may have important biological significance.

Scanning independent ribosomal initiation of the Sendai virus X protein

Both peptide antisera and monoclonal antibodies detect a 10-kd protein (X) in Sendai virus infected cells, which represents approximately the last 95 residues of the 568-amino-acid-long P protein. The X protein does not appear to be derived from a precursor P in vivo, and in in vitro X can be made under conditions in which P synthesis has been arrested by hybridized DNA fragments or specific cleavage of the mRNA. X initiation is nevertheless cap dependent. Ribosomes which initiate X appear to pass directly from the cap to the initiation codon.

The P protein and the nonstructural 38K and 29K proteins of Newcastle disease virus are derived from the same open reading frame

The nucleotide sequence of cloned cDNA copies of the mRNA encoding the Newcastle disease virus (NDV), strain AV, phosphoprotein (P) was determined. The sequence of 1443 nucleotides contains one long open reading frame which could encode a protein with a molecular weight of 42,126, and two smaller open reading frames which could encode proteins with molecular weights of 11,178 and 13,935. Full-length cDNA clones were constructed in an SP6 vector, mRNA was transcribed in a cell-free system using the SP6 polymerase, and the mRNA was translated in a wheat germ cell-free extract. The P mRNA directed the synthesis of, primarily, four products. One, with a molecular weight of 53,000 Da, comigrated with authentic P protein made in infected cells and was precipitable with antisera with specificity for the NDV P protein. The other products of the cell-free reaction had molecular weights of 38,000, 29,000 and 12,000. The 29,000- and the 38,000-Da polypeptides were also precipitable with anti-P protein antibody. Using truncated cDNA clones, evidence is presented that the 38,000- and 29,000-Da proteins are derived from initiation at AUG triplets in the same reading frame as the P protein. Infected cells also contain these polypeptides which may be analogous to C proteins of other paramyxoviruses. Thus the NDV P protein mRNA is different than most other paramyxovirus P protein mRNAs which are translated in two different reading frames to yield the P and C proteins.

Structure, function, and intracellular processing of paramyxovirus membrane proteins

Paramyxoviruses are a fascinating group of viruses with diverse hosts and disease manifestations. They are valuable systems for studying viral pathogenesis, molecular mechanisms of negative strand viral replication, and glycoprotein structure and function. In the past few years this group of viruses has received increased attention and as a result there is a wealth of new information. For example, most of the genes of many paramyxoviruses have been cloned and sequenced. The recent availability of sequence information from a number of paramyxoviruses now allows the direct comparison of the amino acid sequence and determinants of secondary structure of analogous genes across the family of viruses. Such comparisons are revealing for two reasons. First, results provide clues to the evolution of these viruses. Second, and more importantly, comparisons of analogous genes may point to sequences and structural determinants that are central to the function of the individual proteins. Below is a comparison of five of the paramyxovirus genes with a discussion of the implications of common structural determinants for function, intracellular processing, and evolutionary origin. The focus is on the paramyxovirus membrane proteins, although other proteins are discussed briefly.

Antibodies against Sendai virus L protein: distribution of the protein in nucleocapsids revealed by immunoelectron microscopy

Antibodies against the L protein of Sendai virus were made by immunizing rabbits with a synthetic peptide representing a carboxyl-terminal region of the protein predicted from the base sequence of its gene. These antibodies were used to localize the L protein in viral nucleocapsids by electron microscopy. Immunogold labeling revealed that L protein molecules were distributed in clusters along nucleocapsids, suggesting that L molecules act cooperatively in viral RNA synthesis. Immunogold double-labeling showed that all L clusters were associated with clusters of P molecules. We believe that this morphological association reflects the functional cooperation of the L and P proteins in viral RNA synthesis.

Viral RNA polymerases

Recent progress in molecular biological techniques revealed that genomes of animal viruses are complex in structure, for example, with respect to the chemical nature (DNA or RNA), strandedness (double or single), genetic sense (positive or negative), circularity (circle or linear), and so on. In agreement with this complexity in the genome structure, the modes of transcription and replication are various among virus families. The purpose of this article is to review and bring up to date the literature on viral RNA polymerases involved in transcription of animal DNA viruses and in both transcription and replication of RNA viruses. This review shows that the viral RNA polymerases are complex in both structure and function, being composed of multiple subunits and carrying multiple functions. The functions exposed seem to be controlled through structural interconversion.

Nucleotide sequence of the hemagglutinin-neuraminidase gene of Newcastle disease virus avirulent strain D26: evidence for a longer coding region with a carboxyl terminal extension as compared to virulent strains

The nucleotide sequence of DNA clones complementary to the genomic RNA of an extremely avirulent strain D26 of Newcastle disease virus was analyzed, and the sequence of 2102 nucleotides directly following F gene reported previously (Sato et al., 1987, Virus Res. 7, 241-255), and corresponding to HN0 gene was determined. A long open reading frame coding for the HN0 peptide of 616 amino acid residues was found in this sequence. It was flanked by the consensus sequences N1 and N2 (Ishida et al., 1986, Nucleic Acids Res. 14, 6551-6564), and the former was shown by the primer extension method to serve as the transcriptional initiation site. The deduced amino acid sequence of the HN0 peptide was highly homologous to that of the HN peptides of strains Beaudette C and B1, but had a carboxyl terminal extension of 39 amino acid residues with a potential glycosylation site in it. The terminal extension is likely to be excised during the processing, and this is consistent with the observation that unglycosylated HN0 is larger in size than unglycosylated HN. A microheterogeneity among the cDNA clones in the nucleotide sequence was also noted which may be relevant to the synthesis of a small amount of an HN-sized peptide in strain D26-infected cells.

Nucleotide sequence analysis of the L gene of Newcastle disease virus: homologies with Sendai and vesicular stomatitis viruses

The nucleotide sequence of the L gene of the Beaudette C strain of Newcastle disease virus (NDV) has been determined. The L gene is 6704 nucleotides long and encodes a protein of 2204 amino acids with a calculated molecular weight of 248822. Mung bean nuclease mapping of the 5' terminus of the L gene mRNA indicates that the transcription of the L gene is initiated 11 nucleotides upstream of the translational start site. Comparison with the amino acid sequences of the L genes of Sendai virus and vesicular stomatitis virus (VSV) suggests that there are several regions of homology between the sequences. These data provide further evidence for an evolutionary relationship between the Paramyxoviridae and the Rhabdoviridae. A non-coding sequence of 46 nucleotides downstream of the presumed polyadenylation site of the L gene may be part of a negative strand leader RNA.

Molecular cloning and nucleotide sequence of P, M and F genes of Newcastle disease virus avirulent strain D26

Molecular cloning of most if not all of the genome of an avirulent strain D26 of Newcastle disease virus (NDV) was carried out. cDNA clones were aligned by mutual hybridization and restriction map analysis. The nucleotide sequence of 3672 bases which completed the partial sequence of P gene reported in our previous paper (Ishida, N. et al., 1986, Nucleic Acids Res. 14, 6551-6564), and also covered M and F genes, was determined. Each gene contained one long open reading frame which could code for polypeptides of 395, 364, and 553 amino acid residues, respectively. The deduced amino acid sequences of P and M gene products showed little homology to those of other paramyxoviruses. In contrast, comparison of the amino acid sequence of the F gene product revealed highly conserved regions including the amino terminal sequence of the F1 portion following the putative processing site. There was only one basic amino acid residue at the putative processing site, which would explain the low virulence of this strain.

Expression at the cell surface of native fusion protein of the Newcastle disease virus (NDV) strain Italien from cloned cDNA

A cDNA library was constructed with poly(A)+-mRNAs from NDV-Italien infected BHK-21 cells. A clone, that hybridized to the F gene mRNA, was sequenced. A long open reading frame encodes for a protein of 553 amino acids, with a calculated molecular weight of 59,153, consisting of twelve cysteine residues and six potential glycosylation sites. The protein sequence contains a hydrophobic region at the N-terminus of F1 and a presumptive long transmembrane fragment near the C-terminus. Comparison of the F proteins from NDV strains Italien and Australia-Victoria shows that the sequences are very similar, with conservation of most cysteine residues and of the potential glycosylation sites. The F coding sequence was inserted into the genome of vaccinia virus under the control of vaccinia P7.5 transcriptional regulatory sequences. Expression of F protein was demonstrated by indirect immunofluorescence with five anti-F monoclonal antibodies known to react with conformational epitopes.

Detection of polycistronic transcripts in Newcastle disease virus infected cells and identification of their sequence content

The synthesis of six to seven polycistronic transcripts of Newcastle disease virus (NDV) in BHK cells was detected by Northern hybridization using cDNA clones generated by reverse transcription of five NDV mRNAs. Within the molecular weight range resolved by the gel electrophoresis system employed, four of the transcripts were suggested to be distronic, containing sequences of two genes, NP-P, P-M, M-F0 and F0-HN, respectively. In addition, tricistronic molecules of M-F0-HN and possibly of NP-P-M as well as P-M-F0 appeared to develop, although they were very low in amount. These data suggest a gene order of NP-P-M-F0-HN on the NDV genome. The polycistronic as well as monocistronic transcripts were generated with an almost constant proportion in amount throughout the virus replication. Further, at least several of them were also generated under the conditions where only the primary transcription was allowed by inhibiting de novo protein synthesis. Therefore, it appears likely that there is no distinct temporal control in NDV genome expression.

Antigenic characterization of the internal proteins of Newcastle disease virus by monoclonal antibodies

We have prepared and characterized monoclonal antibodies against the three internal structural proteins, M, P and NP, of Newcastle disease virus. At least two non-overlapping antigenic sites were delineated on the M protein, four on the P, and two on the NP by competitive binding assay. One of the two non-overlapping antigenic sites on the M protein was found to be a cluster of at least three distinct epitopes. Enhancement of antibody binding by the binding of a second antibody was observed with the M protein. The reactivity of these monoclonal antibodies with heterologous strains was studied by enzyme-linked immunosorbent assay. The results indicated that there are both highly conserved antigenic sites and those subject to remarkable change on both M and P proteins. On the other hand, NP appeared to be antigenically more stable.

Localization and characterization of Sendai virus nonstructural C and C' proteins by antibodies against synthetic peptides

Antibodies were raised in rabbits against two synthetic peptides, each 30 residues in length, one corresponding to the predicted common carboxyl termini of the nonstructural C and C' proteins of Sendai virus and the other to the unique amino terminus of the larger C protein. Each peptide was inoculated as a covalent complex with tetanus toxoid or in uncomplexed form. Only antibodies to the free carboxyl-terminal peptide precipitated both C and C' proteins made by in vitro translation of viral mRNA and reacted with the C protein from infected cells. These results confirm that the C and C' proteins are carboxyl-coterminal. Contrasting with the reported colocalization of intracellular measles virus C proteins with nucleocapsid inclusions, immunofluorescence studies revealed that Sendai virus C proteins were uniformly distributed in the cytoplasm whereas the viral P protein was present in inclusions that were mainly perinuclear. Since almost all P protein molecules are associated with viral nucleocapsids, these observations suggested that Sendai virus C protein molecules may be both nucleocapsid-associated and free in the cytoplasm. This interpretation was supported when the C and C' proteins were found in both nucleocapsid and free protein fractions of cell lysates. Anti-C antibodies did not inhibit viral RNA synthesis when added to an extract of infected cells. This result was consistent with the conclusion that the C proteins have no direct role in viral transcription, since virions lack C proteins but are transcriptionally active. Therefore, the functions of the C proteins remain undefined.

Messenger RNA encoding the phosphoprotein (P) gene of human parainfluenza virus 3 is bicistronic

The complete nucleotide sequence of the phosphoprotein (P) mRNA of human parainfluenza virus 3 (PIV-3) was derived from two cDNA clones spanning almost the entire P gene. The mRNA, excluding the poly(A) tail, is 2014 nucleotides long and is bicistronic. The first open reading frame (ORF) codes for the phosphoprotein (P) of mol wt 68,860. Seven nucleotides downstream from the first AUG codon, in a +1 reading frame, there is an additional ORF which can code for a polypeptide of mol wt 23,266. The latter protein appears to be similar to the C proteins found in cells infected with several paramyxoviruses. Comparison of the predicted amino acid sequence of the P and C proteins of PIV-3 with the corresponding Sendai virus proteins reveals considerable homology at the C-terminal half. In contrast, the P and C proteins of PIV-3 share very little homology with the measles virus P and C proteins, respectively.

Localization of P, NP, and M proteins on Sendai virus nucleocapsid using immunogold labeling

The distribution of NP, P, and M proteins on Sendai virus nucleocapsids purified from cells and virions were studied by immunogold staining using monoclonal antibodies. NP molecules were found uniformly along the entire length of both cytosol and virion derived nucleocapsids. This observation is in accord with the earlier proposals that NP molecules maintained the structural integrity of the nucleocapsid. The distribution of P in nucleocapsids derived from the cytosol differed from the distribution in those originating from virions. In nucleocapsids derived from the cytosol, P molecules occurred in 4 to 10 discreet clusters at varying locations along the length of the nucleocapsid. In contrast, on nucleocapsids derived from virions, P molecules were uniformly distributed over the entire length of the nucleocapsid. These observations suggest that the distribution of P depends on the functional state of the nucleocapsid. The occurrence of P clusters at different locations on intracellular nucleocapsids indicates that P is a mobile molecule; this suggestion is consistent with P's role in viral RNA synthesis. The distribution of the matrix (M) protein also depended on where the nucleocapsids were derived from. Large quantities of M protein were found along the entire length of nucleocapsids derived from the cytosol, while in virion nucleocapsids, many fewer molecules of M were observed. The large amounts of M on the nucleocapsids originating from the cytosol supports the hypothesis that M protein mediates the recognition between the nucleocapsid and the envelope glycoproteins.

Transcriptive complex of Newcastle disease virus. II. Structural and functional assembly associated with the cytoskeletal framework

The transcriptive complex, the nucleocapsid with the viral RNA-synthesizing activity, of Newcastle disease virus (NDV) contains three protein components, the major structural subunit (NP) and two associated proteins (P and L) involved in the RNA synthesis. We studied the pathway of these proteins from synthesis to assembly into the complex by pulse-chase labeling of infected cells followed by detergent extraction of the cells to separate soluble and cytoskeletal fractions. Most molecules of NP and P (and probably L) became associated with the cytoskeletal framework immediately after their synthesis. Most of the remaining molecules were initially found in the soluble fraction, but joined the cytoskeletal framework within several minutes. Once attached, none of the proteins left the cytoskeleton, and it was here that they assembled with 50 S viral RNA into nucleocapsids. The nucleocapsids thus formed remained bound to the cytoskeletal framework and were found by in situ autoradiography to exhibit viral RNA synthesis on the framework. These results suggested that the cytoskeletal framework could actively participate in the structural and functional assembly of NDV transcriptive complex.

Conformational changes in Newcastle disease virus fusion glycoprotein during intracellular transport

The migration on polyacrylamide gels of nascent (pulse-labeled) and more processed (pulse-labeled and then chased) forms of nonreduced Newcastle disease virus fusion glycoprotein were compared. Results are presented which demonstrate that pulse-labeled fusion protein, which has an apparent molecular weight of 66,000 under reducing conditions (Collins et al., J. Virol. 28: 324-336), migrated with an apparent molecular weight of 57,000 under nonreducing conditions. This form of the Newcastle disease virus fusion protein has not been previously detected. This result suggests that the nascent fusion protein has extensive intramolecular disulfide bonds which, if intact, significantly alter the migration of the protein on gels. Furthermore, upon a nonradioactive chase, the migration of the fusion protein in polyacrylamide gels changed from the 57,000-molecular-weight species to the previously characterized nonreduced form of the fusion protein (molecular weight, 64,000). Evidence is presented that this change in migration on polyacrylamide gels is due to a conformational change in the molecule which is likely due to the disruption of some intramolecular disulfide bonds: Cleveland peptide analysis of the pulse-labeled nonreduced fusion protein (molecular weight, 57,000) yielded a pattern of polypeptides quite different from that obtained from the more processed form of the fusion protein (molecular weight, 64,000). However, the pattern of polypeptides obtained from the nonreduced 64,000-molecular-weight species was quite similar to that obtained from the fully reduced nascent protein (molecular weight, 66,000). This conformational change occurred before cleavage of the molecule. To determine the cell compartment in which the conformational change occurs, use was made of inhibitors which block glycoprotein migration at specific points. Monensin allowed the appearance of the 64,000-molecular-weight form of the fusion protein, whereas carboxyl cyanide m-chlorophenylhydrazine blocked the appearance of the 64,000-molecular-weight form of the fusion protein. Thus, the fusion protein undergoes a conformational change as it moves between the rough endoplasmic reticulum and the medial Golgi membranes.

Intracellular processing of the Newcastle disease virus fusion glycoprotein

The fusion glycoprotein (Fo) of Newcastle disease virus is cleaved at an intracellular site (Nagai et al., Virology 69:523-538, 1976) into F1 and F2. This result was confirmed by comparing the transit time of the fusion protein to the cell surface with the time course of cleavage of Fo. The time required for cleavage of half of the pulse-labeled Fo protein is ca. 40 min faster than the half time of the transit of the fusion protein to the cell surface. To determine the cell compartment in which cleavage occurs, use was made of inhibitors which block glycoprotein migration at specific points and posttranslational modifications known to occur in specific cell membranes. Cleavage of Fo is inhibited by carbonyl cyanide m-chlorophenylhydrazone; thus, cleavage does not occur in the rough endoplasmic reticulum. Monensin blocks the incorporation of Newcastle disease virus glycoproteins into virions and blocks the cleavage of the fusion glycoprotein. However, Fo cannot be radioactively labeled with [3H] fucose, whereas F1 is readily labeled. These results argue that cleavage occurs in the trans Golgi membranes or in a cell compartment occupied by glycoproteins quite soon after their transit through the trans Golgi membranes. The implications of the results presented for the transit times of the fusion protein between subcellular organelles are discussed.

Requirements and functions of vesicular stomatitis virus L and NS proteins in the transcription process in vitro

The L and NS proteins of vesicular stomatitis virus were purified from transcribing ribonucleoprotein complex and were used to study their requirements and functions during reconstitution of RNA synthesis in vitro. The requirements for L and NS proteins for optimal RNA synthesis were found to be catalytic and stoichiometric, respectively. Addition of increasing amounts of NS protein to N-RNA template and saturating L protein, the ratio of N-mRNA to leader RNA synthesis increased linearly. In contrast, when the concentration of L protein was increased the corresponding ratio remained constant. These results, coupled with the observation that the L protein is involved in the initiation of RNA synthesis, suggest that the NS protein is involved in the RNA chain elongation step. The NS protein possibly interacts with both the L protein and the template N-RNA and unwinds the latter to facilitate the movement of L protein on the template RNA.

Monoclonal antibodies to the P protein of Sendai virus define its structure and role in transcription

Four monoclonal antibodies specific for Sendai virus nucleocapsid protein P were used to examine both the antigenic structure of P and its role in transcription. Three distinct antigenic regions were delineated on P by competitive radioimmunoassays (RIAs), and through Western blot analysis all three sites were mapped to a 40,000-MW (40K) Staphylococcus aureus protease V8-digestion fragment, which remains associated with the neucleocapsid structure. To study the function of P, nucleocapsids were treated with saturating amounts of anti-P monoclonal antibodies and it was found that transcription in vitro was inhibited by 60-90%. Data, therefore, are consistent with the conclusion that the P protein is required for transcription and that the 40K protease-resistant core contains the functionally important portion of the molecule. Further analysis of the P structure showed that some of the 40K fragments were linked by disulfide bonds. These results suggest that the protease-resistant 40K fragment is in the carboxyl-terminal half of P, since the three cysteine residues of P are found there (C. Giorgi, B. M. Blumberg, and D. Kolakofsky (1983), Cell 35, 829-836).

Structural and functional analysis of Sendai virus nucleocapsid protein NP with monoclonal antibodies

Monoclonal antibodies specific for Sendai virus nucleocapsid protein NP were used to map the antigenic structure of NP and to investigate the role of NP in transcription. Using nine anti-NP antibodies in competitive-binding (CB) assays, it was found that the NP molecule contained at least two topographically distinct antigenic sites. By Western blot analysis, one of the NP epitopes belonging to antigenic site I was localized to a Mr 34,000 (34K) trypsin digest fragment, and another to a Mr 48,000 (48K) fragment which remained associated with the nucleocapsid. The other antibodies which define antigenic site I did not react with either fragment; however, the results of CB would indicate that their epitopes were in a region on the tertiary structure of the NP molecule that is closely proximal to these fragments. The 48K and 34K fragments on the published NP amino acid sequence have been tentatively identified. Since the 34K and 48K fragments bind antibody, it appears that nucleocapsid-bound NP may be folded into a configuration which places at least some of these sequences on the surface of the nucleocapsid structure. Six antibodies representing both antigenic sites were purified for functional studies. All the antibodies inhibited nucleocapsid transcription in vitro to the same extent (greater than 90%); however, they differed in the amount of antibody required to produce the same effect. Within site I, antibodies producing maximum inhibition were divided into three groups: three antibodies inhibited at relatively low concentrations (0.17 microgram), one antibody inhibited at an intermediate range (0.43 microgram), and another required a 10-fold higher concentration (1.73 microgram) to produce the same effect. The antibody which detected the 48K trypsin digest fragment was the one which fell into the intermediate range for transcription inhibition, while the antibody that detected the 34K fragment was in the low range. Thus, antigenic site I, defined by CB and trypsin digestion studies, can be defined further into three subsites which appear to differ in their involvement in the transcription process. Antigenic site II was defined by a single antibody which also inhibited transcription by greater than 90%.

Protein kinase associated with Newcastle disease virus

Purified virions of Newcastle disease virus (NDV) were found to contain protein kinase activity which was, like other virion-associated kinases, stimulated by Mg2+, and totally independent of Ca2+ and cAMP. The kinase phosphorylated preferentially the P and NP polypeptides of NDV. Triton-KCl fractionation of the virions has shown that the protein kinase activity may be associated with glycoprotein-free subviral particles, but not with nucleocapsids containing either only NP or some L and P proteins together with NP as protein constituent.

The uncoating of paramyxoviruses may not require a low pH mediated step

The effect of lysosomotropic agents, chloroquine and NH4Cl, on the replication of paramyxoviruses was compared with that on the other enveloped RNA viruses whose uncoating is known to be blocked by the agents. Under the conditions where vesicular stomatitis or influenza virus infection was strongly inhibited at an early step, the agents exhibited little inhibitory effect on the progress of infection by Newcastle disease virus and Sendai virus, allowing viral primary transcription to occur and neither inhibiting the virus production significantly nor reducing the number of infected cells. These results are incompatible with the previous report showing that paramyxovirus and the other enveloped RNA viruses may have in common an intracellular step sensitive to lysosomotropic agents (Miller and Lenard, Proc. Nat. Acad. Sci. USA 78, 3605-3609, 1981) and suggest that paramyxovirus uncoating may not require a low pH mediated lysosomal step.

Subcellular location of the major protein antigens of paramyxoviruses revealed by immunoperoxidase cytochemistry

The major structural proteins of Newcastle disease virus and Sendai virus were localized in infected BHK-21 and MDBK cells by ultrastructural immunoperoxidase cytochemistry using antibodies against the individual viral protein antigens. The intracellular glycoproteins were strictly membrane bound, being localized in the rough endoplasmic reticulum (RER), perinuclear spaces, smooth membrane vesicles, and presumed Golgi apparatus. The nucleocapsid proteins were detected exclusively in membrane free cytosol and accumulated there, forming inclusions. The membrane (M) protein was found both in cytosol and on RER. The viral proteins on RER exhibited a distinct site specificity; the glycoproteins were facing the lumen of RER whereas M protein was present at the outer cytoplasmic surface. All the viral proteins were detectable at the plasma membrane where virus assembly takes place. However, their modes of distribution differed remarkably. The glycoproteins were spread widely over the entire cell surface including the areas of virus budding and those of normal morphology, whereas M protein was localized in restricted areas of the membrane, frequently forming a patch of virus specific membrane. The presence of nucleocapsids was confined to the virus particles budding from the plasma membrane. These results complement and extend the earlier morphological and biochemical data on the assembly or morphogenesis of paramyxoviruses.