Neutralizing epitopes of human parainfluenza virus type 3 are conformational and cannot be imitated by synthetic peptides.

The possibility that linear epitopes on the haemagglutinin-neuraminidase (HN) surface glycoprotein of human parainfluenza virus type 3 (PIV-3) might induce neutralizing antibodies after virus infection was investigated. Thirty-seven peptides, representing 64% of the extramembranous portion of the HN molecule of PIV-3, were synthesized. Their ability to bind to 14 neutralizing murine monoclonal antibodies (mAbs) specific for HN or 26 high-titre human serum samples were tested in a direct enzyme-linked immunosorbent assay (ELISA) and in an indirect competition ELISA. None of the synthetic peptides reacted with any of the mAbs or serum samples in the direct test and none of 11 synthetic peptides tested blocked mAbs from binding to HN in the competition ELISA. These findings suggest that synthetic peptides cannot be used to imitate the known neutralizing epitopes on the HN. Analyses of reduced and non-reduced HN in ELISA and immunoblot assays confirmed that protein folding and tertiary structure are essential for epitope formation in these neutralizing sites. However, some children's sera analysed by immunoblotting contained antibodies to an uncharacterized linear epitope(s) not recognized by our panel of mAbs, raising the possibility that a neutralizing linear epitope does exist on the HN of PIV-3.

Mapping of antigenic domains of Sendai virus nucleocapsid protein expressed in Escherichia coli.

Several nonoverlapping epitopes were mapped on the primary sequence of the Sendai virus NP protein. After a complete cDNA clone of the Sendai virus NP gene was expressed in Escherichia coli, deletion constructs were used to generate a series of overlapping NP fragments deleted at their C termini. Immunoblot analyses with 11 monoclonal antibodies identified four antigenic sites. All of these sites resided in the C-terminal half of NP and were also the only sites detected with a polyclonal serum. These findings confirm and extend the evidence that the C terminus of the NP protein represents the domain exposed on the surface of the nucleocapsid. One of the monoclonal antibodies reacted with a site, comprising only 6 amino acids, lying with a hinge between an alpha-helix and a beta-strand in the predicted secondary structure of NP. Since this antibody is a potent inhibitor of in vitro viral RNA synthesis (K. L. Deshpande and A. Portner, Virology 139:32-42, 1984), the epitope may be critical to the flexibility of the NP molecule that makes the RNA template accessible during RNA synthesis.

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.

Paradoxical effects of Sendai virus DI RNA size on survival: inefficient envelopment of small nucleocapsids.

In the assembly of nonsegmented negative-stranded RNA viruses, such as Sendai virus, the envelopment process allows extensively deleted genomes to survive by transmission from cell to cell in virus particles. To assess the impact of the sizes of such defective-interfering (DI) genomes on their survival, we performed competition tests among various species. Among copy-back DI RNAs, a 450-base species was gradually eliminated from DI virions by a 1200-base species, and the latter was independently eliminated by a 2800-base species. In each case, the smaller RNA species was synthesized and encapsidated at least as efficiently as the larger species, revealing that the level of competition was at the envelopment step in virus assembly. In contrast to the results obtained with the copy-back DI RNAs, repeated high multiplicity passage of a family of four internally deleted RNAs eliminated all but the smallest species, comprising about 1600 bases. Both sets of findings can be reconciled by the hypothesis that the efficiency of DI nucleocapsid envelopment decreases progressively when the RNA is smaller than about 1600 bases.

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.

Assembly of influenza ribonucleoprotein in vitro using recombinant nucleoprotein.

The influenza A virus nucleoprotein previously expressed in Escherichia coli after fusion to 32 heterologous amino acids has now been purified and tested for its ability to form complexes with RNA in vitro. By using a simple filter binding assay, we show that ribonucleoprotein (RNP) complexes form readily with single-stranded RNA of viral or nonviral origin but not with double-stranded RNA. The RNP complexes formed were similar to authentic influenza virus RNPs in appearance under the electron microscope, in buoyant density in gradients of cesium chloride, and in sensitivities to pancreatic ribonuclease, to chaotropic reagents, and to high salt. We conclude that nucleoprotein synthesized in E. coli has all the properties required for correct assembly into ribonucleoprotein.

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.

Nucleotide sequences that affect replicative and transcriptional efficiencies of Sendai virus deletion mutants.

Structural features of the genomes of virus deletion mutants (DI virions) influence their replication efficiency. Among nonsegmented negative-strand RNA viruses, substitution of the genomic 3' terminus by a complementary copy of the 5' terminus (so-called "copy-back" sequence) could enhance replication either because the new 3' end is a better promoter of RNA replication or because DI RNAs that possess this sequence are incapable of acting as templates for transcription. Here we provide evidence that both mechanisms operate in mixed infections with Sendai virus DI RNAs. RNAs incapable of transcription always outgrew RNA species that were transcribed. This was true even when the 3'-terminal sequence of the untranscribed RNA was identical to the genomic 3' terminus, as in the case of an internally deleted DI genome (RNA Ra) rendered transcriptionally inert by point mutations of bases 47 and 51 at the 5' end of the positive-strand leader RNA template. Nevertheless, Ra was outgrown by a copy-back DI RNA, indicating that the 3' genomic end of Ra is a less efficient site for replication initiation than the copy-back sequence.

Nucleotide sequences responsible for generation of internally deleted Sendai virus defective interfering genomes.

The deletion points of four internally deleted defective interfering (DI) RNA species (7a, 7b, 7c, and 7d) that reside in a single Sendai virus strain were defined by nucleotide sequencing. DI RNA 7a (Mr 1.24 x 10(6)) retained the entire NP gene with the complete NP protein-coding sequence, except for the last two U residues of the polyadenylation signal, fused to an 1800-nucleotide sequence comprising 5'-terminal genome and adjacent L gene sequences. DI RNA 7b (Mr, 0.70 x 10(6)) consisted of 100 3'-terminal nucleotides fused to 1900 5'-terminal bases; the deletion point in the NP gene precedes the NP protein initiation codon. DI RNA 7c (Mr 0.55 x 10(6)) retained 420 3'-terminal and 1150 5'-terminal nucleotides. The sequence just downstream of the sequenced deletion site is M gene specific, indicating that 7c arose from at least two deletion events and that it comprises NP, M, and L gene fragments. Transcription of RNA 7c could yield an MRNA encoding a fusion protein with a 14,000 Mr (N-terminal NP sequence fused to out of frame M-specific amino acids). DI RNA 7d (Mr 0.92 x 10(6)) retained 1027 3'-terminal nucleotides fused to 1600 bases from the 5'-terminus. It has an open reading frame for a 33,000 Mr N-terminal NP protein fragment. Nucleotide sequences flanking each deletion and just downstream of the NP gene deletion site suggested that these DI genomes were generated by a copy-choice mechanism, involving polymerase jumping during replication of negative polarity virus genome templates. In this process, the termination and reinitiation of RNA synthesis would involve recognition of sequences that regulate virus genome transcription and replication.

Expression of Sendai virus defective-interfering genomes with internal deletions.

Sendai virus strain 7 has been shown to contain four defective interfering (DI) RNA species in which both genome termini and various adjacent fragments of the 3'-terminal NP gene and 5'-terminal L gene are represented, but most or all internal genes and gene boundaries are deleted. Previous sequence analyses of these mutant RNAs suggested that all four possessed the transcription initiation signal of the NP gene and the transcription termination signal of the L gene. The supposition that these signals should specify transcripts has now been supported by oligo(dT) selection of four DI 7 specific RNA species that had apparent molecular weights slightly lower than each DI genome. DI RNA 7a, which contains the entire NP gene, except for two U residues at the end of the poly(A) initiation signal, appeared to be transcribed solely as a readthrough product. Since DI RNA 7a contains the entire NP protein-coding sequence and DI RNAs 7c and 7d contain fragments of it, whereas DI RNA 7b is devoid of it, only transcripts of RNAs 7c and 7d were expected to specify fusion proteins containing NP gene-specific sequences. A strain 7-induced protein that reacted with monoclonal antibodies against the NP protein had the 33,000 Mr size appropriate for the translation product predicted by the sequence of RNA 7d. Other proteins of lower molecular weight were seen only in cells infected by strain 7, but they did not react with NP-specific antibody and their translation in vitro was not blocked by hybridization to an NP gene-specific oligonucleotide. Therefore, at least some of these proteins may be cellular products induced by DI virus infection. These DI transcripts and translation products may influence interference with replication of the parental helper virus.

Translational modulation in vitro of a eukaryotic viral mRNA encoding overlapping genes: ribosome scanning and potential roles of conformational changes in the P/C mRNA of Sendai virus.

Expression of proteins from three overlapping genes in a single mRNA species of Sendai virus was modulated in a cell-free rabbit reticulocyte translation system. Hybrid-arrested translation by oligodeoxynucleotides complementary to specific regions of the mRNA that specifies the viral P, C, and C' proteins demonstrated that ribosomes scan the RNA from its 5' end to find initiation codons, and suggested that the secondary structure of the mRNA influences the selection of alternative initiation codons. Translational modulation of P, C, and C' proteins by Mg++ and spermidine indicated that RNA folding is involved in this selection process.

Constitutively phosphorylated residues in the NS protein of vesicular stomatitis virus.

The NS protein of vesicular stomatitis virus is an auxiliary protein in the virus core (nucleocapsid) that plays a role in virus-specific RNA synthesis. NS exhibits a variety of phosphorylated forms, and the degree of phosphorylation correlates with the rate of RNA synthesis. However, chymotryptic peptide mapping has indicated that all forms of NS share a common cluster of phosphorylated residues. To locate these residues in the primary structure of the molecule, we performed a series of residue-specific chemical and enzymatic cleavages and separated radiophosphate-labeled peptides by gel electrophoresis. The data indicate that the constitutively phosphorylated sites in NS molecules reside in the amino-terminal region of the molecule, between residues 35 and 78. The previously reported resistance of the phosphoamino acids in this region to dephosphorylation by exogenous phosphatase suggests that this domain is embedded within the tertiary structure of the molecule or involved in quaternary interactions. In contrast, the amino acid residues that are phosphorylated secondarily, making NS more active in RNA synthesis, reside in more exposed regions of the molecule.

Polytranscripts of Sendai virus do not contain intervening polyadenylate sequences.

Discrete high-molecular-weight RNA species with the properties of polytranscripts were observed in poly(A)-rich RNA extracted from Sendai virus-infected cells. These RNA species were virus specific, being synthesized in the presence of actinomycin D, but not seen in uninfected cells. They were not genome or antigenome fragments, since they were not encapsidated, as shown by their destruction when ribonuclease was added to cell homogenates and by their absence from the RNA fractions that did not bind to oligo(dT)-cellulose. Two lines of evidence indicated that the gene-specific regions of these polytranscripts were not linked by poly(A) sequences, but were faithful copies of virus genomic RNA sequences at gene boundaries. First, a small cDNA clone obtained by reverse transcription of poly(A)-rich RNA species from infected cells contained 90 bases from the 5' terminus of the gene for the P protein and about 600 bases from the 3' end of the downstream gene, which specifies the M protein, the entire cloned sequence being an accurate complement of the genomic RNA. Second, dideoxynucleotide sequencing of poly(A)-rich RNA species primed by virus gene-specific oligodeoxynucleotides revealed read-through products of transcription containing no detectable poly(A). If Sendai virus polytranscripts are intermediates in the production of monocistronic viral mRNAs by a cleavage process, and poly(A) sequences do not link the mRNAs, polyadenylation would have to follow the cleavage step; it seems more likely that these polytranscipts are aberrant transcription products generated by occasional termination failure in a stop-start mechanism of transcription.

Species classification problems in virus taxonomy.

Although the species is the fundamental unit of taxonomy, virologists only recently have begun to classify virus species in a systematic way under the leadership of the International Committee on Taxonomy of Viruses. Progress has been slow and uneven for several reasons: (i) Attempts to sort species are hampered even when the distinction between classification and nomenclature is blurred. Classifying is based on observation and involves deductive reasoning, whereas naming can be as arbitrary as desired, even to the point of dispensing with the traditional Latin binomial form. (ii) Some virologists deny the possibility of applying the species concept to asexual organisms, such as viruses. Those persons are influenced by an obsolete definition of biological species which rests on observed or inferred barriers to sexual reproduction. (iii) New taxonomic tools, such as mathematical (numerical) taxonomy, might be applied profitably to virus classification, but are unfamiliar to many virologists.

Complete sequence of the Sendai virus NP gene from a cloned insert.

A DNA molecule representing all but the three terminal bases of the Sendai virus nucleoprotein (NP) gene, copied from viral mRNA, was inserted into pBR322. The NP insert comprised 1673 bases. The first AUG protein initiation codon, at position 65, began an open reading frame of 1551 bases, encoding a protein of 517 amino acids with an amino acid composition corresponding to previously published data. The NP gene sequence determined in the present work is similar to that described by Shioda et al. [ Nucl . Acids Res. 11, 7317 (1983)], but there are 14 amino acid differences that probably reflect differences in virus strains. The predicted secondary structure of the NP molecule and the locations within that structure of potential protease cleavage sites are in accord with structural domains previously defined by controlled protease digestion.

Complete sequences of the intergenic and mRNA start signals in the Sendai virus genome: homologies with the genome of vesicular stomatitis virus.

All of the consensus intergenic and transcription initiation sequences of the genome of Sendai virus, a paramyxovirus, have been determined. The boundary between the intergenic sequence, 3'-GAA, and the mRNA start signal, 3'- UCCCANUUUC , was identified by sequencing the 5' termini of specific viral mRNA molecules. One of the five intergenic trinucleotides differed from the rest, consisting of 3'- GGG , and single base substitutions were observed in two of the mRNA start signals. The Sendai virus intergenic sequence was similar to the analogous sequence (3'-GA) of vesicular stomatitis virus (VSV), a member of another family of negative-strand RNA viruses, the rhabdoviruses , but there was no sequence homology between the mRNA start signals of the two viruses. Nevertheless, these mRNA start signals were organized in the same way, being ten bases long and possessing two consensus regions, divided by one (Sendai virus) or two (VSV) variable internal nucleotides. These findings extend the evidence that both families of negative-strand RNA viruses descended from a common ancestor and that an archetypal mechanism of transcriptional regulation has been conserved in their evolution.

Sequence of the 5' end of the Sendai virus genome and its variable representation in complementary form at the 3' ends of copy-back defective interfering RNA species: identification of the L gene terminus.

Direct sequencing showed that the 5' termini of several defective interfering RNA species, both fusion and copy-back types, were homologous to the 5' terminus of the Sendai virus genome. Size analyses of spontaneously formed terminal duplexes (stems) of three copy-back defective interfering RNA species revealed variable extents of terminal complementarity, ranging from about 155 to 210 nucleotides. Direct sequencing of the 3' terminus of one of these copy-back RNA species demonstrated its complementarity to the 5'-terminal sequence of the virus genome. This copy-back sequence contained, in complementary form, the 5' terminus of the L gene, comprising the same sequence, 3'-AUUCUUUUU-5', that was previously identified at the 5' ends of the five other major Sendai virus genes.

Molecular clones representing Sendai virus genes P, NP and M.

DNA copies of segments of Sendai virus genes P, NP and M, obtained by reverse transcription of virus mRNA species extracted from infected cells, were cloned in plasmid pBR322. Genes were identified by hybrid-arrested translation of viral mRNAs in vitro. Hybrid selection of NP mRNA confirmed the identity of an NP gene clone. Partial sequencing of this insert showed that it represents the 5'-terminal region of the gene, containing transcription termination signals. Hybridization of DNA inserts to blots of electrophoretically separated, denatured mRNA species indicated that the P, NP and M messages had sizes of 2400, 2100 and 1500 nucleotides, respectively. Specific T1 ribonuclease-resistant oligonucleotides, previously identified in the NP and M genes, were selected by hybridization to the respective inserts. Although most of the inserts are smaller than 500 base pairs, representing no more than 16% of the P gene and 24% of the NP gene, one of the M gene inserts, comprising 700 base pairs, represents almost half of that gene. These cloned virus gene segments will assist further investigations of the molecular biology of this model paramyxovirus.

Sequence relationships between Kirsten retrovirus genomes and the genomes of other murine retroviruses.

RNA sequence relationships between the genomes of the Kirsten murine sarcoma virus (MSV-K) complex, the Kirsten murine leukemia virus (MuLV-K) complex, the Gross murine leukemia virus (MuLV-G), and the Moloney murine leukemia virus (MuLV-M) were investigated. Sedimentation analyses revealed the expected 30 and 34 S RNA subunits in the MSV-K complex and a previously undetected 30 S RNA subunit accompanying the 34 S RNA subunit in the MuLV-K complex. Nucleic acid hybridization data indicated that each Kirsten virus 30 S RNA subunit had about 40% sequence homology with the RNA genome of MuLV-G, although these sequences were only partially homologous between the two 30 S subunits. In contrast, the MuLV-K 34 S RNA subunit had 96% sequence homology with the MuLV-G genome, whereas the MSV-K 34 S RNA subunit displayed only 71% sequence homology with the MuLV-G genome. Similar relationships were indicated by oligonucleotide fingerprinting. The oligonucleotide data, taken with published sequence data on the MuLV-G and MuLV-M genomes, enabled us to construct partial sequence maps of the MuLV-K 34 S RNA subunit and the MSV-K 34 and 30 S RNA subunits. The sequence arrangements indicated that (1) the MuLV-K 34 S RNA subunit is a variant of the MuLV-G genome; (2) the MSV-K 34 S RNA subunit is a recombinant molecule, which maintains the length of its leukemia virus parent; and (3) the MSV-K 30 S RNA subunit may have been generated from the MuLV-K 34 S genome by a two-stage process, culminating in the retention of parental sequences only within the U5 and U3 noncoding segments and within several amino-terminal coding segments. Further examination of published retrovirus genome sequences revealed several strategically situated sets of potential recognition signals for transcription and translation and suggested a model for genetic recombination based on mRNA splicing signals and areas of limited sequence homology. This model may explain how foreign gene elements can be inserted into retrovirus genomes to generate either functional or defective recombinant retroviruses.