Budding efficiency of Sendai virus nucleocapsids: influence of size and ends of the RNA.

The budding efficiency of Sendai virus antigenomes, as well as of defective interfering (DI) nucleocapsids of the deletion and copy-back types, was compared to that of the viral genome during infections of baby hamster kidney (BHK) cells. The antigenomes were shown to bud into virus particles as efficiently as the genomes, arguing for the irrelevance of the nucleocapsid-RNA ends in regulating the efficiency of budding. The DI nucleocapsids, however, were restricted in their budding by factors inversely proportional to their size, arguing for an effect of nucleocapsid size in this process. This restriction in budding, however, appeared to be only expressed under conditions of very efficient DI-RNA replication.

Sendai virus M protein is found in two distinct isoforms defined by monoclonal antibodies.

The use of a monoclonal antibody defines a subset of Sendai virus M protein representing about 30% of total. This M protein acquires, during the hour following synthesis, an epitope not present on the bulk of M. This epitope maturation is observed in acutely as well as in persistently infected cells. It takes place in vivo in absence of other viral proteins, but it is not observed when the protein is synthesized in a reticulocyte lysate. Epitope maturation does not appear to result from phosphorylation, acylation or disulfide bond formation. If immunofluorescent staining seems to indicate a preferential association of this subset of M protein with nucleocapsids, this is not confirmed by immunogold staining or by nucleocapsid isolation. Incubation of cytoplasmic extracts or of purified M protein in conditions which do not favor M to M protein association results in a relative increase of M protein carrying the maturing epitope. It is concluded that M protein exists in two distinct isoforms.

Homooligomerization of the hemagglutinin-neuraminidase glycoprotein of human parainfluenza virus type 3 occurs before the acquisition of correct intramolecular disulfide bonds and mature immunoreactivity.

The posttranslational maturation of the hemagglutinin-neuraminidase (HN) glycoprotein of human parainfluenza type 3 virus (PIV3) was investigated in pulse-chase experiments in which folding was monitored by immunoprecipitation with conformation-dependent antibodies and gel electrophoresis under nonreducing conditions and oligomerization was monitored by chemical cross-linking and sedimentation in sucrose gradients. The acquisition of mature immunoreactivity and the formation of correct intramolecular disulfide bonds were concurrent events, with half-times of approximately 10 to 15 min. The finding that newly synthesized HN had little reactivity with postinfection cotton rat serum or with most of the members of a panel of HN-specific monoclonal antibodies indicated that the major epitopes of the PIV3 HN protein are highly conformational in nature. Chemical cross-linking studies indicated that the mature HN protein is present in homoligomers, which are probably tetramers. These findings are consistent with recent observations for the HN protein of Sendai virus (S.D. Thompson, W.G. Laver, K.G. Murti, and A. Portner, J. Virol. 62:4653--4660, 1988; S. Vidal, G. Mottet, D. Kolakofsky, and L. Roux, J. Virol. 63:892--900, 1989). Surprisingly, analysis of pulse-labeled HN protein by sedimentation on sucrose gradients after labeling periods of as little as 2 min indicated that it was present intracellularly only in oligomeric form. The same results were obtained when the labeling period was preceded by a 1.5-h cycloheximide treatment to clear the endoplasmic reticulum of presynthesized HN protein, which indicated that the oligomerization did not involve the incorporation of newly synthesized monomers into partially assembled oligomers. Subsequent chase incubations did not significantly alter the sedimentation profile or stability of the oligomeric forms, suggesting that oligomers detected after short labeling periods were tetramers. Association with cellular proteins did not appear to be responsible for the sedimentation of newly synthesized HN protein as an oligomer. The absence of a detectable monomeric form of intracellular HN protein raised the possibility that oligomerization is cotranslational, and it is possible that the type II membrane orientation of the HN protein might be an important factor in its mode of oligomerization.

Intracellular stability of nonreplicating paramyxovirus nucleocapsids.

Using Northern blot analysis, we have demonstrated the ability of infectious measles and Sendai virus particles to rescue the intracellular replication of their homologous defective interfering (DI) nucleocapsids up to 3 days and 1 day, respectively, after initial DI infection. The half-life of the paramyxovirus DI nucleocapsids was therefore judged to be similar to that of rhabdoviruses, and to significantly differ from that of orthomyxoviruses. Moreover, we conclude that the intracellular half-life of measles virus DI nucleocapsids makes possible DI replication in the human body after vaccination with a DI-contaminated attenuated live virus, even when this vaccination represents a low multiplicity of infection.

Drastic immunoreactivity changes between the immature and mature forms of the Sendai virus HN and F0 glycoproteins.

The immunoreactivity of the Sendai virus HN and F0 glycoproteins was shown to mature before reaching the final form exhibited by the native mature proteins. The maturation process differed for the two proteins. The native F0 immunoreactivity was shown to be defined cotranslationally, and the addition of high-mannose sugar residues may represent the final step in defining the maturation of immunoreactivity. On the other hand, native HN immunoreactivity was slowly fashioned during the hour after the completion of protein synthesis. Although addition of high-mannose sugar could constitute a necessary step in this slow maturation process, it was shown not to be sufficient. Processing of high-mannose sugars and HN self-association in homodimers and homotetramers were investigated as possible steps involved in the slow maturation of HN immunoreactivity. They were found not to play a significant role. On the other hand, conformational changes presumably took place during the maturation of HN immunoreactivity. Drastic immunoreactivity differences were also demonstrated between the native and denatured forms of the glycoproteins. Possible implications of these results in defining the pathways of glycoprotein synthesis are discussed.

Reduced temperature can block different glycoproteins at different steps during transport to the plasma membrane.

Reduced temperature has been shown to block the cell surface expression of Sendai virus haemagglutinin-neuraminidase (HN) and fusion (F0) glycoproteins at different steps of their intracellular transport. At 20 degrees C, HN was confined to the rough endoplasmic reticulum or cis Golgi compartment, while F0 acquired complete resistance to digestion by endo-beta-N-acetylglucosaminidase-H and therefore was blocked at a more distal location in the pathway of cell surface expression. The significance of these results for different pathways of transport to the cell surface is discussed.

Membrane orientation and oligomerization of the small hydrophobic protein of human respiratory syncytial virus.

Previous work has demonstrated that the small hydrophobic (SH) protein of human respiratory syncytial virus (RSV) A2 strain is a 64 amino acid integral membrane protein that accumulates intracellularly as an unglycosylated major species (SH0), a minor species truncated at the amino terminus and two N-glycosylated species one of which contains a further addition of polylactosamine. In this study, the membrane orientation of SH0 was mapped by trypsinization of intact RSV-infected cells followed by washout, lysis and immunoprecipitation of protected fragments with antisera specific for the protein termini. This showed that the C terminus is extracellular and the SH protein was not detectably palmitylated. Analysis of the SH protein by sedimentation on sucrose gradients showed that it rapidly assembles into a homo-oligomer that co-sediments with the F protein tetramer. Interestingly, all forms of the SH protein were found in the oligomeric fraction. Chemical cross-linking generated species which appeared to represent dimers, trimers, tetramers and pentamers as well as a minor species of 180K which might correspond to the oligomeric form detected by sucrose gradient sedimentation.

Wide occurrence of measles virus subgenomic RNAs in attenuated live-virus vaccines.

Nine measles vaccine preparations, including four different viral strains, provided by eight different manufacturers were analysed by Northern blot for the nature of their nucleocapsid RNAs. Out of nine preparations, six were shown to contain subgenomic RNAs, along with the full length genomic RNA. Presence or absence of the subgenomic RNAs correlated strictly with the viral strains used. The role of the defective interfering particles in measles virus vaccine attenuation, and in its seroconversion efficacy upon vaccination, as well as the potential hazard of the presence of defective interfering particles in live-virus vaccine preparations, is discussed.

Post-translational processing and oligomerization of the fusion glycoprotein of human respiratory syncytial virus.

The post-translational maturation of the fusion protein (F) of human respiratory syncytial virus was investigated. Chemical cross-linking experiments indicated that F forms homotetramers and provided evidence that the intermonomer contacts involve primarily the F1 subunit. Homooligomerization as measured by sedimentation in sucrose gradients was insensitive to carbonyl cyanide m-chlorophenylhydrazone, indicating that it occurs in the endoplasmic reticulum. Cleavage of the F0 precursor to yield the F1 and F2 subunits was blocked by monensin or brefeldin A, indicating that it takes place in distal cisternae of the trans Golgi compartment or in the more distal trans Golgi network. The F0 precursor was not detected at the cell surface in surface immunoprecipitation experiments, indicating that cleavage is intracellular. The appearance of the cleaved F1 protein at the cell surface was concurrent with that of the attachment glycoprotein (G); this and other information indicated that the type 2 membrane orientation of G is not obligatorily associated with a reduced transit rate. Examination of F maturation in the presence of tunicamycin provided evidence that its expression at the cell surface depends upon cleavage and not directly upon glycosylation.

Oligomerization and post-translational processing of glycoprotein G of human respiratory syncytial virus: altered O-glycosylation in the presence of brefeldin A.

The post-translational maturation of the attachment G glycoprotein of human respiratory syncytial virus (RSV) was investigated. The G protein formed homo-oligomers which sedimented in sucrose gradients at the same rate as the fusion F protein tetramer. Oligomerization of the G protein was insensitive to carbonylcyanide m-chlorophenylhydrazine, showing that this step occurs in the endoplasmic reticulum prior to O-glycosylation which initiated in the trans-Golgi compartment. The sedimentation of the G protein oligomer was essentially unchanged by the subsequent addition of O-linked sugars. This indicated that their contribution to the M(r) of the G protein is less than that estimated by electrophoretic mobility. It also suggested that O-glycosylation is not an important determinant of G protein oligomerization and, by implication, of polypeptide folding. The G protein is palmitylated. In short labelling pulses, the G protein accumulated as two species of 48K and 50K which contained only N-linked sugars, whose difference in M(r) was due solely to an N-linked sugar, which both assembled into oligomers, but which differed in the rate of subsequent O-glycosylation. The G protein was not detectably O-glycosylated in the presence of monensin, confirming previous work. In the presence of brefeldin A (BFA), it accumulated as a partially O-glycosylated species (BFA-G) of 68K to 78K. But further analysis by chase incubations following BFA-washout, by lectin-binding, and by glycosidase treatment suggested that BFA-G was not a fully authentic processing intermediate. In particular, some of the O-linked side-chains of the BFA-G protein were found to be sialylated. Rather than being a normal step in processing, this sialylation probably was due to altered distribution or activity of sialyltransferases during BFA treatment and may have resulted in the premature termination of elongation of some of the O-linked side-chains. Thus, these studies (i) indicate that O-glycosylation of the G protein begins in the trans-Golgi compartment and (ii) suggest that O-glycosylation is completed in as a subsequent compartment, but this latter suggestion is complicated by the evidence that the BFA-G protein is not a fully authentic intermediate.(ABSTRACT TRUNCATED AT 400 WORDS)

The Sendai virus matrix protein appears to be recruited in the cytoplasm by the viral nucleocapsid to function in viral assembly and budding.

The matrix (M) protein is viewed as the regulator of paramyxovirus particle assembly and budding. Accordingly it was observed to be mutated, and/or decreased in amount, in cases where virus particle production was significantly reduced. Here, a non-productive [non-defective and defective interfering (DI)] Sendai virus infection of COS cells is presented where virus particle production is abolished in the presence of a normal amount of intracellular M protein. In this infection the haemagglutinin-neuraminidase envelope glycoprotein is shown to be dispensable for virion production, and the fusion (F0) envelope glycoprotein behaves as in a productive infection. The M protein is shown to accumulate in perinuclear patches within the cytoplasm. In contrast, localization in the plasma membrane is observed in productive infections. However in both productive and non-productive infections a significant fraction of M protein is found in association with cellular membranes. The M protein-membrane association is shown to take place in the absence of any other viral component, and the M protein-membrane complex exhibits properties similar to those observed for the integral membrane protein F0. However these properties are distinct from those of the phosphoprotein, which is thought to associate with membranes in a non-specific manner. Concomitant with the cytoplasmic accumulation of M protein and the reduction of virus particle production in this non-productive infection, DI nucleocapsids are shown not to associate with cellular membrane fractions. This is a property which coincides with their poor envelopment in virus particles. Taken together, these data indicate the need for M protein to be recruited at the perinuclear membranes by the nucleocapsids to participate in viral assembly and budding. This view is consistent with a process of viral assembly taking place on internal cytoplasmic membranes rather than at the plasma membrane.

Addition of high-mannose sugars must precede disulfide bond formation for proper folding of Sendai virus glycoproteins.

The role of glycosylation and of disulfide bonds in the formation of the native structure of the Sendai virus hemagglutinin-neuraminidase (HN) and fusion (F0) glycoproteins was studied. In contrast to the HN and F0 synthesized in vivo, the proteins made from pSP6 transcripts in reticulocyte lysates, whether glycosylated or not, were not recognized by monoclonal antibodies or polyclonal rabbit sera raised against the native proteins; they efficiently reacted only with rabbit antisera raised against the reduced sodium dodecyl sulfate-denatured proteins. These in vitro-made proteins, however, did not contain disulfide bonds. The proteins made in vivo in the presence of tunicamycin, which were also not recognized by the anti-native protein antibodies, did contain disulfide bonds, but they were mainly incorrect interchain disulfide bonds. Moreover, while F0 acquired proper disulfide bonds as soon as it was synthesized under normal conditions in vivo, the disulfides were formed in HN only after a lag of 10 to 30 min. This lag coincides with the delay observed in HN native structure formation. We therefore conclude that the maturation of the HN and F0 proteins depends on the formation of proper intramolecular disulfide bonds, which in turn depends on the previous addition of high-mannose sugars.

A Sendai virus vector leading to the efficient expression of mutant M proteins interfering with virus particle budding.

A Sendai virus expression vector in the form of a transcribing copy-back defective interfering RNA was constructed and shown to efficiently express a tagged matrix protein in the only context of a Sendai virus infection. In an attempt to identify relevant M protein domains involved in viral assembly and budding, a series of deletion mutants were tested for their ability to bind to cellular membrane fractions. The deletion of a region spanning amino acids 105-137 significantly decreased this binding when the protein was expressed in a system driven by the T7 RNA polymerase away from any other viral proteins. Plus or minus charges were introduced in the hydrophobic portion of a predicted amphiphilic helix in this region, and M proteins with altered membrane binding properties were produced. The genes encoding these mutant M proteins were then inserted in the Sendai virus vector and shown to be expressed at levels similar to that of the endogenous wild-type M protein. The presence of a negative charge in the hydrophobic region of the putative amphiphilic helix prevented the incorporation of the mutant protein into virus particles and appeared to decrease the efficiency of virus particle budding. In contrast, the introduction of a positive charge appeared to increase the M mutant uptake into virions. The use a Sendai virus vector has therefore been shown instrumental in the identification of mutant M proteins interfering with the viral assembly-budding process.