Maturation of the envelope glycoproteins of Newcastle disease virus on cellular membranes

Interaction between the respiratory syncytial virus G glycoprotein cytoplasmic domain and the matrix protein

Paramyxovirus assembly at the cell membrane requires the movement of viral components to budding sites and envelopment of nucleocapsids by cellular membranes containing viral glycoproteins, facilitated by interactions with the matrix protein. The specific protein interactions during assembly of respiratory syncytial virus (RSV) are unknown. Here, the postulated interaction between the RSV matrix protein (M) and G glycoprotein (G) was investigated. Partial co-localization of M with G was demonstrated, but not with a truncated variant lacking the cytoplasmic domain and one-third of the transmembrane domain, in cells infected with recombinant RSV or transfected to express G and M. A series of G mutants was constructed with progressively truncated or modified cytoplasmic domains. Data from co-expression in cells and a cell-free binding assay showed that the N-terminal aa 2-6 of G play a key role in G-M interaction, with serine at position 2 and aspartate at position 6 playing key roles.

Disulfide bond formation is a determinant of glycosylation site usage in the hemagglutinin-neuraminidase glycoprotein of Newcastle disease virus

Determinants of glycosylation site usage were explored by using the hemagglutinin-neuraminidase (HN) glycoprotein of the paramyxovirus Newcastle disease virus. The amino acid sequence of the HN protein, a type II glycoprotein, has six N-linked glycosylation addition sites, G1 to G6, two of which, G5 and G6, are not used for the addition of carbohydrate (L. McGinnes and T. Morrison, Virology 212:398-410, 1995). The sequence of this protein also has 13 cysteine residues in the ectodomain (C2 to C14). Mutation of either cysteine 13 or cysteine 14 resulted in the addition of another oligosaccharide chain to the protein. These cysteine residues flank the normally unused G6 glycosylation addition site, and mutation of the G6 site eliminated the extra glycosylation found in the cysteine mutants. These results suggested that failure to form an intramolecular disulfide bond resulted in the usage of a normally unused glycosylation site. This conclusion was confirmed by preventing cotranslational disulfide bond formation in cells by using dithiothreitol. Under these conditions, the wild-type protein acquired extra glycosylation, which was eliminated by mutation of the G6 site. These results suggest that localized folding events on the nascent chain, such as disulfide bond formation, which block access to the oligosaccharyl transferase are a determinant of glycosylation site usage.

Antigenic epitope characterization of matrix protein of Newcastle disease virus using monoclonal antibody approach: contrasting variability amongst NDV strains

A panel of 15 monoclonal antibodies (MABs) against matrix (M) protein of Newcastle disease virus (NDV) was obtained and the specificity towards the M protein was proven by radioimmunoprecipitation assay and antigen capture enzyme-linked immunosorbent assay (ELISA). Further studies were directed to antigenic epitope mapping of the M protein by means of this panel. The epitope characterization was performed by competitive antibody-binding assay by means of labelling each MAB with biotin [3]. At least three clear non-overlapping and two partially overlapping groups were determined, each including four, one, eight, one, and one MAB, respectively. All the above MABs appeared to be induced by structural epitopes formed in conditions of tertiary structure of the native M antigen. Twelve reference and 51 recently isolated local NDV strains have been studied by means of this MAB panel, several lineages having been revealed. The high stability of some epitopes and different variability of the others was demonstrated. No correlation between the above lineages and some other properties of the studied NDV strains (host specificity, date and place of isolation) has been found.

Effects of the components of Newcastle disease virus on the structural order of lipid assemblies

The membrane M-protein of Newcastle disease virus is localized directly beneath the lipid bilayer. Although this protein is the major constituent of the virus, its structural relationship to the lipid or to the other viral component hemagglutinin-neuraminidase, the so called HN-glycoprotein, is still unknown. The effects of either M-protein alone or both M-protein and HN-glycoprotein on the lipid assemblies in reconstituted liposomes were determined by differential polarized phase fluorometry, steady-state fluorescence anisotropy and emission lifetime measurements. It is demonstrated that the degree of rotation of fluorophores in reconstituted liposomes is restricted by the molecular packing of lipids in the bilayer and this in turn can be correlated with the structural order of the lipids in the membrane. The experimental results show that the structural order parameters calculated from the fluorescence measurements are strongly influenced by the presence of both M-protein and HN-glycoprotein in the lipid assemblies.

Cloning and expression of NDV hemagglutinin-neuraminidase cDNA in a baculovirus expression vector system

The hemagglutinin-neuraminidase (HN) gene of the Hitchner B1 strain of Newcastle disease virus (NDV) was cloned as a cDNA and inserted into a baculovirus expression vector. The recombinant HN (recHN) expressed in Spodoptera frugiperda cells had both hemagglutinating and neuraminidase activities both of which were inhibited by polyclonal anti-NDV sera or a monoclonal antibody (MAb) against HN. Infected insect cells could hemadsorb chicken red blood cells suggesting that the recHN is properly glycosylated and transported to the cell surface. A 67-kDa recHN precursor and a 74-kDa, presumably mature, recHN from infected cells were detected by Western blot analysis and were found to comigrate with similar proteins from NDV-infected chick embryo fibroblast cells. The kinetics of synthesis of recHN was similar to that for polyhedrin and some HN appeared in the extracellular medium. HN was copurified with extracellular virus (ECV) from the extracellular medium and was used to immunize chickens. The anti recHN serum was specific to NDV in both ELISA and Western blot analysis.

Mature, cell-associated HN protein of Newcastle disease virus exists in two forms differentiated by posttranslational modifications

Characterization of the posttranslational modifications of the mature, cell-associated hemagglutinin-neuraminidase (HN) protein of Newcastle disease virus (NDV) revealed that the HN protein exists in two forms differentiated by disulfide bonds and glycosylation. One form, HNa, contains intermolecular disulfide bonds and is endoglycosidase H partially resistant. The other form, HNb, is not linked by disulfide bonds and is endoglycosidase H sensitive. Both forms of the protein are modified with fucose indicating transport to the Golgi membranes. Both forms are detected at the cell surface by monoclonal antibody. Furthermore, both forms are transported to the cell surface with identical kinetics. HNa is incorporated into virions. HNb is not incorporated into virions and is presumably degraded. The cDNA derived from the HN gene was expressed from a retrovirus vector. The majority of the protein expressed was in the nonvirion-associated form b. Evidence is presented that the level of gene expression determines the ratio of the two forms of HN protein. At high levels of expression, the virion-associated form is favored while at low levels of expression the nonvirion-associated form is favored. The results presented have implications for persistent infections as well as expression of viral genes from different vectors.

Dynamics of functional maturation and inactivation of HN glycoprotein in NDV-infected chick embryo fibroblasts

In avirulent NDV strain-infected chick embryo cells treated with cycloheximide at different intervals post infection a decrease of the level of hemagglutinating (HA) and neuraminidase (Nase) activities was observed. Studies on this system led to conclusion that the HA-Nase (HN) glycoprotein molecules are unstable and the actual amount of the functionally active (mature) HN entities is determined by a dynamic equilibrium between the antidromic processes of the HN functional maturation and inactivation. Kinetic studies on the actual intracellular levels of the HA and Nase activities using 5 min intervals of their detection after the cycloheximide treatment permitted to uncouple the processes of the HN maturation and inactivation. Analytical part of the studies made it possible to compute quantitative parameters of the involved processes: (a) pool size of the functionally nonactive HN precursors, (b) time needed for their functional maturation, and (c) rate of their inactivation.

Translation and membrane insertion of the hemagglutinin-neuraminidase glycoprotein of Newcastle disease virus

The hemagglutinin-neuraminidase (HN) protein of paramyxoviruses is likely in the unusual class of glycoproteins with the amino terminus cytoplasmic and the carboxy terminus lumenal or external to the cell. The properties of the membrane insertion of the HN protein of Newcastle disease virus, a prototype paramyxovirus, were explored in wheat germ extracts containing microsomal membranes. HN protein was inserted into membranes cotranslationally, resulting in a glycosylated protein completely resistant to trypsin and proteinase K digestion. No detectable posttranslation insertion occurred. Insertion required signal recognition particle. Signal recognition particle in the absence of membranes inhibited HN protein synthesis. Comparisons of the trypsin digestion products of the HN protein made in the cell-free system with newly synthesized HN protein from infected cells showed that the cell-free product was in a conformation different from that of the pulse-labeled protein in infected cells. First, trypsin digestion of intact membranes from infected cells reduced the size of the 74,000-dalton HN protein by approximately 1,000 daltons, whereas trypsin digestion of HN protein made in the cell-free system had no effect on the size of the protein. Second, trypsin digestion of Triton X-100-permeabilized membranes isolated from infected cells resulted in a 67,000-dalton trypsin resistant HN protein fragment. A trypsin-resistant core of comparable size was not present in the digestion products of in-vitro-synthesized HN protein. Evidence is presented that the newly synthesized HN protein in infected cels contain intramolecular disulfide bonds not present in the cell-free product.

Nucleotide sequence of the gene encoding the Newcastle disease virus hemagglutinin-neuraminidase protein and comparisons of paramyxovirus hemagglutinin-neuraminidase protein sequences

The nucleotide sequence of cloned cDNA copies of the mRNA encoding the Newcastle disease virus (NDV), strain A-V, hemagglutinin-neuraminidase (HN) protein was determined. A single open reading frame in the sequence encodes a protein of 570 amino acids with a calculated molecular weight of 62,280. The predicted protein sequence contains only one obvious potential membrane spanning region, located 27 amino acids from the amino terminus of the sequence. The predicted sequence contains 6 glycosylation sites and 14 cysteine residues. Comparison of the NDV HN protein sequence with three other paramyxovirus HN protein sequences reveals two regions that have homologies in all four sequences. The conserved cysteine residues are clustered in these two regions. One conserved region is located near the middle of the predicted sequence while the second region is in the carboxy terminal third of the molecule. The presence of conserved regions suggests the importance of these areas of the molecule in the structure or function of the protein.

Translation and membrane insertion of the hemagglutinin-neuraminidase glycoprotein of Newcastle disease virus

The hemagglutinin-neuraminidase (HN) protein of paramyxoviruses is likely in the unusual class of glycoproteins with the amino terminus cytoplasmic and the carboxy terminus lumenal or external to the cell. The properties of the membrane insertion of the HN protein of Newcastle disease virus, a prototype paramyxovirus, were explored in wheat germ extracts containing microsomal membranes. HN protein was inserted into membranes cotranslationally, resulting in a glycosylated protein completely resistant to trypsin and proteinase K digestion. No detectable posttranslation insertion occurred. Insertion required signal recognition particle. Signal recognition particle in the absence of membranes inhibited HN protein synthesis. Comparisons of the trypsin digestion products of the HN protein made in the cell-free system with newly synthesized HN protein from infected cells showed that the cell-free product was in a conformation different from that of the pulse-labeled protein in infected cells. First, trypsin digestion of intact membranes from infected cells reduced the size of the 74,000-dalton HN protein by approximately 1,000 daltons, whereas trypsin digestion of HN protein made in the cell-free system had no effect on the size of the protein. Second, trypsin digestion of Triton X-100-permeabilized membranes isolated from infected cells resulted in a 67,000-dalton trypsin resistant HN protein fragment. A trypsin-resistant core of comparable size was not present in the digestion products of in-vitro-synthesized HN protein. Evidence is presented that the newly synthesized HN protein in infected cels contain intramolecular disulfide bonds not present in the cell-free product.

The hemagglutinin-neuraminidase (HN) gene of Newcastle disease virus strain Italien (ndv Italien): comparison with HNs of other strains and expression by a vaccinia recombinant

A cDNA library was constructed with poly(A+) mRNA from cells infected with the virulent Italien NDV strain. A clone that hybridized to the HN gene mRNA was sequenced. A long open reading-frame encodes for a protein of 571 amino acids, with a calculated molecular weight of 61,900, including 13 cysteine residues and six potential glycosylation sites. To define the sequence changes that occurred in the avian paramyxovirus hemagglutinin-neuraminidase (HN) during the evolution of virulence, we have studied the HNs of the virulent Italien NDV strain, the mesovirulent Beaudette strain and the nonvirulent Hitchner strain. The majority of amino acid variations are conservative changes but they cluster at 4 preferential sites in the putative head of HN. The clusters of amino acid substitutions are intimately associated or overlap with regions of HN rich in charged amino acid residues and in cysteines. The latter are conserved not only between HNs from all 3 NDV strains but also between HNs of 4 different paramyxoviruses, NDV, SV 5, Sendai and PI 3. The HN coding sequence was inserted into the genome of vaccinia virus under the control of vaccinia P 7.5 K transcriptional regulatory sequences. Expression of native HN proteins at the surface of recombinant HN vaccinia-infected cells was demonstrated by indirect immunofluorescence with 2 anti-HN monoclonals.

Conformational change in a viral glycoprotein during maturation due to disulfide bond disruption

The fusion glycoprotein of Newcastle disease virus is synthesized as an inactive precursor, F0. During intracellular transport and maturation, F0 undergoes a conformational change resulting from the loss of intramolecular disulfide bonds. F0 is also cleaved to yield F1, F2, the active, membrane-fusing form of the protein. Two monoclonal antibodies were used to explore this conformational change and its relationship to cleavage. These antibodies failed to precipitate the pulse-labeled fusion protein but did precipitate the F0 and the F1, F2 forms of the "chase" fusion protein. Use of the inhibitors carbonylcyanide m-chlorophenylhydrazone and monensin showed that the fusion protein acquired the ability to react with the monoclonal antibodies after it left the rough endoplasmic reticulum but before it left the medial Golgi membranes and before it was cleaved. The acquisition of antigenicity correlates with the disruption of intramolecular disulfide bonds during transit through the cell. This correlation was directly confirmed. The pulse-labeled fusion protein could be recognized by both monoclonal antibodies if the protein was first reduced. The formation and disruption of intramolecular disulfide bonds as a posttranslational modification of glycoproteins is discussed.

Topological and operational delineation of antigenic sites on the HN glycoprotein of Newcastle disease virus and their structural requirements

Monoclonal antibodies to the hemagglutinin-neuraminidase glycoprotein of Newcastle disease virus have identified four antigenic sites on the glycoprotein, which are topologically and operationally discriminated from one another. To define the metabolisms and cellular compartments required for formation of the individual antigenic sites, a panel of monoclonal antibodies were examined for their reactivity with the nascent and variously processed forms of the antigen molecules in combination with the use of inhibitors of glycosylation (tunicamycin and N-methyl-1-deoxynojirimycin) and glycoprotein transport (carbonyl cyanide m-chlorophenylhydrazone and monensin). Reactivity was also examined with the antigen molecules deglycosylated by endoglycosidase F and with the antigen molecules reduced by 2-mercaptoethanol. The results taken together suggest that posttranslational organization of the glycoprotein is important for all four of the antigenic sites. At the same time, there appeared to be marked site-specific requirements with respect to glycosylation and disulfide bond formation. However, all of these metabolic requirements were found to be provided within the rough endoplasmic reticulum, and no further processing of the antigen molecules appeared to be necessary for the formation of any of the antigenic sites.

Nucleotide sequence of the gene encoding the Newcastle disease virus fusion protein and comparisons of paramyxovirus fusion protein sequences

The nucleotide sequence of cloned cDNA copies of the mRNA encoding the Newcastle disease virus fusion protein was determined. A single open reading frame in the sequence encodes a hydrophobic protein of 553 amino acids with a calculated molecular weight of 58 978. The previously determined protein sequence of the amino terminus of the F1 (Richardson, G.D. et al. (1980) Virology 105, 205-222) was located within the predicted protein sequence. The predicted protein sequence contains a hydrophobic stretch of 29 amino acids near the carboxy terminal end and likely represents the membrane spanning region of the protein. The F2 portion of the sequence contains one glycosylation site while F1 contains four which are potentially used. The predicted sequence contains 13 cysteine residues. Comparison of the NDV fusion protein sequence with three other paramyxovirus fusion protein sequences reveals little homology common to all four viruses except for the amino terminus of the F1 proteins. However, the positions of the cysteine residues within the sequence are conserved, particularly among the members of the paramyxovirus subgroup, suggesting the importance of disulfide bond formation in the conformation of paramyxovirus fusion proteins.

Intracellular maturation of mumps virus hemagglutinin-neuraminidase glycoprotein: conformational changes detected with monoclonal antibodies

Monoclonal antibodies elicited by immunization with mumps virus glycoproteins were selected with either native or chymotrypsin-treated mumps virus in an enzyme-linked immunosorbent assay. Group I antibodies which preferentially recognized chymotrypsin-treated virus failed to recognize native mumps virus hemagglutinin-neuraminidase (HN). They did react with sodium dodecyl sulfate-denatured HN and the HN chymotryptic fragments HNc2' (molecular weight, 41,000) and HNc1 (molecular weight, 32,000) after transfer to nitrocellulose paper. In contrast, group II antibodies, which preferentially recognized native virus in the enzyme-linked immunosorbent assay, reacted with native HN but failed to bind HN after sodium dodecyl sulfate denaturation. These two groups of monoclonal antibodies were used to define the maturation pathway of the mumps virus HN in infected cells. The HN initially appeared as a 76,000-molecular-weight polypeptide and was recognized only by group I antibodies. A truncated form of HN, HNT (molecular weight, 63,000), was synthesized in the presence of tunicamycin and was also recognized only by group I antibodies. The 76,000-molecular-weight HN was rapidly converted to a 74,000-molecular-weight polypeptide; this form of HN was recognized only by group II antibodies. The oligosaccharide side chains were modified, and intermolecular disulfide bonds were formed as HN was transported to the cell surface. The disulfide-linked oligomers of HN were direct precursors of the HN found in mature virus.

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.

Cytochalasin D accelerates the release of Newcastle disease virus from infected cells

The role of the cellular cytoskeleton in Newcastle disease virus (NDV) infection was explored in two ways. First, the extent of the association of viral proteins with the cytoskeletal fraction of chicken embryo cells was determined. NDV-infected cells, pulse-labelled with [35S]methionine with or without a subsequent chase, were fractionated into Triton X-100-soluble and cytoskeletal fractions. All NDV proteins become associated with the cytoskeletal fraction of cells subsequent to their synthesis. Mixing experiments provided evidence against nonspecific sticking of proteins with this cell fraction. Second, the functional significance of the cytoskeletal association was explored using the inhibitor cytochalasin D. In the presence of this inhibitor, the rate of release of radioactively labelled virions was accelerated 2.5-fold. Colchicine did not significantly alter the rate of virion release. Virus particles released from cytochalasin D-treated cells had the same density as virions released from untreated cells, but were slightly less infectious and contained less actin. These results suggest that functional microfilaments do not play an obligatory role in viral morphogenesis but rather function to slow virus particle release.

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.

Intracellular processing of the vesicular stomatitis virus glycoprotein and the Newcastle disease virus hemagglutinin-neuraminidase glycoprotein

The kinetics of intracellular transport of the vesicular stomatitis virus (VSV) glycoprotein (G) and the Newcastle disease virus (NDV) hemagglutinin-neuraminidase (HN) glycoprotein in chicken embryo cells were compared. To assay for the appearance of pulse-labelled glycoprotein at the cell surface, an antibody-binding assay was developed which allowed the precipitation of only those molecules on the outside surfaces of infected cells. Using this assay, it was found that pulse-labelled VSV G protein appeared at the cell surface with a half-time of approximately 27 min, while pulse-labelled NDV HN glycoprotein reached the cell surface with a half-time of approximately 78 min. To determine the transit time of these glycoproteins to trans-Golgi membranes, the kinetics of the acquisition of endoglycosidase H resistance was analyzed. The half-time of the transit of the G protein to the trans-Golgi membranes was found to be approximately 13 min while that of the HN glycoprotein was found to be approximately 60 min. Since the G protein migrates to the trans-Golgi membranes with a half-time of 13 min, and the cell surface with a half-time of 27 min, the half-time for the transit between the trans-Golgi membrane and the plasma membrane must be approximately 14 min. In a similar analysis, the half-time for the transit of the HN glycoprotein from the trans-Golgi membrane to the plasma membrane must be approximately 18 min, a time not significantly different from that of the G protein. Thus the difference in the kinetics of the intracellular transport of these two glycoproteins resides primarily in the transit from the rough endoplasmic reticulum to the trans-Golgi membranes. These results argue against a non-selective mechanism for the transport of plasma membrane glycoproteins to the cell surface.

Posttranslational modification and intracellular transport of mumps virus glycoproteins

Analysis of the pronase-derived glycopeptides of isolated mumps virus glycoproteins revealed the presence of both complex and high-mannose-type oligosaccharides on the HN and F1 glycoproteins, whereas only high-mannose-type glycopeptides were detected on F2. Endoglycosidase F, a newly described glycosidase that cleaves N-linked high mannose as well as complex oligosaccharides, appeared to completely cleave the oligosaccharides linked to HN and F2, whereas F1 was resistant to the enzyme. Two distinct cleavage products of F2 were observed, suggesting the presence of two oligosaccharide side chains. Tunicamycin was found to reduce the infectious virus yield and inhibit mumps virus particle formation. The two glycoproteins, HN and F, were not found in the presence of the glycosylation inhibitor. However, two new polypeptides were detected, with molecular weights of 63,000 (HNT) and 53,000 (FT), respectively, which may represent nonglycosylated forms of the glycoproteins. Synthesis of the nonglycosylated virus-coded proteins (L, NP, P, M, pI, and pII) was not affected by tunicamycin. The formation of HN oligomers and the proteolytic cleavage of the F protein were found to occur with the same kinetics. Analysis of the time course of appearance of mumps virus glycoproteins on the cell surface suggested that dimerization of HN and cleavage of F occur immediately after their exposure on the plasma membrane.

Newcastle disease virus stimulates the cellular accumulation of stress (heat shock) mRNAs and proteins

A biological agent, Newcastle disease virus, stimulated the synthesis of stress proteins in cultured chicken embryo cells. Previously, only physical and chemical agents were known to induce these proteins. The levels of translatable stress mRNAs were elevated in cells infected with avirulent or virulent strains; however, stress protein synthesis was stimulated strongly only in cells infected by avirulent strains. As did several other paramyxoviruses, avirulent strains of Newcastle disease virus stimulated the synthesis of glucose-regulated proteins as well as stress proteins. Possible stimuli of the synthesis of these two sets of proteins in paramyxovirus-infected cells are considered.

Coding assignments of the five smaller mRNAs of Newcastle disease virus

The polypeptide coding assignments for the five messengers of the 18S size class of Newcastle disease virus (NDV) RNA have been determined by cell-free translation of individual RNAs separated by gel electrophoresis. Listed in order of their decreasing electrophoretic mobilities in acid agarose-urea gels, the coding assignments of the RNAs were as follows: RNA 1, M protein; RNA 2, P protein; RNA 3, NP; RNA 4, F glycoprotein; and RNA 5, HN glycoprotein. RNA 2 also directed the synthesis of 33- and 36-kilodalton proteins, which were tentatively identified as being overlapping segments of the P protein. The 33- and 36-kilodalton polypeptides could be detected in infected cells, but not in purified virions of NDV. Since the other unique NDV RNA, a 35S species, has been shown previously to encode the viral L protein, these results complete the coding assignments of the six known NDV mRNAs.