Rotational mobility of Sendai virus glycoproteins in membranes of fused human erythrocytes and in the envelopes of cell-bound virions

The rotational mobility of Sendai virus envelope glycoproteins (F, the fusion protein, and HN, the hemagglutinin/neuraminidase) was determined by using erythrosin (ER)-labeled monovalent Fab' antibody fragments directed specifically against either F or HN. By use of time-resolved phosphorescence anisotropy, the rotational mobility of Er-Fab'-viral glycoprotein complexes was studied both in the envelopes of unfused virions bound to erythrocyte ghosts and in the target cell membrane after fusion had occurred. The rotational correlation times (phi) of Er-Fab'-labeled F and HN were rather similar in the envelopes of bound unfused virions, but highly different in membranes of fused cells. The different phi values indicate that F and HN diffuse separately in the target cell membrane and for the major part are not complexed together. The temperature dependence of the phi values of the Er-Fab'-viral glycoprotein complexes revealed a breakpoint at 22 degrees C for the F protein both in bound virions and in the membranes of fused cells, and for the HN proteins in the envelopes of bound virions. In all these cases, the phi values increased between 4 and 22 degrees C, demonstrating a reduction in the rate of rotational diffusion. Further elevation of the temperature reversed the direction of the change in phi. This phenomenon may reflect a temperature-dependent microaggregation of F and HN saturating at ca. 22 degrees C and presumably related to the fusion mechanism since the breakpoint temperature correlates closely with the threshold temperature for virus-cell and cell-cell fusion.(ABSTRACT TRUNCATED AT 250 WORDS)

Interactions of human lymphoblasts with targeted vesicles containing Sendai virus envelope proteins

We have studied the internalization of targeted fusogenic liposome content to leukemic T cells (CEM) in vitro. We describe a method for the covalent coupling of T101 antibody to the surface of liposomes and the incorporation of fusogenic viral protein into the liposome membrane. Hygromycin B, an impermeant inhibitor of protein synthesis, was encapsulated in the targeted fusogenic liposomes and delivered directly to the cytoplasm of leukemic T cells by fusion between the two membranes. The cytotoxic effect was measured by [3H]thymidine incorporation. We show that CEM are rapidly and specifically killed by the drug encapsulated in the targeted fusogenic liposomes. This effect is due to the binding of the liposome by means of the antibody and then to the fusion of the liposome with the targeted cell membrane, mediated by F protein.

Comparison of ion-exchange high-performance liquid chromatography columns for purification of Sendai virus integral membrane proteins

The recovery and separation of the integral membrane proteins, the haemagglutinin-neuraminidase (HN) and the fusion protein (F), from a Sendai virus detergent extract were compared on three different ion-exchange high-performance liquid chromatography (IE-HPLC) columns: Mono Q, TSK DEAE-NPR and Zorbax BioSeries SAX. The detergent, either 1-O-n-octyl-beta-glucopyranoside (octylglucoside) or decyl polyethylene glycol-300 (decyl PEG-300), used for extraction of HN and F proteins from the virions, was also present in the elution buffers at a concentration of 0.1%. Recovery of HN and F proteins was primarily dependent on the detergent present in the eluent, resulting in yields of HN varying from 18 to 28 and 56 to 67%, when octylglucoside and decyl PEG-300, respectively, were used. The highest yield for HN protein was obtained by separation on either a Mono Q or a TSK DEAE-NPR column with decyl PEG-300 as the additive. Yields of F protein were lower, and the highest recovery of 46% was found in the presence of decyl PEG-300 by separation on the Mono Q column. Analysis of the fractions by sodium dodecyl sulphate-polyacrylamide gel electrophoresis and by size-exclusion HPLC indicated that the HN protein eluted in the presence of decyl PEG-300 from the Mono Q and the TSK DEAE-NPR columns was obtained in pure form, while the F protein was slightly contaminated with HN. Analysis of the fractions with monoclonal antibodies directed against conformational epitopes of HN and F proteins indicated that after IE-HPLC the conformation of the proteins is largely retained.

Some physico-chemical properties of the rigid form of the Sendai virus nucleocapsid

The effect of some dissociation agents (SDS, beta-mercaptoethanol, urea, EDTA) on the rigid form of the Sendai virus nucleocapsid was studied. Polyacrylamide gel electrophoresis in the presence of lytic mixture (1% SDS, 2% beta-mercaptoethanol, 5 M urea, for 2 min at 100 degrees C) revealed two types of polypeptide subunits (mol. wts. 46,000 and 14,000), as well as the dissociation in the presence of 0.1% SDS only. The EDTA treatment leads to a disorganization of the protein part (10(-2) M) or of the nucleocapsid structure (5 x 10(-2) M).

Conformation and stability of Sendai virus fusion protein

The conformation and stability of Sendai virus fusion (F) protein were studied by circular dichroism spectroscopy, and the protein predictive models of Chou and Fasman and Robson and Suzuki were used to elucidate the secondary structure of Sendai virus F protein. The F protein conformation is predicted to contain 33% alpha-helix, 53% beta-sheet and 15% beta-turn by the Chou and Fasman model, and 30% alpha-helix, 55% beta-sheet, 9% beta-turn and 7% random coil by the Robson and Suzuki model. C.d. studies of F protein purified in the presence of the non-ionic detergent, n-octylglucoside, indicated the presence of 49% alpha-helix and 31% beta-sheet at pH 7.0, 54% alpha-helix and 28% beta-sheet at pH 9.0 and 50% alpha-helix and 23% beta-sheet at pH 5.4. A small change in conformation of the protein occurred when the pH was titrated from 7.0 to 5.4 and from 7.0 to 9.0 and a more pronounced conformational change occurred when the pH was changed from 9.0 to 5.4. The F protein in 0.2% n-octylglucoside was resistant to denaturation by 4 M guanidine hydrochloride, the reducing agent 20 mM mercaptoethanol, and to increases in temperature from 5 to 80 degrees C. Monoclonal anti-F protein antibody showed an increased binding to whole virus when the pH was changed from 7.0 to 9.0. The antibody binding was decreased when the pH was shifted from 9.0 to 5.4 Maximum haemolytic activity was observed with virus that was preincubated at pH 8.0.(ABSTRACT TRUNCATED AT 250 WORDS)

Fluorescence anisotropy of UV-irradiated viruses

The steady-state fluorescence anisotropy measurements on influenza and parainfluenza viruses, showed no changes in the microviscosity of the viral membranes after exposure to UV-irradiation, when a fluorescent probe was used, but the intrinsic fluorescence of viral proteins presented, under the same experimental conditions, a significant difference of anisotropy behaviour in the two viruses used.

Selective extraction of haemagglutinin and matrix protein from Sendai virions by employing trifluoperazine as a detergent

Incubation of trifluoperazine, a local anaesthetic, at concentrations higher than the cmc with Sendai virus particles produces the selective solubilization of the haemagglutinin neuraminidase (HN) and matrix (M) proteins. This phenomenon involves aggregation of the Sendai virions and therefore the separation of HN and M from the rest of the particle can be performed by bench centrifugation. The supernatant contains the HN and M proteins and HN, once inserted into liposomes, elicits its own biological activities. Therefore, the method seems suitable for purifying large amounts of HN.

Oral administration of cholera toxin-Sendai virus conjugate potentiates gut and respiratory immunity against Sendai virus

Successful oral immunization to prevent infectious diseases in the gastrointestinal tract as well as distant mucosal tissues may depend on the effectiveness of an Ag to induce gut immune responses. We and others have previously reported that cholera toxin possesses strong adjuvant effects on the gut immune response to co-administered Ag. To explore further adjuvant effects of cholera toxin, the holotoxin or its B subunit was chemically cross-linked to Sendai virus. The resulting conjugates, which were not infectious, were evaluated for their capacity to induce gut immune responses against Sendai virus after oral administration to mice. Conjugating cholera toxin to virus significantly enhanced the adjuvant activity of cholera toxin compared to simple mixing. Cholera toxin B subunit, however, did not show an adjuvant effect either by itself or conjugated with the virus. Oral administration of the Sendai virus-cholera toxin conjugate was also able to prime for protective anti-viral responses in the respiratory tract. Mice that were orally immunized with the conjugate and intra-nasally boosted with inactivated virus alone showed virus-specific IgA titers in nasal secretions that correlated with protection against direct nasal challenge with live Sendai virus. For comparison, s.c. immunization was also studied. Systemic immunization with the virus-cholera toxin conjugate induced virus-specific antibody responses in serum as well as in the respiratory tract but failed to protect the upper respiratory tract against virus challenge. Systemic immunization plus an intra-nasal boost did, however, confer a variable degree of protection to the upper respiratory tract, which correlated primarily with bronchoalveolar lavage (lung) antibody titers.

Effect of detergents on the structure of integral membrane proteins of Sendai virus studied with size-exclusion high-performance liquid chromatography and monoclonal antibodies

The integral membrane proteins of Sendai virus, the fusion protein F (Mr = 65,000) and the haemagglutinin-neuraminidase protein HN (Mr = 68,000), were used as a model protein mixture. They were subjected to size-exclusion high-performance liquid chromatography on Superose 6HR columns with eluents containing various additives in order to solubilize the proteins. The effect of the additives on the structure of the membrane proteins was investigated with conformation-dependent monoclonal antibodies, either directed against F or HN protein, and by determination of the haemagglutinating capacity of the HN protein. The results show that the structure of the HN protein is more easily disturbed by eluents than that of the F protein. When the elution conditions are mild, e.g., 0.1% octylglucoside, the structure of both proteins is conserved but no separation is obtained. Elution with a buffer containing 0.05% sarkosyl (dodecyl methylglycine sodium salt) did not affect the structure and resulted in pure F protein. Pretreatment of the Amberlite XAD-2-treated Sendai virus envelope extract with 4% sodium dodecyl sulphate (SDS) and elution with 0.1% SDS in 50 mM sodium phosphate (pH 6.5) altered the structure of the HN protein but resulted in purification of the tetramer and the dimer of the HN protein, and the monomer of the F protein.

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.

Reconstitution of fusogenic Sendai virus envelopes by the use of the detergent chaps

Sendai virus envelopes have been a useful tool in studying the mechanism of membrane-membrane fusion and have served as a vehicle for introducing foreign molecules (e.g., membrane proteins) into recipient cells. Reconstituted Sendai virus envelopes are routinely obtained following solubilization of virus particles with Triton X-100. This detergent has a low critical micellar concentration which precludes it from being the best detergent of choice in reconstitution studies. Nevertheless, it has remained in use since other detergents such as sodium deoxycholate and sodium cholate rendered the resultant vesicles inactive. Triton X-100 may be suboptimal for studies of some proteins that need be coreconstituted with the viral envelopes. Thus, alternative advantageous detergents, which retain the envelope fusogenic activity, have been sought. In this study we show that the synthetic detergent 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (Chaps) effectively solubilizes the Sendai virions, and that the vesicles formed by simple reconstitution protocols appear structurally and biochemically similar to those obtained with Triton X-100. The resultant vesicles retain functional integrity as assessed in both fusion and hemolysis assays. This protocol seems to be useful in sendai envelope-mediated reimplantation of Fc epsilon receptors into the plasma membranes of rat basophilic leukemia cells.

Localization of functional sites on the hemagglutinin-neuraminidase glycoprotein of Sendai virus by sequence analysis of antigenic and temperature-sensitive mutants

To locate the various functions associated with the hemagglutinin-neuraminidase (HN) glycoprotein of Sendai virus in the primary structure of the protein, a temperature-sensitive (ts) mutant and seven antigenic mutants were sequenced. The ts mutant was defective in its ability to agglutinate erythrocytes and infect host cells, while its neuraminidase activity was normal. Its sequence revealed two closely spaced amino acid substitutions (residues 262 and 264) and one distant substitution (residue 461). Revertants could not be isolated, suggesting that more than one of the substitutions is responsible for the defective hemagglutinating activity. The antigenic mutants were selected with monoclonal antibodies that delineate four nonoverlapping antigenic sites (I-IV) and separately inhibit hemagglutinating, neuraminidase, and hemolysis activities. Mutants selected with antibodies to antigenic sites I-III were used to map these functions on the primary sequence of HN. Each antigenic mutant had a single point mutation in the HN gene that resulted in an amino acid substitution in the protein. A site II mutant selected with an antibody which inhibits hemolysin activity had a substitution at amino acid 420, while a mutant selected with antibody that inhibits only erythrocyte binding (site III) had a substitution at amino acid 541. Two antigenic mutants selected with an antibody that inhibits hemagglutination and neuraminidase activities (site I) had amino acid substitutions in close proximity (residues 277 and 279) to the two closely spaced substitutions of the ts mutant. These findings suggest that the region defined by the ts mutant and these two antigenic mutants is involved in host cell binding. Antigenic mutants selected with another site I antibody had amino acid changes at residue 184, indicating that antigenic site I is discontinuous in the primary sequence. This antibody blocks only hemagglutination, but mutants selected with it had a decreased neuraminidase activity. This finding supports the idea that the neuraminidase site is close to, but distinct from, the hemagglutination site.

Purification strategies for Sendai virus membrane proteins

Viral membrane proteins extracted from Sendai virions with the non-ionic detergents decylpolyethyleneglycol-300 and Triton X-100 were used as a model mixture of hydrophobic membrane proteins. The detergent extract contained the fusion protein (F) and the tetrameric and dimeric forms of the hemagglutinin-neuraminidase protein (HN). These proteins were purified by size-exclusion high-performance liquid chromatography (HPLC) in the presence of 0.1% sodium dodecyl sulphate, by ion-exchange and metal chelate affinity HPLC in the presence of 0.1% decylpolyethyleneglycol, and by reversed-phase HPLC without prior removal of the detergent. The tetramer of HN and F could be purified by size-exclusion HPLC after dissociation of a micellar aggregate containing tetrameric HN and multimeric F. The F and HN proteins could be purified by ion-exchange HPLC. Pure F protein could be obtained after metal chelate affinity HPLC. The F protein and the dimer and tetramer of HN could be eluted from a large-pore (100 nm) reversed-phase column, but they were eluted as broad, overlapping peaks. Only after reduction of the virion extract, the relatively small (13-15 kilodaltons) F2 protein could be obtained in pure form.

Characterization of the phospholipid and fatty acid composition of Sendai virus

The lipid composition of Sendai virus, propagated in chicken eggs, was analyzed by high performance liquid chromatography (HPLC), thin-layer chromatography (TLC), and gas-liquid chromatography (GLC). Phosphatidylcholine was found to be the dominant phospholipid (37.3%) with phosphatidylethanolamine (26.8%) and phosphatidylserine (12.0%) also present in significant amounts. Analysis of the fatty acid methyl esters revealed that the dominant fatty acids in total phospholipid were: C16:0 (17.6%), C18:0 (15.4%), C18:1 (n-9) (22.0%), and C24:0 (6.0%). Cardiolipin, phosphatidylserine, and sphingomyelin contained higher levels of saturated fatty acids relative to phosphatidylinositol, phosphatidylethanolamine, and phosphatidylcholine.

Sequence analysis of the P and C protein genes of human parainfluenza virus type 3: patterns of amino acid sequence homology among paramyxovirus proteins

The complete nucleotide sequence of the P + C mRNA of human parainfluenza virus type 3 (PF3) was determined by sequencing cDNA, viral genomic RNA and mRNA. The P + C mRNA is 2009 nucleotides in length, exclusive of poly(A), and contains two overlapping open reading frames (ORFs). The P + C mRNA encodes two proteins, the 602 amino acid nucleocapsid phosphoprotein P and the 199 amino acid non-structural protein C. Peptide mapping confirmed that the two proteins are unrelated. Hybrid-arrest translation experiments assigned each of the two proteins to its respective ORF. These studies showed that the coding strategy of the PF3 P + C mRNA is similar to that of Sendai virus. Amino acid sequence alignment showed that the P and C proteins of PF3 and Sendai virus represent homologous pairs. However, these homologies are represented by high contents of accepted amino acid substitutions and by similarity in hydropathy profiles rather than by high contents of exact amino acid matches. Homology with the P and C proteins of measles, canine distemper and respiratory syncytial viruses was at the threshold of significance. The patterns of amino acid sequence homology among the paramyxovirus HN, F, NP, P and C proteins are compared.

Nucleotide sequence of the gene encoding the fusion glycoprotein of Newcastle disease virus

The nucleotide sequence of the gene encoding the fusion (F) glycoprotein of the Beaudette C strain of Newcastle disease virus (NDV) has been determined from cDNA clones obtained from virion RNA. The gene is 1792 nucleotides long, including mRNA start and polyadenylation signals typical of paramyxoviruses. The single open reading frame encodes a polypeptide of 553 amino acids, with a predicted molecular weight of 59042. The F polypeptide has three regions of high hydrophobicity: an N-terminal signal peptide, the N terminus of F1 (known from protein sequencing) and a C-terminal membrane-spanning region by which the F glycoprotein is anchored to the membrane. The cleavage site of F0 is located in a highly basic region of the F polypeptide. Five potential asparagine-linked glycosylation sites are present in the amino acid sequence, of which one is in F2 and the others in F1. Comparison of the NDV F amino acid sequence to those from other paramyxoviruses reveals homology to Sendai virus, simian virus 5 and human respiratory syncytial virus. There is also limited homology between the N terminus of F1 of NDV and the N termini of HA2 of influenza viruses. Post-translational modifications of the NDV F polypeptide are discussed in the light of information provided by the amino acid sequence.

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.

[Demonstration of viral proteins by silver staining]

Investigations were conducted to establish the optimal conditions for silver staining of polypeptides separated by polyacryle-amide gel electrophoresis. The thickness of the gel layer was of 1.5 mm. The experiments showed that the modified Hankeshover and Dernick's technique (4) (replacement of the fixative for the electrophoretically separated polypeptides and extension of the bleaching by Farmer's reagent time) had the best sensitivity and reproducibility. This technique can be performed also on polyacryle-amide gel preparations already stained by the Coomassie Brilliant Blue method. To check the efficiency of this silver staining technique, the authors used it to detect the Sendai virus and B hepatitis virus surface antigen polypeptides.

Isolation of glycoproteins of parainfluenza I (Sendai) by Helix pomatia Lectin column

Glycoproteins of Sendai virus were successfully isolated on a column of Helix pomatia Lectin-Sepharose 6MB following solubilization with Nonidet P-40. This technique can be used as a preparative step for the study of viral glycoproteins.

Size-exclusion high-performance liquid chromatography of Sendai virus membrane proteins in different detergents. A comparison of different columns

Four column packings for size-exclusion high-performance liquid chromatography (HPLC) of proteins with particle sizes from 3 to 13 micron were compared, using 0.1% sodium dodecyl sulphate in the solvent. Their suitability for the purification of hydrophobic membrane proteins was studied with Sendai virus proteins as a model. The calibration curves of the two 13-micron column packings were linear up to high molecular weights. In contrast to this, large proteins (greater than 100-150 kD) were eluted later than expected from the 3- and 6-micron packings. Peak capacities for proteins larger than 20 kD ranged from 4.7 to 5.5. Therefore, purification of complex mixtures of membrane proteins will often require rechromatography by a different mode of HPLC. Non-ionic detergents are suitable for further ion-exchange chromatography. The effect of addition of 0.1% of five non-ionic detergents (three gluco-methylalkanamide detergents, octylglucoside, and decyl-polyethyleneglycol-300) to the solvent was investigated and decyl-polyethyleneglycol-300 was found to be most suitable. Size-exclusion HPLC with this detergent resulted in the separation of micelles of three different sizes, of which the larger two contained exclusively the Sendai virus F protein.

Preparation and characterization of F-protein vesicles isolated from Sendai virus by means of octyl glucoside

We have demonstrated that Triton X-100 is always present in F-protein vesicles at concentrations that can provoke cell lysis. In order to avoid any misinterpretation of the fusogenic capacity of this protein, we solubilized the Sendai virus using octyl glucoside, which can be totally removed from the F protein preparation in less than 16 h by dialysis in the presence of absorbent beads. F-glycoprotein preparations preserved their ability to lyse erythrocytes in the presence of lectins and to induce cell-vesicle fusion as demonstrated by ESR studies. These vesicles were characterized by electron microscopy and SDS-polyacrylamide gel electrophoresis. Lipid analysis of these preparations by thin-layer chromatography indicated that they had the same proportion of lipids as virus envelopes, with slight variations in the sphingomyelin content and the cholesterol/phospholipid molar ratio. F-protein vesicles of different sizes can be obtained by adding exogenous lipids before detergent removal. The hemolytic activity of the vesicles was retained over a large range of lipid concentrations. We conclude that F-protein vesicles prepared with octyl glucoside are convenient tools for studying the fusogenic mechanism of this protein and improving the fusion process between liposomes and cells.

Targeting of loaded Sendai virus envelopes by covalently attached insulin molecules to virus receptor-depleted cells: fusion-mediated microinjection of ricin A and simian virus 40 DNA

Insulin molecules were covalently attached to detergent-solubilized Sendai virus envelope glycoproteins (HN and F polypeptides) by the use of the crosslinking reagent succinimidyl 4-(p-maleimidophenyl)butyrate (SMPB). Reconstitution of modified viral glycoproteins (carrying covalently attached insulin) together with unmodified viral glycoproteins resulted in the formation of "fusogenic" viral envelopes bearing insulin molecules. Reconstitution of such fusogenic viral envelopes in the presence of ricin A or simian virus 40 (SV40) DNA resulted in the formation of viral envelopes bearing insulin molecules and loaded with ricin A or SV40 DNA. Such viral envelopes were able to bind to hepatoma tissue culture cells (HTCC) from which Sendai virus receptors were removed by treatment with neuraminidase. Incubation of viral envelopes loaded with ricin A with virus receptor-depleted HTCC resulted in fusion-mediated injection of the toxin, as inferred from inhibition of protein synthesis and decrease in cell viability of the microinjected cells. Fusion-mediated injection of SV40 DNA was inferred from the appearance of SV40 tumor antigen in microinjected cells. Binding and fusion of the loaded viral envelopes to neuraminidase-treated HTCC was mediated solely by the virus-associated insulin molecules. Addition of free insulin molecules inhibited binding of the viral envelopes and, consequently, the microinjection of ricin A and SV40 DNA.

Isolation of poly(A)-rich mRNA from the chorioallantoic membrane of Sendai virus-infected chick embryos

Total RNA was extracted from the chorioallantoic membrane (CAM) of Sendai virus-infected chick embryos by the original Kecskeméthy-Schäfer method and by a modification of this technique, including phenol treatment, in order to ensure complete removal of proteins. The purity of the total RNA extracted by the modified technique was ascertained by spectral analysis. Chromatography on oligo(dT)-cellulose of the total RNA led to the isolation of poly(A)-rich mRNA--the material retained by oligo(dT)-cellulose and eluted with the buffer of the lowest ionic strength. The ability of the poly(A)-rich mRNA thus obtained to stimulate incorporation of 14C-leucine into protein was demonstrated in a cell-free protein-synthesizing assay system.

The activity of membranes reconstituted from HVJ envelope proteins and lipids to induce hemolysis and fusion between liposomes and erythrocytes

A simple method for preparation of lipid-free envelope proteins (HN protein and F protein) of HVJ (Sendai virus) was developed. Reconstituted 'envelopes' were then prepared from envelope proteins and various lipids by the detergent dialysis method, and the activity to induce hemolysis and fusion between liposome and erythrocyte was studied. Lipid-free envelope protein aggregates could induce hemolysis and liposome-erythrocyte fusion. The activity was however greatly augmented by incorporation of envelope proteins into membrane of viral total lipids. Hemolytic and fusogenic activity was somewhat augmented by incorporation of envelope proteins into dipalmitoylphosphatidylcholine/cholesterol (1:1, molar ratio) and dimyristoylphosphatidylcholine/cholesterol (1:1), though the augmentation was lower than that observed with viral total lipids. When 'envelopes' were reconstituted with the proteins and viral total lipids supplemented with phosphatidylethanolamine, two kinds of 'envelopes' were prepared; one was permeable to Dextran (Mr 75000) and hemolytic, and the other was impermeable to Dextran and nonhemolytic. The latter acquired hemolytic activity after subjection to freezing and thawing, and its barrier function was lost concomitantly. The study suggests that envelope proteins (HN protein and F protein) could function without lipids but their activity was greatly influenced by not only the composition of additional lipids but also mode of arrangement of components on the reconstituted membranes.

Combined size-exclusion and reversed-phase high-performance liquid chromatography of a detergent extract of Sendai virus

Virus envelope proteins obtained by Triton X-100 extraction of Sendai virions were purified to a high degree by a combination of high-performance liquid chromatography (HPLC) methods. Size-exclusion HPLC on a TSK 4000 PW column with several concentrations of acetonitrile or ethanol-1-butanol in 0.1% hydrochloric acid as eluent was used as the first chromatographic step. Peak fractions were diluted in water and further fractionated on reversed-phase columns (TMS-250 or Vydac 218 TP). Size-exclusion HPLC with 45% acetonitrile in 0.1% hydrochloric acid, combined with reversed-phase HPLC on either column, was most suitable for obtaining highly purified F2 protein. Antibodies obtained after injection of this protein were reactive with the intact virus.

Isolation of detergent-extracted Sendai virus proteins by gel-filtration, ion-exchange and reversed-phase high-performance liquid chromatography and the effect on immunological activity

Virus envelope proteins were isolated from Triton X-100 extracts of purified Sendai virions by gel-filtration, ion-exchange and reversed-phase high-performance liquid chromatography (HPLC). The fusion protein F, the matrix protein M and the tetrameric and dimeric form of the HN protein were isolated by gel-filtration HPLC with a solvent containing 0.1% sodium dodecyl sulphate. HN and F were also isolated by ion-exchange HPLC with 0.1% Triton X-100 in the eluent. Reversed-phase HPLC was performed on a C1 column with acetonitrile as the organic solvent. Especially the F1 and F2 component of the fusion protein F were obtained in pure form. The immunological activity of the proteins after HPLC was determined with an enzyme-linked immunosorbent assay (ELISA). After gel-filtration and ion-exchange HPLC, proteins still reacted with antiserum to the intact virus while proteins purified by reversed-phase HPLC did not react.

Preparation and analysis of the nucleocapsid proteins of vesicular stomatitis virus and sendai virus, and analysis of the sendai virus leader-NP gene region

A procedure is presented for isolating the nucleocapsid proteins, N and NP from vesicular stomatitis virus and Sendai virus respectively, in soluble form. These proteins were suitable for the determination of their blocked amino-terminal peptide sequences by gas-liquid chromatography/mass spectrometry at the low nanomole level. The N protein prepared by this procedure was previously shown to retain some of its expected biological activity. The sequence of 626 nucleotides from the 3' end of the Sendai virus genome, which includes the first one-third of the NP gene, was determined. Using this information, primer extension studies on intracellular Sendai virus mRNAs allowed the determination of the structure of the leader-NP intervening sequence and the 5' end of the NP mRNA. Comparison of the amino termini of the nucleocapsid proteins with their respective mRNA sequences revealed that these proteins are similarly processed in vivo.

A simple procedure for the analysis of the structural proteins of influenza and parainfluenza viruses involving adsorption to erythrocytes

A simple procedure for the analysis of the structural proteins of influenza and parainfluenza viruses utilizing adsorption to erythrocytes is described. The method involves virus growth in the presence of [35S]methionine, adsorption of clarified culture medium with a 0.5% suspension of either guinea-pig or chicken erythrocytes and analysis of the virus-erythrocyte aggregates by sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE). All of the structural proteins can be detected using this procedure, and the protein profiles of virus-adsorbed erythrocyte complexes compare extremely well with those of sucrose density gradient purified virus preparations.

Characterization of a glycoprotein fusogen isolated from Sendai virus

After isolation from Sendai virus, the glycoproteins HN and F retained their ability to induce hemagglutination and both heterologous and homologous cell-cell fusion. Both methods for demonstrating cell fusion indicated that the isolated HN and F glycoproteins compared favorably with whole Sendai virus as a fusogen. Conditions affecting the degree of fusion were examined and optimized. Whole virus and isolated glycoprotein preparations were characterized by electron microscopy and by SDS-polyacrylamide gel electrophoresis. Lipid analysis of the glycoprotein preparations by thin layer chromatography and gas chromatography/mass spectrometry indicated that they were partially lipid-depleted during the isolation protocol and the ratio of cholesterol to phospholipid was higher than in the whole virus. A complete fatty acid analysis was performed on lipid extracts from whole virus and from glycoprotein preparations. Detergent was removed from the glycoproteins by dialysis and by incubation with Amberlite XAD-2 resin. The detergent content of the glycoprotein preparations was monitored by gas chromatography and with [3H]Triton X-100. Both methods showed that virtually all (greater than or equal to 99.8%) of the originally added detergent was removed. Electron microscopy of the negatively-stained HN and F preparations showed primarily spherical particles 120 +/- 20 A in diameter (range 80-250 A). Since no organization reminiscent of envelopes could be demonstrated, we conclude that the fusogenic activity of Sendai virus resides in the glycoproteins per se rather than in bilayer integrated lipid-protein complexes.

Purification of detergent-extracted Sendai virus proteins by reversed-phase high-performance liquid chromatography

Sendai virus envelope proteins were isolated by reversed-phase high-performance liquid chromatography. The F (F1 and F2, connected by disulphide bonds), M and HN proteins were extracted from purified Sendai virions with Triton X-100. After removal of the detergent from the extract with Amberlite XAD-2 and reduction of the proteins, separation was performed on a small (10-nm) and on a larger (30-nm) pore size C18 column. Proteins were eluted with a gradient of an ethanol 1-butanol mixture in 12 mM hydrochloric acid. On the 10-nm pore size column, F2 was completely recovered in pure form, whereas the recoveries of the other proteins were low (5-25%). Similar results were obtained with the 30-nm pore size column, except for protein F1 of which the yield was higher (50%).

Isolation of Sendai virus F protein by anion-exchange high-performance liquid chromatography in the presence of Triton X-100

Purified Sendai virions were treated with Triton X-100. The detergent extract containing the fusion protein (F) and the haemagglutinin-neuraminidase protein (HN) was subjected to anion-exchange high-performance liquid chromatography on a Mono Q (Pharmacia) column with 0.1% Triton X-100 in phosphate-buffered saline. HN was not retained by the column while elution with a salt gradient resulted in several peaks containing mainly or only F protein.

Cellular localization of five structural proteins of Sendai virus studied with peroxidase-labelled Fab fragments of monoclonal antibodies

By the use of horseradish peroxidase-labelled Fab fragments of monoclonal antibodies, five major structural components of Sendai virus, namely the nucleocapsid (NP), polymerase (P), matrix (M), fusion (F), and haemagglutinin-neuraminidase (HN) proteins were localized in infected Vero cells. The P and NP proteins were found in association with large clusters of ribosome-like particles and nucleocapsids in the cell cytoplasm. They were not concentrated at the cytoplasmic membrane, except in nucleocapsids within budding viral particles. F and HN proteins, on the other hand, were found in connection with ribosomes and endoplasmic reticulum in the cell cytoplasm, but not in nucleocapsids. Both proteins were evenly distributed on the outer cytoplasmic membrane and appeared on the surface clearly before budding of viral particles. The M protein was seen in connection with both nucleocapsids and ribosomes. It was not found at the cell surface except in budding viral particles.

Study of negatively stained images of Sendai virus nucleocapsids using minimum-dose system

Using minimum-dose system and optical diffraction, effects of electron irradiation on negatively stained images of trypsin-straightened nucleocapsids of Sendai virus were semiquantitatively compared for uranyl-acetate (UA) and phosphotungstic acid (PTA). The results confirmed the superiority of UA in display of fine structures and showed that both UA- and PTA-stained images tended to turn from a one-sided to a two-sided image during irradiation, the general contrast of the picture increased in the UA-stained images but not in the PTA-stained ones, and furthermore the electron doses for the richest information were 18 000 to 30 000 e-/nm2 for UA, but 1000 e-/nm2 for PTA, under the condition used. The optical diffraction patterns of the UA-stained nucleocapsids, its analysis by the superposition method, and rotational harmonics of end-on views of nucleocapsids, together indicated that the most probable arrangement of subunits was 13 per turn of a helix with 5-nm periodicity. This helix also had an arrangement of subunits parallel to the axis. The occurrence of 2.5 nm periodicity was probably produced by an arrangement of a UA-penetrable concave substructure of the subunit.

Search for Sendai 6/94 viral RNA in the antigen-free cell line Cl-C-2 isolated from human multiple sclerosis brain tissue

The viral antigen-free cell line Cl-C-2, obtained from multiple sclerosis brain tissue by cell fusion with CV-1 cells, was examined for the presence of intracellular virus-specific RNA sequences of the persistent Sendai 6/94 virus by nucleic acid hybridization. As a specific probe for this assay, an in vitro synthesized cDNA was used. Oligodeoxyguanidylic acid served as a primer for the initiation of cDNA synthesis. The 6/94 RNA was detectable as expected in the viral antigen-expressing cell lines Cl-E-8 and Cl-F-2, which were used as a reference of the same source. In the viral antigen-free cell line Cl-C-2, however, no viral RNA sequences have been found by hybridization experiments. Corresponding superinfection studies confirmed the conclusion that in cell line Cl-C-2 no viral components are present. The lack of expression of viral proteins and of protection against superinfection seems to be correlated with the lack of viral RNA in Cl-C-2 cells, which may eliminate the persistent virus by a cellular defense mechanism.

Evidence for different receptor sites in mouse spleen cells for the Sendai virus hemagglutinin-neuraminidase (HN) and fusion (F) glycoproteins

Liposomes were reconstituted from phosphatidylcholine and Sendai virus glycoproteins HN or F and their interaction with mouse spleen cells was studied. Both the HN and F liposomes were able to stimulate chemiluminescence (CL), indicating that the glycoproteins were able to interact with the cell membrane independently of each other. The induction of CL in cells which had been pretreated with liposomes by monoclonal antibodies to either HN or F demonstrated that HN and F bind to the cells independently. The presence of F liposomes on the cell surface was also confirmed by immunoelectron microscopy. Cells pretreated with HN and F liposomes revealed a different pattern of CL when challenged with intact virus or the calcium ionophore A23187 indicating that HN and F bind to different receptor sites.

Correlation of rotational mobility and flexibility of Sendai virus spike glycoproteins with fusion activity

The rotational mobility of Sendai virus glycoprotein spikes was measured by flash-induced transient dichroism of eosin triplet probes. The possible importance of this molecular motion for function was investigated by parallel assays of hemagglutination and fusion with erythrocytes. For mobility measurements, the glycoproteins were labeled on amino groups with eosin-5-isothiocyanate and on the galactose residues of the oligosaccharide chains with eosin-5-thiosemicarbazide. The decay of the absorption anisotropy of both probes, which has a time constant of about 100-200 musec at 37 degrees is attributed to the rotation of the proteins about an axis normal to the plane of the membrane. This motion was inhibited by crosslinking of the spike proteins with glutaraldehyde or by the specific binding of human erythrocyte glycophorin (a virus receptor) to the HN glycoprotein. Low values of the initial anisotropy for both probes indicate the existence of a second, faster motion. This is attributed to segmental motion of the glycoproteins. Segmental motion is inhibited by crosslinking with glutaraldehyde but appears to be little affected by interaction with glycophorin. The temperature dependence of the segmental and rotational motion of the proteins revealed a pronounced increase in mobility in the range of 30-35 degrees which was not paralleled by the lipid motion of the Sendai virus envelope membrane. Since the temperature dependence of virus-induced hemolysis has a similar characteristic, the mobility of glycoproteins appears to be correlated with the fusion activity. The hemagglutination activity, however, is not dependent on the mobility of the glycoprotein spikes.

Interaction of viral envelope glycoproteins with fibronectin

An interaction between fibronectin and viral envelope glycoprotein micelles isolated from influenza A, parainfluenza 1, and mumps viruses was found by enzyme immunoassay. All three different glycoprotein micelles bound efficiently to solid-phase fibronectin. When fibronectin was permitted to bind to solid-phase viral glycoproteins, dose-dependent binding was observed. Soluble glycoprotein micelles inhibited the binding of fibronectin to immobilized glycoprotein preparations. The binding was not observed when fibronectin was pretreated with neuraminidase, suggesting that the sugar moieties of fibronectin are responsible for the affinity. This affinity may play a role in virus-cell interactions or in the opsonization of certain viruses during infection.

Detection of cellular receptors for Sendai virus in mouse tissue sections

We have established a method for detecting virus receptors in the tissue sections and have been able to clarify the distribution of cellular receptors for Sendai virus in various mouse organs, including trachea, esophagus, large intestine and cerebrum. The virus receptors were detected in ciliated cells of the trachea, as to be expected for a pneumotropic virus. The lamina propria and connective tissue of the mouse esophagus and large intestine, immediately under the epithelium, contained an abundance at virus receptors, but very few were detected in the epithelium of these organs. In mouse cerebrum, the cells lining the ventricles had a large number of virus receptors.

Component(s) of Sendai virus that can induce interferon in mouse spleen cells

To identify the active component of Sendai virus that induces interferon in mouse spleen cells, infectious and noninfectious viruses, envelope particles derived from them, and isolated hemagglutinin-neuraminidase (HN) glycoproteins were examined for interferon induction. The interaction between membranous structures containing Sendai virus HN glycoprotein and the receptors on the cell surface was shown to be sufficient for interferon induction in mouse spleen cells, suggesting that the actual inducer of interferon in mouse spleen cells is the HN glycoprotein of Sendai virus. When mouse spleen cells were stimulated in vitro with Sendai virus grown in eggs or LLC-MK2 cells or with membranous structures containing glycoproteins obtained from these viruses, interferon could be detected in the culture fluid. Furthermore, isolated HN glycoprotein per se could induce interferon in the cells. A linear correlation was found between the titer of interferon induced and the hemagglutinating activity of the membranous structure containing the HN glycoprotein. It was concluded from these findings that HN glycoprotein was the active component of Sendai virus responsible for interferon induction in mouse spleen cells and that viral RNA and F glycoprotein were not required. The results also showed that the interaction between HN glycoprotein and receptors on the cell surface triggered production of type I interferon (IFN-alpha and IFN-beta). Although when Sendai virus was incubated at 56 degrees C for 5 min it lost its hemolytic and hemagglutinating activities, it induced a considerable amount of interferon in the culture fluid of mouse spleen cells. The interferon-inducing ability of heat-inactivated virus could be absorbed with mouse spleen cells but not with sheep erythrocytes or mouse erythrocytes, indicating that the inactivated virus retained ability to bind to mouse lymphoid cells.

EPR and Mössbauer spectroscopy investigations on the metal ion contents of Sendai virus components

EPR and Mössbauer spectroscopy indicate that Sendai virus contains iron ions in paramagnetic states. Spectral data show that the iron ions are in an oxidized form (Fe3+), having low and high spin states (S = 1/2 and S = 5/2). On enrichment of Sendai virus with 57Fe, the concentration of Fe3+ ions substantially increases in the virus preparations. The Fe3+ ions in the high spin state appear to be tightly bound to the virus components; they are not significantly removed by dialysis. The five main proteins separated by SDS gel electrophoresis from 57Fe-enriched Sendai virus contain the signal corresponding to the presence of Fe3+ ions in the high spin state. The concentration of Fe3+ ions is, however, about five times higher in the HN polypeptide than in the other four components. It is suggested that Fe3+ (5/2) ions might be a structural component of the Sendai virus HN polypeptide.

Evidence for an interaction between the membrane protein of a paramyxovirus and actin

Evidence for an interaction of the membrane (M) protein of Newcastle disease and Sendai viruses with cellular actin was obtained by three different techniques. M protein linked to Sepharose 4B was found to bind actin, but not myoglobin or bovine serum albumin, and to selectively remove actin from a mixture of these three proteins. Sedimentation of a mixture of M protein and F-actin through a sucrose gradient resulted in sedimentation of M protein with actin. Control proteins, bovine serum albumin and cytochrome c, did not sediment with actin. In circular dichroism studies, M protein added to actin in a 1:1 complex resulted in a significant increase in negative ellipticity at 220 nm, which corresponds to an increase in alpha-helix and a decrease in beta-structure and random coil. This is indicative of an interaction between M protein and actin. It is possible that the frequent identification of cellular actin in a number of enveloped viruses may be attributed to the interaction of actin and M protein or its equivalent.

[Circular dichroism study of the ribonucleoprotein structure of Sendai virus isolated from infected chick embryo cells]

Thermostability and secondary structure of RNA, a component of ribonucleoprotein (RNP) of Sendai virus isolated from infected chick embryo cells (cRNP) and from virions (vRNP) were studied by the method of circular dichroism. The secondary structure of RNA in cRNP was shown to be practically no different from that of free RNA whereas incorporation of RNA into vRNP was accompanied by a significant decrease in the number of paired bases in it. Comparison of thermodenaturation parameters of cRNP and vRNP also revealed significant differences in their structural organization. Thus, melting of cRNP as well as of free RNA is of markedly non-cooperative nature indicating poor RNA-protein interactions in the complex. In contrast, the process of vRNP thermodenaturation occurs in a step-wise manner in a narrow temperature range indicating a significant role in the maintenance of this RNP structure of both RNA-protein and, apparently, protein-protein interactions.

[Morphological and structural studies of Sendai virus ribonucleoprotein]

The structure and morphology of Sendai virus ribonucleoprotein (RNP) with native and split protein subunits were studied by the method of circular dichroism and electron microscopy. Cleavage of the polypeptide fragment from RNP protein subunits was shown to cause changes in the secondary structure of RNP in situ but not to affect the RNP morphology; when stained with uranyl acetate both RNP types had an appearance of spiral strands.