The polypeptide composition of influenza A viruses

Inhibition of the fusion-inducing conformational change of influenza hemagglutinin by benzoquinones and hydroquinones

Influenza hemagglutinin (HA) undergoes a conformational change that is required for viral entry. The rearrangement includes exposure of the fusion peptide, a hydrophobic segment buried in the trimer interface of the native protein. Since fusion peptide release triggers the membrane fusion event crucial for viral replication, inhibition of fusion peptide exposure should prevent infection. We reasoned that small molecules that bind to HA and stabilize its nonfusogenic conformation would block viral activity. A computer-assisted method was used to select putative HA ligands. One of the selected compounds, 4A,5,8,8A-tetrahydro-5,8-methano-1,4-naphthoquinone, prevented the conversion of X31 HA to a conformation recognized by alpha-fusion peptide antisera. Several derivatives of this compound, including both benzoquinones and hydroquinones, also showed inhibition. The most effective compounds tested have IC50S between 1 and 20 microM. Representative compounds also inhibited virus-induced syncytia formation, HA-mediated hemolysis, and viral infectivity in vitro. The inhibitors are attractive leads for the development of antiviral drugs and can serve as probes of the mechanism of the conformational change of HA.

Deduced amino acid sequences at the haemagglutinin cleavage site of avian influenza A viruses of H5 and H7 subtypes

The amino acid sequences at the haemagglutinin cleavage sites of 9 avian influenza A viruses of H5 subtype (5 high and 4 low pathogenicity for chickens) and 21 of H7 subtype (13 high and 8 low pathogenicity for chickens) were determined by direct RNA sequencing, PCR amplification sequencing or both. None of the viruses of low pathogenicity had multiple basic amino acids at the cleavage site. All highly pathogenic viruses had an insert of basic amino acids at the cleavage site, except A/chicken/Scotland/59 (H5N1) for which the multiple basic amino acids appeared as substitutions and not insertions. All highly pathogenic viruses examined conformed to the amino acid motif of R-X-R/K-R at the cleavage site which is considered to be essential for high pathogenicity in chickens, with the notable exception of highly pathogenic virus A/turkey/England/50-92/91 (H5N1) which had the sequence R-K-R-K-T-R adjacent to the cleavage site.

The influence of dextran sulfate on influenza A virus fusion with erythrocyte membranes

Dextran sulfate suppresses the low pH-induced fusion of influenza virus A/Brazil 11/78 with erythrocyte membranes, as shown by fluorescence dequenching assay, using the fluorophore octadecylrhodamine B chloride (R18). Inhibition of fusion was maximal at pH 5.0, while at higher pH values (> 5.6) fusion was not affected. Hemolysis of intact red blood cells by influenza A virus at low pH values is also prevented by dextran sulfate. The inhibiting effect of the polymer is mainly ascribed to repression of virus attachment. Evidence is given that the conformational change of the virus envelope protein hemagglutinin (HA) responsible for triggering fusion is not affected by the polymer.

Proton nuclear magnetic resonance studies of the binding of sialosides to intact influenza virus

The dissociation constants for binding of sialic acid derivatives to the hemagglutinin on intact influenza virus were determined using nuclear magnetic resonance (NMR) spectroscopy. The dissociation constants determined with whole virus are similar to, but slightly higher than, those determined with BHA (hemagglutinin released from virus by treatment with the protease bromelain; Sauter et al., 1989, Biochemistry 28, 8388-8396), indicating that the sialic acid binding site is not significantly altered when hemagglutinin is released from virus. Binding was quantified by observing the concentration-dependent broadening of the sialoside resonances in the presence of X-31 virus or alternatively by observing the effect of the sialoside on the resonances of a competitive "reporter" ligand. The glycosidic substituent attached to the sialic acid makes relatively little difference in the affinity of the sialoside for virus: alpha(2,6)-sialyllactose (KD = 2.7 mM) binds only slightly more tightly than alpha(2,3)-sialyllactose (KD = 3.5 mM). However, inversion of the glycosidic center produces a dramatic change in affinity: the dissociation constant for the alpha-methyl glycoside of sialic acid is 4.2 mM, but not binding is observed with the beta-methyl glycoside.

Isolation of matrix protein M1 from influenza viruses by acid-dependent extraction with nonionic detergent

Influenza viruses were disrupted layer by layer with the nonionic detergent NP-40 at fixed pH. Treatment of the virions with NP-40 at neutral or mildly alkaline pH (6.8-8.0) yielded viral core structures containing M1 protein. The matrix M1 protein was selectively extracted from cores at acidic pH 3.0-4.5 with citrate, acetate, and phosphate buffers or with morpholinoethanesulfonic acid. The resulting M1 protein sedimented in a glycerol gradient with a coefficient of 2.8 S and most likely existed as a monomeric form of the 27,000-Da polypeptide. An antigenic map of the monomeric protein M1 tested with a panel of monoclonal anti-M1 antibodies was found to be similar to those of the assembled M1 protein in whole virions. The isolated M1 protein retained biological properties and inhibited the RNA polymerase activity of viral RNP. This transcription-inhibition function of M1 monomers was specifically restricted by one of the monoclonal antibodies studied.

Nuclear transport of influenza virus ribonucleoproteins: the viral matrix protein (M1) promotes export and inhibits import

Because influenza virus replicates in the nucleus and buds from the plasma membrane, its ribonucleoproteins (RNPs) must undergo bidirectional transport across the nuclear membrane. Export from the nucleus to the cytoplasm was found to depend on the viral matrix protein (M1). M1 associated with newly assembled viral RNPs (vRNPs) in the nucleus and escorted them to the cytoplasm through the nuclear pores. In contrast, during entry of the virus into a new host cell, M1 protein dissociated from the RNPs, allowing them to enter the nucleus. Amantadine, an antiviral agent that induces an early block in influenza A infection, was found to block the dissociation event and thereby to prevent import of incoming RNPs into the nucleus. Together, these results showed that M1 modulates the directionality of vRNP transport into and out of the nucleus.

Characterisation of the influenza virus associated protein kinase and its resemblance to casein kinase II

The protein kinase activity associated with purified influenza virus has been examined. By use of a radiolabelled photoreactive ATP analogue (3'-O-(4-benzoyl) benzoyl adenosine triphosphate) a 47 kD polypeptide has been identified that binds ATP. A comparison of the sensitivity of the kinase activity and the 47 kDa polypeptide labelling to inhibitors indicate that the 47 kDa polypeptide is likely to represent the major protein kinase activity of the virus. The virus associated protein kinase phosphorylates the synthetic peptide RREEETEEE, a peptide substrate for casein kinase II. Antiserum directed against casein kinase II revealed a positive signal in immunoblots of purified virus. We propose that the major protein kinase activity associated with purified virus preparations is host cell casein kinase II.

Dextran sulfate inhibits the fusion of influenza virus with model membranes, and suppresses influenza virus replication in vivo

The effect of dextran sulfate and related compounds on the fusion of influenza A virus with model membranes, composed of dioleylphosphatidyl-choline and cholesterol (1:0.5), was investigated by a fusion assay based on de-quenching of fluorescence of octadecyl-rhodamine-HC1 (R18). Dextran sulfate samples of molecular weight of 500,000, 8,000 and 5,000 were found to be potent inhibitors of the virus-liposome fusion process. Polygalacturonic acid also showed anti-fusion activity, but to a lesser extent. Uncharged dextran, positively charged diethylaminoethyldextran, and the monomer glucosamin-1,6-disulfate were ineffective. It was shown that dextran sulfate interacts with the virus. Our results suggest that dextran sulfate binds to and inactivates the viral fusion protein.

Electron microscopy of the influenza virus submembranal structure

Electron micrographs of stain-penetrated influenza virus particles show a variety of internal structures that all consist of units of 4 X 4 nm. Isolated influenza virus M-protein, that is reassociated with lipid, forms very similar structures on liposomes. We therefore conclude that the 4 X 4 nm unit is M-protein. We further argue that the M-protein is not arranged with icosahedral symmetry.

Hemagglutinins from two influenza virus variants bind to sialic acid derivatives with millimolar dissociation constants: a 500-MHz proton nuclear magnetic resonance study

The equilibrium binding of influenza virus hemagglutinin to derivatives of its cell-surface ligand, sialic acid, was measured by nuclear magnetic resonance (NMR) spectroscopy. Binding was quantified by observing perturbations of sialic acid resonances in the presence of protein. The major perturbation observed was a chemical shift of the N-acetyl methyl resonance, presumably due to the proximity of the methyl group to tryptophan 153. X-31 hemagglutinin binds to the methyl alpha-glycoside of sialic acid with a dissociation constant of 2.8 mM and does not bind to the methyl beta-glycoside. Replacing the 4-hydroxyl group of sialic acid with an acetyl group has little effect, while replacing the 7-hydroxyl group with an acetyl prevents binding. Experiments with sialylated oligosaccharides confirm literature reports that mutations at amino acid 226 change the specificity of hemagglutinin for alpha(2,6) and alpha(2,3) glycosidic linkages. The NMR line broadening of sialyloligosaccharides suggests that sialic acid is the only component that contacts the protein. Saccharides containing two sialic acid residues appear to have two separate binding modes. Hemagglutinin that has undergone a low pH induced conformational change retains the ability to bind sialic acid.

Influenza A (H1N1) vaccine efficacy in animal models is influenced by two amino acid substitutions in the hemagglutinin molecule

The immunogenicity and protective efficacy of formalin-inactivated vaccines prepared from influenza A (H1N1) viruses grown in MDCK cells and in eggs was compared in animal models. The A/Chr/157/83 virus grown in MDCK cells (157M) differed by two amino acid substitutions in the HA molecule from the corresponding virus grown in eggs (157E) and the two viruses could be distinguished antigenically by monoclonal and polyclonal antibodies. Following two intramuscular injections of vaccine in ferrets, guinea pigs, and hamsters, both vaccines were equally immunogenic when antibody was analyzed by hemagglutination inhibition using homologous virus. However, single radial hemolysis analysis following antibody cross-adsorption showed that antibody stimulated by 157E vaccine was exclusively strain specific whereas that produced by the 157M vaccine was more broadly reactive. When immunized hamsters were challenged with virus cultivated on mammalian (MDCK) cells, the homologous vaccine induced a higher degree of protection than the corresponding egg-grown vaccine.

Cytotoxic and helper T-lymphocyte responses to antibody recognition regions on influenza virus hemagglutinin

We have previously localized and synthesized twelve antibody recognition sites on influenza virus hemagglutinin (HA). These peptides correspond to exposed surface areas in the 3-D structure of HA. Using intact X31 virus as the immunogen, we have determined the recognition of these synthetic peptides by proliferative T-helper lymphocytes (ThL), delayed type hypersensitivity (DTH), and cytotoxic T-lymphocytes (CTL) responses. The responses to the individual determinants in each of these immune compartments were under separate Ir gene control. Conversely, using the peptides as immunogens, we have determined the ability of various peptide-specific antibodies (in outbred mice) and ThLs (in H-2k, H-2d, H-2s and H-2b mice) to recognize intact virus. Whereas most of the peptides primed the mice for an anti-peptide proliferative ThL response, only very few of these cross-reacted with the virus. The identity of the peptide(s) eliciting virus cross-reactive ThLs varied with the strain. The importance of antibody, ThL, CTL and DTH responses in protection against viral infection and in vaccine design is discussed.

Cytotoxic T lymphocyte recognition sites on influenza virus hemagglutinin

When influenza virus infection occurs, part of the cytotoxic T lymphocyte responses induced are directed to the major surface molecule of the virus, the hemagglutinin. However, despite their potential use as a peptide vaccine, little information is available concerning the submolecular areas in the hemagglutinin that are responsible for its immunologic recognition by cytotoxic T lymphocytes. The primary goal of this study is to determine whether submolecular areas recognized by antibodies and helper T cells are also important in the virus-specific, T lymphocyte-mediated cytotoxic responses generated towards virus-infected cells. A panel of synthetic peptides representing areas of the hemagglutinin, homologous to those in influenza AX-31 virus which have previously been shown to bind anti-influenza virus antibodies and provoke proliferation of virus-primed T-helper lymphocytes, was tested in two different cytotoxicity assays. In the experiments presented here, it was found that when selected peptides were incubated with appropriate L929 target cells, lysis by virus-specific cytotoxic T cells was observed. In addition, AX-31-primed lymphocytes preincubated with these synthetic peptides (both individually and as an equimolar mixture) exhibited enhanced lysis of virus-infected syngeneic targets. The cytotoxic responses showed dose-response characteristics in all cases, and in each of the two assays used the same patterns of cytotoxic induction were observed. The recognition of peptides was MHC-restricted since virus-specific cytotoxic T cells from C3H/He mice (H-2k) lysed L929 (H-2k) target cells after incubation with peptides or viruses, but did not lyse P815 (H-2d) targets under the same conditions.

Influenza A virus M2 protein: monoclonal antibody restriction of virus growth and detection of M2 in virions

The influenza A virus M2 protein is an integral membrane protein of 97 amino acids that is expressed at the surface of infected cells with an extracellular N-terminal domain of 18 to 23 amino acid residues, an internal hydrophobic domain of approximately 19 residues, and a C-terminal cytoplasmic domain of 54 residues. To gain an understanding of the M2 protein function in the influenza virus replicative pathway, we produced and characterized a monoclonal antibody to M2. The antibody-binding site was located to the extracellular N terminus of M2 as shown by the loss of recognition after proteolysis at the infected-cell surface, which removes 18 N-terminal residues, and by the finding that the antibody recognizes M2 in cell surface fluorescence. The epitope was further defined to involve residues 11 and 14 by comparing the predicted amino acid sequences of M2 from several avian and human strains and the ability of the M2 protein to be recognized by the antibody. The M2-specific monoclonal antibody was used in a sensitive immunoblot assay to show that M2 protein could be detected in virion preparations. Quantitation of the amount of M2 associated with virions by two unrelated methods indicated that in the virion preparations used there are 14 to 68 molecules of M2 per virion. The monoclonal antibody, when included in a plaque assay overlay, considerably showed the growth of some influenza virus strains. This plaque size reduction is a specific effect for the M2 antibody as determined by an analysis of recombinants with defined genome composition and by the observation that competition by an N-terminal peptide prevents the antibody restriction of virus growth.

Localization of RNA polymerases on influenza viral ribonucleoproteins by immunogold labeling

Monospecific antisera for the influenza polymerase proteins and high resolution immunoelectron microscopy have been used to investigate the topographical distribution of the polymerase molecules on influenza ribonucleoproteins (RNPs). Antibodies to PB1, PB2, and PA identify a single polymerase binding site located at, or very close to, the end of each RNP. Double labeling experiments confirm that all three polymerases are at the same end of each RNP and that they are in close association.

Structural changes in the haemagglutinin which accompany egg adaptation of an influenza A(H1N1) virus

Antigenic changes are often induced in the haemagglutinin (HA) of human isolates of influenza A(H1N1) and B viruses during their isolation and propagation in embryonated hens' eggs. In this report we describe molecular changes in the HA of an A(H1N1) virus which accompany egg adaptation. The HA1 amino acid substitutions of egg-adapted variants are located in the vicinity of the receptor binding site. This suggests that egg-adapted variants are selected on the basis of altered receptor site specificity with concomitant effects on the antigenic configuration of the HA molecule. In this study, at least three antigenically distinct groups of egg-adapted variants were observed. These observations have implications for the indiscriminate use of egg-adapted viruses in sero-epidemiological studies and vaccine production.

Quantitative relationships between an influenza virus and neutralizing antibody

In this quantitative study of the interaction of influenza virus with neutralizing antibody we have determined the maximum number of antibody molecules which can bind to the haemagglutinin (HA) of native influenza A/FPV/Rostock/34 (H7N1) particles in aqueous suspension and the minimum number which is required to cause neutralization. Using radiolabelled immunoglobulins approximately one IgG molecule, whether of monoclonal or polyclonal origin, binds per HA spike under conditions of antibody saturation. In the same manner, we have determined that when infectivity is neutralized by 63% (1/e) about 70 molecules of monoclonal IgGs HC2 and HC10 were bound per virus particle and this is supported by independent evidence from electron microscopy. However, the kinetics of neutralization were single-hit or at most, under critical conditions of low temperature (4 degrees) and minimal neutralizing concentrations of antibody, two-hit. This apparent conflict is reconciled by a hypothesis which proposes that neutralization occurs only when antibody binds to certain "neutralization relevant" HA spikes which are in the minority. It is suggested that these only differ from the majority of "neutralization irrelevant" HA spikes by their transmembrane interaction with the core of the virion.

Conformational changes in the hemagglutinin of influenza virus which accompany heat-induced fusion of virus with liposomes

Incubation of X-31 influenza virus at 62 degrees results in changes in hemagglutinin structure which cause the virus to fuse with liposomes at neutral pH. Mutants of X-31 which contain different hemagglutinins and as a consequence fuse with liposomes at higher pH than wild-type virus also fuse at a lower temperature. The heat-induced changes in hemagglutinin structure were monitored by CD, fluorescence spectroscopy, electron microscopy, and proteolytic digestion and compared with the characteristic changes which occur at low pH required for hemagglutinin-mediated membrane fusion at physiological temperature. The results indicate that the heat-induced changes in hemagglutinin which allow fusion activity result in partial denaturation of the molecule. By comparison the changes in structure required for fusion at low pH and normal temperature are specifically restricted.

Biochemical and antigenic analysis using monoclonal antibodies of a series of of influenza A (H3N2) and (H1N1) virus reassortants

Reassortant influenza A viruses with high growth capacity in eggs and suitable as candidate vaccine strains or as standard reagents for influenza HA quantification were prepared using the high yielding A/PR/8/34 (H1N1) as one parent and a number of 'wild' strains of influenza A (H1N1) or (H3N2) viruses as the other parent. The genetic and antigenic composition of the reassortants was determined. The parental derivation of genes in the reassortants was established by electrophoretic analysis of virus RNA and virus induced polypeptides. The haemagglutinin (HA) antigens of the three H1N1 viruses (NIB-6, NIB-7 NIB-12) were found to resemble those of the parental viruses when tested against a panel of monoclonal antibodies and using the HI test. A similar correspondence between the antigenic characteristics of the HA of the influenza A (H3N2) reassortants (NIB-1, NIB-4, NIB-5, NIB-8 and NIB-11) and parental viruses was noted. Therefore laboratory manipulations to produce the reassortants did not result in the selection of significant antigenic variants.

Comparative analyses of the specificities of anti-influenza hemagglutinin antibodies in human sera

Estimates of the variety of specificities of anti-influenza hemagglutinin antibodies in postinfection human sera taken between 1969 and 1971 and in 1978 were made by using Fab fragments of defined monoclonal antibodies in competitive virus-binding assays. The results obtained with the sera taken between 1969 and 1971 indicated that different sera contained antibodies with different ranges of specificities, whereas the 1978 sera mainly contained a broad range of antibodies. The results are discussed in relation to the mechanism of antigenic drift in influenza virus, the commonly observed antigenic heterogeneity of influenza virus isolates, and the efficacy of antiinfluenza vaccination.

Differential infection of receptor-modified host cells by receptor-specific influenza viruses

Influenza viruses of contrasting receptor specificity have been examined for their ability to infect receptor-modified MDCK cells containing sialyloligosaccharide receptor determinants of defined sequence. Cells were treated with sialidase to remove sialic acid and render them resistant to infection and were then incubated with sialyltransferase and CMP-sialic acid to restore sialic acid in the SA alpha 2,6Gal or SA alpha 2,3Gal linkages. The viruses A/RI/5 + /57 and A/duck/Ukraine/1/63, previously shown to exhibit preferential binding of SA alpha 2,6Gal and SA alpha 2,3Gal linkages, respectively, were found to exhibit differential infection of the receptor-modified cells in accord with their receptor specificity. Coinfection of SA alpha 2,3Gal derivatized cells with a mixture of the two viruses resulted in selective propagation of the SA alpha 2,3Gal-specific A/duck/Ukraine/1/63 virus. The results demonstrate the potential for cell surface receptors to mediate selection of receptor-specific variants of influenza virus.

Interaction of influenza virus haemagglutinin with cell membranes

Influenza virus causes susceptible cells to undergo haemagglutination, haemolysis and oxygen radical formation. Each activity is the result of an interaction between the haemagglutinin (HA) glycoprotein and the cell plasma membrane, and appears to involve three discrete functions of the HA glycoprotein.

Host antigens associated with haemagglutinin

A delayed-type hypersensitivity (DTH) test has been used to detect the presence of host-specific antigen(s) is highly purified egg-grown influenza virus, virus components and isolated haemagglutinin. Cyclophosphamide-treated mice, primed with an extract from allantoic fluid, showed DTH reactions when challenged with preparations containing envelope lipid or polymer-type subunits, whereas lipid-free derivatives such as internal virus protein complexes and monomer haemagglutinin preparations lacked the activity. This approach has been extended to demonstrate the presence of associated host antigens in SV40-vector expressed haemagglutinin produced in simian cells.

An efficient method for introducing macromolecules into living cells

The hemagglutinin (HA) of influenza virus was used to obtain efficient and rapid bulk delivery of antibodies and horseradish peroxidase (HRP) into the cytoplasm of living tissue culture cells. By exploiting HA's efficient cell surface expression, its high affinity for erythrocytes, and its acid-dependent membrane fusion activity, a novel delivery method was developed. The approach is unique in that the mediator of both binding and fusion (the HA) is present on the surfaces of the target cells. A recently developed 3T3 cell line which permanently expresses HA, Madin-Darby canine kidney cells infected with influenza virus, and CV-1 cells infected with a simian virus 40 vector carrying the HA gene were used as recipient cells. Protein-loaded erythrocytes were bound to the HA on the cell surface and a brief drop in pH to 5.0 was used to trigger HA's fusion activity and hence delivery. About 3 to 8 erythrocytes fused per 3T3 and CV-1 cell, respectively, and 75-95% of the cells received IgG or HRP. Quantitative analysis showed that 1.8 X 10(8) molecules of HRP and 1.4 X 10(7) IgG molecules were delivered per CV-1 cell and 6.2 X 10(7) HRP molecules per 3T3 cell. Cell viability, as judged by methionine incorporation into protein and cell growth and division, was not impaired. Electron and fluorescence microscopy showed that the fused erythrocyte membranes remained as discrete domains in the cell's plasma membrane. The method is simple, reliable, and nonlytic. The ability to simultaneously and rapidly deliver impermeable substances into large numbers of cells will permit biochemical analysis of the fate and effect of a variety of delivered molecules.

Alterations in the hemagglutinin associated with adaptation of influenza B virus to growth in eggs

In 1943 Burnet reported on changes in the hemagglutinating properties of human influenza virus which occurred during adaptation of the virus to growth in chicken eggs. Only recently has direct evidence been presented that these changes affect the antigenic properties of the virus. Schild et al. (G. C. Schild, J. S. Oxford, J. C. deJong, and R. G. Webster (1983), Nature (London) 303, 706-709) demonstrated that egg adaptation of influenza B virus selects variants which are antigenically distinct from virus grown from the same source in mammalian cells. The molecular changes in the hemagglutinin (HA) of influenza B virus associated with adaptation to growth in eggs have now been identified. A specific glycosylation site at the distal tip of the HA of influenza B virus grown exclusively in mammalian cell culture is lost or altered during egg adaptation. Since the HA functions in adsorption of virus to cells, it is concluded that removal or modification of an oligosaccharide structure at this position is required for influenza B virus to attach to and infect the allantois cells of the egg and that this has important implications for the antigenic configuration of the molecule.

Hybridoma antibodies produced against bromelain derived cores of influenza virus

Splenic lymphocytes from BALB/c mice immunized with "cores" of influenza virus, obtained after bromelain cleavage of the surface glycoprotein, were fused with the P3-NS1/1-Ag-1 mouse cell line to yield hybridoma cultures. Among 20 stable cloned hybrid cells secreting monoclonal antibodies, one was specific for the nucleoprotein (NP), 11 were specific for the membrane (M) protein and eight were specific for the hemagglutinin (HA). These "cores" used as immunogen contained only the internal proteins of the influenza virus, namely the three polymerases, the NP and the M protein and no HA when examined by standard procedures of SDS-PAGE, electron microscopy and hemagglutination activity. It thus appeared that a small amount of contaminating antigens can sensitize a sufficient number of mouse B cells to be selected as hybrid partners. These antibodies were provisionally assigned as anti-carbohydrate attached to the HA.

Activation of the ppp(A2'p)nA system in interferon-treated, herpes simplex virus-infected cells and evidence for novel inhibitors of the ppp(A2'p)nA-dependent RNase

High doses (100-1000 reference units/ml) of alpha or beta interferons are required to inhibit the growth of herpes simplex virus types I and II (HSV-I and HSV-II) in human Chang cells. In contrast, much lower doses (10-100 reference units/ml) of interferon inhibit replication of encephalomyocarditis virus (EMCV) in these cells. In the HSV-infected cells these high doses did not prevent the virus-induced shut off of host protein synthesis. The interferons were more effective in reducing the virus yield of HSV-I than of HSV-II. At the above concentrations they inhibited HSV-I protein synthesis but had little apparent effect on that of HSV-II. Similar amounts of (2'-5')oligo(adenylate)s were synthesised in response to HSV-I, HSV-II and EMCV infection of Chang cells after treatment with alpha or beta interferons. No (i.e. less than 1 nM) (2'-5')oligo(adenylate)s were found in control cells or on virus infection alone. Only low levels of ppp(A2'p)nA-specific rRNA cleavage were observed in the interferon-treated HSV-infected cells. In contrast, high levels were found in response to EMCV, despite the fact that ppp(A2'p)nA accumulated to similar levels with each of the three viruses in these cells. High-performance liquid chromatographic analysis of material from interferon-treated Chang cells 18 h after infection with HSV-I or HSV-II, combined with radiobinding, radioimmune and rRNA cleavage assays, confirmed the presence of ppp(A2'p)2A and ppp(A2'p)3A at greater than nanomolar concentration. In addition, apparently equivalent amounts of two other putative (2'-5')oligo(adenylate) derivatives which compete in the radiobinding and radioimmune assays, were present. These compounds were only weak activators of the ppp(A2'p)nA-dependent RNase and under appropriate conditions were capable of inhibiting the activation of this RNase by authentic ppp(A2'p)nA. The presence of these potentially inhibitory compounds provides a possible explanation for the relatively low levels of activation of the ppp(A2'p)nA-dependent RNase in interferon-treated, HSV-infected Chang cells.

An investigation of antigenic drift of neuraminidases of influenza A (H1N1) viruses

A newly developed lectin neuraminidase test (LNT) and a panel of mouse monoclonal and post-infection ferret antibodies have been used to analyse antigenic drift in N1 neuraminidases of influenza A viruses isolated between 1933 and 1957 and also between 1977 and 1980. Significant antigenic differences were detected among the 'early' (1933-57) viruses since the NA of viruses isolated one year apart could be distinguished serologically. The NA of the 're-emerged' virus A/USSR/92/77 (H1N1) was antigenically related but not identical to influenza A viruses isolated in 1949 (A/Paris/49 (H1N1), A/Geneva/49 (H1N1) which thus predates the previously observed antigenic similarity of A/USSR/77 with A/FW/50 (H1N1) virus.

Identification of the influenza virus transcriptase by affinity-labeling with pyridoxal 5'-phosphate

Pyridoxal 5'-phosphate (PLP), a reversible inhibitor of in vitro transcription by fowl plaque virus, has been used to identify the transcriptase. Kinetic analyses showed that PLP competitively inhibits the addition of each nucleoside triphosphate in ApG-primed reactions, suggesting that both initiation and elongation are affected. The irreversible inhibition by PLP following reduction with borohydride was prevented by preincubation with the first substrate: GTP in unprimed reactions or CTP in the presence of ApG. On reaction of FPV proteins with PLP and [3H]borohydride the core protein PB1 was preferentially labeled and the labeling was selectively blocked by GTP or ApG + CTP. These data suggest that PB1 has the nucleotide-binding site of the transcriptase, is responsible for both initiation and elongation, and is apparently associated with the 3' ends of template RNAs in virions.

Biochemical and serological studies of influenza B viruses: comparisons of historical and recent isolates

The genetic characteristics of 24 representative influenza B viruses isolated in widely different geographical areas of the world between 1940 and 1980 were analysed using either RNA:RNA hybridisation or oligonucleotide mapping. Additional biochemical characterisation included electrophoretic analysis of virus-induced polypeptides and virion RNAs. A panel of monoclonal antibodies to virus HA was used to investigate serological relationships between the viruses. The influenza B viruses examined constituted a genetically and serologically related group but mutational changes were detected in all eight genes of the viruses isolated in different eras and also in genes of viruses isolated in the same epidemic year. Regardless of the overall and dominating similarities, at a higher level of discrimination it was clear that certain genetic and serological relationships were more complex than expected and, for example, some recently circulating field viruses were apparently more closely related antigenically and genetically to viruses isolated five to twelve years previously than to other viruses isolated concurrently. No evidence of recombination with hitherto undescribed influenza B viruses and with genes coding for internal proteins was detected.

The estimation of host antigen in experimental and commercial influenza subunit preparations by delayed-type hypersensitivity reaction

A delayed-type hypersensitivity (DTH) test has been used to detect the presence of host-specific antigen(s) in highly-purified egg-grown influenza virus and virus components. Cyclophosphamide-treated mice, primed with an extract from allantoic fluid, showed DTH reactions when challenged with whole virus, spikeless virus particles or polymer-type subunits. All commercial egg-grown influenza vaccines showed the presence of host antigen, whereas lipid-free derivatives such as internal virus protein complexes and monomer HA preparations lacked the activity. These findings are discussed in relation to vaccine application.

Single amino acid substitutions in influenza haemagglutinin change receptor binding specificity

The haemagglutinin (HA) glycoproteins of influenza virus membranes are responsible for binding viruses to cells by interacting with membrane receptor molecules which contain sialic acid (for review see ref. 1). This interaction is known to vary in detailed specificity for different influenza viruses (see, for example, refs 2-4) and we have attempted to identify the sialic acid binding site of the haemagglutinin by comparing the amino acid sequences of haemagglutinins with different binding specificities. We present here evidence that haemagglutinins which differ in recognizing either NeuAc alpha 2 leads to 3Gal- or NeuAc alpha 2 leads to 6Gal- linkages in glycoproteins also differ at amino acid 226 of HA1. This residue is located in a pocket on the distal tip of the molecule, an area previously proposed from considerations of the three-dimensional structure of the haemagglutinin to be involved in receptor binding.

[Influenza]

Influenza is the last great uncontrolled plague of mankind. Pandemics and epidemics occur at regular time intervals. The influenza viruses are divided into the types A, B and C and show unique variability of their surface antigens (hemagglutinin and neuraminidase). Influenza viruses of type A show the largest degree of antigenic variation which, in turn, resulted in the definition of a number of subtypes, each comprising many strains. By comparison, influenza viruses of types B and C exhibit much less variation of their surface antigens. As a consequence, no subtypes but many different strains have been recognized. The degree of antigenic variation correlates with the epidemiologic significance of the virus types, type A being the most and type C the least important. Two different kinds of antigenic variation have been recognized: In the case of minor variation of one or both surface antigens, the term "antigenic drift" is employed. Antigenic drift occurs with all three types of virus, it is caused by point mutations which increase the chance of survival of mutants in the diseased host. In addition, influenza A viruses show sudden and complete changes of their surface antigens in regular time intervals, resulting in the appearance of new subtypes. This event is called "antigenic shift". The mechanisms responsible for antigenic shift are poorly understood, only. In addition to the recycling of preceding subtypes, reassortment resulting from double infection of cells with strains of human and animal origin are considered possible explanations. By use of modern DNA recombinant technology, the base sequences of a series of virus genes and, as a consequence, the amino acid sequence of the corresponding antigens have been determined. By means of monoclonal antibodies, the antigenic structure of many influenza antigens has been further elucidated. It can be expected that further research on the molecular basis of antigenic variation could finally result in an understanding of the causal mechanisms. It is an outstanding feature of the epidemiology of influenza A viruses that a family of related strains prevails for a certain period of time and disappears abruptly as a new subtype emerges.(ABSTRACT TRUNCATED AT 400 WORDS)

Disulfide bonding in influenza virus proteins as revealed by polyacrylamide gel electrophoresis

Disulfide bonding in the major proteins of influenza virus A, WSN strain, was studied by electrophoresis in sodium dodecyl sulfate-polyacrylamide gels under reducing and nonreducing conditions. The electrophoretic behavior of the proteins correlated with their localization in the virions and their chemical composition. The internal proteins of the viral particles, i.e. matrix and nucleoproteins, were shown to contain a relatively small number of cysteine residues. Electrophoresis under nonreducing conditions yielded multiple forms of the proteins which could be discriminated by small but readily observable, reproducible differences in their migration rates in the gel. the multiplicity of the protein forms was caused by the formation of intramolecular disulfide bonds in matrix and nucleoproteins that arose during or after solubilization in sodium dodecyl sulfate. On the other hand, we failed to detect native inter- and intramolecular linkages in matrix and nucleoproteins. External glycoproteins of the virions (HA and NA) had, in contrast to the internal ones, a higher number of cysteine residues and native disulfide bonds. At least three disulfide linkages were revealed in HA and NA in our experiments. In uncleaved HA all of the linkages were intramolecular. In NA at least one disulfide bond linked two identical polypeptides into a dimer. It was established that the reduction of the different disulfide linkages in HA and NA required different concentrations of the reducing agent.

Evidence of diffusion artefacts in diaminobenzidine immunocytochemistry revealed during immune electron microscope studies of the early interactions between influenza virus and cells

Anti-haemagglutinin-labelled antibodies have been used to search for influenza entry into cells by fusion of viral and plasma membranes. The plasma membranes of infected cells were stained by immunoperoxidase but not by immunoferritin reagents. It is suggested that the staining obtained with the peroxidase conjugate was due to diffusion of the diaminobenzidine reaction product away from the enzymic site. Immunoferritin labelling provided no evidence for entry of influenza by fusion of viral and plasma membranes under conditions of physiological pH.

Quantitation and analysis of the specificity of post-immunization antibodies to influenza B viruses using single radial haemolysis

The single radial haemolysis (SRH) technique detected anti-B/HK/8/73 HA antibody rises in 59-85% of paired sera from persons immunized with different influenza vaccines. In contrast, analysis of the same sera by the haemagglutination inhibition (HI) test indicated significant antibody rises in only 27-54% of paired sera. High levels of antibody were detected to influenza B/HK/8/73 and B/Singapore/222/79 viruses in post-immunization sera analysed by SRH, whereas the HI test indicated comparatively low geometric means antibody titres. Most adults responded to immunization with influenza B virus by producing cross-reactive (CR) antibody which reacted with different influenza B viruses including the early isolate B/Lee/40.

Peptide mapping of 125I-labelled membrane protein of influenza viruses by reverse-phase high-performance liquid chromatography

The resolution potential of reverse-phase high-performance liquid chromatography (HPLC) for peptide analysis of hydrophobic viral membranes has been investigated, using as model the membrane (M) protein of influenza virus. Proteolytic digests of 125I-labelled M protein and CNBr fragments, extracted from radioiodinated whole virus, have been separated on a uBondapak C18 column with an isopropanol or acetonitrile solvent system. Peptide mapping of trypsin digests of M protein from A/PR/8/34 (H1N1) and A/chicken/Germany/N/49 (H10N7) viruses was identical, whereas Staphylococcus aureus V8 protease digests showed minor differences in at least two peptides. The results also show that HPLC is a powerful tool for the separation of proteolytic digests of viral proteins, since the peptide maps are highly reproducible and recovery was greater than 85%.

Changes in the conformation of influenza virus hemagglutinin at the pH optimum of virus-mediated membrane fusion

A conformational change in the hemagglutinin glycoprotein of influenza virus has been observed to occur to pH values corresponding to those optimal for the membrane fusion activity of the virus. CD, electron microscopic, and sedimentation analyses show that, in the pH range 5.2-4.9, bromelain-solubilized hemagglutinin (BHA) aggregates as protein-protein rosettes and acquires the ability to bind both lipid vesicles and nonionic detergent. Trypsin treatment of BHA in the pH 5.0-induced conformation indicates that aggregation is a property of the BHA2 component and that the conformation change also involves BHA1. The implications of these observations for the role of the glycoprotein in membrane fusion are discussed.

Studies on neuraminidase from influenza virus A(H3N2) obtained by two procedures

1. Neuraminidase was obtained by (A) bromelain solubilization or (B) by treatment with N-lauroylsarcosine. 2. 5-N-acetyl-2-O-(3-methoxyphenyl)-alpha-D-neuraminic acid, employed as substrate, avoids the interference produced by the thiobarbituric acid method, and is not interfered by the ampholytes. 3. Only about 20% of original enzyme activity was lost after electrofocusing. The sample from procedure A showed two peaks, corresponding to pIs 4.4 and 5.6. The sample from procedure B, having a higher activity, showed only one peak at pI 4.4. 4. Samples A and B showed different Km and hydrolysis rate with N-acetylneuraminyl-lactose and glycophorin A. It was not found significantly different with other substrates: alpha 1-acid glycoprotein, brain gangliosides, 5-N-acetyl-2-O-(3-methoxyphenyl)-alpha-D-neuraminic acid and 2'-(4-methyl umbelliferyl)-alpha-D-N-acetylneuraminic acid.

Strain specificity of serum antibody to the haemagglutinin of influenza A (H3N2) viruses in children following immunization or natural infection

The specificity of serum anti-HA antibody from children immunized or infected with A/Victoria/75 (H3N2 or A/Texas/77 (H3N2) virus was examined using the single radial haemolysis test together with adsorption of antibody with three antigenic variants A/Hong Kong/68 (H3N2), A/Port Chalmers/73 (H3N2) and A/Victoria/75 (H3N2). The majority of young children reacted to vaccination or infection by producing strain-specific (SS) antibody to the homologous virus. A small proportion of children's sera contained cross-reacting (CR) antibodies capable of reacting with the haemagglutinins of all antigenic variants of the sub-type including A/HK/1/68. In contrast, most adults reacted immunologically to either vaccination or infection by producing CR antibody, reacting with all variants of the antigenic subtype including the prototype virus A/HK/1/68 (H3N2).

Glycosylation sites of influenza viral glycoproteins: characterization of tryptic glycopeptides from the A/USSR(H1N1) hemagglutinin glycoprotein

Glycosylated tryptic peptides of the hemagglutinin (HA) glycoprotein of influenza A/USSR/90/77(H1N1) virus were separated by a combination of ion-exchange chromatography and gel filtration. Seven different glycosylated tryptic peptide classes were obtained from the HA1 polypeptide, and only one glycosylated peptide was obtained from the HA2 polypeptide. Several of the tryptic fragments of HA1 and the HA2 glycopeptides were sulfated. The nature of the carbohydrate chain in each of the glycosylated tryptic peptides was determined from observations of the incorporation of different sugar precursors and susceptibility to cleavage by the enzyme endoglycosidase H and by compositional analysis by gas chromatography. Such analyses showed that three types of carbohydrate chains were present in HA1 (type I [complex], type II [high mannose], and hybrid type), whereas HA2 contained only type I oligosaccharide chains. The amino acid composition of each of the glycosylated tryptic peptides was also determined.

Neuraminidase from influenza virus A (H3N2): specificity towards several substrates and procedure of activity determination

Neuraminidase (acylneuraminyl hydrolase, EC 3.2.1.18) from the influenza virus A/Hong Kong/68 (H3N2) was purified after treatment of the purified virus with sarcosyl (sodium laurylsarcosinate), centrifugation at 110 000 x g, and chromatography on DEAE-Sephadex and Sephadex G-200. It migrated as a single component during electrophoresis on polyacrylamide gel, and its molecular weight was estimated about 270 000. The enzyme was thermolabile, the activity being reduced to 60% in 10 min at 50 degrees C. The purified neuraminidase had an apparent Km value of 4.1 . 10(-3) M for 5-N-acetyl-2-O-(3-methoxyphenyl)-alpha-D-neuraminic acid and was able to release sialic acid with linkages alpha 2-3, alpha 2-6 and alpha 2-8 (with very different efficiency) from fetuin, gangliosides, colominic acid, and bovine and porcine submaxillary mucins. The enzymic activity was measured by several procedures: (A) spectrophotometric determination at 340 nm of the NADH produced in the reaction catalysed by beta-galactose dehydrogenase on beta-galactose + NAD+, this beta-galactose was the product released from lactose by beta-galactosidase and lactose was the product of the neuraminidase activity on N-acetylneuraminyl-lactose; (B) determination of the colored quinone yielded by the liberated methoxyphenol with 4-aminoantipyrine (Santer, U.V., Yee-Foon, J. and Glick, M.C. (1978) Biochim. Biophys. Acta 523, 435-442); (C) periodate-thiobarbiturate procedures (Warren, L. (1959) J. Biol. Chem 234, 1971-1975 or Aminoff, D. (1961) Biochem. J. 81, 384-391). Some peculiarities of these methods are discussed.

Cell cooperation in antibody responses to influenza virus. I. priming of helper t cells by internal components of virion

T cells recognizing internal components of the influenza virion can cooperate with B cells recognizing hemagglutinin to enhance the hemagglutinin inhibition (HAI) antibody response. Cooperation occurs only when the internal proteins and hemagglutinin are subsequently presented in association. The effect enhances the production of both 2-mercaptoethanol-resistant and -sensitive antibodies. The cooperating cells express the Thy-1+, Ly-1+2- surface phenotype and thus are characteristic of helper T cells. Immunization of mice with the internal components of the virion increases survival after exposure to lethal influenza infection. Mice primed with purified matrix protein produce enhanced amounts of HAI antibody after infection with influenza. These results may help to explain reports on the effects of heterotypic infection on antibody production, and also heterotypic immunity.