Class II-restricted T-cell clones to a synthetic peptide of influenza virus hemagglutinin differ in their fine specificities and in the ability to respond to virus.

Fifteen T-cell clones were derived from BALB/c or DBA/2 mice immunized with a synthetic peptide corresponding to the C-terminal 24 residues (residues 305 to 328) of the HA1 chain of H3 subtype influenza virus hemagglutinin. All of the clones proliferated when the peptide was presented in association with I-Ed. By using shorter homologs, it was shown that the T-cell response was focused predominantly on the region at the N-terminal end of the peptide encompassed by residues 306 to 319. Individual clones recognizing this region differed in their absolute requirements for residues at the extremities of the site and also in their patterns of efficiency of recognition of shorter homologs. One particular clone defined another site of T-cell recognition within residues 314 to 328. The response of the clones to peptide analogs identified certain residues within the sites that were critical for recognition, with the substitution Gln-311----Ser having a differential effect on clones responding to the N-terminal site. Only one of the clones responded well to influenza virus itself. This clone also required relatively low concentrations of the parent peptide for optimum stimulation and was suppressed by higher concentrations. The data demonstrate striking heterogeneity in the T-cell response even to a short synthetic peptide, with different T-cell clones recognizing slightly different but overlapping areas of the molecule.     

Genetic control and fine specificity of the immune response to a synthetic peptide of influenza virus hemagglutinin.

The immune response to a synthetic peptide, H3 HA1(305-328), representing the C'-terminal 24 amino acid residues of the HA1 chain of the hemagglutinin of the H3 subtype of influenza virus is controlled by genes in the I region of the major histocompatibility complex. Mice of the H-2d haplotype are high responders and produce antibody for several months after a single injection of peptide without carrier. Mice of the H-2b, H-2k, and H-2q haplotypes are low antibody responders. Investigation of recombinant and congenic mouse strains revealed that high responsiveness requires the genes that encode the I-Ed molecule. Immunoassays, involving direct binding to analogs of this peptide and inhibition by both these analogs and synthetic epitopes, were used to analyze the specificity of the polyclonal response. In BALB/c mice, the primary antibody response is directed principally against the antigenic site 314-LKLAT-318, whereas the secondary response after a boost is predominantly directed to a distinct site, 320-MRNVPEKQT-328. The T-cell response to the peptide H3 HA1(305-328), as measured by antigen-induced proliferation of primed T cells in vitro, is also I-Ed restricted in high-responder H-2d mice and is directed against an antigenic site that does not require the four C-terminal residues unique to the H3 influenza subtype. A different epitope appears to be recognized by T cells from CBA (H-2k) mice, which proliferate to a moderate extent on exposure to the peptide but, nevertheless, do not provide help for an antibody response.     

In vitro antibody response to influenza virus. II. Specificity of helper T cell recognizing hemagglutinin

Intraperitoneal immunization of mice with liver influenza virus was shown to induce helper T (TH) cells with specificity for the hemagglutinin (HA). The interaction of virus-primed TH cells with purified HA was studied independently of B cell reactivity to the same antigen by using the generation of nonspecific help as an index of activation of HA-specific TH cells. TH cells from mice primed with any of the H3 viruses A/Aichi/68 X A/Bel/42 (H3N1), A/Memphis/102/72 X A/Bel/42 (H3N1) or A/Port Chalmers/73 (H3N2) were strongly cross-reactive towards HA of other strains within the H3 subtype. In addition, several examples of cross-reactivity towards HA of a different subtype were observed, usually of a lower magnitude. TH cells from mice primed to any of the H3 viruses above or to A/Bel/42 (H1N1) virus cross-reacted with the HA of A/Japan/305/57 (H2); furthermore, priming with A/Bel/42 or with A/Jap/305/57 X A/Bel/42 (h2N1) virus yielded TH cells that cross-reacted with certain of the H3 HA preparations. The cross-reactivity observed between subtypes was not due to the common chicken host carbohydrate component of HA, since no response to the purified type A HA preparations was obtained with T cells from mice primed with egg-grown influenza B/Hong-Kong/8/73 virus. The results indicate that HA of different subtypes may share cross-reactive antigenic determinants recognized by TH cells. Within a subtype, HA are highly cross-reactive with respect to tH cell recognition.     

Mapping of a protective helper T cell epitope of human influenza A virus hemagglutinin

The synthetic peptide comprising the 317-341 region of human influenza A virus (H1N1 subtype) hemagglutinin elicits peptide-specific antibody and helper T cell responses and confers protection against lethal virus infection. Molecular mapping of the 317-329 region, which encompasses the epitope recognized by peptide-specific T cells, revealed that the minimal size required for T cell activation was the 317-326 segment. The most likely peptide alignment, which placed 320Leu to pocket 1 of the I-E(d) peptide binding groove, was predicted by molecular mechanics calculations performed with the parental and with the Ala-substituted analogs. In line with the prediction data, the results of the peptide binding assay, where the relative binding efficiency to I-E(d) molecules expressed on the surface of antigen-presenting cells was monitored, identified the 320-326 core sequence interacting with the major histocompatibility class II peptide binding groove. Functional analysis of Ala-substituted variants by functional assays and by calculating the surface-accessible areas of the single peptidic amino acids in the I-E(d)-peptide complexes demonstrated that 324Pro is a primary contact residue for the T cell receptor. Our results show that this type of analysis offers a suitable tool for molecular mapping of helper T cell epitopes and thus provides valuable data for subunit vaccine design.     

A large degree of functional diversity exists among helper T cells specific for the same antigenic site of influenza hemagglutinin.

The site-1 determinant of the hemagglutinin molecule of influenza virus (A/PR/8/34) is one of several immunodominant sites in the BALB/c Th cell response to Ha. A synthetic peptide comprising this T cell site (HA110-120), a panel of analogs containing single substitutions in this determinant, and homologs truncated at the amino- or carboxyl-terminal were used to examine the fine specificities of 15 T cells specific for site-1 in the context of I-Ed. The results indicate that every residue within the minimal determinant plays a role in the T cell recognition process, as single substitutions at any of these positions affected the ability of the peptide to stimulate at least some site 1-specific T cells. For the majority of the residues examined, substitutions had dissimilar effects on distinct T cells, indicating that the substituted residues were affecting recognition in a receptor-specific manner. Each of the 15 T cells examined had a distinct fine specificity pattern, suggesting that the BALB/c T cell repertoire for this site is likely to exceed 100 distinct clonotypes.     

Proliferating and helper T lymphocytes display distinct fine specificities in response to human fibrinopeptide B

The fine specificity of T cell responses involved in the generation of help for antibody production and proliferation was examined by using the 14 amino acid peptide human fibrinopeptide B (hFPB, B beta 1-14) and its synthetic peptide homologues B beta 1-14(Lys14), B beta 1-13, and B beta 3-14. Peritoneal exudate or lymph node T cells from C57BL/10 and B10.BR mice immunized with hFPB or its synthetic homologues were used to measure in vitro proliferative responses. T cells from hFPB-immunized B10.BR mice showed specific proliferation to hFPB, but were unresponsive to B beta 1-14(Lys14), B beta 1-13, and B beta 3-14. B10.BR mice immunized with B beta 1-14(Lys14), B beta 1-13, or B beta 3-14 were unresponsive to all peptides tested. T cells from C57BL/10 mice showed no specific proliferation after immunization and challenge with any of the peptide antigens. In contrast to the patterns of T cell proliferation, immunization of both B10.BR and C57BL/10 mice with hFPB, B beta 1-14(Lys14), B beta 1-13, or B beta 3-14 primed for significant helper T cell activity, as assessed by the augmentation of a primary in vitro B cell IgM anti-FITC plaque-forming cell response after culture with B beta 1-1(Lys14)-FITC. Significant peptide-specific helper activity was observed when the FITC moiety was conjugated to the carboxyl terminal lysine (B beta 1-14(Lys14)-FITC) as well as FITC substitution at the amino terminus (FITC-B beta 3-13 or FITC-B beta 3-14). These results suggest that the fine specificity of T cell responses to peptide antigens are different for helper and proliferating T cells and that responsiveness by one T cell subpopulation does not predict the response pattern of other functional subpopulations.     

Cytolytic T lymphocyte and antibody responses to synthetic peptides of influenza virus hemagglutinin

Two peptides corresponding to HA1(181-204) and HA2(103-123) of the A/Japan/305/57 influenza virus hemagglutinin (HA) were chemically synthesized by solid-phase methods and were tested for their ability to generate murine secondary anti-influenza cytolytic T lymphocytes (CTL) in vitro and to bind monoclonal anti-HA antibodies. Peptide HA1(181-204) could only generate CTL in the presence of helper factors contained in supernatant fluids from either Concanavalin A-stimulated mouse spleen cultures or WEHI-3 cells grown in vitro. Peptide HA2(103-123) stimulated the induction of anti-influenza CTL independent of helper factors, but the stimulation was also greatly increased if helper factors were added. A 10-fold molar excess of peptide HA2(103-123) was required to obtain optimal CTL activation over the quantities required in the HA1(181-204) system. This molar ratio remained unchanged, even in the presence of helper factors. Induction of influenza-specific CTL was antigen-dependent in both systems, even though some killing of noninfected target cells was also occasionally observed. Our results suggest that synthetic peptides can be recognized as antigenic determinants in the generation of H-2-restricted anti-viral CTL capable of killing appropriately infected target cells. The inability of peptide HA1(181-204) to generate sufficient help for CTL development suggests that certain regions of the HA can be recognized by CTL precursors, but not by all of the required helper cells. Peptide HA1(181-204) also reacted with three monoclonal anti-HA antibodies as well as mouse anti-influenza (A/Japan/305/57) immune sera. This antibody reactivity suggests the possibility of a shared antigenic epitope or region between T and B cells, and therefore provides new insight in our understanding of viral antigenicity.     

Role of receptor-binding activity of the viral hemagglutinin molecule in the presentation of influenza virus antigens to helper T cells.

The concentration of antigen required to stimulate influenza virus-specific helper T cells was observed to be dependent upon the antigenic form bearing the relevant determinant: intact, nonreplicative virus was needed only in picomolar amounts, while denatured proteins, protein fragments, or synthetic peptides were required in micromolar concentrations for a threshold level of stimulation. Antigenic efficiency of intact virus was found to result from the attachment of virus to sialic acid residues on the surface of the antigen-presenting cell since spikeless viral particles lacking the hemagglutinin molecule were much less efficient antigens for helper T cells and continuous presence of hemagglutination-inhibiting antihemagglutinin antibodies reduced efficiency of stimulation by intact virus approximately 100-fold for both hemagglutinin and internal virion proteins. Influenza virus associated rapidly with antigen-presenting cells; less than 10 min at 20 degrees C was sufficient to introduce virus for a maximal level of T-cell stimulation. This rapid attachment was blocked by antibodies to the hemagglutinin or by pretreatment of the antigen-presenting cells with neuraminidase to remove the cellular virus receptor. Following viral adsorption by antigen-presenting cells, a lag period of 30 min at 37 degrees C was required for the expression of helper T-cell determinants. One early event identified was the movement of the virus to a neuraminidase-insensitive compartment, which can occur at 10 degrees C, but which was not equivalent to expression of helper T-cell determinants. Preincubation of cells with virus at 10 degrees C for 4 h reduced the lag period of helper T-cell determinant expression to 15 min when these cells were shifted to 37 degrees C, suggesting that transition of the virus to a neuraminidase-resistant state is a required step in presentation of T-cell antigenic determinants.     

The recognition specificity of a murine helper T cell for hemagglutinin of influenza virus A/PR/8/34

Human large granular lymphocytes (LGL), which are known to be responsible for natural killer (NK) cell activity, also produced a variety of lymphokines including interleukin 2 (IL 2), colony stimulating factor (CSF), and interferon (IFN) in response to phytohemagglutinin (PHA) or concanavalin A (Con A). Human peripheral blood LGL, which were purified by removal of monocytes adhering to plastic flasks and nylon columns, followed by separation on a discontinuous Percoll gradient, and additional treatment with anti-OKT3 and Leu-M1 plus complement, were more potent producers of these lymphokines than unseparated mononuclear cells (MNC), nylon column-eluted cells, or purified T lymphocytes. Moreover, IL 2 production by LGL could be further distinguished in that it was not enhanced by the addition of macrophages or macrophage-derived factor, i.e., IL 1, whereas addition of macrophages did potentiate IL 2 production by T lymphocytes. Further analysis of cells in the LGL population using various monoclonal antibodies revealed that removal of cells with OKT11 or AF-10, a monoclonal antibody against human HLA-DR antigen, decreased IL 2 production, whereas removal of OKT8+, OKM1+, Leu-M1+, or Leu-7+ cells led to enhanced IL 2 production. The LGL population is therefore heterogeneous and includes at least three functionally and phenotypically distinct subsets. An atypical T cell subset (OKT3-, Leu-1-, OKT11+) rather than the myeloid subset of LGL (Leu-M1+ or OKMI+) was the source of LGL-derived IL 2, whereas the latter subset and/or another subset of OKT8+ cells appear to regulate this IL 2 production. In addition to performing NK activity, LGL on a per cell basis seem to be more effective than T lymphocytes in producing lymphokines, namely, IL2, CSF, and IFN.     

Immunologic response to influenza virus neuraminidase is influenced by prior experience with the associated viral hemagglutinin. III. Reduced generation of neuraminidase-specific helper T cells in hemagglutinin-primed mice

In BALB/c mice primed by influenza virus infection to H3 hemagglutinin and N2 neuraminidase, presentation of N2 in association with a heterosubtypic (H7) hemagglutinin results in production of a greater amount of N2 antibody than is found with homologous (H3N2) reimmunization. Titration of primed helper T cell (Th) activity by adoptive transfer of purified T cells to athymic mice given H6N2 vaccine demonstrates a lesser number of N2-specific Th cells in mice subjected to homologous reimmunization. We conclude that Th cells participate in the mediation of intermolecular (intravirionic) antigenic competition between influenza virus hemagglutinin and neuraminidase.     

pH-dependent membrane fusion activity of a synthetic twenty amino acid peptide with the same sequence as that of the hydrophobic segment of influenza virus hemagglutinin

A twenty amino acid hydrophobic peptide with the same sequence as that of the HA2 N-terminal segment of influenza virus hemagglutinin was synthesized and studied as to its fusion activity. The peptide caused rapid and efficient fusion of egg yolk phosphatidylcholine sonicated vesicles at acidic pH but not at neutral pH. The threshold pH was ca. 6.2 and the maximum fusion occurred at pH 4.8, the half-maximal pH for fusion being 5.6. The pH dependence was similar to that of the parent virus. The fusion efficiency was dependent on the ration of lipid to peptide, increasing with decreasing ratio. The fusion can be rapidly switched on and off by adjusting the pH, to the acidic side and neutral, respectively. The peptide with an acetylated or succinylated N-terminus also showed low pH-induced fusion activity but the pH range was shifted by ca. 1 unit to the acidic side. The results indicate that the HA2 hydrophobic segment in the virus fusion protein is directly involved in the fusion reaction and protonation of the acidic residues in the segment is required for the activity.     

Immune response to human influenza virus hemagglutinin expressed in Escherichia coli

Cloned DNA fragments coding for parts of strain WSN (H1N1) influenza virus hemagglutinin (HA) were fused to a bacterial leader DNA derived from the Escherichia coli trp operon. Fusion proteins produced consisted of 190 amino acids of trpLE' protein at the amino terminus, and HA amino acids, either 1-308, 1-396, or 1-548 (complete HA), at the carboxyl terminus. These proteins were expressed at high levels (10-20% of total protein) in E. coli starved for tryptophan. A CNBr fragment (HA1-211) was derived from HA-308. Each of the proteins was purified and used for immunizing mice and rabbits. The antibody produced was shown to bind to (i) the HA fusion proteins, (ii) detergent-treated viral HA, (iii) HA, on intact virions, and (iv) the HA on the surface of cells infected with influenza virus. This shows that the HA fusion proteins expressed in bacteria can elicit antibodies that recognize at least some determinants of the native viral HA, and probably could lead to development of an anti-influenza vaccine.     

In vitro antibody response to influenza virus. I. T cell dependence of secondary response to hemagglutinin.

A good secondary IgG response to the hemagglutinin (HA) of influenza virus has been obtained in vitro in Marbrook-type cultures of influenza-primed mouse spleen cell suspensions stimulated with inactivated influenza virus. Anti-HA antibody was quantitated by a solid phase radioimmunoassay (RIA) by using purified HA as substrate. The T dependence of this secondary response was shown by depletion of T cells and reconstitution with a source of primed or unprimed T cells. The help given by T cells primed to the homologous virus was many times greater than that given by unprimed T cells, although the latter was significant. The system described will allow investigation of the specificity requirements of helper T cells engaged in the anti-HA response.     

Antigenic properties of synthetic fragments of the heavy chain of influenza virus A hemagglutinin

The antigenic properties of the synthetic peptides corresponding to the regions 122-133, 136-147, 154-164 of the virus A/Aichi/2/68 hemagglutinin heavy chain have been studied. The 122-133 and 136-147 peptides comprise together almost whole antigenic determinant A, while the 154-164 peptide is a part of determinant B. Rabbits immunized by the peptides conjugated with carrier-protein BSA gave the high immune response to hapten-peptides. Each antiserum reacted only with homologous conjugate. All the antipeptide serums reacted with the virus A/Aichi/2/68 fixed on the base. Conjugate of the 136-147 peptide reacted with the rabbit antiserum against the virus A/Aichi/2/68 rendering the direct evidence to location of at least one hemagglutinin antigenic determinant in the region 136-147.     

Murine TH response to influenza virus: recognition of hemagglutinin, neuraminidase, matrix, and nucleoproteins

BALB/c mice were primed with type A influenza virus by footpad injection or by aerosol infection with PR8 [A/PR/8/34-(H1N1)]. Isolated T cells from draining lymph nodes were then tested for their proliferation in the presence of purified viral proteins hemagglutinin, neuraminidase, matrix, and nucleoprotein. Significant responses [( 3H]thymidine incorporation) were seen against each of the four proteins after either priming scheme. When helper T (TH) cell clones were isolated by hybridoma formation from two different strains of mice, responsiveness (interleukin 2 production) towards each protein was against apparent. Of 12 virus-specific T cell hybridomas isolated, four responded to matrix, three to nucleoprotein, one to neuraminidase, three to hemagglutinin, and one cell was of undefined specificity. Each hybridoma was also tested for recognition of the HK virus [A/Hong Kong/1/68-(H3N2)], which differs in subtype from the priming strain. All matrix-specific cells, two nucleoprotein-specific cells, and the cell of undefined specificity were cross-reactive with HK virus. H1-subtype specificity was seen for all hemagglutinin and neuraminidase-specific cells and one of the three nucleoprotein-specific cells. Because many virus-immune TH cells recognize antigenically variable determinants, a significant fraction of TH cell function may be lost after virus evolution. When selecting priming schemes for long-term immunization against influenza, the isolated enhancement of TH cells recognizing conserved determinants on matrix and nucleoprotein may therefore be considered.     

Antibody-forming cell response to virus challenge in mice immunized with DNA encoding the influenza virus hemagglutinin.

Immunization of mice with DNA encoding the influenza virus hemagglutinin (HA) affords complete protection against lethal influenza virus infection and the means to investigate the mechanisms of B-cell responsiveness to virus challenge. Using a single-cell enzyme-linked immunospot assay, we sought to determine the localization of HA-specific antibody-forming cells (AFCs) during the development of humoral immunity in mice given HA DNA vaccine by gene gun. At 33 days postvaccination, populations of AFCs were maintained in the spleen and bone marrow. In response to lethal challenge with influenza virus, the AFCs became localized at the site of antigenic challenge, i.e., within the draining lymph nodes of the lung compartment. Immunoglobulin G (IgG)- and IgA-producing AFCs were detected in lymph nodes of the upper and lower respiratory tracts, underscoring their importance in clearing virus from the lungs. Response to challenge required competent CD4+ T cells, without which no AFCs were generated, even those producing IgM. By contrast, in mice vaccinated with an HA-containing subunit vaccine, fewer AFCs were generated in response to challenge, and these animals were less capable of resisting infection. Our findings demonstrate the comparable localization of AFCs in response to challenge in mice vaccinated with either HA DNA or live virus. Moreover, the former strategy generates both IgG- and IgA-producing plasma cells.     

Cytotoxic T cell recognition of the influenza nucleoprotein and hemagglutinin expressed in transfected mouse L cells

L cells expressing either the A/NT/60/68 nucleoprotein or the A/PR/8/34 (H1) hemagglutinin by DNA mediated gene transfer were used to investigate recognition by influenza A specific cytotoxic T lymphocytes (CTL). A subpopulation of CTL that recognized the H1 hemagglutinin was detected in mice primed with either A/PR/8/34 (H1N1) or A/JAP/305/57 (H2N2) influenza viruses. However, neither CTL from mice primed with A/NT/60/68 (H3N2) nor the recombinant virus X31 (H3N2) showed any activity on L cells expressing H1. These results showed that the majority of fully crossreactive CTL do not recognize the hemagglutinin molecule. A comparison between nucleoprotein and hemagglutinin transfected L cells reveals the nucleoprotein as the major target for CTL that are crossreactive on the three pandemic strains of human influenza A virus.     

Immunogenicity of loop-structured short synthetic peptides mimicking the antigenic site A of influenza virus hemagglutinin

In order to assess the relevance of conformation for the antigenic site A of the hemagglutinin of influenza virus we synthesized two peptides, comprising two variant sequences of the central part of site A (amino acids 140 - 146 of subunit HA1) inserted into an artificial peptide skeleton, which imposes a loop-like structure on the respective sequence stretch. Assuming that the loop structure in the synthetic peptides would roughly approximate to the structure of the cognate protein sequence we tried to raise protein-reactive anti-peptide antibodies. The antibodies obtained indeed showed reactivity against influenza virus, although the discriminating specificity with regard to a mutation at position 144 was lost for virus binding in contrast to the highly specific peptide binding. Considering the failures in raising anti-hemagglutinin antibodies against the site A by immunization with short flexible peptide our results support the hypothesis that conformation makes a major contribution to the immunogenic and antigenic characteristics of site A in influenza hemagglutinin.     

Formation of mixed hemagglutinin trimers during double infection with influenza virus strains of the same subtype

Formation of hemagglutinin spikes in the course of the mixed infection of cell culture by two influenza virus strains belonging to the same antigenic subtype or to different subtypes was studied by means of immunoprecipitation of [14C]-labelled hemagglutinins from cell lysates. The immunoprecipitates were further analysed by polyacrylamide gel electrophoresis. Lysates of separately infected cells mixed before lysis were used as control samples. The analysis of immunoprecipitates revealed the formation of chimeric hemagglutinin spikes in the cells infected by the strains possessing hemagglutinins of the same subtype but not in the cells infected by the strains of different subtypes (H1 and H3). The results are discussed in connection with the homology of amino-acid sequences of influenza virus hemagglutinins.     

Binding kinetics of sulfatide with influenza A virus hemagglutinin

Association of a sulfated galactosyl ceramide, sulfatide, with the viral envelope glycoprotein hemagglutinin (HA) delivered to the cell surface is required for influenza A virus (IAV) replication through efficient translocation of the newly synthesized viral nucleoprotein from the nucleus to the cytoplasm. To determine whether the ectodomain of HA can bind to sulfatide, a secreted-type HA (sHA), in which the transmembrane region and cytoplasmic tail were deleted, was generated by using a baculovirus expression system. The receptor binding ability and antigenic structure of sHA were evaluated by a hemagglutination assay, solid-phase binding assay and hemagglutination inhibition assay. sHA showed subtype-specific antigenicity and binding ability to both sulfatide and gangliosides. Kinetics of sHA binding to sulfatide and GD1a was demonstrated by quartz crystal microbalance (QCM) analysis. QCM analysis showed that the sHA bound with the association rate constant (k _on) of 1.41?×?10⁴ M^?1 sec^?1, dissociation rate constant (k _off) of 2.03?×?10^?4 sec^?1 and K _d of 1.44?×?10^?8 M to sulfatide immobilized on a sensor chip. The k _off values of sHA were similar for sulfatide and GD1a, whereas the k _on value of sHA binding to sulfatide was 2.56-times lower than that of sHA binding to GD1a. The results indicate that sulfatide directly binds to the ectodomain of HA with high affinity.