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

Intermediate Levels of Pre-Existing Protective Antibody Allow Priming of Protective T Cell Immunity against Influenza

Overcoming interfering impacts of pre-existing immunity to generate universally protective influenza A virus (IAV)-specific T cell immunity through vaccination is a high priority. In this study, we passively transfer varied amounts of H1N1-IAV-specific immune serum before H1N1-IAV infection to determine how different levels of pre-existing Ab influence the generation and protective potential of heterosubtypic T cell responses in a murine model. Surprisingly, IAV nucleoprotein-specific CD4 and CD8 T cell responses are readily detected in infected recipients of IAV-specific immune serum regardless of the amount transferred. When compared with responses in control groups and recipients of low and intermediate levels of convalescent serum, nucleoprotein-specific T cell responses in recipients of high levels of IAV-specific serum, which prevent overt weight loss and reduce peak viral titers in the lungs, are, however, markedly reduced. Although detectable at priming, this response recalls poorly and is unable to mediate protection against a lethal heterotypic (H3N2) virus challenge at later memory time points. A similar failure to generate protective heterosubtypic T cell immunity during IAV priming is seen in offspring of IAV-primed mothers that naturally receive high titers of IAV-specific Ab through maternal transfer. Our findings support that priming of protective heterosubtypic T cell responses can occur in the presence of intermediate levels of pre-existing Ab. These results have high relevance to vaccine approaches aiming to incorporate and evaluate cellular and humoral immunity towards IAV and other viral pathogens against which T cells can protect against variants escaping Ab-mediated protection.

HLA-associated protection of lymphocytes during influenza virus infection

Background

Heterozygosity at HLA class I loci is generally considered beneficial for host defense. We report here an element of HLA class I homozygosity that may or may not help preserve its existence in populations but which could indicate a new avenue for antiviral research.

Methods

Lymphocytes from serologically HLA-homozygous or -heterozygous donors were examined for synthesis of influenza virus proteins and RNA after exposure to virus as peripheral blood mononuclear cells. The virus-exposed lymphocytes were also examined for internalization of the virus after exposure, and for susceptibility to virus-specific cytotoxic T lymphocytes in comparison with virus-exposed monocytes/macrophages and unseparated peripheral blood mononuclear cells. Results were compared using two-tailed Fisher’s exact test.

Results

Serologically-defined HLA-A2-homozygous lymphocytes, in contrast to heterozygous lymphocytes, did not synthesize detectable influenza virus RNA or protein after exposure to the virus. HLA-A2-homozygous lymphocytes, including both homozygous and heterozygous donors by genetic sequence subtyping, did internalize infectious virus but were not susceptible to lysis by autologous virus-specific cytotoxic T lymphocytes (“fratricide”). Similar intrinsic resistance to influenza virus infection was observed with HLA-A1- and HLA-A11-homozygous lymphocytes and with HLA-B-homozygous lymphocytes.

Conclusions

A significant proportion of individuals within a population that is characterized by common expression of HLA class I alleles may possess lymphocytes that are not susceptible to influenza virus infection and thus to mutual virus-specific lysis. Further study may identify new approaches to limit influenza virus infection.

Influenza Virus Infection of Human Lymphocytes Occurs in the Immune Cell Cluster of the Developing Antiviral Response

Monocytes-macrophages and lymphocytes are recruited to the respiratory tract in response to influenza virus challenge and are exposed to the virus during the establishment of immune defenses. The susceptibility of human lymphocytes to infection was assessed. The presence of monocytes-macrophages was required to attain infection of both resting and proliferating lymphocytes. Lymphocyte infection occurred in the context of immune cell clusters and was blocked by the addition of anti-intercellular adhesion molecule-1 (ICAM-1) antibody to prevent cell clustering. Both peripheral blood-derived and bronchoalveolar lymphocytes were susceptible to infection. Both CD4⁺ and CD8⁺ T lymphocytes were susceptible to influenza virus infection, and the infected CD4⁺ and CD8⁺ lymphocytes served as infectious foci for other nonpermissive or even virus-permissive cells. These data show that monocytes-macrophages and both CD4⁺ and CD8⁺ lymphocytes can become infected during the course of an immune response to influenza virus challenge. The described leukocyte interactions during infection may play an important role in the development of effective anti-influenza responses.

Differential requirements for endosomal reduction in the presentation of two H2-E(d)-restricted epitopes from influenza hemagglutinin

We examined the role of reduction in the presentation of two H2-E(d)-restricted epitopes (site 1 epitope (S1) and site 3 epitope (S3)) occupying distinct domains of the influenza hemagglutinin major subunit that contains four intrachain disulfide bonds and is connected to the virion by one interchain bond. S3 is situated within the stalk region that unfolds in response to mild acidification, and loads onto recycling H2-E(d) in the early endosome, while S1, located in the structurally constrained globular domain, loads onto nascent H2-E(d) in the late endosome. Predicting dependence upon reduction for either epitope seemed plausible but the results from several approaches were clear: presentation of S1 but not S3 is reduction dependent. Surprisingly, IFN-gamma-inducible lysosomal thiol reductase (GILT), the only reductase thus far known to be involved in MHC class II-restricted processing, is not necessary for the generation of S1. However, GILT is necessary for presentation of either epitope when the virus is pretreated with a reducible cross-linker. The results suggest that unfolding of the Ag, perhaps a prerequisite for proteolytic processing in many cases, proceeds either spontaneously in the early endosome or via reduction in a later endosome. They further imply mechanisms for GILT-independent reduction in the late endosome, with GILT perhaps being reserved for more intractable Ags.

Recent developments in avian influenza research: epidemiology and immunoprophylaxis

Influenza A viruses have been isolated from humans, from several other mammalian species and a wide variety of avian species, among which, wild aquatic birds represent the natural hosts of influenza viruses. The majority of the possible combinations of the 15 haemagglutinin (HA) and nine neuraminidase (NA) subtypes recognized have been identified in isolates from domestic and wild birds. Infection of birds can cause a wide range of clinical signs, which may vary according to the host, the virus strain, the host's immune status, the presence of any secondary exacerbating microorganisms and environmental factors. Most infections are inapparent, especially in waterfowl and other wild birds. In contrast, infections caused by viruses of H5 and H7 subtypes can be responsible for devastating epidemics in poultry. Despite the warnings to the poultry industry about these viruses, in 1997 an avian H5N1 influenza virus was directly transmitted from birds to humans in Hong Kong and resulted in 18 confirmed infections, thus strengthening the pandemic threat posed by avian influenza (AI). Indeed, reassortant viruses, harbouring a combination of avian and human viral genomes, have been responsible for major pandemics of human influenza. These considerations warrant the need to continue and broaden efforts in the surveillance of AI. Control programmes have varied from no intervention, as in the case of the occurrence of low pathogenic (LP) AI (LPAI) viruses, to extreme, expensive total quarantine-slaughter programmes carried out to eradicate highly pathogenic (HP) AI (HPAI) viruses. The adoption of a vaccination policy, targeted either to control or to prevent infection in poultry, is generally banned or discouraged. Nevertheless, the need to boost eradication efforts in order to limit further spread of infection and avoid heavy economic losses, and advances in modern vaccine technologies, have prompted a re-evaluation of the potential use of vaccination in poultry as an additional tool in comprehensive disease control strategies. This review presents a synthesis of the most recent research on AI that has contributed to a better understanding of the ecology of the virus and to the development of safe and efficacious vaccines for poultry.

Immunity to influenza A H9N2 viruses induced by infection and vaccination

Avian influenza A H9N2 viruses are widespread among domestic poultry and were recently isolated from humans with respiratory illness in China. Two antigenically and genetically distinct groups of H9N2 viruses (G1 and G9) are prevalent in China. To evaluate a strategy for vaccination, we compared G1 and G9 viruses for their relative immunogenicity and cross-protective efficacy. Infection of BALB/c mice with representative viruses of either group protected against subsequent challenge with the homologous or heterologous H9N2 virus in the absence of detectable cross-reactive serum hemagglutination inhibition antibody. Mice injected intramuscularly with inactivated G1 whole virus vaccine were completely protected from challenge with either H9N2 virus. In contrast, mice administered inactivated G9 vaccine were only partially protected against heterologous challenge with the G1 virus. These results have implications for the development of human vaccines against H9N2 viruses, a priority for pandemic preparedness.

Differences in the biological phenotype of low-yielding (L) and high-yielding (H) variants of swine influenza virus A/NJ/11/76 are associated with their different receptor-binding activity

Low- (L) and high-yielding (H) variants of A/sw/NJ/11/76 influenza virus were compared for their growth properties in embryonated chicken eggs and MDCK cells and for their binding affinity for the membrane fractions prepared from cells of the chicken embryo allantoic membrane. MDCK, and swine tracheal cells, as well as for soluble sialic acid containing macromolecules and monovalent sialosides. We have shown, that during infection in MDCK cells and in eggs, the progeny of the L variant remain predominantly cell associated, in contrast to those of H. As a result, accumulation of the L mutant in allantoic or culture fluid is significantly slowed in comparison with the H variant. Visualization of the infectious foci formed by the viruses in MDCK cell monolayers and on the allantoic membrane revealed that L spreads predominantly from cell to cell, while the spread of H involves release of the virus progeny into solution and its rapid distribution over the cell monolayer via convectional flow of the liquid. In the binding assays, L displayed significantly higher binding affinity than H for cellular membranes, gangliosides, and sialylglycoproteins, however, the affinity of the variants for the monovalent sialic acid compounds was comparable. Unlike H. L bound strongly to dextran sulfate. The data obtained suggest that all distinctions of the L and H biological phenotypes reported previously [Kilbourne, E.D., Taylor, A. H. Whitaker, C.W., Sahai, R., and Caton, A (1988) Hemagglutinin polymorphism as the basis for low-and high-yield phenotypes of swine influenza virus. Proc. Natl. Acad. Sci. USA 85, 7782-7785] could be rationally explained by a more avid binding of the L variant to the surface of target cells, and that this effect is mainly due to enhanced electrostatic interactions.

Role of chain pairing for the production of functional soluble IA major histocompatibility complex class II molecules

Structural studies of cellular receptor molecules involved in immune recognition require the production of large quantities of the extracellular domains of these glycoproteins. The murine major histocompatibility complex (MHC) class II-restricted response has been extensively studied by functional means, but the engineering and purification of the native, empty form of the most-studied murine MHC class II molecule, IA, has been difficult to achieve. IA molecules, which are the murine equivalent of human histocompatibility leukocyte antigen-DQ molecules, have a low efficiency of chain pairing, which results in poor transport to the cell surface and in the appearance of mixed isotype pairs. We have engineered soluble IA molecules whose pairing has been forced by the addition of leucine zipper peptide dimers at their COOH-terminus. The molecules are secreted "empty" into the extracellular medium and can be loaded with single peptide after purification. These IA molecules have been expressed in milligram quantity for crystallization as well as for activation of T cells and measurement of MHC class II-T cell receptor interactions.

Enhancement of antigen presentation of influenza virus hemagglutinin by the natural human anti-Gal antibody

Immunogenicity of inactivated virus or subviral vaccines may be enhanced by complexing with an IgG antibody. Such antibody would increase the uptake, processing and presentation of the vaccine's antigens by antigen presenting cells (APC), via the adhesion of the antibody-vaccine complex to Fc-receptors on macrophages and other APC. A natural antibody in humans, which may be generally exploited for this purpose, is the natural anti-Gal antibody. This antibody is ubiquitously produced as 1% of circulating IgG in humans and Old World primates, and it interacts specifically with the carbohydrate epitope Gal alpha 1-3 Gal beta 1-4 GlcNAc-R (termed the alpha-galactosyl epitope). This epitope is synthesized in large amounts in cells of nonprimate mammals and New World monkeys by the glycosylation enzyme alpha 1,3 galactosyltransferase. Here we describe in vitro studies on the ability of anti-Gal to bind to alpha-galactosyl epitopes on influenza virus propagated in mammalian cells, and to enhance presentation by APC of viral hemagglutinin antigenic determinants to specific helper T cell clones. The various approaches for achieving alpha-galactosyl epitope expression on virion and subviral vaccines are discussed.

Melanoma-specific CD4+ T lymphocytes recognize human melanoma antigens processed and presented by Epstein-Barr virus-transformed B cells

While much emphasis has been placed on the role of MHC class I-restricted CD8+ T cells in the recognition of tumor-specific antigens (Ag), evidence has accumulated that CD4+ T cells also play a critical role in the anti-tumor immune response. However, little information exists on the nature of MHC class II-restricted human tumor Ag. In an attempt to develop in vitro systems to characterize such Ag, we examined the ability of Epstein-Barr virus (EBV)-transformed B cells to present melanoma-associated Ag to melanoma-specific CD4+ cells. CD4+ T cells cultured from lymphocytes infiltrating a s.c. melanoma metastasis secreted TNF-alpha and GM-CSF specifically in response to autologous cultured melanoma cells expressing MHC class II molecules. These CD4+ cells also recognized MHC class II-compatible EBV-B cells pulsed with extracts of autologous melanoma cells, but failed to recognize EBV-B cells pulsed with autologous non-transformed cells or a variety of allogeneic tumors or normal cells. B cells pre-fixed with paraformaldehyde were incapable of Ag presentation, suggesting that intracellular processing events were occurring. Antibody-blocking studies defined HLA-DR as the dominant if not exclusive restriction locus in this T-B interaction, and HLA-DR genotyping revealed DRBI*0404 to be the probable restriction element. In a second patient, a CD4+ T-cell clone cultured from a melanoma lesion recognized autologous tumor Ag presented by autologous EBV-B; no corss-reactivity was observed with the other tumor system investigated, nor with autologous CD4+ T cells specific for tetanus toxoid. These findings demonstrate that tumor Ag can be processed and presented by EBV-transformed B cells to MHC class II-restricted tumor-specific CD4+ T cells. They also provide a model system for direct identification of these tumor-derived antigens.

Sequence features that correlate with MHC restriction

Identification of common sequence motifs in antigenic peptides restricted to a specific class II molecule has not been easy due to the large variation in length and sequence that is observed in these peptides. The goal of this study is to develop an automated computerized method for the identification of sequence features and structural determinants that play a role in the MHC restriction of helper T-cell antigenic peptides. For this, we compiled an extended database of helper T-cell sites, including the information on MHC restriction, when available. Two groups of peptides are assigned to each MHC type: (1) peptides that bind to that MHC molecule to elicit a T-cell response, and (2) peptides that were shown experimentally either not to bind to or not to elicit a T-cell proliferative response in association with that MHC molecule. We search for common motifs in the group of binding peptides, and identify significant motifs that are frequent among these peptides but almost absent in the group of non-binding peptides. A motif consists of physical-chemical and structural properties that may be responsible for binding specificity and can be extracted from sequence data, such as, hydrophobicity, charge, hydrogen bonding capability, etc. The first search is performed on the non-aligned binding peptides. Next, the sequences are aligned according to an identified motif and a search for additional, conserved, properties is performed. The statistical significance of the motifs is evaluated as well as their compatibility with published experimental results on substitution effects. Here we demonstrate the general scheme of the analysis and results for I-Ek and I-Ak associated peptides.

Use of FITC-labeled influenza virus and flow cytometry to assess binding and internalization of virus by monocytes-macrophages and lymphocytes

The binding of influenza virus to the surface of cells and the internalization of virus particles by all or a subset of cells are key points in the pathogenesis of viral infection. The current studies established a method for discrimination of surface-bound from internalized influenza virus. Fluorescein isothiocyanate (FITC) was attached to the viral hemagglutinin and neuroaminidase proteins; the fluorescent virus retained infectivity. A flow cytometric technique was then adapted for study of virus-cell interactions, with addition of ethidium bromide to quench green fluorescence associated with FITC-labeled virus that was cell-bound but remained external. Ethidium bromide was excluded by intact cell membranes, and internalized virions retained green fluorescence. Cells could be examined by fluorescence microscopy or flow cytometry, with flow cytometry allowing rapid, kinetic assessment of large numbers of cells and subsets of virus-exposed cells. The data showed that, whereas a majority of both monocytes-macrophages and lymphocytes bound influenza virus, a large percentage of monocytes-macrophages but only a very small percentage of lymphocytes internalized the virus. This procedure provides a simple and effective method to distinguish surface-bound from internalized influenza virus, and allows precise kinetic analyses on large numbers of cells.

Peripheral tolerance to an islet cell-specific hemagglutinin transgene affects both CD4+ and CD8+ T cells

To study the basis for immunological tolerance of peripheral tissue-specific antigens, a transgenic mouse line was established that expresses the influenza hemagglutinin (HA) on pancreatic islet beta cells (Ins-HA transgenic mice). When followed up to 14 months of age, Ins-HA transgenic mice did not develop spontaneous autoimmune disease. Upon immunization with HA-expressing viruses, high titers of HA-specific circulating antibody were detected; however, T cell responses by both the T helper and T cytolytic compartment were markedly reduced as compared with transgene-negative littermates, and no evidence could be found for islet infiltrates. Adoptive transfer of histocompatible lymphocytes from transgene-negative mice plus virus into irradiated Ins-HA hosts resulted in islet inflammation dominated by CD4+ T cells, indicating that the HA antigen was accessible to activated T cells. These results suggest that T cells can be rendered tolerant of antigens expressed outside the thymus.

Immunogenicity of free synthetic peptides corresponding to T helper epitopes of the influenza HA 1 subunit. Induction of virus cross reacting CD4+ T lymphocytes in mice

Four linear synthetic peptides corresponding to residues 12-29, 50-67, 121-138 and 131-147 of the HA 1 subunit of H3 subtype influenza virus (NT/60/68) were tested for their capacity to elicit in vivo peptide-specific CD4+ T cells cross reacting with whole virus. By studying the in vitro peptide proliferative response of lymph node cells from mice sensitized in vivo with free peptides emulsified in complete or incomplete Freund adjuvant, it was found that region 12-29 could be recognized by CD4+ T lymphocytes in the context of H-2k and H-2b, region 50-67 in association with H-2b and region 121-138 in the context of H-2d MHC molecules. Outbred OF 1 mice could recognize regions 50-67 and 121-138. Peptides 50-67 and 121-138 are of potential interest for synthetic vaccine design since they induced in BALB/c (peptide 121-138) and OF 1 (both peptides) mice a CD4+ T cell population that cross reacted with whole virus. The region 50-67 is of particular interest since only few substitutions have been found in this area in natural variants of the H3 virus subtype.

Invariant chain targets HLA class II molecules to acidic endosomes containing internalized influenza virus

The role of the HLA class II-associated invariant chain in the intracellular trafficking of HLA-DR molecules was examined in a transient expression system using HeLa cells. In the absence of alpha and beta polypeptides, invariant chain was retained in the endoplasmic reticulum (ER). In the absence of invariant chain, intracellular alpha beta heterodimers could be detected only in the ER and the Golgi apparatus. However, when alpha and beta subunits were coexpressed with invariant chain, HLA-DR molecules were detectable in peripheral cytoplasmic vesicles, which also contained invariant chain. In addition, an antibody directed to an acid-induced conformational determinant on the influenza hemagglutinin molecule detected internalized influenza virus in the HLA-DR-containing vesicles. These findings provide direct evidence that the invariant chain targets class II molecules to an acidic endosomal compartment and that this compartment, long suspected to be the site of antigen processing, is the site where class II molecules interact with natural antigen.

Single amino acid substitutions in the hemagglutinin can alter the host range and receptor binding properties of H1 strains of influenza A virus

We have previously characterized an influenza A (H1N1) virus which has host-dependent growth and receptor binding properties and have shown that a mutation which removes an oligosaccharide from the tip of the hemagglutinin (HA) by changing Asn-129 to Asp permits this virus to grow to high titer in MDBK cells, (C. M. Deom, A. J. Caton, and I. T. Schulze, Proc. Natl. Acad. Sci. USA 83:3771-3775, 1986). We have now isolated monoclonal antibodies specific for the mutant HA and have used escape mutants to identify alterations in HA sequence which reduce virus yields from MDBK cells without reducing those from chicken embryo fibroblasts. Two types of escape mutants which grow equally well in chicken embryo fibroblasts were obtained. Those with the parent phenotype contain Asn at residue 129 and are glycosylated at that site. Those with the mutant phenotype are unchanged at residue 129 but have a Gly to Glu substitution at residue 158, which is close to residue 129 on the HA1 subunit. Binding assays with neoglycoproteins containing N-acetylneuraminic acid in either alpha 2,3 or alpha 2,6 linkage to galactose showed that the MDBK-synthesized oligosaccharides at Asn-129 reduce binding to both of these receptors, leaving the HA's preference for alpha 2,6 linkages unchanged. Glu at residue 158 greatly reduces binding to both receptors without reducing virus yields from MDBK cells. We conclude that changes in the receptor binding properties of the HA can result either from direct alteration of the HA protein by host cell glycosylation or from mutations in the HA gene and that these changes generate heterogeneity that can contribute to the survival of influenza A virus populations in nature.

Insights into neutralization of animal viruses gained from study of influenza virus

It has long been known that the binding of antibodies to viruses can result in a loss of infectivity, or neutralization, but little is understood of the mechanism or mechanisms of this process. This is probably because neutralization is a multifactorial phenomenon depending upon the nature of the virus itself, the particular antigenic site involved, the isotype of immunoglobulin and the ratio of virus to immunoglobulin (see below). Thus not only is it likely that neutralization of one virus will differ from another but that changing the circumstances of neutralization can change the mechanism itself. To give coherence to the topic we are concentrating this review on one virus, influenza type A which is itself well studied and reasonably well understood [1–3]. Reviews of the older literature can be found in references 4 to 7.

Immunogenic peptides of influenza virus subtype N1 neuraminidase identify a T-cell determinant used in class II major histocompatibility complex-restricted responses to infectious virus

Six nonoverlapping peptides of the neuraminidase (NA) glycoprotein of influenza virus A/Puerto Rico/8/34 (H1N1) (PR8 virus) were found to be immunogenic for proliferating T cells when injected into BALB/c mice in Freund adjuvant. T cells elicited by peptide immunization could recognize PR8 virus in vitro. However, only one of these peptides, corresponding to residues 79 to 93 of NA (NA 79-93), was able to restimulate T cells of mice immunized with infectious virus. T cells that recognized this peptide were uniformly I-Ed restricted, yet infectious influenza virus was required for responses. NA 79-93-specific T-hybridoma clones raised by immunization either with whole virus or with the synthetic peptide alone each responded to replicative virus and not to UV-inactivated virions. These data suggest that the NA 79-93 T-cell determinant which is commonly presented during an encounter with influenza virus in vivo is processed preferentially from NA synthesized within antigen-presenting cells.

Identification of eight determinants in the hemagglutinin molecule of influenza virus A/PR/8/34 (H1N1) which are recognized by class II-restricted T cells from BALB/c mice

Eight nonoverlapping regions of the hemagglutinin (HA) molecule of influenza virus A/PR/8/34 (PR8), which serve as recognition sites for class II-restricted T cells (TH) from BALB/c mice, have been identified in the form of 10- to 15-amino-acid-long synthetic peptides. These TH determinants are located between residues 110 to 313 of the HA1 polypeptide. From a total of 36 HA-specific TH clones and limiting-dilution cultures of independent clonal origins, 33 (90%) responded to stimulation with one of these peptides. The residual three TH clones appeared to recognize a single additional determinant on the HA1 polypeptide which could not be isolated, however, in the form of a stimulatory peptide. None of the motifs that have been proposed to typify TH determinants were displayed by more than half of these recognition sites. Most unexpected was the finding that none of the TH determinants was located in the ectodomain of the HA2 polypeptide that makes up roughly one-third of the HA molecule. Possible reasons for the preferential recognition of HA1 as opposed to HA2 by TH are discussed.

Mechanisms of neutralization of influenza virus in tracheal epithelial and BHK cells vary according to IgG concentration

The interaction of IgG-neutralized type A influenza virus with differentiated epithelial cells of mouse trachea, BHK cells, and chicken erythrocytes was studied using three mouse monoclonal antibodies (IgG2a) each directed against a different antigenic site on the hemagglutinin. At high HIU:HAU ratios virus was neutralized greater than 99%, monodisperse, and attached to tracheal epithelial and BHK cells in normal amounts. The majority (70-80%) of neutralized virus failed to attach to erythrocytes. At low HIU:HAU ratios the virus was aggregated by each of the antibodies, and attachment to tracheal epithelial and BHK cells was inhibited by up to 75%. Combined aggregation and inhibition of attachment could theoretically account for up to 96% loss of infectivity but this corresponded with the observed degree of neutralization with only one of the antibodies. With increasing antibody:virus ratios, aggregation and inhibition of attachment contributed ever diminishingly to the observed neutralization and eventually not at all. Both neutralized and infectious virus attached to neuraminidase-sensitive receptors. After attachment neutralized virus became increasingly resistant to removal by neuraminidase suggesting that it had been internalized by the cell.

Age-related decline in interleukin 2 production in response to influenza vaccine

Articles in the recent literature document an abnormal antibody response in elderly persons to influenza vaccination. Several studies have presented evidence to show that immune dysfunction in aged mice and humans may be due to a defect in the production of interleukin 2 (IL2) by helper T cells (TH). Cultures of peripheral blood mononuclear cells (PBMC) were prepared from blood samples taken at eight weeks after vaccination (0.5 mL of Armand-Frappier, 15 micrograms/0.5 mL each of A/Taiwan/1/86, A/Leningrad/360/86, and B/Ann Arbor/1/86 administered in the fall of 1987) from a group of elderly men and a young control group. Peripheral blood mononuclear cells were frozen in 10% dimethyl sulfoxide (DMSO) until all the cells were cultured. After stimulation with a 1/320 dilution of the same influenza vaccine, cultures of PBMC from young controls showed a significantly greater increase in IL2 production than the cultures of PBMC from the elderly group of patients. This was statistically significant at both day 3 (P less than .01) and day 5 (P less than .05) of culture using the Mann-Whitney U test. Previous experiments that have shown defective IL2 production related to aging have used potent mitogens such as concanavalin A and phytohemagglutinin to stimulate TH. This study provides evidence that defective IL2 production may also occur in response to physiologic antigenic stimulation and may be one explanation for the reduced efficacy of influenza vaccination in elderly persons.

Virus entry and antigen biosynthesis in the processing and presentation of class-II MHC-restricted T-cell determinants of influenza virus

Receptor-mediated uptake of influenza virus is responsible for efficient introduction of virus particles to APC. This leads to the effective presentation to T-cells of very small concentrations of proteins entering on the intact virus. Endocytosed virus transits rapidly to the endosome compartment. Entry into this environment appears to greatly affect the fate of T-cell determinants. While promoting the presentation of determinants which require extensive antigen processing, the intracellular environment appears also to lead to destruction of labile determinants, such as those of NA. The same NA determinants are efficiently presented by actively infected cells, indicating that newly biosynthesized viral proteins need not be subjected to the same handling as internalized viral particles. In a similar way, site 3 of HA, which, in a single pulse of noninfectious virus or isolated HA protein is expressed with a relatively short half-life, has greatly improved levels of duration and expression on actively infected APC. Since certain T(H) determinants are unavailable or poorly expressed when introduced on nonreplicative influenza virus, vaccination with inactivated virus might have limitations in stimulating T(H) as well as class-I responses. Finally, individual T-cell determinants of the same protein can exhibit distinct patterns of expression and persistence on APC surfaces. These different half-lives of T(H) determinants may be influential in determining immuno-dominance of T-cell sites. Determinants that are longer-lived on APC may have a greater probability of interacting with appropriate T(H) precursors, which could lead to an enhanced T-cell response to that region of the viral protein.

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.

Brefeldin A specifically inhibits presentation of protein antigens to cytotoxic T lymphocytes

Cytotoxic T lymphocytes (CTLs) recognize foreign antigens, including viral proteins, in association with major histocompatibility complex (MHC) class I molecules. Brefeldin A, a specific inhibitor of exocytosis, completely and reversibly inhibited the presentation of viral proteins, but not exogenous peptides, to MHC class I-restricted CTLs directed against influenza virus antigens. The effect of brefeldin A on antigen presentation correlated with its inhibition of intracellular transport of newly synthesized class I molecules. Brefeldin A is thus a specific inhibitor of antigen processing for class I-restricted T cell recognition. Its effect on antigen presentation supports the idea that exogenous peptide antigens associate with cell surface class I molecules, whereas protein antigens processed via the cytosolic route associate with nascent class I molecules before they leave the trans-Golgi complex.

Rabies virus-specific T cell hybridomas: identification of class II MHC-restricted T-cell epitopes using synthetic peptides

Rabies virus-specific T-cell hybridomas were produced from immune mice by somatic cell fusion. Cloned T-cell hybridomas were studied for antigen specificity using purified virus, a recombinant vaccinia virus expressing rabies glycoprotein and synthetic peptides containing amino acid sequences of rabies viral antigens. Two closely situated T-cell epitopes of rabies glycoprotein, and one of rabies nucleoprotein were identified using synthetic peptides corresponding to amino acid sequences of these proteins. The major histocompatibility gene complex elements that determine the recognition of antigen by these T-cell hybrids were determined using mouse fibroblasts (L cells) transfected with and expressing the I-Ad and I-Ed genes. Some of the T cell hybridomas exhibited significant cytotoxic activity against target cells expressing surface rabies antigens. This T cell mediated cytotoxicity requires cell-to-cell contact between target and effector cells since no by-stander cytotoxicity was observed. The results are discussed in the context of their significance for the design of newer subunit vaccines to prevent rabies infection.

Class II major histocompatibility complex-restricted T cells specific for a virion structural protein that do not recognize exogenous influenza virus. Evidence that presentation of labile T cell determinants is favored by endogenous antigen synthesis

The contribution of viral infectivity to the expression of MHC class II-restricted T cell determinants was studied. A murine I-Ed-restricted T cell hybridoma recognizing the neuraminidase (NA) glycoprotein of influenza PR8 virus was stimulated strongly by infectious virus but failed to recognize antigen introduced on noninfectious virions. Recognition correlated with the de novo synthesis of viral NA within infected APC. The effectiveness of infectious virus did not depend strictly upon the amount of NA present in cultures, since high NA concentrations could be achieved by addition of nonreplicative virus without being stimulatory for NA-specific T cells. Recognition of a determinant generated only when synthesized in murine host cells was ruled out, since, in high concentration, NA isolated from purified egg-grown virions, even if reduced and alkylated, was recognized by the T hybridoma clone. Isolated NA was recognized when added to pre-fixed APC, suggesting that this form of antigen was able to bypass the usual processing pathway of exogenous proteins. Data suggest that endogenously synthesized antigen may contribute most significantly to presentation of labile T cell determinants. In addition to NA, recognition of an I-Ed-restricted determinant of the influenza hemagglutinin (HA) molecule, shown previously to have a relatively short half-life on APC surfaces, was enhanced greatly by infectious virus. In contrast, T cell recognition of a more stably expressed I-Ed-restricted site of the same HA polypeptide was only marginally improved on infected APC.

Inhibitory effects of monoclonal antibodies to a synthetic peptide of influenza haemagglutinin on the processing and presentation of viral antigens to class II-restricted T-cell clones

Monoclonal antibodies (mAb) prepared against a synthetic peptide of influenza virus haemagglutinin (HA), containing a known T-cell determinant, were used to examine the mechanism of antigen-induced activation of HA-specific class II-restricted T-cell clones. Previous studies had shown that T-cell clones, established from mice primed by infection with influenza virus, recognize variable antibody binding region of HA, including a determinant formed from residues within the sequence HA1 48-68. MAb to the synthetic peptide, p48-68, recognized purified HA and whole virus in an ELISA, and their specificity pattern for natural variant viruses was similar to that described for the T-cell clones specific for the same peptide. The anti-peptide mAb inhibited peptide or virus-induced proliferation of the peptide specific T-cell clones (but has no effect on a unrelated HA-specific clone), whereas mAb to the native HA molecule inhibited virus but not peptide-induced T-cell activation. In addition, the anti-peptide mAb showed significant inhibition of T-cell proliferation to peptide or virus pulsed antigen-presenting cell (APC). The results suggest that the anti-HA mAb affect antigen induced T-cell activation simply through blocking virus uptake by the APC, whereas the anti-peptide antibodies, which appear to recognize the same determinant on the peptide and the processed antigen, mediate their effect at the level of antigen presentation.

Differential ability of B cells specific for external vs. internal influenza virus proteins to respond to help from influenza virus-specific T-cell clones in vivo

When a helper T-cell (TH) clone specific for the hemagglutinin, neuraminidase, matrix protein, or nucleoprotein of influenza strain A/PR/8/34 is adoptively transferred to athymic mice 1 day after virus infection the anti-viral antibody response of the mouse is enhanced. This response is directed predominantly to the hemagglutinin and requires associative T-cell-B-cell interactions. Delaying transfer of the TH clone has three consequences: (i) the onset of the anti-hemagglutinin antibody response is delayed; (ii) the titer of the anti-hemagglutinin response is reduced; and (iii) the titer of the antibody in the response against the internal proteins, matrix protein and nucleoprotein, is enhanced upon transfer of matrix protein- or nucleoprotein-specific, but not hemagglutinin- or neuraminidase-specific, TH clones. Thus, there is a hierarchy of help: B cells recognizing viral surface components, hemagglutinin or neuraminidase, can receive help from TH clones specific for any of the major structural viral proteins. In contrast, B cells responding to internal viral components, matrix protein or nucleoprotein, are restricted to receiving help almost exclusively from TH clones with the same protein specificity. These observations suggest that, upon B-cell surface immunoglobulin-antigen interaction and uptake of intact virus, B cells specific for viral surface proteins process and present all major structural viral antigens, enabling the B cells to interact with TH clones specific for any virion protein. B cells recognizing internal viral components, which may be accessible to interaction with B-cell immunoglobulin receptors mainly as free proteins, would present only the protein for which they are specific and, thereby, receive help only from the TH clones of the same protein specificity.