Antigen-specific human T lymphocyte clones: viral antigen specificity of influenza virus-immune clones

Human T lymphocyte clones (TLC) specific for type A (A/Texas/1/77) influenza virus and maintained in continuous culture with T cell growth factor, were analyzed to define the cellular specificity pattern of virus recognition. A panel of TLC were stimulated with strains of serologically characterized type A influenza subtypes. Five TLC recognized all the viral subtypes; the remaining clones recognized only subtypes that shared serologically defined determinants with the immunizing subtype. In addition, the 11 TLC were analyzed for their fine antigenic specificity by using the purified viral components hemagglutinin (HA), neuraminidase (NA), matrix protein (MP), and nucleoprotein (NP). Five TLC proliferated in response to NA, four to MP, one to HA, and one to NP. None of the clones responded to the unrelated B strain influenza virus, B/Singapore. Furthermore, the fine specificity of an MP-reactive TLC was confirmed by subcloning.     

Cloned lines of human cytotoxic T lymphocytes with specificity for influenza virus

The generation of human cytotoxic T cell clones with specificity for influenza virus and some of their characteristics are described. The clones were generated by limiting dilution of peripheral blood lymphocytes after two in vitro stimulations with autologous influenza A/USSR virus-infected cells and were grown in T cell growth factor. The majority of the virus-specific clones showed cross-reactivity for different influenza A virus subtypes but did not recognize influenza B virus-infected cells. The HLA specificity of two clones was further analyzed. One clone, LL33, was specific for HLA-Bw60, the other, clone WH5, for HLA-A1. Clone WH5 also seemed to recognize the serologically related HLA-A26 as restriction element for the recognition of the viral antigen. Whereas the virus-specific CTL clones had the OKT3+,4-,8+ phenotype, another clone, WH 49, exhibiting natural killer-like activity, was found to have the OKT3+,4+,8- phenotype.     

Human helper T-cell clones that recognize different influenza hemagglutinin determinants are restricted by different HLA-D region epitopes

Human T-lymphocyte clones (TLCs) were generated against the hemagglutinin (HA) of A/Texas/1/77 influenza virus by limiting dilution. TLCs were then screened for antigen specificity on chemically synthesized peptides representing the HA1 molecule. It has been hypothesized that different T cells that recognize the identical antigenic determinant are controlled by (restricted by) the same class II epitope. Two TLCs, HA1.4 and HA1.7, both recognized the same HA peptide and in proliferation studies exhibited identical restriction patterns. Two other clones, HA 1.9 and HA 2.43, recognized different HA determinants and also had distinct restriction patterns. Proliferation inhibition studies with monoclonal antibodies against human class II molecules demonstrated three unique patterns of blocking with the clones, suggesting that clones may be restricted to a unique class II epitope depending on the HA determinant recognized. These data can be interpreted as supporting the argument that human immune responses to influenza hemagglutinin are under Ir gene control exerted at the level of the viral antigenic determinant recognized in association with particular D-region restricting elements. The determinant selection and clonal deletion theories are compared for their capacity to best explain these findings.Abbreviations used in this paper ³HTdR tritiated methyl thymidine - MHC major histocompatibility complex - HLA human MHC - PBLs peripheral blood lymphocytes - APCs antigen-presenting cells - TLCs T-lymphocyte clones - TCGF T-cell growth factor - MoAbs monoclonal antibodies     

Characterization of subtype-specific and cross-reactive helper-T-cell clones recognizing influenza virus hemagglutinin

The specificity and function of two T-cell clones derived from A/Memphis/1/71 (H3) influenza virus (Mem 71)-immune BALB/c spleen cells have been compared. One clone, X-31 clone 1, was subtype specific, proliferating in response to influenza strains of the H3 subtype only. The other, Jap clone 3, cross-reacted in proliferation assays with heterologous subtypes of influenza A, but not type B. Both clones recognized the HA1 chain of the hemagglutinin (HA) molecule and their proliferation in response to detergent-disrupted virus could be specifically inhibited by monoclonal antibodies to the HA. The T-cell clones were of the L3T4+ phenotype. Both recognized antigen in association with I-Ed, as indicated by studies with H-2 recombinant strains of mice and by blocking with monoclonal anti-I-E antibody. In vivo, both clones elicited a delayed-type hypersensitivity (DTH) reaction when inoculated into mouse footpads together with virus, X-31 clone 1 again displaying subtype specificity and Jap clone 3 being cross-reactive. The clones were also able to provide factor-mediated help in vitro to virus-primed B cells in an anti-HA antibody response. The cross-reactive T-cell clone provided help not only for B cells primed with influenza A subtype H3 and responding to H3 virus in culture, but also for H2 virus-primed B cells making anti-H2 antibody.     

Expression of an antigen specific for trunk lateral cells in quarter embryos of the ascidian, Halocynthia roretzi

Cell-lineage analysis has demonstrated that a pair of the right and left A7.6 cells of a 64-cell embryo of the ascidian Halocynthia roretzi, descendants of A4.1 cells of an 8-cell embryo, give rise to trunk lateral cells (TLCs). In this study, in order to investigate cellular mechanisms involved in the specification of TLCs, we have examined the expression of a TLC-specific antigen in cleavage-arrested embryos and in quarter partial embryos. Although cleavage arrest of embryos by treatment with cytochalasin B at early stages, prior to and including the 16-cell stage, inhibited expression of the TLC-specific antigen, embryos arrested at the 32-cell stage and at later stages developed the antigen. The only blastomeres exhibiting expression of the antigen were the presumptive TLCs, as predicted by cell-lineage assignments. When the developmental potential of quarter embryos that originated from four isolated blastomere-pairs (a4.2, b4.2, A4.1, and B4.1 pairs) of an 8-cell embryo was examined, the A4.1 quarter embryos, which are developmentally fated to give rise to TLCs, rarely showed evidence of expression of the antigen. Expression of the antigen was not observed in a4.2 and b4.2 quarter embryos, which are not associated with the TLC fate. By contrast, expression of the antigen was detected in about a half of the B4.1 quarter embryos which are also not associated with the TLC fate. These results are discussed with reference to the relationship between TLCs and mesenchyme cells.     

Vaccinia virus-specific human CD4+ cytotoxic T-lymphocyte clones.

Vaccinia virus-specific cytotoxic T-lymphocyte (CTL) clones were established from a healthy donor, who had been immunized with vaccinia virus vaccine, by stimulation of peripheral blood lymphocytes with UV-inactivated vaccinia virus antigen. The phenotype of all of the clones established was CD3+ CD4+ CD8- Leu11-. We used a panel of allogenic vaccinia virus-infected B-lymphoblastoid cell lines and demonstrated that some of the clones recognized vaccinia virus epitopes presented by human leukocyte antigen (HLA) class II molecules. Monoclonal antibodies specific for either HLA-DP or HLA-DR determinant reduced the cytotoxicity of specific clones. The HLA-restricted cytotoxicity of the clones is vaccinia virus specific, because vaccinia virus-infected but not influenza virus-infected autologous target cells were lysed. Using vaccinia virus deletion mutants, we found that some of the CTL clones recognize an epitope(s) that lies within the HindIII KF regions of the vaccinia virus genome. These results indicate that heterogeneous CD4+ CTL clones specific for vaccinia virus are induced in response to infection and may be important in recovery from and protection against poxvirus infections.     

Induction and activity of class II-restricted, Lyt-2+ cytolytic T lymphocytes specific for the influenza H5 hemagglutinin

In influenza A virus infections, CTL are a significant component of the host immune response which limits viral replication and promotes recovery. To examine the CTL response to the influenza virus A/Ty/Ont/7732/66[H5N9], particularly the H5 hemagglutinin, a long term CTL line was generated from spleen cells of A/Ty/Ont-immune Balb/c [H-2d] mice secondarily stimulated in vitro with A/Ty/Cal/Hurst-2/71[H5N2]. This CTL line was highly specific for influenza viruses of the H5 subtype. From this line, clones were isolated by limiting dilution and shown to be H5 hemagglutinin-specific based on recognition of an H5 vaccinia virus recombinant (H5 Vac). The clones exhibited the classical CTL surface phenotype Lyt-1-2+L3T4-; however, unlike the typically class I-restricted Lyt-2+ CTL, they were restricted in antigen recognition by class II (I-E) MHC molecules based on target cell recognition and antibody blocking of cytotoxicity. The clones recognized both infectious and non-infectious A/Ty/Ont presented by class II+ target cells. In adoptive transfer studies to assess the biologic role of the clones in vivo, these class II-restricted clones did not appear to alter mortality. However, these cells significantly reduced both morbidity and virus titers in the lungs of infected animals at 5 days post-infection. Thus, in the immune response to this virus, class II-restricted Lyt-2+ CTL specific for the H5 hemagglutinin were readily generated and their biologic role in vivo involved viral clearance.     

Characterization of human T-lymphocyte clones (TLCs) specific for HLA-region gene products

Clones of lymphocytes, primed in vitro to HLA-DR1; Dw1, were tested for allospecific proliferation on a panel of thirty-one HLA-phenotyped stimulating cells. No clone was restimulated exclusively by cells sharing the DR1; Dw1 priming antigens and most clones were restimulated by subsets of cells bearing DR1; Dw1. Generally, positive responses were at least 20-fold higher than autologous negative controls. Peak proliferative responses occurred around 72 h and varied, depending on the stimulating cell as well as the responding clone. Selected clones were induced to proliferate only by cells incapable of forming rosettes with sheep erythrocytes. Specific proliferation by TLCs was blocked by monoclonal DR-specific antibodies, but not by monoclonal anti-Thy 1.2. Genetic studies demonstrated that TLCs detected some cell-surface determinants that are encoded by genes in linkage disequilibrium with HLA and others that may not be linked to the human major histocompatibility complex.Abbreviations used in this paper ³HTdR tritiated methylthymidine - HTC homozygous typing cell - MHC major histocompatibility complex - HLA human MHC - MLC mixed leukocyte culture - PBL peripheral blood lymphocytes - PLT primed lymphocyte typing - TCGF T-cell growth factor - IL-2 interleukin 2 - TLC T-lymphocyte close     

Antigen-specific human T lymphocyte clones: mechanisms of inhibition of proliferative responses by xenoantiserum to human nonpolymorphic HLA-DR antigens

We studied the effects of xenoantiserum to human nonpolymorphic Ia-like antigens upon in vitro antigen-specific T cell proliferative responses in unfractionated PBL populations and at the monoclonal level. Our findings suggest that the xenoantiserum, although it inhibits the antigen-specific response of unfractionated PBL and allospecific T cell clones, does not inhibit the proliferative response to cloned influenza virus immune human T lymphocytes, and therefore may be mediating inhibition by dual mechanisms: direct inhibition of alloantigen recognition and induction of nonspecific suppression. Kinetic differences may explain these phenomena. In cocultivation experiments with a virus-specific clone, the RaIa antiserum appears to induce an OKT3+,8+,4-, radiosensitive regulatory subset of lymphocytes. When adoptively transferred, these induced cells inhibit the TLC response in an antigen-nonspecific and genetically nonrestricted manner. We discuss the various modes and levels of inhibition of antigen-specific proliferation by anti-Ia antisera and their multiple activities.     

Phenotypic heterogeneity of Gross virus-induced thymic lymphomas in the rat: cellular origins and migratory properties

Neoplastic thymocytes from rat thymic lymphoma-leukemias induced by the rat-adapted Gross leukemia virus (RAGV) were analyzed for a variety of differentiation markers. The neoplasms from individual rats all expressed the antigenic phenotype MP+, W3/13+, Thy-1+, RT-1+, RT-7+, W3/25-. However, approximately two-thirds of the neoplasms were positive for the OX 8 antigen, and one-third were negative. The OX 8- neoplasms only involved the thymus, whereas approximately 40% of the OX 8+ neoplasms involved the spleen as well as the thymus. Virtually all OX 8+ and OX 8- neoplastic cells contained terminal deoxynucleotidyl transferase (TdT), and both OX 8+ and OX 8- lymphomas expressed the lactate dehydrogenase (LDH)-5' isozyme and the primary, but not the secondary, ADA isozyme. This enzymatic phenotype is characteristic of thymocyte precursors, but not thymocytes. Our results therefore indicate that RAGV-induced lymphomas arise from transformed prethymic TdT+ cells which contain the LDH-5' and the primary ADA isozymes. These preleukemic cells presumably migrate to the thymus where they express the RT-7 pan-T-cell antigen and, in some instances, the OX 8 antigen during the development of overt leukemia. The OX 8+ neoplasms, being more differentiated than their OX 8- counterparts, then migrate to peripheral lymphoid tissues.     

Rapidly expanded activated human killer cell clones have strong antitumor cell activity and have the surface phenotype of either T gamma, T-non-gamma, or null cells

Cloned lymphoid cell lines showing cytolytic activity were derived from natural killer (NK) cell-enriched cell fractions obtained by fluorescence-activated cell sorting of cells that reacted with B73 .1, an NK cell-specific monoclonal antibody (MCA). The clones were cultured for more than 30 generations (i.e., more than 10(9) descendants from a single cell). The rapid expansion was achieved by using a special culture system developed for this purpose and based on the use of two types of allogeneic feeder cells. Three phenotypically different types of cytotoxic clones were obtained. These clones showed a broad spectrum of cytolytic activity against several NK-susceptible and NK-nonsusceptible tumor target cells. One of these clones had the following binding pattern to MCA: B73 .1+, T3-, T4-, T8-, HNK1 -, and Lyt-3-. These cells formed rosettes with IgG-coated erythrocytes but not with sheep erythrocytes, and therefore might be null cell-derived. Most of the cytotoxic clones showed the following phenotype: B73 .1+, T3-, T4-, T8-, HNK1 -, Lyt-3+, E+, and EA-gamma +. These clones were probably derived from T-gamma cells. In addition, one clone with cytolytic activity was derived from B73 .1- cells. This had the phenotype B73 .1-, T3+, T4-, T8-, HNK1 -, Lyt-3+, E+, and EA-gamma-, and may be of T-non-gamma cell origin. About 10 noncytolytic clones showed the phenotype B73 .1-, T3+, T4, or T8+, HNK1 -, Lyt-3+, Ia+, E+, and EA-gamma -. An absolute correlation was found between the presence of the B73 .1 antigen, the absence of the T3 marker, and the capacity of the cells to form EA rosettes. Furthermore, all clones except one (Lyt-3-) formed E rosettes. Although the in vitro life span varied from clone to clone, B73 .1- clones generally grew faster and for longer times (greater than or equal to 50 generations) than did B73 .1+ ones (less than or equal to 40 generations). The cytolytic activity, cell surface phenotype as determined with MCA, rosette formation, and target cell specificity spectrum remained stable over the entire culture period. We conclude that the majority of the activated MHC-nonrestricted cytolytic clones obtained in this culture system show a particular phenotype. These cells can be expanded to large numbers. Whether or not these clones might be derived from B73 .1+, HNK1 + NK cells with the morphologic appearance of large granular lymphocytes will be discussed.     

Isolation and characterization of Ni-specific T cell clones from patients with Ni-contact dermatitis

Ni-specific T lymphocyte clones (TLC) were isolated from two patients with Ni-contact dermatitis. All of the isolated TLC required both histocompatible antigen-presenting cells (APC) and Ni for induction of proliferation. By using a panel of HLA-typed Epstein Barr virus-transformed B cells (EBV-B cells) as APC and monoclonal anti-DR antibody, the clones were shown to recognize Ni in the context of HLA class II determinants. All of the clones that were isolated are OKT3+, OKT4+, OKT8-. In the presence of Ni, they polyclonally activate autologous B cells, and in the presence of Ni and autologous EBV-B cells, they produce IL 2 and very high levels of IFN-gamma. The Ni-specific clones should be helpful in the identification of the Ni-induced antigen which is recognized by T cells.     

Influenza virus-specific human cytotoxic T cell clones: Heterogeneity in antigenic specificity and restriction by class II MHC products

Human cytotoxic T lymphocytes specific for A/JAP/57 (H2N2) influenza virus were cloned from in vitro stimulations of peripheral blood lymphocytes. Analysis of the viral specificity in cytotoxic function revealed one clone that killed all type A influenza-infected targets, another clone that was specific for the hemagglutinin subtype of the immunizing influenza virus, and the third clone that demonstrated cytotoxicity restricted to the hemagglutinin of A/JAP/57 and A/JAP/62 (H2N2) and not other type A influenza strains with the H2N2 subtypes. The phenotype of these three clones was Leu 2^?, Leu 3⁺, Leu 4⁺; MHC restriction of their cytotoxic function was mapped to HLA-DR by a panel of target cells as well as by inhibition of cytotoxicity with monoclonal antibodies. Proliferation of these clones, examined in a tritiated thymidine incorporation assay, was found to be driven by antigen in the absence of exogenous lymphokines. For all three clones antigen-dependent production and secretion of lymphokines with IL-2 activity was demonstrated. The antigen specificity of proliferation and factor production was shown to be identical to the pattern that each clone revealed in its cytotoxic function.     

Preexisting influenza-specific CD4+ T cells correlate with disease protection against influenza challenge in humans

Protective immunity against influenza virus infection is mediated by neutralizing antibodies, but the precise role of T cells in human influenza immunity is uncertain. We conducted influenza infection studies in healthy volunteers with no detectable antibodies to the challenge viruses H3N2 or H1N1. We mapped T cell responses to influenza before and during infection. We found a large increase in influenza-specific T cell responses by day 7, when virus was completely cleared from nasal samples and serum antibodies were still undetectable. Preexisting CD4+, but not CD8+, T cells responding to influenza internal proteins were associated with lower virus shedding and less severe illness. These CD4+ cells also responded to pandemic H1N1 (A/CA/07/2009) peptides and showed evidence of cytotoxic activity. These cells are an important statistical correlate of homotypic and heterotypic response and may limit severity of influenza infection by new strains in the absence of specific antibody responses. Our results provide information that may aid the design of future vaccines against emerging influenza strains.     

Characteristics and functions of Sendai virus-specific T-cell clones

Several murine Sendai virus-specific T-cell clones were characterized in vitro and in vivo. All T-cell clones were phenotypically Thy-1.2+, and most clones were Lyt-1+,2-; one T-cell clone was Lyt-1-,2-. Some of the clones proliferated in response to antigen presented on I region-compatible stimulator cells. Proliferation could be inhibited by monoclonal antibodies directed against class II antigens. Clones which proliferated in response to antigen secreted lymphokines which could be identified as Interleukin 2 and Interleukin 3. All of the clones tested in vivo induced a delayed-type hypersensitivity response in syngeneic mice challenged with antigens. Depending on the experimental conditions chosen, Interleukin 2-producing clones as well as non-Interleukin 2-producing clones mediated help for stimulation of cytolytic T lymphocytes.     

Changes in paracrine interleukin-2 requirement, CCR7 expression, frequency, and cytokine secretion of human immunodeficiency virus-specific CD4+ T cells are a consequence of antigen load

Virus-specific CD4+ T-cell responses are thought to be required for the induction and maintenance of many effective CD8+ T-cell and B-cell immune responses in experimental animals and humans. Although the presence of human immunodeficiency virus (HIV)-specific CD4+ T cells has been documented in patients at all stages of HIV infection, many fundamental questions regarding their frequency and function remain. A 10-color, 12-parameter flow cytometric panel was utilized to examine the frequency, memory phenotype (CD27, CCR7, and CD45RA), and cytokine production (interleukin-2 [IL-2], gamma interferon, and tumor necrosis factor alpha) of CD4+ T cells specific for HIV antigens as well as for adenovirus, Epstein-Barr virus (EBV), influenza H1N1 virus, influenza H3N2 virus, cytomegalovirus, varicella-zoster virus (VZV), and tetanus toxoid in normal controls, long-term nonprogressors (LTNP), and HIV-infected patients with progressive disease on or off therapy. The HIV-specific CD4+ T-cell responses in LTNP and patients on therapy were similar in frequency, phenotype, and cytokine production to responses directed against adenovirus, EBV, influenza virus, and VZV. HIV-specific CD4+ T cells from patients off antiretroviral therapy demonstrated a shift towards a CCR7(-) CD45RA(-) phenotype and a reduced percentage of IL-2-producing cells. The alterations in cytokine production during HIV viremia were found to be intrinsic to the HIV-specific CD4+ T cells and caused a requirement for IL-2 supplied exogenously for proliferation to occur. These observations suggest that many previously described changes in HIV-specific CD4+ T-cell function and phenotype are a consequence of high levels of antigen in viremic patients. In addition, defects in function and phenotype of HIV-specific CD4+ T cells are not readily discernible in the context of antiretroviral therapy but rather are similar to responses to other viruses.     

Composite response of naive T cells to stimulation with the autologous lymphoblastoid cell line is mediated by CD4 cytotoxic T cell clones and includes an Epstein-Barr virus-specific component.

We have approached the challenge of generating a primary T cell response to Epstein-Barr virus (EBV) in vitro by stimulating naive T cells with the autologous EBV-transformed lymphoblastoid cell line (LCL), a rich source of EBV-associated cytotoxic T lymphocyte (CTL) epitopes. Responsive T cells from three EBV-seronegative donors were cloned in agarose, phenotyped for T cell markers by flow cytometry, and their cytotoxic properties analyzed in the 51Cr release assay. Most clones (greater than 95%) expressed the CD4 phenotype and 59% of these clones showed cytotoxic properties. The dominant CTL response was specific for FCS-associated epitopes presented by FCS-grown autologous LCL target cells and was restricted by class II HLA antigens. Other clonal components included: (i) an EBV-specific response by HLA-restricted CD4 CTL clones that did not discriminate between A- and B-type EBV transformants; (ii) an EBV-specific response by an HLA-restricted CD4 CTL clone that discriminated between A- and B-type transformants, and (iii) a nonspecific cytotoxic response by CD3+,4+,8-, CD3+,4-,8-, and CD3-,4-,8- clones that were broadly allotypic or restricted to the lysis of K562 target cells. The EBV-specific CTL clones did not lyse the autologous EBV-negative B or T cell blasts and their specificity patterns of lysis were supported by the cold target competition data. These studies highlight the role of CD4 CTL in the establishment in vitro of a primary immune response to a human virus.     

Human T cell clones present antigen

Two human T cells clones are described which react with influenza virus hemagglutinin type H3 and synthetic peptides of H3 when presented by PBMC APC. Both T cell clones also responded to peptide Ag in the absence of additional APC suggesting that T cells can simultaneously present and respond to Ag. T cell clones could only present peptide Ag and not an appropriate strain of inactivated whole influenza virus thus indicating an inability to process Ag conventionally. Peptide presentation by T cells was dose dependent, restricted by MHC class II Ag and was dependent on the number of Ag presenting T cells per culture. Experiments with nested peptides showed that the same epitope was recognized in the presence and absence of PBMC APC. No Ag or IL-2 from the propagation procedure was carried over into assays and two-color fluorescence-activated cell sorter analysis of each clone detected no contaminating cells with the phenotype of monocytes, macrophages or B cells; in each T cell clone, all cells expressing MHC class II Ag co-expressed CD3. These date therefore provide strong evidence that human T cell clones can simultaneously present and respond to appropriate forms of Ag.     

A rat anti-mouse T4 monoclonal antibody (H129.19) inhibits the proliferation of Ia-reactive T cell clones and delineates two phenotypically distinct (T4+, Lyt-2,3-, and T4-, Lyt-2,3+) subsets among anti-Ia cytolytic T cell clones

Hybridoma H129 .19 was derived by fusion between spleen cells of a Lou / Ws1 rat immunized with an Lyt-1+,2- anti-I-Ak cytolytic T lymphocyte (CTL) clone and the nonsecreting myeloma X63-Ag8.653. The monoclonal antibody (mAb) H129 .19 (IgG2a, kappa) was selected for its capacity to inhibit the lytic potential of the immunizing clone. H129 .19 identified a monomorphic determinant on a 55 m.w. murine T cell differentiation antigen, which appeared to be homologous to the human T4 molecule in that: 1) H129 .19 reacted with 80% adult thymocytes, with a subset of splenic T cells, and with the interleukin 2 (IL 2)-producing EL4 thymoma; 2) The mAb bound to and inhibited the IL 2 production and the proliferation of various allo- or soluble antigen-reactive T cell clones that recognized restriction or activating determinants on the I-A or I-E molecules, respectively; 3) H129 .19 did not inhibit the proliferation and/or cytolysis of Lyt-2,3+ T cells specific for class I MHC antigen; and 4) Among six anti-Iak CTL clones examined in this study, the mAb H129 .19 reacted with two I-Ak-specific, Lyt-2,3- clones on which it exerted strong cytolysis inhibiting effect at the effector cell level. By contrast, two other anti-I-Ak and two anti-I-Ek CTL clones were found to express the Lyt-2,3+,T4- cell surface phenotype. The cytolytic potential of the latter clones was not inhibited by anti-Lyt-2,3 mAb. These studies strongly suggest that the mouse T4 molecule facilitates the recognition of class II MHC antigen by most but not all T cells.     

Recognition of cloned influenza virus hemagglutinin gene products by cytotoxic T lymphocytes.

The influenza A virus hemagglutinin (HA) is an integral membrane glycoprotein expressed in large quantities on infected cell surfaces and is known to serve as a target antigen for influenza virus-specific cytotoxic T lymphocytes (CTL). Despite the fact that HAs derived from different influenza A virus subtypes are serologically non-cross-reactive, the HA has been implicated by previous experiments to be a target antigen for the subset of T cells capable of lysing cells infected with any human influenza A subtype (cross-reactive CTL). To directly determine whether the HA is recognized by cross-reactive CTL, we used vaccinia virus recombinants containing DNA copies of the PR8 (A/Puerto Rico/8/34) (H1N1) or JAP (A/JAP/305) (H2N2) HA genes. When these viruses were used to stimulate HA-specific CTL and to sensitize target cells for lysis by HA-specific CTL, we found no evidence for HA recognition by cross-reactive CTL aside from a relatively small degree of cross-reactivity between H1 and H2 HAs. Results of unlabeled target inhibition studies were consistent with the conclusion that the HA is, at most, only a minor target antigen for cross-reactive CTL.