Direct priming and cross-priming contribute differentially to the induction of CD8+ CTL following exposure to vaccinia virus via different routes

To explore the relative importance of direct presentation vs cross-priming in the induction of CTL responses to viruses and viral vectors, we generated a recombinant vaccinia vector, vUS11, expressing the human CMV (HCMV) protein US11. US11 dislocates most allelic forms of human and murine MHC class I heavy chains from the lumen of the endoplasmic reticulum into the cytosol, where they are degraded by proteasomes. Expression of US11 dramatically decreased the presentation of viral Ag and CTL recognition of infected cells in vitro without significantly reducing total cell surface MHC class I levels. However, because US11 is an endoplasmic reticulum resident membrane protein, it cannot block presentation by non-infected cells that take up Ag through the cross-priming pathway. We show that the expression of US11 strongly inhibits the induction of primary CD8(+) CTLs when the infection occurs via the i.p. or i.v. route, demonstrating that direct priming is critical for the induction of CTL responses to viral infections introduced via these routes. This effect is less dramatic following i.m. infection and is minimal after s.c. or intradermal infection. Thus, classic MHC class I Ag presentation and cross-priming contribute differentially to the induction of CD8(+) CTLs following exposure to vaccinia virus via different routes.     

Unrestricted recognition of a nonpeptide antigen by CD8+ cytolytic T lymphocytes

CD8+ murine CTL that are specific for an unusual nonpeptide Ag, the heme moiety of hemoglobin, have been derived by in vitro stimulation of spleen cells with hemin. Such CTL demonstrate a requirement for the expression of class I Ag on target cells, yet appear to be unrestricted to the extent that both syngeneic and allogeneic targets precoated with hemin are sensitive to lysis. A series of CTL clones with specificity for hemin was derived from C57BL/6 mice. They exhibited the same type of promiscuous recognition that was observed in CTL populations from a number of different strains. The possibility that hemin acts as a nonspecific mediator of lysis by CTL was ruled out by the fact that a variety of CTL populations and clones specific for different Ag did not exhibit hemin-specific lysis. Some explanations offered to explain these results include 1) the possibility that hemin is recognized by binding to a site on the MHC other than the Ag-binding groove, and 2) the possibility that TCR recognition of a rigid molecule, such as hemin, may be less sensitive to polymorphic variation in the MHC than is recognition of a conventional peptide Ag whose conformation may differ significantly when bound to MHC molecules whose sequences differ within the Ag-binding groove.     

Failure or success in the restoration of virus-specific cytotoxic T lymphocyte response defects by dendritic cells

C57BL/6 (B6, H-2b) mice are CTL responders to both Sendai virus and Moloney leukemia virus. In the former response the H-2Kb class I MHC molecule is used as CTL restriction element, in the latter response the H-2Db molecule. B6 dendritic cells (DC) are superior in the presentation of Sendai virus Ag to CTL in comparison with B6 normal spleen cells. Con A blasts have even less capacity to present viral Ag than NSC, and LPS blasts show an intermediate capacity to present viral Ag. H-2Kb mutant bm1 mice do not generate a CTL response to Sendai virus, but respond to Moloney leukemia virus, as demonstrated by undetectable CTL precursors to Sendai virus and a normal CTL precursor frequency to Moloney virus. Compared to B6 mice, other H-2Kb mutant mice show decreased Sendai virus-specific CTL precursor frequencies in a hierarchy reflecting the response in bulk culture. The Sendai virus-specific CTL response defect of bm1 mice was not restored by highly potent Sendai virus-infected DC as APC for in vivo priming and/or in vitro restimulation. In mirror image to H-2Kb mutant bm1 mice, H-2Db mutant bm14 mice do not generate a CTL response to Moloney virus, but respond normally to Sendai virus. This specific CTL response defect was restored by syngeneic Moloney virus-infected DC for in vitro restimulation. This response was Kb restricted indicating that the Dbm14 molecule remained largely defective and that a dormant Kb repertoire was aroused after optimal Ag presentation by DC. In conclusion, DC very effectively present viral Ag to CTL. However, their capacity to restore MHC class I determined specific CTL response defects probably requires at least some ability of a particular MHC class I/virus combination to associate and thus form an immunogenic complex.     

Influenza A-specific, HLA-A2.1-restricted cytotoxic T lymphocytes from HLA-A2.1 transgenic mice recognize fragments of the M1 protein.

Previous studies have indicated that in transgenic mice expressing human class I MHC molecules, it is difficult to demonstrate a significant CTL response to a viral Ag in the context of the transgenic molecule. In this paper, a procedure is reported for the isolation of influenza-specific murine CTL restricted by the human class I molecule HLA-A2.1. The principal specificity of such CTL is for a fragment of the influenza M1 protein that has been previously shown to be immunodominant for human HLA-A2.1-restricted CTL. CTL of this specificity were also established through the use of peptide-pulsed rather than virus-infected stimulators. The dependence of murine CTL recognition upon peptide length and HLA-A2 structure was established to be similar to that previously reported for human CTL. However, the fine specificity of CTL maintained on virus-infected stimulators was somewhat different from that of CTL maintained with M1 peptide. This suggests that differences in surface density or peptide structure between peptide-pulsed and virus-infected stimulators may result in the outgrowth of T cells with different receptor structures. The immunodominance of the M1 peptide determinant in both mice and humans suggests that species-specific differences in TCR structure, Ag-processing systems, and self-tolerance are of less importance than limitations on the ability of antigenic peptides to bind to appropriate class I molecules. These results thus establish the utility of the transgenic system for the identification of human class I MHC-restricted T cell epitopes.     

Monomorphic molecules function as additional recognition structures on haptenated target cells for HLA-A1-restricted, hapten-specific CTL

Hapten-specific T cells have been shown to recognize haptenated peptides with high avidity and, in some instances, with promiscuous MHC restriction. In this study, the impact of Ag density on MHC restriction of a CTL response specific to the trinitrophenyl (TNP) hapten was investigated. In this study, we demonstrate a novel recognition mechanism used by TNP-specific CD8(+) CTL in the presence of high Ag doses. Although low levels of TNP epitopes on target cells allowed for HLA-A1-restricted CTL activity only, entirely MHC-independent target cell recognition became operative at high TNP loading. In both cases, recognition was mediated by the TCR. This MHC-independent recognition is target cell type restricted and critically involves in our model direct recognition of the ectonucleotidase family surface molecule CD39 by the CTL.     

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.     

Retrovirus-induced changes in major histocompatibility complex antigen expression influence susceptibility to lysis by cytotoxic T lymphocytes

Retrovirus infection of murine fibroblasts was found to alter the expression of major histocompatibility complex (MHC) antigens. Fibroblasts infected with Moloney murine leukemia virus (M-MuLV) exhibited up to a 10-fold increase in cell surface expression of all three class I MHC antigens. Increases in MHC expression resulted in the increased susceptibility of M-MuLV-infected cells to lysis by allospecific cytotoxic T lymphocytes (CTL). M-MuLV appears to exert its effect at the genomic level, because mRNA specific for class I antigens, as well as beta 2-microglobulin, show a fourfold increase. Fibroblasts infected with the Moloney sarcoma virus (MSV):M-MuLV complex show no increase in MHC antigen expression or class I mRNA synthesis, suggesting that co-infection with MSV inhibits M-MuLV enhancement of MHC gene expression. Quantitative differences in class I antigen expression on virus-infected cells were also found to influence the susceptibility of infected cells to lysis by H-2-restricted, virus-specific CTL. Differential lysis of infected cells expressing varied levels of class I antigens by M-MuLV-specific bulk CTL populations and CTL clones suggests that individual clones may have different quantitative requirements for class I antigen expression. The MSV inhibition of MHC expression could be reversed by interferon-gamma. Treatment of MSV:M-MuLV-infected fibroblasts with interferon-gamma increased their susceptibility to lysis by both allogeneic and syngeneic CTL. The data suggest that interferon-gamma may function in the host's immune response to viral infections by enhancing MHC antigen expression, thereby increasing the susceptibility of virus-infected cells to lysis by H-2-restricted, virus-specific CTL.     

Vaccinia virus-specific CD8+ cytotoxic T lymphocytes in humans.

Stimulation of human vaccinia virus immune peripheral blood mononuclear cells in vitro from vaccinia virus-immune donors with live vaccinia virus-infected autologous cells generated vaccinia virus-specific cytotoxic T lymphocytes (CTL) capable of lysing vaccinia virus-infected cells. We generated vaccinia virus-specific CD8+ clones and CD4+ CTL lines by limiting dilution from two donors by using peripheral blood mononuclear cells obtained 2 months or 4 years postrevaccination with vaccinia virus. These results demonstrate that vaccinia virus-specific CTL are generated as a result of immunization of humans with vaccinia virus and that both CD8(+)- and CD4(+)-specific T cells are maintained as memory cells.     

Defective presentation of endogenous antigens by a murine sarcoma. Implications for the failure of an anti-tumor immune response

MHC class I-restricted CTL play a central role in the immune response against methylcholanthrene (MCA)-induced sarcomas in mice. We, therefore, hypothesized that MCA-induced tumors may evade immune recognition by failing to present Ag to CD8+ CTL. Of a number of previously described MCA-induced sarcomas, one, MCA 101, fails to induce CTL, is nonimmunogenic, and grows rapidly and lethally in nonimmunosuppressed recipients. To better understand the nonimmunogenicity of MCA 101 we examined its ability to present foreign Ag to CTL. Unlike immunogenic sarcomas, MCA 101 failed to present endogenously synthesized influenza virus Ag to influenza virus-specific CTL. The deficiency in presentation of endogenous Ag by MCA 101 was attributed to a markedly reduced rate of synthesis of class I molecules because up-regulation of class I synthesis by IFN-gamma greatly increased the presentation of influenza A virus Ag. Despite low levels of cell surface class I expression, MCA 101 presented exogenous peptide Ag to anti-influenza CTL with efficiency similar to immunogenic MCA sarcoma cell lines. These findings could not be attributed to deficiencies in class I assembly or transport, as has been suggested by others who have studied mutant cells with defective Ag presentation. Furthermore, our studies suggest that some tumor cells can escape recognition by CTL and subsequent immune eradication by suppressing presentation of endogenous Ag.     

Resistance to H-2-restricted but not to allo-H2-specific graft and cytotoxic T lymphocyte responses in lymphoma mutant

The lymphoma mutant RMA-S escaped graft rejection after transplantation over a minor histocompatibility barrier, whereas it was rejected in H-2 allogeneic mice. The parental control line was rejected in both situations. The mutant, which had been selected against MHC class I molecules retained 5 to 10% of the wild-type H-2Db, Kb, and beta 2-microglobulin expression on the cell surface. It remained sensitive to allo-H-2b CTL in vitro, but was completely resistant to minor histocompatibility antigen-specific, H-2b-restricted CTL. It was equally resistant to other H-2b-restricted responses against internally derived Ag, such as tumor-specific CTL or a CTL clone specific for the influenza virus nucleoprotein. The results indicate a target cell defect that selectively abolishes the sensitivity to H-2-restricted CTL directed against internally processed Ag. This appears sufficient to shift the transplantation response over a minor histocompatibility Ag barrier from rejection to acceptance. There are two possible explanations for the results: 1) a block in the MHC class I-directed pathway for internal Ag processing, and 2) subthreshold H-2/Ag ligand density in relation to triggering requirements of restricted CTL. Regardless of the type of defect, the results demonstrate a difference between allo-H-2-specific and H-2-restricted CTL recognition at the level of the target cell.     

Class I MHC-restricted recognition of cells expressing a gene encoding a 41 amino acid product of the influenza hemagglutinin

Class I H-2Kd-restricted influenza hemagglutinin (HA)-specific CTL recognize two immuno-dominant sites as represented by synthetic peptides spanning epitopes located in the HA1 and hydrophobic transmembrane domains of the influenza HA. Using a vaccinia virus recombinant expression system, we have examined CTL recognition of HA deletion mutants expressed in target cells. We have demonstrated that a truncated influenza HA gene encoding only the transmembrane anchor region containing a class I recognition site and a short segment of the cytoplasmic tail of the HA can be efficiently presented to class I CTL. These results set the stage for detailed analyses of the intracellular events associated with Ag presentation to class I CTL and offer novel possibilities for future vaccine design.     

Cytolytic T lymphocytes from the BALB/c-H-2dm2 mouse recognize the vesicular stomatitis virus glycoprotein and are restricted by class II MHC antigens.

BALB/c-H-2dm2 mice (H-2KdI-AdI-EdDd), a congenic strain of BALB/c mice, have a deletion of the class I MHC Ag, H-2Ld. This gene encodes the exclusive class I MHC-restricting gene product for vesicular stomatitis virus-specific cytolytic T lymphocytes. When dm2 mice were immunized with infectious vesicular stomatitis virus, a specific CTL response was generated. These CTL lysed VSV-infected targets that expressed Iad gene products, but not VSV-infected Iad- targets. The CTL were used initially as long term cytolytic lines; 13 CTL clones were derived by limit dilution. All of the clones expressed the phenotype CD3+, CD4+, CD8-; some clones expressed TCR that are members of the V beta 8 family, others did not. The clones were restricted by class II MHC Ag, both I-Ad and I-Ed serving as restricting elements for individual clones of the panel. All of the clones derived from dm2 mice were specific for the immunizing serotype, Indiana, of VSV and did not lyse syngeneic cells infected with VSV of the New Jersey serotype. Studies using defective interfering virus particles, UV light-inactivated virus, and purified micelles of the viral glycoprotein indicated that infectious virus was not required for sensitization of target cells for immune recognition by the class II MHC-restricted CTL clones. Additional studies using recombinant vaccinia virus vectors to sensitize targets confirmed the specificity of the clones for the viral glycoprotein. These studies also demonstrated a cryptic population of class II-restricted CTL in BALB/c lines specific for VSV G. Naturally occurring variant viruses and mutant viruses, selected for escape from neutralization by mAb, were used in an effort to map the determinant(s) recognized; on the basis of patterns of target cell lysis, three groups of epitopes recognized by the clones were defined. Therefore, in the absence of the class I MHC Ag required for a CTL response to VSV, dm2 mice generated CTL with the CD4+ phenotype that recognized different epitopes on the viral glycoprotein, and lysed cells in a class II-MHC restricted, Ag-specific manner.     

A single amino acid difference within the alpha-2 domain of two naturally occurring equine MHC class I molecules alters the recognition of Gag and Rev epitopes by equine infectious anemia virus-specific CTL

Although CTL are critical for control of lentiviruses, including equine infectious anemia virus, relatively little is known regarding the MHC class I molecules that present important epitopes to equine infectious anemia virus-specific CTL. The equine class I molecule 7-6 is associated with the equine leukocyte Ag (ELA)-A1 haplotype and presents the Env-RW12 and Gag-GW12 CTL epitopes. Some ELA-A1 target cells present both epitopes, whereas others are not recognized by Gag-GW12-specific CTL, suggesting that the ELA-A1 haplotype comprises functionally distinct alleles. The Rev-QW11 CTL epitope is also ELA-A1-restricted, but the molecule that presents Rev-QW11 is unknown. To determine whether functionally distinct class I molecules present ELA-A1-restricted CTL epitopes, we sequenced and expressed MHC class I genes from three ELA-A1 horses. Two horses had the 7-6 allele, which when expressed, presented Env-RW12, Gag-GW12, and Rev-QW11 to CTL. The other horse had a distinct allele, designated 141, encoding a molecule that differed from 7-6 by a single amino acid within the alpha-2 domain. This substitution did not affect recognition of Env-RW12, but resulted in more efficient recognition of Rev-QW11. Significantly, CTL recognition of Gag-GW12 was abrogated, despite Gag-GW12 binding to 141. Molecular modeling suggested that conformational changes in the 141/Gag-GW12 complex led to a loss of TCR recognition. These results confirmed that the ELA-A1 haplotype is comprised of functionally distinct alleles, and demonstrated for the first time that naturally occurring MHC class I molecules that vary by only a single amino acid can result in significantly different patterns of epitope recognition by lentivirus-specific CTL.     

Cytolytic T-lymphocyte responses to respiratory syncytial virus: effector cell phenotype and target proteins.

Cytolytic T-lymphocyte (CTL) activity specific for respiratory syncytial (RS) virus was investigated after intranasal infection of mice with RS virus, after intraperitoneal infection of mice with a recombinant vaccinia virus expressing the F glycoprotein, and after intramuscular vaccination of mice with Formalin-inactivated RS virus or a chimeric glycoprotein, FG, expressed from a recombinant baculovirus. Spleen cell cultures from mice previously infected with live RS virus or the F-protein recombinant vaccinia virus had significant CTL activity after one cycle of in vitro restimulation with RS virus, and lytic activity was derived from a major histocompatibility complex-restricted, Lyt2.2+ (CD8+) subset. CTL activity was not restimulated in spleen cells from mice that received either the Formalin-inactivated RS virus or the purified glycoprotein, FG. The protein target structures for recognition by murine CD8+ CTL were identified by using target cells infected with recombinant vaccinia viruses that individually express seven structural proteins of RS virus. Quantitation of cytolytic activity against cells expressing each target structure suggested that 22K was the major target protein for CD8+ CTL, equivalent to recognition of cells infected with RS virus, followed by intermediate recognition of F or N, slight recognition of P, and no recognition of G, SH, or M. Repeated stimulation of murine CTL with RS virus resulted in outgrowth of CD4+ CTL which, over time, became the exclusive subset in culture. Murine CD4+ CTL were highly cytolytic for RS virus-infected cells, but they did not recognize target cells infected with any of the recombinant vaccinia viruses expressing the seven RS virus structural proteins. Finally, the CTL response in peripheral blood mononuclear cells of adult human volunteers was investigated. The detection of significant levels of RS virus-specific cytolytic activity in these cells was dependent on at least two restimulations with RS virus in vitro, and cytolytic activity was derived primarily from the CD4+ subset.     

Induction of potent antitumor CTL responses by recombinant vaccinia encoding a melan-A peptide analogue

There is considerable interest in the development of vaccination strategies that would elicit strong tumor-specific CTL responses in cancer patients. One strategy consists of using recombinant viruses encoding amino acid sequences corresponding to natural CTL-defined peptide from tumor Ags as immunogens. However, studies with synthetic tumor antigenic peptides have demonstrated that introduction of single amino acid substitutions may dramatically increase their immunogenicity. In this study we have used a well-defined human melanoma tumor Ag system to test the possibility of translating the immunological potency of synthetic tumor antigenic peptide analogues into recombinant vaccinia viruses carrying constructs with the appropriate nucleotide substitutions. Our results indicate that the use of a mutated minigene construct directing the expression of a modified melanoma tumor Ag leads to improved Ag recognition and, more importantly, to enhanced immunogenicity. Thus, recombinant vaccinia viruses containing mutated minigene sequences may lead to new strategies for the induction of strong tumor-specific CTL responses in cancer patients.     

Class I MHC-restricted cytotoxic T lymphocyte recognition of cells infected with human cytomegalovirus does not require endogenous viral gene expression.

The human pathogen CMV, is a major cause of morbidity and mortality in immunocompromised hosts. The CD8+ class I-restricted CTL response to CMV assists in preventing progression of CMV infection to life-threatening disease; however, the viral Ag recognized by CD8+ CTL are not well characterized. In general, virus-specific CTL recognize endogenously synthesized viral proteins processed and presented associated with class I MHC molecules. Although proteins or inactivated virions have been experimentally delivered to the cytoplasm to result in class I MHC presentation, this mode of Ag delivery to the class I processing pathway after natural viral entry has not been documented in humans. Our data demonstrate that the CMV-specific class I-restricted CTL response in individuals latently infected with CMV is predominantly specific for selected structural virion proteins introduced into the cell after viral penetration and efficient recognition occurs in the absence of de novo viral gene expression. This CTL response may provide a biological advantage for limiting the spread of infection after CMV reactivation because infected cells are lysed before viral assembly.     

Resistance of human cells to the adenovirus E3 effect on class I MHC antigen expression. Implications for antiviral immunity

Group C human adenovirus (Ad) serotypes (e.g., Ad2 and Ad5) cause persistent infections in man. One proposed mechanisms to explain human adenovirus persistence is an ineffective CTL response due to reduced cell surface expression of class I MHC Ag on virally infected cells, an effect mediated by the 19-kDa glycoprotein encoded by Ad early region 3 (E3). In the present study, the generality of this phenomenon was tested by analyzing E3 19-kDa glycoprotein down-regulation of cell surface class 1 MHC Ag on a variety of human cell types. With the exception of the Ad5 early region 1 (E1) transformed cell line, 293, Ad2/5 infection of fibroblastic, epithelial, and lymphoid cells did not cause major decreases in surface class I Ag until the terminal stages of infection when cell death is imminent. Furthermore, newly synthesized class I Ag continued to be surface expressed on most cell types at times when infected cells contained large amounts of Ad E3 19-kDa glycoprotein. These data indicate that most types of human cells are resistant to the E3 19-kDa glycoprotein effect, suggesting that virus-specific CTL recognition and lysis of most Ad2/5-infected human cells should not be limited by E3 19-kDa-mediated reduction in class I MHC Ag expression.     

Generation of CD8(+) T cell memory in response to low, high, and excessive levels of epitope

The magnitude of a virus-specific memory CTL population can dramatically influence the outcome of secondary infections, yet little is known about the determinants of memory size. We investigated the impact of epitope levels on CTL memory generation by using a recombinant vaccinia virus system that allows for a broad range of epitope expression with the same infectious dose of virus. The size of the memory pool was examined using MHC class I/peptide tetramer staining and IFN-gamma ELISPOT analysis following priming with viruses expressing low, high, or excessive epitope levels. The size of the epitope-specific CD8(+) T cell memory population correlates with Ag dose at the low and high levels of epitope expression. However, at excessive epitope levels, the number of functional, IFN-gamma-producing, epitope-specific memory cells is significantly reduced compared with the number of tetramer(+) cells. These results demonstrate that the level of epitope expressed during an acute viral infection in vivo can dramatically influence CTL memory size. Furthermore, when epitope is overexpressed, the quality of the response can be adversely affected. Therefore, epitope expression level is an important consideration when developing approaches to optimize CTL memory induction.     

Fine specificity and MHC restriction of trinitrophenyl-specific CTL

In this study, the fine specificity and MHC restriction of a CTL response specific to the trinitrophenyl (TNP) hapten was analyzed. Based on the structure of peptide/Kb complexes and ternary TCR/Ag/MHC complexes, four TNP peptides, two octamers, and two nonamers were chosen for eliciting anti-TNP CTL responses. Hapten was conjugated at position 4 in the octamers and at position 5 in the nonamers, positions which should allow engagement of the hapten by TCRs. Potent CTL activity for each of the TNP peptides was obtained that was highly hapten-specific; however, there were considerable differences in the extent of cross-reactivity with other TNP peptides, with the octamers generating more cross-reactive CTL than the nonamers. MHC restriction analysis suggested that anti-hapten responses were less dependent on MHC recognition than anti-peptide responses. This was evidenced by the relative ease of detecting cross-reactivity to haptenated peptides presented by allo-MHC and by the relative insensitivity of anti-hapten vs anti-peptide CTL to mutations in the Kb molecule at potential TCR interaction sites. One potential explanation for this insensitivity to MHC mutation was the finding that the anti-hapten response appeared to be of higher avidity, since a > 100-fold difference in the amount of Ag required to sensitize target cells was found between these two types of Ags.