Differential functional avidity of dengue virus-specific T-cell clones for variant peptides representing heterologous and previously encountered serotypes

Proinflammatory cytokines secreted by memory CD8+ and CD4+ T cells are thought to play a direct role in the pathogenesis of dengue virus infection by increasing vascular permeability and thereby inducing the pathophysiologic events associated with dengue hemorrhagic fever and dengue shock syndrome. Severe disease is frequently observed in the setting of secondary infection with heterologous dengue virus serotypes, suggesting a role for cross-reactive memory T cells in the immunopathogenesis of severe disease. We used a large panel of well-characterized dengue virus-specific CD8+ T-cell clones isolated from Pacific Islanders previously infected with dengue virus 1 to examine effector memory function, focusing on a novel dominant HLA-B*5502-restricted NS5(329-337) epitope, and assessed T-cell responses to stimulation with variant peptides representing heterologous serotypes. Variant peptides were differentially recognized by dengue virus 1-specific effector CD8+ cytotoxic T lymphocytes (CTL) in a heterogeneous and clone-specific manner, in which cytolytic function and cytokine secretion could be enhanced, diminished, or abrogated compared with cognate peptide stimulation. Dengue virus-specific CTL stimulated with cognate and variant peptides demonstrated a cytokine response hierarchy of gamma IFN (IFN-gamma) > tumor necrosis factor alpha (TNF-alpha) > interleukin-2 (IL-2), and a subset of clones also produced IL-4 and IL-6. Individual clones demonstrated greater avidity for variant peptides representing heterologous serotypes, including serotypes previously encountered by the subject, and IFN-gamma and TNF-alpha secretion was enhanced by stimulation with these heterologous peptides. Altered antiviral T-cell responses in response to stimulation with heterologous dengue virus serotypes have implications for control of virus replication and for disease pathogenesis.     

Alternative mechanisms of respiratory syncytial virus clearance in perforin knockout mice lead to enhanced disease

Virus-specific cytotoxic T lymphocytes are key effectors for the clearance of virus-infected cells and are required for the normal clearance of respiratory syncytial virus (RSV) in mice. Although perforin/granzyme-mediated lysis of infected cells is thought to be the major molecular mechanism used by CD8(+) cytotoxic T lymphocytes for elimination of virus, its role in RSV has not been reported. Here, we show that viral clearance in perforin knockout (PKO) mice is slightly delayed but that both PKO and wild-type mice clear virus by day 10, suggesting an alternative mechanism of RSV clearance. Effector T cells from the lungs of both groups of mice were shown to lyse Fas (CD95)-overexpressing target cells in greater numbers than target cells expressing low levels of Fas, suggesting that Fas ligand (CD95L)-mediated target cell lysis was occurring in vivo. This cell lysis was associated with a delay in RSV-induced disease in PKO mice compared to the time of disease onset for wild-type controls, which correlated with increased and prolonged production of gamma interferon and tumor necrosis factor alpha levels in PKO mice. We conclude that while perforin is not necessary for the clearance of primary RSV infection, the use of alternative CTL target cell killing mechanisms is less efficient and can lead to enhanced disease.     

The virus-specific and allospecific cytotoxic T-lymphocyte response to lymphocytic choriomeningitis virus is modified in a subpopulation of CD8(+) T cells coexpressing the inhibitory major histocompatibility complex class I receptor Ly49G2

The role of negatively signaling NK cell receptors of the Ly49 family on the specificity of the acute CD8(+) cytotoxic T-lymphocyte (CTL) response was investigated in lymphocytic choriomeningitis virus (LCMV)-infected C57BL/6 mice. Activated CD8(+) T cells coexpressing Ly49G2 expanded during LCMV infection, and T-cell receptor analyses by flow cytometry and CDR3 spectratyping revealed a unique polyclonal T-cell population in the Ly49G2(+) fraction. These cells lysed syngeneic targets infected with LCMV or coated with two of three LCMV immunodominant peptides examined. Transfection of these sensitive targets with H2D(d), a ligand for Ly49G2, inhibited lysis. This was reversed by antibody to Ly49G2, indicating effective negative signaling. LCMV characteristically induces an anti-H2(d) allospecific T-cell response that includes T-cell clones cross-reactive between allogeneic and LCMV-infected syngeneic targets. The CD8(+) Ly49G2(+) population mediated no allospecific killing, nor was any NK-like killing observed against YAC-1 cells. This study shows that CD8(+) Ly49G2(+) cells participate in the virus-induced CTL response but lyse a more restricted range of targets than the rest of the virus-induced CTL population.     

IL-4 diminishes perforin-mediated and increases Fas ligand-mediated cytotoxicity In vivo

CTL have evolved two major mechanisms for target cell killing: one mediated by perforin/granzyme secretion and the other by Fas/Fas ligand (L) interaction. Although cytokines are integral to the development of naive CTL into cytolytic effectors, the role of cytokines on mechanisms of CTL killing is just emerging. In this study, we evaluate the effects of IL-4 in Fas(CD95)/FasL(CD95L)-mediated killing of Fas-overexpressing target cells. Recombinant vaccinia viruses (vv) were constructed to express respiratory syncytial virus M2 Ag alone (vvM2) or coexpress M2 and IL-4 (vvM2/IL-4). MHC-matched Fas-overexpressing target cells (L1210Fas+) were used to measure both perforin- and FasL-mediated killing pathways. In contrast to Fas-deficient (L1210Fas-) target cells, effectors from vvM2/IL-4-immunized mice were able to lyse L1210Fas+ target cells with similar magnitude as vvM2-infected mice. Addition of EGTA/Mg2+ revealed that effectors from vvM2/IL-4-infected mice primarily lyse targets by a Ca2+-independent Fas/FasL pathway. Analysis of FasL expression by flow cytometry showed that IL-4 increased cell surface FasL expression on CD4+ and CD8+ splenocytes, with peak expression on day 4 after infection. These data demonstrate that IL-4 increases FasL expression on T cells, resulting in a shift of the mechanism of CTL killing from a dominant perforin-mediated cytolytic pathway to a dominant FasL-mediated cytolytic pathway.     

CTL-mediated killing of intracellular Mycobacterium tuberculosis is independent of target cell nuclear apoptosis

Two subsets of human CTL have been defined based upon phenotype and function: CD4(-) CD8(-) double-negative (DN) CTL lyse susceptible targets via Fas-Fas ligand interaction and CD8(+) CTL via the granule exocytosis pathway. CD8(+) CTL, but not DN CTL, can mediate an antimicrobial activity against Mycobacterium tuberculosis-infected target cells that is dependent on cytotoxic granules that contain granulysin. We investigated the role of nuclear apoptosis for the antimicrobial effector function of CD1-restricted CTL using the caspase inhibitor N:-benzyloxycarbonyl-Val-Ala-Asp-fluoromethylketone. We found that DN CTL-induced target cell lysis was completely dependent on caspase activation, whereas the cytolytic activity of CD8(+) CTL was caspase independent. However, both DN and CD8(+) CTL-induced nuclear apoptosis required caspase activation. More important, the antimicrobial effector function of CD8(+) CTL was not diminished by inhibition of caspase activity. These data indicate that target cell nuclear apoptosis is not a requirement for CTL-mediated killing of intracellular M. tuberculosis.     

Differential susceptibility of cells expressing allogeneic MHC or viral antigen to killing by antigen-specific CTL

CD8(+) cytotoxic T lymphocytes (CTLs) generated by immunization with allogeneic cells or viral infection are able to lyse allogeneic or virally infected in vitro cells (e.g., lymphoma and mastocytoma). In contrast, it is reported that CD8(+) T cells are not essential for allograft rejection (e.g., heart and skin), and that clearance of influenza or the Sendai virus from virus-infected respiratory epithelium is normal or only slightly delayed after a primary viral challenge of CD8-knockout mice. To address this controversy, we generated H-2(d)-specific CD8(+) CTLs by a mixed lymphocyte culture and examined the susceptibility of a panel of H-2(d) cells to CTL lysis. KLN205 squamous cell carcinoma, Meth A fibrosarcoma, and BALB/c skin components were found to be resistant to CTL-mediated lysis. This resistance did not appear to be related to a reduced expression of MHC class I molecules, and all these cells could block the recognition of H-2(d) targets by CTLs in cold target inhibition assays. We extended our observation by persistently infecting the same panel of cell lines with defective-interfering Sendai virus particles. The Meth A and KLN205 lines infected with a variant Sendai virus were resistant to lysis by Sendai virus-specific CTLs. The Sendai virus-infected Meth A and KLN205 lines were able to block the lysis of Sendai virus-infected targets by CTLs in cold target inhibition assays. Taken together, these results suggest that not all in vivo tissues may be sensitive to CTL lysis.     

Mechanisms of lysis by cytotoxic T lymphocyte clones. Lytic activity and gene expression in cloned antigen-specific CD4+ and CD8+ T lymphocytes.

Cloned murine Th having properties of either Th1 or Th2 cells as well as CD8+ CTL were tested for the capacity to lyse: 1) nucleated target cells bearing Ag or coated with anti-CD3 mAb, or 2) SRBC target cells coated with anti-CD3 mAb in a short term 51Cr-release assay. The lysis of SRBC occurs by a mechanism that does not involve nuclear degradation but presumably does involve membrane damage. Three patterns were observed: CTL and some Th2 cells lysed efficiently nucleated target cells and SRBC coated with anti-CD3 mAb. Th1 and some Th2 T cells lysed nucleated target cells but did not lyse efficiently the SRBC coated with anti-CD3 mAb. Finally, some Th2 cells failed to lyse efficiently either nucleated or SRBC targets. We also examined these clones for their expression of N-alpha-benzyloxycarbonyl-L-lysin thiobenzyl esterase activity, and for the expression of perforin or CTLA-1 (granzyme B) mRNA. Total N-alpha-benzyloxycarbonyl-L-lysin thiobenzyl esterase activity expressed by CTL and Th2 clones tended to be higher than that of Th1 cells. Perforin mRNA and CTLA-1 mRNA were readily detectable in CTL and some Th2 clones. Expression of perforin and CLTA-1 mRNA correlated well with the capacity of these clones to lyse SRBC coated with anti-CD3 mAb. Our results show that some but not all Th2 clones have lytic characteristics similar to those of CD8+ CTL. Two mechanisms appear to contribute to their lytic process, one mechanism of lysis involves membrane damage that correlates with the expression of perforin mRNA; a second mechanism involves the induction of DNA degradation in the target cells. In contrast, some CD4+ effector cells appear to lack the capacity to lyse efficiently via the mechanism involving membrane damage and may only have the lytic activity associated with the capacity to induce DNA degradation.     

Protein kinase C theta regulates stability of the peripheral adhesion ring junction and contributes to the sensitivity of target cell lysis by CTL

Destruction of virus-infected cells by CTL is an extremely sensitive and efficient process. Our previous data suggest that LFA-1-ICAM-1 interactions in the peripheral supramolecular activation cluster (pSMAC) of the immunological synapse mediate formation of a tight adhesion junction that might contribute to the sensitivity of target cell lysis by CTL. Herein, we compared more (CD8(+)) and less (CD4(+)) effective CTL to understand the molecular events that promote efficient target cell lysis. We found that abrogation of the pSMAC formation significantly impaired the ability of CD8(+) but not CD4(+) CTL to lyse target cells despite having no effect of the amount of released granules by both CD8(+) and CD4(+) CTL. Consistent with this, CD4(+) CTL break their synapses more often than do CD8(+) CTL, which leads to the escape of the cytolytic molecules from the interface. CD4(+) CTL treatment with a protein kinase Ctheta inhibitor increases synapse stability and sensitivity of specific target cell lysis. Thus, formation of a stable pSMAC, which is partially controlled by protein kinase Ctheta, functions to confine the released lytic molecules at the synaptic interface and to enhance the effectiveness of target cell lysis.     

Fas-ligand-mediated lysis of erbB-2-expressing tumour cells by redirected cytotoxic T lymphocytes

A chimeric receptor, consisting of the single-chain variable (scFv) domains of an anti-erbB-2 mAb linked via a CD8 membrane-proximal hinge to the Fc receptor γ chain, was expressed in the mouse cytotoxic T lymphocyte (CTL) hybridoma cell line, MD45. This cell line was grafted with the additional specificity to recognise and bind erbB-2-expressing breast carcinoma target cells T47D, MCF-7 and BT-20 in a non-MHC-restricted manner. Tumour cell lysis was antigen-specific since erbB-2-negative tumours were insensitive to lysis by MD45-scFv-anti-erbB-2-γ clones, and lysis of erbB-2⁺ tumour targets was inhibited in the presence of an anti-erbB-2 mAb. Furthermore, target cell death correlated with the level of chimeric receptor expression on the effector MD45 subclones. Redirected MD45 CTL utilised Fas ligand to induce target cell death since soluble Fas-Fc fusion protein completely inhibited cytolysis. The sensitivity of tumour target cells to Fas ligand was further enhanced by treating them with interferon-γ, a regulator of Fas and downstream signalling components of the Fas pathway. Overall, this study has demonstrated the requirement for successful activation of Fas ligand function in conjunction with cytokine treatment for effective lysis of breast carcinoma target cells mediated by redirected CTL. Received: 23 July 1998 / Accepted: 5 October 1998     

High pro-inflammatory cytokine secretion and loss of high avidity cross-reactive cytotoxic T-cells during the course of secondary dengue virus infection

Background

Dengue is one of the most important human diseases transmitted by an arthropod vector and the incidence of dengue virus infection has been increasing – over half the world''s population now live in areas at risk of infection. Most infections are asymptomatic, but a subset of patients experience a potentially fatal shock syndrome characterised by plasma leakage. Severe forms of dengue are epidemiologically associated with repeated infection by more than one of the four dengue virus serotypes. Generally attributed to the phenomenon of antibody-dependent enhancement, recent observations indicate that T-cells may also influence disease phenotype.

Methods and Findings

Virus-specific cytotoxic T lymphocytes (CTL) showing high level cross reactivity between dengue serotypes could be expanded from blood samples taken during the acute phase of secondary dengue infection. These could not be detected in convalescence when only CTL populations demonstrating significant serotype specificity were identified. Dengue cross-reactive CTL clones derived from these patients were of higher avidity than serotype-specific clones and produced much higher levels of both type 1 and certain type 2 cytokines, many previously implicated in dengue pathogenesis.

Conclusion

Dengue serotype cross-reactive CTL clones showing high avidity for antigen produce higher levels of inflammatory cytokines than serotype-specific clones. That such cells cannot be expanded from convalescent samples suggests that they may be depleted, perhaps as a consequence of activation-induced cell death. Such high avidity cross-reactive memory CTL may produce inflammatory cytokines during the course of secondary infection, contributing to the pathogenesis of vascular leak. These cells appear to be subsequently deleted leaving a more serotype-specific memory CTL pool. Further studies are needed to relate these cellular observations to disease phenotype in a large group of patients. If confirmed they have significant implications for understanding the role of virus-specific CTL in pathogenesis of dengue disease.     

Positive and negative consequences of soluble Fas ligand produced by an antigen-specific CD4(+) T cell response in human carcinoma immune interactions.

The influence of a human CD4(+) T cell response in anti-carcinoma immune reactions remains largely uncharacterized. Here, we made use of a major histocompatibility complex (MHC) class-II-restricted, anti-ras oncogene-specific CD4(+) T cell line produced previously in vivo from a patient with metastatic carcinoma in a peptide-based phase I trial. Using this patient-derived T cell line as a potentially relevant cell type, we examined the consequences of the anti-carcinoma CD4(+) T cell response, with emphasis on specific lymphokines potentially important for the regulation of Fas/Fas ligand (FasL) interactions. Antigen (Ag)-specific CD4(+) T cells produced substantial amounts of IFN-gamma following recognition of MHC class-II-matched Ag-presenting cells expressing the cognate peptide. The IFN-gamma promoted significant upregulation of Fas on the surface of colon carcinoma cells and sensitized these targets to Fas-mediated apoptosis and Ag-specific CD8(+) cytotoxic T lymphocyte (CTL)-mediated lysis involving a Fas-based effector mechanism. Moreover, Ag-stimulated CD4(+) T cells secreted soluble FasL (sFasL), which induced the death of TNF-resistant/refractory colon, breast, and ovarian carcinoma cells. Interestingly, although CD4(+)-derived sFasL expressed cytotoxic activity, the recovery of carcinoma cells which resisted Fas-mediated lysis displayed enhanced metastatic ability in vivo, compared with the unselected parental population, in an athymic mouse model. Thus, a tumor-specific CD4(+) T cell response may have both positive and negative consequences in human carcinoma via the production of proinflammatory cytokines such as IFN-gamma and/or sFasL that may (1) improve or facilitate CTL-target engagement, contact-independent effector mechanisms, and the overall lytic outcome and (2) potentially select for Fas-resistant tumor cells that escape immune destruction, which may thus impact the metastatic process.     

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.     

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.     

Avidity dictates the lytic capacity of human cytolytic T lymphocyte clones with similar fine specificity against murine cells expressing HLA-B27 antigen

The role of the avidity of human CTL in the recognition and lysis of murine P815 cells expressing HLA-B27.1 Ag has been examined. Seven B27-specific alloreactive CTL clones were tested for their ability to lyse a B27.1+-P815 transfectant clone 1-7E, obtained after cotransfection of P815-HTR cells with HLA-B27.1 and human beta 2-microglobulin genes. The expression level of HLA-B27.1 on 1-7E cells was comparable to that on a human lymphoblastoid cell line, as determined by flow cytometry. Of the seven CTL clones used, CTL 1, 26, and 29 displayed the same fine specificity as established with a panel of target cells expressing six structurally different HLA-B27 variants. However, CTL 1 and 29 were of higher avidity than CTL 26, in that the lysis of human target cells by only this latter clone was inhibited by an anti-CD8 mAb. Based on the same criteria, CTL 2, 15, and 48 possessed the same or very similar fine specificity, but CTL 48 was of higher avidity than CTL 2 or 15. The seventh clone, CTL 40, was of a different fine specificity and its lysis of human target cells was also inhibited by the same anti-CD8 mAb. Only those clones whose lysis of human targets could not be inhibited by anti-CD8 antibody were able to lyse the 1-7E murine transfectants. These results indicate that, for human CTL clones with identical or very similar fine specificity, only those of higher avidity are able to lyse P815 murine cells expressing the HLA-B27 antigen. The lysis of HLA-B27.1+-murine transfectants by relevant clones was inhibited by anti-CD8 antibody. This result strongly suggests that the relative contribution of CD8 in stabilizing the interaction between human CTL and HLA-B27+-murine target cells is more significant than with human target cells.     

The requirements for triggering of lysis by cytolytic T lymphocyte clones. II. Cyclosporin A inhibits TCR-mediated exocytosis by only selectively inhibits TCR-mediated lytic activity by cloned CTL

TCR-mediated granule exocytosis, as measured by the release of serine esterase activity, has been implicated in the lytic process of Ag-specific CTL. Exocytosis appears to be the mechanism of release of other lysis-relevant molecules including cytotoxic lymphokines and proteins that have the capacity to induce membrane lesions as measured by the hemolysis of non-nucleated SRBC. In the studies presented here, we assessed the contribution of exocytosis and lymphokine production in CTL lysis of nucleated and non-nucleated target cells by using a panel of murine CTL clones. Ag-mediated activation of cytolysis, lymphokine production, and exocytosis could be mimicked by mAb against the TCR/CD3 complex, or by stimulation with the combination of PMA + calcium ionophore, which appear to bypass the TCR (neither PMA nor calcium ionophore alone induced these functions efficiently in our CD8+ CTL clones). Although lysis, IFN-gamma production and exocytosis of N-alpha-benzyloxycarbonyl-L-lysin esterase (BLTE) activity were induced by either stimulus, we were able to identify distinct activation requirements for each of these functions. We found that lymphokine production, exocytosis, and cytolysis could be selectively inhibited. Cycloheximide inhibited IFN-gamma production, but did not inhibit exocytosis of BLTE activity or cytolysis. In addition we showed that cyclosporine A (CsA) profoundly inhibited IFN-gamma production as well as exocytosis induced by stimulation through the Ag receptor or by PMA + calcium ionophore. In contrast, CsA had little or no effect on lysis of nucleated target cells that bear the relevant Ag. These findings indicate that our CTL clones can lyse target cells by a mechanism independent of exocytosis or (de novo) lymphokine production. To directly assess the capacity of our CTL clones to lyse target cells without inducing nuclear damage we developed a system of coating non-nucleated SRBC with anti-CD3 mAb for use as stimuli and as targets for lysis. We found that our cloned CTL were indeed activated to produce IFN-gamma by SRBC that were coated with anti-CD3 mAb, and, furthermore, they were able to lyse the SRBC in a short term cytolytic assay. Thus our CD8+ CTL are capable of lysing certain target cells by a mechanism independent of DNA degradation, presumably by inducing a membrane lesion. In addition, CsA did inhibit lysis of the non-nucleated SRBC targets as well as exocytosis of BLTE activity.(ABSTRACT TRUNCATED AT 400 WORDS)     

CD4+CD25+ T cells lyse antigen-presenting B cells by Fas-Fas ligand interaction in an epitope-specific manner

Suppression by regulatory T cells is now acknowledged to play a key role in the down-regulation of T cell responses to foreign and self Ags. In addition to the naturally occurring CD4(+)CD25(+) population, several subtypes of induced regulatory cells have been reported, but their mechanisms of action remain unclear. Conversely, cytotoxic CD4(+) cells that lyse cells presenting their cognate peptide have been described, but their potential role in immunoregulation remains to be delineated. A CD4(+) T cell line derived from BALB/c mice immunized with peptide 21-35, containing a major T cell epitope of a common allergen, Dermatophagoides pteronyssinus group 2 allergen, was found to lyse the Ag-presenting WEHI cell line via Fas-Fas ligand and only in the presence of the cognate peptide. Cytolytic activity was likewise shown for other T cell lines and occurred even after a single cycle of in vitro stimulation. Moreover, T cells that efficiently lysed WEHI cells were unresponsive to stimulation with their cognate Ag and were dependent on IL-2 for growth and survival, which was reflected in a constitutive expression of CD25 independently of activation status. Proliferating B cells were also killed by the CTLs. By lysing Ag-presenting B cells in an epitope-specific manner, the nonproliferating CTLs were shown to down-regulate the proliferation of bystander T cells. These data demonstrate that cytotoxic CD4(+)CD25(+) T cells that lack proliferation capacities have the potential to down-regulate an immune response by killing Ag-presenting B cells. This could represent an important and specific down-regulatory mechanism of secondary immune responses in vivo.     

Dengue virus-specific cross-reactive CD8+ human cytotoxic T lymphocytes

Stimulation with live dengue virus of peripheral blood mononuclear cells from a dengue virus type 4-immune donor generated virus-specific, serotype-cross-reactive, CD8+, class I-restricted cytotoxic T lymphocytes (CTL) capable of lysing dengue virus-infected cells and cells pulsed with dengue virus antigens of all four serotypes. These CTL lysed autologous fibroblasts infected with vaccinia virus-dengue virus recombinant viruses containing the E gene or several nonstructural dengue virus type 4 genes. These results demonstrate that both dengue virus structural and nonstructural proteins are targets for the cytotoxic T-cell-mediated immune response to dengue virus and suggest that serotype-cross-reactive CD8+ CTL may be important mediators of viral clearance and of virus-induced immunopathology during secondary dengue virus infections.     

The soluble viral glycoprotein of vesicular stomatitis virus efficiently sensitizes target cells for lysis by CD4+ T lymphocytes

The soluble glycoprotein Gs of vesicular stomatitis virus (VSV), at approximately 10(4) molecules per cell, sensitized target cells for lysis by clones of CD4+ cytolytic T lymphocytes (CTL). In addition to lysis, the clones responded by proliferation and interleukin-2 release. Targets sensitized by Gs competed effectively with VSV-infected cells for recognition. Immune cytolysis by these CD4+ CTLs was restricted by class II major histocompatibility complex (MHC) antigens and was specific to VSV. The specific class II MHC antigen which was restricting for each clone remained the same whether the targets were sensitized by infection with VSV or by exogenously added soluble antigen. Sensitization by Gs appeared to require prior processing because the antigen-presenting cells that were fixed prior to exposure to Gs failed to be recognized by the CTL clones. The high efficiency of this uptake and processing was suggested by the inability of Gs at concentrations up to 10(7) per cell to block superinfection by VSV or to effect the RNA-synthetic machinery of uninfected cells. Also, Gs failed to hemolyze sheep erythrocytes when there was hemolysis by virions or an amino-terminal peptide of the VSV glycoprotein. Extrapolation of these results to viral diseases was possible because soluble viral glycoproteins were naturally synthesized during many viral infections and class II MHC antigens were inducible in cells of nonlymphoid origin. Therefore, CD4+ CTLs may be important participants in increasing virus-induced pathology, especially among adjacent uninfected cells.     

Analysis of Murine CD8+ T-Cell Clones Specific for the Dengue Virus NS3 Protein: Flavivirus Cross-Reactivity and Influence of Infecting Serotype

Serotype-cross-reactive dengue virus-specific cytotoxic T lymphocytes (CTL) induced during a primary dengue virus infection are thought to play a role in the immunopathogenesis of dengue hemorrhagic fever (DHF) during a secondary dengue virus infection. Although there is no animal model of DHF, we previously reported that murine dengue virus-specific CTL responses are qualitatively similar to human dengue virus-specific CTL responses. We used BALB/c mice to study the specificity of the CTL response to an immunodominant epitope on the dengue virus NS3 protein. We mapped the minimal H-2K^d-restricted CTL epitope to residues 298 to 306 of the dengue type 2 virus NS3 protein. In short-term T-cell lines and clones, the predominant CD8⁺ CTL to this epitope in mice immunized with dengue type 2 virus or vaccinia virus expressing the dengue type 4 virus NS3 protein were cross-reactive with dengue type 2 or type 4 virus, while broadly serotype-cross-reactive CTL were a minority population. In dengue type 3 virus-immunized mice, the predominant CTL response to this epitope was broadly serotype cross-reactive. All of the dengue virus-specific CTL clones studied also recognized the homologous NS3 sequences of one or more closely related flaviviruses, such as Kunjin virus. The critical contact residues for the CTL clones with different specificities were mapped with peptides having single amino acid substitutions. These data demonstrate that primary dengue virus infection induces a complex population of flavivirus-cross-reactive NS3-specific CTL clones in mice and suggest that CTL responses are influenced by the viral serotype. These findings suggest an additional mechanism by which the order of sequential flavivirus infections may influence disease manifestations.     

Localization of Fas ligand in cytoplasmic granules of CD8+ cytotoxic T lymphocytes and natural killer cells: participation of Fas ligand in granule exocytosis model of cytotoxicity

Fas ligand (FasL) has been implicated in cytotoxic T lymphocyte (CTL)- and natural killer (NK) cell-mediated cytotoxicity. In the present study, we investigated the localization of FasL in murine CTL and NK cells. Immunocytochemical staining showed that FasL was stored in cytoplasmic granules of CD8+ CTL clones and in vivo activated CTL and NK cells, where perforin and granzyme A also resided. Immunoelectron microscopy revealed that FasL was localized on outer membrane of the cytoplasmic granules, while perforin was localized in internal vesicles. Western blot analysis showed that the membrane-type FasL of 40 kDa was stored in CD8+ CTL clones but not in CD4+ CTL clones. By utilizing a granule exocytosis inhibitor (TN16), we demonstrated that FasL translocated onto cell surface upon degranulation of anti-CD3-stimulated CD8+ CTL clones. Moreover, TN16 markedly inhibited the FasL-mediated cytotoxicity by CD8+ T cell clones and NK cells. These results suggested a substantial contribution of FasL to granule exocytosis-mediated target cell lysis by CD8+ CTL and NK cells.