Alpha beta TCR+ cells are a minimal fraction of peripheral CD8+ pool in MHC class I-deficient mice

MHC class I molecules play a role in the maintenance of the naive peripheral CD8+ T cell pool. The mechanisms of the peripheral maintenance and the life span of residual CD8+ cells present in the periphery of beta 2-microglobulin-deficient (beta 2m-/-) mice are unknown. We here show that very few CD8+ cells in beta 2m-/- mice coexpress CD8 beta, a marker of the thymus-derived CD8+ T cells. Most of the CD8 alpha+ cells express CD11c and can be found in beta 2m/RAG-2 double-deficient mice, demonstrating that these cells do not require rearranged Ag receptors for differentiation and survival and may be of dendritic cell lineage. Rare CD8 alpha+CD8 beta+ cells can be detected following in vivo alloantigenic stimulation 2 wk after the adult thymectomy. Selective MHC class I expression by bone marrow-derived cells does not lead to an accumulation of CD8 beta+ cells in beta 2m-/- mice. These findings demonstrate that 1) thymic export of CD8+ T cells in beta 2m-/- mice is reduced more severely than previously thought; 2) non-T cells expressing CD8 alpha become prominent when CD8+ T cells are virtually absent; 3) at least some beta 2m-/- CD8+ T cells have a life span in the periphery comparable to wild-type CD8+ cells; and 4) similar ligands induce positive selection in the thymus and survival of CD8+ T cells in the periphery.     

Functional characterization of MHC class II-restricted CD8+CD4- and CD8-CD4- T cell responses to infection in CD4-/- mice

Classical CD4(+) and CD8(+) T cells recognize Ag presented by MHC class II (MHCII) and MHC class I (MHCI), respectively. However, our results show that CD4(-/-) mice mount a strong, readily detectable CD8(+) T cell response to MHCII-restricted epitopes after a primary bacterial or viral infection. These MHCII-restricted CD8(+)CD4(-) T cells are more similar to classical CD8(+) T cells than to CD4(+) T cells in their expression of effector functions during a primary infection, yet they also differ from MHCI-restricted CD8(+) T cells by their inability to produce high levels of the cytolytic molecule granzyme B. After resolution of a primary infection, epitope-specific MHCII-restricted T cells in CD4(-/-) mice persist for a long period of time as memory T cells. Surprisingly, upon reinfection the secondary MHCII-restricted response in CD4(-/-) mice consists mainly of CD8(-)CD4(-) T cells. In contrast to CD8(+) T cells, MHCII-restricted CD8(-)CD4(-) T cells are capable of producing IL-2 in addition to IFN-gamma and thus appear to have attributes characteristic of CD4(+) T cells rather than CD8(+) T cells. Therefore, MHCII-restricted T cells in CD4(-/-) mice do not share all phenotypic and functional characteristics with MHCI-restricted CD8(+) T cells or with MHCII-restricted CD4(+) T cells, but, rather, adopt attributes from each of these subsets. These results have implications for understanding thymic T cell selection and for elucidating the mechanisms regulating the peripheral immune response and memory differentiation.     

Memory phenotype of CD8+ T cells in MHC class Ia-deficient mice

B6.K(b-)D(b-) mice are devoid of class Ia but express normal levels of class Ib molecules. They have low levels of CD8 T cells in both the thymus as well as peripheral T cell compartments. Although the percentage of splenic CD8 alpha alpha T cells is increased in these animals, approximately 90% of CD8 T cells are CD8 alpha beta. In contrast to B6 animals, most of the CD8 T cells from these mice have a memory phenotype (CD44(high)CD122(high) CD62L(low)) including both CD8 alpha beta and CD8 alpha alpha subsets. In the thymus of B6.K(b-)D(b-) animals, there is a decrease in the percentage of SP CD8 T cells, although most are CD44(low), similar to that seen in B6 mice. The spleens from day 1-old B6 and B6.K(b-)D(b-) mice have a relatively high proportion of CD44(high)CD62L(low) CD8 T cells. However, by day 28 most CD8 T cells in B6 mice have a naive phenotype while in B6.K(b-)D(b-) mice the memory phenotype remains. Unlike CD44(high) cells that are found in B6 animals, most CD44(high) cells from B6.K(b-)D(b-) mice do not secrete IFN-gamma rapidly upon activation. The paucity of CD8 T cells in B6.K(b-)D(b-) mice might be due in part to their inability to undergo homeostatic expansion. Consistent with this, we found that CD8 T cells from these animals expand poorly in X-irradiated syngeneic hosts compared with B6 CD8 T cells that respond to class Ia Ags. We examined homeostatic expansion of B6 CD8 T cells in single as well as double class Ia knockout mice and were able to estimate the fraction of cells reactive against class Ia vs class Ib molecules.     

MHC recognition by hapten-specific HLA-A2-restricted CD8+ CTL

T cell recognition by peptide-specific alphabeta TCRs involves not only recognition of the peptide, but also recognition of multiple molecular features on the surface of the MHC molecule to which the peptide has been bound. We have previously shown that TCRs that are specific for five different peptides presented by HLA-A2 recognize similar molecular features on the surface of the alpha1 and alpha2 helices of the HLA-A2 molecule. We next asked whether these same molecular features of the HLA-A2 molecule would be recognized by hapten-specific HLA-A2-restricted TCRs, given that hapten-specific T cells frequently show reduced MHC dependence/restriction. The results show that a panel of CD8+ CTL that are specific for the hapten DNP bound to two different peptides presented by HLA-A2 do the following: 1) show stringent MHC restriction, and 2) are largely affected by the same mutations on the HLA-A2 molecule that affected recognition by peptide-specific CTL. A small subset of this panel of CD8+ CTL can recognize a mutant HLA-A2 molecule in the absence of hapten. These data suggest that TCR recognition of a divergent repertoire of ligands presented by HLA-A2 is largely dependent upon common structural elements in the central portion of the peptide-binding site.     

Peripheral CD8+CD25+ T lymphocytes from MHC class II-deficient mice exhibit regulatory activity

We characterized CD8(+) T cells constitutively expressing CD25 in mice lacking the expression of MHC class II molecules. We showed that these cells are present not only in the periphery but also in the thymus. Like CD4(+)CD25(+) T cells, CD8(+)CD25(+) T cells appear late in the periphery during ontogeny. Peripheral CD8(+)CD25(+) T cells from MHC class II-deficient mice also share phenotypic and functional features with regulatory CD4(+)CD25(+) T cells: in particular, they strongly express glucocorticoid-induced TNFR family-related gene, CTLA-4 and Foxp3, produce IL-10, and inhibit CD25(-) T cell responses to anti-CD3 stimulation through cell contacts with similar efficiency to CD4(+)CD25(+) T cells. However, unlike CD4(+)CD25(+) T cells CD8(+)CD25(+) T cells from MHC class II-deficient mice strongly proliferate and produce IFN-gamma in vitro in response to stimulation in the absence of exogenous IL-2.     

Peripheral pool of CD8+ T-cells contains lymphocytes with antigen-specific receptors that recognize syngeneic MHC class II molecules

The capacity of T-lymphocytes to recognize "nonself" and tolerating "self" is formed as a result of positive and negative selection in the thymus. While obtaining and testing specificity of T-hybridomas, we demonstrated that the major part of peripheral pool of CD8+ T-lymphocytes carried receptors specific to "self" MHC class II molecules. Such an unexpected specificity of receptors has been found in some T-cell hybridomas produced by fusion of activated peripheral CD8+ T-lymphocytes with a tumor partner transfected by the coreceptor CD4 gene. The reactivity to "self" is not an experimental artifact due to an increased avidity of interaction of the hybridoma cells with antigen-presenting cells. Also, it is not an expression of reactivity of T-cells to superantigens, products of endogenous viruses of mouse breast cancer. The formation of a pool of such T-cells involves both cells with double receptor specificity and cells coexpressing two alpha-chains of T-cell receptor. Their appearance in the periphery can be due to the capacity of thymocytes differentiating in the direction of CD4+ cells to avoid negative selection via change of expression of coreceptor CD4 to CD8.     

CD8alpha+ and CD11b+ dendritic cell-restricted MHC class II controls Th1 CD4+ T cell immunity

The activation, proliferation, differentiation, and trafficking of CD4 T cells is central to the development of type I immune responses. MHC class II (MHCII)-bearing dendritic cells (DCs) initiate CD4(+) T cell priming, but the relative contributions of other MHCII(+) APCs to the complete Th1 immune response is less clear. To address this question, we examined Th1 immunity in a mouse model in which I-A(beta)(b) expression was targeted specifically to the DCs of I-A(beta)b-/- mice. MHCII expression is reconstituted in CD11b(+) and CD8alpha(+) DCs, but other DC subtypes, macrophages, B cells, and parenchymal cells lack of expression of the I-A(beta)(b) chain. Presentation of both peptide and protein Ags by these DC subsets is sufficient for Th1 differentiation of Ag-specific CD4(+) T cells in vivo. Thus, Ag-specific CD4(+) T cells are primed to produce Th1 cytokines IL-2 and IFN-gamma. Additionally, proliferation, migration out of lymphoid organs, and the number of effector CD4(+) T cells are appropriately regulated. However, class II-negative B cells cannot receive help and Ag-specific IgG is not produced, confirming the critical MHCII requirement at this stage. These findings indicate that DCs are not only key initiators of the primary response, but provide all of the necessary cognate interactions to control CD4(+) T cell fate during the primary immune response.     

MHC class I gene conversion mutations alter the CD8 T cell repertoire

MHC class I molecules are highly polymorphic within populations. This diversity is thought to be the result of selective maintenance of new class I alleles formed by gene conversion. It has been proposed that rare alleles are maintained by their ability to confer resistance to common pathogens. Investigation has focused on differences in the presentation of foreign Ags by class I alleles, but the majority of peptides presented by class I molecules are self peptides used in shaping the naive T cell repertoire. We propose that the key substrate for the natural selection of class I gene conversion variants is the diversity in immune potential formed by new alleles. We show that T cells compete with each other for niches in the thymus and spleen during development, and that competition between different clones is dramatically affected by class I mutations. We also show that peripheral naive T cells proliferate preferentially in the presence of the class I variant that directed T cell development. The data argue that class I gene conversion mutations dramatically affect both the development and the maintenance of the naive CD8 T cell repertoire.     

High avidity antigen-specific CTL identified by CD8-independent tetramer staining

Tetrameric MHC/peptide complexes are important tools for enumerating, phenotyping, and rapidly cloning Ag-specific T cells. It remains however unclear whether they can reliably distinguish between high and low avidity T cell clones. In this report, tetramers with mutated CD8 binding site selectively stain higher avidity human and murine CTL capable of recognizing physiological levels of Ag. Furthermore, we demonstrate that CD8 binding significantly enhances the avidity as well as the stability of interactions between CTL and cognate tetramers. The use of CD8-null tetramers to identify high avidity CTL provides a tool to compare vaccination strategies for their ability to enhance the frequency of high avidity CTL. Using this technique, we show that DNA priming and vaccinia boosting of HHD A2 transgenic mice fail to selectively expand large numbers of high avidity NY-ESO-1(157-165)-specific CTL, possibly due to the large amounts of antigenic peptide delivered by the vaccinia virus. Furthermore, development of a protocol for rapid identification of high avidity human and murine T cells using tetramers with impaired CD8 binding provides an opportunity not only to monitor expansion of high avidity T cell responses ex vivo, but also to sort high avidity CTL clones for adoptive T cell transfer therapy.     

Negative selection of Tcra-V8+CD8+ T cells by MHC class I molecules

Tcrb-V-specific positive and negative selection of T cells has been well documented. In contrast, nothing is known about Tcra-V-specific selection. Using Tcra-V8-specific KT50 antibody Tcra-V8-specific selection of T cells has been examined. The CD8⁺ T cell subpopulation bearing Tcra-V8 are shown to be negatively selected by major histocompatibility complex (MHC) class I H-2K^d and H-2D^d/L^d molecules. Furthermore, percentages of these T cells are also influenced by Tcra-V haplotypes. Involvement of non-H-2 self (super)antigens in this MHC class I restricted negative selection, however, remains to be determined.     

An MHC class Ib-restricted CD8+ T cell response to lymphocytic choriomeningitis virus

Conventional MHC class Ia-restricted CD8(+) T cells play a dominant role in the host response to virus infections, but recent studies indicate that T cells with specificity for nonclassical MHC class Ib molecules may also participate in host defense. To investigate the potential role of class Ib molecules in anti-viral immune responses, K(b-/-)D(b-/-)CIITA(-/-) mice lacking expression of MHC class Ia and class II molecules were infected with lymphocytic choriomeningitis virus (LCMV). These animals have a large class Ib-selected CD8(+) T cell population and they were observed to mediate partial (but incomplete) virus clearance during acute LCMV infection as compared with K(b-/-)D(b-/-)β(2)-microglobulin(-/-) mice that lack expression of both MHC class Ia and class Ib molecules. Infection was associated with expansion of splenic CD8(+) T cells and induction of granzyme B and IFN-γ effector molecules in CD8(+) T cells. Partial virus clearance was dependent on CD8(+) cells. In vitro T cell restimulation assays demonstrated induction of a population of β(2)-microglobulin-dependent, MHC class Ib-restricted CD8(+) T cells with specificity for viral Ags and yet to be defined nonclassical MHC molecules. MHC class Ib-restricted CD8(+) T cell responses were also observed after infection of K(b-/-)D(b-/-)mice despite the low number of CD8(+) T cells in these animals. Long-term infection studies demonstrated chronic infection and gradual depletion of CD8(+) T cells in K(b-/-)D(b-/-)CIITA(-/-) mice, demonstrating that class Ia molecules are required for viral clearance. These findings demonstrate that class Ib-restricted CD8(+) T cells have the potential to participate in the host immune response to LCMV.     

Helper T lymphocytes which recognize the MHC class I alloantigens in vivo are CD4+CD8-1

To determine the CD4 or CD8 phenotype of the Th lymphocyte which recognizes in vivo the MHC class I alloantigens, B10 recombinant mice were treated with anti-CD8 or anti-CD4 mAb and immunized with lymphoid cells from donors differing in the K or D region of the MHC. Alloantibodies were evaluated by a 51Cr-release assay or by indirect immunofluorescence. The production of IgG anti-Dd and anti-Kk alloantibodies was increased by the deletion of the CD8+ and absent in mice depleted of the CD4+ subset. These experiments indicate that the helper influence elicited by the recognition of a MHC class I alloantigen in vivo is due to cells of the CD4+CD8- phenotype.     

Nonconventional CD8+ T cell responses to Listeria infection in mice lacking MHC class Ia and H2-M3

CD8(+) T cells restricted to MHC class Ib molecules other than H2-M3 have been shown to recognize bacterial Ags. However, the contribution of these T cells to immune responses against bacterial infection is not well defined. To investigate the immune potential of MHC class Ib-restricted CD8(+) T cells, we have generated mice that lack both MHC class Ia and H2-M3 molecules (K(b-/-)D (b-/-)M3(-/-)). The CD8(+) T cells present in K(b-/-)D (b-/-)M3(-/-) mice display an activated surface phenotype and are able to secrete IFN-γ rapidly upon anti-CD3 and anti-CD28 stimulation. Although the CD8(+) T cell population is reduced in K(b-/-)D (b-/-)M3(-/-) mice compared with that in K(b-/-)D (b-/-) mice, this population retains the capacity to expand significantly in response to primary infection with the bacteria Listeria monocytogenes. However, K(b-/-)D (b-/-)M3(-/-) CD8(+) T cells do not expand upon secondary infection, similar to what has been observed for H2-M3-restricted T cells. CD8(+) T cells isolated from Listeria-infected K(b-/-)D (b-/-)M3(-/-) mice exhibit cytotoxicity and secrete proinflammatory cytokines in response to Listeria-infected APCs. These T cells are protective against primary Listeria infection, as Listeria-infected K(b-/-)D (b-/-)M3(-/-) mice exhibit reduced bacterial burden compared with that of infected β(2)-microglobulin-deficient mice that lack MHC class Ib-restricted CD8(+) T cells altogether. In addition, adoptive transfer of Listeria-experienced K(b-/-)D (b-/-)M3(-/-) splenocytes protects recipient mice against subsequent Listeria infection in a CD8(+) T cell-dependent manner. These data demonstrate that other MHC class Ib-restricted CD8(+) T cells, in addition to H2-M3-restricted T cells, contribute to antilisterial immunity and may contribute to immune responses against other intracellular bacteria.     

The predominance of CD8+ T cells after infection with measles virus suggests a role for CD8+ class I MHC-restricted cytotoxic T lymphocytes (CTL) in recovery from measles. Clonal analyses of human CD8+ class I MHC-restricted CTL

Stimulation of PBMC, in children recovering from acute measles, with autologous EBV-transformed and measles virus (MV)-infected lymphoblastoid cell lines (B-LCL) expanded primarily MV-specific CD8+ T cells. A large number of CD8+ T cell clones were obtained either by passaging of bulk cultures at limiting dilutions or by direct cloning of PBMC without previous stimulation in bulk culture. The MV-specific CD8+ T cell clones responding in a proliferative and a CTL assay were found to be class I MHC restricted. In contrast, CD4+ MV-specific T cell clones, which were generated by the same protocol, recognized MV in association with class II MHC molecules. Analysis of processing requirements for Ag presentation to CD8+ and CD4+ T cell clones, measured by the effect of chloroquine in a proliferative T cell response, revealed that both types of T cells recognized MV Ag processed via the endogenous/cytoplasmic pathway. Thus, these studies indicate that, as in most other viral infections and in contrast to previous suggestions, the class I MHC-restricted CTL response by CD8+ T cells may be an important factor in the control and elimination of MV infection. Therefore, the role proposed for CD4+ class II-restricted T cells in recovery from measles needs to be reevaluated.     

Potent cytolytic response by a CD8+ CTL clone to multiple peptides from the same protein in association with an allogeneic class I MHC molecule

CTL clone 2C recognizes the allogeneic class I MHC molecule L(d) in association with peptides derived from alpha-ketoglutarate dehydrogenase (oxoglutarate dehydrogenase (OGDH)), a ubiquitous intracellular protein. One of these peptides, QLSPFPFDL (QL9), elicits more vigorous cytolytic responses than two previously identified naturally processed peptides with overlapping sequences, LSPFPFDL (p2Ca) and VAITRIEQLSPFPFDL (p2Cb), from OGDH. In this study, we show that QL9 forms a more stable complex with cell surface L(d) than does p2Ca or p2Cb and is processed from the longer, naturally occurring peptide p2Cb by 20S proteosomes in vitro. The N-terminal cyclized pyroglutaminyl QL9 (pyroQL9), a form of QL9 to which it is converted at the low pH used for peptide isolation from tissue extracts, is even more active than QL9 in cytotoxicity assays with 2C CTL. Overall, the results indicate that along with the abundant natural peptides p2Ca and p2Cb, the QL9 and other OGDH peptides of various lengths, sharing a conserved C-terminal sequence, are also processed and presented with L(d) as allogeneic ligands for T cells expressing 2C TCR. All these peptides, each available in a low amount, could act in concert at the cell surface, resulting in a high density of cognate ligands that accounts for the exceptionally potent cytolytic response by 2C CTL.     

Depletion of CD8+ cells exacerbates organ-specific autoimmune diseases induced by CD4+ T cells in semiallogeneic hosts with MHC class II disparity

Autoimmune diseases are known to be induced in some donor-recipient combinations of mice undergoing the graft-vs-host reaction (GVHR). In this paper, we report on the development of primary biliary cirrhosis (PBC)-like hepatic lesions and also on pancreatic insulitis in (B6 x bm12)F1 mice injected with B6 CD4+ T cells. At the sites of these lesions, cellular infiltration around ductal structure was observed. Immunohistochemical studies revealed that both CD4+ and CD8+ T cells were present in the lesions of the liver and pancreas. To clarify the role of the CD8+ T cells, which were probably of host origin, we used a mAb against the Lyt-2 molecule. Both the PBC-like hepatic lesions and pancreatic insulitis were exacerbated by eliminating CD8+ T cells from mice with MHC class II GVHR. Also, autoantibodies against the pyruvate dehydrogenase-E2 component, which has been recently found to contain an immunodominant site (autoepitope) for B cell reactivity in patients with PBC, were detected in the sera of these mice by ELISA and their presence was confirmed by immunoblotting procedures. Our findings suggest that similar mechanisms as in GVHR caused by MHC class II disparity are active in the development of PBC. It should also be noted that, in addition to the hepatic lesions, insulitis closely resembling that seen in the nonobese diabetic mouse was induced in our experimental system. The results suggest that our model provides a unique opportunity to study organ-specific autoimmune diseases. Because the effector in our experimental system was defined to be CD4+ T cells responding to Iabm12 Ag, our findings support the hypothesis that an excessive immune response directed against Ia Ag can produce autoimmune disease.     

A model for CD8+ CTL tumor immunosurveillance and regulation of tumor escape by CD4 T cells through an effect on quality of CTL.

Understanding immune mechanisms influencing cancer regression, recurrence, and metastasis may be critical to developing effective immunotherapy. Using a tumor expressing HIV gp160 as a model viral tumor Ag, we found a growth-regression-recurrence pattern, and used this to investigate mechanisms of immunosurveillance. Regression was dependent on CD8 T cells, and recurrent tumors were resistant to CTL, had substantially reduced expression of epitope mRNA, but retained the gp160 gene, MHC, and processing apparatus. Increasing CTL numbers by advance priming with vaccinia virus expressing gp160 prevented only the initial tumor growth but not the later appearance of escape variants. Unexpectedly, CD4 cell depletion protected mice from tumor recurrence, whereas IL-4 knockout mice, deficient in Th2 cells, did not show this protection, and IFN-gamma knockout mice were more susceptible. Purified CD8 T cells from CD4-depleted mice following tumor regression had more IFN-gamma mRNA and lysed tumor cells without stimulation ex vivo, in contrast to CD4-intact mice. Thus, the quality as well as quantity of CD8+ CTL determines the completeness of immunosurveillance and is controlled by CD4 T cells but not solely Th2 cytokines. This model of immunosurveillance may indicate ways to enhance the efficacy of surveillance and improve immunotherapy.     

Detection and enrichment of antigen-specific CD4+ and CD8+ T cells based on cytokine secretion

The Cytokine Secretion Assay is an innovative method for analysing and enriching live cytokine-secreting cells. In this assay, a cytokine affinity matrix is built on the cell plasma membrane, which traps cytokines produced by the cell in response to specific stimuli. The specifically bound cytokine is then detected, and the cells optionally enriched, using fluorochrome-conjugated cytokine-specific antibodies and magnetic microbeads. This method allows extremely detailed phenotyping of live cells and the detection of cytokine responses at very low frequencies. Here, the latest cell staining and separation procedures are reviewed, with particular reference to the best application of the technology and troubleshooting in a variety of different situations.     

Susceptibility of astrocytes to class I MHC antigen-specific cytotoxicity

Cell-mediated immune mechanisms contribute to tissue injury within the central nervous system (CNS) in a number of experimental diseases, including experimental allergic encephalomyelitis and some viral infections, and may mediate lesion formation in multiple sclerosis. We investigated the conditions under which murine astrocytes can become susceptible targets of cytotoxic T cells. We demonstrate that mouse astrocytes in vitro can be susceptible targets of class I major histocompatibility complex (MHC)-specific cytotoxicity mediated by L3 cytotoxic T lymphocytes (CTL). Expression of appropriate class I MHC antigen on the astrocytes is a requirement, because only cells bearing the H-2d phenotype are susceptible to lysis by L3 cells. BALB/c-H-2dm2 astrocytes lacking the specific determinant recognized by L3 cells are not susceptible to lysis. Astrocyte lysis can, however, occur under culture conditions in which MHC antigen expression is immunocytochemically low or undetectable. Cytolysis can be inhibited by pretreatment of the effector L3 cells with either anti-Lyt-2 monoclonal antibody (mAb) or anti-clonotypic mAb and by preincubation of the glial target cells with an appropriate anti-H-2 antibody (anti-H-2Ld). mAb to lymphocyte function-associated antigen does not inhibit cytotoxicity of the L3 clone against glial cells. Knowledge regarding the role of CTL within the CNS, including the surface molecules involved in glial cell lysis, could further the development of immunotherapies designed to effect immune reactivity within the CNS.     

Characterization of the Fas ligand/Fas-dependent apoptosis of antiretroviral, class I MHC tetramer-defined, CD8+ CTL by in vivo retrovirus-infected cells

C57BL/6 (B6; H-2(b)) mice mount strong AKR/Gross murine leukemia virus (MuLV)-specific CD8(+) CTL responses to the immunodominant K(b)-restricted epitope, KSPWFTTL, of endogenous AKR/Gross MuLV. In sharp contrast, spontaneous virus-expressing AKR.H-2(b) congenic mice are low/nonresponders for the generation of AKR/Gross MuLV-specific CTL. Furthermore, when viable AKR.H-2(b) spleen cells are cocultured with primed responder B6 antiviral precursor CTL, the AKR.H-2(b) cells function as "veto" cells that actively mediate the inhibition of antiviral CTL generation. AKR.H-2(b) veto cell inhibition is virus specific, MHC restricted, contact dependent, and mediated through veto cell Fas ligand/responder T cell Fas interactions. In this study, following specific priming and secondary in vitro restimulation, antiretroviral CD8(+) CTL were identified by a labeled K(b)/KSPWFTTL tetramer and flow cytometry, enabling direct visualization of AKR.H-2(b) veto cell-mediated depletion of these CTL. A 65-93% reduction in the number of B6 K(b)/KSPWFTTL tetramer(+) CTL correlated with a similar reduction in antiviral CTL cytotoxicity. Addition on sequential days to the antiviral CTL restimulation cultures of either 1) AKR.H-2(b) veto cells or 2) a blocking Fas-Ig fusion protein (to cultures also containing AKR.H-2(b) veto cells) to block inhibition demonstrated that AKR.H-2(b) veto cells begin to inhibit B6 precursor CTL/CTL expansion during days 2 and 3 of the 6-day culture. Shortly thereafter, a high percentage of B6 tetramer(+) CTL cocultured with AKR.H-2(b) veto cells was annexin V positive and Fas(high), indicating apoptosis as the mechanism of veto cell inhibition. Experiments using the irreversible inhibitor emetine demonstrated that AKR.H-2(b) cells had to be metabolically active and capable of protein synthesis to function as veto cells. Of the tetramer-positive CTL that survived veto cell-mediated apoptosis, there was no marked skewing from the preferential usage of Vbeta4, 8.1/8.2, and 11 TCR normally observed. These findings provide further insight into the complexity of host/virus interactions and suggest a fail-safe escape mechanism by virus-infected cells for epitopes residing in critical areas of viral proteins that cannot accommodate variations of amino acid sequence.