Clonal anergy is maintained independently of T cell proliferation

Ag encounter in the absence of proliferation results in the establishment of T cell unresponsiveness, also known as T cell clonal anergy. Anergic T cells fail to proliferate upon restimulation because of the inability to produce IL-2 and to properly regulate the G(1) cell cycle checkpoint. Because optimal TCR and CD28 engagement can elicit IL-2-independent cell cycle progression, we investigated whether CD3/CD28-mediated activation of anergic T cells could overcome G(1) cell cycle block, drive T cell proliferation, and thus reverse clonal anergy. We show here that although antigenic stimulation fails to elicit G(1)-to-S transition, anti-CD3/CD28 mAbs allow proper cell cycle progression and proliferation of anergic T cells. However, CD3/CD28-mediated cell division does not restore Ag responsiveness. Our data instead indicate that reversal of clonal anergy specifically requires an IL-2-dependent, rapamycin-sensitive signal, which is delivered independently of cell proliferation. Thus, by tracing proliferation and Ag responsiveness of individual cells, we show that whereas both TCR/CD28 and IL-2-generated signals can drive T cell proliferation, only IL-2/IL-2R interaction regulates Ag responsiveness, indicating that proliferation and clonal anergy can be independently regulated.     

Antagonistic roles for CTLA-4 and the mammalian target of rapamycin in the regulation of clonal anergy: enhanced cell cycle progression promotes recall antigen responsiveness.

CD4(+) T cells that undergo multiple rounds of cell division during primary Ag challenge in vivo produce IL-2 on secondary Ag rechallenge, whereas cells that fail to progress through the cell cycle are anergic to restimulation. Anti-CTLA-4 mAb treatment during primary Ag exposure increases cell cycle progression and enhances recall Ag responsiveness; however, simultaneous treatment with rapamycin, an inhibitor of the mammalian target of rapamycin and potent antiproliferative agent, prevents both effects. The data suggest that cell cycle progression plays a primary role in the regulation of recall Ag responsiveness in CD4(+) T cells in vivo. CTLA-4 molecules promote clonal anergy development only indirectly by limiting cell cycle progression during the primary response.     

CD25+Foxp3+ regulatory T cells facilitate CD4+ T cell clonal anergy induction during the recovery from lymphopenia

T cell clonal anergy induction in lymphopenic nu/nu mice was found to be ineffective. Exposure to a tolerizing peptide Ag regimen instead induced aggressive CD4(+) cell cycle progression and increased Ag responsiveness (priming). Reconstitution of T cell-deficient mice by an adoptive transfer of mature peripheral lymphocytes was accompanied by the development of a CD25(+)Foxp3(+)CTLA-4(+)CD4(+) regulatory T cell population that acted to dampen Ag-driven cell cycle progression and facilitate the induction of clonal anergy in nearby responder CD25(-)CD4(+) T cells. Thus, an early recovery of CD25(+) regulatory T cells following a lymphopenic event can prevent exuberant Ag-stimulated CD4(+) cell cycle progression and promote the development of clonal anergy.     

IL-2 unresponsiveness in anergic CD4+ T cells is due to defective signaling through the common gamma-chain of the IL-2 receptor

Repeated administration of the superantigen staphylococcal enterotoxin A to mice transduces a state of anergy in the CD4+ T cell compartment, characterized by inhibition of IL-2 production and clonal expansion in vivo. In contrast to what has been reported on anergic T cell clones in vitro, culture of in vivo anergized CD4+ T cells in the presence of exogenous IL-2 did not overcome the block in responsiveness. In this study, we demonstrate that CD4+ T cells from mice anergized with staphylococcal enterotoxin A also exhibit a reduced proliferative capacity in response to IL-7 and IL-15, cytokines that share a common gamma-chain with the IL-2R. Flow-cytometric analysis revealed only modest changes in the expression of the different IL-2R chains. In a number of experiments, our results also provide evidence that excludes a major role of the IL-2R alpha-chain in this system. According to these results, the inability of anergic cells to respond to IL-2 is not mainly due to a down-regulation of the high affinity IL-2R, but to a perturbation in intracellular signaling. Our study confirmed that the activation and tyrosine phosphorylation of Janus-associated kinase 3 and STAT5 were considerably weaker after anergy induction. Moreover, anergic CD4+ T cells showed significantly reduced DNA-binding ability to STAT5-specific elements. Taken together, we suggest that the observed IL-2 unresponsiveness in anergic CD4+ T cells could be due to a defect in signaling through the common gamma-chain of the IL-2R.     

Promotion of human T lymphocyte proliferation by IL-4

The capacity of human rIL-4 to support the proliferation of mitogen-stimulated T cells directly as well as by increasing IL-2 production or enhancing IL-2 responsiveness was investigated. IL-4 augmented proliferation of T cells stimulated with PHA, Con A, immobilized mAb to the CD3 molecular complex (OKT3), or PMA. IL-4 increased the number of mitogen-stimulated cells entering the cell cycle as well as enhancing ongoing proliferation of mitogen-activated lymphoblasts. Facilitation of initial activation by IL-4 was not inhibited by mAb to the p55 component of the IL-2R, anti-Tac, and, therefore, was not dependent on endogenous IL-2 activity. However, IL-4-mediated enhancement of ongoing T cell proliferation stimulated by PHA or OKT3 was partially but not completely blocked by anti-Tac. Analysis of the supernatants from PHA-stimulated T cell cultures indicated that IL-4 increased the production of IL-2 by mitogen-activated cells. Moreover, IL-4 increased the amount of IL-2 mRNA that accumulated in mitogen-stimulated T cells. In addition, IL-4 markedly augmented IL-2R expression by PHA-stimulated T cells. Although IL-4 promoted ongoing DNA synthesis of mitogen-stimulated T cells in an IL-2-dependent manner, it was also able to sustain their proliferation directly. Thus, IL-4 supported proliferation of PMA-activated T cells in a manner that was not inhibited by anti-Tac. Furthermore, IL-4 could augment proliferation and IL-2R expression of T cells stimulated with PHA in the presence of cyclosporin A, which blocks endogenous cytokine production or anti-Tac. Finally, IL-4 was noted to enhance proliferation of both CD4+ and CD8+ T cell subsets. The results indicate that IL-4 enhances proliferation of mitogen-activated human T cells by a number of mechanisms, including the direct promotion of cell cycle entry and subsequent DNA synthesis, enhanced production of IL-2, and increased responsiveness to IL-2 in part by up-regulation of IL-2R expression.     

CD40 ligand trimer and IL-12 enhance peripheral blood mononuclear cells and CD4+ T cell proliferation and production of IFN-gamma in response to p24 antigen in HIV-infected individuals: potential contribution of anergy to HIV-specific unresponsiveness

It has been suggested that CD4+ T cell proliferative responses to HIV p24 Ag may be important in the control of HIV infection. However, these responses are minimal or absent in many HIV-infected individuals. Furthermore, while in vitro and in vivo responses to non-HIV recall Ags improve upon administration of highly active antiretroviral therapy, there does not appear to be a commensurate enhancement of HIV-specific immune responses. It is possible that CD4+ p24-specific T cells are deleted early in the course of infection. However, it is also possible that a discrete unresponsiveness, or anergy, contributes to the lack of proliferation to p24. To evaluate the possible contribution of unresponsiveness to the lack of CD4+ T cell proliferation to p24 in HIV-infected individuals, we attempted to overcome unresponsiveness. CD40 ligand trimer (CD40LT) and IL-12 significantly increased PBMC and CD4+ T cell proliferative responses to p24 Ag in HIV-infected, but not uninfected, individuals. No increase in proliferative response to CMV Ag was observed. CD40LT exerted its effect through B7-CD28-dependent and IL-12- and IL-15-independent mechanisms. Finally, the increase in proliferation with CD40LT and IL-12 was associated with an augmented production of IFN-gamma in most, but not all, individuals. These data suggest the possible contribution of HIV-specific unresponsiveness to the lack of CD4+ T cell proliferation to p24 Ag in HIV-infected individuals and that clonal deletion alone does not explain this phenomenon. They also indicate the potential for CD40LT and IL-12 as immune-based therapies for HIV infection.     

Homeostatic proliferation as an isolated variable reverses CD8+ T cell anergy and promotes tumor rejection

Although recent work has suggested that lymphopenia-induced homeostatic proliferation may improve T cell-mediated tumor rejection, there is little direct evidence isolating homeostatic proliferation as an experimental variable, and the mechanism by which improved antitumor immunity occurs via homeostatic proliferation is poorly understood. An adoptive transfer model was developed in which tumor-specific 2C/RAG2(-/-) TCR transgenic CD8+ T cells were introduced either into the lymphopenic environment of RAG2(-/-) mice or into P14/RAG2(-/-) mice containing an irrelevant CD8+ TCR transgenic population. RAG2(-/-), but not P14/RAG2(-/-) recipients supported homeostatic proliferation of transferred T cells as well as tumor rejection. Despite absence of tumor rejection in P14/RAG2(-/-) recipients, 2C cells did become activated, as reflected by CFSE dilution and CD44 up-regulation. However, these cells showed poor IFN-gamma and IL-2 production upon restimulation, consistent with T cell anergy and similar to the hyporesponsiveness induced by administration of soluble peptide Ag. To determine whether homeostatic proliferation could uncouple T cell anergy, anergic 2C cells were transferred into RAG(-/-) recipients, which resulted in vigorous homeostatic proliferation, recovery of IL-2 production, and acquisition of the ability to reject tumors. Taken together, our data suggest that a major mechanism by which homeostatic proliferation supports tumor rejection is by maintaining and/or re-establishing T cell responsiveness.     

Antigen receptor-mediated anergy in resting T lymphocytes and T cell clones. Correlation with lymphokine secretion patterns.

The goal of these studies was to define the stimuli and factors that control the induction of anergy in unimmunized resting T lymphocytes. Initial experiments, aimed at establishing the system, showed that exposure of Th1 but not Th2 clones to immobilized anti-CD3 leads to a block in autocrine growth factor production and proliferation upon subsequent restimulation with Ag+APC. Anergy is not prevented by accessory cells, suggesting that this model of T cell tolerance may be due to receptor-mediated inhibitory signals, independent of costimulatory molecules. Culture of small (resting) unimmunized T lymphocytes with anti-CD3 +/- IL-2 induces unresponsiveness to restimulation with anti-CD3, but culture with anti-CD3+IL-4, which stimulates the differentiation of resting cells into IL-4 producers, does not induce anergy. Thus, IL-4-producing clones and bulk populations of IL-4-producing T cells are resistant to Ag receptor-mediated inhibitory stimuli. These results provide experimental models for studying the mechanisms of anergy in normal, unselected, mature T cells, and demonstrate fundamental similarities between cloned cell lines and unimmunized T lymphocytes in the induction of anergy.     

The poststimulation program of CD4 versus CD8 T cells (death versus activation-induced nonresponsiveness)

Both CD8 and CD4 T cells undergo autocrine IL-2-induced proliferation and clonal expansion following stimulation with Ag and costimulation. The CD8 T cell response is transient because the cells rapidly become activation-induced nonresponsive (AINR) and exhibit split anergy. In these cells, the capacity for IL-2 production is lost, but TCR-mediated IFN-gamma production and cytotoxicity are maintained. At this point, the CTL become dependent on IL-2 provided by CD4 Th cells for continued expansion. If IL-2 is available to support expansion for a brief period, AINR is reversed and the cells regain the ability to produce IL-2. In this study, we show that CD4 T cells do not become AINR, but instead are rendered susceptible to Fas-mediated activation-induced cell death following stimulation through TCR and CD28. Using z-VAD-fmk or anti-Fas ligand mAb to inhibit cell death, we demonstrate that previously activated CD4 T cells retain the ability to up-regulate c-Jun N-terminal kinase activity and IL-2 mRNA levels upon TCR engagement and no longer require costimulation. This rewiring of signaling pathways is similar to that seen following reversal of AINR in CD8 T cells. Thus, CD8 and CD4 T cells appear to use distinct mechanisms, AINR and activation-induced cell death, respectively, to limit excessive clonal expansion following a productive response, while permitting important effector functions to be expressed.     

The roles of IL-12 in providing a third signal for clonal expansion of naive CD8 T cells

Stimulation of an effective in vitro or in vivo response by naive CD8 T cells requires three signals: TCR engagement, costimulation/IL-2, and a third signal that can be provided by IL-12. In addition to being required for acquisition of cytolytic function, IL-12 is required for optimal IL-2-dependent proliferation and clonal expansion. In experiments examining in vitro stimulation of naive CD8 T cells, IL-12 is shown to stimulate expression of the IL-2R alpha-chain (CD25) to much higher levels than are reached in response to just TCR and costimulation and/or IL-2. In addition, high CD25 expression is substantially prolonged in the presence of IL-12. As a consequence, the cells proliferate more effectively in response to low levels of IL-2. Examination of adoptively transferred TCR transgenic CD8 T cells responding to peptide Ag confirmed that IL-12 up-regulates CD25 in vivo, even when B7-mediated costimulation is largely blocked. TCR- and IL-2-dependent proliferation of CD8 T cells from mice deficient in CD25 was also found to increase in the presence of IL-12, indicating that CD25 up-regulation is not the only mechanism by which IL-12 increases clonal expansion of the cells. IL-2 and IL-12 both act to increase expression of both CD25 and the IL-12R, thus providing positive cross-regulation of receptor expression. These results suggest that when cross-priming dendritic cells present class I/Ag and costimulatory ligands, and produce IL-12, naive CD8 T cells will begin to produce IL-2 and both receptors will be optimally up-regulated to insure that an effective response is generated.     

Inhibition of cell cycle progression by rapamycin induces T cell clonal anergy even in the presence of costimulation

Costimulation (signal 2) has been proposed to inhibit the induction of T cell clonal anergy by either directly antagonizing negative signals arising from TCR engagement (signal 1) or by synergizing with signal 1 to produce IL-2, which in turn leads to proliferation and dilution of negative regulatory factors. To better define the cellular events that lead to the induction of anergy, we used the immunosuppressive agent rapamycin, which blocks T cell proliferation in late G1 phase but does not affect costimulation-dependent IL-2 production. Our data demonstrate that full T cell activation (signal 1 plus 2) in the presence of rapamycin results in profound T cell anergy, despite the fact that these cells produce copious amounts of IL-2. Similar to conventional anergy (induction by signal 1 alone), the rapamycin-induced anergic cells show a decrease in mitogen-activated protein kinase activation, and these cells can be rescued by culture in IL-2. Interestingly, the rapamycin-induced anergic cells display a more profound block in IL-3 and IFN-gamma production upon rechallenge. Finally, in contrast to rapamycin, full T cell activation in the presence of hydroxyurea (which inhibits the cell cycle in early S phase) did not result in anergy. These data suggest that it is neither the direct effect of costimulation nor the subsequent T cell proliferation that prevents anergy induction, but rather the biochemical events that occur upon progression through the cell cycle from G1 into S phase.     

A polyclonal model for B cell tolerance. I. Fc-dependent and Fc-independent induction of nonresponsiveness by pretreatment of normal splenic B cells with anti-Ig.

We have developed a simple and adaptable, polyclonal model for B cell nonresponsiveness that is based on the inhibitory activity of anti-Ig as a surrogate for Ag. In our system the induction phase (treatment with anti-Ig) is separated from the challenge phase (Ag or mitogen), so that the critical events in each phase can be evaluated. Our results show that T cell-depleted B cells precultured for 18 to 24 h with rabbit anti-Ig reagents are rendered unresponsive to challenge with either Ag, fluorescein coupled to Brucella abortus (FL-BA), or mitogen (LPS). This state of nonresponsiveness (anergy) is reflected by an inhibition of a prototype response to the fluorescein hapten, as well as total Ig and IgG synthesis, but no reduction in proliferation to LPS. Interestingly, mitogen-induced polyclonal antibody formation was consistently reduced by 90% by treatment with either F(ab')2 or intact IgG anti-Ig. In contrast, the Ag-driven (FL-BA) response of pretreated B cells was inhibited by only 50 to 70%. Moreover, the latter effect usually required pretreatment with intact IgG anti-Ig, a result that suggests the importance of an Fc-dependent negative signal affecting the B cell's response to FL-BA. Furthermore, pretreatment and coculture of B cells with IL-4 blocked the Fc-dependent inhibition of the FL-BA responsiveness. These results, as well as kinetics experiments establishing a 4-h latent period, suggest that simple blocking of surface Ig receptor on target B cells is not responsible for the induction of anergy. Pretreated B cells displayed unique phenotypic changes after treatment with anti-Ig, including a diminution of Thy-1 expression in response to LPS + IL-4, as well as a reduction in membrane IgM and J11d expression (i.e., they were IgMlo, IgDmed, and J11dlo, as recently reported for anergic B cells in transgenic mice). These results suggest that B cell anergy can be induced in mature B cells by both Fc-dependent and Fc-independent processes that lead to unique phenotypic changes and may reflect egress from G0 in the absence of T cell help. The significance of these changes to tolerance mechanisms is discussed.     

p59fyn (Fyn) promotes the survival of anergic CD4-CD8- alpha beta TCR+ cells but negatively regulates their proliferative response to antigen stimulation

T cell anergy is characterized by alterations in TCR signaling that may play a role in controlling the unresponsiveness of the anergic cell. We have addressed questions regarding the importance of the Src kinase p59(fyn) (Fyn) in this process by using Fyn null mice. We demonstrate that a mature population of CD4(-)CD8(-) alphabeta TCR(+) anergic T cells lacking Fyn have a substantial recovery of their proliferation defect in response to Ag stimulation. This recovery cannot be explained by ameliorated production of IL-2, and the improved proliferation correlates with an enhanced ability of the Fyn(-/-) anergic T cells to up-regulate the high affinity IL-2 receptor. We also observe that anergic CD4(-)CD8(-) alphabeta TCR(+) T cells have a heightened survival ability that is partially dependent on the elevated levels of Fyn and IL-2 receptor beta-chain expressed by these cells. The enhanced survival correlates with an increased capacity of the anergic cells to respond to IL-15. We conclude that Fyn plays an important role in aspects of T cell anergy pertaining to TCR signaling and to cell survival.     

IL-21 enhances and sustains CD8+ T cell responses to achieve durable tumor immunity: comparative evaluation of IL-2, IL-15, and IL-21

Cytokines that use the common receptor gamma-chain for regulating CD8(+) T cell responses to Ag include IL-2, IL-15, and the recently identified IL-21. The ability of these cytokines to regulate antitumor activity in mice has generated considerable interest in understanding their mode of action. In this study we compare the abilities of IL-2, IL-15, and IL-21 to stimulate immunity against tumors in a syngeneic thymoma model. Durable cures were only achieved in IL-21-treated mice. By monitoring both endogenous and adoptively transferred tumor Ag-specific CD8(+) T cells, it was determined that IL-21 activities overlap with those of IL-2 and IL-15. Similar to IL-2, IL-21 enhanced Ag activation and clonal expansion. However, unlike IL-2 treatment, which induces activation-induced cell death, IL-21 sustained CD8(+) T cell numbers long term as a result of increased survival, an effect often attributed to IL-15. These findings indicate that the mechanisms used by IL-21 to promote CD8(+) T cell responses offer unique opportunities for its use in malignant diseases and infections.     

Intracellular activation signal requirements for the induction of IL-2 responsiveness in resting T cell subsets in humans

Activation signal requirements for the induction of the IL-2 responsiveness in purified subsets of human resting T cells, T4+ or T8+, have been investigated under the monocyte-depleted conditions. Substantial levels of IL-2 responsiveness were induced in T8+ cells by lectin, Con A, mAb directed against the CD3 Ag, OKT3, Ca2+ ionophore, ionomycin or phorbol ester, PMA. In contrast, none of these stimuli was by itself sufficient for the induction of IL-2 responsiveness in the T4+ subset. The latter cells could, however, be induced to respond to IL-2 by combinations of PMA plus either of Con A, OKT3, or ionomycin (but not any combination of Con A, ionomycin, and OKT3). These data indicate that induction of IL-2 responsiveness in the resting T4+ subset is more complex, possibly requiring two intracellular activation signals, increase in the concentration of intracellular Ca2+ and activation of protein kinase C, whereas either signal may directly trigger IL-2 responsiveness in the resting T8+ cells. The data further suggest that under optimal conditions, growth of both resting T4+ and T8+ subsets may be independent of monocytes.     

Death ligand TRAIL induces no apoptosis but inhibits activation of human (auto)antigen-specific T cells

TNF-related apoptosis-inducing ligand (TRAIL), a member of the TNF superfamily, induces apoptosis in susceptible cells, which can be both malignant and nontransformed. Despite homologies among the death ligands, there are great differences between the TRAIL system on the one hand and the TNF and CD95 systems on the other hand. In particular, TRAIL-induced apoptosis differs between rodents and man. Studies on animal models of autoimmune diseases suggested an influence of TRAIL on T cell growth and effector functions. Because we previously demonstrated that TRAIL does not induce apoptosis in human (auto)antigen-specific T cells, we now asked whether TRAIL exhibits other immunoregulatory properties in these cells. Active TRAIL inhibited calcium influx through store-operated calcium release-activated calcium channels, IFN-gamma/IL-4 production, and proliferation. These effects were independent of APC, Ag specificity, and Th differentiation, and no differences were detected between healthy donors and multiple sclerosis patients. TRAIL affected neither the expression of the cell cycling inhibitor p27(Kip1) nor the capacity of T cells to produce IL-2 upon Ag rechallenge, indicating that signaling via TRAIL receptor does not induce T cell anergy. Instead, the TRAIL-induced hypoproliferation could be attributed to the down-regulation of the cyclin-dependent kinase 4, indicating a G(1) arrest of the cell cycle. Thus, although it does not contribute to mechanisms of peripheral T cell tolerance such as clonal anergy or deletion by apoptosis, TRAIL can directly inhibit activation of human T cells via blockade of calcium influx.     

Anergic Th1 cells express altered levels of the protein tyrosine kinases p56lck and p59fyn.

Tolerance in T lymphocytes can result from clonal anergy, or paralysis, of Ag-specific T cells. To investigate the molecular mechanisms responsible for anergy, a system in which tolerance can be induced in vitro was employed. Anergy, as defined by long-lived nonresponsiveness to normal antigenic stimulation for IL-2 production, was produced in cloned murine CD4+ Th1 cells. Here we report that such anergic Th1 cells express constitutively reduced amounts of the protein tyrosine kinase p56lck and constitutively elevated levels of the protein tyrosine kinase p59fyn. Because protein tyrosine phosphorylation is known to be important for the normal induction of IL-2 synthesis, these results suggest that T cell anergy may be maintained, at least in part, by alterations in tyrosine phosphorylation signaling events.     

Epigenetic remodeling of the IL-2 and IFN-gamma loci in memory CD8 T cells is influenced by CD4 T cells

Memory T cells (T(M)) are able to rapidly exert effector functions, including immediate effector cytokine production upon re-encounter with Ag, which is critical for protective immunity. Furthermore, this poised state is maintained as T(M) undergo homeostatic proliferation over time. We examined the molecular basis underlying this enhanced functional capacity in CD8 T(M) by comparing them to defective CD8 T(M) generated in the absence of CD4 T cells. Unhelped CD8 T(M) are defective in many functions, including the immediate expression of cytokines, such as IL-2 and IFN-gamma. Our data show that this defect in IL-2 and IFN-gamma production is independent of clonal selection, functional avidity maturation, and the integrity of proximal TCR signaling, but rather involves epigenetic modification of these cytokine genes. Activated Ag-specific CD8 T cells exhibit rapid DNA demethylation at the IL-2 and IFN-gamma loci and substantial histone acetylation at the IFN-gamma promoter and enhancer regions. These epigenetic modifications occur early after infection at the effector stage and are maintained through memory development. However, activated unhelped CD8 T cells, which fail to develop into functional memory and are incapable of rapid cytokine production, exhibit increased DNA methylation at the IL-2 promoter and fail to acetylate histones at the IFN-gamma locus. Thus, CD4 T cell help influences epigenetic modification during CD8 T(M) differentiation and these epigenetic changes provide a molecular basis for the enhanced responsiveness and the maintenance of a "ready-to-respond" state in CD8 T(M).     

Antigen-experienced T cells undergo a transient phase of unresponsiveness following optimal stimulation

Interaction of the Ag-specific receptor of T lymphocytes with its Ag/MHC ligand can lead either to cell activation or to a state of unresponsiveness often referred to as anergy. It has been generally assumed that anergy develops as a consequence of inadequate stimulation, such as in response to altered peptide ligands or to agonists presented by costimulatory-deficient accessory cells. The present study uncovers an alternative way of inducing an unresponsive state in T cells. Indeed, we demonstrate herein that Ag-stimulation of murine CD4+ Th clones induces cellular activation, characterized by cytokine production and cell proliferation, followed by a state of transient (lasting up to 6 days) unresponsiveness to further antigenic stimulation. This state of activation-induced unresponsiveness 1) is not a consequence of inadequate costimulation, as it occurs when cells are stimulated in the presence of dendritic cells or anti-CD28 Abs; 2) develops after an optimal response to Ag; 3) is not due to cell death/apoptosis or CTLA-4 engagement; 4) down-regulates the proliferation and cytokine production of both Th1- and Th2-like clones; and 5) does not affect the early steps of signal transduction. Finally, naive T cells are not sensitive to this novel form of unresponsiveness, but become gradually susceptible to activation-induced unresponsiveness upon Ag stimulation. Collectively, these data suggest that activation-induced T cell unresponsiveness may represent a regulatory mechanism limiting the clonal expansion and effector cell function of Ag-experienced T cells, thus contributing to the homeostasis of an immune response.