The immune response and the eye. I. The effects of monoclonal antibodies to T suppressor factors in anterior chamber-associated immune deviation (ACAID)

We report the effects of two monoclonal antibodies (mab) specific for murine T suppressor (Ts) factors (TsF) in anterior chamber (AC)-associated immune deviation (ACAID), as induced by AC inoculation of TNP-coupled syngeneic spleen cells (TNP-Spl). One mab (14-12) is specific for Ts effector factor and can block the induction of Ts cells in ACAID if given before or after AC injection of TNP-Spl. The other mab (14-30) is specific for Ts inducer factors and blocks suppression only after given after TNP-Spl. We also studied the surface phenotype of the Ts cells induced by AC injection of TNP-Spl. We show that at least two cells are required for the adoptive transfer of suppression in TNP-ACAID. One is Lyt-2+ and 14-12+, the other is I-J+. These Ts cells have the surface phenotype of Ts effector cells as seen in other systems. These results indicate that mab which bind TsF in other systems affect Ts cells in TNP-ACAID, and that the Ts cells induced in TNP-ACAID are only of the Ts effector type.     

The immune response and the eye. III. Anterior chamber-associated immune deviation can be adoptively transferred by serum

After the anterior chamber (AC) injection of trinitrophenol-coupled (TNP) spleen cells, it is observed that systemic delayed-type hypersensitivity responses to TNP are inhibited by Ag-specific suppressor T cells. We recently reported that suppression is initiated by viable TNP-coupled T cells within the inoculum and upon further analysis we found that these cells have the surface phenotype of CD4+ Ts inducer cells. We report here that treatment of these TNP-T cells with cycloheximide or cytochalasin-B before to AC injection abolishes suppression, whereas treatment with 2000 rad radiation does not. This indicates that protein synthesis and secretion are required to initiate suppression but proliferation is not. Further, we demonstrate the adoptive transfer of suppression by serum of AC inoculated animals. Detection of the component in serum in adoptive transfer assays, however, requires removal of the spleen before AC injection. We establish that the material in serum is a Ts cell product (T suppressor-inducer factor) based on three criteria: it is Ag specific, genetically restricted, and reactive with a mAb that specifically identifies these molecules. These results suggest that the signal leaving the eye to induce suppression of delayed-type hypersensitivity is T cell derived and that molecules mediating immune regulation for this organ are made within the eye and transported via the serum to the spleen.     

The immune response and the eye. II. The nature of T suppressor cell induction in anterior chamber-associated immune deviation (ACAID)

We studied the cellular basis for the induction of Ts cells in anterior chamber (AC)-associated immune deviation (ACAID) by using TNP-modified syngeneic spleen cells (TNP-Spl). We demonstrate that the cells responsible for the induction of TNP-ACAID are non adherent, IA- T cells. This is in contrast to the antigen-presenting cells which induce suppression after the i.v. injection of TNP-Spl which are IA+/I-J+ adherent cells. Furthermore, two T cells within the TNP-Spl population are required to initiate suppression in TNP-ACAID: one is Lyt-1+, and I-J+, the other is Lyt-1+ and reactive with a monoclonal antibody, 14-30, which specifically identifies Ts inducer cells. The antigen specificity of ACAID resides in the 14-30+ T cell, and not the I-J+ cell. Although both cells must be viable to induce suppression, neither they (nor their products) must be in direct contact within the eye; one population may be in the right AC, the other in the left. Our results suggest that it is Ts inducer cells placed into the AC of the eye which initiate TNP-ACAID, and that these cells exit (or secrete Ts factors which exit) the eye to induce Ts effector cells in the spleen.     

Characterization of the suppressor cell(s) responsible for anterior chamber-associated immune deviation (ACAID) induced in BALB/c mice by P815 cells

Anterior chamber-associated immune deviation (ACAID) is a complex set of immune responses induced by the inoculation of antigens into the anterior chamber of the eye. Histocompatibility antigens, tumor-specific antigens, reactive haptens, and viral antigens have been shown to induce this phenomenon, which comprises the following specific host responses: high titer humoral antibodies, primed cytotoxic T cells, but specifically, impaired skin graft rejection and delayed-type hypersensitivity (DTH). Using the model system of ACAID induced by inoculation of P815 mastocytoma cells into the anterior chambers of H-2-compatible, but minor H-incompatible, BALB/c mice, we demonstrate that the impaired capacity of these animals to develop and express DTH is due to the activation of suppressor T cells. Generation of these cells requires an intact spleen, is not inhibited by cyclophosphamide pretreatment, and is abrogated by systemic treatment of the host with anti-I-J monoclonal antibodies. This splenic suppressor cell(s) can transfer suppression of DTH adoptively to naive syngeneic mice. One suppressor cell is Thy-1.2, Lyt-2.2, and I-Jd positive. A minority of these cells (or a second population of suppressor cells) also expresses the L3T4 surface marker. Suppression is exerted on the efferent limb of DTH expression, although afferent suppression is not excluded. P815-induced ACAID suppressor cells resemble similar cells induced by haptenated spleen cells inoculated into the anterior chamber of the eye. We propose that induction of these suppressor cells, whose target of action is selective for T DTH cells, but not for other types of T cells, is responsible for the phenomenon of immune privilege in the anterior chamber of the eye.     

Activation of human B lymphocytes by a particulate antigen

A specific IgM antibody response toward the trinitrophenol (TNP) hapten can be induced in mononuclear blood cell suspensions upon culture with a particulate antigen: polyacrylamide beads conjugated with the TNP hapten (TNP-PAA). The response, and its specificity, are demonstrated by an increase in the number of TNP binding B lymphocytes (specific rosette forming cells), by the appearance of cells producing anti-TNP antibody at a high rate (haemolytic plaques), (ELISA test). The anti-TNP response requires monocytes, the role of which is to produce interleukin-1 (IL-1) and T lymphocytes (belonging to the T4 helper subset) the role of which is to produce interleukins (the characterization of which is under study). We propose a model or B cell activation based on the following signals: an early specific signal, provided by the particulate antigen; several non specific signals, provided by T derived interleukins. The anti-TNP response is negatively regulated by monocytes, the functional states of which can be modified in certain situations (autoimmunity, aging) or influenced by glucocorticoids. Suppressor T lymphocytes of this response (not exclusively of the T8 phenotype) can be induced and this can allow the evaluation of T suppressor cell function. This was used in adult idiopathic thrombocytopenic purpura treated with high doses of intra-venous gammaglobulins.     

Ocular immune responses. II. Priming of A/J mice in the vitreous induces either enhancement of or suppression of subsequent hapten-specific DTH responses

We previously showed that the "immunologic privilege" of the anterior chamber results not from afferent blockade, but rather from induction of hapten-specific suppressor T cells that appear after anterior chamber priming with antigen. These suppressor T cells induced by anterior chamber priming differ from those induced by i.v. priming in their ability to block the efferent as well as the afferent limb of the immune response and in their lack of idiotypic surface receptors detected by rabbit anti-idiotypic antibody. We now report that intravitreal priming with haptenated syngeneic spleen cells does not result in generation of suppressor cells, but rather, can in some instances result in an enhanced systemic immunoreactivity to the priming hapten. If soluble antigenic preparations are used, however, intravitreal priming results in the generation of the suppressor T cells, which suppress subsequent DTH and CTL responses to the immunizing hapten. The suppressor cell generation after intravitreal priming is a cyclophosphamide-sensitive process. These results demonstrate that soluble products are processed differently in ocular compartments compared with cell surface coupled ligands, and further demonstrate that the generation of hapten-specific suppressor T cells is dependent, at least in part, on the form and on the specific compartment of the eye that is inoculated.     

T cell regulation of B cell activation. An antigen-mediated tripartite interaction of Ts cells, Th cells, and B cells is required for suppression

To determine the requirements underlying the antigen specificity observed in T cell-mediated immune response suppression, cloned major histocompatibility complex (MHC)-restricted T suppressor (Ts) cells specific for keyhole limpet hemocyanin (KLH) and cloned MHC-restricted T helper (Th) cells specific for fowl gamma-globulin (FGG) were employed to study the regulation of trinitrophenyl (TNP)-specific B cell responses. Neither antigen bridging between Ts cells and Th cells (FGG=KLH) nor bridging between Ts cells and B cells (TNP-KLH) was sufficient to allow suppression; a mixture of FGG=KLH and TNP-KLH was also insufficient for suppression. In contrast, suppression was induced by KLH-specific Ts cells only when suppressor determinants (KLH), helper determinants (FGG), and B cell determinants (TNP) were covalently linked on the same molecule (TMP-FGG)=(TNP-KLH) or TNP-(FGG=KLH)). These findings imply that a tripartite antigen-mediated interaction of Ts cells, Th cells, and responding B cells is necessary for the mediation of this antigen-specific suppression.     

Nonspecific T suppressor factor (nsTsF) cascade in contact sensitivity: nsTsF-1 causes an Ly-1+2- I-A+ immune T cell to produce a second, genetically restricted, nsTsF-2

We studied the mode of action of the nonspecific T suppressor factor (nsTsF-1) made in the picryl (TNP) system when T acceptor cells armed with antigen-specific TsF are triggered by antigen in the context of I-J. This suppressor factor does not inhibit the passive transfer of contact sensitivity directly, as shown by its failure to inhibit passive transfer by immune cells deprived of I-A+ cells. Its immediate target is an immune, antigen-specific, Ly-1+2-, I-A+ T cell. This cell, which may be regarded as a T suppressor effector cell (Ts-eff-2), produces nsTsF-2 when exposed sequentially to nsTsF-1 and antigen. This nsTsF subsequently inhibits the passive transfer of contact sensitivity. The action of nsTsF-2 is MHC genetically restricted. As the nsTsF-2 bears I-A determinant(s), this raises the possibility that it may act by combining with the recognition site for I-A on the T cell that mediates contact sensitivity.     

Regulation of the systemic immune response by visible light and the eye

The injection of certain antigens into the anterior chamber (AC) of the eye results in the induction of antigen-specific suppressor T cells (Ts cells), which inhibit systemic delayed-type hypersensitivity (DTH). We have previously shown that down-regulation by Ts cells after AC injection with 2,4,6-trinitrophenol (TNP)-coupled spleen cells (TNP-Spl) is initiated by the intraocular activation of Ts inducer cells. These cells activate T suppressor-effector cells in the spleen that are responsible for suppressed DTH. With dark- and light-reared mice (Balb/c), we show that visible light has a direct effect on the intraocular T cell reaction that leads to systemic suppression. Our results show that if light is prevented from reaching the eye by dark rearing, by placing light-reared animals in the dark after AC injection, or by closing the eyelids of light-reared animals after AC injection, Ts cells are not activated. We show that light is responsible for establishing conditions in the eye that cause the preferential activation of Ts cells. The intraocular conditions established by light are not developmentally mandated as is visual development, but can be eliminated in adult light-reared animals by placing them in the dark for 18 h after AC injection. These conditions can also be induced in adult dark-reared animals by returning them to the light for just over 24 h before AC injection. These studies have important implications for understanding intraocular immune responses and possibly for the treatment of eye disease.     

Transmission of hapten-specific tolerance to an unrelated carrier

The principle of linked recognition is well defined in response and suppression. Yet, to our knowledge, it is not explored in the context of tolerance. To investigate, whether the status of tolerance toward a hapten (TNP) can be transferred to a subsequently introduced carrier, animals which were tolerized by a subimmunogenic dose of hapten (TNP) coupled to syngeneic monoclonal anti-TNP IgG, with the rationale of combining the phenomena of low zone tolerance and syngeneic IgG-induced suppression, were challenged with TNP-horse red blood cells (HRBC). Conjugates of high density (40 mM) TNP-syngeneic IgG (TNP40-IgG) were immunogenic and after challenge with TNP-HRBC, animals responded to TNP and to HRBC. Yet, spleen cells (SC) of mice injected with TNP2.5-IgG and challenged with TNP-HRBC were tolerant against TNP as well as the carrier. Limiting dilution (LD) analysis revealed that subimmunogenic doses of TNP coupled to IgG resulted in diminished activation of help, failure to activate contrasuppressor T cells (TCS), and significantly augmented activation of suppressor T cells (TS). On the other hand, after challenge with TNP-HRBC, activation/expansion of carrier-specific helper (TH), suppressor, and contrasuppressor T cells were not affected by previous immunization with subimmunogenic or immunogenic doses of TNP-IgG conjugates, but HRBC-specific TCS could not interact with TNP-specific TS. Hence, to initiate tolerance it was necessary (and sufficient) that an activated and expanded TS population was not counterregulated by TCS. In this situation, an established status of dominance of suppression for the epitope TNP could not be disrupted by an immunogene carrying a multitude of new epitopes; i.e., tolerization by subimmunogenic doses of the individual epitope TNP resulted in unresponsiveness against any immunogen carrying this epitope.     

Ocular immune privilege promoted by the presentation of peptide on tolerogenic B cells in the spleen. II. Evidence for presentation by Qa-1

Ocular immune privilege is the result of several unique features of the eye, including the systemic down-regulation of Th1 immune responses to Ags encountered in the anterior chamber of the eye-a phenomenon termed anterior chamber-associated immune deviation (ACAID). The induction of ACAID requires the participation of three cell populations: the ocular ACAID APC, the splenic B cell, and the splenic T cell. Because B cells have been implicated in tolerogenic Ag presentation in other systems, we hypothesized that B cells were responsible for the induction of regulatory T cells in ACAID. The central hypothesis for this study is that APC from the eye migrate to the spleen where they release antigenic peptides (OVA) that are captured and presented to T cells by splenic B cells. A combination of in vitro and in vivo studies demonstrated that splenic B cells, incubated with ACAID APC in vitro, were capable of inducing ACAID when transferred to naive mice. The induction of ACAID required the normal expression of ss(2)-microglobulin on both the B cell and ACAID APC, but not on the T suppressor cells. Moreover, the induction of ACAID regulatory cells required histocompatibility between the B cells and regulatory T cells at the TL/Qa region. The results indicate that: 1) B cells are necessary for the induction of ACAID; 2) ACAID B cells do not directly suppress the expression of delayed-type hypersensitivity; and 3) the induction of Ag-specific regulatory T cells by ACAID B cells requires histocompatibility at the TL/Qa region.     

Mechanism of action of cyclosporin A in vivo. I. Cyclosporin A fails to inhibit T lymphocyte activation in response to alloantigens

Although cyclosporin A (Cy A) has been widely used clinically as a potent suppressor of organ allograft rejection and has been shown to block T lymphocyte activation in vitro by inhibiting the generation of interleukin 2 (IL-2) and other lymphokines, little direct evidence is available to support the view that the immunosuppressive effects of Cy A in vivo are mediated by a similar inhibition of the autocrine lymphokine cascade. We have used a quantitative assay for the assessment of the role of the IL-2/IL-2 receptor system in the activation of the draining popliteal lymph node population after the injection of allogeneic cells in the footpad to define the effects of Cy A on the early events of lymphocyte activation in vivo and to compare them with the effects of Cy A on lymphocyte activation in vitro. The administration of Cy A in vivo had no effect on alloantigen-induced increases in cell size, percentage of cells expressing the IL-2 receptor, the spontaneous or IL-2-driven proliferation of freshly explanted cells, or the induction of cytotoxic T lymphocyte activity. These findings raise major questions about the mechanism of action of Cy A in vivo and suggest that more experimentation is required to probe the mechanisms of Cy A-induced suppression of the response to allografts.     

Subunits of IgM reconstitute defective contact sensitivity in B-1 cell-deficient xid mice: kappa light chains recruit T cells independent of complement

The elicitation of contact sensitivity (CS) to local skin challenge with the hapten trinitrophenyl (TNP) chloride requires an early process that is necessary for local recruitment of CS-effector T cells. This is called CS initiation and is due to the B-1 subset of B cells activated at immunization to produce circulating IgM Ab. At challenge, the IgM binds hapten Ag in a complex that locally activates C to generate C5a that aids in T cell recruitment. In this study, we present evidence that CS initiation is indeed mediated by C-activating classic IgM anti-TNP pentamer. We further demonstrate the involvement of IgM subunits derived either from hybridomas or from lymphoid cells of actively immunized mice. Thus, reduced and alkylated anti-TNP IgM also initiates CS, likely due to generated H chain-L chain dimers, as does a mixture of separated H and L chains that still could weakly bind hapten, but could not activate C. Remarkably, anti-TNP kappa L chains alone mediated CS initiation that was C-independent, but was dependent on mast cells. Thus, B-1 cell-mediated CS initiation required for T cell recruitment is due to activation of C by specific IgM pentamer, and also subunits of IgM, while kappa L chains act via another C-independent but mast cell-dependent pathway.     

Activation of Lyt-1+ and Lyt-2+ T cell cloned lines: stimulation of proliferation, lymphokine production, and self-destruction

Antigen-induced activation of a chicken gamma-globulin (CGG)-specific Lyt-1+ T cell clone measured both as a function of proliferation and immune interferon (IFN-gamma) production is restricted by a class II determinant of the major histocompatibility complex (MHC) mapped to the I-A subregion, as determined by studies with both recombinant inbred lines and monoclonal antibodies. Activation of Lyt-2+ picryl chloride (PC1)-specific cloned T cell lines by trinitrophenyl (TNP)-coupled spleen cells results in proliferation and the production of at least two lymphokines: lymphotoxin (LT) and IFN-gamma. This antigen-specific activation is restricted to a class I determinant of the MHC complex encoded in the K region. Thus, the common intracellular pathway leading to production of IFN-gamma by Lyt-1+ and Lyt-2+ T cells is mediated and restricted through different surface recognition units. The LT that is produced by antigen-specific activation of T cells not only kills fibroblasts, but it inhibits interleukin 2 (IL 2)-maintained T cells as well. Activation of T cells by concanavalin A (Con A) results in suicidal inhibition of proliferation and cell death by those clones that make LT, but not by those that produce only IFN-gamma under such induction conditions. These results indicate that it is neither Con A nor IFN-gamma that kills T cells, but LT. These results strongly suggest a self-regulatory role of LT in limiting continuing unrestricted T cell response to antigen activation.     

Antigen and receptor-driven regulatory mechanisms. VI. Demonstration of cross-reactive idiotypic determinants on azobenzenearsonate-specific antigen-binding suppressor T cells producing soluble suppressor factor(s)

The first detectable suppressor T cell (Ts) arising after i.v. administration of azobenzenearsonate- (ABA) conjugated syngeneic spleen cells to A/J mice has been studied for its receptor specificity and ability to produce soluble suppressor factor(s). This cell, termed Ts1, has a specific receptor for the eliciting antigen ABA, as demonstrated by selective binding to ABA protein- but not TNP protein-coated plastic dishes. The activity of ABA-Ts1 can be abrogated by treatment with anti-idiotypic antibodies made against anti-ABA antibodies of A/J mice (anti-CRI), indicating that these ABA-binding cells possess a surface receptor structure sharing idiotypic determinants with antibodies of the same specificity. Finally, soluble extracts from, antigen-adherent ABA-Ts1, but not nonadherent cells from the same spleen cell population, possess suppressive activity when assayed directly for afferent suppression or tested for their ability to trigger a second population of Ts (Ts2) in naive recipients. These findings demonstrate a close concordance between a T cell surface receptor, soluble T suppressor factors, and B cell derived antibody, all capable of direct recognition of the eliciting ABA antigen.     

Modulation of help and suppression in a hapten-carrier system.

Provision of beta-galactosidase (GZ) under defined conditions of dose and time can either help or suppress a subsequent response to trinitrophenyl (TNP)-GZ in CBA/J mice. The optimal helper effect occurs when 10(7) spleen cells from mice primed 9 or more days previously with 10 mug GZ are adoptively transferred to irradiated recipients which are than challenged with 10 mug TNP50GZ. Optimum suppression results from the transfer of spleen cells from mice primed 3 days previously with 100 mug GZ and challenge of recipients with TMP150GZ. Both help and suppression are carrier-specific and mediated by T cells. In experiments where helper or suppressor cells were mixed with normal cells, the anti-TNP response was proportional to the number of primed cells transferred. The results point to a wave of suppression as the initial event after immunization, which is succeeded by period in which the helper effect dominates.     

Hapten-specific T cell responses to 4-hydroxy-3-nitrophenyl acetyl. XIII. Characterization of a third T cell population involved in suppression of in vitro PFC responses

The involvement of a third-order suppressor T cell population (Ts3) in the suppression of in vitro PFC responses was analyzed. It was shown that Ts2 effector-phase suppressor cells, induced by the i.v. injection of NP-coupled syngeneic spleen cells, require a third suppressor T cell population to effect NPb idiotype-specific suppression of an in vitro B cell response. This Ts3 population was shown to be present in NP-primed but not unprimed donors. The Ts3 population specifically binds NP and is Lyt-1-, Lyt-2+, I-J+ and bears NPb idiotypic determinants. The involvement of the Ts3 population in a suppressor pathway that requires recognition of idiotypic determinants is discussed.     

T cell regulation of B cell activation: antigen-specific and antigen-nonspecific suppressor pathways are mediated by distinct T cell subpopulations

The present studies were carried out to characterize the cellular events involved in the induction and function of carrier-specific Ts cells, which selectively regulate the generation of IgG responses by Lyb-5- B cells. It was demonstrated that this regulation is in fact mediated by two distinct suppressor pathways. In one pathway, carrier-primed Lyt-1 + 2 - Ts cells are specifically activated by in vitro reexposure to the priming antigen. After this specific activation, these Lyt-1 + 2 - Ts cells are able to suppress IgG responses in an antigen-nonspecific manner. This suppression requires the participation of unprimed Lyt-1 - 2 + T cells, and is effective in both the early and the late phases of antibody responses. A second suppressor pathway requires the antigen-specific activation of primed Lyt-1 - 2 + Ts cells. Suppression of antibody responses by activated Lyt-1 - 2 + Ts cells is highly carrier specific, in contrast to the nonspecific effector function of Lyt-1 + 2 - Ts cells, appears to act without requirement for additional T cell populations; and is effective only early in the course of the antibody response. Thus, it appears that two Ts cell populations may function through distinct mechanisms to regulate the generation of IgG Lyb-5- B cell responses.     

Mechanism of action of a T suppressor factor (TsF) in contact sensitivity: the T cell target for TsF activity in adoptive transfer of immunity is not effector cell

The passive transfer of contact sensitivity (CS) by immune cells into normal animals requires the interaction of two distinct Ly-1+ T cells, one which is Vicia villosa lectin (VV)-nonadherent, the other which adheres to VV. Functional deletion of either cell type abrogates the adoptive transfer of CS into normal animals, whereas VV-nonadherent cells alone can transfer CS into animals pretreated with cyclophosphamide (Cy). An antigen-specific T suppressor factor, designated TNP-TsF, inhibits the transfer of CS into normal adoptive recipients. TNP-TsF mediates its suppressive activity by inducing an I-J+ subfactor (designated I-J2) from the assay population by the interaction of PC1-F (a TNP-binding subfactor of TNP-TsF) with antigen-primed Ly-2+ T cells. This I-J+ subfactor then complements TNBS-F (an antigen-nonbinding subfactor of TNP-TsF) to form an antigen-nonspecific effector molecule which suppresses DTH responses in an antigen-nonspecific fashion. We report here that TNP-TsF suppresses the adoptive transfer of CS into normal animals but not into animals pretreated with Cy. TNBS-F + I-J2, the effector complex of TNP-TsF, also suppresses the transfer of CS into normal but not Cy-treated animals. When the Ly-1 immune cells were separated into VV-adherent and -nonadherent populations, the TNBS-F + I-J2 suppressor complex suppressed the functional activity of the VV-adherent cell population, but not the VV-nonadherent cells. This suppressive activity correlates with the need for VV-adherent cells in the transfer of CS into normal but not Cy-treated recipients. When an I-J+ molecule (I-J1) from an SRBC-specific TsF was used in place of I-J2 to form a suppressor complex with TNBS-F, this TNBS-F + I-J1 TsF suppressed the transfer of CS into both normal and Cy-treated recipients. This difference in functional suppressive activity correlated with a difference in target cell specificity: TNBS-F + I-J1 suppressed the VV-nonadherent TDTH cell, whereas TNBS-F + I-J2 suppressed the VV-adherent T cell of CS. Immune cells which are transferred under conditions which do not require the VV-adherent cell for transfer are not suppressed by TNBS-F + I-J2 or TNP-TsF, but are suppressed by the TNBS-F + I-J1.(ABSTRACT TRUNCATED AT 250 WORDS)     

CD4+ NKT cells,but not conventional CD4+ T cells,are required to generate efferent CD8+ T regulatory cells following antigen inoculation in an immune-privileged site

Following inoculation of Ag into the anterior chamber (a.c.), systemic tolerance develops that is mediated in part by Ag-specific efferent CD8(+) T regulatory (Tr) cells. This model of tolerance is called a.c.-associated immune deviation. The generation of the efferent CD8(+) Tr cell in a.c.-associated immune deviation is dependent on IL-10-producing, CD1d-restricted, invariant Valpha14(+) NKT (iNKT) cells. The iNKT cell subpopulations are either CD4(+) or CD4(-)CD8(-) double negative. This report identifies the subpopulation of iNKT cells that is important for induction of the efferent Tr cell. Because MHC class II(-/-) (class II(-/-)) mice generate efferent Tr cells following a.c. inoculation, we conclude that conventional CD4(+) T cells are not needed for the development of efferent CD8(+) T cells. Furthermore, Ab depletion of CD4(+) cells in both wild-type mice (remove both conventional and CD4(+) NKT cells) and class II(-/-) mice (remove CD4(+) NKT cells) abrogated the generation of Tr cells. We conclude that CD4(+) NKT cells, but not the class II molecule or conventional CD4(+) T cells, are required for generation of efferent CD8(+) Tr cells following Ag introduction into the eye. Understanding the mechanisms that lead to the generation of efferent CD8(+) Tr cells may lead to novel immunotherapy for immune inflammatory diseases.