Requirement for B cells for activation of contrasuppressor T cells by type III pneumococcal polysaccharide

Type III pneumococcal polysaccharide (S3) is unable to activate S3-specific contrasuppressor T cells (Tcs) in mice depleted of B cells by chronic anti-IgM treatment or in immune defective xid mice that lack the B cell subset required for anti-S3 antibody responses. The inability of S3 to activate Tcs in xid mice was shown to be due to a requirement of B cells for Tcs activation rather than to an absence of Tcs in xid mice. The B cells from normal mice that are required for Tcs activation apparently function to present the S3 Ag to Tcs. S3 physically coupled to spleen cells (S3-SC) prepared from normal BCF1 SC could activate Tcs in both xid and BCF1 mice whereas S3-SC prepared from xid SC or B cell-depleted BCF1 SC could not activate Tcs in either strain. B cell APC function was abrogated by 3000 R irradiation and by treatment of the B cells with either chloroquine or paraformaldehyde. Interestingly, B cells from mice previously immunized with S3 were unable to function in Tcs activation; preimmunization of B cell donors with an irrelevant Ag or with a T-dependent form of S3 had no effect on their ability to function as APC. These latter observations are discussed in terms of the in vivo persistence of polysaccharide Ag and their ability to induce B cell tolerance under the experimental conditions used for these experiments. The results of this study provide evidence that B cells play an important and apparently obligatory role in the activation of Tcs by S3; B cells apparently function to present Ag to Tcs, resulting in the activation of this regulatory T cell subset.     

Requirements for activation of contrasuppressor T cells by type III pneumococcal polysaccharide

Either S3-coupled spleen cells (S3-SC) or soluble S3 activates two populations of regulatory T cells, T suppressor cells (Ts) and contrasuppressor T cells (Tcs). The latter cells function to mask the activity of Ts in unfractionated T cell populations, so that Ts can be detected only after removal of Tcs. Activation of Tcs by S3 may be required for induction of an antibody response to S3. This is suggested by the findings that Tcs are activated only by immunogenic doses of S3, that Tcs are not detectable in the spleens of mice tolerant to S3, and that (CBA/N X BALB/c)F1 male (xid) mice, which are genetically unresponsive to S3, do not develop Tcs after immunization with S3. Moreover, the kinetics of activation of Tcs by S3 closely parallels the kinetics of the antibody response to S3. Tcs have no detectable activity in the absence of Ts, indicating that these cells do not function as amplifier or helper T cells.     

Direct demonstration of specific suppressor T cells in the mice tolerant to type III pneumococcal polysaccharide: two-step requirement for development of detectable suppressor cells

Spleen cells from CAF1 mice made tolerant to type III pneumococcal polysaccharide (S3) with S3 coupled to syngeneic spleen cells (S3-SC) develop S3-specific suppressor T cells (Ts). These Ts could be demonstrated consistently only when spleen cells from tolerant mice were cultured in vitro with the specific antigen and the specific tolerogen. Spleen cells from normal mice cultured under the same conditions did not suppress the antibody response to S3. When different numbers of Ts were transferred to normal CAF1 mice, an unusual dose-effect pattern was observed. Maximal suppression of the S3 response occurred when relatively low numbers of Ts, 3 to 30 x 10(5) per recipient, were transferred, whereas larger numbers of cells, 150 x 10(5) per recipient, were not suppressive. These results indicate that a presumably T-independent antigen, S3, can activate antigen-specific Ts. These Ts exhibit unusual dose effects upon transfer and require both an in vivo induction period and in vitro activation for development of maximal activity. These latter observations suggest that S3 may activate a different population of T cells with suppressor function than do conventional T-dependent antigens. The loss of suppression observed when greater than optimal numbers of cells were transferred suggests that a second type of T cell, which has the ability to 'neutralize' the activity of S3-specific Ts, is also induced in the same spleen cell population.     

Characterization and activity of contrasuppressor T cells induced by type III pneumococcal polysaccharide

Optimally immunogenic amounts of type III pneumococcal polysaccharide (S3) activate a population of contrasuppressor T cells (Tcs), which have been shown to play an important role in the induction of anti-S3 antibody responses. These Tcs belong to a unique T cell subset that has the surface phenotype Lyt 1+2- L3T4- I-J+ I-A+. These Tcs are also cyclophosphamide (Cy)-sensitive and sensitive to antilymphocyte serum (ALS) and mitomycin C. Tcs have antigen-binding receptors, indicating that any interactions of Tcs with B cells or T suppressor cells (Ts) (both of which also have antigen-binding receptors) must be via an antigen bridge rather than an idiotype-anti-idiotype interaction. Tcs are also Igh restricted in their action. Contrasuppression is manifest only when the Tcs are Igh compatible with both the Ts and the responding B cells. Tcs apparently mediate their effects by releasing a soluble factor, since a soluble factor extracted from Tcs is able to abrogate the effects of S3-specific Ts.     

Splenic I-J-bearing antigen-presenting cells in activation of suppression: further characterization

A set of I-J-bearing murine splenic antigen-presenting cells (APC) has been found to be responsible for first order suppressor cell (Ts1, afferent suppressor cell) activation in the azobenzenearsonate (ABA) hapten system after intravenous administration. Suppressor cells induced by this set of hapten-coupled cells do not function in the efferent phase of the delayed hypersensitivity (DTH) response. The functional activity of this novel APC to activate afferent suppressor cells was resistant to a dose of ultraviolet radiation (UVR) sufficient to largely abrogate the ability of splenic APC to immunize for a DTH response. It was also found that the previously described splenic I-J-bearing APC needed for third-order suppressor cell (Ts3, effector-suppressor cell) activation is adherent and UVR resistant. The sets of I-J-bearing APC appear to be crucial elements in the activation of suppression and thus in determining the balance between immunologic reactivity and unresponsiveness. Furthermore, the UVR resistance of this set of novel APC may be relevant to the in vivo effects of UVR exposure to mice.     

Epidermal cells in activation of suppressor lymphocytes: further characterization

Intravenous administration of hapten-coupled, high-density (density greater than 1.077) epidermal cells (HD-EC) to mice results in the appearance of transferable splenic T suppressor (Ts) cells as assayed in adoptive transfer experiments. Depletion of I-A bearing cells from the HD-EC population before hapten coupling prevents these cells from inducing Ts cell formation, whereas depletion of Thy-1-bearing cells from the HD-EC cell preparation has no effect. When HD-EC are adhered to glass for 2 hr, the ability to induce Ts cell formation resides in the adherent population. Exposure of HD-EC to a dose of ultraviolet radiation (UVR) that largely abrogates the ability of hapten-coupled EC to immunize mice for a DTH response does not affect the ability of these cells to activate Ts cells. Treatment of mice with i.p. administration of 20 mg/kg of cyclophosphamide 2 days before EC harvesting abrogates the ability of HD-EC from these mice to induce Ts cell formation. HD-EC from B10.A(3R) (I-Jb) but not B10.A(5R) (I-Jk) mice induce Ts cell formation in B10.A(3R) mice, demonstrating that the ability to do so is restricted by the I-J locus. Transmission electron microscopy of adherent HD-EC populations demonstrated that two cell types were present. One type had the characteristics of keratinocytes; the other was monocyte-like and resembled Langerhans cells or indeterminate cells in many aspects. Immunoelectron microscopy revealed this second cell type to bear I-A/I-E antigen. These cells were T-200 positive and Mac-1 negative by immunoperoxidase staining. Extensive examination by light and electron microscopy failed to reveal any dermal components in the EC populations; however, a very small degree of dermal contamination cannot be excluded. Thus, EC that activate afferent-acting Ts cells are high-density, I-A+, Thy-1-, I-J restricted, glass adherent, and functionally UVR resistant and cyclophosphamide sensitive.     

Soluble factors in tolerance and contact sensitivity to DNFB in mice. VIII. Regulation of T suppressor cell function by autoreactive T helper cells

When cultured with DNP-labeled I-A+ cells, Lyt 2+ T suppressor cells (Ts) from 2,4,-dinitrobenzene sulfonate (DNBS)-tolerized mice are activated to synthesize and release a suppressor factor (SSF) which suppresses the transfer of contact sensitivity to DNFB. The signals required to activate the DNBS-primed Ts to produce SSF were studied in greater detail. As previously observed with fixed DNP-labeled spleen cell stimulators, the supernatants from cultures of DNBS-primed spleen cells and glutaraldehyde-fixed DNP-labeled P388D1 cell monolayers did not contain SSF. When the tolerant cells were harvested from these monolayers and were treated with IL-1, the Ts released the synthesized SSF. Synthesis and release of SSF required Ts recognition of DNP/class I MHC on the hapten-presenting cells followed by interaction with the costimulator IL-1. When the tolerant cells were cultured with fixed DNP-labeled I-A+ or I-A- stimulators to induce SSF synthesis, release was induced by adding either unlabeled or TNP-labeled unprimed spleen cells to the cultures. The release of SSF was blocked when the second stimulators were pretreated with anti-I-A antibody but not with anti-DNP or anti-class I MHC antibodies. These results indicate that the release of SSF by DNBS-primed Lyt 2+ Ts is regulated by the activity of a self-I-A-reactive (i.e., autoreactive) T cell in the tolerant spleen cell population.     

Activation requirements of cloned inducer T cells. I. Differential inhibition by anti-L3T4 or anti-I-A is determined by the accessory cell population

We have described a trinitrophenyl (TNP)-specific inducer clone, clone Ly-1-T1, which responds to a variety of different stimuli, including a) soluble TNP-protein conjugates plus syngeneic (H-2d) spleen cells, b) TNP directly coupled to syngeneic or allogeneic spleen cells, and c) activated I-A identical B cells in the absence of nominal antigen. In the present study we used a panel of antibodies to investigate the recognition structures involved in the activation of clone Ly-1-T1 by these different stimuli. We show that allogeneic spleen cells must be conjugated by using relatively high concentrations of TNBS to be efficient stimulators of the clone. In contrast, syngeneic spleen cells conjugated by using a much wider range of concentrations will activate the clone. The response of the clone to TNP-coupled allogeneic spleen cells is inhibited by anti-L3T4 and anti-Ia antibodies. In contrast, stimulation of the clone with syngeneic spleen cells coupled by using the same concentrations of TNBS is not inhibited with either anti-Ia or anti-L3T4 antibody. The inhibition pattern observed with anti-Ia and anti-L3T4 antibodies was also determined by the nature of the accessory population used to present soluble TNP-protein conjugates. Anti-I-Ad antibodies blocked the activation of clone Ly-1-T1 by TNP-protein plus splenic adherent cells, indicating the involvement of polymorphic I-A determinants in this response. Anti-L3T4 antibody had little or no effect on this response, suggesting that a significant L3T4-Ia interaction is not required. Finally, the response of the clone to activated B cells in the presence or absence of TNP-protein is exquisitely sensitive to inhibition by anti-L3T4 as well as anti-I-A antibodies. The data suggest that the requirement for an L3T4-I interaction depends on the combination of antigen and accessory cell type used to stimulate the clone.     

Characterization of accessory cell function during acute infection of BALB/cByJ mice with mouse hepatitis virus (MHV), strain JHM.

Earlier studies revealed defective concanavalin A-stimulated proliferation and cytokine production by spleen cells derived from BALB/cByJ mice acutely infected with mouse hepatitis virus (MHV), strain JHM. Based on those observations, assays of in vitro antigen-presenting cell (APC) function were undertaken. APC function of unfractionated spleen cells from individual MHV-infected mice was highly variable. Experiments using pooled spleen cells derived from MHV-infected mice revealed that adherent spleen cell APC function was impaired to a much greater degree than B cell APC function. Adherent cells derived from peritoneal exudates of infected mice exhibited an APC defect that was similar in magnitude to that observed for splenic adherent cells. Splenic B cells derived from acutely infected BALB/cByJ mice harbored infectious MHV. In contrast, lysates of adherent spleen cells from acutely infected mice did not kill intracerebrally inoculated neonatal mice, but did induce seroconversion among all survivors. Despite impairment of APC function of cells derived from MHV-infected donors, neither indomethacin nor accessory cells from uninfected control mice restored concanavalin A-induced proliferative responses of spleen cells collected from acutely infected mice. These results and those of earlier studies suggest that, although APC function is impaired, in vitro T cell dysfunction exhibited by spleen cells from MHV-JHM-infected donors is probably related to an inherent proliferative defect subsequent to T cell activation. Defective concanavalin A-stimulated proliferation does not appear to be secondary to accessory cell function suppression or to inhibitory factors secreted by accessory cells.     

Activation of idiotype-specific suppressor T cells by injection of antibody carrying a recurrent idiotype

Intravenous injection of spleen cells (SC) coated with an antitrinitrophenyl (anti-TNP) IgM monoclonal antibody, Sp6 (Sp6-SC), which carries a recurrent idiotype, resulted in activation of a Lyt-2-positive population which did adhere to Sp6-coated plates. No effect of Sp6-SC injection could be observed in vivo on an anti-TNP B-cell response when mice were primed with an immunogenic dose of TNP-horse red blood cells (HRBC), but an anti-TNP response was observed when Sp6-SC-injected mice were primed with a subimmunogenic dose of TNP-HRBC. Furthermore, after intravenous (iv) injection of Sp6-SC, it was no longer possible to suppress a primary anti-TNP response by iv injection of TNP-haptenized thymocytes. In vitro analysis showed that the Sp6-induced suppressor T cell (Ts) population had no measurable influence on TNP-specific naive B cells, nor did it suppress TNP-specific helper T cells (THTNP), but it did lead to counterregulation of TNP-specific suppressor T cells (TsTNP). Hence, iv injection of antibody carrying a recurrent idiotype resulted in activation of a Ts population which functioned as inhibitor of suppression, thus displaying a helper effect.     

Infectious and noninfectious tolerance are blocked by a monoclonal antibody to T-suppressor factor

Two forms of hapten-specific unresponsiveness have been demonstrated following intravenous (iv) injection of hapten-conjugated syngeneic spleen cell based on the nature of the antigen-presenting cell (APC): I-J+, I-A- APC have been shown to induce T-suppressor cells (Ts cells) which are demonstrated upon adoptive transfer, while I-J-, I-A+ APC induce a nontransferable tolerance. In this paper we report that a monoclonal antibody specific for T-suppressor effector cells and factors (14-12) can block the Ts cells induced by I-J+, I-A- APCs and the tolerance induced by I-J-, I-A+ APCs. In addition, it sufficiently overcomes suppression such that injection of TNP-spl iv induces immunity rather than suppression. We show that the I-A+, I-J- TNP-spl, which induce nontransferable tolerance upon iv injection, are the cells which induce immunity in 14-12-treated recipients. These results demonstrate that injection of I-J-, I-A+ APC does not lead to clonal deletion and the tolerance induced by the iv injection of both I-J+, I-A- and I-J-, I-A+ APC operate via Ts cells.     

Distinct subsets of accessory cells activate Thy-1+ triple negative (CD3-, CD4-, CD8-) cells and Th-1 delayed-type hypersensitivity effector T cells.

The SJL strain of mice possess a unique developmental delay in the ability to exhibit delayed-type hypersensitivity (DTH) responses after immunization with a wide variety of Ag. Similar to other models of DTH, the adoptive transfer of syngeneic Ag-pulsed macrophages from DTH-responsive mice into these DTH-unresponsive mice results in the activation of Ag-specific, CD4+ DTH effector Th1 T cells. The absence of other defects in APC-dependent immune responses indicate that the macrophages is the sole APC required for the induction of DTH effector T cells in SJL mice. The defect occurs during the sensitization phase of the DTH response; however, it has not been determined whether a Th cell, which is required for the induction of CD4+ DTH effector T cells, was present in the DTH unresponsive SJL mice. In this study, we have determined that the Thy-1+ helper cell is induced upon Ag stimulation of nonresponder mice and present evidence for the existence of an accessory cell distinct from the macrophage that induces CD4+ DTH effector T cells. Our data indicate that CD4+ DTH effector T cells are induced in an Ag-specific and MHC-restricted manner by an adherent macrophage that expresses the Mac-1+, Mac-2-, Mac-3+, I-A+ phenotype. Adoptive transfer of as few as 100 of the Mac-1+, Mac-2-, or Mac-3+ subsets from DTH responsive donors to DTH unresponsive recipients is able to overcome the DTH deficit. The activation of CD4+ DTH effector T cells in the SJL mouse cells also requires a Thy-1+, Lyt-1+, CD3-, CD4-, CD8-, helper cell. In contrast to the Mac-1+, Mac-3+, I-A+ accessory cell, this helper cell requires an adherent, irradiation resistant, accessory cell that expresses the Mac-1+, Mac-2-, Mac-3-, I-A- surface phenotype for activation. Further, the interaction between this accessory cell and the Thy-1+ helper cell is neither Ag-specific nor MHC restricted. This is the first demonstration of an accessory cell requirement for the Thy-1+, Lyt-1+, B220-, CD4-, CD8-, CD3- DTH Th cell. These data indicate that the activation of the triple negative helper cells and subsequent activation of the CD4+ effector T cells are regulated by two distinct macrophage subpopulations.     

Modulation of suppressor T cell induction with gamma-interferon

The ability of antigen-coupled splenic adherent cells to induce suppressor T cells (Ts) is dependent on the presence of I-J determinants on antigen-presenting cells. After 4 days of in vitro culture, antigen-coupled adherent cells lose the capacity to induce Ts. Supernatants from Con A-stimulated lymphocyte cultures and purified interferon-gamma can sustain accessory function for the induction of Ts. Furthermore, after in vitro culture of splenic adherent cells, there is an apparent correlation between the loss of I-A determinants and the decrease in I-J-restricted Ts induction. Stimulation of Ia expression with interferon-gamma results in a simultaneous increase in the ability to induce Ts. Finally, elimination of I-A-bearing splenic adherent cells with antibody + C eliminates I-J-restricted Ts induction. The combined data imply a co-regulation of I-A and I-J on the antigen-presenting cells involved in the induction of both the Ts1 and Ts3 suppressor T cell subsets.     

Requirements for suppressor cell activation. Role of accessory cells

In the 4-hydroxy-3-nitrophenyl acetyl (NP) suppressor system, third order suppressor cells (Ts3) subset of suppressor cells is generated after Ag priming, but, in order to express suppressor activity, these cells need to be further activated or triggered with a specific second order suppressor factor. By in vitro activation of Ts3-containing lymph node cells or a pTs3 hybridoma we now show that macrophages are also required for Ts3 activation. In addition, we demonstrate that IJ genetic restrictions control this activation process. Furthermore, we directly demonstrate Ts3 activation using cloned macrophage hybridoma cells. To further investigate the interactions between Ts3 cells and the accessory cells involved in their activation, we attempted to block the second order suppressor factor mediated activation of Ts3 cells with antibodies. The activation of Ts3 cells can be blocked by the addition of anti-IJ, anti-IJ idiotype or anti-NPb idiotype antibodies, but not by anti-CD8, anti-IA, or anti-IE antibodies. Anti-IJ mAb blocked Ts3 activation at the lymphocyte level whereas anti-IJ idiotype blocked activation at the accessory cell level. Finally we tested, whether these antibodies can also directly activate primed Ts3 cells. We demonstrate that cross-linked anti-IJ, anti-NPb and anti-CD3 antibodies can activate Ts3 cells. The results are discussed in terms of receptor-ligand structures on Ts and accessory cells which are required for the activation of Ts3 cells.     

创伤小鼠血清,巨噬细胞,Ts细胞对反抑制T细胞的影响

研究了创伤小鼠反抑制T细胞(Tcs)比例、功能的变化及创伤血清、巨噬细胞、抑制性T细胞(Ts)对正常小鼠Tcs细胞的影响。结果表明,创伤小鼠脾细胞中VVL~ 细胞百分率于伤后一过性减少,Tcs细胞在T淋转、IL-2、IL-2R检测系统中的反抑制活性均明显受抑;创伤小鼠血清、巨噬细胞、Ts细胞在体外对正常Tcs细胞反抑制活性(T淋转、IL-2、IL-2R检测系统)均具有不同程度的抑制作用,创伤后4天小鼠血清在体内对正常小鼠脾脏VVL~ 细胞百分率无明显影响,但可明显降低正常小鼠Tcs细胞的反抑制活性。表明创伤可致Tcs细胞比例及功能发生改变,创伤后血清、巨噬细胞、Ts细胞参与介导了Tcs细胞功能的受抑过程。     

In vivo treatment with monoclonal anti-I-A antibodies: disappearance of splenic antigen-presenting cell function concomitant with modulation of splenic cell surface I-A and I-E antigens

A single injection of anti-I-Ak antibody (AB) into H-2k mice resulted in abrogation of splenic antigen-presenting cell (APC) function for protein antigen-primed T cells or alloantigen-specific T cells. Spleen cells from anti-I-A-treated mice are not inhibitory in cell mixing experiments when using cloned antigen-specific T cells as indicator cells, thus excluding a role for suppressor cells in the observed defect. Also, nonspecific toxic effects and carry-over of blocking Ab were excluded as causes for the defect. Experiments with anti-I-Ak Ab in (H-2b X H-2k)F1 mice showed abrogation of APC function for T cells specific for both parental I-A haplotypes. In homozygous H-2k mice, anti-I-Ak treatment not only abrogated APC function for I-Ak-restricted cloned T cells but also for I-AekE alpha k-restricted cloned T cells. FACS analysis of spleen cells from anti-I-Ak-treated (H-2b X H-2k)F1 mice revealed the disappearance of all Ia antigens (both I-A and I-E determined), whereas the number of IgM-bearing cells was unaffected. The reappearance of APC function with time after injection was correlated with the reappearance of I-A and I-E antigen expression. In vitro incubation of spleen cells from anti-I-A-treated mice led to the reappearance of Ia antigen expression and APC function within 8 hr. Thus, it appears that B cells (as determined by FACS analysis) and APC (as determined by functional analysis) behave similarly in response to in vivo anti-I-A Ab treatment. We interpret these findings as suggesting that in vivo anti-I-A treatment temporarily reduces the expression of Ia molecules through co-modulation on all Ia-bearing spleen cells, thereby rendering them incompetent as APC. Such modulation of Ia molecules does not occur when spleen cells are incubated in vitro with anti-I-A antibodies. These results imply that a primary defect purely at the level of APC in anti-I-A-treated mice may be responsible for the observed T cell nonresponsiveness when such mice are subsequently primed with antigen.     

Molecular signals in antigen presentation. II. Activation of cytolytic cells in vitro after ultraviolet radiation or combined gamma and ultraviolet radiation treatment of antigen-presenting cells

Murine low-density spleen cells have potent antigen-presenting ability in a hapten-specific cytolytic T lymphocyte (CTL) system using the hapten azobenzenearsonate (ABA). Exposure of these cells to 0.33 KJ/m2 of ultraviolet radiation (UVR) after coupling to hapten results in markedly inhibited antigen-presenting function that can be substantially corrected or bypassed by interleukin 1 (IL 1). These results have been interpreted to reflect an inhibition of Lyt-1+ T cell activation by UVR-treated APC. Treatment of these cells sequentially with 1500 rad of gamma-radiation (GR) prior to hapten coupling, followed by 0.33 KJ/m2 of UVR radiation after coupling, results in an antigen-presenting defect only minimally improved by IL 1. However, partially purified interleukin 2 (IL 2) can completely bypass or correct this defect. Thus, combined GR and UVR induces a different or more profound defect in APC function when compared to UVR alone. However, these cells do provide a signal(s) other than hapten necessary for CTL activation because ABA-coupled high density spleen cells do not activate CTL cells, even with the addition of IL 2. Fluorescence-activated cell sorter analysis demonstrates that exposure of these low density spleen cells to GR or UVR results in decreased I-A antigen expression at 24 hr than either alone. The addition of nonhapten-coupled low-density APC partially reconstitutes the ability of combined GR/UVR-treated LD-APC to present antigen, and this effect is enhanced by the administration of exogenous IL 1. This occurs despite a lack of significant accessory cell activity by the LD-APC for the ABA hapten, and indicates that combined GR/UVR-treatment of APC is not functionally equivalent to completely removing them.     

Soluble factors in tolerance and contact sensitivity to DNFB in mice. VI. Cellular and lymphokine requirements for stimulating suppressor factor production in vitro

Coculture of spleen cells from mice tolerized with 2,4-dinitrobenzenesulfonate (DNBS) and DNP-labeled spleen cells (DNP-SC) activates Lyt-2+ T suppressor cells (Ts) to synthesize and release a suppressor factor (SSF) into the supernatant, which suppresses the transfer of contact sensitivity to DNFB. The purpose of the present study was to examine in greater detail the signals required to activate DNBS-primed Ts to produce SSF. The supernatant from cultures of tolerant cells and glutaraldehyde-fixed DNP-SC did not have SSF. In contrast, the soluble cell lysate from these cultures did contain the suppressive activity. Pretreatment of glutaraldehyde-fixed DNP-SC with either anti-DNP or anti-class I, but not anti-class II MHC, antibodies blocked SSF synthesis. The addition of IL 1 to cultures of DNBS-tolerant cells and glutaraldehyde fixed DNP-SC restored the ability of the Ts to release the synthesized factor. These results indicate that Ts recognition of the hapten/class I MHC determinant stimulates the synthesis of SSF, and a costimulator is required to induce the release of the factor. The supernatants from cultures of either L3T4-depleted tolerant cells and DNP-SC or tolerant cells and anti-I-A antibody-treated DNP-SC had no SSF activity. The addition of a costimulator (IL 1) also restored the ability of the Ts to release the synthesized factor in cultures of L3T4-depleted tolerant cells and DNP-SC. These results suggest that an L3T4 cell in the DNBS-primed cell population interacts with I-A determinants on a cell in the DNP-stimulator population to initiate the generation of the mediator required for SSF release. This further suggests that the Ts is unable to induce the costimulator from the hapten-presenting cell during interaction with the DNP/class I MHC ligand. Therefore, the production of SSF is regulated not only by the presentation of the appropriate hapten/MHC determinant but also by the interactions of cells that function in generating the costimulator needed to induce release of the suppressor factor.     

Functional analysis of cloned macrophage hybridomas. VI. Differential ability to induce immunity or suppression

We previously screened a series of macrophage hybridomas derived from fusion of P388D1 (H-2d) tumor cells with CKB (H-2k) splenic adherent cells for their ability to induce I-J restricted Ts cell responses. One Ia+ macrophage clone (63) consistently induced Ag-specific, I-J-restricted Ts. To evaluate whether macrophage hybridoma 63 also induced delayed-type hypersensitivity (DTH) immunity, mice were immunized with hapten-coupled macrophage hybridoma cells. Hapten-coupled splenic adherent cells and control macrophage hybridomas induced significant primary DTH responses, whereas hapten-coupled macrophage 63 induced little or no immunity when injected into H-2 compatible hosts. However, macrophage hybridoma 63 specifically activated I-Ak, I-Ad, or I-Ed restricted T cell hybridomas/clones, in vitro in the presence of appropriate Ag. Three different strategies designed to eliminate suppressor cell activity were successfully used to demonstrate that hapten-coupled macrophage 63 could also induce in vivo immunity. First, after immunization with hapten-coupled macrophages, mice were treated with cyclophosphamide. Second, macrophage 63 was treated with anti-IJ idiotype antibody before 4-hydroxy-3-nitrophenyl acetyl hapten (NP) coupling. Finally, haptenated macrophages were injected into I-A compatible but I-J incompatible recipients. These protocols are known to inhibit the induction of Ts activity, thus these results indirectly suggest that there is stimultaneous generation of Ts activity in vivo. The latter hypothesis was tested in adoptive transfer experiments. Transfer of lymph node cells from NP-63 primed B10.BR (H-2k) mice induced immunity in naive 4R animals, whereas the same number of immune cells suppressed NP-induced DTH responses in 5R mice. The combined results indicate that a cloned macrophage line can activate both Th and Ts cells. Macrophages which induce Ts activity may be responsible for maintaining the balance of immunity vs suppression. The data support the hypothesis that IJ interacting molecules (IJ-IM) expressed on macrophages are critical for induction of suppressor cell activity.     

In vivo treatment with anti-I-A antibodies: differential effects on Ia antigens and antigen-presenting cell function of spleen cells and epidermal Langerhans cells

The in vivo activation of T cells by a variety of antigens can be inhibited by the administration of anti-I-A antibodies (Ab) at the time of antigen priming. This inhibition can partially be explained by the temporary loss of Ia molecules from Ia-bearing antigen-presenting cells (APC) in the spleen. In this study, the effects of i.p. injected monoclonal Ab specific for I-A glycoproteins of different H-2 haplotypes on Ia antigen expression and APC function of spleen cells and epidermal Langerhans cells were compared. It was found that anti-I-A Ab quickly bound to both spleen cell and Langerhans cell Ia antigens. Although spleen cell Ia antigens were modulated and thus temporarily disappeared, Ia antigen expression by epidermal Langerhans cells was not modulated. In functional studies, the capacity of spleen cells and epidermal cells from anti-I-A Ab treated vs control animals to function as APC for antigen-specific, I-A- or I-E-restricted T cell clones was tested. A single injection of anti-I-A Ab completely abolished the APC function of spleen cells as shown in several inbred mouse strains, F1 animals, and with the use of several different Ab and T cell clones. In contrast, Langerhans cell-dependent APC function of epidermal cells remained completely unaltered. Even multiple injections of high doses of Ab never caused any inhibition of Langerhans cell function. Experiments with anti-I-Ak or anti-I-Ad Ab in an (H-2k X H-2d)F1 animal showed abrogation of APC function of spleen cells, but again not of Langerhans cells. Thus in vivo anti-I-A Ab administration appears to differentially affect Ia antigen expression and APC function from spleen and epidermis: Ia antigens are modulated from spleen cells but not from epidermis, and APC function disappears in the spleen but not in the epidermis. The abrogation of splenic but not of Langerhans cell APC function with anti-I-A Ab will facilitate the dissection of the relative contributions of Langerhans cells as compared with other APC in the generation of cutaneous immune responses.