Anti-Qa-2-induced T cell activation. The parameters of activation, the definition of mitogenic and nonmitogenic antibodies, and the differential effects on CD4+ vs CD8+ T cells

The MHC Ag Qa-2 is a glycolipid anchored class I molecule expressed at high levels on all peripheral T lymphocytes. In this study we found that anti-Qa-2 antibodies could stimulate the proliferation of murine T cells in vitro. Anti-Qa-2-induced proliferation required secondary cross-linking with anti-Ig antibody and the presence of PMA. Only Qa-2+ strains could be induced to proliferate by anti-Qa-2 antibody, but under the conditions employed, anti-CD3 could induce proliferation in Qa-2+ and Qa-2-strains. Interestingly, only anti-Qa-2 reagents directed against the alpha 3 domain of the Qa-2 class I molecule were effective in inducing proliferation. Furthermore, unlike purified CD4+ cells, purified CD8+ cells were unable to be stimulated by the anti-Qa-2 antibodies. These results lead to the inclusion of Qa-2 in a group of physiologically relevant, glycolipid-anchored, cell-surface molecules, mobilization of which can generate signals that initiate the proliferation of T cells. Such molecules may play a secondary role in cellular activation after the primary engagement of the TCR.     

The anti-T cell monoclonal antibody 9.3 (anti-CD28) provides a helper signal and bypasses the need for accessory cells in T cell activation with immobilized anti-CD3 and mitogens

CD28 is an antigen of 44 kDa which is expressed on the membrane of the majority of human T cells. The present study examines the functional effects of an anti-CD28 monoclonal antibody (mAb 9.3) on T cell activation induced with immobilized anti-CD3 mAb OKT3 or with mitogens, in the absence of accessory cells. To this end, we used blood resting T cells that were completely depleted of accessory cells (monocytes, B cells, and natural killer cells), and consequently did not respond to recombinant interleukin-2 (rIL-2), to immobilized OKT3, to PHA, or to Con A. Addition of mAb 9.3 to the cultures enhanced IL-2 receptor expression (Tac antigen) on PHA- or immobilized OKT3-stimulated T cells and induced IL-2 receptors on Con A-stimulated T cells. Moreover, addition of mAb 9.3 to cultures of T cells stimulated with PHA, Con A, or immobilized OKT3 resulted in IL-2 production. Soluble mAb 9.3 was a sufficient helper signal for T cell proliferation in response to PHA or immobilized OKT3. Crosslinking of mAb 9.3 by culture on anti-mouse IgG-coated plates enhanced the helper effect and was an essential requirement for the induction of T cell proliferation in response to Con A. No other anti-T cell mAb (anti-CD2, -CD4, -CD5, -CD7, -CD8) was found to provide a complete accessory signal for PHA or Con A stimulation of purified T cells. T cell proliferation induced by the combination of PHA and mAb 9.3 was strongly inhibited by the anti-IL-2 receptor mAb anti-Tac. In conclusion, mAb 9.3 can provide a signal bypassing monocyte requirement in T cell activation with immobilized OKT3, PHA, and Con A, resulting in an autocrine IL-2-dependent pathway of proliferation.     

Signal transduction through class I MHC by a monoclonal antibody that detects multiple murine and human class I molecules.

We have generated a hamster anti-mouse class I reactive mAb that is capable of activating T cells in the presence of the cofactor PMA, as assayed by both IFN-gamma production and cellular proliferation. This mAb detects an epitope present on the majority of murine class I molecules, with the known exceptions of H-2Kk and H-2Kq, and is therefore not beta 2-microglobulin-specific. It also recognizes multiple human class I molecules. The epitope recognized by this antibody maps to the class I alpha 1 domain. The activation properties of this mAb are not mediated exclusively through the glycosylphosphatidylinositol-linked Qa-2 molecule, as the antibody activates spleen cells from Qa-2 negative strains. Although class I molecules are not usually considered as activation Ag, these data demonstrate their potential for involvement in signal transduction.     

Biochemical characterization of the molecules reactive with Qa-6 antiserum and the monoclonal antibody 20-8-4: evidence for structural similarity with the Qa-2 molecule

The Qa-6 alloantigen and the molecule that crossreacts with the monoclonal antibody (mAb) 20-8-4 have been shown to be serologically distinct from the Qa-2 alloantigen by strain distribution and tissue distribution, respectively. In this report, we address the biochemical relationships among Qa-2, Qa-6, and the 20-8-4 cross-reactive molecule by using immunoprecipitation and polyacrylamide gel electrophoresis. Each of these molecules had an apparent m.w. of approximately 41K and was associated on the cell surface with beta 2-microglobulin. Removal of N-linked oligosaccharides with endoglycosidase F reduced their apparent m.w. to approximately 33K to 34K. The determinants recognized by anti-Qa-6 and mAb 20-8-4 were shown to reside on the same molecule(s) precipitated by anti-Qa-2 sera by immunodepletion experiments. The mAb 20-8-4 was also shown to preclear the molecules detected by the Qa-6 and Qa-2 antisera. Two-dimensional gel electrophoresis analysis demonstrated complete co-migration of the approximately 41K molecules detected by the three antibodies. By peptide map analysis with V8 protease, all three molecules appeared identical. Also, the determinant recognized by Qa-6 antiserum co-modulated with that recognized by the anti-Qa-2 mAb D3.262. Taken together, these results demonstrate that the molecules recognized by these three antisera and/or mAb are biochemically indistinguishable. These data, in conjunction with the serologic and genetic findings suggest that mAb 20-8-4 recognizes a molecule that is biochemically similar and possibly identical to the Qa-2 antigen. Moreover, although the genetic, serologic, and biochemical data demonstrate that Qa-6 is not controlled by the Qa-2 locus, but rather by a gene telomeric to Qa-2, the molecule bearing the Qa-6 determinant is very similar, if not identical, to the Qa-2 molecule. Several possible explanations for these discrepancies are discussed.     

Activation of cord T lymphocytes. I. Evidence for a defective T cell mitogenesis induced through the CD2 molecule

A study was carried out on cord blood T cell activation via the CD2-mediated pathway. Despite similar percentages of circulating CD3+ and CD2+ cells in adult and cord blood, the proliferation of cord PBMC to the anti-CD3 mAb and cord T cells to anti-CD2 mAb were defective. The T cell CD3-surface structure was normally able to control CD2-mediated activation, as its modulation by a non-mitogenic anti-CD3 mAb blocked cord PBMC proliferation induced by anti-CD2 mAb. CD2-stimulated cord T cells did not proliferate and did not produce a significant amount of IL-2 in culture, although they expressed the IL-2R. This observation was confirmed by the optimal proliferation of CD2-induced cord T cells when rIL-2 was added. Despite the alternative T cell activation pathway is monocyte-independent in adults, the defective cord T cell activation via the CD2 molecule could also be bypassed by the addition of PMA, small amounts of either autologous or allogeneic adult and cord AC or simply rIL-1 alone. Our findings provide evidence for an intrinsic functional defect in cord CD2-mediated T cell activation, which is linked to an impaired increase of free cytoplasmic calcium, as confirmed by the effectiveness of calcium ionophore A23187 in restoring a good CD2-induced cord T cell proliferation and by measurement of cellular calcium uptake after activation via the CD2 molecule. The characteristics of cord T cells revealed by this study recall the thymocyte functional pattern and may represent functional expression of the previously described phenotypic immaturity of cord T cells.     

Stimulation of human Jurkat cells by monoclonal antibody crosslinking of transfected-Ly-6A.2 (TAP) molecules.

Monoclonal antibody crosslinking of phosphatidylinositol-anchored Ly-6A.2 molecules on the surface of murine T lymphocytes leads to cell activation and secretion of IL-2. To examine the potential activity of these molecules in human T cells we transfected the Ly-6A.2 gene into Jurkat cells. Transfection of Jurkat cells with genomic Ly-6A.2 sequences results in low levels of Ly-6A.2 on the cell surface. However, linking the Ly-6A.2 sequences to the enhancer from the human CD2 gene results in greatly increased expression of Ly-6A.2. These molecules are anchored to the membrane via a phosphatidylinositol linkage. Crosslinking of Ly-6A.2 molecules with soluble mAb stimulates the transfected Jurkat cells to produce IL-2. This stimulation is abrogated by treatment with phosphatidylinositol-specific phospholipase C. The transfected human T cells displayed the same unusual crosslinking requirements for stimulation with anti-Ly-6A.2 mAbs as previously observed for murine T cells. Crosslinking of Ly-6A.2 with soluble antibodies is stimulatory, whereas immobilized antibodies are inactive. The crosslinking requirements for antiCD3 mAb stimulation display a reciprocal pattern. These data demonstrate that the Ly-6A.2 pathway for T cell activation is conserved between human and murine T cells.     

Heterologous cross-linking of Lyt-2 (CD8) to the alpha beta-T cell receptor is more effective in T cell activation than homologous alpha beta-T cell receptor cross-linking

Ag recognition of Lyt-2 (CD8)-positive T lymphocytes requires the presentation by APC of a suitably processed Ag in association with MHC class I molecules. In previous studies we have obtained evidence that, for optimal activation, both the alpha beta-TCR and Lyt-2 have to participate in this recognition process. In the current study we investigate the functional consequences of limited cross-linking of these cell surface molecules by using soluble, dimeric hetero- and homoconjugates of mAb to Lyt-2 and to the TCR beta-chain (F23.1). Heterologous cross-linking of Lyt-2 to the TCR induced a vigorous, selective Lyt-2+ T cell proliferative response. Functionally active cytotoxic cells were generated, and a high frequency of responding cells was observed in limiting dilution analyses. In contrast, homologous TCR cross-linking initiated a less pronounced proliferation with a relatively low frequency of response, whereas Lyt-2 cross-linking resulted in no cellular proliferation. Significant T cell activation occurred with exposure to anti-Lyt-2: F23.1 mAb dimers at concentrations an order of magnitude lower than those required for stimulation by F23.1:F23.1 mAb dimers. The induction of proliferation by mAb dimers occurred in the absence of Fc components and in rigorously APC depleted, purified T cell preparations. Effective stimulation of resting T cells could be induced also by heterodimers of monovalent Fab fragments. Heterologous cross-linking of Lyt-2 to the TCR was superior to homologous TCR cross-linking primarily with respect to proliferation in IL-2 containing media and to IL-2R expression, whereas proliferation in response to other lymphokines and the production of IL-2 itself were similar under both cross-linking regimens. Thus, when linked to the TCR, Lyt-2 contributed a strong, positive signal toward IL-2-dependent growth of resting T cells. We assume that in the case of Ag-driven T cell activation, the class I MHC molecule acts as the physiologic cross-linking ligand for Lyt-2 and the TCR.     

Suppression of Ia-unrestricted primary anti-Qa-1 cytotoxic T lymphocyte responses by class II major histocompatibility complex-restricted cellular interactions

A model has been established for investigating the cellular interactions for the generation and regulation of primary cytotoxic T lymphocyte (CTL) responses to Qa-1 alloantigens. Although NZB anti-BALB/c one-way mixed leukocyte cultures (MLC) generate anti-Qa-1b CTL, anti-Qa-1 CTL responses are not generated during BALB/c anti-NZB one-way MLC or during two-way MLC with NZB and BALB/c spleen cells. However, depletion of L3T4+ cells from the spleens of BALB/c mice before two-way MLC with NZB spleen cells resulted in anti-Qa-1b CTL responses. Likewise, the addition of anti-L3T4 monoclonal antibody (mAb) or anti-I-Ad mAb to two-way MLC with NZB and BALB/c spleen cells resulted in the generation of anti-Qa-1b CTL. Conversely, anti-Lyt-2 mAb inhibited the generation of anti-Qa-1 CTL. These data indicate that class II major histocompatibility complex-restricted cellular interactions are capable of suppressing the generation of Ia-unrestricted anti-Qa-1 CTL responses by Lyt-2+ responder cells. This model provides a novel opportunity to both characterize the cellular interactions responsible for regulating primary CTL responses to the Qa/Tla-encoded class I molecule Qa-1, and determine the contribution of this L3T4+ Ts-dependent defect in NZB mice to the pathogenesis of autoimmunity.     

Human T cell activation. Synergy between CD73 (ecto-5'-nucleotidase) and signals delivered through CD3 and CD2 molecules

Interaction of the glycosyl phosphatidylinositol-linked differentiation Ag CD73 (ecto-5'-nucleotidase) with the CD73-specific mAb 1E9 generates agonistic signals that strongly synergize with T cell activation induced by CD3 and CD2 mAb. This synergy is observed only when 1E9 is immobilized on plastic and occurs in the absence of accessory cells or exogenous lymphokines. 1E9 induces a rapid (though transient) increase in [Ca2+]i in a minor proportion (20 to 30%) of unfractionated T lymphocytes (presumably CD73+ cells). However, this [Ca2+]i mobilization is not sufficient to fully activate CD73+ T cells, as shown by the requirement of additional signals such as CD3 or CD2 stimulation to initiate T cell proliferation. These signals cannot be substituted by the exogenous lymphokines, rIL-1, rIL-2, or rIL-4, or PMA (when T cells are rigorously depleted of monocytes). These data indicate that CD73 may behave as an accessory molecule regulating interactions between T cells and antigens or APC. A comparison was carried out with mAb 9.3 to the differentiation Ag CD28, another agonistic molecule with activating properties similar to CD73. Despite their lower percentage, the ability of CD73+ T cells to amplify the proliferation induced by CD3 or CD2 mAb was equivalent or even greater than that of CD28+ T cells. Once activated, CD73+ cells may recruit the remaining (CD73-) cells primed by CD3 or CD2 stimulation. Based on these data, we suggest that CD73+ T lymphocytes may be a specialized subset to amplify immune responses originated by the CD3 and CD2 activation pathways. Finally, the functional association between CD73 and integral membrane molecules like CD3 and CD2 suggests that GPI-anchored molecules may play a role in transmembrane signaling mediated by conventional second messenger systems.     

Anti-CD4 monoclonal antibodies enhance phorbol 12-myristate, 13-acetate-induced activation of human T cells

Evidence exists which indicates that the T cell differentiation molecule CD4 may interact with nonpolymorphic determinants of major histocompatibility complex (MHC) class II antigens on accessory cells to stabilize the formation of a ternary complex formed by the T cell receptor (CD3-TcR), antigen, and MHC class II restriction element. However, there is also evidence which suggests alternative or additional functional roles of CD4 in the delivery of signals to T cells independent of MHC class II recognition. In the present study, we examined different anti-CD4 monoclonal antibodies (mAbs) for their ability to influence lymphocyte proliferation induced by phorbol 12-myristate, 13-acetate (PMA). We found that the response of human peripheral blood mononuclear cells to PMA could be enhanced by some anti-CD4 mAbs (OKT4, OKT4A) but not by others (G17-2). This enhancement was due neither to a direct action of the mAbs on the monocytes nor to intercellular crosslinking through an Fc-Fc receptor interaction. We also found that the binding of anti-CD did not influence the down-regulation of CD4 expression induced by PMA, ruling out any correlation between increased stimulation and CD4 modulation. Our results, taken together with those recently published on the ability of a soluble anti-CD4 mAb (B66) to induce lymphocyte activation by itself, provide evidence that CD4 antigen plays a positive functional role in T cell stimulation in addition to stabilizing the antigen-antigen receptor interaction.     

Stimulation of human T cells via anti-T cell receptor monoclonal antibody BMA031: distinct cellular events involving interleukin-2 receptor and lymphocyte function antigen 1

We have analyzed activation of resting human T cells by anti-T cell receptor (TCR) monoclonal antibody (mAb) BMA031, a murine mAb of the G2b isotype. Human peripheral blood lymphocytes (PBL) respond to anti-TCR mAb by short-term proliferation in vitro and by acquisition of responsiveness to interleukin 2 (rIL-2) in the absence of detectable IL-2 production. Cell depletion and limiting dilution experiments indicate that anti-TCR mAb +/- rIL-2 stimulation covers a substantial portion of human T cells, including CD4+ and CD8+ cells. Enhancement by rIL-2 of anti-TCR mAb-induced proliferation is blocked by anti-IL-2 receptor (IL-2R, p55) mAb, while anti-TCR mAb-induced proliferation is not. In contrast, anti-TCR mAb-induced proliferation is blocked by anti-lymphocyte function antigen 1 (LFA-1, CD11a) mAb and is not demonstrable in PBL from two patients with severe congenital LFA-1 deficiency, not even in the presence of irradiated LFA-1+ PBL. We conclude that stimulation of resting human T cells by anti-TCR mAb BMA031 enables dissociation of distinct steps in T cell activation that specifically require participation of IL-2R (p55) and LFA-1 cell surface molecules in a mutually exclusive way.     

Activation of Lyt-2+ (CD8+) and L3T4+ (CD4+) T cell subsets by anti-receptor antibody

The mAb F23.1, specific for V beta 8-related determinants on the TCR, was used to study the requirements for TCR cross-linking and for accessory cells (AC) in the induction of proliferation or IL-2 responsiveness in L3T4+ (CD4+) and Lyt-2+ (CD8+) T cells. T cells were exposed in vitro to soluble native F23.1 antibody, to heteroconjugates composed of the Fab fragments of F23.1 linked to Fab fragments of antibodies specific for Ia determinants on AC, or to F23.1 immobilized on an insoluble matrix. Soluble F23.1 antibody-induced proliferation in naive T cells only in the presence of both AC and exogenous IL-2, and these responses were confined to Lyt-2+ T cells. In contrast, heteroconjugates capable of crosslinking F23.1+ TCR to AC surface Ia determinants were capable of inducing proliferation in both L3T4+ and Lyt-2+ T cells in the absence of added lymphokine. Moreover, binding to and presumably multi-valent crosslinking of the TCR by immobilized F23.1 was sufficient to induce proliferation in both Lyt-2+ and L3T4+ T cells in the absence of AC or exogenous IL-2. Further, it was found that the conditions necessary for T cell growth factor secretion paralleled closely those required for induction of T cell proliferation in the absence of added lymphokine, suggesting that production of endogenous lymphokine might be the limiting process for triggering of T cell proliferation. Taken together, these findings suggest that under optimal conditions of TCR cross-linking, TCR occupancy and cross-linking is sufficient to deliver all of the signals necessary to initiate proliferation in naive populations of both L3T4+ and Lyt-2+ T cells. However, when conditions for TCR signaling are suboptimal, as may be the case for normal Ag-mediated stimulation, a role for second signals delivered by AC or exogenous lymphokines can become critical for T cell activation.     

Two roles for CD4 cells in the control of the generation of cytotoxic T lymphocytes.

The generation of CTL against Qa-1 Ag in C57BL/6 (B6) (Qa-1b) and B6.Tlaa (Qa-1a) congenic strains requires in vivo priming with the Qa-1 alloantigen together with a helper Ag, such as H-Y. The primed precursors obtained from these female mice generate Qa-1-specific CTL activity upon culture in vitro. Although the presence of the H-Y helper Ag is not required for the in vitro sensitization, no response occurs in the absence of CD4 cells. Addition of unprimed B6.Tlaa CD4 cells from Qa-1 incompatible radiation bone marrow chimeras (B6.Tlaa----B6), that are presumably tolerant to Qa-1b, provide helper activity for Qa-1b-specific CTL. This indicates that although CD4 cells are obligatory for the Qa-1 response, they need not be specific for alloantigens on the APC to generate helper activity in in vitro cultures. Addition of unirradiated B6 CD8-depleted spleen cells to CD4-depleted B6.Tlaa anti-B6 cultures in the presence of either B6.Tlaa CD4 cells or rIL-2 prevents the generation of Qa-1 specific CTL. This inhibition is not due to an anti-idiotypic Ts cell since B6.Tlaa----B6 chimeric cells do not suppress an anti-Qa-1b response. Rather, this finding is consistent with that of a veto cell mechanism. To determine whether CD4 cells themselves exhibit veto activity, highly purified CD4 populations were tested for their ability to inhibit the generation of Qa-1-specific CTL. CD4 cells precultured for 2 to 3 days with Con A and rIL-2 specifically inhibit CTL activity whereas resting cells do not, similar to that noted for CD8 veto cells. The relative efficiency of activated CD4 cells is greater than that of resting NK cells but is less than that of activated CD8 or NK cells. Thus, CD4 cells not only provide helper activity for CTL precursors, but also act as veto cells to prevent the generation of CTL activity.     

Evidence for the existence of distinct heterogeneity among the peripheral CD4-CD8- T cells from MRL-lpr/lpr mice based on the expression of the J11d marker, activation requirements, and functional properties

Autoimmune-susceptible, MRL-lpr/lpr (lpr) mice develop a profound lymphadenopathy resulting from the accumulation of CD4-CD8- (double-negative, DN) cells in peripheral lymphoid organs. The source and the mechanism of this abnormal accumulation of cells is still unknown. Recently, we reported that a significant number (approximately 35%) of the CD4-CD8- cells expressed J11d, a marker expressed by immature thymocytes but not by mature functional peripheral T cells. In the present study, we investigated the phenotype, growth requirements, and functional properties of purified J11d+ and J11d- subpopulations. Using the mAb, F23.1, which recognizes a TCR determinant encoded by the V beta 8 gene family, it was observed that approximately 30% of the J11d+ and J11d- DN cells expressed this determinant. Further studies on the thymus revealed that J11d+ DN cells from lpr thymus also contained F23.1+ cells (approximately 25%), whereas, similar cells from normal MRL(-)+/+mice were all F23.1-, consistent with earlier reports in other normal strains. Further phenotypic studies revealed that the peripheral J11d+ and J11d- cells from lpr mice were similar in expressing CD3, Ly-5 (B220), and Ly-24 (Pgp-1) determinants. When stimulated with phorbol myristic acetate (PMA) and recombinant IL-2 (rIL-2), only J11d- cells but not J11d+ cells responded by proliferation. However, in the presence of calcium ionophore (A23187) and PMA, both J11d+ and J11d- subpopulations proliferated by producing and responding to endogenous IL-2 but not IL-4. The lymph node T cells from 1-month-old MRL-lpr/lpr mice responded strongly when stimulated with PMA + rIL-4 or PMA + rIL-6. In contrast both J11d+ and J11d- subpopulations failed to respond when similarly stimulated. The J11d+ but not J11d- cells demonstrated spontaneous cytotoxic activity against the NK-sensitive YAC-1 tumor targets. The J11d- cells did not exhibit cytotoxic potential in spite of culture with PMA + rIL-2. Even after repeated culture in vitro with PMA + A23187 or PMA + rIL-2, both J11d+ and J11d- subpopulations failed to express the mature phenotype bearing CD4 and/or CD8 antigens. The present study demonstrates the expansion of unique J11d+, alpha beta-TCR+, DN T cells with cytotoxic potential in lpr mice and further suggests the existence of phenotypic and functional heterogeneity among the abnormal lpr DN cells.     

CD3Ti+ human thymocyte-derived clones displaying a differential response to activation via CD3Ti and CD2

Previous studies indicated that, unlike peripheral T-cells, freshly isolated thymocytes show little or no proliferation to activation signals via either the antigen/MHC receptor complex (CD3Ti) or the CD2 structure, unless exogenous IL-2 or phorbol esters are added. To investigate these differences in more detail, we have studied the response of clonal populations of mature thymocyte subsets as well as peripheral T-cell clones to activation via either CD3Ti or CD2. Here we report the characterization of three clones belonging to different subsets of mature thymocytes: CD3+ CD4+ (Ti alpha/beta), CD3+ CD8+ (Ti alpha/beta), and CD3+ CD4- CD8- (Ti gamma/delta). All three clones could be induced to proliferate to insolubilized anti-CD3 mAb. In contrast, activating anti-CD2 mAbs, which induced proliferation in all peripheral T-cell clones tested, did not induce an appreciable proliferation of the thymocyte clones. The latter required additional signals provided by the phorbol ester PMA. However, anti-CD2 mAbs were able to induce early activation events such as phosphoinositide turnover and [Ca2+]i increase to an extent similar to the ones elicited by anti-CD3 mAb. These results further support previous findings suggesting that mature thymocytes are not functionally identical to peripheral T-cells.     

Recognition by cytotoxic T lymphocytes of Qa-2 antigens. Sensitivity of Qa-2 molecules to phosphatidylinositol-specific phospholipase C

Con A splenic lymphoblasts were incubated with phosphatidyl-inositol specific phospholipase C (PIPLC) derived from Bacillus thuringiensis and subsequently analyzed for Qa-2 Ag with the Qa-2 reactive mAb Qa-m2. This treatment completely removed Qa-2 detectable Ag on lymphoblasts from H-2d animals, indicating that these molecules are likely anchored to the cell membrane through phosphatidyl inositol (PI). Although exposure of lymphoblasts from H-2b mice to PIPLC greatly reduced Qa-2 expression, a subpopulation of cells retained a limited quantity of the Ag. Bulk cultured anti-Qa-2 CTL generated against the Qa-2 region from H-2b haplotype mice lysed Qa-2+ targets from B6.K2 (H-2b) and BALB/cJ (H-2d) animals. Pretreatment of these lymphoblast targets with PIPLC completely abolished lysis of the BALB/cJ target cells, whereas lysis of B6 targets was reduced only slightly. Anti-Qa-2 CTL clones tested against PIPLC-treated B6 target cells revealed two patterns of reactivity. One group of clones was unaffected in its ability to lyse PIPLC-pretreated targets and cross-reacted on Q6d/Ld molecules expressed on transfected L cells. A second group was unable to lyse PIPLC-pretreated lymphoblasts and cross-reacted on Q7d/Ld targets. These data suggest that H-2b-derived lymphoblasts express two different types of Qa-2 molecules with respect to PIPLC sensitivity; one type is sensitive to PIPLC and cross-reactive with Q7d, the other type is resistant to PIPLC and cross-reactive with Q6d. In contrast, H-2d lymphoblasts express only the PIPLC-sensitive type of molecules. It was also noted that bulk cultured anti-Qa-2 CTL more readily lysed H-2b target cells expressing a smaller quantity of PIPLC-resistant Ag than H-2d targets expressing a larger amount of PIPLC-sensitive Ag. Further, anti-Qa-2 CTL clones readily lysed PIPLC-treated target cells expressing very low levels of serologically detectable Qa-2. This suggests that recognition of class I molecules anchored to the membrane via a PIPLC-resistant linkage may more readily activate CTL for expression of lytic activity than molecules anchored through PI.     

A monoclonal antibody recognizing 68- to 75-kilodalton protein(s) associated with the human IL-1 receptor

We produced an IgM mAb termed 4.9 against an EBV-containing lymphoblastoid cell line, termed 3B6. This mAb reacted with both various B and T cell lines such as HSB2 cells, with an NK-like cell line YT-C3 cells, and with human fibroblast MCR-5 cells. It also reacted with normal resting peripheral B lymphocytes, monocytes, and anti-CD2- or anti-CD3-activated T lymphocytes. The 4.9 mAb immunoprecipitated two bands estimated to be of Mr 68 and 75 kDa from iodinated 3B6 cells. The 4.9 mAb inhibited the proliferation of peripheral T lymphocytes induced either by anti-CD3 mAb or anti-CD2 mAb. The 4.9 mAb inhibited also the proliferation of murine thymocytes both in the presence of PHA and IL-1 and the proliferation of human fibroblasts in the presence of IL-1. Radiolabeled IL-1 binding on 3B6 cells revealed two types of IL-1 binding sites with high and low affinity for IL-1 (300 sites/cell with a Kd of 6 x 10(-11)M and 6000 sites/cell with a Kd of 3 x 10(-9)M). On both 3B6 and YT-C3 cells, mAb 4.9 inhibited specifically the binding of 125I-labeled rIL-1, alpha or beta, whereas the irrelevant IgM mAb did not. Conversely, rIL-1, alpha or beta, could inhibit specifically the binding of radioiodinated 4.9 mAb to 3B6 or YT-C3 cells, whereas rIL-2, rIFN, or the irrelevant IgM mAb were ineffective. 125I-4.9 mAb bound 3B6 cells with an association constant (Ka) of 2 x 10(8)/M and demonstrated 6000 binding sites/cell. We thus conclude that mAb 4.9 recognizes a protein complex (68 to 75 kDa) closely associated with the IL-1R.     

Agents that mimic antigen receptor signaling inhibit proliferation of cloned murine T lymphocytes induced by IL-2

We have shown previously that stimulation of cloned murine T lymphocytes via the TCR inhibits their responsiveness to rIL-2. Signaling via the TCR is believed to result in a variety of biochemical events that include a rise in intracellular free calcium and activation (translocation) of protein kinase C. These two signals also can be generated by calcium ionophores, such as ionomycin, and by activators of protein kinase C, such as PMA. We report here that treatment of cloned murine T lymphocytes with PMA, ionomycin, or the combination led to a dose-dependent inhibition of IL-2-dependent proliferation but did not inhibit lymphokine secretion. Concentrations of PMA and ionomycin that maximally inhibited proliferation stimulated maximal lymphokine secretion and increased mitochondrial activity as assessed by measurement of cleavage of 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium-bromide. Furthermore, PMA, ionomycin, the combination, or immobilized anti-CD3 mAb added after 12 to 16 h of culture with IL-2 could inhibit proliferation. These results demonstrate that PMA and ionomycin mimic stimulation of the TCR by high concentrations of immobilized anti-TCR mAb in that proliferation is inhibited and lymphokine secretion is induced. In addition, PMA or ionomycin could independently inhibit proliferation of some cells. These findings suggest that alternative mechanisms exist to regulate proliferation. Either increased levels of intracellular calcium or the physiologic events corresponding to those induced by PMA can inhibit IL-2-dependent replication of T lymphocytes.     

Clonal analysis of the anti-Qa-1 cytotoxic T lymphocyte repertoire: definition of the Qa-1d and Qa-1c alloantigens and cross-reactivity with H-2

To characterize the four common Qa-1 allelic products, we examined in detail the CTL-defined determinants encoded by Qa-1. In previous studies with anti-Qa-1 CTL and alloantisera, investigators have described antigenic determinants present on Qa-1a and Qa-1b antigens, but they have defined Qa-1c and Qa-1d exclusively by their cross-reactivity with Qa-1a and/or Qa-1b determinants. To delineate further the CTL-defined determinants encoded by Qa-1d, we generated CTL clones with Qa-1d specificity and demonstrated that the Qa-1d molecule expressed determinants that were not detected on Qa-1a, Qa-1b, or Qa-1c target cells. Other CTL clones derived from anti-Qa-1d MLC recognized new antigenic determinants on Qa-1c that cross-reacted with Qa-1d. Each of the four common Qa-1 phenotypes was shown to exhibit unique antigenic determinants. In addition, Qa-1d anti-Qa-1a and Qa-1d anti-Qa-1b CTL confirmed extensive cross-reactivity among these Qa-1 alloantigens. Analysis of CTL from these four immunizations also resulted in the isolation of Qa-1a-specific and Qa-1d-specific CTL clones that cross-reacted with H-2Df and H-2Ks, respectively.