Effects of monoclonal antibodies directed against murine T lymphocyte cell surface antigens on lymphokine production by cloned T lymphocytes reactive with class I MHC or Mls alloantigens

Monoclonal antibodies recognizing murine T lymphocyte cell surface structures implicated in T lymphocyte-mediated cytolysis, including Lyt-2, L3T4, LFA-1, and a cytolytic T lymphocyte (CTL) clonotypic determinant, were used as probes to investigate the role of these structures in lymphokine production by T cell clones induced by antigen or lectin. The clone-specific antibody 384.5 bound to and inhibited antigen-induced lymphokine production by the L3 CTL clone, but did not affect lymphokine production by other T cell clones. Antibodies against the T cell surface structures Lyt-2 or L3T4, which are expressed by mutually exclusive T cell subsets, inhibited antigen-induced lymphokine production by class I major histocompatibility complex (MHC) antigen-reactive CTL clones or an M1s-reactive helper T lymphocyte (HTL) clone, respectively. Antibody against the broadly distributed LFA-1 molecule inhibited antigen-induced lymphokine production by all of the clones tested. Lectin-induced lymphokine production by cloned T cells was not inhibited by the clonotypic antibody, anti-Lyt-2, or anti-LFA-1; slight inhibition of the HTL clone was observed with the anti-L3T4 antibody. None of these structures appear to be uniquely involved with a particular functional response. Our results suggest that each of these structures is involved with the interactions between the effector cell and the stimulating cell leading to lymphokine production.     

Clonal analysis of cytolytic T lymphocyte-mediated lysis of target cells with inducible antigen expression: correlation between antigen density and requirement for Lyt-2/3 function

The lysis by allospecific cytolytic T lymphocytes (CTL) of the BALB/c lymphoma ST-4.5, a cell line that can be induced by interferon-gamma (IFN-gamma) to express increased amounts of major histocompatibility complex (MHC) class I antigens, was investigated. Culture of ST-4.5 in IFN-gamma increased the surface expression of Kd molecules from originally low levels and Dd from undetectable amounts by approximately fivefold as determined by fluorescence-activated cell sorter (FACS) analysis, whereas the levels of several other antigens (Ld, I-Ad, Thy-1, Lyt-2, L3T4, and LFA-1) were not affected. The lysis of ST-4.5 by Dd- and Ld-specific CTL clones correlated with the expression of those antigens on target cells as determined by both FACS and biochemical analysis. Lysis of ST-4.5 by CTL clones specific for Kd antigen fell into two distinct groups: those that could lyse targets cultured either normally or in IFN-gamma, and those that could only lyse targets that had been precultured in IFN-gamma. The apparent sensitivity to antigen exhibited by the Kd-specific CTL clones predicted their sensitivity to inhibition of target lysis by anti-Lyt-2/3 antibody. Those CTL clones that were only active against ST-4.5 expressing higher amounts of surface antigen (resulting from IFN-gamma preculture) were readily inhibited by anti-Lyt-2/3 antibody, whereas those CTL capable of lysing normally cultured targets having lower amounts of surface antigen were heterogeneous in their sensitivity to anti-Lyt-2/3; some were inhibitable, whereas others were resistant. In addition, another CTL clone that was resistant to inhibition by anti-Lyt-2/3 alone was readily inhibited by a synergistic combination of anti-Lyt-2/3 plus anti-Kd (but not anti-Dd or Ld) antibodies. These results indicate that CTL antigen receptor sensitivity to (or affinity for) antigen and the level of specific antigen expression by the target cell may both be important criteria in assessing Lyt-2/3 molecule function in CTL-mediated cytolysis. The function of recognition-associated molecules such as Lyt-2/3 may be to strengthen and increase the number of receptor-ligand binding events that facilitate CTL-target membrane interactions that lead to the lysis of the target cell.     

Effects of anti-Lyt-2 and anti-L3T4 monoclonal antibodies on the function of cytotoxic T lymphocyte/helper T lymphocyte hybrid T cell clones

CTL/HTL hybrid clones provide a unique system that allows detailed analysis of the role of Lyt-2, L3T4, and other structures involved in T cell functions. We have demonstrated previously that the fusion of cloned murine CTL and helper T lymphocytes with defined specificity generated hybrid cells that expressed both Lyt-2 and L3T4 as well as two TCR. Data obtained with these hybrid clones demonstrated that cytolysis is closely linked to the CTL TCR. We have analyzed the effects of anti-Lyt-2 and anti-L3T4 as well as anti-TCR mAb on cytolysis, proliferation, and lymphokine release by a number of hybrid clones. We found that anti-Lyt-2 and anti-L3T4 mAb were able to inhibit both proliferation and lymphokine release by the hybrid clones in response to stimulation of either the CTL or helper T lymphocyte parent TCR. In contrast, only anti-Lyt-2 and anti-CTL TCR mAb were able to block cytolysis of target cells bearing the Ag recognized by the CTL TCR. These results provide further evidence that cytolysis is closely linked to the CTL TCR and that Lyt-2 and L3T4 have more than a passive role as accessory molecules on the surface of T lymphocytes.     

Cytolytic T lymphocyte clones that proliferate autonomously to specific alloantigenic stimulation. II. Relationship of the Lyt-2 molecular complex to cytolytic activity, proliferation, and lymphokine secretion

Previous analyses of the inhibitory effects of anti-Lyt-2 monoclonal antibodies (mAb) on cytolytic activity suggested that Lyt-2/3 antigens expressed on the surface of murine cytolytic T lymphocytes (CTL) are involved in antigen recognition. In the present study, we investigated the effects of anti-Lyt-2 mAb (in the absence of complement) on the functional activities of H-2K/D-specific Lyt-2+ CTL clones that proliferate to antigenic stimulation in the absence of helper T cells or added interleukin 2 (IL 2) and secrete lymphokines. For those clones that were inhibited in cytolysis by anti-Lyt-2 mAb, a parallel inhibition of antigen-dependent proliferation and lymphokine secretion (interferon, macrophage-activating factor) was observed. Inhibition of proliferation or lymphokine secretion could be overcome by the addition of IL 2 or lectin, respectively. Collectively, these results would strongly suggest that anti-Lyt-2 mAb were inhibiting CTL antigen recognition. Not all CTL clones, however, were inhibited in cytolysis by anti-Lyt-2 mAb, in which case proliferation and lymphokine secretion were similarly unaffected. This heterogeneity of Lyt-2+ CTL clones in their susceptibility to inhibition of cytolytic activity, proliferation, and lymphokine secretion by anti-Lyt-2 mAb is discussed in the context of a model proposing that Lyt-2/3 molecules function to stabilize the interaction between CTL receptors and the corresponding target/stimulating cell antigens. Such a stabilization may be required by CTL possessing few and/or low affinity receptors.     

Physical and functional association of the T cell receptor and the T3 molecular complex on cytotoxic T cell clones that are differentially inhibitable by anti-T3 antibodies

To examine the hypothesis that the antigen-specific T cell receptor (TcR) can function independently from the T3 complex on cytolytic T lymphocyte (CTL) clones, the physical and functional association of the T3 molecular complex and the T cell receptor has been examined on CTL clones that are differentially susceptible to inhibition by anti-T3 antibodies. From a panel of nine DPw2-specific CTL clones derived from the same donor, two clones (8.4 and 8.8) that were the most disparate in their susceptibility to inhibition by anti-T3 antibody were chosen for study. No significant differences were found between 8.4 and 8.8 for: (1) the levels of cell surface expression of the T3 complex and the TcR; (2) the ability to modulate T3 cell surface molecules; and (3) the capacity of the TcR to comodulate with the T3 complex. Modulation of the T3 complex from clone 8.4 did not significantly affect cytolytic activity, and incubation of modulated 8.4 with additional anti-T3 antibody did not inhibit cytolytic activity. Although no T3 function for clone 8.4 could be demonstrated by simply blocking cytolytic activity with anti-T3 antibody, addition of limiting quantities of anti-T11 (but not anti-T4, anti-Tac, or anti-LFA-1) antibodies plus anti-T3 produced a marked synergistic inhibition of cytolysis. These results suggest that: (1) CTL clones that are resistant to inhibition by anti-T3 antibodies actually have a physical and functional association between the T3 complex and the TcR; and (2) the ability to demonstrate a functional role for T3 by antibody blocking may, in some cases, require limiting the involvement of the T11 molecule in CTL-target interactions. The most likely explanation for the observed heterogeneity in susceptibility to blocking by anti-T3 antibodies is, therefore, thought to be that individual CTL clones possess TcR with differential avidity for specific targets.     

Studies on the cytolytic attack mechanism of the cytotoxic T lymphocyte (CTL): preparation of antisera against cellfree cytosolic extracts of a CTL clone capable of blocking the lethal hit stage of CTL cytolysis and analysis of the cytolytic structure

Rat antiserum (as well as purified IgG and F(ab')2 fragments) raised against cellfree cytosolic extracts (CFE) of an alloimmune cytotoxic T lymphocyte (CTL) clone (B6.1.SF.1) is a potent inhibitor of CTL-mediated cytotoxicity. Inhibition by this antiserum (termed alpha CTLL) occurred during the postbinding lethal hit stages of cytolysis, because it did not inhibit target cell binding, nor did it prematurely dissociate CTL-target cell conjugates; inhibition was observed regardless of the H-2 haplotype of the target cell or CTL employed; inhibition was reversible when pretreated, and washed CTL were used as effectors; and in Ca++ pulse experiments alpha CTLL inhibited cytolysis beyond the Ca++-dependent (lethal hit) stage of cytolysis. This antiserum did not inhibit lysis of P815 cells by activated murine macrophages or by human cytotoxic cells, and extensive absorption of the antiserum on viable thymocytes, normal spleen cells, or CTL did not reduce its blocking activity. CFE prepared from several sources of CTL, including in vivo elicited peritoneal exudate lymphocytes (PEL), secondary MLC-generated CTL, alloimmune splenic T cells, and CTL clones, contained material(s) that inhibited the ability of alpha CTLL to block CTL-mediated cytolysis. The inhibitory activity was not detected in CFE from a variety of noncytotoxic cell sources, including thymocytes, normal C57BL/6 spleen cells, EL4 or P815 tumor cells, macrophages, and helper T cell clones. It was also absent in CFE prepared from human CTL cells. Furthermore, although alpha CTLL neutralizing activity was not detectable in CFE prepared from memory CTL, it rapidly appeared in CTL parallel to the development of cytolytic activity during secondary MLC cultures. The inhibitory material in CTL-CFE appeared to be specific for alpha CTLL antibody, as it did not affect the CTL blocking activity of anti-Lyt-2 or anti-target cell antisera. Finally, CTL-CFE did not contain proteases that degraded the alpha CTLL antibody. By the use of a soluble-phase immunoabsorbent assay, the biochemical properties of materials present CFE derived from CTL and reactive with alpha CTLL antibody were examined. CTL cytosolic material(s) reactive with alpha CTLL IgG was unstable to brief heating (50 degrees C) or acidic pH, but not to high ionic strength buffers. The material was inactivated by treatment with pronase but not by DNase, collagenase, or trypsin. Gel filtration chromatography of CTL-CFE revealed multiple peaks of alpha CTLL neutralizing activity.(ABSTRACT TRUNCATED AT 400 WORDS)     

Inhibition of T cell-mediated cytolysis by monoclonal antibodies directed against Lyt-2: heterogeneity of inhibition at the clonal level

The inhibitory effect of monoclonal anti-Lyt-2 antibodies on T cell-mediated cytolysis has been investigated at the clonal level. In agreement with previous reports from several laboratories, populations of cytolytic T lymphocytes (CTL) generated in vitro in mixed leukocyte cultures (MLC) were reversibly inhibited by monoclonal anti-Lyt-2 antibodies in a dose-dependent fashion. However, when alloimmune peritoneal exudate lymphocytes (PEL) were used as a source of CTL, little or no inhibitory effect of anti-Lyt-2 antibodies on cytolysis was observed. A series of CTL clones derived from MLC or PEL populations was also tested for inhibition of cytolysis by anti-Lyt-2 antibodies. In agreement with results obtained at the population level, most MLC-derived clones (81%) were strongly inhibited by the reagent, whereas few PEL clones (15%) were inhibited. Several of these clones were expanded and maintained in culture without loss of their "inhibition phenotype." Flow cytofluorometric analysis using the same monoclonal anti-Lyt-2 antibodies further revealed that both inhibited and uninhibited clones expressed comparable amounts of Lyt-2 antigen. These results provide direct evidence that inhibition of CTL by anti-Lyt-2 antibodies is heterogeneous at the clonal level. The possibility that this heterogeneity may be related to avidity of antigen receptors is discussed.     

Role of accessory molecules in signal transduction of cytolytic T lymphocyte by anti-T cell receptor and anti-Ly-6.2C monoclonal antibodies

Accessory molecules present on the cell surface of cytolytic T lymphocytes (CTL) play an important role in their activation. Antigen-specific recognition by CTL is inhibited by antibodies against Lyt-2, L3T4, or LFA-1 molecules. Presently it is not known whether these molecules function by binding a ligand such as class I or class II on the target cell or by delivering a signal that down-regulates T cell activation. In the present study we utilized anti-T cell antibodies including anti-T3 and anti-T cell receptor (alpha/beta) as well as an anti-Ly-6.2C monoclonal antibody to activate CTL clones to kill irrelevant targets or secrete BLT esterase. The redirected lysis assay system utilizes the fact that heteroconjugates between anti-T3, and anti-T cell receptor, or anti-Ly-6.2C and anti-trinitrophenyl can trigger CTL lysis of trinitrophenyl-coupled targets that did not express antigen. In this system anti-Lyt-2 antibodies as well as anti-LFA-1 antibodies inhibited triggering via T cell receptor-related molecules but not via the anti-Ly-6.2C heteroconjugate. In addition, the anti-Lyt-2 was shown to inhibit conjugate formation in the heteroaggregate assay system suggesting that the anti-Lyt-2 antibodies acted early in inhibiting CTL activity. Similar results were observed in a system in which the CTL clones were triggered to secrete a BLT-esterase-like activity in the absence of target cells. Anti-T3 coated on plastic was shown to activate BLT-esterase secretion. This secretion was inhibited by anti-Lyt-2 and anti-LFA-1. Thus, it would appear that both the Lyt-2 molecule and the LFA-1 molecule act as signal-transducing elements involved in CTL activation. In particular, the Lyt-2 molecule appears to preferentially function in receptor-mediated T cell activation.     

T cell antigen receptor triggered exocytosis in cytotoxic T lymphocytes is inhibited by soluble, but not immobilized monoclonal antibodies to Lyt-2 antigen

The effect of monoclonal antibodies (mAb) to surface antigens on the T cell antigen receptor (TcR)-triggered exocytosis of intracellular granules in cytotoxic T lymphocytes (CTL) was studied. Soluble anti-LFA-1, anti-TcR, and anti-Lyt-2 mAb inhibited both CTL-inflicted 51Cr-release from the target cell (TC) and TC-stimulated exocytosis of granules from cloned CTL. Soluble anti-TcR and anti-Lyt-2 mAb but not soluble anti-LFA-1 mAb inhibited exocytosis, which was triggered by solid-phase anti-TcR mAb. Immobilized anti-Lyt-2 did not inhibit secretion triggered by immobilized anti-TcR mAb; immobilized anti-LFA-1 mAb had an modest inhibiting effect. Inhibition of exocytosis by soluble anti-Lyt-2 mAb was greater when stimulating anti-TcR mAb were immobilized at a lower density on a plastic surface. When the requirement for TcR cross-linking was bypassed by synergistic action of phorbol ester and ionophore A23187, no inhibition of exocytosis by soluble anti-Lyt-2 mAb was detected. The obtained data point to steric hindrance as the most likely explanation of the inhibition of TcR-triggered CTL activation by anti-Lyt-2 mAb.     

A rat anti-mouse T4 monoclonal antibody (H129.19) inhibits the proliferation of Ia-reactive T cell clones and delineates two phenotypically distinct (T4+, Lyt-2,3-, and T4-, Lyt-2,3+) subsets among anti-Ia cytolytic T cell clones

Hybridoma H129 .19 was derived by fusion between spleen cells of a Lou / Ws1 rat immunized with an Lyt-1+,2- anti-I-Ak cytolytic T lymphocyte (CTL) clone and the nonsecreting myeloma X63-Ag8.653. The monoclonal antibody (mAb) H129 .19 (IgG2a, kappa) was selected for its capacity to inhibit the lytic potential of the immunizing clone. H129 .19 identified a monomorphic determinant on a 55 m.w. murine T cell differentiation antigen, which appeared to be homologous to the human T4 molecule in that: 1) H129 .19 reacted with 80% adult thymocytes, with a subset of splenic T cells, and with the interleukin 2 (IL 2)-producing EL4 thymoma; 2) The mAb bound to and inhibited the IL 2 production and the proliferation of various allo- or soluble antigen-reactive T cell clones that recognized restriction or activating determinants on the I-A or I-E molecules, respectively; 3) H129 .19 did not inhibit the proliferation and/or cytolysis of Lyt-2,3+ T cells specific for class I MHC antigen; and 4) Among six anti-Iak CTL clones examined in this study, the mAb H129 .19 reacted with two I-Ak-specific, Lyt-2,3- clones on which it exerted strong cytolysis inhibiting effect at the effector cell level. By contrast, two other anti-I-Ak and two anti-I-Ek CTL clones were found to express the Lyt-2,3+,T4- cell surface phenotype. The cytolytic potential of the latter clones was not inhibited by anti-Lyt-2,3 mAb. These studies strongly suggest that the mouse T4 molecule facilitates the recognition of class II MHC antigen by most but not all T cells.     

Identification of monoclonal antibodies specific for the T cell receptor complex by Fc receptor-mediated CTL lysis

Monoclonal antibodies (mAb) directed at the T cell receptor complex (TcR) on cloned T cells have generally been identified by their ability to inhibit the clone's antigen-specific function. Because such inhibition is highly dependent on antibody concentration and affinity, detection of anti-clonotypic antibodies to murine alloreactive T cells has been very difficult. In this report, an alternative method is described on the basis of the ability of antibodies specific for the TcR complex to activate T cells in an antigen-independent manner. The assay is based upon the observation that soluble antibodies to human T3 promote lysis of irrelevant, Fc receptor-positive targets by a human CTL line. By using this approach, an anti-TcR mAb has been identified among a panel of murine mAb generated against an alloreactive CTL clone. Induction of lysis by soluble anti-TcR mAb has been shown to require both the expression of Fc receptors on the target cell and conjugate formation between the effector and the target cell. This assay provides a screening procedure that is much more sensitive than inhibition of function, and it preferentially detects antibodies specific for cell surface molecules involved in T cell activation.     

The functional significance, distribution, and structure of LFA-1, LFA-2, and LFA-3: cell surface antigens associated with CTL-target interactions

Three cell surface antigens associated with the cytolytic T lymphocyte(CTL)-target cell interaction were identified by generation of monoclonal antibodies (MAb) against OKT4+, HLA-DR-specific CTL and selection for inhibition of cytolysis in a 51Cr-release assay. These MAb block cytolysis by both OKT4+ and OKT8+ CTL and the proliferative responses to PHA and the mixed lymphocyte response (MLR). LFA-1 is an antigen widely distributed on lymphoid tissues and is composed of two polypeptides of 177,000 and 95,000 Mr on all cell types studied. Anti-LFA-1 MAb block NK cell-mediated cytolysis in addition to T lymphocyte-mediated cytotoxicity and proliferation. LFA-2 (Mr = 55,000 to 47,000), a determinant on the sheep red blood cell receptor, is expressed by T cells but not B cells and appears specific for T cell functions. LFA-3 (Mr = 60,000) is a widely distributed antigen present on both hematopoietic and nonhematopoietic tissues and appears to only be involved in T cell functions. MAb to LFA-1 and LFA-2 inhibit function by binding to effector cell surface molecules, whereas anti-LFA-3 MAb appear to block by binding to the target cells. Together with previously described molecules, LFA-1, LFA-2, and LFA-3 demonstrate the complexity of CTL-mediated cytotoxicity at the molecular level.     

Functional heterogeneity in allospecific cytotoxic T lymphocyte clones. II. Development of syngeneic cytotoxicity in the absence of specific antigenic stimulation

Two out of four long-term murine allospecific cytotoxic T lymphocyte (CTL) clones tested could develop high levels of cytotoxicity against syngeneic target cells when cultured under appropriate conditions. All CTL clones maintained strict allospecificity so long as they were cultured with both appropriate allogeneic stimulator cells and growth factor (supernatant from secondary mixed lymphocyte cultures). In two of the clones, syngeneic reactivity rapidly developed when the allogeneic stimulator cells were replaced with syngeneic or third party stimulator cells, and when the supernatant from EL4 thymoma cells stimulated with phorbol ester was used as growth factor. In addition to killing the appropriate allogeneic target, clones with syngeneic reactivity could kill both syngeneic C57BL/6 targets and H-2-congenic BALB.B targets but not third party unrelated targets, suggesting that the self structure recognized was coded for within the major histocompatibility complex. Such clones did not kill the natural killer (NK) target YAC. The results obtained from cold target inhibition and from subcloning at limiting dilution of clones with syngeneic reactivity suggested that both allogeneic and syngeneic reactivity could be expressed by the same individual cell in the CTL clone. The specificity for syngeneic H-2 as opposed to third party H-2 and NK-sensitive target cells, and the observation that both allospecific and syngeneic killing could be partially blocked by anti-Lyt-2 antibody treatment of the CTL, strongly suggested that different recognition structures are involved in CTL-mediated syngeneic cytotoxicity and NK cytotoxicity.     

Class II antigen-specific murine cytolytic T lymphocytes (CTL). II. Genuine class II specificity of Lyt-2+ CTL clones

Class II-specific allogeneic cytolytic T lymphocytes (CTL) consist of two types of cells, i.e., Lyt-2+L3T4- and Lyt-2-L3T4 T cells. The Lyt-2+L3T4- class II-specific CTL population constitutes a conspicuous exception to the general correlation observed between the class of major histocompatibility complex antigen recognized and the type of accessory molecules expressed by T cells. In order to examine the specificity of such an exceptional T cell population, CTL clones were established by limiting dilution of a bulk CTL line developed in an I region incompatible combination of mouse strains, B10.QBR anti-B10.MBR. These CTL lines showed single genetic specificity indicating their clonal nature with respect to CTL activities. Lyt-2+L3T4- (2+4-), Lyt-2-L3T4+ (2-4+) and Lyt-2-L3T4- (2-4-) clones were obtained. Among many CTL clones showing a spectrum of genetic specificities, 2+4- and 2-4+ clones with apparent I-Ak-specificity, were studied further and four lines of evidence confirmed their class II specificity: 1) genes encoding the target antigen for these CTL clones were mapped within the I-A subregion by simple genetics; 2) an I-Ak-specific monoclonal antibody readily blocked specific cytolysis by these clones; 3) the clones failed to react with cells expressing mutated I-Ak antigens; and 4) a B cell tumor transfected with alpha- and beta-chain genes of I-Ak was specifically lysed by these CTL clones. These data therefore establish the existence of Lyt-2+ CTL with genuine class II specificity. All 2-4+ CTL were sensitive to the blocking effect of an antibody to L3T4, whereas none of the 2+4- class II-specific CTL were sensitive to blocking by an anti-Lyt-2 antibody, indicating that class II-specific CTL with "wrong phenotype" is not dependent on the function of the accessory molecule. Besides true class II-specific CTL clones, 2+4- clones with a spectrum of genetic specificities were obtained, including clones recognizing a combination of an I-Ak product and the Kb molecule. Two 2-4- clones were also specific for the combination of Kb + I-Ak. These clones most likely recognize an allogeneic class II antigen in the context of a class I antigen and therefore would more appropriately be included in the class I-restricted T cell population.     

Recognition of HLA-A2 mutant and variant target cells by an HLA-A2 allospecific human cytotoxic T lymphocyte line

HLA-A2 specific human cytotoxic T lymphocytes (CTL) cell lines have been developed using T cell growth factor and coculture of peripheral blood lymphocytes with selected allogeneic target cell lines. The CTL-8 line showed specificity for human leukocyte antigens (HLA)-A2 bearing target cells after 5 weeks in culture when tested against a panel of 14 lymphoblastoid cell lines in a 51Chromium (51Cr) release assay. Purified anti-human leukocyte antigens (HLA) monoclonal antibodies W6/32 and PA2.1 inhibited cytolysis by 85% and 60%, respectively. The CTL-8 line lysed non-HLA-A2 target cells in the presence of lectins concanavalin A (Con A) or phytohemagglutinin-P lectin (PHA-P) indicating the specificity of cytolysis was not due to nonspecific resistance of target cells to the CTL-lytic mechanism. The T5-1 HLA-A2 mutant cell series were tested as targets for the CTL-8 line. Cell clones 8.18.1, 8.21.1 and 8.6.1, which express altered HLA-A2 molecules as determined by their decreased reactivity with allospecific monoclonal antibodies, were lysed by the CTL-8 line as efficiently as the T5-1 wild type. These cell lines also acted as efficient cold target competitors for a normal HLA-A2 target cell. The 8.14.1 cell clone expressed a lower amount of HLA-A2 alloantigen and showed a corresponding decreased reactivity with CTL-8 in direct cytolytic and cold target competitive inhibition assays. In contrast, the M7 and DK1 HLA-A2 variant cell lines, which express normal HLA-A2 serological determinants, were inefficiently lysed by CTL-8 and did not act as competitive inhibitors of normal HLA-A2 target cells. These results support the concept that the alloantigenic determinant(s) recognized by T cells and antibodies occur at separate regions on the HLA-A2 molecule.     

A novel cytotoxic T-cell clone that exhibits differential modes of recognition in the proliferative and cytolytic phase

A T-cell clone (1G8-H7) cytotoxic to P815Y mastocytoma (H-2d) has been established from spleen cells of a C3H/He mouse (H-2k) primed with P815Y cells by means of in vitro stimulation with irradiated C3H.H-2o(H-2KdDk) spleen cells. The clone 1G8-H7 was an interleukin 2 (IL-2)-dependent and H-2Kd antigen-dependent CTL clone and it killed P815Y cells but not Concanavalin A-induced spleen blast cells bearing H-2Kd antigen. The involvement of H-2Kd antigen in the cytolytic recognition mechanism was shown by the inhibition of lysis by anti-H-2Kd monoclonal antibody and also by the cold inhibition experiment that employed H-2Kd-bearing spleen cells. Comparison of cytotoxic activities between 1G8-H7 and Kd-specific CTL clones showed that the killing of P815Y cells by clone 1G8-H7 was not explained by the susceptibility to cell-mediated cytolysis of P815Y cells. These results suggest that H-2Kd antigen on the stimulating cell is sufficient to deliver a proliferation signal in the proliferative phase of this clone, but in the cytolytic phase an additional interaction with surface structure on the target cell other than that with H-2Kd antigen is required for the induction of cytolysis. Possible elucidations for the differential modes of recognition are discussed.     

Conditions of anti-Lyt-2-mediated inhibition of TcR/CD3-induced IFN-gamma secretion by a CTL clone

The relationship between the T cell receptor (TcR) for antigen (Ag) and the Lyt-2/3 molecule during T cell activation was studied using the T cell clone KB5.C20, which is dependent upon Lyt-2 for target cell killing. This cytolytic T cell clone can be activated to secrete IFN-gamma by stimulation with H-2Kb expressing cells or with monoclonal antibodies directed against a clonotypic structure of the TcR or against associated CD3 molecules. IFN-gamma production induced by H-2Kb can be inhibited by anti-Lyt-2mAb. In addition, TcR-mediated activation using the anticlonotypic mAb Désiré-1 in soluble form can be inhibited by anti-Lyt-2 mAb in soluble form either as a divalent IgG or as its monovalent Fab fragment. Anti-Lyt-2 mAb immobilized on plastic wells was also inhibitory. Stimulation induced by the anti-TcR mAb or by anti-CD3 mAb immobilized on plastic can be inhibited only with plastic immobilized and not with soluble anti-Lyt-2mAb, however. These results are discussed in terms of local interactions between TcR and Lyt-2 molecules.     

Susceptibility of cytotoxic T lymphocyte (CTL) clones to inhibition by anti-T3 and anti-T4 (but not anti-LFA-1) monoclonal antibodies varies with the "avidity" of CTL-target interaction

To explore the role of the T3, T4, and LFA-1 molecules in high and low "avidity" interactions between SB2-specific cytotoxic T lymphocyte (CTL) clones and their targets, monoclonal antibody-mediated inhibition of cytotoxicity has been studied in experiments that vary the "avidity" of interaction in three different ways. 1) Previous results have been extended with respect to different CTL clones assayed on the same SB2-positive target cells. Differences between clones in susceptibility to anti-T3 inhibition paralleled variations in anti-T4 inhibition, and both correlated inversely with the "avidity" of the effector-target interaction (inferred previously from studies of conjugate dissociation). 2) A high "avidity" clone, 8.4, was identified that lysed not only SB2-positive cells but also cross-reacted on a few SB2-negative cells. Cold target inhibition studies confirmed the cross-reaction, and together with conjugate dissociation studies, indicated that cross-reaction to be of lower "avidity" than the specific recognition of SB2. Cross-reactive lysis was much more susceptible to inhibition by anti-T3 and anti-T4 than was specific lysis. 3) Anti-T3 and anti-T4 blocking was analyzed in the presence of anti-Ia antibody to reduce the amount of Ia antigen available on the target. Anti-T3 and anti-T4 antibody blocking was more efficient after the addition of anti-Ia antibody concentrations that (by themselves) produced minimal inhibition of lysis. As a control, anti-LFA-1 antibody blocking was analyzed in each of these three experimental systems that compare interactions of different "avidity"; minimal variation was observed in the efficiency of inhibition by anti-LFA-1. Thus, anti-T3 and anti-T4 inhibition correlates inversely with the "avidity" of that CTL-target interaction, but anti-LFA-1 inhibition does not.     

Species-restricted recognition of transfected HLA-A2 and HLA-B7 by human CTL clones

Human cytolytic T lymphocytes (CTL) clones and HLA-A2- and HLA-B7-transfected human, monkey, and mouse cell lines were used to investigate the basis for species-restricted antigen recognition. Most allospecific CTL clones obtained after stimulation with the human JY cell line (source of HLA-A2 and HLA-B7 genomic clones) recognized HLA antigens expressed in human and monkey cell lines but did not recognize HLA expressed in murine cells. By initially stimulating the responder cells with HLA-transfected mouse cells, two CTL clones were obtained that recognized HLA expressed in murine cells. Functional inhibition of these CTL clones with anti-class I monoclonal antibodies (MAb) indicated that clones reactive with HLA+ murine cells were of higher avidity than clones that did not recognize HLA+ murine target cells. MAb inhibition of accessory molecule interactions demonstrated that the LFA-1 and T8 surface molecules were involved in CTL-target cell interactions in all three species. In contrast, the LFA-2/CD2 molecule, previously shown to participate in a distinct activation pathway, was involved in the cytolysis of transfected human and monkey target cells, but not in the lysis of HLA+ murine cells. Thus transfection of HLA genes into different recipient species cell lines provides us with the ability to additionally delineate the functional requirements for allospecific CTL recognition and lysis.