Blocking of CTL-mediated killing by monoclonal antibodies to LFA-1 and Lyt-2, 3. II. Evidence that trypsin pretreatment of target cells removes a non-H-2 molecule important in killing

We sought additional evidence for an inverse relationship between functional CTL-target cell affinity on the one hand, and susceptibility of the CTL-mediated killing to inhibition by alpha LFA-1 and alpha Lyt-2,3 monoclonal antibodies on the other hand. Previously, we experimentally reduced affinity by pretreating the target cells with papain. This removed most of the class I H-2 antigens, had little effect on the ability of allospecific CTL to recognize and kill these targets, but dramatically reduced the initial strength of CTL-target cell adhesion, and increased by more than 10-fold the susceptibility of the killing to inhibition by alpha Lyt-2,3 and alpha LFA-1 MAb. In the present report, we find that pretreating the target cells with trypsin, like papain, does not significantly change the susceptibility of the target cells to killing by allospecific CTL in a 2-hr assay, and increases by about 10-fold susceptibility of the killing to inhibition by alpha LFA-1. Unlike papain, however, trypsin does not consistently increase blocking by alpha Lyt-2,3, does not remove class I H-2 antigens from the target cell, and does not substantially reduce the strength of initial CTL-target adhesion formation (estimated by post dispersion lysis after a 5-min conjugate-forming incubation). These results show a functional difference between LFA-1 and Lyt-2,3. Both papain and trypsin produced similar 10-fold increases in susceptibility to blocking by alpha LFA-1. In contrast, susceptibility to inhibition by alpha Lyt-2,3 was increased nearly 100-fold by papain, but was not consistently affected by trypsin. Thus, the above-mentioned inverse relationship holds for alpha Lyt-2,3 but not for alpha LFA-1. Our results are consistent with the hypothesis that Lyt-2,3 but not LFA-1 participates in recognition of class I H-2 antigens. Possibly LFA-1 participates in an adhesion-strengthening process that follows T cell recognition, and which may also be used by other LFA-1 expressing leucocytes in intercellular interactions. Finally, our results suggest (for the first time in the mouse system) that an unidentified non-H-2 "trypsin-sensitive counter blocking" molecule on the target cell plays an important role in CTL-target cell interaction.     

Differences between macrophage migration inhibitions by lymphokines and muramyl dipeptide (MDP) or lipopolysaccharide (LPS): migration enhancement by lymphokines

To investigate the repertoire of molecules which are associated with cytolytic T-lymphocyte (CTL)-mediated killing, function-blocking monoclonal antibodies (MAb) have been selected and characterized. Spleen cells from rats immunized with secondary mouse CTL were fused with mouse myeloma cells. Antibodies secreted by 2400 hybrid cultures were selected solely by their ability to block CTL-mediated killing in a mouse anti-rat xenogeneic system. Fifteen cultures with antibodies which blocked CTL-mediated killing were chosen for cloning and further characterized by immunoprecipitation and immunofluorescence flow cytometry. One group of five monoclonal antibodies recognized the Lyt-2,3 molecule of 35,000 M_r. The second group of six MAb recognized the LFA-1 antigen containing two subunits of 180,000 and 95,000 M_r. One MAb giving only partial inhibition of killing was an IgM anti-Thy-1. It strongly agglutinated CTL. The target antigens defined by three other MAb were not definitively identified. Competition in cell binding between anti-Lyt-2,3 and anti-LFA-1 MAb suggested that their blocking effect in cytolysis is due to binding to distinct and spatially separate molecules on effector cells. The results of direct screening for functional blockade support the important role of Lyt-2,3 and LFA-1 molecules in T-cell-mediated cytolysis.     

Mouse alloantibodies capable of blocking cytotoxic T cell function. V. The majority of I region-specific CTL are Lyt-2+ but are relatively resistant to anti-Lyt-2 blocking

In an attempt to solve the conflict concerning the correlation between the Lyt-2 phenotype of T cells subsets and the type of the MHC antigens involved in the recognition by T cells, class 2 (I region) antigen-specific CTL were studied for their Lyt phenotypes and the sensitivity to the blocking effects of anti-Lyt-2,3 antibodies. To avoid contamination by CTL to class 1 antigens such as Qa antigens, A.TH anti-A. TL attackers and A.TH anti-A attackers were tested on LPS blasts of the A strain and the A.TL stain, respectively. By using these combinations, it was shown that the majority of I region-specific killers were Thy-1+, Lyt-1+23+. Specific target cell lysis by these cells were, however, found to be far less sensitive to the blocking effects of various monoclonal antibodies to the Lyt-2,3 antigens than conventional class 1-specific CTL. This conclusion was drawn by directly comparing the sensitivity of the I region-specific and K region-specific killing by identical numbers of the same attacker cells (A.TH anti-A). No significant difference was seen between the primary and the hyperimmune CTL. Lyt-2-, Thy-1+ killer cells with I region specificity could be induced when Lyt-2-depleted A.TH responder cells were stimulated in vitro. Such Lyt-2- killer cells were not induced to the H-2K alloantigen.     

CTL adhesion and antigen recognition are discrete steps in the human CTL-target cell interaction

Th initial step in cytolytic T lymphocyte (CTL)-mediated cytolysis involves target cell adhesion and antigen recognition. To investigate these initial events in the CTL-target interaction, we used HLA-A2- and HLA-B7-specific human CTL clones and HLA-typed B lymphoblastoid target cells. By using two different adhesion assays, we demonstrated antigen nonspecific CTL-target cell adhesion. To more precisely define the contribution of the antigen-specific receptor to CTL-target cell adhesion, we used the HLA-A2, HLA-B7, and mock transfected RD target cells. Consistent with the results when using B lymphoblastoid target cells, the CTL clones demonstrated equivalent adhesions to the RD target cells whether or not they expressed HLA-A2 or HLA-B7. These results suggested that CTL-target cell adhesion occurred independent of the T cell receptor. By using the calcium-sensitive dye Indo-1 and flow cytometry, we assessed CTL-target cell adhesion and CTL activation. Simultaneous measurement of adhesion and intracellular free calcium demonstrated that CTL-target cell adhesion alone did not activate CTL clones. Both CTL-target cell adhesion and the presence of the appropriate HLA target molecule were necessary for the efficient activation of human CTL. MAb inhibition studies indicated that antigen nonspecific adhesion is largely regulated by the LFA-1, CD2 (LFA-2/T11), and LFA-3 cell surface molecules. These antigen nonspecific cell-cell interaction molecules appear to play an important role in facilitating antigen recognition and subsequent target cell lysis.     

Specific lymphocyte-target cell conjugate formation between tumor-specific helper T-cell hybridomas and IA-bearing RCS tumors and IE-bearing allogeneic cells. I. Role of Ia and both L3T4 and LFA-1 antigens in recognition/binding

The studies reported here describe the feasibility of using single cell techniques with nonadherent target cells for the formation of T helper lymphocyte-target cell conjugates in an Ia recognition system. We have taken advantage of four tumor-specific T cell hybridomas lines, two of which respond only to IA-bearing RCS tumor cells of SJL/J (H-2s) origin, and the other two that respond to both RCS and IA- or IE-bearing allogeneic cells of H-2k,d haplotypes. The conjugate frequency between the T cell hybridomas and target cells was scored microscopically and was facilitated by labeling the lymphocyte with fluorescein. The frequency of conjugate formation ranged from 20 to 40% above background. Conjugate formation was antigen specific and correlated well with the hybridoma specificity determined by IL 2 responses after antigenic stimulation. The cross-reactive hybridomas formed conjugates with RCS and LPS blasts derived from CBA or DBA/2 origin, but not with cells of syngeneic or other allogeneic strains. Conjugate formation with RCS was inhibited greater than 50% with mAb directed against IAs determinants on the RCS tumor cells, and conjugate formation with allogeneic cells was blocked only with mAb directed to either IA/IEk or IA/IEd specificities directed against the alpha or beta polypeptide chain. Blocking of conjugate formation was also achieved by various mAb directed against surface membrane molecules associated with the T cell hybridomas. LFA-1 mAb inhibited significantly the formation of conjugates. However, L3T4 mAb blocked only partially the conjugates. Other antibodies directed against Lyt-1 or Thy-1.2 antigens were without blocking effect. The poor blocking observed with L3T4 mAb did not correlate with the almost complete blocking observed in the IL 2 response by the same hybridomas. These studies of the syngeneic anti-RCS tumor response directed against IA-bearing RCS showed that the conjugate assay permits mapping of tumor-associated Ia epitopes. In addition, the results of these studies demonstrate the feasibility of conjugate formation in determining the antigenic specificity of the T helper system. This assay system can be used to establish the minimal frequency of antigen-reactive cells and can divide the T helper response into multiple steps (i.e., recognition/binding, activation, proliferation, and lymphokine release) and determine the surface membrane molecules involved in recognition.     

T3 monoclonal antibody activation of nonspecific cytolysis: a mechanism of CTL inhibition

The T3 antigen is expressed on all cytotoxic T lymphocytes (CTL). Monoclonal antibodies (MAb) to the T3 antigen previously have been shown to inhibit CTL-mediated killing of cells expressing the relevant target antigens. The mechanism of T3 MAb inhibition, however, remains undefined. In this report, we describe a novel effect of the T3 MAb: the stimulation of allospecific CTL clones to kill target cells that do not express the relevant HLA antigens. The stimulation of nonspecific killing was seen only with MAb to the T3 antigen; MAb to other function-associated antigens (e.g., LFA-1, LFA-2, LFA-3, T4, T8, HLA-A,B,C, and DR) had no effect. T3 MAb stimulated nonspecific killing by CTL clones expressing both the T4+ and T8+ phenotype and by CTL clones specific for both class I and class II HLA alloantigens. Target cell susceptibility to T3 MAb stimulated killing was variable. CTL clones lysed some target cell lines very efficiently (e.g., K562, Daudi, and M124.1) but lysed other cell lines much less efficiently (e.g., 23.1, Mann, and L cells). In CTL-mediated cytotoxicity assays with target cells expressing the relevant HLA antigens, T3 MAb demonstrated the expected inhibition of cytolysis. Thus, the ability of T3 MAb to stimulate and inhibit CTL-mediated cytolysis suggests that both effects may be the result of a common mechanism of activation.     

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.     

Gene mapping and somatic cell hybrid analysis of the role of human lymphocyte function-associated antigen-3 (LFA-3) in CTL-target cell interactions

LFA-3 is expressed on a wide variety of human cell lines, including those which have been used as recipients for gene transfer of human class I gene products, whereas a murine counterpart is either absent or significantly different such that the anti-LFA-3 monoclonal antibody (MAb) does not bind. By using a somatic cell genetic approach, we demonstrate that LFA-3 is not a major histocompatibility complex-encoded molecule, and that its gene locus maps to human chromosome 1. When LFA-3 and HLA-A2 are coexpressed on the mouse cell surface, anti-LFA-3 MAb interfered with specific recognition and lysis of these target cells by human CTL capable of lysing HLA-A2-expressing mouse transfectants. A significant contribution of the LFA-3 molecule to CTL reactivity was not observed, however, because the presence of LFA-3 did not restore recognition by CTL clones previously found incapable of lysing HLA-A2-expressing mouse transfectants, nor was it required by those human CTL that could lyse mouse cell transfectants. Thus, we have used genetic techniques to demonstrate that LFA-3 may serve a role in CTL-target cell interactions at the target cell level, but is not a molecule absolutely required for human allospecific CTL recognition of HLA antigens expressed on mouse cells. We suggest that LFA-3 may not participate directly in CTL function under normal circumstances, but delivers a more general inhibitory signal only when provoked by bound MAb.     

Functional distinctions between the LFA-1, LFA-2, and LFA-3 membrane proteins on human CTL are revealed with trypsin-pretreated target cells

We asked whether we could distinguish the roles of the human lymphocyte membrane proteins LFA-1, LFA-2, and LFA-3 in the function of CTL-mediated killing. Little is known about the functions of these molecularly distinct proteins beyond the facts that i) binding of a monoclonal antibody (MAb) to any one of them is sufficient to inhibit killing, ii) that in each case inhibition involves prevention of CTL-target cell conjugate formation, and iii) that MAb to LFA-1 and LFA-2 inhibit best when bound to the CTL, whereas anti-LFA-3 inhibits only when bound to the target cell. This latter is despite the fact that (in our test system) LFA-1 and LFA-3 are expressed both on the CTL and on the target. When the target cells were pretreated with trypsin, the sensitivity of CTL-mediated killing was affected in a different way for each site. Inhibition of anti-LFA-1 was increased by approximately 20-fold. Inhibition by anti-LFA-2 was unaffected. Inhibition by anti-LFA-3 was abolished. Trypsin did not remove the specific antigens recognized by the various CTL, HLA-A,B,C or HLA-DR. Nor did it remove LFA-1 from the target cell. It did, however, selectively remove LFA-3 from the target cell. These results indicate, for the first time, that LFA-1 and LFA-2 have functionally distinct roles. They suggest that an unidentified trypsin-sensitive target cell molecule, operationally designated the "trypsin-sensitive counter blocker" (TSCB), plays an important role in the function of LFA-1, possibly by providing a target cell binding site for LFA-1 on the CTL. The hypothesis that this TSCB is identical to LFA-3 (and the related possibility that LFA-1 and LFA-3 are mutual ligands) is not favored by our data, but is not excluded. Finally, the data indicate that the mechanisms by which MAb inhibit killing differ at the LFA-1 and LFA-3 sites. They are consistent with LFA-1 providing adhesion strengthening by binding to another site (the TSCB?) and with LFA-3 delivering an inhibitory signal when provoked with MAb.     

Lymphocyte-mediated cytolysis of allogeneic tumor cells in vitro. III. Enzyme sensitivity of target cell antigens.

Target tumor cells pretreated with high concentrations of papain or Pronase were resistant to lysis by cytotoxic T lymphocytes (CTL), whereas treatment with trypsin or neuraminidase had no protective effect. Parallel determinations of the H-2 content of target cells following enzyme treatment showed that approximately 80% of surface H-2 was removed by papain or Pronase, 40% by trypsin, and virtually none by neuraminidase treatment. Both susceptibility to lysis by CTL and content of surface H-2 after papain treatment were fully restored by 6 hr at 37 °C in nutrient medium. These findings suggest that lymphocyte-mediated cytolysis (LMC) determinants (target cell antigens bound by CTL) are sensitive to degradation by papain and Pronase but are resistant to the enzymatic action of trypsin and neuraminidase. That a similar pattern of enzyme sensitivity is shown by serologically defined H-2 antigens indicates that both functional classes, LMC and H-2, may have a structural association.     

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.     

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.     

Unexpected cell surface labeling in conjugates between cytotoxic T lymphocytes and target cells

Specific binding of target cells by cytotoxic T lymphocytes (CTL) is an example of tight interaction between two different cell types. The molecular events that occur at the cell membranes during these interactions are largely unknown. In the present report, we describe an electron microscopic immunostaining study made on CTL-target cell conjugates. Various membrane structures were labeled with monoclonal antibodies specific for structures possibly relevant to cytolysis (Lyt-2, LFA-1, and target cell class I major histocompatibility antigens) or probably unrelated to the cytolytic process (effector cell class I major histocompatibility antigens). Antibodies against Thy-1 were also used. Staining was achieved with immunoperoxidase or immunoferritin. With both techniques nonconjugated cells were either stained or not, depending on whether they bore the antigen corresponding to the antibody used. However, when conjugated to an antigen-bearing cell, a "non-antigen bearing" cell was labeled near the cell interaction area. No increased Fc receptor activity could be detected on bound cells near the interaction area. These data are consistent with the occurrence of limited exchange of membrane macromolecules between bound CTL and target cell.     

Studies on the induction and expression of T cell-mediated immunity. XIV. Antigen-nonspecific oxidation-dependent cellular cytotoxicity (ODCC) mediated by sodium periodate oxidation of cytotoxic T lymphocytes

Alloimmune murine thymus-derived cytotoxic lymphocytes (CTL) generated in vivo or in vitro are shown to lyse antigen-nonspecific target cells (tumor cells, Con A, and LPS blasts) following treatment of CTL with an oxidizing agent, sodium periodate (NaIO4). It has been shown that NaIO4 oxidizes terminal sialic acid residues of cell surface macromolecules. The presence of reactive aldehyde groups, generated by NaIO4 modification, is required for the expression of antigen-nonspecific cytotoxicity because treatment of modified cells with a reducing agent such as potassium borohydride (KBH4) resulted in the abrogation of cytotoxicity. However, KBH4 treatment of unmodified or NaIO4-modified CTL has no effect on antigen-specific cytotoxicity. The modification of CTL by NaIO4 is sufficient to lead to the formation of lymphocyte-target cell conjugates and lysis of bound targets. Monoclonal antibodies directed against the Lyt-2 antigens of CTL, but not Lyt-1 antigens, in the absence of complement inhibited the nonspecific cytotoxicity resulting from NaIO4 modification of effector lymphocytes. These findings suggest that the mere interaction with or perturbation of appropriate cell surface molecule(s) of effector lymphocytes such as Lyt antigens by receptor-ligand interaction in SCMC or by NaIO4 modification in ODCC may lead to the expression of cytotoxicity. The present studies demonstrate a functional role of surface carbohydrates on CTL in cell-to-cell recognition and interactions. Furthermore, the results suggest that target cell modification is not a requisite for recognition and lysis in an antigen-nonspecific cytotoxic system such as ODCC. However, partial blocking of ODCC by alloantibodies directed against the H-2 of unmodified target cells suggests that NaIO4-modified CTL recognize unrelated target H-2 antigens. The implication of these findings on the molecular mechanism of cell-mediated cytotoxicity is discussed.     

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.     

Surface markers of T cells causing lethal graft-vs-host disease to class I vs class II H-2 differences

Information was sought on the phenotype of lymphoid cells causing lethal graft-vs-host disease (GVHD) in irradiated mice expressing whole or partial H-2 differences. In all strain combinations tested, pretreating donor lymph node (LN) cells with anti-Thy-1 monoclonal antibodies (MAb) plus complement (C) abolished mortality. With GVHD directed to class I H-2 differences, pretreating LN cells with anti-Lyt-2 MAb prevented mortality, whereas MAb specific for Ly-1 or L3T4 cell surface determinants caused severe mortality. These data imply that lethal GVHD directed to class I H-2 differences is mediated by L3T4-, Lyt-2+ cells; this subset of T cells was shown previously to control GVHD directed to multiple minor histocompatibility antigens, i.e., antigens seen in the context of self-class I molecules. With whole H-2 differences, GVHD appeared to be controlled largely but not exclusively by L3T4+, Lyt-2-T cells. This T cell subset was also the predominant cause of GVHD directed to class II differences. With class II incompatibilities, depleting donor cells of L3T4+ T cells, either by pretreatment with anti-L3T4 MAb + C or by fluorescence activated cell sorter selection, greatly reduced but did not completely abolish GVHD. These data might imply that L3T4-, Lyt-2+ cells have some capacity to elicit anti-class II GVHD. A more likely possibility, however, is that the residual GVHD to class II differences observed with Lyt-2+-enriched cells reflected minor contamination with L3T4+ cells.     

Analysis of T cell activation requirements with the use of alloantigens or an anti-clonotypic monoclonal antibody

H-2Kb-specific alloreactive cytotoxic T lymphocyte (CTL) clones, which secrete macrophage-activating factor (MAF) in response to antigen, were used to study the antigenic and physiologic parameters for T cell-antigen receptor (Ti)-mediated activation. When H-2Kb was presented on untreated, formaldehyde (FOR)-fixed cells, or liposomes, optimal stimulation in the absence of co-factors was obtained only with the untreated cells. FOR cells, which were efficient inhibitors of CTL-target cell interactions for the CTL clones studied, had a greatly reduced activating capacity. Phorbol myristic acetate (PMA), which alone had no activating effect on the CTL clones, acted in synergy with FOR cells, restoring an unimpaired H-2Kb-dependent activation for some CTL clones. H-2Kb-liposomes were not stimulatory even in the presence of PMA and/or splenic feeder cells. For one H-2Kb-specific CTL clone (KB5-C20), activation was studied with the use of an anti-clonotypic (anti-Ti) monoclonal antibody (mAb), Désiré-1. By using this immunoglobulin (Ig) G2a mAb or its F(ab')2 or Fab fragments, it was observed that the association constant of the IgG2a (4.7 X 10(9) M-1) for KB5-C20 was 30-fold higher than that of the Fab fragment, whereas the molar concentration of mAb required to inhibit 50% of the H-2Kb-specific CTL activity of clone KB5-C20 was 70-fold to 90-fold higher for the Fab fragment than for the IgG2a (1 to 5 X 10(-10) M). It was also observed that activation as measured by MAF secretion of clone KB5-C20 was obtained by using the divalent IgG2a mAb or its F(ab')2 fragment at 10(-9) M to 10(-8) M in the absence of any added co-factor or feeder cells, whereas a 500-fold higher molar concentration of the Fab fragment only induced very low levels of MAF secretion. Also, in the presence of PMA, the mAb-mediated activation of MAF secretion by clone KB5-C20 was increased, but Fab-induced activation never resulted in high titers of MAF. We conclude that the intrinsic "affinity" of the H-2Kb-Ti interaction is probably so low for the Ti of clone KB5-C20 that efficient activation by H-2Kb is obtained only when multivalency is achieved on H-2Kb-expressing cells, and possibly when molecules on the T cells such as Lyt-2 and LFA-1 stabilize the interactions.(ABSTRACT TRUNCATED AT 400 WORDS)     

Expression and function of asialo GM1 in alloreactive cytotoxic T lymphocytes

In the present study we examined asialo GM1 (AsGM1) expression and its function in alloreactive cytotoxic T lymphocytes (CTL). We consistently found that the cytotoxic activity of bulk culture-derived allo-CTL was susceptible to the treatment of anti-AsGM1 (alpha AsGM1) plus complement. To further determine whether the expression of AsGM1 was maintained in CTL, we examined cloned T cells. The expression of AsGM1 in the T cell clones was assessed by their susceptibility to lysis by alpha AsGM1 plus complement and the reduction or abrogation of their cytotoxic activity by this treatment. It was found that, with one exception, all Lyt-2+, Thy-1+ CTL clones were AsGM1+ (seven out of eight), independent of their class specificity (class I or class II). In contrast, all Thy-1+, L3T4+ CTL (2) or helper T cell (4) clones AsGM1-. These findings suggested that there was a close association between the expression of AsGM1 and the expression of Lyt-2. The cytotoxic reaction of the anti-class I MHC CTL clones that expressed AsGM1 was blocked by alpha AsGM1 or alpha Lyt-2 antibody. The Lyt-2+, AsGM1+ anti-class II MHC CTL clone-mediated lysis was inhibited by alpha AsGM1. Addition of AsGM1 in micelle form (AsGM1-M) alone also blocked the cytotoxic reactions. Addition of other structurally similar but antigenically different glycolipids or other non-AsGM1-containing liposome preparations did not affect CTL-mediated cytotoxicity. Furthermore, adding both alpha AsGM1 and AsGM1-M together at proper doses inhibited the blocking effect (deblocking) of either alone, and other structurally similar glycolipids did not inhibit the blocking. The deblocking was specific, since AsGM1-M did not affect the blocking by alpha Lyt-2. These findings indicate that not only is AsGM1 expressed in a majority of Lyt-2+ CTL clones, but it may also be involved in the CTL- target interaction to mediate lytic reaction.     

Class II antigen-specific murine cytolytic T lymphocytes (CTL). I. Analysis of bulk populations and establishment of Lyt-2+L3T4- and Lyt-2-L3T4+ bulk CTL lines

Murine allogeneic cytolytic T lymphocytes (CTLs), including long-term bulk CTL lines, were induced in I-region-incompatible combinations of strains in vitro in order to study the phenotypes of class II major histocompatibility complex (MHC) antigen-specific CTLs, as well as the possible functional involvement of accessory cell interaction molecules such as Lyt-2 and L3T4. This report shows that class II-specific allogeneic CTL populations consist of two types of T cells. Lyt-2+L3T4- (2+4-) and Lyt-2-L3T4+ (2-4+), in variable proportions depending on the strain combination, that in vitro bulk CTL lines with each of these phenotypes can be established, that the killing function of 2-4+ CTL is sensitive to the blocking effect of anti-L3T4 antibodies, suggesting functional involvement of this molecule in the CTL-target interaction, that anti-Lyt-2 antibodies fail to block killing by 2+4- cells, suggesting that such CTLs do not utilize this molecule in their killing function, and that while I-A-specific CTLs of both phenotypes are detectable, 2-4+ cells could not be detected among I-E-specific CTL populations.     

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.