Serological studies on the major histocompatibility complex of new inbred strains of the guinea pig.

New inbred strains of guinea pigs, JY 1, JY 2, JY 3, JY 6, JY 9 and JY 10 have been established in this Institute. Serologic studies of guinea pig leukocyte antigens (GPLA antigens) were carried out in order to examine their major histocompatibility complex (GPLA complex). Antisera specific for Ia antigens were raised by cross-immunization of NIH strain 2 (NIH 2) and NIH strain 13 (NIH 13) guinea pigs, well known inbred guinea pigs. The sera identified four distinct Ia specificities, which were designated as Ia.2a, Ia2b, Ia.13a and Ia.13b. Six antigenic specificities different from the above Ia specificities were identified by sera obtained by appropriate immunization of the inbred guinea pigs and were designated as P.1, P.2, P.3, P.4, P.5 and P.6. Antigenic specificities of GPLA antigens recognized in inbred guinea pigs were : NIH 2 (Ia.2a, Ia.2b, P.1, P.2, P.O, P.4), NIH 13 (Ia.13a, Ia.13b, P.1, P.2, P.3, P.4), JY 1 (Ia.13a, Ia.13b, P.5), JY 2 (Ia.2b, Ia.13b, P.3, P.4, P.6), JY 3 (Ia.13a, Ia.13b, P.2, P.4, P.5), JY 6 (Ia.2b, Ia.13b, P.3, P.6), JY 9 (Ia.13a, Ia.13b, P.4, P.5), JY 10 (Ia.13a, Ia.13b, P.2, P.3, P.4, P.6), JY 9 (Ia.13a, Ia.13b, P.4, P.5), JY 10 (Ia.13a, Ia.13b, P.2, P.3, P.4, P.6). The correspondence of these specificities to those already reported was discussed and the P.2 or P.4 was considered to be an additional specificity of GPLA antigens that have not been reported yet. As the new inbred strains of guinea pigs were thus found to possess characteristic GPLA complex, which differ from each other and from those of NIH 2 and NIH 13 strain, they should be useful for studies of roles of the major histocompatibility complex in the immune system.     

Mouse T lymphocytes proliferative responses specific for human MHC products in mouse anti-human xenogeneic MLR

It has been reported that human T cells recognize the polymorphism of murine Ia antigens in the human anti-mouse xenogeneic mixed lymphocyte reactions (MLR). In this study, murine T cell recognition of human Class II antigens of the major histocompatibility complex (MHC) was analyzed in mouse anti-human xenogeneic MLR responses. The xenoreactive murine T cell proliferative response was blocked by adding anti-HLA-DR monoclonal antibody to the xenogeneic MLR culture. The specificity of xenoreactive murine T cells was examined with regard to the secondary and tertiary xenogeneic MLR system. The xenoreactive murine T cells were restimulated by distinct human stimulator cells that had no shared HLA antigens with the stimulator used in the primary MLR. The data presented here show that the murine xenoreactive T cells recognize the shared determinant(s) of HLA-DR antigen on non-T, non-B stimulator cells. The xenoreactive murine T cell proliferative responses were mediated by Thy-1+, Lyt-1+, and Lyt-2- cells. Furthermore, the xenoreactive T cell responses required Ia+ cells, and Ia antigen on accessory cells plays a crucial role in eliciting the xenoreactive responses against human stimulator cells, while Ia+ accessory cells in the responding cell population are not essential for the elicitation of allogeneic MLR responses, as reported previously.     

Ia antigens in inbred rats and their relationship to the MLR phenotype.

Three different alloantisera were raised by using Ag-B/MLR disparate rats, and the cytotoxic activity remaining after absorption with erythrocytes to remove anti-Ag-B antibodies was examined. The alloantisera detected surface antigens present only on B cells and segregation studies demonstrated that the genes that code for these antigenic specificities were linked to the major histocompatibility complex. The reactivity of the alloantisera with splenic lymphocytes from a panel of strains representative of the currently known Ag-B groups showed that multiple specificities were present in two of the three antisera and that these specificities were shared by many inbred strains. The appropriate absorption studies showed, however, that each antiserum detected an unique specificity that was found only in those inbred strains that shared the same mixed lymphocyte reactivity (MLR) phenotype as the donor strain. The alloantiserum produced against the KGH strain inhibited the MLR reactions involving this strain only when it was used as the stimulating cell population. The antigens detected by the three alloantisera described here have the characteristics of Ia antigens, and they have tentatively been designated Ia.1 (ACI anti-KGH), Ia.3 (B3 anti-BN) and Ia.4 (MNR anti-DA).     

Functional activation of immune lymphocytes by antigenic stimulation in cell-mediated immunity. IV. Role of macrophage and its soluble factor in antigen-induced MIF production of immune T lymphocytes.

Histocompatibility-linked restriction of macrophage-T lymphocyte interaction in antigen-induced MIF production by sensitized lymphocytes was examined, by using combinations of inbred strain 2, strain 13, and JY-1 guinea pigs. The effective interaction of the antigen-bearing macrophages with the immune T lymphocytes was observed when the donor of the antigen-bearing macrophages and that of the immune lymphocytes shared Ia antigens of the major histocompatibility complex. Identities of B antigens and S antigens were not important for this cooperation. It was further demonstrated that the previously reported soluble factor derived from LPS-stimulated peritoneal adherent cells (macrophages) could help antigenic activation of the immune lymphocytes across the strain barrier provided a small number of macrophages (0.01%) from syngeneic strain were present. These results show that the presence of macrophages is absolutely required to present antigen to immune T lymphocytes in a genetically restricted manner and the soluble factor from macrophages appears to give a nonspecific effect on the lymphocyte activation in addition to or in collaboration with antigenic stimulation.     

Macrophage-lymphocyte clusters in the immune response to soluble protein antigen in vitro. VII. Genetically restricted and nonrestricted physical interactions.

We have assessed the genetic restrictions on physical interactions between macrophages and central lymphocytes and between central and peripheral lymphocytes in antigen-specific macrophage-lymphocyte clusters with respect to I-region differences of inbred strains 2 and 13 guinea pigs. When using lymphocytes from guinea pigs immunized with DNP-OVA or DNP-GL in CFA, the antigen-specific interaction between central lymphocyte and macrophage requires that both cells be derived from animals syngeneic at the I-region of the major histocompatibility complex. In studies using antigens, the responses to which is under the control of MHC-linked Ir genes, macrophages from the responder, but not from the nonresponder parental strain support cluster formation with responder x nonresponder F1(2 X 13) T cells. In contrast, the physical interactions between central and peripheral T lymphocytes are not restricted by the I-region of the MHC and the peripheral lymphocyte need not be from an animal immune to the antigen used to drive macrophage central lymphocyte interactions.     

The syngeneic mixed leukocyte reaction: the genetic requirements for the recognition of self resemble the requirements for the recognition of antigen in association with self

We have used cells from inbred strain 2 and strain 13 guinea pigs in order to define further the role of Ia antigens in the syngeneic mixed leukocyte reaction (MLR). The guinea pig syngeneic MLR resembled the autologous MLR in man in that it demonstrated both memory and specificity. The Ia antigens appeared to be the proliferative stimuli in that the primary stimulator cell was an Ia-positive adherent peritoneal exudate cell (PEC) and the reaction could be specifically inhibited by anti-Ia sera directed to the stimulator cell. We also demonstrated the existence of two (2 x 13)F1 T cell populations that were capable of reacting to one or the other parental PEC in the absence of any known exogenous antigen. These results suggest that the syngeneic MLR may represent T cell activation mediated through a receptor for self Ia.     

Antigen-binding receptors on T cells from long-term MLR. Evidence of binding sites for allogeneic and self-MHC products

Antibody inhibition of radiolabelled stimulator membrane vesicle binding by T blasts activated in the mixed lymphocyte reaction (MLR) was used to identify responder-cell determinants involved in the binding phenomenon. Antisera or monoclonal antibodies against Thy-1, Lyt-1, Lyt-2 and Ly-6 antigens were not inhibitory. However, antibodies against heavy-chain V region (V_H) determinants strongly inhibited vesicle binding by both primary and longterm MLR blasts. Anti-Ia (both alloantisera and monoclonal reagents) caused inhibition of antigen binding by primary MLR blasts only. T blasts from long-term MLR lines were neither Ia-positive, nor susceptible to blocking of antigen binding with anti-Ia. However, these cells were capable of specifically absorbing soluble syngeneic Ia material, with the concomitant appearance of vesiclebinding inhibition with anti-Ia sera. Acquisition of syngeneic Ia by T blasts was effectively blocked with the anti-V_H reagent. Passively bound self-Ia did not interfere with vesicle binding in the absence of anti-Ia. These results strongly suggest the existance of specific self-Ia acceptor sites closely linked to the receptors for stimulator alloantigens on T cells proliferating in MLR. A receptor model based on these findings is briefly discussed.Abbreviations used in this paper B10 C57BL/10 - Con A concanavalin A - FcR Fc receptor - FCS fetal calf serum - H heavy chain - Ia I-region associated antigen - Ig immunoglobulin - LPS lipopolysaccharide - Lyt T-lymphocyte differentiation antigen - MHC major histocompatibility complex - MLR mixed lymphocyte reaction - PM plasma membrane - T thymus derived - Tcr T-cell receptor - V variable region of Ig     

Macrophage-lymphocyte interaction. III. Site of alloantiserum inhibition of T lymphocyte proliferation induced by allogeneic or aldehyde-bearing cells.

Inhibition by anti-Ia sera of guinea pig T lymphocyte proliferation induced by allogeneic macrophages (MLR) and NaIO4 or neuraminidase-galactose oxidase-treated macrophages has been investigated in order to identify the target cell upon which the antisera act. Anti-2 and anti-13 alloantisera were found to inhibit both MLR and aldehydeinduced T cell reactivity when directed against the specificity of the stimulatory macrophage. Little or no inhibition was observed when these antisera were directed against the T lymphocyte specificity when cultures were harvested at the time of peak proliferation. In addition, anti-2 serum was found to inhibit macrophage-lymphocyte rosett formation at 20 hr between neuraminidase-galactose oxidase-treated strain 2 macrophages and strain 13 lymphocytes. These findings demonstrate that inhibition of T cell proliferation can be produced by anti-Ia sera directed against the macrophage and raise the possibility that Ir gene products may function in part at the level of the macrophage.     

T lymphocyte heterogeneity in the rat. III. Autoreactive T cells are activated by B cells

Evidence has been presented to show that CD4+ autoreactive T cell lines (ATs)2 in the rat require periodic stimulation with syngeneic spleen cells for in vitro proliferation. This proliferation can be blocked by treatment of the stimulator (spleen) cells with mAb to Ia antigens. Although ATs are Ia+ and can activate the allogeneic MLR, they fail to be autostimulatory. Fractionation of the spleen cells revealed that ATs can be stimulated with B cells and not by macrophages, although the latter were efficient in several accessory cell functions, including antigen presentation, lectin-dependent T cell activation and allogenic MLR response. Moreover, B cells proliferated and differentiated in response to AT cells. These data are compatible with a model in which ATs respond to hitherto undetermined B cell membrane antigen(s) in association with MHC class II antigens. These results may have important implications in understanding autoimmune responses.     

Liver sinusoidal lining cells express class II major histocompatibility antigens but are poor stimulators of fresh allogeneic T lymphocytes

Guinea pig liver sinusoidal lining cells (LSLC), a mixture of Kupffer cells (KC) and sinusoidal endothelial cells (EC), were examined for their capacity to function as antigen-presenting cells (APC). LSLC were extremely poor stimulators of freshly isolated allogeneic T lymphocytes even though a large number of them expressed class II major histocompatibility complex (MHC) antigens (Ia). This deficiency could not be explained by a lack of soluble factor production by LSLC, because an interleukin 1-containing macrophage (M phi) supernatant could not restore the capacity of LSLC to stimulate allogeneic T cells. Moreover, LSLC were able to promote mitogen-induced proliferation of accessory cell-depleted T lymphocytes. No evidence of suppression was apparent in experiments in which LSLC were added to cultures of T cells stimulated by allogeneic peritoneal exudate M phi (PEM). The Ia expressed by LSLC was functional because they were able to stimulate an alloreactive T cell line. When LSLC were mixed and co-cultured with either PEM syngeneic to the responding lymphocytes or Ia-negative fibroblasts, the allostimulatory ability of LSLC was greatly augmented. In contrast, the addition of mitogen-activated T cell supernatants had only a minimal effect on the capacity of LSLC to stimulate allogeneic T cells. The data suggest that LSLC lack a biologic property that is necessary for recognition of class II MHC determinants by fresh but not primed allogeneic T cells and that is not required to support T cell activation induced by nonspecific mitogenic lectins. These findings may be important in understanding the reason that antigen introduced into the portal blood appears not to initiate an immune response.     

Helper effects required during in vivo priming for a cytolytic response to the H-Y antigen in nonresponder mice

Induction of H-Y-specific cytotoxic T lymphocyte (CTL) responses in nonresponder female mice was attempted by i.v. injection of allogeneic male cells, followed by in vitro restimulation of recipient spleen cells with syngeneic male cells. Responses were obtained only in two strain combinations in which the recipients, although phenotypically nonresponders, carried responder alleles at class I major histocompatibility complex (MHC) loci, and the immunizing cells differed from the recipients at class II MHC loci. The two positive strain combinations were B10.A(2R) anti-B10.A(4R), and B10.GD anti-B10.D2(R101). In the first combination, both recipient and donor are nonresponders to H-Y, and the CTL are induced via a bystander effect of another CTL response to a previously undetected minor histocompatibility (H) antigen. This "carrier" antigen can only induce CTL against H-Y and itself when the immunizing cells express class II MHC molecules. Furthermore, the presence of H-Y and the carrier antigen on the same cell is a prerequisite for the generation of H-Y-specific CTL. In the second combination, the recipient is a nonresponder, whereas the donor is a responder. The two strains differ at only E alpha and E beta class II MHC loci. For the induction of CTL, H-Y and the foreign E molecule must be expressed on the same cells. Thus, the B10.D2(R101) cells that express E molecules on their surface probably provide the E-nonexpressor B10.GD recipients with a stimulus for the generation of H-Y-specific T helper cells. The data are consistent with the notion that antigen-specific class II MHC-restricted T helper cells are involved in the initiation of CTL responses to minor H antigens.     

Recognition and response to alloantigens in vivo. I. Negative and positive selection of MLR reactivity in murine peripheral blood lymphocytes to major histocompatibility complex and Mls antigens

Specific mixed lymphocyte reaction (MLR) responsiveness to allogeneic major histocompatibility complex (MHC), or minor lymphocyte-stimulating (Mls) determinants, was depleted in the peripheral blood lymphocytes (PBL) obtained from mice 24 to 48 hr after i.v. injection of 5 to 7.5 X 10(7) MHC or Mlsa-incompatible spleen cells, respectively. Results of cell mixture experiments suggest that the generation of suppressor cells was not the explanation for this specific reduction in MLR proliferation occurring with these PBL responder cells. To gain additional insight into parameters involved in the recognition of allodeterminants in vivo, experimental manipulations of the host environment and donor cell inoculum utilized in the negative selection procedure were employed. For example, removal of the spleen in the recipient animal, an anatomic site in which injected allogeneic cells and corresponding host antigen-reactive cells (ARC) are trapped, still permitted the specific depletion in murine PBL of host ARC for donor foreign MHC antigens. This finding may implicate other sites such as the liver where unprimed host alloreactive clones are trapped. In addition, irradiation of allogeneic donor cells significantly reduced their capacity to trap alloreactive T cell clones in vivo, whereas heat treatment of the donor cells completely eliminated this ability, even though the Ia determinants were still expressed, measured by flow cytometry. After the negative selection period, kinetic analysis of proliferation showed that 3, 4, or 5 days after injection of MHC-incompatible allogeneic spleen cells, the PBL of the recipient showed specific hyperresponsiveness to the MHC-haplotype of the donor cells. Interestingly, these primed PBL responder cells had the volume distribution of small resting cells; thoracic duct lymphocytes (TDL), positively selected by adoptive transfer of T cells to irradiated semiallogeneic recipients, are reported to be mainly blast cells. In contrast to the MLR hyperresponsiveness that results from priming with MHC-incompatible splenocytes, PBL, obtained at these later time points from mice primed with Mlsa-incompatible, H-2-compatible splenocytes, showed complete unresponsiveness in MLR to these Mlsa-bearing stimulator cells, as well as some nonspecific reduction in proliferation to MHC-incompatible stimulator cells regardless of their Mls genotype.(ABSTRACT TRUNCATED AT 400 WORDS)     

Demonstration of a new genetic locus in the major histocompatibility system of the rat

A new recombination within the major histocompatibility complex (RT1) of the rat has been detected. The recombination occurred between a wild-derived haplotype, provisionally designated p1, and the RT1 haplotype of the BN strain. The recombinant haplotype, designated p3, carries the RT1.A locus (classical histocompatibility antigens) of the BN strain, a locus from the BN strain that codes for the expression of an Ia antigen and strong mixed lymphocyte response (MLR), and a second locus derived from the p1 haplotype that controls the expression of a second Ia antigen, the ability to elicit a strong MLR and the immune response to poly(G1u⁵²Lys³³Tyr¹⁵). This recombinant therefore demonstrates the division of the RT1.B region into two loci, tentatively designated RT1.B and RT1.D, and provides evidence for the existence of at least four loci in the MHC of the rat.     

Antigen-presenting cells that induce anti-H-2K T-cell responses: Differences in stimulator-cell requirements for induction of proliferation and cell-mediated lympholysis

Splenic T or B cells, which have been depleted of adherent cells by passage through Sephadex G10 columns, fail to stimulate allogeneic lymph-node cells (LN) in primary mixed lymphocyte reactions (MLR) both when the stimulating antigens are H-2 plus Ia and H-2K only. This failure cannot be ascribed to lack of viability of G10-passed cells, since by dye exclusion they are 95 percent viable and can be induced to proliferate in vitro by exposure to LPS or allogeneic cells. Stimulation of MLR activity could be restored by addition of small numbers of plastic-adherent spleen cells (SAC) which had to be syngeneic with the G10-passed stimulator cells. Further, SAC alone without G10-passed cells induced MLR activity which was, on a cell-for-cell basis, 40 times more effective than that induced by unfractionated spleen cells. If the SAC were first depleted of Ia⁺ cells, no stimulation was obtained. This result was observed both in cases where responder and stimulator strains differed across the entireH-2-gene complex and in a mutant-wild type combination (CBA and H-2^km1) in which the difference between the two strains has been mapped to theK region only. These results indicate that Ia⁺ SAC contain a subset(s) of cells which are responsible for stimulation in MLR, regardless of whether the alloantigenic differences involve either Ia or H-2K. In contrast to the inability of G10-passed splenic cells to stimulate MLR activity, these cells were able to stimulate CTL from cytotoxic T lymphocyte precursors (CTL.P) in combinations where the antigenic differences between responder and stimulator were at the entireH-2 complex or atH-2K only. However, SAC were more potent stimulators of cell-mediated lympholysis (CML) activity on a cell-for-cell basis. Thus, either CTL.P can be stimulated by nonadherent spleen cells or they are specifically sensitive to a small subpopulation of contaminating cells that cannot readily be removed by G10 passage.     

Neonatal tolerance induction to Mlsa. II. T cells induce tolerance to Mlsa

We have investigated the ability of murine T cell lines to induce neonatal tolerance to Mlsa (minor lymphocyte stimulating). Mlsb mice were injected within 24 hr of birth with MHC (major histocompatibility complex) identical T cell lines generated by culturing responders from Mlsa strains with stimulators from Mlsb strains. Injected mice were tested at 6 to 8 weeks of age for responses in either primary mixed leukocyte reaction or IL-2 limiting dilution analysis. Mlsa specific responses by injected tolerant mice relative to noninjected controls were reduced by 92-98% in MLR and by 2- to 10-fold in IL-2 LDA. In contrast, responses against third-party MHC antigens by either the injected or the noninjected mice were identical. Fifty percent of all mice injected with the T cell lines were tolerant to Mlsa. These results strongly suggest that murine T cells express the Mlsa gene product.     

Mixed lymphocyte reaction in mice genetically selected for high (Hi/PHA) or low (Lo/PHA) responsiveness to phytohemagglutinin.

Lymph node cells from Hi/PHA and Lo/PHA mice were evaluated for proliferative response after stimulation by allogeneic lymphocytes (MLR) originating from four inbred strains of different H-2 haplotype (C57B1/6, DBA/2, CBA, A). Reactivity to MLR and PHA were compared in these two lines and in the four inbred strains. The high and low responder status of Hi/PHA and Lo/PHA, as determined by T mitogens lymphocyte responsiveness, was also observed when one measured T responsiveness after MLR. Values obtained with the four inbred strains are included in the range of those measured in Hi/PHA and Lo/PHA cells when stimulated by PHA as well as by allogeneic cells. In contrast, when used as stimulator cells, Hi/PHA or Lo/PHA lymphocytes induce an equivalent proliferative response versus every responder inbred strain studied. These experiments support the hypothesis of a common genetic control of proliferative response following PHA or MLR stimulation. The genes implicated would be different from those coding for I region associated antigens.     

Existence of T cells manifesting self-reactivity indistinguishable from alloreactivity

The studies reported here were designed to analyze the phenotypic characteristics of self-reactive T lymphocytes induced in culture by allogeneic effect factor (AEF), as well as the control of their functional activities by the major histocompatibility complex (MHC). Unprimed T cells cultured with AEF in the absence of exogenous stimulating target cells become activated against self-antigens, as evidenced by their ability to manifest two distinct activities. First, such cells could lyse syngeneic target cells. This cytolytic activity was directed against H-2K antigens and was mediated by Lyt-2+ T cells. Second, the AEF-activated T cells could be stimulated in a secondary culture to high levels of proliferative activity by irradiated syngeneic spleen cells. The stimulator cells in this syngeneic mixed lymphocyte reaction (MLR) were found to be Thy-1-negative, Ia-positive splenic adherent cells. Stimulation in the secondary syngeneic MLR was provided by I-region specificities, and the majority of the proliferating cells were Lyt-1+ cells. Finally, AEF-induced T cells were effective in serving as effectors of graft-vs-host reactions in vivo in syngeneic recipients. These results prove that, under appropriate conditions, murine T lymphocytes can display aggressive patterns of self-reactivity that are similar in both quantity and quality to the classical patterns of alloreactivity and may have great significance for our understanding of MHC recognition processes.     

Human T cells in cord blood: Abnormalities in Ia antigens induction by phytohemagglutinin and in autologous mixed lymphocyte reactions

About 25% of human T cells isolated from cord blood acquired Ia antigens following stimulation with phytohemagglutinin (PHA) for 72 hr. This percentage is markedly lower than that found in PHA-activated T-cell populations (PHA-T cells) isolated from peripheral blood of adults. The low expression of Ia antigens by human T cells from cord blood does not reflect abnormalities in the sensitivity to PHA stimulation and/or in the kinetics of induction of Ia antigens. PHA-T cells from cord blood display a low stimulatory activity in autologous mixed lymphocyte reactions (MLR). The defect does not reflect a nonspecific abnormality in the stimulatory activity of PHA-T cells from cord blood, since the latter do not differ from PHA-T cells from adults in their ability to stimulate allogeneic T cells from adults. Furthermore the defect does not reflect a nonspecific abnormality in the proliferative response of T cells from cord blood, since the latter display a normal proliferative response to PHA-T cells from adults. The defect in the proliferative response is not restricted to the autologous MLR with PHA-T cells, since it was found also in autologous MLR with non-T cells as stimulators. Correlation of the temporal evolution of the abnormalities of human T cells with the maturation of the immune system may contribute to our understanding of the role of Ia antigens in cell-cell interactions and of the biological significance of abnormalities of autologous MLR.     

The function of macrophages in antigen recognition by guinea pig T lymphocytes. III. Genetic analysis of the antigens mediating macrophage-T lymphocyte interaction.

Activation of immune T lymphocytes by antigen-pulsed macrophages is mediated by the Ia antigens of the guinea pig MHC or the products of closely linked genes. Studies using combinations of macrophages and T cells derived from outbred animals with different Ia antigens and/or Ir gene products have demonstrated that sharing of Ir gene products between macrophage and T cells is not sufficient for effective macrophage-T cell interaction. The role of the Ia antigens in the absence of the linked Ir gene products could not be directly examined because we were unable to identify an animal which bore the full complement of Ia antigens in the absence of the Ir gene that is normally associated with them. The results of these studies support the concept of the functional expression of the Ir gene product in the macrophage.     

Cloned human cytotoxic T lymphocyte (CTL) lines reactive with autologous melanoma cells. I. In vitro generation, isolation, and analysis to phenotype and specificity

Activation of peripheral blood lymphocytes (PBL) from a melanoma patient either in secondary MLC in which EBV-transformed B cells from the cell line JY were used as stimulator cells, or by co-cultivation with the autologous melanoma cells in a mixed leukocyte tumor cell culture (MLTC) resulted in the generation of cytotoxic activity against the autologous melanoma (O-mel) cells. From these activated bulk cultures four cloned cytotoxic T lymphocyte (CTL) lines were isolated. The CTL clone O-1 (T3+, T4+, T8-, OKM-1-, HNK-, and HLA-DR+), and O-36 (T3+, T4-, T8+, OKM-, HNK-, and HLA-DR+) were obtained from MLC, whereas the CTLC clones O-C7 (T3+, T4+, T8-, OKM-1-, HNK-, and HLA-DR+) and O-D5 (T3+, T4-, T8+, OKM-1-, HNK, and HLA-DR+) were isolated from autologous MLTC. All four CTL clones were strongly cytotoxic for O-mel cells but failed to lyse autologous fibroblasts and autologous T lymphoblasts. Moreover, the CTL clones lacked NK activity as measured against K562 and Daudi cells. Panel studies indicated that the CTL clones also killed approximately 50% of the allogeneic melanoma cells preferentially, whereas the corresponding T lymphoblasts were not lysed. Monoclonal antibodies against class I (W6/32) and class II (279) MHC antigens failed to block the reactivity of the CTL clones against O-mel and allogeneic melanoma cells, indicating that a proportion of human melanoma cells share determinants that are different from HLA antigens and that are recognized by CTL clones. In contrast to the CTL clones isolated from MLTC, the clones obtained from MLC also lysed JY cells, which initially were used as stimulator cells. The reactivity of O-36 against JY could be inhibited with W6/32, demonstrating that this reactivity was directed against class I MHC antigens. These results suggest that the lysis of O-mel and JY cells by O-36 has to be attributed to two independent specificities of this CTL clone. The specificity of the other cross-reactive CTL clone (O-1) could not be determined. The notion that individual CTL clones can have two specificities was supported by the following observations. The cytotoxic reactivity of both O-1 (T4+) and O-36 (T8+) against JY was blocked by monoclonal antibodies directed against T3 and human LFA-1, and against T3, T8, and human LFA-1, respectively.(ABSTRACT TRUNCATED AT 400 WORDS)