Prethymic nylon wool-passed bone marrow cells, substituting for helper T cells, can augment the generation of cytotoxic T lymphocytes from their precursors.

Nylon wool-passed bone marrow (NW-BM) cells treated with anti-Thy.1 monoclonal antibody and complement were added to a mixed lymphocyte culture which contained a limiting number of lymph node cells, as responder cells, and a sufficient number of mitomycin-c-treated allogeneic spleen cells as stimulator cells. NW-BM cells of the same MHC haplotype as responder cells enhanced the generation of allo-specific cytotoxic T lymphocytes (CTL) not only at a relatively high dose (3 x 10(3) cells/well) of responder cells, but also at an extremely dilute dose (1 x 10(3) cells/well). NW-BM cells which had a third-party MHC haplotype, a haplotype different from both responder and stimulator cells, also enhanced the generation of CTL at relatively high doses, but not at low doses, of responder cells. NW-BM cells which had MHC haplotypes identical with those of responder cells induced CTL from helper T cell-depleted responder cells, but NW-BM cells which had the third-party haplotype did not. These results showed that the enhancing effects of NW-BM cells of the same MHC haplotype as responder cells might be due to a specific helper effect and the enhancing effect of NW-BM cells of the third-party haplotype might be due to a nonspecific filler effect, which only conditioned the cultured cells. It was also found that, to exhibit the helper effect, NW-BM cells had to possess MHC class II, but not MHC class I, molecules in common with CTL precursors. This study showed that in the induction of CTL, prethymic NW-BM cells had a capability comparable to that of mature helper T cells.     

Antigen presentation by Langerhans cells in vivo: donor-derived Ia+ Langerhans cells are required for induction of delayed-type hypersensitivity but not for cytotoxic T lymphocyte responses to alloantigens

T cell activation in response to allogeneic stimulation and hapten-specific delayed-contact hypersensitivity responses in vivo can be initiated by Ia-bearing epidermal Langerhans cells (LC). By using a murine heterotopic corneal allograft model, we have investigated the requirement for allogeneic LC as antigen-presenting cells (APC) in the in vivo induction of delayed-type hypersensitivity (DTH) and cytolytic T lymphocyte (CTL) responses to alloantigens in fully allogeneic and H-2 I region-disparate strain combinations. LC-deficient, avascular central corneal allografts from BALB/c donors failed to induce DTH responsiveness when grafted to a subdermal bed on C57BL/6 recipients (p greater than 0.05), yet antigen-specific primary CTL reactivity developed within 7 days after grafting. LC-containing corneal-limbus allografts or central corneal allografts containing a latex bead-induced infiltrate of LC resulted in intense DTH as well as CTL responsiveness when grafted in this same strain combination. Similarly, LC-containing but not LC-deficient corneal allografts from A.TL donors induced DTH responsiveness in I region-disparate A.TH hosts despite the fact that these grafts survived for prolonged duration (less than 28 days). By contrast, CTL induction in I region-disparate hosts was independent of the presence of allogeneic LC. Corneal epithelial cells of grafts removed from I region-disparate hosts 7 days posttransplantation were shown by immunohistology to express the Iak antigens of donor origin. The possibility that bone marrow-derived allogeneic LC were a sufficient requirement for DTH induction was confirmed in experiments performed with CB6F1----B6 bone marrow chimeras used as corneal allograft donors. Corneal-limbus grafts obtained from mice 90 days after chimerization were shown by immunohistology to contain Iad-bearing CB6F1 LC as a sole source of class II alloantigens. When grafted to C57BL/6 recipients, LC-containing chimeric corneas induced DTH responsiveness that was similar in magnitude to that observed in C57BL/6 mice grafted with chimeric skin, yet no DTH response to LC-deficient chimeric central corneal grafts was observed. Moreover, in all cases, the chimeric corneal and skin allografts survived for prolonged duration (greater than 28 days). These results demonstrate that donor-derived LC act as APC in the induction of DTH responsiveness to allogeneic tissue; however, there was no apparent requirement for allogeneic LC in the induction of CTL responses to class I or class II MHC alloantigens.(ABSTRACT TRUNCATED AT 400 WORDS)     

Pretreatment with minor histocompatibility antigens prevents the development of functional CTL helper cell activity

We have been studying the regulation of allogeneic cytotoxic cells (CTL) in vivo. CBA/J (H-2k, mls d) responder mice are unable to develop CTL after an allogeneic footpad immunization if they are pretreated i.p. with spleen cells from either C3H/HeN (H-2k, mls c) or B10.BR (H-2k, mls b) mice. These mouse strain combinations are H-2 compatible but differ at the Mls and other minor histocompatibility loci. We reported that this state of CTL unresponsiveness is specific and that the allogeneic cells used for footpad immunization and the pretreatment strain must share both minor antigens and part of the MHC. In this paper, we describe some of the characteristic features of this CTL unresponsiveness. The CBA host plays an active role and appears to down-regulate its subsequent response against minor antigens after the initial pretreatment. This statement is based on the following: 1) The inhibition of in vivo CTL generation can be achieved by injecting F1 or irradiated C3H cells, i.e., under conditions where GVHD was not a factor; and 2) the state of unresponsiveness is abolished by host treatment with cyclophosphamide. In addition, we demonstrate that the lack of CTL development in pretreated responder animals is the result of impaired helper cell activity. Draining LNC from unresponsive mice can become functionally cytolytic if cultured in a Con A-activated spleen cell supernatant. However, normal CTL responses were not restored after adult thymectomy or splenectomy. Thus, the state of CTL inhibition that is induced by the minor antigen pretreatment is the result of a host-mediated regulatory circuit.     

The role of T cell accessory molecules in the generation of class II-specific xenogeneic cytolytic T cells

In the generation of allogeneic, hapten-modified and virus-specific cytotoxic T cell (CTL) responses there is usually a requirement for T-T interaction between the T helper cell (TH) and the precursor CTL (CTL). We have investigated the role of a TH signal in the induction of a xenogeneic mouse antihuman CTL response by using membranes and liposomes bearing the xenogeneic antigen to stimulate primed responders. The TH signal can be achieved by either an Ia-restricted, L3T4+ DR-specific T cell or by the addition of nonspecific T helper factors(s). This signal is delivered to an Lyt-2+, L3T4-DR-specific CTL to generate active xenogeneic (xeno-) CTL. The roles of the T cell accessory molecules L3T4, Lyt-2, and LFA-1 in the generation of and target cell lysis by xeno-CTL are investigated.     

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.     

CD4 help-independent induction of cytotoxic CD8 cells to allogeneic P815 tumor cells is absolutely dependent on costimulation

Mice made transgenic (Tg) for a rat anti-mouse CD4 Ab (GK mice) represent a novel CD4-deficient model. They not only lack canonical CD4 cells in the periphery, but also lack the residual aberrant Th cells that are found in CD4-/- mice and MHC class II-/- mice. To analyze the role of CD4 help and costimulation for CTL induction against alloantigens, we have assessed the surface and functional phenotype of CD8 cells in vivo (e.g., clearance of allogeneic P815 cells) and in vitro. In our CD4-deficient GK mice, CTL responses to allogeneic P815 cells were induced, albeit delayed, and were sufficient to eliminate P815 cells. Induction of CTL and elimination of allogeneic P815 cells were inhibited both in the presence and absence of CD4 cells by temporary CD40 ligand blockade. This indicated that direct interaction of CD40/CD40L between APCs and CD8 cells may be an accessory signal in CTL induction (as well as the indirect pathway via APC/CD4 interaction). Furthermore, whereas in CTLA4Ig single Tg mice P815 cells were rejected promptly, in the double Tg GK/CTLA4Ig mice CTL were not induced and allogeneic P815 cells were not rejected. These findings suggest that CD40/CD40L is involved in both CD4-dependent and CD4-independent pathways, and that B7/CD28 is pivotal in the CD4-independent pathway of CTL induction against allogeneic P815 cells.     

Regulation of the production of immune interferon and cytotoxic T lymphocytes by interleukin 2

The activation of alloantigen-specific cytotoxic T lymphocyte precursors is dependent upon the presence of both macrophages and helper T cells or regulatory molecules derived from these facilitative cells. Three biochemically distinct helper factors have been identified: interleukin 1 (macrophage-derived), Interleukin 2 (T cell derived), and immune interferon. All 3 factors are found in supernatants of mixed lymphocyte cultures (MLC), however, the removal of macrophages from these cultures completely ablates the production of these factors as well as the induction of cytotoxic T lymphocytes (CTL). The addition of IL 2 to these macrophage-depleted MLC restores the ability of responder T cells to: 1) bypass the requirement for macrophage soluble function, 2) produce immune interferon, and 3) generate CTL. The kinetics and dose response of immune interferon production in response to IL 2 correlates with the generation of CTL. The production of immune interferon as well as the generation of CTL requires T cells, alloantigen, and IL2. Furthermore, the induction of CTL by IL2 was neutralized by the addition of anti-immune interferon. These data suggest that: 1) the regulation of immune interferon production is based on a T to T cell interaction mediated by IL 2, and 2) immune interferon production may be required for IL 2 induction of CTL. These findings are consistent with the hypothesis that the induction of CTL involves a linear cell-factor interaction in which IL 1 (macrophage-derived) stimulates T cells to produce IL 2, which in turn stimulates other T cells to produce immune interferon and become cytotoxic.     

Regulatory mechanisms in cytotoxic T lymphocyte development. III. Induction, specificity, and genetic restriction of an in vitro suppressor T cell

We addressed questions pertaining to the immunogenetics of an in vitro alloinduced suppressor T cell (Ts) previously shown to inhibit cytotoxic T-lymphocyte (CTL) development by suppressing CTL precursor proliferation. Using intra-MHC recombinant strains of B10 congenic mice, the requirements for H-2 differences to induce Ts activity, the antigen specificity of the Ts, and the genetic restriction of Ts function were studied. It was found that differences at the K, D, or I regions alone can induce strong suppressor activity. Suppression of CTL development does not appear to be genetically restricted since the Ts inhibit CTL from responder cells disparate at K, K and D, I, or K and I. The alloinduced Ts is specific for the antigen stimulating its induction, but also inhibits CTL responses against immunologically unrelated determinants, even between class I and class II antigens, provided those determinants are carried on cells expressing the original inducing antigen. Ts can be triggered by antigens present on the responder cells but absent on the stimulator cells, indicating that the suppressive signal may be exerted directly on the responder population without specific interaction with stimulator cells.     

Minor histocompatibility antigens on canine hemopoietic progenitor cells

Adoptive immunotherapy with CTL against minor histocompatibility Ags (mHA) provides a promising way to treat leukemia relapse in allogeneic chimeras. Here we describe the in vitro generation of CTL against mHA in the dog. We tested their inhibitory effect on the growth of hemopoietic progenitor cells stimulated by hemopoietic growth factors in a 4-day suspension culture. CTL were produced by coculture of donor PBMC with bone marrow-derived dendritic cells (DCs). These DCs were characterized by morphology, high expression of MHC class II and CD1a, and the absence of the monocyte-specific marker CD14. Characteristically these cells stimulated allogeneic lymphocytes (MLR) and, after pulsing with a foreign Ag (keyhole limpet hemocyanin), autologous T cells. CTL were generated either ex vivo by coculture with DCs of DLA-identical littermates or in vivo by immunization of the responder with DCs obtained from a DLA-identical littermate. In suspension culture assays the growth of hemopoietic progenitor cells was inhibited in 53% of DLA-identical littermate combinations. In canine families mHA segregated with DLA as restriction elements. One-way reactivity against mHA was found in five littermate combinations. In two cases mHA might be Y chromosome associated, in three cases autosomally inherited alleles were detected. We conclude that CTL can be produced in vitro and in vivo against mHA on canine hemopoietic progenitor cells using bone marrow-derived DCs.     

Mutations in H-2K b influence the specificity of alloreactive effector cells included in the repertoire of H-2D b -restricted cytotoxic T lymphocytes against Moloney leukemia virus

Moloney leukemia virus-specific cytotoxic T lymphocytes (CTL), generated by secondary in vitro stimulation of spleen cells with syngeneic virus-infected cells, frequently lysed not only syngeneic virus-infected cells, but also noninfected allogeneic target cells. This phenomenon was studied with B6(H-2 ^b ) responder cells and a series of H-2K ^b -mutant responder cells. Thus, B6 Moloney-specific CTL lysed noninfected K ^b -mutant cells, but not B6 cells, whereas K ^b -mutant Moloney-specific CTL lysed noninfected B6 cells and not noninfected cells of the same mutant. Cold-target-inhibition studies showed that the CTL reactions against different allogeneic cells were mediated by different subpopulations of virus-specific CTL: lysis of allogeneic target cells was fully inhibited only by the same allogeneic and by syngeneic virus-infected cells, but not by another allogeneic cell, also lysed by the same effector-cell population. Lysis of syngeneic virus-infected cells could not be inhibited by allogeneic target cells. These data imply that a minority of virus-specific CTL shows cross-reactivity with a given allogeneic target cell. It is concluded that limited amino acid substitutions in the K^b molecule alter the repertoire of Moloney virus-specific CTL, as reflected in alloreactive CTL populations, even though the virus-specific CTL response. of B6 and all K ^b mutants is mainly D^b-restricted. Thus, the development of tolerance to self class-I major histocompatibility complex (MHC) molecules affects the repertoire of self-restricted cytotoxic T cells.     

The role of class I MHC products in polyclonal activation of CTL function

The generation of CTL function by agents such as lectins, oxidative chemicals, or serum components has been regarded as independent of class I MHC products, because the CTL thus generated are able to lyse virtually any allogeneic target. However, we show here that CTL activation by lectin requires interaction of the pre-CTL with a class I MHC product on the lectin-presenting cell. The lectin-presenting cell can be an irradiated syngeneic or allogeneic spleen cell or, alternatively, lectin can be seen on a neighboring pre-CTL. In either case, there is an absolute requirement for simultaneous (although probably unlinked) perception of a class I MHC product. These results suggest that restricted clonal CTL activation by antigen, and polyclonal activation by so-called "nonspecific" mitogenic agents, may proceed through similar if not identical pathways.     

Lyt-2+ suppressor T cells are resistant to anti-Lyt-2 antibody blocking

Lyt-2 molecules play a role in antigen recognition by cytotoxic T lymphocytes (CTL). In an attempt to determine whether Lyt-2 molecules play a similar role in suppressor T cell (Ts) functions, the effect of anti-Lyt-2 antibodies on Ts generation and effector activity was studied. Allospecific Ts were induced in allogeneic mixed lymphocyte cultures (MLC). Anti-Lyt-2 antibodies added to MLC in the absence of complement abolished CTL generation, but had no effect on concomitant induction of Ts. In a different experimental system, allospecific Ts were induced in cultures treated with pyrilamine, which blocks generation of CTL but allows differentiation of Ts. The addition of anti-Lyt-2 antibodies to pyrilamine-treated MLC resulted in unaffected induction of Ts. It was further demonstrated that the effector activity of Ts was as resistant to anti-Lyt-2 antibodies as their induction, in contrast to the cytolytic activity of CTL, which was inhibited by the same antibodies. Ts in the present experimental system were Lyt-2+ antigen-specific cells. It therefore appears that Lyt-2 molecules, although expressed on both CTL and Ts, are involved in CTL activity, but do not play an essential role in Ts function.     

T cell-accessory cell interactions that initiate allospecific cytotoxic T lymphocyte responses: existence of both Ia-restricted and Ia-unrestricted cellular interaction pathways

The specificity of the T-accessory cell interactions that initiate primary allospecific cytotoxic T lymphocyte (CTL) responses were found to be surprisingly diverse and of three distinct major histocompatibility complex (MHC) specificities, involving responder T cell recognition of: a) self-Ia accessory cell determinants, b) allo-Ia accessory cell determinants, or c) allo-K/D accessory cell determinants. Any one of these T-accessory cell interactions was sufficient to initiate allospecific CTL responses. It was observed that when accessory cells did not express foreign class I MHC determinants, primary allospecific CTL responses were invariably initiated by Ia-restricted T-accessory cell interactions. In contrast, it was observed that when accessory cells did express foreign class I MHC determinants, primary allospecific CTL responses could be initiated by Ia-independent T-accessory cell interactions that were specific for allogeneic, but not self, K/D determinants and that did not involve recognition of polymorphic Ia determinants. The MHC specificities of the T-accessory cell interactions that initiate primary allospecific and primary trinitrophenyl (TNP)-self CTL responses were also compared. It was observed that primary allospecific and primary TNP-self CTL responses could be initiated by self-Ia-restricted T-accessory cell interactions, and that in both responses the Ia determinants that the responding T cells recognized as self-specificities on the accessory cell surface were those that their precursors had encountered on radiation-resistant thymic elements in their differentiation environment. In contrast to the initiation of primary TNP-self CTL responses that required the activation by accessory cells of Ia-restricted T helper (TH) cells, allospecific CTL responses could also be initiated by class I-restricted T cells specific for accessory cell K/D determinants. Interestingly, such class I-restricted T cells present in primary responder cell populations were triggered only by recognition of allogeneic, but not self, K/D accessory cell determinants, even when the accessory cells were modified with TNP. Thus, the present study demonstrates that primary allospecific CTL responses, but not TNP-self CTL responses, are initiated by Ia-restricted or Ia-independent cellular interaction pathways. These results raise the possibility that unprimed class I-restricted TH cells that mediate the Ia-independent cellular interaction pathway may predominantly express an allospecific, but not a self + X-specific, receptor repertoire. Possible mechanisms by which these distinct T-accessory cell interactions initiate primary allospecific CTL responses are discuss     

Allogeneic T cell activation triggering by MHC class I antigens

The role of MHC-encoded class I molecules in allogeneic activation and proliferation of human T lymphocytes was investigated. The study was performed by using primary mixed culture of lymphocytes from MHC recombinant siblings identical for MHC class II Ag (DR, DP, DQ) and displaying MHC class I disparity. The results indicate that such allogeneic combination is sufficient to trigger early activation steps within responder T cells without promoting a significant proliferation. After MHC class I allosensitization, a significant proportion of cells entered the cell cycle (G0----G1). The stimulatory potential of MHC class I Ag was further stressed by the specific induction on responder cells of IL-2R (22% T cell activation Ag positive). Under the same experimental conditions, transferrin receptor expression and IL-2 activity were not detectable. This is consistent with the low T cell proliferation. Exogenous rIL-1 did not improve IL-2 production and the subsequent T cell proliferation indicating that these two events were not associated with a defective accessory cell function involving IL-1 release. MHC class I disparity can also prime precursor CTL to differentiate into IL-2-dependent functional MHC restricted cytotoxic T cells. Conversely IFN-gamma had no effect. Addition to the culture of W6/32, a mAb specifically directed against a monomorphic determinant on human class I HLA-A, -B, and -C Ag was able to block all these activation events. These data clearly indicate a role of HLA class I Ag involvement in the early events triggering allogeneic T cell activation.     

CD3- bone marrow cells augment the generation of cytotoxic T lymphocytes showing a preference for the X-chromosome linked gene product of stimulator cells

Responder cells, composed of both a limited number of nylon wool-passed lymph node (NW-LN) cells and an excess number of CD3+ cell-depleted bone marrow (CD3- BM) cells from the same strain of mice, were stimulated with allogeneic spleen cells in vitro. The CD3- BM cells augmented the generation of allogeneic major histocompatibility complex (MHC) class I specific cytotoxic T lymphocytes (CTL) from NW-LN cells. C3H/He (H-2k, C3H background) responder cells were stimulated with either B10.D2 (H-2d, B10 background) or BALB/c (H-2d, BALB background) spleen cells. In the former stimulation, the CTL induced lysed B10.D2 target cells more efficiently than the BALB/c cells. Furthermore, these CTL lysed more (B10.D2 x BALB/c) F1 male target cells than (BALB/c x B10.D2) F1 male. In the latter stimulation, the CTL lysed more BALB/c than B10.D2 cells, and more (BALB/c) x B10.D2) F1 male than (B10.D2 x BALB/c) F1 male. The reciprocal mixed lymphocyte cultures (MLC) were carried out, in which BALB/c responder cells were stimulated with either C3H/He or B10.BR (H-2k, B10 background) spleen cells. In the former stimulation, the CTL induced lysed more C3H/He or (C3H/He x B10.BR) F1 male target cells than B10.BR or (B10.BR x C3H/He) F1 male, and in the latter, the reciprocal results were obtained. These results suggested that the CTL induced had a preference for the X-chromosome linked gene products (Xlgp), besides the specificity for the allogeneic MHC class I, of the mice used as stimulator.     

Cell types involved in cytotoxicity induced by heated cells and inhibition of this cytotoxicity by anti-human B cell sera.

We have studied the induction of cytotoxic activity in human peripheral blood lymphocytes by heated allogeneic cells. By separating T and B cells from the responder and stimulator cell populations we found that cytotoxic cells are generated in responder T cell populations by both T and the B stimulator cells. Rabbit antisera to a membrane glycoprotein complex (33,000 and 27,000 m.w. by SDS-gel electrophoresis) isolated from a human B cell line were utilized to explore further the nature of the effector cells in this type of cytotoxicity. This antiserum, present during the 6-day-culture period, blocked generation of cytotoxic effector cells. Depletion of cells bearing the B cell antigen from the responder cell population by anti-B cell serum and complement (C) eliminated cytotoxicity. Furthermore, heated cell-induced cytotoxicity was blocked by simply pretreating the responder or the stimulator cell populations with anti-B cell serum in the absence of C. Apparently the human lymphocyte that functions as the effector cell in heated cell-induced cytotoxicity bears the Ia-like antigen that might be important in triggering this type of cytotoxicity.     

Dissociation of differentiation and proliferation in the primary induction of cytolytic T lymphocytes by alloantigens

The requirement for DNA synthesis in the induction of cytolytic T lymphocytes (CTL) by alloantigens has been investigated. C57BL/6 splenic T cells purified by passage on nylon wool columns were stimulated in vitro in mixed leukocyte culture (MLC) and assayed for cytotoxicity against 51Cr-labeled target cells. With this system, CTL activity was detectable after 24 hr of MLC and reached high levels after 48 hr. Addition of cytosine arabinoside (ARA-C) or hydroxyurea to such cultures at concentrations that were sufficient to inhibit DNA synthesis by greater than 98% did not reduce CTL activity measured after 24 hr; however, the increase in activity that occurred between 24 and 48 hr in control cultures was strongly reduced (or abolished) by these drugs. Velocity sedimentation analysis of MLC cells activated for 48 hr in the presence of ARA-C further revealed that CTL precursor lymphocytes had enlarged into medium- to large-sized CTL under these conditions. These studies provide direct evidence that the primary induction of CTL by alloantigens can be dissociated into a differentiation step, which occurs within 24 hr in the absence of DNA synthesis and is accompanied by blast transformation, and a subsequent proliferation.     

Individual differences in the cytotoxic T-lymphocyte response in man to public HLA determinants

The allospecific anti-HLA response of cytotoxic T lymphocytes (CTL) from 22 unrelated individuals and 7 monozygous twin pairs was examined. From each responder, CTL were generated in several responder-stimulator combinations, each mismatched for one HLA-A or -B antigen. The CTL were assayed in the cell-mediated lympholysis (CML) on panels of third-party target cells, comprising cells that express the stimulating antigen (specific target cells), cells that express an antigen cross-reactive with the stimulating antigen (CREG target cells), and cells that do not express either the stimulating or a cross-reactive antigen (nonsharing target cells). Individual variations in the allo-CTL response were observed. We identified individuals (responders) who showed a consistently narrow CTL response and those who showed a broad reaction pattern to various stimulator cells. The narrow response was restricted almost entirely to specific target cells; the broad response comprised lysis of specific, CREG, and nonsharing target cells. These differences were evidently not dependent on the HLA-A, -B, -C phenotype of the responder, because HLA-A, -B, (-C)-identical individuals responded differently to the same stimulator. The identical response of monozygous twins indicates that the allogeneic CTL response is genetically controlled. The CTL response is not regulated by the HLA-DR antigens of the responder, nor is it influenced by the DR mismatch between responder and stimulator. The observed differences were not dependent on sex or age and could not be explained by differences in the T-lymphocyte subsets (OKT3+, OKT4+, OKT8+) or by differences in proliferative reactivity to mitogens (phytohemagglutinin, concanavalin A, phorbol-myristate acetate, pokeweed mitogen, anti-T3 monoclonal antibodies). The IL-2 activity in the supernatants of mixed lymphocyte cultures of broad and narrow responder-stimulator combinations did not differ.