Specific T-cell-mediated killing of autologous lung tumour cells

The phenomenon that strong syngeneic T-cell-mediated cytotoxicity is observed if killer, stimulator, and target cells share H-2 histocompatibility antigens is called H-2 restriction. Here a syngeneic model system making use of hapten-coupled stimulator and target cells is used to explore whether H-2 restriction is absolute or not. Using TNP-coupled spleen or tumor cells as stimulator or target cells in syngeneic and allogeneic situations, it is shown that neither the induction step nor the effector step of TNP-dependent killing is H-2 restricted. By varying the experimental assay conditions more or less H-2-restricted, TNP-dependent killing can be observed. For instance, suboptimal coupling of TNP to targets may result in H-2-restricted killing. Similarly, the use of spleen cell targets as opposed to spleen blast cells or tumor cells may result in H-2-restricted lysis. In contrast optimal coupling of TNP to sensitive target cells and coupling of TNP to cells with certain H-2 haplotypes may lead to significant TNP-dependent killing which is not H-2 restricted. Since hapten-coupled cells lacking H-2 are neither stimulators nor targets these results suggest that the T-cell receptor recognizes TNP-modified H-2 antigens simply as nonself-H-2. Thus hapten coupling of syngeneic cells appears to lead to a histocompatibility antigen change similar to the situation in an allogeneic cytotoxic reaction. Experiments are presented which support this view showing that TNP-coupled and uncoupled syngeneic or allogeneic stimulator and target cells cross-react. For instance allogeneic sensitization may lead to killing on TNP-coupled targets syngeneic to the effector cells and TNP-coupled stimulator cells syngeneic to the effector cells may induce killing on uncoupled syngeneic targets. TNP-dependent cytotoxicity can therefore be envisaged as a kind of allogeneic reactivity due to modification of H-2 antigens by the TNP coupling. This conclusion may have bearing on other model systems in which syngeneic killing appears to be H-2 restricted. In support of this possibility it is shown that allogeneic sensitization may lead to priming of memory cells able to respond to minor histocompatibility antigens.     

Natural killer (NK)-like cytotoxic activity of allospecific T cell receptor-gamma,delta+ T cell clones. Distinct receptor-ligand interactions mediate NK-like and allospecific cytotoxicity

We recently generated a series of human alloantigen-specific, CD3+,TCR-gamma,delta+ clones by stimulating CD3+,CD4-,CD8- T cells from normal individuals with allogeneic lymphoblastoid cell lines (LCL). As reported previously, these clones display cytotoxic activity against their specific stimulators but not against irrelevant LCL. Further studies of these and other TCR-gamma,delta+ clones, described in this report, indicate that most but not all of these clones express the NK cell associated marker, NKH-1 or Leu-19, and kill NK-sensitive targets such as the K562 and Molt 4 lines, but not an irrelevant LCL or NK-resistant line, Raji. TCR-gamma,delta+ clones which lacked expression of Leu-19 lysed their allospecific targets but had no detectable NK activity. The allospecific cytotoxicity of Leu-19+ and Leu-19- clones was inhibited by mAb to CD3 or the TCR delta-chain. In contrast, the NK-like activity of the Leu-19+ clones was enhanced by these antibodies over a wide range of antibody concentration. Although mAb to LFA-1 markedly inhibited both the allospecific and NK-like activity of these clones, an HLA class I framework specific mAb (W6/32) had no effect on NK-like cytolysis but did inhibit allospecific killing, suggesting that the target structures on the surface of allospecific and NK-sensitive cells are distinct. The receptors utilized by the TCR-gamma,delta+ clones to recognize NK-sensitive and allospecific targets are also distinct, since killing of NK-sensitive targets was blocked by the presence of cold (unlabeled) NK-sensitive cells but not by cold allospecific targets, whereas allospecific cytolysis was inhibited by cold allospecific targets but not by NK-sensitive cells. We conclude that some CD3+,TCR-gamma,delta+ clones exhibit NK-like as well as allospecific killing and that these two activities are mediated by distinct receptor-ligand interactions.     

NK-like cytotoxicity of allospecific gamma delta TCR+ T cell clones]

We recently generated a series of human alloantigen-specific, CD3+, gamma delta- TCR+ clones by stimulating CD3+, CD4-, CD8- T cells from normal individuals with allogeneic lymphoblastoid cell lines (LCL). These clones display cytotoxic activity against their specific stimulators but not against irrelevant LCL. Most but not all of these clones express the NK cell associated marker, CD57, and kill NK-sensitive targets such as the K562 and Molt 4 lines, but not NK-resistant line, Raji. Gamma delta clones which lacked expression of CD57 had no detectable NK activity. The allospecific cytotoxicity of CD57+ and CD57- clones was inhibited by mAb to CD3 or the TCR delta- chain. In contrast, the NK-like activity of the CD57+ clones was enhanced by these antibodies over a wide range of antibody concentration. An HLA class I framework-specific mAb had no effect on NK-like cytolysis but did inhibit allospecific killing, suggesting that the target structures on the surface of allospecific and NK-sensitive cells are distinct. The receptors utilized by the gamma delta- TCR+ clones to recognize NK-sensitive and allospecific targets are also distinct, since killing of NK-sensitive targets was blocked by the presence of cold (unlabeled) NK-sensitive cells but not by cold allospecific targets, whereas allospecific cytolysis was inhibited by cold allospecific targets but not by NK-sensitive cells. We conclude that some CD3+, TCR- gamma delta+ clones exhibit NK-like as well as allospecific killing and that these two activities are mediated by distinct receptor-ligand interactions.     

In vitro induction of immunological tolerance

IL-2 was previously shown to induce cytotoxic effectors with a broad spectrum of target specificities in thymus and spleen cell cultures. This study was designed to show whether T cells activated by H-2 allogeneic cells in MLC or by syngeneic tumor cells in MLTC are also potential targets for these cytotoxic effectors. We found that thymocytes activated in vitro for 5 days by rIL-2 were capable of killing tumor cells as well as activated T cells. Thymocytes activated by IL-2 were accordingly utilized as a means of effecting clonal deletion of T cells activated by H-2 allogeneic target cells in MLC. To establish whether the unresponsiveness is specific. IL-2-activated thymocytes were added as third party cells to MLC and MLTC. The results showed that both T cells, proliferating in response to H-2 allogeneic cells, and CTL, reactive against syngeneic tumors or H-2 allogeneic cells, are eliminated from the T cell pool. Only alloreactive T cells are specifically eliminated in MLC by IL-2-activated thymocytes, as the remaining T cells are capable of proliferating and generating CTL in response to antigenically unrelated third party allogeneic cells. The possibility that unresponsiveness might be due to soluble factors was ruled out by studies performed with a diffusable "chamber insert" culture system. The results provide evidence that IL-2-activated thymocytes induce in vitro T cell tolerance.     

Studies of H-2 restriction in cell-mediated cytotoxicity and transplantation immunity to Leukemia-associated antigens.

H-2 dependency of T cell-mediated cytotoxicity and transplantation immunity to leukemia-associated antigens has been investigated. Through the use of a 20-hr 125IUdR release assay, it was found that the induction of T cell-mediated cytotoxicity against Friend virus-induced leukemias of different H-2 haplotype orgins could be produced by immunization with both syngeneic and allogeneic tumor cells; the effector cells that were generated by syngeneic immunization could also provide effective killing of allogeneic tumor cells, although the killing of allogeneic targets might require a longer incubation time (20 to 40 hr). Furthermore, in vivo transplantation immunity against Friend virus-induced leukemias also was induced by immunization with both syngeneic and allogeneic tumors and syngeneic immunization could induce specific protection against the challenge with a-logeneic tumor in x-irradiated hosts. These findings clearly indicate that, both at the sensitizing phase and effector phase of the immune response, there is no strict H-2 dependency for T cell-mediated cytotoxicity or in in vivo transplantation imunity to leukemia-associated antigens.     

The virus-specific and allospecific cytotoxic T-lymphocyte response to lymphocytic choriomeningitis virus is modified in a subpopulation of CD8(+) T cells coexpressing the inhibitory major histocompatibility complex class I receptor Ly49G2

The role of negatively signaling NK cell receptors of the Ly49 family on the specificity of the acute CD8(+) cytotoxic T-lymphocyte (CTL) response was investigated in lymphocytic choriomeningitis virus (LCMV)-infected C57BL/6 mice. Activated CD8(+) T cells coexpressing Ly49G2 expanded during LCMV infection, and T-cell receptor analyses by flow cytometry and CDR3 spectratyping revealed a unique polyclonal T-cell population in the Ly49G2(+) fraction. These cells lysed syngeneic targets infected with LCMV or coated with two of three LCMV immunodominant peptides examined. Transfection of these sensitive targets with H2D(d), a ligand for Ly49G2, inhibited lysis. This was reversed by antibody to Ly49G2, indicating effective negative signaling. LCMV characteristically induces an anti-H2(d) allospecific T-cell response that includes T-cell clones cross-reactive between allogeneic and LCMV-infected syngeneic targets. The CD8(+) Ly49G2(+) population mediated no allospecific killing, nor was any NK-like killing observed against YAC-1 cells. This study shows that CD8(+) Ly49G2(+) cells participate in the virus-induced CTL response but lyse a more restricted range of targets than the rest of the virus-induced CTL population.     

Fine specificity of HLA-B27 cellular allorecognition. HLA-B27f is a functional variant distinguishable by cytolytic T cell clones

Three HLA-B27 allospecific cytolytic T lymphocyte (CTL) clones were isolated by limiting dilution of HLA-B27-negative responder cells stimulated with HLA-B27.1-positive lymphoblastoid cells. These clones displayed three distinct reaction patterns when tested for their lytic ability against target cells expressing various structurally defined HLA-B27 subtypes. One of the clones was specific for HLA-B27.1; a second CTL clone reacted only with B27.1 and, less efficiently, with B27.2; the third clone recognized both B27.1 and B27f targets but not cells expressing any other B27 subtype. These results indicate that HLA-B27f is a functional variant amenable to differential recognition by alloreactive CTL. A correlation of the structure of the HLA-B27 subtypes with the reactivity of these clones revealed that multiple B27-specific alloreactive CTL are activated against epitopes of the HLA-B27.1 molecule sharing common structural features. This illustrates the complexity and fine specificity of the allogeneic CTL response against class I HLA antigens and suggests that their immunodominant regions are those which are capable of eliciting a diverse polyclonal response against each of these regions, rather than inducing the selective expansion of a single T cell clone.     

Detection of double target binders at the single cell level: an evaluation of the specificity of NK and MLC-induced NK-like cells

MLC-generated cells were tested on 7 consecutive days in the single cell cytotoxicity assay to determine the kinetics of natural and allospecific killing. Maximum cytotoxicity to the NK-sensitive target, K562, was found on Day 3 of MLC with an increase at that time in both the number of cells binding and the number of cells killing K562. The maximum allospecific response was found on Days 6 and 7 with an increase in cells able to bind and kill the alloantigen-bearing target. To determine whether the anti-K562 and allospecific killing were mediated by the same effector cells or different cell populations, both targets were tested simultaneously in the single cell assay. At no time during the 7 days were cells detected capable of simultaneously binding both K562 and allospecific targets. These data indicate that there are two different cell populations responsible for allospecific cytotoxicity and MLC-induced NK-like cytotoxicity. The cytotoxic specificity of unstimulated and MLC-generated NK-like cells was also investigated. When two different NK-sensitive targets (e.g., K562 and MOLT-4) were tested together in the single cell assay, there was no concurrent binding of targets by either fresh PBL prior to MLC stimulation or Day 3 MLC-generated cells. When unstimulated effector cells were enriched for NK activity by Percoll density gradient centrifugation, only a small number of effector cells simultaneously binding two different NK-sensitive targets was detected in the single cell assay. These results imply that the NK cell population is heterogeneous and composed of subpopulations recognizing diverse target specificities.     

Mechanism of target cell lysis by cytotoxic T lymphocytes (CTL) employing RSV-induced H-2 congenic and recombinant mouse tumor cells: demonstration of soluble mediators released from H-2-restricted CTL clones

The secretion and the specificity of cytotoxic mediators from H-2-restricted cytotoxic T lymphocytes (CTL) were examined using non-virus-producing target tumor cells induced by the Schmidt-Ruppin strain of Rous sarcoma virus (SR-RSV) in B10 congenic and recombinant mice. By using rat concanavalin A supernatant, two H-2-restricted CTL clones were established from cytotoxic effector cells of B10.A(5R) mice primed with SR-RSV-induced syngeneic tumor Cell-free supernatants from the H-2-restricted CTL clones cocultured with syngeneic tumor cells had selectively high cytotoxic activity for syngeneic and H-2-compatible tumor cells, but not for H-2-incompatible tumor cells. YAC-1 cells, and B10.A(5R) blasts as defined in the 5-hr 51Cr-release assay. The cytotoxic activity was detected in the cell-free supernatants from the CTL clones cocultured with the CTL-sensitive syngeneic and H-2-compatible tumor cells, but not with the CTL-insensitive tumor cells and YAC-1 cells. The cytotoxic activity of the cell-free supernatant could be adsorbed by the syngeneic tumor cells, but not by YAC-1 and L(s) cells. Thus, the H-2-restricted CTL clones against SR-RSV-induced tumor cells were capable of releasing cytotoxic mediators by coculturing with syngeneic or H-2-compatible tumor cells, and the cytotoxic mediators showed a certain H-2-restricted manner in killing the target cells. These results suggest that the lysis of RSV-induced tumor cells by H-2-restricted CTL can at least in part be mediated by cytotoxic factors.     

Effects of sodium periodate modification of lymphocytes on the sensitization and lytic phases of T cell-mediated lympholysis.

Sensitization of mouse splenic lymphocytes in vitro with sodium borohydride, suggesting that the biologic effects of sodium periodate are-treated autologous spleen cells stimulated a one-way mixed lymphocyte reaction and led to the generation of thymus-derived cytotoxic effector cells. These effectors were capable of lysing in 4 hr periodate-treated syngeneic and, to a lesser extent, periodate-treated allogeneic target cells. These results suggest that sensitization by periodate-treated autologous cells could result either from a specific reaction to modified self components or from a nonspecific mitogenic stimulation. Effector cells generated by allogeneic sensitization were detected on periodate-modified targets, irrespective of the H-2 antigens expressed by the targets. The effects of periodate modification on both stimulator and target cells were reversible by sodium periodate are dependent on the formation of a free aldehyde group on cell surface glycoproteins. Pretreatment of stimulator cells with neuroaminidase prevented the effect of periodate treatment, suggesting that the sensitization involves oxidized sialic acid residues. During the 4-hour 51Cr-release assay periodate-treated targets could be used to detect cytotoxic effector cells of any specificity. Fresh spleen cells and lymphocytes cultured for 5 days without antigen or in the presence of lipopolysaccharide did not lyse periodate-treated targets. An increasing level of cytotoxicity was detected on periodate-treated targets when the effector cells were generated, respectively, by stimulation with concanavalin A, by sensitization with periodate-modified autologous cells. Although the lysis of periodate-treated targets is itself nonspecific, effector cell specificity could be determined by selective blocking of the lytic phase with cells syngeneic to the stimulators. These results indicate that a nonspecific interaction can occur between lymphocytes and periodate-treated target cells, but that this interaction leads to lysis only when the lymphocytes were activated to become cytotoxic effectors.     

Retrovirus D/New England and its relation to Mason-Pfizer monkey virus.

We have generated lymphocytic choriomeningitis virus-specific, H-2-restricted cytotoxic thymus-derived lymphocyte (CTL) clones. By using these reagents in several in vitro assays with infected target cells, we show that CTLs by themselves prevent the release of infectious virus into culture fluids and significantly lower the titers of infectious virus previously produced. This ability of cloned CTLs is not influenced by monensin. However, monensin does abrogate the ability of CTLs from spleens of mice primed 6 to 8 days previously with virus to kill virus-infected syngeneic targets. When tested for the participation of lymphokines in this system, the CTLs proliferate when reacted with syngeneic lymphocytic choriomeningitis virus-infected macrophages but fail to make interleukin-2. These CTLs make gamma interferon when reacted with syngeneic virus-infected targets. However, the production of interferon does not directly correlate with CTL-mediated killing. The number of H-2K and D molecules expressed on the target cell surface is not altered during the course of lymphocytic choriomeningitis virus infection. Electron microscopy shows finger-like projections of the CTL clone thrust into the infected cell and lesions bearing an internal diameter of approximately 15 nm in those membranes, illustrating the lytic process.     

Hierarchy of cytotoxic T cell clones. I. Reversal of resistance to lysis and killing between anti-hapten cytotoxic T cells

Cells from clones of anti-hapten cytotoxic T lymphocytes (CTL) can act as both effector cells and, when treated with the specific hapten, as target cells. Individual clones can kill haptenated cells only from other clones that are less efficient killers. Clones specific for both fluorescein and trinitrophenol could be ordered in a single hierarchy in which resistance to lysis correlated with lytic efficiency. When the killing efficiency was reduced with phorbol myristate acetate (PMA) or the colchicine analogue, Colcemid, the degree of resistance to lysis was also reduced. The use of PMA-treated fluoresceinated targets greatly enhanced intraclonal killing and similarly lead to a repositioning of clones within the hierarchy of normal cells. By the haptenation of appropriate clones, efficient CTL could kill cells from other clones in a direction apparently opposite to recognition. The results demonstrate that effects other than antigen recognition of the target cell may result in variations in the nature of T cell immune responses.     

Induction of anomalous killing activity from antigen-specific CTL clones by adding high doses of human recombinant interleukin 2

Four out of six long-term murine cytotoxic T lymphocyte (CTL) clones specific for trinitrophenyl (TNP)-modified spleen cells could develop an anomalous cytotoxicity against syngeneic and allogeneic tumor cells upon stimulation with TNP-modified spleen cells and high doses of human recombinant interleukin 2 (rIL-2). On FACS analysis, hyperactivated CTLs were positive for Thy-1, Ly 2 and LFA-1, but negative for L3T4 and asialo GM1. The staining profile of the cells with each antibody indicated that the CTL clones consisted of just one cell type. Monoclonal anti-Ly 2.2 and anti-LAA (lymphokine-activated cell-associated antigen) antibodies inhibited cytolysis of CTL and hyperactivated CTL clones against TNP-modified spleen cells, but failed to inhibit the anomalous killing of the hyperactivated CTL. The cold target competition test suggested the degeneracy of antigen specificity. The present study demonstrated that the CTL clone acquired a new specificity for tumor target cells upon stimulation with a high dose of rIL-2.     

Hierarchy of cytotoxic T cell clones. II. Intraclonal triggering of lysis by hapten-specific CTL

Cells from clones of anti-hapten murine cytotoxic T lymphocytes (CTL) can act as both target and effector cells, but will not lyse members of the same clone. The effect of haptenation on the cytolytic activity of anti-fluorescein (FL) and anti-trinitrophenol (TNP) CTL clones was examined. Treatment of anti-FL clones with fluorescein isothiocyanate or anti-TNP clones with trinitrobenzene sulphonic acid induces these clones to kill in an antigen-independent fashion. Targets killed by the haptenated CTL included syngeneic and allogeneic B lymphocyte blast cells, P815, YAC-1 and in one case human GM 4072 tumor cells. The importance of CD8 and T cell receptor (TCR) occupancy is demonstrated by the ability to block autotriggering by antibody directed against Ly 2 and the TCR. The results demonstrate that effects other than antigen recognition of the target play a role in the final outcome of effector-target cell interactions and provide a mechanism which could lead to autodestruction and immunosuppression particularly in some types of viral infection.     

In vivo activation of autoreactive cytotoxic T lymphocytes after bone marrow transplantation: evidence for the prethymic specificity of T cells?

The light density fraction (A + B, i.e., remaining above the 26% concentration in the discontinuous BSA gradient) of BCF1 (H-2b X H-2k) mouse bone marrow contains cells that after injection into irradiated syngeneic recipients give rise to autoreactive Lyt-2+, Thy-1+ CTL. After injection of unfractionated bone marrow cells, the levels of these CTL were low or undetectable, suggesting that either the precursors were highly enriched in the A + B fraction or that bone marrow cells with higher density have a suppressive function. The specificity of the killing was not directed toward all the available class I MHC antigens: only targets carrying H-2Kb-coded determinants were killed. There was no overlapping between the autoreactive and alloreactive precursors: cells from the A + B fraction could not respond to an alloantigen in vitro, not even in the presence of an interleukin 2-containing supernatant, and the autoreactive CTL activated in vivo could not kill allogeneic targets. The induction of the autoreactive CTL did not require the presence of the appropriate MHC antigen in the maturation environment, thus differing from the activation of mature T cells. The observed CTL specificity, together with the previous findings showing that prethymic T cells are locating in the same BSA fraction as the precursors for these autoreactive cells, support the idea that the prethymic T cell repertoire is, at least partially, directed to recognize self-MHC antigens.     

Regulation of the hapten-specific T cell response. I. Preferential induction of hyporesponsiveness to the D-end of the major histocompatibility complex in the hapten-specific cytotoxic T cell response

In this paper we have examined the phenomenon of hapten-specific tolerance in the cytolytic T lymphocyte (CTL), using the trinitrophenyl (TNP) and azobenzenearsonate haptens. We found that the H-2 K and H-2 D-end restricted CTL in H-2a mice are differentiable in the ease with which they are tolerized to the TNP hapten. With TNP modified syngeneic spleen cells (TNP-SC), or low amounts of trinitrobenzylsulfonic acid as tolerogen, preferential hyporesponsiveness of D-end restricted CTL can be observed. Larger doses of hapten, e.g. a higher amount of trinitrobenzylsulfonic acid, will tolerize both K- and D-end restricted TNP-specific CTL in H-2a mice. The phenomenon of preferential D-end restricted CTL hyporesponsiveness is not observed in H-2d, H-2k, or H-2b mice, nor is it observed in H-2a mice with respect to the azobenzenearsonate hapten. We have also shown that the clones of CTL responsible for lysis of TNP-modified allogeneic targets (cross-reactive lysis) in H-2a mice probably overlap with the D-end restricted TNP-specific CTL since D-end restricted hyporesponsiveness induced by intravenous injection of TNP spleen cells also results in the elimination of cross-reactive lysis of TNP-modified allogeneic targets. The possible mechanisms of preferential D-end hyporesponsiveness to the TNP hapten in the H-2a mice as well as its significance and relationship to previous work in this area are discussed in this paper.     

Veto cell H-2 antigens: veto cell activity is restricted by determinants encoded by K, D, and I MHC regions

Responder cells from primary syngeneic and allogeneic one-way mixed-lymphocyte cultures (MLC) specifically inhibit the development of cytotoxic T lymphocytes (CTL) directed against the major histocompatibility complex (MHC) antigens of the MLC responder cells. This special kind of suppressor activity is known as veto suppression. Ia+ cells with veto activity obtained from H-2 recombinant mouse strains were shown to downregulate alloantigen (class II)-specific helper activity for class I-specific CTL development in a primary MLC provided that the veto cells expressed the same I-E alpha subregion as the MLC stimulator cells. The veto-induced suppression of allo-help was prevented by the addition of supernatant from concanavalin A-stimulated spleen cells (Con A-SN) and was inhibited considerably by very high amounts of recombinant interleukin-2 (IL-2). In the presence of Con A-SN, CTL precursors recognizing either the K end or the D end of the veto cell MHC were found to be inactivated. Thus, our results indicate that MLC responder cells include active veto cells expressing Ia region-encoded restriction elements for allospecific T helper cells, as well as K- or D-encoded restriction elements for allospecific T cytotoxic cells.     

Loss of specificity in cytolytic T lymphocyte clones obtained by limit dilution culture of Ly-2+ T cells

Nonspecific cytotoxicity developed reproducibly and with high frequency in limit dilution cultures consisting of low numbers of murine cells stimulated with concanavalin A in the presence of growth factors and irradiated filler cells. The individual clones in cultures showing nonspecific killing were all derived from single, Thy-1+, Ly-2+ cells. At early times of culture (day 5 or 6), clones appeared to be specific in their lytic activity, as expected of cytolytic T lymphocytes (CTL). On continued culture (day 8 or 9), most of the originally specific CTL clones became nonspecific, killing a range of murine target cells, both syngeneic and allogeneic. The lack of specificity was observed at all effector cell doses. The effector cells responsible for the nonspecific cytolysis were Thy-1+ and Ly-2+, as were most cells in the cultures. The effector cells had the normal DNA content for a dividing T cell population, and most cells in the cultures had a normal chromosome complement. In mixed cultures in which the responder cells and the irradiated filler cells were from different mouse strains, the nonspecific killers displayed the Thy-1 and H-2 allotypes of the responder, and not of the filler cells. The development of a broad cytotoxic potential appears to be a normal and rapid event when Ly-2+ T cell-derived CTL-clones are grown under these conditions; this is a caveat for the use of limit dilution cultures to determine the T cell specificity repertoire. The relationship between these nonspecific CTL, activated lymphocyte killers, and natural killer cells is discussed.     

Cloned "anomalous" killer cells derived from allogeneic mixed leukocyte culture

In addition to allospecific cytotoxic lymphocytes, cytolytic effector cells capable of killing a broad range of targets are generated during mixed leukocyte culture (MLC). These cells, which have been previously called anomalous killer cells, are a distinct functional subset separate from natural killer cells or allospecific cytotoxic lymphocytes but display many characteristics of lymphokine-activated killers. In order to isolate anomalous killer cells for detailed analysis, we generated the cytolytic effectors from an allogeneic MLC using heat-inactivated stimulators. This treatment of the stimulator population abrogated the generation of classical allospecific cytotoxic lymphocytes but allowed the generation of anomalous killer cells which were subsequently cloned via limiting dilution. The clones derived by this method displayed the functional properties of anomalous killers seen in bulk MLCs. The clones demonstrated potent cytolytic activity against both NK-sensitive and NK-resistant tumor targets in vitro and also suppressed tumor growth in vivo. Ultrastructural studies revealed features similar to those of cloned antigen-specific cytolytic cells and clones with NK-like function. The cells expressed surface glycoproteins associated with both NK and T lymphocytes including Thy-1, Ly-2, T200, Qa-5, asialo GM1, and the antigens defined by the NK alloantisera NK-2.1 and NK-3.1. These cells may play an important role during early phases of the immune response, since cytolytic cells of broad specificity may protect the host until classical cytotoxic lymphocytes with restricted specificity are generated.