Coexpression of the human HLA-A2 or HLA-B7 heavy chain gene and human beta 2-microglobulin gene in L cells

L cells expressing human HLA-A2 or HLA-B7 class I antigen heavy chains are not recognized by human cytotoxic T lymphocytes directed at HLA-A2 or HLA-B7 antigens. To test whether the absence of human beta 2-m was the cause of the lack of recognition by the human cytotoxic T lymphocytes, coexpression of the human beta 2-m gene and the HLA-A2 or HLA-B7 heavy chain in L cells ("double transfectants") was obtained. In addition, L cells expressing HLA-A2 or HLA-B7 antigens in association with human beta 2-m were obtained by an exchange reaction, in which human beta 2-m from serum replaced the endogenous murine beta 2-m. Both types of transfectant cells were used in 51Cr-release assays and cold target inhibition assays for human cytotoxic T cell clones which were directed at HLA-A2 or HLA-B7. Neither human CTL clones nor a mixture of CTL specific for HLA-A2 and HLA-B7 were able to recognize these cells. Several alternative explanations for these observations are discussed.     

Lymphocyte responses to syngeneic antigens. I. Enhancement of the murine autologous mixed lymphocyte response by polyethylene glycol

The normally weak murine T-cell proliferative response against autologous non-T stimulator cells (the autologous mixed lymphocyte culture (MLC) was enhanced markedly by inclusion of the hydrophilic polymer, polyethylene glycol (PEG), into the culture medium. Potentiation of the autologous MLC was indicated on the basis of increased [³H]TdR incorporation by responding cells, as well as by the numbers of viable cells recovered from mixed cell cultures. PEG is not a polyclonal activator of T and/or B lymphocytes, since nylon wool nonadherent lymphoid cells (T cell-enriched fraction), nylon wool adherent cells (B cell-enriched fraction) and T cell-deficient “nude” spleen cells were not stimulated into DNA synthesis when cultured separately with PEG. Inclusion of 4% PEG into the culture medium was found to optimally enhance autologous MLC, although concentrations between 2 and 5% also significantly elevated responsiveness. At a responder/stimulator ratio of 1:2, autologous MLC yielded peak [³H]TdR incorporation after 5 days of culture. At lower ratios (1:1 and 2:1), however, Δ cpm of autologous MLC continued to increase over a culture period of 7 days. Enhanced responsiveness in the presence of PEG was observed in strains of mice representing a variety of H-2 haplotypes, indicating that at least the potential for autoreactivity of this type is a naturally occurring and widespread characteristic of murine species. An absolute requirement for purified T responder cells was necessary in the autologous MLC, since unseparated lymphoid cell responder LN or spleen cells demonstrated marked proliferation when cultured alone in medium containing PEG. The proliferation of T cells to autologous non-T cells within the same unseparated lymphoid cell preparation appears to be responsible for this phenomenon. Ia antigens expressed by the stimulator cells are involved in the induction of T-cell response, since anti-Ia sera added directly to the cultures inhibited the autologous MLC, but did not affect other T-cell responses to alloantigens or mitogens. Despite the marked proliferation observed in the autologous MLC performed in the presence of PEG, there was no generation of cytotoxic effector cells. Thus, PEG does not appear to add, or alter determinants on stimulator cells to an extent that they are recognized as foreign by precursor cytotoxic T cells. Although the mechanism of enhancement of autologous MLC by PEG is not totally defined, it appears, at least functionally, to promote cellular interactions that occur normally between T cells, B cells, and macrophages. In this respect, PEG will be a powerful and useful probe to dissect the cellular interactions that take place in autologous responses.     

Functional significance of the Fc receptor on mixed lymphocyte culture-activated T blasts.

Fc receptor (FcR)-carrying blast cells were separated from nonFcR blast cells after priming in primary mixed lymphocyte culture (MLC) by erythrocyte-antibody rosetting and by 1-g velocity sedimentation. Both types of blast cells were cytotoxic to relevant allogeneic target cells in vitro. The FcR-positive and FcR-negative blasts were then plated on a feeder layer syngeneic to the primary MLC responder cells. After feeder layer culture both types of cells reverted into secondary small lymphocytes. When restimulated with the original stimulator cells, both types of secondary lymphocytes produced the relevant secondary cell-mediated lysis responses. Thus no functionally dissimilar subclasses of secondary T lymphocytes can be distinguished in the MLC-stimulated T-cell population on the basis of the FcR.     

Cytotoxicity of human peripheral lymphocytes in cell-mediated lympholysis; antibody-dependent cell-mediated lympholysis and natural cytotoxicity assays after mixed lymphocyte culture.

Lymphocytes that have been purified by Ficoll-Hypaque centrifugation lose antibody-dependent and natural cytotoxic activities upon culture in tissue culture medium supplemented with human plasma. However, stimulation of peripheral lymphocytes in the mixed leukocyte culture (MLC) appears to enhance killer (K) and natural killer (NK) activities in addition to generating cytotoxic T ymphocytes. Enhancement of NK and antibody dependent activities appears to correlate with cell division as measured by 3H-thymidine uptake. However, elimination of dividing cells in the MLC by addition of 5-bromodeoxyuridine has no effect on NK and K cells activities. Since this treatment abolishes cell-mediated lympholysis mediated by cytotoxic T lymphocytes, it is a useful probe for determining the relative activities of NK, K, and cytotoxic T lymphocyte effector cells after lymphocyte stimulation.     

Lipopolysaccharide-induced immunomodulation of the generation of cell-mediated cytotoxicity. I. Suppression of the development of cytotoxic lymphocytes

Bacterial lipopolysaccharide from a variety of Gram-negative organisms suppresses the development of cytotoxic killer cells in the murine MLC. Cytotoxic T lymphocytes were generated in vitro by incubating BALB/c responder spleen cells with irradiated C57BL/6 stimulator cells for 5 days in mixed lymphocyte culture (MLC). The addition of LPS at the initiation of MLC suppressed killing of 51Cr-labeled target cells in a dose-dependent manner. LPS was active only during the afferent phase of CMC, since it did not interfere with the efferent phase of the assay. Furthermore, timed addition and timed removal studies suggested that the presence of LPS during the first 48 hr of MLC was critical for maximal suppression of CMC. Lipid A extracted from LPS, which had been shown to be highly suppressive when added to the sensitization phase of the CMC assay, was also inhibitory. Moreover, when LPS was added to MLC in the presence of tritiated thymidine, the proliferative activity of the responder cells increased markedly after 72 hr of culture. These data suggest that LPS, a known B cell mitogen, can modulate the complex sequence of cellular interactions that leads to the generation of cell-mediated cytotoxicity.     

Differential effect of anti-beta 2-microglobulin on IL 2 production and IL 2 receptor expression in the primary mixed lymphocyte culture reaction

The mechanism of inhibition of the proliferative response in primary mixed lymphocyte culture (1 degree MLC) by antibodies to beta 2-microglobulin (beta 2m) was investigated. It is demonstrated that anti-beta 2m antibodies inhibit the production of interleukin 2 (IL 2). In contrast, the expression of IL 2 receptor is not affected by anti-beta 2m. The addition of purified exogenous IL 2 to the antibody-treated 1 degree MLC can completely restore the proliferative response, indicating that anti-beta 2m does not interfere with IL 2 binding to its receptor. Similarly, anti-beta 2m does not interfere with the capacity of IL 2-dependent T cell lines or T cell clones to respond to exogenous IL 2. The inhibition of cell proliferation and IL 2 production by anti-beta 2m is maximal when the antibody is added at the beginning of 1 degree MLC culture, and no effect of anti-beta 2m is seen when added after 3 days of culture. Anti-beta 2m has no effect on mitogen-induced cell proliferation and IL 2 production. Anti-beta 2m acts on the responder cell population, as demonstrated in experiments in which responder cells or stimulator cells are treated separately with the antibody. The expression of HLA-class II antigens (i.e., HLA-DR and DQ (DC) on the T cells activated on 1 degree MLC is not affected by anti-beta 2m. These studies indicate that the HLA-beta 2m class I antigen complex plays a role in T lymphocyte activation via release of IL 2, and suggest the existence of different mechanisms for activation of IL 2 producers and IL 2 responders in 1 degree MLC.     

A permanent human cytotoxic T-cell line with high killing capacity against a lymphoblastoid B-cell line shows preference for HLA A,B target antigens and lacks spontaneous cytotoxic activity

The optimal conditions for the generation of highly cytotoxic human T lymphocytes (CTL) in vitro against a lymphoblastoid B-cell line (JY) in primary and secondary mixed lymphocyte cultures (MLC) were investigated. Variation of the stimulator:responder (S:R) cell ratio influenced both the specific cytotoxicity and the spontaneous cytotoxicity as well as the recovery of the responder cells. T lymphocytes of donor JR (HLA A23,29; B7,7; DRw5) were stimulated with JY (HLA A2,2; B7,7; DRw4,6) in primary and secondary MLC at S:R ratios of 1:50 and 1:10, respectively, since stimulations at these S:R ratios resulted in the highest specific cytotoxicity against JY, the lowest spontaneous cytotoxicity against K562 and Daudi, and in a good recovery of the responder cells. From these T-lymphocyte cultures an exponentially growing CTL line (JR-2) was obtained by weekly stimulations with irradiated JY cells at a S:R ratio of 1:1. After 2 months of culturing the growth rate of the JR-2 cells declined, but could be restored by the addition of conditioned medium, containing T-cell growth factor (TCGF). Irradiated JY cells or TCGF alone were insufficient to maintain proliferation. JR-2 cells were strongly cytotoxic for JY (50% lysis was obtained at an effector:target ratio of 1:2) but the cytotoxic activity against a classical target cell for spontaneous cytotoxicity (K562) was negligible. The cytotoxic activity of JR-2 cells against JY could be inhibited by a monoclonal antiserum W6/32, which recognizes all HLA A, B, and C specificities, and by a monoclonal antiserum directed against β2 microglobulin, whereas monoclonal anti-Ia antisera showed no inhibition. JR-2 cells lysed fresh HLA A2-homozygous lymphocytes more efficiently than HLA A2-heterozygous lymphocytes, whereas the latter were better killed than HLA A2-negative lymphocytes.     

Expression of murine interleukin-2 cDNA in E. coli and biological activities of recombinant murine interleukin-2

Murine interleukin-2 (MIL-2) cDNA was inserted into an expression vector carrying an Escherichia coli tryptophan promoter and was expressed in E. coli. Recombinant MIL-2 produced by E. coli supported the growth of murine CTLL-2 cells, but not that of human T-cell blasts. Recombinant MIL-2 strongly inhibited the binding of recombinant human IL-2 (HIL-2) to murine responder cells, but only very weakly inhibited the binding to human responder cells. Moreover, recombinant MIL-2 induced secondary alloantigen specific cytotoxic T lymphocytes (2 degrees CTL) from memory CTL and activated natural killer (NK) cells in murine systems in the same manner as recombinant HIL-2. The results suggest that the species hierarchy (that MIL-2 derived from native cell culture does not act on human T-cells) is due to the protein moiety, not the sugar moiety, and is to be ascribed to the difference in binding affinity of MIL-2 and HIL-2 to murine and human responder cells respectively, and that recombinant MIL-2 shares identical biological and immunological activities with recombinant HIL-2. Thus, MIL-2 might be a convenient tool for extensive studies of the pharmacological and physiological activities of IL-2 in murine models.     

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.     

Suppressor cell induction factor: a new mediator released by stimulated human lymphocytes and distinct from previously described lymphokines

Suppressor cell induction factor (SIF) was produced by alloantigen-stimulated human peripheral blood lymphocytes, and it activated human T cells to become effective suppressors of the mixed lymphocyte reaction (MLR). The activity of SIF was resistant to 56 degrees C and to pH 2, and was precipitated by 50 to 80% saturated ammonium sulfate. SIF had a m.w. range, as determined by gel filtration, of 18,000 to 29,000; it did not bind to DEAE cellulose columns; and it was recovered in the pH range from 6.9 to 7.3 on isoelectric focusing. SIF was biochemically separable from IL 2, BF, IFN-gamma, and CSF. Furthermore, IL 2 activity was completely removed by absorption of MLC supernatants by murine cytotoxic T lymphocyte line (CTLL) cells, whereas SIF activity was unabsorbable, thus distinguishing SIF from IL 2. In addition, antiviral activity of MLC supernatants was completely abolished by anti-human IFN-gamma serum, whereas SIF activity was unaffected by this antiserum, thus distinguishing SIF from IFN-gamma. Since treatment of these supernatants with antiserum against human lymphoblastoid cell IFN(alpha/beta) had no effect on either antiviral or SIF activities in these supernatants, SIF was also distinguishable from IFN alpha/beta. These results indicate that SIF is a distinct new lymphokine with the ability to induce suppressor function in human T cells.     

H-2K/H-2D and Mls and I region-associated antigens stimulate helper factor(s) involved in the generation of cytotoxic T lymphocytes

This study examines the antigen that stimulate production or release of a soluble helper factor(s) involved in development of cytotoxic T lymphocytes (CTL). Antigens associated with the Mls locus, I and K/D regions of the MHC were all capable of stimulating responder cells in MLC to produce helper factor. These supernatant fluids were all capable of providing "help" for the generation of cytotoxic T lymphocytes in MLC in which spleen cells are stimulated by allogeneic heat-treated thymocytes or splenocytes. Previous reports from our laboratory as well as others have shown that heat-treated cells do not stimulate a cytotoxic response. Heat-treatment of Mls, I, and H-2K/H-2D region incompatible stimulatory cells in MLC eliminated their ability to induce responder cells to produce helper factor, suggesting this is the mechanism whereby heat-treatment reduces the ability of cells to stimulate cell-mediated lympholysis (CML). The inability of supernatant fluids, from MLCs in which heat-treated cells were the stimulators, to assist in the generation of cytotoxic T cells did not appear to be the result of any suppressive factor induced by such treatment. Further, the antigens that stimulate pre-killer cells appear functionally distinct from those heat labile antigens (Mls, I, H-2K/H-2D associated) that stimulate helper factor production since heat-treated allogeneic cells served as stimulators of cytotoxicity provided helper activity was added to the MLC.     

Suppression of in vitro CML generation by alloactivated lymphocytes: analysis of antigen-nonspecific suppressive mechanisms

We have investigated the in vitro phenomena associated with antigen-nonspecific suppression of mixed lymphocyte culture (MLC) responses by allocativated lymphocytes. Using an experimental system that we described in a previous communication, we observed that a) the degree of suppressive activity generated by allocativation correlates directly with the intensity of proliferation observed during induction of suppressive activity, b) suppressive activity segregates exclusively with proliferating (lymphoblast) subpopulations of alloactivated lymphocytes, c) when suppressive cells are included in MLC, subsequent [3H]thymidine incorporation is enhanced and accelerated, rather than impaired, and d) a considerable proportion of the cells recovered from suppressed MLC appear to be the progeny of the suppressive population, and not the progeny of the MLC responder population. These data suggest that antigen-nonspecific suppression mediated by alloactivated lymphocytes has two related components: 1) cytokine preemption by suppressive (alloactivated) lymphocytes, and 2) MLC responder cell dilution by the progeny of suppressive lymphocytes. These data are consistent with the hypothesis that the antigen-nonspecific suppressive activity of alloactivated lymphocytes can reflect the coincidental ability of activated T cells to recognize and respond to mitogenic lymphokines in vitro. The data further explain why antigen-nonspecific suppression is difficult to reverse by addition of exogenous lymphokines to suppressed MLC.     

Analysis of the HLA-Cw3-specific cytotoxic T lymphocyte response of HLA-B7 X human beta 2m double transgenic mice

The cytolytic responses of either normal (non transgenic), HLA-B7 (single transgenic) or HLA-B7 x human beta 2 microglobulin (double transgenic) DBA/2 mice induced by transfected HLA-Cw3 P815 (H-2d) mouse mastocytoma cells were compared, to evaluate whether the expression of an HLA class I molecule in responder mice would favor the emergence of HLA-specific, H-2-unrestricted CTL. Only 8 of 300 HLA-Cw3-specific CTL clones tested could selectively lyse HLA-Cw3-transfected cells in an H-2-unrestricted manner, all having been isolated after hyperimmunization of double transgenic mice. These clones also lysed HLA-Cw3+ human cells. Unexpectedly, the lysis of the human but not that of the murine HLA-Cw3 cells was inhibited by Ly-2,3-specific mAb. Despite significant expression of HLA-B7 class I molecules on transgenic lymphoid cells, including thymic cells, limiting dilution analysis and comparative study of TCR-alpha and -beta gene rearrangements of the eight isolated clones (which suggested that they all derived from the same CTL precursor) indicated that the frequency of HLA-Cw3-specific H-2 unrestricted cytotoxic T lymphocytes remained low (even in HLA-B7 x human beta 2-microglobulin double transgenic mice). This suggests that coexpression of HLA class I H and L chain in transgenic mice is not the only requirement for significant positive selection of HLA class I-restricted cytotoxic mouse T lymphocytes.     

Tumour-reactive lymphocytes stimulated in mixed lymphocyte and tumour culture

Summary Lymphocytes from cancer patients were stimulated in mixed culture with autologous tumour (MLTC) or pooled allogeneic lymphocytes (MLC). Both protocols induced increased uptake of ³H-thymidine at 5 days and the appearance of lymphoblasts. Blasts were isolated on discontinuous Percoll gradients and either expanded as bulk cultures or cloned directly under limiting dilution conditions in the presence of conditioned medium containing IL-2. Results with MLTC-blast-CTC have been reported elsewhere. MLC-activated cultures lysed autologous tumour but not autologous lymphoblasts. Lysis of some allogeneic tumours, lymphoblasts from members of the inducing pool, and K562 was also apparent. MLC activated cultures did not undergo restimulation in response to autologous tumour or lymphocytes but were restimulated by leukocytes from pool members.MLTC clones showed autologous tumour-specific cytotoxic activity or cross-reactive proliferative responses with tumours of the same site and histology. The majority of MLC clones cytotoxic for autologous tumour were also specific and did not lyse allogeneic tumour, K562, or lymphoblasts from the inducing pool. Two clones lysed autologous tumour and pool members. None of the clones tested proliferated in response to autologous tumour following MLC activation but some were responsive to pool members and one clone was restimulated by autologous monocytes. No association was found between clone phenotype and function. The implication of these data is that the effector cells with activity against autologous tumour induced in MLC arose largely by transstimulation of in vivo-activated tumour reactive lymphocytes by IL-2 release rather than expansion of NK-like effectors or sharing of antigenic specificities between tumour and allogeneic lymphocytes. Since MLC activation of cancer patients lymphocytes does not induce proliferative responses to autologous tumour it is unlikely to be a useful procedure in preparing cells for immunotherapy protocols. Abbreviations used in this paper: PBL, peripheral blood lymphocytes; TIL, tumour infiltrating lymphocytes; MLTC, mixed lymphocyte tumour culture; IL-2, interleukin-2; MLC, mixed lymphocyte culture; LSM, lymphocyte separation medium; BSS, balanced salt solution; HuSe, human serum; PBS, phosphate-buffered saline; CTC, cultured T cells; PHA, phytohaemagglutinin; CM, cultured medium; NK, natural killer; FcR, receptor for the Fc portion of IgG     

Regulation of the cytotoxic activity of alloreactive cytotoxic T lymphocytes by helper cells and lymphokines

The cytotoxic activity of alloreactive cytotoxic T lymphocytes (CTL) was maintained and augmented by transferring cells from a 5-day mixed lymphocyte culture MLC into a host culture (HC) containing indomethacin, freshly explanted normal spleen cells, and peritoneal cells which were syngeneic to the MLC cells. The MLC cells used in the transfer experiments were generated by culturing untreated H-2b splenic responders with irradiated H-2d stimulators, or were generated by culturing Lyt-2-depleted H-2b splenic responders with irradiated H-2d stimulators. The allo-CTL were found to be derived from the donor MLC (first culture) when unfractionated MLC cells were transferred into a host (second) culture and incubated for 5 days. In contrast, the allo-CTL were derived from host culture cells when Lyt-2-depleted MLC cells were transferred and the combined cultures incubated for 5 days. In the former case, the augmentation of MLC-derived cytotoxicity did not result from nonspecific expansion of all donor T cells; instead it was mediated by lymphokine(s), distinct from IL-2, produced by helper T cells generated in host culture, which appeared to selectively expand the antigen-specific CTL or to increase the cytotoxic activity of these CTL. The helper T cells were Thy-1+, L3T4+, and Lyt-2-. These findings indicate that antigen-nonspecific help was provided by helper cells or helper factors (lymphokines) generated in the host culture, which maintained and augmented the cytotoxic activity of the fully generated allo-CTL. This helper effect was also seen in the induction of primary allo-CTL responses which could be generated with fewer stimulating cells and with a stronger cytotoxic response at different R/S ratios tested. The generation of allo-CTL in second culture following transfer of Lyt-2-depleted MLC cells to host cultures appears to have involved antigen carryover from the MLC; however, antigen carryover alone was not sufficient. It appears that in the absence of Lyt-2+ suppressor T cells, antigen-specific help might be generated in donor cultures (Lyt-2-depleted MLC) which promoted or recruited the generation of antigen-specific CTL in host culture.     

Studies on non-H-2-linked lymphocyte-activating determinants. IV. Ontogeny of the Mls product on murine B cells.

The minor lymphocyte stimulating (Mls) locus codes for lymphocyte activating determinants (LADs) on murine B lymphocytes, but not T lymphocytes. This observation was strengthened by a series of techniques which allow deletion and addition of T and B cells. These included the use of cytotoxic antisera such as anti-Thy 1.2, anti-MTLA, anti-MBLA, and complement, and the use of a goat anti-μ antisera, and finally the use of a fluorescence activated cell sorter (FACS).The studies in this report document the organ distribution and the ontogenetic appearance of the surface LADs on the surface of B lymphocytes from DBA/2N (H-2^d, Mls^a) and CBA/J (H-2^k, Mls^d) mice. Adult-like ability to stimulate H-2 identical BALB/c (H-2^d, Mls^b) and C3H/He (H-2^k, Mls^c) responder cells appeared at about 4–5 weeks of age. Inability of neonatal cells to induce an Mls-defined MLC was found not to be due to a low frequency of B lymphocytes or to the presence of suppressor cells, but due to the absence of the Mls-coded LADs on their surface. These data support the concept that the Mls-coded LADs are present on adult B lymphocytes and are specific markers of B-cell differentiation, which is preceded by membrane IgM and the δ homologue of human IgD, Ia, and the receptor for the third component of complement.     

Induction and characterization of minor histocompatibility antigens. Specific primary cytotoxic T lymphocyte responses in vitro

A definite cytotoxic activity was developed in a BALB/c (H-2d) anti-DBA/2 primary mixed leukocyte culture (MLC), which received interleukin 2 (IL-2) on day 3 of culture. This cytotoxic activity was minor histocompatibility antigens (MIHA)-specific at the stimulator level, and was not developed in a syngeneic (BALB/c anti-BALB/c) MLC. The addition of IL-2 on day 3 of culture was crucial; no or very weak cytotoxic activity was developed in MLC receiving IL-2 on day 0 or on both day 0 and day 3. Only appropriate MIHA-allogeneic tumor cells were lysed as the target of the cytotoxic activity. The cytotoxic activity seemed MIHA-specific also at the target level; it lysed tumor cells of DBA/2 mouse origin but not those of BALB/c (syngeneic) origin. Phenotypes of the cytotoxic effector cell were Thy-1+ Lyt-2+. We concluded from these results that MIHA-specific cytotoxic T lymphocytes (CTL) were generated in the MIHA-allogeneic primary MLC. In this newly developed system, we studied genetic and antigenic requirements for primary anti-MIHA CTL responses in vitro. We demonstrated; among spleen cells (SC) of seven B10 H-2-congenic strains only SC of B10.D2 strain whose major histocompatibility complex (MHC) (H-2d) was compatible with the responder MHC effectively stimulated responder BALB/c (H-2d) SC for an anti-MIHA (DBA-C57BL-common) CTL response. Similarly, only SC of two out of seven C x B recombinant inbred strains (C x B.H and C x B.D), which were compatible at the MHC with responder SC, activated responder BALB/c SC for the response. The possibility that cells responding to H-2 alloantigens suppressed the anti-MIHA response was ruled out. Additional experiments showed that compatibility at the H-2K-end or the H-2D-end of the MHC was sufficient for a definite anti-MIHA response. These provided formal evidence that primary anti-MIHA CTL responses in vitro were MHC-restricted at the stimulator level. We then showed that sonication-disrupted SC or Sephadex G-10 column-passed nonadherent SC failed to stimulate responder SC for a primary anti-MIHA CTL response, whereas G-10-passed nonadherent SC responded well to adherent stimulator cells. Further study demonstrated that Ia+ adherent cells were the most active cell type as stimulator. Finally, we confirmed that the primary anti-MIHA CTL responses to adherent stimulator cells was MHC-restricted.     

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.     

Cytotoxic lymphocytes induced by soluble factors derived from the medium of leukocyte cultures.

Studies were undertaken to evaluate the cytotoxic capacity of human peripheral blood lymphocytes activated by either supernatants (CFM) derived from lymphocyte cultures or lymphocytes treated for 60 min at 45 degrees C. The effect of the addition of heat-treated cells on the cytotoxic activity of CFM-induced effector cells was also studied. CFM from either unmixed or mixed cultures of lymphocytes was capable of activating cytotoxic effector cells. These effector cells could kill any allogeneic target cells but failed to effect cytotoxicity on the target cells autologous to the responding cells. Both the heat-treated cells and CFM from cultures of these cells also activated lymphocytes to cytotoxic effector cells having specific receptors for nonself antigens. The question of whether heat-treated cells activate cytotoxic cells by themselves or through secreted soluble factor cannot yet be clearly answered. The findings of the present investigation suggest that expression of cytotoxicity induced in MLC is not necessarily restricted to the target cells syngeneic to the stimulator cells, but can be extended to any allogeneic target cells by the indirect effect of soluble factor secreted from stimulated cells that causes a polyclonal activation of cytotoxic precursors in the responding cell populations. The present findings also emphasize the need for caution in the use of heat-treated lymphocytes as innocent-bystander cells in MLC to provide additional cytotoxic specificities in the responder cells, since heat-treated cells alone can activate lymphocytes to cytotoxic effector cells that kill any allogeneic target cells.     

Neoplastic cells obtained from Hodgkin's disease are potent stimulators of human primary mixed lymphocyte cultures

Neoplastic cells obtained from the pleural effusion of a patient with Hodgkin's disease have been maintained in culture since 1978. These tumor cells have been shown to have the cytologic features, cytochemical staining, and cell surface markers of Reed-Sternberg cells. In this study we demonstrate that the cell line termed L428 is a potent stimulator of the primary human mixed lymphocyte reaction. Significant proliferation occurred when mononuclear leukocytes obtained from normal donors were stimulated with radiated L428 cells at responder:stimulator ratios varying from 200:1 to 20:1. Proliferative responses occurred between days 3 and 6 of the cultures with maximal proliferation on day 5. Under optimal culture conditions, mean net proliferative response of 14 normal donors was 51,000 +/- 10,600 dpm. The mixed lymphocyte response was totally blocked by concentrations of monoclonal anti-Ia antibody that had no effect on concanavalin A-induced proliferation. However, the mixed lymphocyte response was not blocked by an anti-K562 cell monoclonal antibody of the same immunoglobulin subclass that binds to the L428 cells. Antigen processing by responder monocytes or Ia-positive cells was not required for the MLC. When responder T cells from two normals were depleted of Ia-bearing cells and monocytes, the mixed lymphocyte reaction between the two normals was eliminated, yet the stimulation of each normal by the L428 cells was not reduced. The cells that proliferated in response to stimulation by the L428 cells were T cells, primarily of the helper subset. No IL 1 activity could be detected in concentrated supernatants of L428 cultures after stimulation of L428 cells by mitogens, phorbol esters, or muramyl dipeptide, or in the MLC. All of these cultures contain fetal calf serum. However, the L428 cells are capable of producing IL 1, because IL 1 was detected when the L428 cells were stimulated with LPS in the absence of fetal calf serum. These neoplastic cells, obtained from Hodgkin's disease, have many similarities to the murine as well as human dendritic cells.