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.     

Generation of cytotoxic T lymphocytes in vitro. VI. Effect of cell density on response in mixed leukocyte cultures.

Reexposure of day 14 murine mixed leukocyte culture (MLC) populations to the original irradiated allogeneic stimulating spleen cells has previously been found to result in the ratpid generation of cytolytic T lymphocytes (CTL) associated with a net increase in cultured cell number. Under the experimental conditions used, day 5 MLC cells appeared unable to respond to the allogeneic stimulus. In order to characterize further the development of the potential for anamnestic reactivity during the course of MLC, C57BL/6 spleen cells were incubated with irradiated (1000 rads) DBA/2 spleen cells (primary MLC) for up to 3 weeks. At various time intervals after the onset of the primary MLC, the surviving cells were collected and reexposed, at varying cell concentrations, to irradiated DBA/2 spleen cells (secondary MLC). At daily intervals thereafter, CTL activity was assessed using a quantitative 51Cr-release assay system. A paradoxic effect of responding cell concentration on generation of CTL activity was observed; relatively greater increase in CTL activity was observed as the concentration of responding cells was decreased over a 100-fold range. This effect was more pronounced with responding cells reexposed to antigen after primary MLC for 20 days, but was observed even with normal cells. The apparent unresponsiveness of day 5 MLC cells to alloantigen restimulation could be overcome by simple dilution of responding cells. Cytotoxic activity at the time of restimulation with antigen seems to be a major factor determining the magnitude of the secondary response. Since intact cells bearing alloantigens are required for the generation of CTL in MLC, residual cytotoxic cells reduce the effective antigenic stimulus by destroying stimulating cells. This effect of concentration of responding cells on generation of CTL in MLC complicates interpretation of experiments investigating the role of "inhibitor" and "helper" cell in cell-mediated immune responses occurring in vitro. Under optimal conditions, the highest CTL activity and the largest increase in total cell number was observed 4 days after restimulation of day 10 MLC cells. On a per cell basis, the lytic activity was up to 4 times greater than that observed at the peak of a primary response, and the number of viable cells recovered was nearly 20 times higher than that at the onset. Such secondary MLC are thus a convenient source of lymphoid cells selected primarily on the basis of proliferation induced by alloantigens.     

Generation of cytotoxic T lymphocytes in vitro. VII. Suppressive effect of irradiated MLC cells on CTL response.

Irradiated cells obtained from MLC at the peak of the CTL response caused profound suppression of generation of CTL when added in small numbers at the initiation of primary MLC prepared with normal spleen cells. The inhibitory activity of the MLC cells was not affected by irradiation (1000 rads) but was abolished by treatment with anti-theta serum and complement. The suppression was immunologically specific. The response of A (H-2a) spleen cells toward C3H (H-2k) alloantigens was suppressed by irradiated MLC cells obtained from MLC prepared with A spleen cells and irradiated C3H-stimulating cells, whereas the response of A spleen cells toward DBA/2 (H-2d) alloantigens was affected relatively little. However, if irradiated C3H X DBA/2 F1 hybrid spleen cells were used to stimulate A spleen cells in MLC, addition of irradiated MLC cells having cytotoxic activity toward C3H antigens abolished the response to both C3H and DBA/2 antigens. The response to DBA/2 antigens was much less affected when a mixture of irradiated C3H and DBA/2 spleen cells was used as stimulating cells. Thus, the presence of MLC cells having cytotoxic activity toward one alloantigen abolished the response to another non-cross reacting antigen only when both antigens were present on the same F1 hybrid-stimulating cells. This suppression of generation of CTL by irradiated MLC cells apparently involves inactivation of alloantigen-bearing stimulating cells as a result of residual cytotoxic activity of the irradiated MLC cells. This mechanism may be active during the decline in CTL activity noted in the normal immune response in vivo and in vitro.     

Immunoregulation by mouse T-cell clones. I. Suppression and amplification of cytotoxic responses by cloned H-Y-specific cytolytic T lymphocytes

H-Y-specific and H-2Db-restricted, Lyt-1-2+ T-cell clones ( CTLL ) with graded specific cytotoxic activities on male C57BL/6 (B6) target cells ( 1E3 , ; 2C5 , ++; 2A5 , +, 3E6 , +/-) were tested for their capacity to inhibit the generation of H-Y-specific cytotoxic T lymphocytes (CTL) in vitro. Addition of irradiated lymphocytes of CTLL 1E3 and CTLL 3E6 but not those of CTLL 2A5 or CTLL 2C5 abolished the generation of CTL from in vivo primed H-Y-specific precursor cells (CTLP) when added to fresh mixed-lymphocyte cultures (MLC). Exogenous sources of T-cell growth factors (TCGF) did not overcome suppression. Rather the presence of TCGF resulted in a further enhancement of suppressive activities in CTLL 1E3 and 3E6 and the induction of similar activities in cells from CTLL 2A5 and 2C5 , which by themselves were not inhibitory. Moreover when added to similar MLC on Day 1 instead of Day 0, only irradiated cells of CTLL 3E6 but not those of the other three CTLL were suppressive. Induction of suppressive activities in H-Y-specific CTLL was independent of the appropriate male stimulator cells since it was also observed in MLC induced by irrelevant antigens (H-2, trinitrophenol). Furthermore at low cell numbers, irradiated lymphocytes from any of the CTLL consistently enhanced CTL activities generated from H-Y-specific CTLP. This augmenting activity, which was not TCGF, could be transferred by soluble mediators present in antigen-sensitized CTLL cultures. Thus, these data indicate (i) that cytotoxic effector cells can function as suppressor cells in the generation of CTL, (ii) that the cytotoxic activity of cloned CTL does not correlate with their capacity to suppress CTL responses, (iii) that the inhibition of CTL responses by CTLL is not due to simple consumption of T-cell growth factors produced in MLC, and (iv) that different CTL clones may interfere with the generation of CTL at different stages of their maturation. Moreover, the experiments suggest an antigen-independent enhancement of suppression by the interaction of CTL with lymphokines. Together with the augmenting activity evoked by cloned CTL the data provide strong evidence for the expression of multiple immunological functions by one particular subset of T cells and suggest that cytotoxic effector cells can differentially regulate the maturation and/or clonal expression of their precursor cells.     

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.     

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.     

Proteolytically modified human beta 2-microglobulin augments the specific cytotoxic activity in murine mixed lymphocyte culture

A proteolytically modified form of beta 2-microglobulin (beta 2-m) present in the serum of patients suffering from autoimmune, immunodeficient diseases and cancer has been reported in the literature. In the present study we show that human beta 2-m as well as the proteolytically modified human form (M-beta 2-m) bind to murine lymphocytes expressing H-2 class I antigens; M-beta 2-m, when added at day 0 and 1 of culture in nanomolar concentrations to a one-way murine allogeneic mixed lymphocyte culture (MLC) augments the generation of specific cytotoxic T lymphocytes; M-beta 2-m increases the endogenous production of interleukin 2 in the MLC culture; monoclonal antibody which reacts with both the native beta 2-m and M-beta 2-m molecule blocks the augmentation of cytotoxic T lymphocyte production induced by M-beta 2-m; murine as well as human MLC responder cells can proteolytically modify native human beta 2-m; and the modifying activity of murine MLC responder cells was blocked in an intermediary step by an alloantibody, which reacts specifically with murine major histocompatibility complex, class I-associated beta 2-m. These findings suggest that the modification process is preceded by an association of human beta 2-m with the cell surface of the responder cells. Our data indicate that the modification of beta 2-m might reflect early events in allospecific responder cell activation.     

Proliferative and cytotoxic immune functions in aging mice. II. Decreased generation of specific suppressor cells in alloreactive cultures

The ability of spleen cells from aged C57BL/6 mice to generate specific suppressor cells in mixed lymphocyte cultures (MLC) against allogeneic H-2 antigens was investigated. The suppressor cells from young and old mice were assayed in parallel for their ability to inhibit the proliferative response and the generation of cytotoxicity in fresh MLC. Suppressor cell generation was found to be significantly decreased in 41% of aged mice (23 to 28 mo) as compared to young controls (3-8 mo). The suppressor cells were H-2-specific, radiation-resistant (1000 R), and Thy-1+; they did not function by lysing the fresh stimulators or responder cells, or by absorbing the interleukin 2 in the fresh cultures. Suppression required very small numbers of cells to be effective. It was concluded that the effect of aging was less marked on specific suppressor cell generation than on generation of cytotoxic T cells in the MLC. However, a third type of response studied, the proliferative response, was affected earliest and most severely.     

In vitro immunization. Effect of growth and differentiation factors on antigen-specific B cell activation and production of monoclonal antibodies to autologous antigens and weak immunogens

The antigen-specific activation of murine nonimmunized B lymphocytes subsequently used in hybridization experiments has been investigated by using phylogenetically conserved antigens or autologous immunogens. This in vitro immunization was supported by B cell growth and differentiation factors derived from phorbol myristate acetate-stimulated EL-4 thymoma cells and mixed lymphocyte cultures (MLC). A filter immuno-plaque assay was used to evaluate the effect of different activation procedures on the number of antigen-specific plaque-forming cells (PFC). We first determined the requirement for MLC-derived lymphokines in the in vitro immunization. An optimal number of antigen-specific PFC was obtained when using 33 to 50% of the supernatant from a 48-hr MLC to support the activation. B cell growth and differentiation factors derived from EL-4 cultures were then tested for their abilities to potentiate the number of PFC by using both unseparated spleen cells and highly purified Ig-positive B cells as target cells. The combination of lymphokines found in supernatants from 25% EL-4 thymoma culture and 33% MLC yielded the highest number of PFC when used to support an in vitro immunization. This optimal factor preparation was used to determine the kinetics (4 to 7 days) and the dose response (0.01 to 10 micrograms antigen/ml) of antigen-specific B cell activation before using the immunized splenocytes as parental cells in cell fusion experiments. Mouse albumin and hemoglobin, actin (25 micrograms/ml), RNA polymerase II (5 micrograms/ml), as well as syngeneic mouse serum were used to immunize BALB/c spleen cells in vitro. We obtained antigen-specific PFC by using all of the different immunogens, including syngeneic mouse serum, and the in vitro immunized cells were then used in hybridization experiments. The specific efficiencies of each fusion that made use of cells immunized with mouse albumin, hemoglobin, syngeneic mouse serum, actin, or RNA polymerase II were 12, 31, 33, 52, and 22%, respectively, which illustrated the apparent lack of immune tolerance found when the immunization was performed in culture.     

Reversal of phorbol ester-mediated reduction of cloned T lymphocyte cytolysis by interleukin 2

During previous studies on the regulation of cloned T lymphocyte function, we observed that murine cytotoxic T lymphocyte (CTL) clones progressively lose the ability to lyse appropriate target cells during prolonged (24 to 48 hr) incubation with the tumor promoter phorbol myristic acetate (PMA). We further observed that the cytolytic function of PMA-treated CTL clones can be restored by incubation with secondary MLC supernatant (2 degrees MLC SN), a potent source of cytokines. We now report our observations on the nature of the cytokine(s) responsible for recovery of CTL activity. Like 2 degrees MLC SN, the lectin-induced SN from a cloned helper T cell and the lectin-induced SN from a T cell hybridoma can restore cytolytic activity to cloned CTL treated with PMA. In contrast, supernatants from L929 cells, WEHI-3 cells, and P388D1 cells fail to restore cytolytic activity to similarly treated cloned CTL. These data suggest that IL 2 and/or gamma-IFN, but not CSF-1, CSF-GM, IL 3, or IL 1, can influence expression of cytolysis by cloned CTL. Furthermore, highly purified IL 2 can restore cytolytic activity, even when cytosine arabinoside is present to inhibit clonal expansion. Our studies indicate that cytolysis is a reversible function of cloned CTL, and that cytolysis may not necessarily represent an end-stage feature of CTL maturation. Our studies further show that IL 2 is both necessary and sufficient for resumption of cytolytic function by "deactivated" CTL. As such, these observations suggest that IL 2 can regulate not only T cell proliferation but also the expression of cytolysis by some cytolytic T cell populations.     

Cell-mediated immune response in vitro. I. The development of suppressor cells and cytotoxic lymphocytes in mixed lymphocyte cultures.

During the in vitro development of cytotoxic lymphocytes (CL), suppressor cells also develop. Spleen cells or lymph node cells harvested from mixed lymphocyte cultures (MLC) on day 2 (day-2 MLC) and added to a fresh MLC suppressed the development of CL. This suppressive effect was sensitive to treatment with anti-theta and C. The suppressive effect of day-2 MLC was not due to cytotoxic effects nor to altered kinetics of the development of both suppressor cells and CL. Although CL develop from hydrocortisone-treated spleen cells, day-2 MLC of hydrocortisone-treated spleen cells did not suppress the development of CL. These studies suggest that suppressor cells and CL are derived from different T cell subpopulations.     

Suppression of Ia-unrestricted primary anti-Qa-1 cytotoxic T lymphocyte responses by class II major histocompatibility complex-restricted cellular interactions

A model has been established for investigating the cellular interactions for the generation and regulation of primary cytotoxic T lymphocyte (CTL) responses to Qa-1 alloantigens. Although NZB anti-BALB/c one-way mixed leukocyte cultures (MLC) generate anti-Qa-1b CTL, anti-Qa-1 CTL responses are not generated during BALB/c anti-NZB one-way MLC or during two-way MLC with NZB and BALB/c spleen cells. However, depletion of L3T4+ cells from the spleens of BALB/c mice before two-way MLC with NZB spleen cells resulted in anti-Qa-1b CTL responses. Likewise, the addition of anti-L3T4 monoclonal antibody (mAb) or anti-I-Ad mAb to two-way MLC with NZB and BALB/c spleen cells resulted in the generation of anti-Qa-1b CTL. Conversely, anti-Lyt-2 mAb inhibited the generation of anti-Qa-1 CTL. These data indicate that class II major histocompatibility complex-restricted cellular interactions are capable of suppressing the generation of Ia-unrestricted anti-Qa-1 CTL responses by Lyt-2+ responder cells. This model provides a novel opportunity to both characterize the cellular interactions responsible for regulating primary CTL responses to the Qa/Tla-encoded class I molecule Qa-1, and determine the contribution of this L3T4+ Ts-dependent defect in NZB mice to the pathogenesis of autoimmunity.     

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.     

The genetics of cell-mediated lympholysis.

The role of HLA antigens in the generation of cytotoxic cells in CML has been investigated. Cytotoxic effector cells were generated in MLC among HLA-A or HLA-A and HLA-B disparate, HLA-D identical siblings, and among HLA-A and HLA-B disparate, MLC identical (%RR less than or equal to 2 3.6) unrelated individual. The data indicate that HLA-D differences and poliferative MLC responses as measured by 3H-thymidine incorporation are not requisite for the in vitro generation of cytotoxic cells and suggest the existence of a CML-S locus (loci) distinct from HLA-A, HLA-B and HLA-D. The degree of cytotoxicity generated in a proliferative versus a "nonproliferative" MLC was comparable. In addition, these studies demonstrate that antigens other than the currently definable HLA-A, HLA-B, HLA-C, and HLA-D can serve as target determinants in cell-mediated lympholysis.     

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.     

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.     

The effects of soluble products of activated lymphocytes and macrophages on blastocyst implantation events in vitro

The purpose of this study was to investigate the effects of soluble products of activated lymphocytes and macrophages on mouse blastocyst attachment and trophoblast outgrowth in vitro. Hatched blastocysts were incubated with medium alone, supernatant fluids from mixed lymphocyte cultures (MLC), and with individual human and murine lymphokines and monokines in fibronectin-coated wells. Cultures were assessed at 24, 48, and 72 h for blastocyst attachment and trophoblast outgrowth. Both human and murine MLC supernatant fluids significantly enhanced trophoblast outgrowth in vitro. The cytokine, interleukin-1 beta (Il-1 beta), at a concentration of 10(3) U/ml, inhibited blastocyst attachment but significantly enhanced trophoblast outgrowth of attached blastocysts. Granulocyte, macrophage-colony-stimulating factor (GM-CSF) at a concentration of 250 U/ml significantly inhibited blastocyst attachment, while gamma interferon (gamma-IFN) at a concentration of 2.5 x 10(3) U/ml significantly inhibited trophoblast outgrowth and caused degenerative morphological changes in these cells. The results of this study indicate that products of activated immune cells may either facilitate or impede implantation events depending on the types of predominant cytokines present, their concentration(s), and the timing of their secretion relative to embryonic development.     

Allogeneic T-cytotoxic reactivity of senescent mice: affinity for target cells and determination of cell number

Experiments were performed to determine the cause(s) of the reduced T-cytotoxic-cell response observed in senescent mice. The cytotoxic cells studied developed in mixed lymphocyte cultures (MLC) of 6 × 10⁶ C57B1/6J (H-2^b) spleen cells from mice of various ages which were stimulated by doses of irradiated Balb/c (H-2^d) cells giving responder to stimulator ratios of 10:10 and 10:1. The cytotoxic response, as determined in a ⁵¹Cr-release assay against P815 (H-2^d) mastocytoma cells in culture, declines with age. This age-related decline is more pronounced with the lower dose of stimulator cells (10:1). The cytotoxic response developing in 10:10 and 10:1 MLC of spleen cells from young mice is comparable in magnitude, whereas the lower dose (10:1) is much less stimulatory in cultures of spleen cells from mice above 12 months of age. In order to better understand this age-dependent decline in cytotoxic response, the affinity of effector cells to their target and the percentage of cytotoxic cells which develop in the cultures of spleen cells from mice of various ages were determined. The affinity of cytotoxic cells developing in 10:10 MLC does not change with age. The affinity of cytotoxic cells developing in 10:1 MLC from young mice is significantly higher than the affinity of those developing in 10:10 MLC. This dose-dependent increase in affinity is not apparent in 20-month-old mice, which show equal affinity of cytotoxic cells in 10:10 and 10:1 MLC. The percentage of cytotoxic cells in the cultures was found to decrease with age. This decrease was more pronounced after 10:1 stimulation. Thus the decline with age in cytotoxic response can be attributed to a decrease in number of functional cytotoxic cells developing in MLC cultures, regardless of stimulator cell dose and a decrease in affinity for target cells at low stimulator cell doses.     

Regulatory mechanisms in cytotoxic T lymphocyte development. II. Dissociation of in vitro cytotoxic T-lymphocyte and suppressor T-cell activities with L-ornithine

L-ornithine was found to differentially affect the induction of allospecific cytotoxic T lymphocytes (CTL) and suppressor T cells (Ts). At a concentration of 10 mM, ornithine inhibited the development of CTL in a mixed-leukocyte culture (MLC). This same population of cells suppressed the generation of CTL when irradiated and cocultured with fresh syngeneic lymphocytes and alloantigen. Suppression was mediated by Lyt-1-2+ cells and was antigen specific. Suppression was abrogated when IL-2 (10 U/ml) was added to the cocultures, but could not be reversed by increasing the antigen dose. Ornithine was not toxic to CTL precursors but rather arrested their development. Cells from MLC plus ornithine developed CTL activity within 2 days of transfer to secondary cultures in the absence of ornithine. Development of CTL effector cells (CTLe) was augmented by but did not require exogenous IL-2. Generation of CTLe from the MLC plus ornithine population was radiation sensitive and could be inhibited by reexposure to ornithine, even in the presence of IL-2. Thus, Lyt-1-2+ T cells allostimulated in vitro in MLC plus ornithine and lacking CTL activity convey radiation-resistant, antigen-specific suppression.     

Cyclosporine A and peripheral tolerance. Inhibition of veto cell-mediated clonal deletion of postthymic precursor cytotoxic T lymphocytes.

Veto cell-mediated suppression of CTL responses has been proposed as one mechanism by which self tolerance is maintained in mature T cell populations. We have reported that murine bone marrow cells cultured in the presence of high-dose IL-2 (activated bone marrow cells) mediate strong veto suppressor function in vitro and in vivo, and that such veto activity is effected through clonal deletion of cytotoxic T cell precursors. In our studies, we have determined that bone marrow cell populations from athymic NCr-nu mice (H-2d) mediate strong veto cell activity without exposure to exogenous IL-2 in vitro. To examine mechanisms by which these naturally occurring veto cell populations in BM suppress precursor CTL (pCTL) responses, we used as a responding cell population in MLC, spleen cells of transgenic mice expressing at high frequency TCR specific for H-2 Ld encoded Ag with stimulation by H-2d-expressing cells in culture. Flow cytometric analysis was performed by staining the responding MLC cell population with the mAb 1B2 specific for the transgene-encoded TCR and determined changes of 1B2+ T cells. Such experiments demonstrated that the anti-H-2d cytotoxic response by these cell populations was specifically suppressed by NCr-nu (H-2d) bone marrow, and that 1B2+ pCTL were in fact specifically deleted from the responding cell population by incubation with such naturally occurring veto cell populations expressing the appropriate target Ag. In addition, to further understand the interactions of pCTL and veto cells and possible contributions by the latter to peripheral tolerance, we evaluated the effect of cyclosporine A (CsA) on veto cell-mediated suppression of pCTL of the transgenic mice. CsA inhibited veto cell-mediated suppression of cytotoxic T cell responses, and this inhibition correlated with a lack of clonal deletion of pCTL by veto cells in the presence of CsA. Furthermore, CsA exerted its effect through pCTL and not through veto cells, indicating that pCTL may play an active role in their own deletion by veto cells.