An autoreactive T cell clone that can be activated to provide both helper and suppressor function

To understand further the biologic significance of the autologous mixed lymphocyte reaction, we determined the functional properties of autoreactive T cell lines and clones. Initially, we found that cells in an uncloned autoreactive Leu-3+ T cell line helped immunoglobulin production when added to cultures containing fresh T and non-T cells in the absence of pokeweed mitogen (PWM) but suppressed immunoglobulin production in the same cultures in the presence of PWM. To explain this phenomenon, we studied the immunoregulatory potential of an autoreactive T cell clone termed MTC-4. This clone bore the phenotype Leu-3+, 2-, 8-, 11-, DR+ and underwent proliferation when co-cultured with autologous, but not allogeneic non-T cells. Of interest, the immunoregulatory potential of the MTC-4 cells varied according to how the cells were activated. When MTC-4 cells were cultured with autologous non-T cells in the absence of antigen or mitogen (unactivated non-T cells), polyclonal immunoglobulin production (detected by reverse PFC assay) was observed. This helper activity was MHC-restricted in that it was elicited only by autologous non-T cells or MHC-matched allogeneic non-T cells; however, once activated by autologous non-T cells, it could also help allogeneic non-T cells. In contrast, when MTC-4 cells were cultured with autologous non-T cells in the presence of PWM (activated non-T cells), immunoglobulin production was greatly suppressed. This suppression was also observed when MTC-4 cells were added to cultures containing exogenous T cell help (such as that provided by autologous fresh T cells) and was not due to a direct effect of PWM on the T cell clone, because preincubation of MTC-4 cells with PWM before culture with non-T cells did not result in suppression. On the basis of these data, we conclude that autoreactive T cells can have dual immunoregulatory function that is manifest, at least in part, at the single cell level. Moreover, these regulatory functions are differentially elicited depending on the state of activation of the stimulating autologous non-T cells: when stimulated by MHC antigens present on unactivated B cells, they provide helper activity; and when stimulated by MHC antigens present on activated B cells, they act as suppressor cells. Autoreactive T cells with dual regulatory potential appear to make up a substantial proportion of all autoreactive T cells and are cells that are uniquely adapted to maintain immunologic homeostasis.     

Characterization of the human newborn response to herpesvirus antigen

An investigation was made into the human newborn cellular response to herpes simplex virus type 1 (HSV), cytomegalovirus (CMV), and varicella zoster virus (VZV) to understand more about the nature of the neonate's susceptibility to overwhelming infection by these viruses. Newborn mononuclear cells sustained the proliferation in culture of maternal (i.e., haplotype-matched) T cell blasts with specificity for HSV, CMV, or VZV (p less than 0.05). This is evidence for intact antigen-processing capability by newborn monocytes. The response of the maternal T cell blasts appeared to be HLA-haplotype-restricted as suggested by experiments in which maternal T cell blasts were limited in number. Our culture conditions elicited responses predominantly from the T4+ lymphocyte subset. A low frequency of herpesvirus-specific T4+ lymphocytes in newborn blood might contribute to deficient viral immunity, so we evaluated the virus-specific T cell responding frequency in human newborns in limiting dilution cultures. We were unable to find a herpesvirus-specific responder cell frequency greater than 1:1,400,000 in nonimmune newborns. Three of seven adults who had no serum antibody to CMV had a CMV responder cell frequency (RCF) of 1:100,000 to 1:200,000. The RCF to HSV in immune children, ages 18 mo to 12 yr, and adults, ages 13 to 80 yr, ranged from 1:14,000 to 1:18,000. We conclude that newborn monocyte processing of herpesvirus antigen is intact, that T cell RCF is low in neonates, and that immunity to HSV after infection outside the newborn period results in comparable RCF between adults and children.     

Regulation on murine T cell responses to autologous antigens by alpha-fetoprotein

Murine α-fetoprotein (AFP), a major component of fetal and newborn sera, was shown to exert potent immunosuppressive effects on autologous mixed lymphocyte reactions (AMLR) in vitro. Thus, the relatively vigorous proliferative response of newborn CBA/J thymocytes reacting in mixed cultures against adult syngeneic spleen cells was almost totally abrogated by 200 and 100 μg/ml AFP over the 6-day time course studied, with significant suppression still evident in the presence of 10 μg/ml AFP. In contrast, the maximum achievable suppression of parellel allogeneic MLRs was only 40 to 60%. The newborn thymocyte anti-adult syngeneic spleen AMLR was shown to be mediated by an Lyt 1⁺23^? T-cell subset reacting against Ia⁺ adult non-T stimulator cells. Newborn and adult AMLRs resulting from autochthonous T responder/non-T stimulator cell mixtures from individual animals were also found to be highly sensitive to AFP-mediated suppression. The fact that fetal-derived AFP could be shown to efficiently inhibit neonatal thymocyte responses to autologous antigens when tested in vitro in amounts 20 to 50 times lower than the levels present in fetal and newborn sera suggests a potentially important role for endogenous AFP in the regulation of autosensitization during ontogeny.     

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.     

T cell proliferative response to interleukin 2: different frequency of responders among CD45R0 and CD45RA subsets

A proportion of human blood T cells is known to proliferate in cultures containing 10 or more units/ml of interleukin (IL)2, in the absence of exogenously added antigen. A possible explanation for this phenomenon is that the IL2 serves to maintain the proliferation of memory T cells which have recently been activated by antigen in vivo. To test this possibility we therefore separated T cells according to their CD45 (common leukocyte antigen) phenotype into the CD45RO and CD45RA subsets which are associated with memory and naive status, respectively. The frequency of responder cells in limiting dilution analysis of adult MNC was 1:1625 CD45RO cells, 1:2405 for CD45RA cells, and 1:1642 for unseparated cells. CD45RA cells from newborns had a 1:1850 frequency of responders. The IL2 responder cells were predominantly CD3+ TcR alpha beta +, with a minor component of TcR delta cells. There were no differences in the frequency of T cells using V beta 5 and V beta 8 between responding and nonresponding cells. The data argue against a requirement for prior sensitization for a proliferative response to IL2 and give no evidence that the subset of T cells which responds to IL2 differs in phenotype from nonresponsive cells.     

Improvement of decreased interleukin 2 (IL-2) responsiveness and IL-2 production in autologous mixed-lymphocyte reaction of cord blood lymphocytes by interferon-gamma and IL-2 and the role of HLA-DQ antigen

Cord blood T cells did not produce interleukin 2 (IL-2) nor acquire responsiveness to it in autologous mixed-lymphocyte reaction (AMLR) as they do when activated by phytohemagglutinin (PHA). The ability of the cells to respond to IL-2 was restored either by the addition of recombinant IL-2 to the AMLR culture or by the preculture of non-T stimulator cells with recombinant interferon-gamma (IFN-gamma). IL-2 production was also induced when the T cells were added with recombinant IL-2 at the initiation of the AMLR culture, preceded by the treatment of non-T cells with recombinant IFN-gamma. IL-2-producing cells of cord blood induced in the above-mentioned condition were defined to be OKT4+ T cells, because the deletion of OKT4+ T cells from T-cell population abrogated the reaction, while that of OKT8+ T cells did not. Acquisition of IL-2 responsiveness and IL-2 production of T cells seemed to be mediated by HLA-DR and HLA-DQ molecules of non-T cells because these reactions were blocked by the treatment of non-T cells either with monoclonal anti-HLA-DR or with anti-HLA-DQ antibody. The HLA-DR and HLA-DQ densities of cord blood non-T cells were low as compared with those of adult, but the expression of HLA-DQ was remarkably improved by IFN-gamma treatment. In regard to IL-2, both IFN-gamma and IL-2 were needed to enable the lymphocytes to produce. This may suggest that some functional maturation by IL-2 of responder T cells is further required. These combined data suggested that cord blood non-T cells are defective as a stimulator in AMLR and this could be corrected by enhancing the expression of HLA-DQ antigen.     

Induction of interleukin 3 but not interleukin 2 or interferon production in the syngeneic mixed lymphocyte reaction

The syngeneic mixed lymphocyte reaction (SMLR) was assayed in the medium containing syngeneic normal mouse serum (NMS), by using nylon-adherent stimulator cells and nonadherent responder T cells, which were prepared from murine spleens in the absence of fetal calf serum (FCS) to avoid any sensitization to xenogeneic protein antigens. The responder cells in this SMLR, without definite background proliferation, generated specific proliferative response to the syngeneic stimulator cells in a dose-related fashion. The SMLR was accompanied by production of interleukin 3 (IL 3) but not interleukin 2 (IL 2) or interferon (IFN). No cytotoxicity against the syngeneic or allogeneic target cells was induced. Correlating with no production of IL 2 or IFN, no natural killer (NK) activity was detected. The proliferation was not inhibited by addition of specific antiserum for IFN-gamma. In contrast, proliferation in the responder cells when incubated with allogeneic stimulator cells was inhibited by anti-IFN-gamma serum and accompanied by production of IL 2 and IFN as well as IL 3, and by augmentation of NK activity and generation of cytotoxic T cells. Cell surface analysis revealed that the cells producing IL 3 in this SMLR system were Thy-1+ Lyt-1+2- helper T cells. Cells responding to the SMLR culture fluids with DNA replication were Thy-1-Lyt-1-2- asialo GM1- no-marker cells, which were the same as a population responsible for partially purified IL 3. On the other hand, when the responder cells were exposed to FCS before culture and assayed for SMLR in the FCS-free NMS medium, variable levels of IL 2 production were induced in response to the stimulator cells. The responder cells generated a high background DNA replication in the absence of syngeneic stimulators, suggesting that this IL 2 production may result from the stimulation of T cells by FCS as a foreign antigen. Overall, these results suggest that the SMLR may be a cellular interaction, in which non-T cells stimulate Lyt-1+2- helper T cells to produce IL 3 but not IL 2 or IFN. This IL 3 can, in turn, induce proliferation of IL 3 responding cells, which appear to be early precursors in lymphocyte differentiation, but no proliferative response or activation of IL 2- and IFN-dependent mature T cells or NK cells.     

Activation and function of an autoreactive T cell clone with dual immunoregulatory activity

Previously it was demonstrated that the human autoreactive CD4+ T cell clone MTC-4 is bifunctional, having the capacity to augment differentiation of autologous B cells into Ig-secreting cells in the absence of PWM and the capacity to suppress such differentiation in the presence of PWM. In the present study it was shown that these two functions of MTC-4 are mediated by distinctly different mechanisms. In the presence of autologous class II MHC Ag, MTC-4 releases one or more non-MHC-restricted soluble factors which stimulate B cell differentiation. The helper factors are different from IL-2, and act on both resting (small) and activated (large) B cells. The suppressor function of MTC-4 cells is elicited when MTC-4 cells are co-cultured with autologous non-T cells preincubated with PWM for 4 h, but not with non-T cells preincubated with PWM for 24 h; thus, activated autologous non-T cells have a transient capacity to induce MTC-4 suppressor function. Induction of MTC-4 suppressor activity is not associated with increased proliferation of MTC-4 and is mediated by low numbers of these cells. Unlike helper function, MTC-4 suppression of Ig synthesis can occur late in B cell cultures, and MTC-4 suppresses Ig production by autologous B cells, but not by allogeneic B cells. Finally, in co-cultures with activated autologous non-T cells and allogeneic B cells, MTC-4 can simultaneously produce helper factors that augment Ig synthesis by allogeneic B cells and suppress Ig synthesis by autologous B cells. In summary, exposure of MTC-4 to autologous non-T cells causes release of non-MHC-restricted factors which augment Ig production by both resting and activated autologous B cells, whereas exposure of MTC-4 to recently activated B cells causes MTC-4 to express the additional function of directly suppressing Ig production by differentiated autologous B cells. Thus autoreactive T cells may be uniquely suited to regulate Ig production.     

Soluble antigen-primed inducer T cells activate antigen-specific suppressor T cells in the absence of antigen-pulsed accessory cells: phenotypic definition of suppressor-inducer and suppressor-effector cells

This study was undertaken to characterize interactions among human T cell subpopulations involved in the generation of suppressor T cells specific for a soluble antigen. Purified PPD-primed Leu-3+ cells, when co-cultured for 7 days with fresh autologous Leu-2+ cells, induced differentiation of Leu-2+ but not Leu-3+ cells into specific suppressor T cells, which subsequently inhibited the proliferative response of fresh Leu-3+ cells to PPD but not to tetanus toxoid or allogeneic non-T cells. The PPD-specific suppressor effect of activated Leu-2+ cells was not due to altered kinetics of the PPD response and also extended to the secondary response of PPD-primed Leu-3+ cells. Furthermore, only those Leu-2+ cells that lacked the 9.3 marker, an antigen present on the majority of T cells including the precursors of cytotoxic T cells, differentiated into suppressor T cells. To analyze the inducer population, fresh Leu-3+ cells were separated into Leu-3+,8- and Leu-3+,8+ subpopulations with anti-Leu-8 monoclonal antibody, activated with PPD, and then were examined for inducer function. Although both Leu-3+,8- and Leu-3+,8+ cells proliferated in response to PPD and upon activation expressed comparable amounts of HLA-DR (Ia) antigens, the Leu-3+,8+ subpopulation alone induced Leu-2+ cells to become suppressor-effectors in the absence of PPD-pulsed autologous non-T cells. Once activated, however, Leu-2+ suppressor cells inhibited the PPD response of both Leu-3+,8- and Leu-3+,8+ cells. These results indicate that antigen-primed Leu-3+,8+ inducer cells can directly activate Leu-2+, 9.3- precursors of antigen-specific suppressor T cells in the absence of antigen-pulsed autologous non-T cells.     

T cell proliferation induced by autologous non-T cells is a response to apoptotic cells processed by dendritic cells

Self-reactive T cells are present in the mature immune repertoire as demonstrated by T cell proliferation induced by autologous non-T cells in the autologous mixed lymphocyte reaction. This reaction generates regulatory T cells in vitro and may reflect immune regulatory pathways in vivo, but the antigenic peptides recognized remain uncharacterized. We revisited this issue in light of the importance of apoptosis in immune regulation. We found that apoptosis among peripheral blood non-T stimulator cells is associated with augmented induction of autologous T cell proliferation. Our data show that caspase activity in the non-T stimulator population is essential for induction of autologous T cell proliferation, suggesting that cellular components in the non-T cell fraction are enzymatically modified, most likely by effector caspases, and have a direct or indirect effect on autoreactive T cell activation. Furthermore, exposure of macrophage-derived dendritic cells to apoptotic non-T cells augments autologous T cell proliferation, and blockade of alpha(v)beta(5) integrin, but not alpha(v)beta(3), inhibits the capacity of irradiated non-T cells or dendritic cells to stimulate autologous T cell proliferation. These experiments, using an entirely autologous system, suggest the interpretation that autoreactive T cells may recognize self-Ags modified through the actions of caspases and presented to T cells by dendritic cells. Induction of an in vivo autologous mixed lymphocyte reaction by caspase-modified self-Ags present in apoptotic cells may represent a mechanism to maintain peripheral immune tolerance.     

MHC class-II-restricted antigen presentation by myelin basic protein-specific CD4+ T cells causes prolonged desensitization and outgrowth of CD4- responders.

T cells express MHC class II glycoproteins under various conditions of activation or inflammation. To assess whether T cell APC (T-APC) activity had long-term tolerogenic consequences, myelin basic protein (MBP)-specific rat T cells were induced to acquire MBP-derived I-A complexes to promote reciprocal antigen presentation. T-T antigen presentation caused extensive cell death among T-APC and MBP-specific T responders and caused long-term desensitization of surviving responders. Addition of the anti-I-A mAb OX6 to activated I-A+ responders inhibited T-APC activity, accelerated recovery from postactivation refractoriness, and prevented long-term loss of reactivity in responder T cells. Antigenic activation of responder T cells with irradiated T-APC induced profound losses in reactivity that lasted for over 1 month of propagation in IL-2 and was associated with preferential outgrowth of CD4- T cells. Antigen-activated CD4- T cells exhibited more rapid IL-2-dependent growth that eventually normalized compared to CD4+ T cells 1-2 months after antigen exposure. In conclusion, expression of T-APC activity by activated T cells represents an important negative feedback pathway that depletes antigen-reactive T cells and causes long-term desensitization of surviving T cells. Hence, T cell APC may be an important mechanism of self-tolerance.     

Induction of T cell-dependent B cell differentiation by anti-CD3 monoclonal antibodies

Three monoclonal antibodies (mAb) recognizing the CD3 (T3) surface complex each induced B cell differentiation (as measured by PFC generation) in cultures containing T + non-T cells. Irradiation of the T cells before culture usually augmented the PFC response. An IgG2a mAb (454) induced PFC in all donors tested, whereas two IgG1 mAb (147 and 446) induced PFC in only 80% of the donors tested. This heterogeneity in PFC response to IgG1 anti-CD3 mAb strictly paralleled the heterogeneity in proliferative response to IgG1 anti-CD3 mAb and was governed by cells within the non-T population. In IgG1 anti-CD3 high responders (HR), all anti-CD3 mAb tested induced Tac expression. In IgG1 anti-CD3 low responders (LR), mAb 454 induced Tac expression, but mAb 147 did not. However, when the cultures were supplemented with exogenous interleukin 2, Tac expression and PFC generation in response to mAb 147 was similar to the response to mAb 454 in both HR and LR. The addition of anti-Tac to the cultures partially inhibited anti-CD3-induced PFC generation. These studies indicate that anti-CD3 mAb can lead to B cell differentiation under appropriate experimental conditions and may be valuable in studying polyclonal T cell-dependent B cell differentiation in normal and disease states.     

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.     

Human cytotoxic lymphocytes. V. Frequency and specificity of gamma delta+ cytotoxic lymphocyte precursors activated by allogeneic or autologous stimulator cells

We have investigated the frequency and specificity of gamma delta+ cytotoxic lymphocyte precursors (CLP) under limiting dilution culture conditions. E rosette separated total T cells and CD3+CD4-CD8-TCR alpha beta- double-negative (DN) T cells were cocultured with allogeneic or autologous PBMC stimulator cells, and frequencies of alloreactive and autoreactive CLP were determined after 12 to 14 days against Con A blast target cells. Freshly isolated DN cells consisting of 82.3 +/- 8.2% gamma delta+ T cells did not exert cytolytic activity against K562 or anti-TCR gamma delta mAb-producing hybridoma cells. In striking contrast to E+ cells, the vast majority of alloantigen-stimulated clonally developing DN CLP did not show specificity for stimulator-derived target cells. Thus, frequencies of alloreactive and autoreactive CLP after alloantigenic stimulation were in the range of 1/100 to 1/4800 and 1/450 to 1/5000, respectively. After coculture with autologous stimulator cells, frequencies of autoreactive and alloreactive DN CLP were 1/700 to 1/2700 and 1/1360 to 1/4500, respectively. Split culture analysis revealed that most proliferating DN colonies selected for high probability of clonality simultaneously killed both autologous and HLA-mismatched allogeneic targets. The majority of the DN cells expressed the CD3+/TCR gamma delta+ phenotype after culture, and thus were not CD2+CD3- NK cells. Taken together, our results show that 1) freshly isolated peripheral blood gamma delta+ T cells lack cytotoxic activity, and 2) most cytotoxic gamma delta+ T cells activated by autologous or allogeneic stimulator cells under limiting dilution conditions do not discriminate between autologous and allogeneic targets.     

Murine neonatal spleen contains natural T and non-T suppressor cells capable of inhibiting adult alloreactive and newborn autoreactive T-cell proliferation

The spleen of neonatal mice is known to be a rich source of cells capable of suppressing a variety of immune functions of adult lymphocytes in vitro. From such observations has emerged the concept that the gradual development in ability to express immune functions after birth is due in part to the parallel normal physiological decay of naturally occurring regulatory suppressor cells. There is, however, some confusion in the literature as to the exact nature of the newborn of the newborn inhibitory cell type(s). In contrast to most previous reports which detect only a single type of neonatal suppressor cell, usually a T cell, we show here that newborn spleen harbors both T and non-T inhibitory cells. Both types of suppressor cells could be shown to suppress the proliferative response of adult spleen to alloantigens as well as newborn T cells reacting against self-Ia antigen in the autologous mixed lymphocyte reaction (AMLR). Newborn suppressor T cells were characterized as being non-adherent to Ig-anti-Ig affinity columns, soybean agglutinin receptor negative (SBA-), and susceptible to lysis by anti-T-cell specific antiserum plus complement. Non-T suppressor cells were identified as non-phagocytic, SBA receptor positive (SBA+), and resistant to cytotoxic treatment with anti-T-cell antibodies and complement. The apparent controversy surrounding previous reports as to the T versus non-T nature of newborn suppressor cells can be reconciled by the present observation that both types of inhibitory cells coexist in the spleen. Furthermore, the demonstration that newborn suppressor cells can effectively regulate T-cell proliferative activity mediated by other newborn cells provides more direct support for the contention that such inhibitory cells play a physiological role in controlling immune responsiveness during early ontogeny.     

Suppressive Effect by Cooperation of Splenic and Peritoneal Adherent Cells on Generation of Cytotoxic T Lymphocytes

When spleen cells primed in vivo against allogeneic lymphoid cells were used as responder cells in secondary mixed lymphocyte cultures, a high degree of cytotoxicity was generated even in the absence of splenic adherent cells. However, removal of adherent cells from such primed responder spleen cells reduced the cytotoxicity to some extent. On the other hand, when these responder cells were transferred into the peritoneal cavity of irradiated syngeneic mice together with antigenic cells, unseparated responder cells generated a lower degree of cytotoxicity than did adherent cell-depleted responder cells. In an in vitro system, peritoneal adherent cells also suppressed the generation of cytotoxic T lymphocytes by unseparated responders; however they augmented the cytotoxic T lymphocyte generation by adherent cell-depleted responders. These adherent cell populations with augmenting activity became inhibitory when they coexisted. The mechanism of this inhibitory action remains unclear.     

Interferon gamma modulates the ability of autologous non-T cells to stimulate T cells to produce and respond to interleukin 2

The interactions of T-cell receptor with self-Ia antigen on non-T cells induced IL-2 production and IL-2 receptors on the cell surface and thus responsiveness to IL-2 of T cells in autologous mixed-lymphocyte reaction (AMLR). Four-day-cultured autologous non-T cells lost their ability to stimulate T cells to produce and respond to IL-2 with concurrent decrease of HLA-DR and HLA-DQ antigen expressed on the cell surface. Culturing of non-T cells with 500 U/ml of recombinant interferon gamma (IFN-gamma) maintained their stimulating ability which was otherwise lost. Treatment of non-T cells with monoclonal anti-HLA-DR or anti-HLA-DQ antibody before mixture with T cells abrogated their ability to induce IL-2 production and IL-2 responsiveness of T cells. The combined data suggested that Ia antigen expressed on non-T cells is modulated by IFN-gamma, which increases the ability of non-T cells to stimulate autologous T cells to produce and respond to IL-2.     

Spontaneous proliferation in unfractionated spleen cell cultures: autologous mixed-lymphocyte reactions (AMLR) which can be differentially regulated by prostaglandins and lymphokines

The present studies were undertaken to define the contribution of the autologous or syngeneic mixed-leukocyte reactions (AMLR/SMLR) to the cellular proliferation observed in unfractionated spleen cell cultures. Proliferation was studied in whole, untreated 6-day murine spleen cell cultures supplemented with syngeneic serum. These cultures exhibited relatively low but significant levels of cellular proliferation as measured by uptake of radioactive thymidine ([3H]TdR). Treatment of spleen cells with monoclonal anti-Thy 1.2 antibody and complement before culture, the addition of specific anti-I-A monoclonal antibodies to the cultures or removal of Ia+ adherent cells before initiation of culture all inhibited the proliferative response significantly. Thus, the autologous proliferation of untreated and unfractionated spleen cells manifests the main characteristics of the AMLR/SMLR, namely, its dependence on T (responder) and Ia+ (stimulator) cells and specific inhibition by anti-I-A antibodies. A marked augmentation in cellular proliferation was observed in unfractionated spleen cell cultures treated for the initial 24 hr of culture with 5 X 10(-6) M indomethacin, an inhibitor of prostaglandin synthesis. Conversely, the addition of 7 X 10(-9) M prostaglandin E1 (PGE1) to these cultures depressed cellular proliferation. This suppression of autologous splenic cell proliferation induced by PGE1 could be partially reversed by the addition of concanavalin A-induced lymphokine (LK) preparations early in the culture. These findings indicate that (a) the proliferation of unfractionated spleen cell cultures occurring in the absence of exogenous stimulatory signals is due largely to an ongoing AMLR, and (b) biologically active mediators with opposing influences, namely, prostaglandins and immunostimulatory LK, participate in the regulation of the AMLR.     

Possible regulation of autologous mixed lymphocyte reaction by OKM1+ NK cells

T cells are stimulated by autologous non-T cells and interleukin 2 (IL-2) is produced in the conventional autologous mixed lymphocyte reaction (AMLR) in young healthy controls. The role of cells with natural killer (NK) cell markers (OKM1+ cells or Leu 7+ cells) in the AMLR was studied. There were significant inverse correlations between the percentage of input OKM1+ cells minus monocyte (OKM1+ NK cells) and either AMLR proliferation (gamma = -0.9, P less than 0.001) or IL-2 production (gamma = -0.75, P less than 0.01) in the AMLR cultures after 7 days measured at 7 days. A statistically significant correlation was observed between the percentage of input Leu 7+ cells and AMLR proliferation (gamma = -0.64, P less than 0.05), but not IL-2 production. These results suggest that the AMLR is controlled by OKM1+ NK, perhaps acting through IL-2 regulation.