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.     

The activation of guinea pig T lymphocytes by anti-beta 2-microglobulin serum.

In order to study further the role of beta 2-m in the regulation of the immune response, we have examined the effects of a goat anti-guinea pig beta 2-m serum on a number of T lymphocyte functions in vitro. Anti-beta 2-m serum produced a marked inhibition of the response of peritoneal exudate T cells to antigen and mitogen stimulation. Surprisingly, a marked activation of lymph node T lymphocyte proliferation was observed in the absence of antigen or mitogen stimulation. This stimulatory effect of anti-beta 2-m serum was shown to be specific for beta 2-m and required the presence of macrophages. The T cell proliferative response induced by anti-beta 2-m could not be blocked by antisera to the antigens of the guinea pig MHC. These studies suggest that beta2-m may play some critical role in the immune response at the level of T cell activation.     

Some biological properties of beta2-microglobulin and its antibody.

beta2-Microglobulin on the surface of lymphocytes exists in two molecular forms, first as part of the HL-A antigen complex, and second as a free molecule unbound to other membrane macromolecules. Quantitative determinations of the numbers of molecules of beta2-microglobulin per lymphocyte when compared to published values for the numbers of HL-A molecules per cell are consistent with an excess of beta2-microglobulin compared to HL-A antigens on the cell surface. Turnover studies of beta2-microglobulin from the lymphocyte surface indicated that both beta2-microglobulin and HL-A components are metabolized at similar rates. beta2-Microglobulin appears to be released in the free form. HL-A antigens, if released from the cell surface, appear to be released unbound to beta2-microglobulin. The effects of anti-beta2-microglobulin antibody on lymphocyte activation, namely on the mixed lymphocyte reaction and on antigen induced proliferative response, were studied. Anti-beta2-microglobulin completely inhibited the mixed lymphocyte reaction and the antigen induced proliferative response.     

Induction of allograft tolerance after total lymphoid irradiation (TLI): development of suppressor cells of the mixed leukocyte reaction (MLR).

We searched for the presence of suppressor cells of the MLR in C57BL/Ka leads to BALB/c chimeras. The chimeras were made with total lymphoid irradiation (TLI) and marrow transplantation. Spleen cells from the old chimeras inhibited the MLR of BALB/c responder cells against C57BL/Ka stimulator cells. Inhibition was specific for the stimulator cells, since no effect on the MLR was observed with C3H or BALB.C3H stimulator cells. Maximal inhibition was achieved when the responder cells in the MLR shared the H-2 haplotype of the chimeric recipient. Spleen cells obtained from chimeras young 30 to 40 days after BM transplantation inhibited the MLR nonspecifically, since similar marked inhibition was observed regardless of the H-2 haplotype of the responder or stimulator cells. The finding of antigen-specific and nonspecific suppressor cells is similar to that observed in mice rendered tolerant to bovine serum albumin after treatment with TLI.     

Generation of natural killer-like activity in mixed lymphocyte-tumor cell cultures. II. Correlation between expression of HLA-DR antigens on the activated T cells and their cytotoxic capability

In this study, we investigated the role of DR antigens in human mixed lymphocyte reactions (MLR) at the responder cell level. Upon stimulation by allogeneic lymphocytes or leukemic cell lines, a large proportion of T cells underwent blastogenesis and began expressing DR antigens. Analysis by a fluorescence-activated cell sorter revealed that both subpopulations of large activated T cell blasts and of small T lymphocytes became DR+ by synthesis and/or uptake. Depletion of DR+ responder cells from 6-day-old MLRs by treatment with anti-DR monoclonal antibodies (mAbs) plus complement (C) reduced but did not completely abrogate the natural killer (NK)-like activity of the responder lymphocytes, suggesting that the MLR-induced cytotoxic cells include both DR+ and Dr- populations. The expression of NK-like activity by the responder cells was also greatly reduced upon addition of anti-DR mAbs (without C) at the start of the mixed cultures. This effect was observed regardless of the presence of DR antigens on the stimulator cells, indicating that the anti-DR mAbs can interact with the antigens present on both the stimulator and responder populations. These data show that during an MLR, the continued presence of DR antigens on the responding population is essential for the expression and maintenance of the proliferative and cytotoxic capabilities of these cells.     

Requirement of Ia-positive accessory cells in the MLR response against class II antigen on human B cell tumor line

In this report we have made a comparative study of the capacity of normal human stimulator cells and Epstein-Barr virus-transformed human B cell line Wa (EBV-Wa) cells to stimulate alloreactive T cells. Class II antigen (presumably HLA-DR4 determinant) on EBV-Wa cells was shown to act as a stimulating molecule in the mixed lymphocyte reaction (MLR) through a blocking study by using anti-Ia antibodies. Furthermore, it was found that HLA-DR-positive accessory cells in the responder population were required to elicit MLR responses against HLA-DR antigen on EBV-Wa cells. In contrast, HLA-DR-positive accessory cells in the responding cell population were not essential for elicitation of MLR responses against HLA-DR antigen on normal allogeneic peripheral blood mononuclear cells, as reported. The cell-cell interaction between responder HLA-DR-positive accessory cells and responding T cells in a major histocompatibility complex (MHC)-restricted manner was required for eliciting MLR responses against class II antigen on EBV-Wa cells such as antigen-presenting cell-T cell interaction in soluble antigen-specific T cell proliferative responses. The function of HLA-DR-positive accessory cells in the responder population could not be substituted for by the presence of interleukin 1. Furthermore, there was no obvious correlation between the degree of surface HLA-DR antigen expression on EBV-Wa cells and its stimulating ability. Thus, two distinct types of allo-class II, antigen-specific T cell activation between normal human stimulator cells and EBV-Wa cells were shown to exist.     

Two distinct class II molecules encoded by the genes within HLA-DR subregion of HLA-Dw2 and Dw12 can act as stimulating and restriction molecules

By using two-dimensional polyacrylamide gel electrophoresis (2D-PAGE), we investigated the difference in the HLA class II molecule between HLA-Dw2 and Dw12, both of which are typed as HLA-DR2 serologically. The anti-HLA-DR framework monoclonal antibody (MoAb) HU-4 precipitated an alpha-chain and two beta-chains of human class II molecules from both Dw2 and Dw12 homozygous B lymphoblastoid cell lines. It was demonstrated clearly that an alpha-chain (alpha 1) and one of the beta-chains (beta 1) showed no difference in mobility in the 2D-PAGE between Dw2 and Dw12, but that another beta chain (beta 2) of Dw2 was distinct from that of Dw12 in the 2D-PAGE profile. Thus, MoAb HU-4 precipitated alpha 1 beta 1 and alpha 1 beta 2 molecules from Dw2 and Dw12, and the alpha 1 beta 1 molecule appears to be an HLA-DR2 molecule. The alpha 1 beta 2 molecule, on the other hand, is a class II molecule distinct from those precipitated with anti-DR2, anti-DQw1 (DC1, MB1, MT1), or anti-FA MoAbs. MoAb HU-4 completely inhibited the mixed lymphocyte culture reaction (MLR) between Dw2 and Dw12, but anti-DR2 MoAb HU-30, which reacts only with the alpha 1 beta 1 molecule, did not show an inhibitory effect on the MLR between Dw2 and Dw12. The alpha 1 beta 2 molecule is therefore the molecule which elicits MLR between Dw2 and Dw12. An IL 2-dependent T cell line established from an HLA-Dw12/D blank heterozygous high responder to the streptococcal cell wall antigen (SCW) clearly distinguished the Dw2 specificity from Dw12 specificity expressed on the antigen-presenting cell (APC). Moreover, MoAb HU-4 markedly inhibited the cooperation between the T cell line and APC to respond to SCW. These observations indicate that the alpha 1 beta 2 molecule is recognized as a restriction molecule by the T cell line at the antigen presentation of SCW through APC MoAb HU-30 on the other hand partially inhibited the MLR between Dw2 or Dw12 homozygous cell as a stimulator cell and non DR2 cell as a responder cell. It markedly inhibited the proliferative response of the Dw12/D- heterozygous T cell line to SCW, presented by Dw2+ but Dw12- allogeneic APC, and the peripheral response of Dw2 or Dw12 homozygous peripheral blood lymphocytes to SCW. Thus, two distinct class II molecules encoded by the genes within the HLA-DR subregion of HLA-Dw2 and Dw12 can act as stimulating molecules in the MLR and as restriction molecules in the antigen presentation by APC.     

Macromolecular insoluble cold globulin (MICG): a novel protein from mouse lymphocytes. III. Relationship to the mixed lymphocyte reaction and effect of anti-MICG antiserum in vivo.

In the present communication we have examined the relationship between the synthesis of macromolecular insoluble cold globulin (MICG) and the mixed lymphocyte reaction (MLR). In addition, we have studied in vivo the effect of antiserum to MICG on the antibody response to sheep red blood cells. The experiments indicate that MICG synthesis compared to either IgM or total protein is selectively stimulated in responder T cells exposed to allogeneic stimulator cells in the MLR. Furthermore, cytotoxicity studies utilizing anti-MICG antiserum demonstrated that T cells bearing MICG on their surface are an essential component of the responder cell population in the MLR. In vivo administration of antiserum to MICG significantly suppressed both the primary and secondary antibody response to sheep red blood cells. A possible mechanism for this suppression is discussed.     

Mouse T lymphocytes proliferative responses specific for human MHC products in mouse anti-human xenogeneic MLR

It has been reported that human T cells recognize the polymorphism of murine Ia antigens in the human anti-mouse xenogeneic mixed lymphocyte reactions (MLR). In this study, murine T cell recognition of human Class II antigens of the major histocompatibility complex (MHC) was analyzed in mouse anti-human xenogeneic MLR responses. The xenoreactive murine T cell proliferative response was blocked by adding anti-HLA-DR monoclonal antibody to the xenogeneic MLR culture. The specificity of xenoreactive murine T cells was examined with regard to the secondary and tertiary xenogeneic MLR system. The xenoreactive murine T cells were restimulated by distinct human stimulator cells that had no shared HLA antigens with the stimulator used in the primary MLR. The data presented here show that the murine xenoreactive T cells recognize the shared determinant(s) of HLA-DR antigen on non-T, non-B stimulator cells. The xenoreactive murine T cell proliferative responses were mediated by Thy-1+, Lyt-1+, and Lyt-2- cells. Furthermore, the xenoreactive T cell responses required Ia+ cells, and Ia antigen on accessory cells plays a crucial role in eliciting the xenoreactive responses against human stimulator cells, while Ia+ accessory cells in the responding cell population are not essential for the elicitation of allogeneic MLR responses, as reported previously.     

Differential inhibition of the MLR by iron: Association with HLA phenotype

The effect of iron on the MLR was examined by pretreating peripheral blood mononuclear cells from 77 unrelated Caucasians with five concentrations of Ferric-citrate (10.0 mM, 1.0 mM, 0.1 mM, 0.01 mM and 0.005 mM). After incubation with the metal, the cells were washed and cultured in a one-way MLR with a pool of stimulator cells. Cell viability remained unchanged (greater than 90 percent) during the 6-day culture period. Citrate per se had no effect on either the responder or the stimulator population. Iron treatment influenced the MLR in the following ways: (1) a variable degree of inhibition was observed which related to the dose of Ferric-citrate used and to HLA phenotype, (2) the responder but not the stimulator cells were affected, (3) no statistically significant differences were seen between female and male donor cells and (4) the mean percent response of cells from HLA-A2 donors were significantly (0.005 The present results indicate that iron can interact with lymphoid cells and influence some immunological functions in vitro. The possibility is discussed that similar interactions take place in vivo which could contribute to the prognosis of certain diseases associated with particular HLA phenotypes.     

Failure of (SJL/J x PL/J)F1 hybrid mice to develop immunologic tolerance to V beta 17a+ T cells results in F1 anti-SJL mixed lymphocyte reaction.

It has been reported previously that spleen cells from (SJL x PL) F1 hybrid mice are not tolerant to SJL parental cells as assessed by a one-way MLR. The possibility that the F1 anti-SJL reaction was due to the effect of lymphokines produced by the irradiated SJL T cells in response to I-Eu expressed on the F1 hybrid cells was eliminated since inclusion of anti-I-E mAb was without effect. Cell separations showed the responder cells to be plastic and nylon wool nonadherent Ia- T cells. Separation of the SJL spleen cells showed that the stimulator cells were nonadherent, passed through a nylon wool column, and were Ia-. the F1-anti-SJL MLR was blocked 70 to 90% by inclusion of mAb KJ23a in the culture medium that indicated that the stimulatory cell population was V beta 17a+ T cells. This was confirmed by the use of V beta 17a+ and V beta 17a-T cell clones as stimulators. To determine whether failure to develop tolerance to this T cell subset in F1 hybrid mice might be responsible for the F1-anti-parent MLR, (SJL x PL)F1 mice were treated at birth and 48 h thereafter with anti-I-E mAb for 7 wk. Spleen cells from antibody-treated F1 mice were nonreactive with irradiated SJL parental cells in contrast to spleen cells from control mice which indicated that V beta 17a+ T cells were eliminated by negative selection before the development of tolerance.     

Mixed lymphocyte reaction in mice genetically selected for high (Hi/PHA) or low (Lo/PHA) responsiveness to phytohemagglutinin.

Lymph node cells from Hi/PHA and Lo/PHA mice were evaluated for proliferative response after stimulation by allogeneic lymphocytes (MLR) originating from four inbred strains of different H-2 haplotype (C57B1/6, DBA/2, CBA, A). Reactivity to MLR and PHA were compared in these two lines and in the four inbred strains. The high and low responder status of Hi/PHA and Lo/PHA, as determined by T mitogens lymphocyte responsiveness, was also observed when one measured T responsiveness after MLR. Values obtained with the four inbred strains are included in the range of those measured in Hi/PHA and Lo/PHA cells when stimulated by PHA as well as by allogeneic cells. In contrast, when used as stimulator cells, Hi/PHA or Lo/PHA lymphocytes induce an equivalent proliferative response versus every responder inbred strain studied. These experiments support the hypothesis of a common genetic control of proliferative response following PHA or MLR stimulation. The genes implicated would be different from those coding for I region associated antigens.     

Role of individual chains of HLA-DR antigens in activation of T cells induced by alloantigens

The role of HLA-DR antigens in the activation of T cells in the allogeneic mixed lymphocyte reaction (MLR) was studied by using antibodies raised against the alpha, beta or the complex of both chains of the HLA-DR antigens. Antisera directed against the alpha or the beta chain strongly inhibited the T-cell proliferative response when added at the begining of MLR cultures but not 72 h later. T cells from MLR cultures treated with either alpha-chainor beta-chain-specific antibodies did not respond to interleukin-2 (IL-2) by proliferating, whereas T cells from non-anti-DR-treated cultures showed a proliferative response to IL-2 stimulation. However, neither the anti-alpha chain nor the anti-beta chain serum was able to inhibit continuous proliferation of already activated, IL-2-reactive T cells supported by IL-2. In MLR, OKT4⁺ but not OKT8⁺ lymphocytes synthesized IL-2. This function was abrogated by the alpha-chain-specific antibody but not by the anti-beta chain serum. Interleukin-1 (IL-1) did not reverse the inhibitory activity on IL-2 synthesis of the alpha-chain antibody, while IL-1 promoted the production of IL-2 in MLR cultures not exposed to the anti-DR sera. In addition, nonstimulated OKT4⁺ cells were unresponsive to IL-1 and did not produce IL-2. From these results, it is concluded that HLA-DR antigens participate actively in the activation of T cells by allogeneic non-T cells. Thus, both the alpha and beta chains of HLA-DR antigens render resting T cells sensitive to IL-2. In addition, the alpha but not the beta chain participates in the production of IL-2 by enabling OKT4⁺ lymphocytes to respond to IL-1 and subsequently to synthesize IL-2. Once T cells have acquired responsiveness to IL-2 and this growth factor has been produced there is no further requirement for HLA-DR antigens. Continuous proliferation and growth of IL-2-reactive T cells depends on the availability of interleukin-2.     

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.     

Suppression of mixed lymphocyte reactions by alloantigen-activated spleen-localizing thymocytes.

Heavily irradiated BALB/c and C57BL/6 mice were injected intravenously with BALB/c thymocytes. At varying times thereafter spleen and lymph node cell suspensions from these animals were treated with mitomycin C and added as regulator populations to mixed lymphocyte reactions (MLR) with syngeneic responder cells. Alloantigen-activated spleen-localizing thymocytes suppressed MLR responses 40 to 95%. Suppressor activitity, manifested as a quantitative reduction in peak proliferative responses, was maximal 4 days after cell transfer. Antigenic specificity for the stimulator cell strain in MLR was not demonstrated. The effect of lymph nodelocalizing thymocytes as regulators in MLR was variable, but in most experiments these cells slightly enhanced responses. We conclude that splenic localization is an intrinsic property of the thymocyte subpopulation capable of suppressing MLR responses, and that the suppressor activity of this subpopulation is substantially enhanced by activation in allogeneic hosts.     

Analysis of responder cell-cell interactions in the syngeneic mixed leukocyte response

In a previous study we identified the target antigens on stimulator cells in the murine syngeneic mixed leukocyte response (MLR) as self Ia molecules. The experiments reported here utilized analysis of log-log cell number-response titration slopes to study the responder T-cell population in the syngeneic MLR. The data indicated that in the peripheral lymphoid population at least two cell populations interact to produce a murine syngeneic MLR. One of these cell types appeared to be a member of an Lyt 2- subset, another a member of an Lyt 2+ subset. A potential third cell type, which was detected in the presence of (PMA)-induced EL4 supernatants, was found in the thymus, an organ that did not appear to contain either of the other two subsets. Experiments with adult thymectomized and neonatal mice suggested that the cell populations involved in the syngeneic MLR were mature T cells and were not an early differentiation state of T lymphocytes whose ability to be stimulated by Ia antigens alone was a transient event.     

Effect of L-ornithine on proliferative and cytotoxic T-cell responses in allogeneic and syngeneic mixed leukocyte cultures

The effect of L-ornithine on cytotoxic and proliferative responses in mixed leukocyte cultures has been analyzed. The activation of cytotoxic T lymphocytes (CTL) was strongly inhibited when 9 X 10(-3) M L-ornithine was added at the initiation of the cultures. The CTL precursor cells were not completely and irreversibly inactivated, however, since the cells generated normal cytotoxic activity if resuspended after 6 days in fresh culture medium together with a fresh set of stimulator cells. Experiments in microcultures with nylon-wool-nonadherent T-cell-enriched spleen cells as responder cells and "plastic adherent cells" as stimulator cells revealed that the cytotoxic responses were almost completely suppressed if ornithine was added within the first 20 hr but were only partially suppressed if ornithine was added after 48 hr. Also, ornithine had only a mild suppressive effect on proliferative responses in allogeneic and syngeneic mixed leukocyte cultures. The strong suppressive effect of the cytotoxic response was therefore not explained by a general toxic effect of L-ornithine on the responding cells in the culture. The addition of interleukin 2 (IL-2)-containing EL-4 supernatants did not prevent but rather enhanced the suppressive effect of L-ornithine. This indicated that the inhibitory effect was not (exclusively) expressed at the level of the IL-2-producing helper T cells. Since activated macrophages have been reported to secrete arginase, it appears that L-ornithine may be part of a regulatory circuit that selectively regulates the development of cytotoxic effector T cells.     

The syngeneic mixed leukocyte reaction: the genetic requirements for the recognition of self resemble the requirements for the recognition of antigen in association with self

We have used cells from inbred strain 2 and strain 13 guinea pigs in order to define further the role of Ia antigens in the syngeneic mixed leukocyte reaction (MLR). The guinea pig syngeneic MLR resembled the autologous MLR in man in that it demonstrated both memory and specificity. The Ia antigens appeared to be the proliferative stimuli in that the primary stimulator cell was an Ia-positive adherent peritoneal exudate cell (PEC) and the reaction could be specifically inhibited by anti-Ia sera directed to the stimulator cell. We also demonstrated the existence of two (2 x 13)F1 T cell populations that were capable of reacting to one or the other parental PEC in the absence of any known exogenous antigen. These results suggest that the syngeneic MLR may represent T cell activation mediated through a receptor for self Ia.     

In vitro secondary MLR. I. Kinetics of proliferation and specificity of in vitro primed responder cells.

We have examined the kinetics and specificity of secondary in vitro mixed lymphocyte reactions (MLR). With limited numbers of primed responder cells (PRC) in the presence of "excess antigen" it was possible to obtain proliferative responses that were proportional to the number of PRC initially placed in culture. The responding cells, after an initial lag period, seem to grow exponentially until day 3 of culture. The responses of PRC (with the strain combinations and culture conditions described in this report) seemed to be directed toward stimulator cell determinants whose expression was determined by genes in the I region of the MHC. In one case, the relevant incompatibilities could be further restricted to the I-A region. Although PRC responded best to stimulator cells sharing the I region with the priming stimulator cell, apparent cross-reactivity could be observed by restimulating PRC with stimulator cells that did not carry the MHC haplotype of the priming stimulator cell. The rate of proliferation (measured as 3H-thymidine incorporation) in these apparent cross-reactions was reproducible and comparable to the rate observed in response to the priming stimulator cell. It was possible, therefore, to estimate the proportion of PRC that reacted in the presence of third party stimulator cells compared to the response of these PRC to the priming stimulator cells. We have estimated that the response of A (B6) PRC against H-2d and H-2s haplotype stimulator cells is about half of the response of these PRC to H-2b, the priming stimulator cell.     

Dual parameter flow cytometric analysis of DNA content, activation antigen expression, and T cell subset proliferation in the human mixed lymphocyte reaction

This study provides direct correlation via dual parameter flow cytometry (simultaneous assessment of immunofluorescence and DNA content) between mixed lymphocyte reaction (MLR) responder cell entry into the S/G2/M phases of the cell cycle with the kinetics of expression of two activation-associated cell surface proteins, Tac (IL 2 receptor) and 4F2 (unknown metabolic function). A small population of activated cells was identifiable by expression of both Tac and 4F2 antigens before peak DNA synthesis in the MLR. This population of activation antigen-positive cells expanded linearly in size from days 3 to 7 of culture. Treatment of immature MLR cultures with anti-4F2 Mab and complement (C) before DNA synthesis (treatment on day 3, peak DNA synthesis on days 5 to 6) resulted in blunted proliferation and activation antigen expression when the same culture was analyzed after maturation on day 6, indicating that the activated population had been previously detected and removed by anti-4F2 Mab + C. The 4F2 antigen was expressed on a greater percentage of cells in the MLR at all times (days 3 to 9) than was Tac, was present on virtually all S/G2/M phase responder cells, and a large fraction of cells remained intensely 4F2+ subsequent to peak DNA synthesis. In contrast, after initially preceding responder cell entry into the S phase of the cell cycle, the kinetics of Tac antigen expression closely paralleled the kinetics of responder cell proliferation. A subpopulation of cycling responder cells was noted in all MLR cultures studied that expressed Tac antigen weakly or not at all. Cells within both T4 and T8 cell subsets proliferate with similar kinetics in response to alloantigen. The possibility that activation antigens can be utilized to study effector cell generation in the MLR and that this flow cytometric technique may be utilized to analyze the response to various alloantigens is discussed.