T cell recognition in the mixed lymphocyte response. II. Ia-positive splenic adherent cells are required for non-I region-induced stimulation

Ia-positive splenic adherent cells (SAC) have been shown to be the predominant stimulators of a mixed lymphocyte response (MLR) to whole H-2 differences, in which most of the proliferative response is directed against I region-encoded determinants. The present studies were undertaken to examine the ability of several purified lymphoid subpopulations to activate T cells in response to the non-H-2-linked MIs products or to products of the K or D regions of H-2. The results demonstrated that adherent cell-depleted populations of T and B cells were nonstimulatory, whereas SAC were potent stimulators for responses involving each of these genetic differences. Treatment of these SAC with anti-Ia and C abrogated their MLR-stimulating ability. In contrast, whereas treatment of SAC with anti-Ia and C abrogated their ability to stimulate an MLR directed against K or D region-encoded determinants, this treatment had no effect on their ability to generate a cytotoxic T lymphocyte response against these same determinants. These findings suggest that in addition to presenting allogeneic I region-encoded determinants, Ia-positive SAC also play a unique role in the presentation of non-I region-encoded alloantigens to proliferating T cells.     

Immunomodulating activity of p-hydroxyphenyllactic and ascorbic acids

p-Hydroxyphenyl lactic acid (PHA) in a concentration of 5 . 10(-5) M produced a significant inhibition of cell proliferation in response to alloantigens in a one-way mixed lymphocyte culture (MLC) in colonic cancer patients and in blast transformation in response to suboptimal doses of Con A. Multiple administration of ascorbic acid in an optimal concentration to the culture increased the proliferative response of lymphocytes to alloantigens and Con A. PHA and ascorbic acid did not exhibit any immunomodulating action during the use of healthy donors' lymphocytes or lymphocytes from colonic cancer patients, transformed with optimal mitogen doses. PHA did not affect the production of cytotoxic T lymphocytes in the MLC of the spleens of allogeneic mice but inhibited lymphocyte proliferation in response to alloantigens in the MLC of the spleens obtained from B6 and vitamin A deficient animals.     

Sex-associated differences in the regulation of immune responses controlled by the MHC of the mouse

The immunologic potential of T lymphocytes and antigen-presenting cells (APC) from male and female mice were compared. Lymphocytes from female mice or from male mice that cannot produce and respond to testosterone (Tfm/y) were more reactive than male lymphocytes to alloantigens in MLR. Spleen cells from Tfm/y mice equipped with estrogen implants showed a higher responsiveness than control Tfm/y to alloantigens. The removal of suppressive adherent cells or the addition of T cell growth factor (TCGF) enhanced the proliferative activity of the cells in the MLR. The responsiveness of female cells to alloantigens, however, remained superior to that observed in male cells. Similarly, in the presence of TCGF, thymocytes from female mice react more effectively than male cells in MLR. In addition, Con A-stimulated spleen cells from female mice produce more interleukin 2 (IL 2) than do spleen cells from males or female mice treated with testosterone. Lymphocytes from immunized mice were tested for their ability to respond to soluble antigens (KLH and OVA) in vitro. Again, female immunocompetent cells respond more vigorously than male cells or cells originating in female mice with testosterone implants. APC from female spleen were more efficient than male APC in initiating a secondary response in primed lymphocytes from either males or female mice. Moreover, castration of male mice enhanced, and treatment of female mice with androgen reduced, the efficiency of antigen presentation. In conclusion, these data suggest that female cells are superior to male cells in immunologic functions that are known to be associated with reactions to and recognition of histocompatibility antigens, i.e., antigen presentation and MLR. Furthermore, our present data indicate that the differential reactivity of immunocytes between male and female mice depends on the hormonal balance of the animal.     

Mouse model for analysis of non-MHC genes that influence allogeneic response: recombinant congenic strains of OcB/Dem series that carry identical H2 locus

Alloreactivity is the strongest known primary immune response. Its clinical manifestations are graft rejection, graft-versus-host disease and graft-versus-leukemia effect. The strongest stimulation by allogeneic cells is due to incompatibility at the major histocompatibility complex (MHC) genes. However, the non-MHC genes also participate in allogeneic response. Here we present a mouse model for study of the role of non-MHC genes in regulation of alloreactivity and show that they besides encoding antigens also regulate the responsiveness. Recombinant congenic strains (RCS) of O20/A (O20)-c-B10.O20/Dem (OcB/Dem) series have been derived from the parental strains O20 and B10.O20, which carry identical MHC haplotypes (H2^pz) and therefore their differences in alloantigen response depend only on non-MHC genes. We have tested a MLR response by spleen cells of the strains O20, B10.O20, and 16 OcB/Dem strains through stimulation by cells from strains C57BL/10 (H2^b), BALB/c (H2^d), CBA (H2^k), and DBA/1 (H2^q) alloantigens. Proliferative response of O20, B10.O20 and OcB/Dem strains to these four alloantigens exhibited a similar but not completely identical pattern of reactivity. The responses to different alloantigens were highly correlated: C57BL/10-BALB/c r = 0.87, C57BL/10-CBA r = 0.84, C57BL/10-DBA/1 r = 0.83. Cluster analysis of the responses by O20, B10.O20, and OcB mice identified groups of strains with distinct patterns of response. This data shows that two main types of genes influence MLR: 1. structural genes for major and minor alloantigens and 2. genes regulating T-cell receptor signal transduction or mediating costimulatory signals by antigen-presenting cells.     

The abrogation of allosensitization following the induction of mixed allogeneic chimerism

The association of preformed anti-donor Abs with the hyperacute rejection of bone marrow and solid organ allografts and the persistence of the anti-donor immune response secondary to immunologic memory make allosensitization an absolute contraindication to transplantation. Mixed allogeneic (A + B-->A) bone marrow chimerism has been demonstrated to confer donor-specific tolerance in nonsensitized recipients, but has not been evaluated in the setting of allosensitization. The current study documents that despite significant anti-donor sensitization, mixed allogeneic engraftment is possible and provides a marked advantage over fully allogeneic (B-->A) models. Moreover, the acceptance of donor skin grafts and loss of circulating anti-donor Abs suggest that allosensitization can be abrogated with the induction of stable mixed allogeneic chimerism.     

Generation of Human Alloantigen-specific T Cells from Peripheral Blood

The study of human T lymphocyte biology often involves examination of responses to activating ligands. T cells recognize and respond to processed peptide antigens presented by MHC (human ortholog HLA) molecules through the T cell receptor (TCR) in a highly sensitive and specific manner. While the primary function of T cells is to mediate protective immune responses to foreign antigens presented by self-MHC, T cells respond robustly to antigenic differences in allogeneic tissues. T cell responses to alloantigens can be described as either direct or indirect alloreactivity. In alloreactivity, the T cell responds through highly specific recognition of both the presented peptide and the MHC molecule. The robust oligoclonal response of T cells to allogeneic stimulation reflects the large number of potentially stimulatory alloantigens present in allogeneic tissues. While the breadth of alloreactive T cell responses is an important factor in initiating and mediating the pathology associated with biologically-relevant alloreactive responses such as graft versus host disease and allograft rejection, it can preclude analysis of T cell responses to allogeneic ligands. To this end, this protocol describes a method for generating alloreactive T cells from naive human peripheral blood leukocytes (PBL) that respond to known peptide-MHC (pMHC) alloantigens. The protocol applies pMHC multimer labeling, magnetic bead enrichment and flow cytometry to single cell in vitro culture methods for the generation of alloantigen-specific T cell clones. This enables studies of the biochemistry and function of T cells responding to allogeneic stimulation.     

The effect of a high external temperature on cellular immunity]

The study was made of spleen cells proliferative response to mitogens PHA, Con A or alloantigens in relation to hyperthermia effects. Acute hyperthermia (rectal temperature 42 degrees) enhanced lymphocyte function, proliferative responses to allo-antigens, PHA and Con A increased. Thermal shock was associated with suppression of the spleen cell response. Mice suffering from hyperthermia for 20 min (43-44 degrees) daily during 10, 20 and 30 days showed suppressed T-cell immune response. Normal splenocyte proliferation recovered 40 days after hyperthermia induction.     

Tolerance induction of alloreactivity by portal venous inoculation with allogeneic cells followed by the injection of cyclophosphamide. II. Cellular and molecular mechanisms underlying tolerance

BALB/c mice receiving allogeneic C3H/He or C57BL/6 spleen cells via portal venous (p.v.) route or a single administration of cyclophosphamide (Cy) were capable of rejecting the respective allogeneic C3H/He- or C57BL/6-derived tumor cells. In contrast, the combined treatment of p.v. inoculation with allogeneic lymphocytes and Cy administration abrogated the capability of rejecting allogeneic tumor cells. Such abrogation of alloreactivity was alloantigen-specific and associated with the suppression of potentials to generate delayed-type hypersensitivity (DTH) and cytotoxic T lymphocyte (CTL) responses to alloantigens. This was further substantiated by the inhibition of molecular mechanisms underlying anti-allo-DTH and -CTL responses. Thus, the above combined treatment led to the decreased production of lymphokines such as macrophage-activating factor (MAF) and interleukin 2 (IL2) following the stimulation with the relevant alloantigens. These results demonstrate that p.v. inoculation of allogeneic cells followed by a single administration of Cy results in the effective elimination of alloreactivity as verified by the suppression of cellular and molecular mechanisms of alloreactive responses.     

Evidence that Con A induces cytotoxicity in the same subclass of T cells as does alloimmunization.

We have studied the induction of cytoxic activity in murine T cells by the T cell mitogen Con A. Here we report the results of experiments that indicate that this cytotoxicity develops in the same class of T cells potentially activatable to cytotoxicity by immunization with allogeneic cells. Cytotoxic activity does not result from activation of cells of the T-helper class by PHA, and extensive reduction of the proportion of cells of the T-helper class by in vivo treatment with ATS does not comparably reduce the cytotoxicity developed in response to Con A. The Con A-activated cytotoxic cell sediments as a large cell. Furthermore, spleen cell populations previously immunized to alloantigens in vivo develop greatly increased cytotoxicity specific for the alloantigen of the immunizing haplotype after culture with Con A in vitro.     

Monocyte-derived human macrophages mediate anergy in allogeneic T cells and induce regulatory T cells

Activation of alloreactive T cells by APCs such as dendritic cells (DC) has been implicated as crucial step in transplant rejection. In contrast, it has been proposed that macrophages (Mphi) maintain tolerance toward alloantigens. It was therefore the aim of this study to further analyze the T cell-stimulatory capacity of mature DC and Mphi in vitro using the model of allogeneic MLR. There was a strong proliferative response in T cells cocultured with DC, which was further increased upon restimulation in a secondary MLR. In contrast, T cells did not proliferate in cocultures with Mphi despite costimulation with anti-CD28 and IL-2. Cytokine analysis revealed considerable levels of IL-10 in cocultures of T cells with Mphi, whereas high amounts of IL-2 and IFN-gamma were present in cocultures with DC. There was only minimal T cell proliferation in a secondary MLR when T cells were rescued from primary MLR with Mphi and restimulated with DC of the same donor, or DC of an unrelated donor (third party), whereas a strong primary proliferative response was observed in resting T cells, demonstrating induction of T cell anergy by Mphi. Functional analysis of T cells rescued from cocultures with Mphi demonstrated that anergy was at least partly mediated by IL-10-producing regulatory T cells induced by Mphi. These results demonstrate that Mphi drive the differentiation of regulatory T cells and mediate anergy in allogeneic T cells, supporting the concept that Mphi maintain peripheral tolerance in vivo.     

Suppressive effects of cyclosporin A on the induction of alloreactivity in vitro and in vivo

The purpose of the present study was the investigation of the effect of cyclosporin A (CsA) on the induction of alloreactivity in vitro and in vivo. Addition of CsA to mouse mixed lymphocyte cultures (MLC) not only inhibited lymphocyte proliferation but also prevented the generation of alloreactive cytolytic lymphocytes (CL). It was necessary to add CsA within the first 3 days of a 5-day MLC in order to achieve a significant suppressive effect. Lymphocytes, after being cultured in MLC with CsA for 4 days or longer, were incapable of being activated upon re-exposure to the same alloantigens although their responses to unrelated antigens remained intact, indicating antigen specificity of the suppression induced by CsA and its long-lasting effect. Furthermore, lymphocytes from mice treated with CsA after allosensitization failed to manifest primary cytotoxicity and could not be reactivated in a secondary MLC. Finally, CsA had no effect on those CL already generated, suggesting that CsA acts upon the induction of CL rather than the effector phase.     

Antibody-mediated immunosuppression of a cytotoxic cell response not involving a simple antigen-masking mechanism.

An in vitro cytotoxic cell response against alloantigens was inhibited by antibody directed against the alloantigens and also by anti-trinitrophenyl antibody provided that the allogeneic stimulator cells were modified with trinitrophenyl. Inhibition of an anti-allogeneic cytotoxic cell response against trinitrophenyl-coupled allogeneic stimulator cells by anti-trinitrophenyl antibody is dependent upon the intact Fc portion of inhibitory antibody. The magnitude of the difference between intact and F(ab')2 anti-trinitrophenyl antibody in immunosuppressive activity suggests that the Fc portion emits negative signals rather than simply adding to a steric hindrance effect.     

Induction of T cell activity in athymic (nu/nu) mice infected with Trypanosoma rhodesiense

Infection of C57BL/10 (B10)3 nu/nu mice with Trypanosoma rhodesiense results in the development of significant T-cell reactivity in spleen and lymph nodes. The proliferative responses to mitogens, such as concanavalin A (Con A) and phytohemagglutinin (PHA), and in mixed-lymphocyte reactions (MLR) to alloantigens are enhanced compared with control uninfected nu/nu mice. These results serve to emphasize the stimulatory nature of trypanosomes on the immune system.     

Cell-mediated immunity to male-strain histocompatibility alloantigens detected after natural insemination and systemic immunization in the female mouse using the cell-mediated microcytotoxicity test

Female cell-mediated immunity to allogeneic spermatozoa after repeated natural insemination, in the absence of pregnancy, was compared with that after systemic challenge using the cell-mediated microcytotoxicity test to measure cytotoxic cell alloreactivity. After multiple (3-6) inseminations the majority of females (11 out of 13) showed a significant degree of lymphocytotoxicity to male-strain histocompatibility alloantigens in the para-aortic lymph nodes, and to a lesser extent in the spleens, while a single insemination was usually not sufficient to evoke a specific cytotoxic cell response. This differed from the low and highly variable degree of female sensitization after multiple systemic challenge with allogeneic spermatozoa via the intraperitoneal route. By contrast, a single systemic challenge via the footpad proved to be the most highly consistent and effective route for eliciting cell-mediated immunity to male-strain histocompatibility alloantigens in all 9 female mice. This alloreactivity appeared to be directed at alloantigens other than the male-specific H-Y antigen. These findings show that the precise route of immunization is a major factor in the development of female cell-mediated immune responsiveness to allogeneic spermatozoa.     

Functional analysis of cloned macrophage hybridomas. IV. Induction and inhibition of mixed lymphocyte responses

A series of macrophage (M phi) hybridomas were generated by fusion of drug-marked P388D1 (H-2d) tumor cells with CKB (H-2k) splenic adherent cells. The ability of this panel of cloned M phi hybridomas expressing various levels of surface Ia antigens to induce allogeneic mixed lymphocytes responses (MLR) was examined. All MLR stimulatory M phi hybridomas expressed surface Ia antigens. However, some Ia+ and all Ia- M phi hybridomas were unable to induce vigorous MLR responses. Furthermore, even after induction of surface Ia antigen expression with Con A supernatants (Con A Sn) or purified interferon-gamma, the nonstimulatory M phi hybridomas remained ineffective at inducing strong MLR proliferative responses. Furthermore, addition of the latter M phi hybridoma clones (both with and without Con A Sn treatment) to conventional MLR cultures resulted in inhibition of MLR responses. The series of inhibitory M phi hybridomas secreted normal levels of IL 1 upon stimulation with lipopolysaccharide. After surface Ia induction with Con A Sn, the inhibitory M phi hybridomas could stimulate secretion of IL 2 and expression of IL 2 receptors. Moreover, although they inhibited conventional MLR responses, IL 2 production and IL 2 receptor expression were not significantly inhibited. Addition of these M phi hybridomas 24 to 48 hr after initiation of MLR response also inhibited MLR proliferation. The results indicated that the group of inhibitory M phi hybridomas can inhibit MLR responses after IL 2 secretion and acquisition of IL 2 receptors. Finally, this inhibitory activity has been maintained during 1 yr of continuous in vitro culture, and the hybridomas represent a stable "homogeneous" subpopulation of inhibitory macrophages. Thus, the inhibitory phenotype appears to reflect arrest at a distinct differentiation stage.     

Restoration of T-cell function in nude mice by grafting the epitheliomesenchymal thymic rudiment from 10-day-old euthymic embryos

The capacity of the uncolonized thymic epithelium to restore immune function in nude mice was demonstrated by grafting the 3rd branchial arch area taken from euthymic 10-day BALB/c embryos into syngeneic newborn nude mice. Twenty-six percent of the operated animals became immunocompetent. T-cell function was tested with skin grafts and the presence of high levels of Thy-1 positive cells plus a variety of in vitro culture assays: Con A stimulation of T lymphocytes, cytotoxicity and alloreactivity in MLR of the recipient toward allogeneic spleen cells. All these tests showed a pattern of response similar to normal euthymic BALB/c mice.     

Suppressor T cell recognition of major and minor histocompatibility alloantigens: selected suppression of MHC-directed responses by minor alloantigen Ts

The induction of suppression by i.v. administered alloantigens in the murine host was analyzed as a model of the possible effects of blood transfusion on transplant survival. The results indicated that suppressor T cells (Ts) specific for minor histocompatibility alloantigens could be readily induced by the i.v. presentation of minor alloantigen-disparate spleen cells. In contrast, similar priming with cells differing solely at the H-2 major histocompatibility complex stimulated only positive T cell immunity, with no evidence of suppression. The induction of H-2 directed Ts activity could be accomplished only by i.v. priming with major plus minor incompatible donor cells, suggesting that suppressor cell recognition of minor alloantigens may have facilitated the generation of Ts against H-2-encoded major transplantation antigens. A role for minor histocompatibility antigens in the regulation of H-2-specific immunity at the effector level was also indicated. Ts induced by i.v. pretreatment with minor antigen-disparate donor cells not only suppressed the delayed-type hypersensitivity (DTH) response to the relevant minor alloantigens, but also inhibited DTH against unrelated H-2 alloantigens introduced during subsequent intradermal immunization. Suppression of H-2-directed T cell reactivity was specific in that the presence of the Ts-inducing minor alloantigens was also required and occurred only when the minor and unrelated major alloantigens were presented within the same inoculum, if not on the same cell surface. The capacity of Lyt-2+Ts or Ts-derived suppressive factors specific for one set of cell surface molecules to modulate responses to an unrelated group of surface antigens does not appear to represent a general phenomenon, because similar suppression of immunity to unrelated tumor-specific transplantation antigens by minor-specific Ts was not observed. These results are discussed with respect to the possible mechanism of H-2-directed suppression and the role of the I region in Ts recognition of antigen.     

Augmentation of generation of human allospecific cytotoxic T lymphocyte by PPD in in vitro sensitization culture

Summary PPD augmented human lymphocyte blastogeneic response to allogeneic lymphocytes in the mixed lymphocyte reaction (MLR) and generation of human cytotoxic lymphocytes against allogeneic human lymphocytes in in vitro sensitization (IVS) culture. The augmenting effect of PPD in the MLR was unequivocally synergistic at its lower concentrations (0.05 and 0.01 g/ml). The augmentation of MLR was observed following addition of a supernatant of culture medium of lymphocytes which had been precultured with PPD for 24 h then washed free of PPD and recultured without PPD for another 24 h. PHA and Con A, in contrast, suppressed both MLR and the generation of alloreative cytotoxic cells. The alloreactive cytotoxic lymphocytes whose generation was augmented by PPD belonged to the SRBC-rosette forming fraction and passed through a nylon-wool column. The NK cell-like activities of the alloreactive cytotoxic lymphocytes were not augmented by PPD. Analysis of the alloreactive cytotoxic lymphocytes whose generation was augmented by PPD by competitive inhibition assay with unlabeled cells indicated that the same allogeneic lymphocytes used as sensitizing cells in IVS culture inhibited the cytotoxicity, while MOLT-4 cells, which are frequently used as target cells for the human NK-cell assay, did not. When lymphocytes with known HLA-A and HLA-B were used in the IVS culture and the cytotoxicity assay, PPD was found to augment the cytotoxicity only against the target lymphocytes that possessed the same HLA as the sensitizing lymphocytes in IVS.     

Existence of T cells manifesting self-reactivity indistinguishable from alloreactivity

The studies reported here were designed to analyze the phenotypic characteristics of self-reactive T lymphocytes induced in culture by allogeneic effect factor (AEF), as well as the control of their functional activities by the major histocompatibility complex (MHC). Unprimed T cells cultured with AEF in the absence of exogenous stimulating target cells become activated against self-antigens, as evidenced by their ability to manifest two distinct activities. First, such cells could lyse syngeneic target cells. This cytolytic activity was directed against H-2K antigens and was mediated by Lyt-2+ T cells. Second, the AEF-activated T cells could be stimulated in a secondary culture to high levels of proliferative activity by irradiated syngeneic spleen cells. The stimulator cells in this syngeneic mixed lymphocyte reaction (MLR) were found to be Thy-1-negative, Ia-positive splenic adherent cells. Stimulation in the secondary syngeneic MLR was provided by I-region specificities, and the majority of the proliferating cells were Lyt-1+ cells. Finally, AEF-induced T cells were effective in serving as effectors of graft-vs-host reactions in vivo in syngeneic recipients. These results prove that, under appropriate conditions, murine T lymphocytes can display aggressive patterns of self-reactivity that are similar in both quantity and quality to the classical patterns of alloreactivity and may have great significance for our understanding of MHC recognition processes.     

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.