Control by major histocompatibility complex genes of macrophage interaction with thymocytes during induction of T-effectors of graft vs host reaction. I. Genetic control on the cellular level

H-2 complex control of interaction between macrophages and thymocytes during induction of T-cell effectors GVH was studied. Intensity of the local GVH reaction was evaluated by the index of the lymph nodes enlargement. Genes of the H-2 system control interaction of macrophages with thymocytes during the formation of T-cell effectors GVH. H-2K subregion genes identity of interacting cells was necessary and sufficient for the effective induction of T-effectors GVH. I and D region differences did not affect the formation of T-cells inducing GVH.     

The role of major histocompatibility complex genes in the reaction of macrophages and thymocytes during induction of T-effectors of the graft vs host reaction. III. Effect of antisera against H-2 complex antigens on the realization of the process

The data are presented on the influence of antisera to different products of the histocompatibility gene complex on the interaction between macrophages and thymocytes during the formation of T-cell GVH effectors. The intensity of the local GVH reaction was evaluated by the index of the lymph nodes enlargement. The close physical contact between cells was necessary for the induction of T-effectors GVH. Treatment of macrophages or thymocytes with anti-H-2 and anti-H-2K antibodies, prior to the beginning of combined incubation, or addition of these antisera to the cultural media suppressed the formation of T-cell inducing GVH. Anti-H-2 I and anti-H-2 D sera did not affect the formation of GVH T-effectors.     

Macrophages and the functional differentiation of thymocytes (a review of the authors' own data)

Cellular, humoral, and genetic mechanisms of induction of T-effectors of the transplant vs. host reaction (THR) have been studied in two-cell culture of phagocyte mononuclears and thymocytes. A direct physical contact and similarity of H-2K locus of major histocompatibility complex between the cooperating cells in culture is required for successful induction of T-effectors of THR. Contact interaction of macrophages with thymocytes leads to accumulation of a 67 KDa humoral factor in the culture medium. Incubation of intact thymocytes with this factor leads to functional transformation of immature thymocytes into corresponding effector cells. Similarity of H-2K locus of the factor producers and intact lymphocytes is also required for successful humoral induction of the T-effectors. The surface H-2K antigen is able to induce formation of THR t-effectors from non-reactive thymocytes. The H2-K-specific mediator, affinity-isolated from the supernatant of the macrophage-thymocyte culture can also cause this induction.     

Functional differentiation of thymocytes induced by macrophages: cellular, humoral and genetic aspects

The cellular, humoral and genetical mechanisms of induction of T-effectors of the graft vs. host reaction (GHR) were studied in a double-cell culture of phagocytizing mononuclears with thymocytes. Experiments were carried out on mice of inbred and recombinant strains. The GHR intensity was estimated by the increase in the number of cells in the popliteal lymph node, regional with reference to the introduction of parental thymocytes into the F1 hybrid. For the induction of the GHR T-effectors from the immature population of thymocytes to be realized, a direct physical contact and identity by the H-2K locus of the major histocompatibility complex between the cooperating cells in culture are indispensable. An antiserum containing antibodies against the H-2K locus products prevents the induction. At the same time antibodies against antigens controlled by loci of I-region or the H-2D locus do not affect the accumulation of T-effectors. Contact interaction of phagocytizing mononuclears with thymocytes results in accumulation of a 65,000 D humoral factor in the culture medium. Incubation of the intact thymocytes with this factor ensures functional transformation of immature thymocytes to corresponding effector cells. For the humoral induction of T-effectors to be successfully realized, identity by the T-2K locus between the factor producents and intact thymocytes is indispensable, as well as in the conditions of direct intercellular interaction. It is suggested that H-2K specificity is incorporated into the factor structure.     

Changes in the expression of the surface antigens of thymocytes during their cultivation with macrophages

The data on changes in expression of H-2 complex and Thy-1 antigens on cell surface of thymocytes resulting from their incubation with peritoneal macrophages has been presented. The process of joint cultivation of thymocytes with macrophages leads to significant decrease in number of cells with Thy-2-antigen and increase in that with H-2 complex antigens. An increase in H-2K+ cells in experimental thymocytes as compared to control ones was observed. No changes in H-2D expression was observed. A significant increase in Ia+ macrophages was observed after interaction with thymocytes as compared with intact mononuclear phagocytes.     

Immunogenetic analysis of H-2 mutations. III. Genetic mapping and involvement in immune reactions of the H-2ka mutation.

Mutation M523 (H-2ka) occurred spontaneously in strain CBA/CaLacSto and was discovered during routine skin graft testing for genetic homogeneity. By linkage and complementation tests, the mutation was previously mapped in the K end of the H-2 complex. We demonstrate that the mutation occurred in the K region, without affecting the I region in the K end of the complex. The mutant antigens cause rejection of skin grafts, stimulate cells in mixed lymphocyte culture, and function as stimulators as well as targets in cell-mediated lymphocytotoxicity. Yet, they are serologically indistinguishable from the antigens of the original strain and do not induce formation of humoral antibodies upon immunization of the CBA strain. Together with the results obtained on testing of other H-2 mutants, the data strongly support the notion that classical H-2 antigens (i.e., products of the H-2K and H-2D loci) can function as lymphocyte-stimulating determinants, and that I-region differences are not required for the induction of strong cell-mediated lymphocytotoxicity.     

Neonatal infection with mouse thymic virus. Differential effects on T cells mediating the graft-versus-host reaction.

Neonatal infection with mouse thymic virus (TA), a murine herpes virus, produced extensive but temporary necrosis of the thymus which was maximal at 10 to 14 days of age. Studies of precursor and amplifier cells mediating graft-vs-host (GVH) reactivity of thymocytes, spleen cells (SC), and lymph node cells (LNC) of normal and TA-infected mice were made at 4 and 8 weeks of age. Infection with TA resulting in a profound reduction (70 to 80%) in the direct GVH reactivity of thymocytes at both ages; by comparison, the capacity of thymocytes to produce synergy when combined with normal LNC was normal at 8 weeks. Direct GVH reactivity of SC was depressed 90% 4 weeks after infection with TA but returned to near normal at 8 weeks. Direct GVH reactivity of LNC from TA-infected mice was normal at 4 and 8 weeks of age, but amplifier T cell activity in LNC was markedly depressed at 8 wekks. These results demonstrate that TA has highly selective effects upon subpopulations of T cells in thymus and lymph node.     

Antigen-specific helper T cells recognize determinants encoded in the H-2D region of the H-2 gene complex

Observations have frequently been interpreted as showing that the helper T cells which collaborate with alloantigen-specific cytotoxic T-cell precursors can only recognize antigens encoded in the I region of the H-2 gene complex. An experimental system is described here that allows analysis of the recognition repertoire of these helper cells. CBA helper T-cell precursors can be primed in vitro to antigens encoded in the H-2 ^b gene complex. These helpers can then be tested for the existence of a subset of helper cells which recognize antigens encoded in the D region of H-2 ^b haplotype. CBA thymocytes were used as a source of cytotoxic T-cell precursors that respond poorly in the absence of exogeneous helper activity. The source of alloantigen was varied by using irradiated spleen cells from various (BALB/c × recombinant)F₁ hybrid mice as stimulator cells. When the stimulator cell bears BALB/c determinants recognized by the cytotoxic T-cell precursor and also bears only the D region antigens of the H-2 ^b haplotype, an anti-BALB/c cytotoxic response is generated only if the anti-H-2^b helper population contains cells able to recognize H-2D^b. A positive cytotoxic response was obtained, indicating that helper cells are not limited to recognition of I region antigens and can efficiently recognize antigens encoded in the D region of the H-2 gene complex. This was confirmed by the demonstration of helpers specific for H-2D^d. We were unable to detect any evidence for Ia-restricted recognition of the H-2D alloantigens, suggesting that, as for cytotoxic T lymphocytes (CTL), helper cell recognition of class I alloantigens is an unrestricted event.     

Synergistic interactions between lymph node and thymus cells in response to antigenic differences limited to selected regions of the H-2 complex.

Thymus and lymph nodes from the A.TL recombinant line were utilized as sources of responding cells in MLR (mixed lymphocyte response) assays to MHC-determined (major histocompatibility complex) antigenic differences. Cells from both sources were stimulated to proliferate by antigenic determinants controlled by the H-2K region alone, H-2D region and the H-2I-H-2S regions. Nylon-fiber-adherent splenic cells from each of the stimulating cell strains stimulated T-cell-dependent responses. Synergistic interactions between A.TL thymus and lymph node cells were initiated by antigenic products limited to single H-2 regions. Antigenic differences determined within the H-2I region were not required for synergistic responses to H-2K-controlled products or for the generation of cytotoxic killer cells to H-2D-associated antigens. The H-2I-region-associated products also were very effective in stimulating T-cell synergy. These data demonstrate that the two responsive T-cell subpopulations can both be stimulated by alloantigens coded within a single known H-2 region.     

Interactions between MHC-encoded products and cloned T-cells. I. Fine specificity of induction of proliferation and lysis

To study the interactions between T cells and class I MHC products, we developed in vitro a T-cell line reactive to H-2K^b stimulating cells and derived T-cell clones from it. Although the T-cell line could proliferate in the absence of exogeneous T-cell growth factors when stimulated with H-2K^b spleen cells, each of the derived T-cell clones required both H-2K^b stimulating cells and an external source of T-cell growth factor for its propagation. Each of the T-cell clones was also cytolysic for H-2K^b target cells. Such T-cell clones allowed the comparison of the antigenic requirements for proliferation and cytolysis. By using H-2K ^b mutant mice, we found that while the original anti-H-2K^b T-cell line reacted with each of the six mutants tested, the individual T-cell clones could be distinguished in terms of their reactivity pattern. Similar fine specificity patterns were found when H-2K ^b mutant cells were used as stimulating or target cells for any given T-cell clone. Each of the three monoclonal H-2K^b-specific antibodies reacting with different epitopes of the H-2K^b molecule totally inhibited H-2K^b-induced proliferation and lysis by the T-cell clones. Further blocking studies involved use of Fab antibody fragments and definition of their reactivity on cells from the H-2K ^b mutants. We concluded that: (1) blocking with a monoclonal antibody does not prove identity of alloantigens recognized by the T-cells and the antibody; (2) a monoclonal antibody could either block or not block H-2K^b-CTL interactions depending on structural variations of the H-2K^b molecule not affecting the CTL-H-2K^b functional interaction; (3) blocking one type of H-2K^b-T-cell interaction (induction of proliferation) always affects the other type (cytolysis).Abbreviations used in this paper MHC major histocompatibility complex - CTL cytotoxic - T lymphocytes - Th T helper cells - PMA 4-phorbol 12-myristate 13-acetate - Con A Concanavalin A - LPS E. coli lipopolysaccharide - SCA Con A stimulated rat spleen-cells supernatant - SBD B6 anti-DBA/2 mixed lymphocyte culture supernatant - TCGF T-cell growth factors - IL-2 interleukin 2 - mAb monoclonal antibody - FCS fetal calf serum - PBS phosphate buffered saline - C complement     

Transgenic mice to study T-cell receptor gene regulation and repertoire formation

Transgenic mice have been obtained with genes coding for an alpha beta T-cell receptor that recognizes the male-specific antigen H-Y in association with the Db class I major histocompatibility complex molecule. Most if not all of the T-cells express the beta chain encoded by the transgene and show allelic exclusion of endogenous beta genes. In contrast, the expression of the alpha transgene does not completely block rearrangement and formation of functional endogenous alpha genes. In H-2b transgenic female mice the transgenic T-cell receptor is functionally expressed on at least 30% of CD8+ peripheral T-lymphocytes as indicated by their ability to lyse male target cells. Also in transgenic H-2b male mice a large proportion of peripheral T-cells appear to express the transgenic receptor. However, these cells do not react with male target cells because they show only low level or no expression of CD8 cell interaction molecules. Tolerance is established in the male transgenic thymus through deletion of CD4+CD8+ immature thymocytes.     

Opposing reactivities of subpopulations of T lymphocytes toward syngeneic tumor cells: separation of early thymocytes.

The present communication is a continuation of earlier studies which indicated that interaction between syngeneic tumors and those lymphocytes in the early stages of thymic processing can result in enhanced tumor growth in vivo. The thymocytes involved in this tumor enhancement were found previously in the rapidly dividing subpopulation of subcapsular cortical thymocytes, both in the untreated thymus and in the thymus undergoing repopulation after cortisone depletion. In the present experiments we have isolated this small subpopulation of early thymocytes. After cortisone injection such cells could be separated from the medullary cortisone-resistant thymocytes since the latter cells exhibit a high level of surface H-2 antigens and were thus lysed preferentially by anti-H-2 serum and complement. The repopulating subcapsular early thymocytes, which were resistant to this treatment, were incapable of responding to PHA while their basal proliferation rate was undiminished, and the majority of the cells were found to be dividing. When such low H-2 early thymocytes were injected together with three different tumors into syngeneic mice their tumor-enhancing activity was evident. It is clear that such early thymocytes are not devoid of biologic reactivity and their release from the thymus could have decisive results.     

Murine thymomas induced by fractionated-X-irradiation have specific T-cell receptor rearrangements and characteristics associated with day-15 to -16 fetal thymocytes.

We report here that specific T-cell receptor rearrangements were observed in fractionated-X-irradiation-induced murine leukemias. Consistent gamma-chain rearrangements, limited beta-chain rearrangements, and no detectable alpha-chain rearrangements were observed. Gene expression studies revealed that, in comparison with normal thymus tissue, expression of alpha T-cell receptor genes was lower in the thymomas, beta expression was much higher but approximately equal to that of normal thymocytes, and gamma expression was significantly increased. After coupling these data with those from analyses using reagents against other surface markers, such as Lyt-2, L3T4, H-2, IL-2R and MEL-14, we concluded that the target T cells for fractionated-X-irradiation-induced transformation resemble fetal thymocytes from days 15 and 16 of gestation.     

H-2-restricted GVH reaction caused by T cells from normal donors of certain strains

A comparison has been made of lethal graft-versus-host (GVH) reactions caused by T cells from radiation chimeras and from normal mice. In the recipient strains tested, T cells from both chimeric and normal A, A.SW, and CBA mice showed H-2-restricted killing, while T cells from chimeric and normal C57BL/6 failed to show any evidence for H-2-restricted GVH reactions. With other strains tested as donors, T cells from chimeras showed H-2-restricted GVH reactions, while the corresponding normal cells showed some similarities to the chimeras but not complete H-2-restriction.[/p]     

MHC non-restricted, CD95-independent apoptosis of immature thymocytes induced by thymic epithelial cells

The interaction of thymocytes with thymic epithelial cells in the absence of an exogenous antigen was studied in vitro. Thymic, but not splenic epithelial cells induced apoptosis of thymocytes. A thymic epithelial cell line (TEC) induced apoptosis of thymocytes but not of splenic T-cells. The target population for TEC-induced death were immature CD4(+)8(+) (double positive), but not mature single positive thymocytes. TEC also induced DNA fragmentation in day 18 foetal thymocytes, most of which are CD4(+)8(+) cells. Radiation leukemia virus (RadLV)-transformed thymic lymphoma clones expressing various phenotypes reflected this sensitivity, in that a CD4(+)8(+)3(+) clone apoptosed by thymic epithelial cells or TEC. Other, single positive or double negative clones were resistant. Thymocytes from C3H (H-2(k)), C57BL/6 (H-2(b)) and Balb/C (H-2(d)) mice apoptosed equally in response to either C57BL/6 thymic epithelial cells or TEC (H-2(b) x H-2(d)). Likewise, thymocytes from MRLIpr((-/-)) and B6Ipr((-/-)) mice, which do not express CD95 were also apoptosed by TEC.The data suggest that thymic epithelial cells induce MHC non-restricted, Fas-independent apoptosis of immature thymocytes. This response may reflect a mechanism through which thymocytes expressing TcR with no affinity to self MHC/peptide complexes are eliminated.     

Adult thymectomy promotes the manifestation of autoreactive lymphocytes.

Spleen cells from adult thymectomized mice (ATX) were assayed in a syngeneic graft vs host (GVH) model based upon enlargement of the draining popliteal lymph node following syngeneic cell inoculation into the hind footpad. Spleen cells from ATX mice have been found to induce a significantly higher increase in the weight of the regional lymph node than that induced by the injection of normal spleen cells. Irradiated spleen cells from ATX donors did not cause a similar increase, suggesting either that proliferation of the transferred cells was required at some stage of the reaction or that autoreactive cells are radiosensitive. Autoreactive cells were found in the spleen of mice 2 to 3 months after the thymectomy but were never found in the lymph nodes of such animals or in the thymus of intact mice. They are not phagocytic adherent cells and are not retained on nylon wool columns, which suggests that they belong to the T-cell lineage. Autoreactivity is lost when spleen cells from ATX donors are depleted of autologous rosette-forming cells (A-RFC) by centrifugation on a Ficoll-Hypaque gradient after rosette formation. Autoreactive spleen lymphocytes might belong to the population of A-RFC previously characterized as a population of immature T cells.     

Effect of T-cell mitogens and T-lymphocyte deficiency on splenic colony formation

A study was made of the influence of T-cell mitogens (Con A and PHA) on the colony formation and differentiation of hemopoietic stem cells from normal and thymectomized mice, as well as of the relationship between the colony formation and the dose of injected thymocytes. The incubation of bone marrow cells with Con A and PHA was shown to inhibit the growth of spleen colonies. This inhibition is reduced by thymocytes within the dose intervals of 0.25-2.0 X 10(7) cells/mouse. Administration of these agents serially has led to the potentiation of inhibition effect and to the inability of thymocytes to reverse it. Con A and PHA exert no effect on the differentiation of stem cells. Incubation of the bone marrow cells from thymectomized mice with Con A is much less effective in the depression of colony formation, if compared with the treatment by intact bone marrow preparations. A reversed picture was observed using antiserum to mouse brain (RAMBS). It is proposed that regulation of stem cells is governed by different subpopulations of thymocytes.     

Thymocyte maturation following interaction with thymus-derived macrophages.

Murine C57BL/6 thymocytes were cultivated together with syngeneic thymus-derived macrophages (TDM phi) for up to 96 hr to determine whether TDM phi participate in thymocyte maturation. The expression level of H-2b and Thy-1.2 antigens served as thymocyte differentiation surface markers as analyzed by flow cytometry. Indirect immunofluorescent staining profiles of the thymocytes demonstrate a dramatic increase in H-2b expression and a profound decrease in Thy-1.2 expression during cultivation with TDM phi. A similar phenomenon was observed when enriched populations of immature thymocytes were cocultivated with TDM phi. These changes were not observed when thymocytes were cultivated alone or with trypsin-treated TDM phi; neither were they observed when cortisone-resistant thymocytes manifesting mature characteristics were cultivated together with TDM phi. These findings suggest that interaction of thymocytes with TDM phi, involving binding and engulfment, results in the appearance of mature thymocyte subsets.     

Effect of thymocyte-stimulating factor-containing supernatants on the surface antigens of murine thymocytes.

Incubation of murine thymocytes in thymocyte-stimulating factor (TSF)-containing supernatants causes a four- to fivefold increase in the expression of the H-2^k and H-2^d antigens and a similar decrease in the expression of the TL antigen (in TL⁺ strains) on the surface of these cells. Experiments with antisera directed toward the private H-2K and H-2D antigens showed that TSF-containing supernatants cause approximately the same increase in the expression of the H-2K and H-2D antigens of thymocytes of the d and b haplotypes. With thymocytes of the k haplotype, only an increase in the expression of the H-2D antigens takes place, while no significant increase was found for the H-2K antigens. TSF-containing supernatants cause no significant change in the expression of the following antigens on the surface of thymocytes: Thy-1.1, Thy-1.2, Ly-1.2, Ly-2.2, Ly-6.2, Th-B, Ia-1,2,3,7, and G_IX. A factor similar to murine TSF, produced by human peripheral blood leukocytes, does not affect appreciably the expression of the H-2 antigens on the surface of murine thymocytes. The factor(s) causing the increased expression of the H-2 antigens on the surface of murine thymocytes appears to be produced by T lymphocytes. The factor(s) is eluted from a Sephadex G-100 column in at least two broad peaks with molecular weights of 300,000 and 90,000-25,000. Most of the activity enhancing the expression of the H-2 antigens is lost at pH 2, while most of it is maintained at pH 11.5 and at 56 °C. On the basis of these properties, it is concluded that the factor under study is probably different from the factor enhancing the phytohemagglutinin responsiveness of thymocytes.