Tumour Growth Causes Suppression of Autoreactive T-Cell Proliferation by Disrupting Macrophage Responsiveness to Interferon-γ

Normal immune homeostasis is regulated partly by a small population of CD4⁺ T cells that react to autologous major histocompatibility complex class-II molecules on self-cells. Decreased autoreactive T-cell responses are associated with cancer. Tumour growth causes syngeneic macrophages (Mø) to suppress autoreactive T-cell proliferation by decreasing Mø class-II expression and increasing Mø production of the suppressor molecule prostaglandin E₂ (PGE₂). Because interferon-γ (IFN-γ) is a potent Mø activation molecule which regulates both Mø PGE₂ and class-II expression, the effects of IFN-γ on tumour-induced suppression of autoreactive T-cell proliferation were investigated. Exogenous IFN-γ increased normal host (NH) CD4⁺ autoreactive T-cell proliferation stimulated by syngeneic NHMø but decreased proliferation stimulated by tumour-bearing host (TBH) Mø. Antibody (Ab) neutralization of endogenous IFN-γ activity reduced TBH Mø-mediated suppression. Kinetic studies showed that endogenous IFN-γ suppressor activity was not exclusive during T-cell activation. Indomelhacin treatment blocked IFN-γ-induced suppression in TBH Mø-T cell cultures. TBH Mø-T cell cultures contained significantly more PGE₂ than those containing NH Mø. Exogenous IFN-γ increased early PGE₂ production in TBH Mø cultures but decreased production in NHMø cultures. The Ab-mediated neutralization of endogenous transforming growth factor-β or tumour necrosis factor-x reduced TBH Mμ-mediated suppression and blocked IFN-γ-induced suppression. Short-term treatment of Mμ with IFN-γ before their addition to T cells caused TBH Mμ to stimulate T-cell proliferation, which suggests that early suppressor molecule production by TBHMø inhibits synthesis or activity of IFN-γ-induced stimulatory monokines. These results show that tumour growth causes Mø to suppress autoreactive T-cell responses by allowing IFN-γ to induce Mø suppressor molecules, which block production or activity of stimulatory monokines.     

Inhibition of natural killer cell-mediated bone marrow graft rejection by allogeneic major histocompatibility complex class I,but not class II molecules

The role of major histocompatibility complex (MHC) class I and class II molecules in natural killer (NK) cell-mediated rejection of allogeneic, semi-syngeneic and MHC-matched bone marrow grafts was investigated. The use of β₂-microglobulin (β₂m) -/- and β₂m +/- mice as bone marrow donors to MHC-mismatched recipients allowed an analysis of whether the presence of semi-syngeneic and allogeneic MHC class I gene products would be triggering, protective or neutral, in relation to NK cell-mediated rejection. Loss of β₂m did not allow H-2^b bone marrow cells to escape from NK cell-mediated rejection in allogeneic (BALB/c) or semi-allogeneic (H-2D^d transgenic C57BL/6) mice. On the contrary, it led to stronger rejection, as reflected by the inability of a larger bone marrow cell inoculum to overcome rejection by the H-2-mismatched recipients. In H-2-matched recipients, loss of β₂m in the graft led to a switch from engraftment to rejection. At the recipient level, loss of β₂m led to loss of the capability to reject H-2-matched β₂m-deficient as well as allogeneic grafts. When MHC class II-deficient mice were used as donors, the response was the same as that against donors of normal MHC phenotype: allogeneic and semi-syngeneic grafts were rejected by NK cells, while syngeneic grafts were accepted. These data suggest a model in which allogeneic class I molecules on the target cell offer partial protection, while certain syngeneic class I molecules give full protection from NK cell-mediated rejection of bone marrow cells. There was no evidence for a role of MHC class II molecules in this system.     

Induction of mouse syngeneic MLR by in vivo xenogeneic immunization with HLA-DR antigens

To study in mice the effects of in vivo xenogeneic immunization with human major histocompatibility complex (MHC) class II antigens, the animals were injected with HLA-DR antigens and their proliferative responses tested in vitro. The results showed that small amounts of HLA-DR proteins, acting as nominal antigens, were not only able to prime mice for a secondary in vitro xenogeneic mixed lymphocyte reaction but also induced a syngeneic mixed lymphocyte reaction. In contrast, allogeneic or syngeneic immunization of mice with soluble MHC class II molecules failed to stimulate an autoreactive response. The syngeneic mixed lymphocyte reaction was primarily directed against syngeneic MHC class II molecules since the murine T lymphocytes reacted against MHC class II-positive dendritic spleen cells and MHC class II-transfected mouse fibroblasts. A self-reactive T-cell line induced under these experimental conditions did not react in xenogeneic and allogeneic mixed lymphocyte reactions. However, these T lymphocytes proliferated when human peripheral blood lymphocytes of various haplotypes were presented in the context of syngeneic mouse antigen presenting cells.     

CDw78 — a determinant on a major histocompatibility complex class II subpopulation that can be induced to associate with the cytoskeleton

In the present study we demonstrate that CDw78 monoclonal antibody (mAb) recognizes a distinct subpopulation of major histocompatibility complex (MHC) class II molecules. We show that the CDw78 epitope is present on less than 10 % of the total number of MHC class II molecules expressed on different cells, is not linked to a single isotype, and exhibits a characteristic expression pattern in tonsils. While mAb against MHC class II (DR, DP and DQ) stained the majority of cells both in the mantle zone and in germinal centers, the CDw78 staining was more heterogeneous with the strongest reactivity and the highest number of positive cells in the mantle zone and in the light centrocyte-rich part of the germinal centers. Antibodies to this MHC class II subpopulation (e.g. FN1) induced association with the cytoskeleton and a subsequent capping in more than 90 % of peripheral blood B cells. In contrast, mAb against MHC class II (DR, DP and DQ) did not induce association with the cytoskeleton and only 10–20 % of B cells were induced to cap, suggesting that CDw78 defines a population of MHC class II molecules functionally different from the majority of these antigens. Scatchard plot analysis indicates that FN1 mAb is of relatively low affinity (K_a = 1.5 × 10⁸M^?1) and monovalent Fab fragments fail to bind to the cell surface with measurable affinity. Our data seen in the context of the ability of FN1 to co-stimulate B cells with a suboptimal dose of anti-μ suggest that CDw78 mAb might recognize a functional important subpopulation of MHC class II molecules so far not described. It seems likely that this subpopulation represents dimerized or aggregated MHC class II molecules that can selectively bind this low-affinity mAb.     

Engagement of major histocompatibility complex class II molecules leads to nitrite production in bone marrow-derived macrophages

The present study was designed to examine whether engagement of major histocompatibility complex (MHC) class II molecules can lead to induction of NO synthase in bone marrow-derived macrophages. We treated the macrophages with toxic shock syndrome toxin 1 (TSST-1), a superantigen which activates T cells in an MHC class II-dependent manner. Upon addition of syngeneic spleen cells as a source of mature T cells to the TSST-1-treated macrophage culture, NO₂? production was greatly increased. To test whether monoclonal antibodies (mAb) to MHC class II antigens also serve as an effective trigger signal for induction of NO synthase we incubated the cells with the anti-I-A^d/b mAb D3.137 and measured NO₂? production in culture supernatants. The addition of the mAb D3.137 resulted in NO₂? production which was completely suppressed by N^G-monomethyl-L-arginine, a homologue of L-arginine, indicating that antibody-induced NO₂? production was due to activation of NO synthase. The ability of anti-I-A antibodies, which may imitate the effects of T cells, to induce NO₂? production suggests that MHC class II molecules act as transmembrane signal transducers finally leading to induction of NO synthase.     

Allogeneic recognition of class I molecules: Anti-H-2Ld repertoire of H-2b mice includes T cells recognizing mutant class II H-2b (Abm12) molecules

Two major histocompatibility complex (MHC) class I-reactive T cell clones derived from H-2^b mice, generated against the allogeneic L^d molecule, were found to recognize the H-2^b class II mutant A^bm12 molecule as well. In addition, these clones also recognize the class II A^s molecule, and display a class II-dependent reactivity to staphylococcal enterotoxin B. Neither the class I nor the class II alloreactivities of the clones were found to be dependent on other MHC molecules. Both clones express CD4+CD8^? phenotypes. The CD4 molecule appears to be involved in their class II reactivity, while little or no role for CD4 could be detected in the class I reactivity. This is the first report of a class I/class II cross-reactivity being mediated by CD4⁺ T cells. The structural basis for this cross-reactivity is discussed.     

Macrophage function during the development of adjuvant disease

Using rat peritoneal macrophages and blood monocytes we examined the relationship of developing adjuvant disease (AD) with the expression of class I and II antigens, release of interleukin-1 (IL-1) and production of prostaglandin E₂ (PGE₂). We observed that class I and II antigens initially decreased; class II remained low throughout, whereas class I returned to normal. PGE₂ and IL-1 gradually increased. Treatmentin vivo with the NSAID Na-diclofenac lowered PGE₂ and IL-1 release and partly reversed the observed reduction of class I and II antigens. Also, exposure of the cellsin vitro to lipopolysaccharide increased class I antigen expression.     

Perforin dependence of natural killer cell-mediated tumor control in vivo

Adaptive immune surveillance by T cells against infections and tumors depends on the presence of antigenic peptides presented by major histocompatibility complex (MHC) molecules. If antigenic tumor-specific peptides or MHC class I molecules are absent, the adaptive T cell immune response fails. Natural killer (NK) cells seem to complement the specific T cells by recognizing target cells lacking MHC class I (e.g. RMA-S). The role of perforin, which is crucially involved in T cell and NK cell-mediated target cell lysis, was evaluated in mice lacking perforin with respect to their capacity to eliminate a syngeneic lymphoid tumor. Here, we show that growth of MHC class I^? RMA-S tumor cells in unprimed mice was controlled by NK cells through perforin-dependent cytotoxicity.     

Influence of Intestinal Microflora on Murine Bone Marrow and Spleen Macrophage Precursors

To investigate the adjuvant effect of intestinal flora on macrophage–colony-stimulating factor-responsive macrophage progenitors from spleen and bone marrow, we compared progenitor numbers and phenotypic characteristics of in vitro matured macrophages in germ-free and flora-associated mice (conventional, Escherichia coli -monoassociated and conventionalized mice). The data obtained show that the flora affected differentially bone marrow and spleen progenitors. It increased the numbers of progenitors in the spleen but not in the bone marrow. It did not modify the expression of F4/80, Mac-1 and major histocompatibility complex (MHC) class II on bone-marrow-derived macrophages (BMDM), while it clearly up-regulated MHC class II expression on spleen-derived macrophages (SDM). This effect was more pronounced in flora-associated ex germ-free mice than in conventional mice and it was greatly enhanced in the absence of M-CSF. In vitro stimulation by lipopolysaccharide had no effect on marker expression of BMDM, while it decreased F4/80 and enhanced MHC class II molecules on SDM from germ-free and flora-associated mice. However, the expression of MHC class II remained lower in germ-free mice. Enhancement of MHC class II molecule expression on SDM may contribute to the protective role of flora, because successful immune responses are dependent on the expression of these molecules.     

Macrophage Priming and Activation During Fibrosarcoma Growth: Expression of c-myb,c-myc,c-fos,and c-fms

Macrophages (M?)³ function by a two-step process that includes priming (induction of cytokine and enzyme mRNA) and activation (production of effector molecules). The initial steps in M? priming involve the expression of certain proto-oncogenes that regulate expression of other genes. Because tumor growth primes M? to produce several suppressor monokines, we determined if cancer induced M? expression of these proto-oncogenes. Unstimulated peritoneal M? from tumor-bearing hosts (TBH) constitutively expressed the proto-oncogenes c-fms, c-fos, c-myc, and c-myb, whereas normal host (NH) M? had little or no expression of these proto-oncogenes. When M? were given a 24-h adherence priming stimulus, NH M? expressed c-fms and c-fos at levels equivalent to TBH M? constitutive expression. Adherence had little or no effect on c-fms and c-fos expression in TBH M? or on NH and TBH M? c-myc expression. c-myb expression was not induced in NH M? during adherence and was strongly decreased in TBH M?. Activation with a 1-h lipopolysaccharide-treatment increased NH and TBH M? expression of c-fms, c-fos, and c-myc, with higher expression of these proto-oncogenes in TBH M?. Activation failed to induce c-myb expression in NH M? and completely inhibited expression in TBH M?. Because c-fms, c-fos, and c-myc are normally expressed early during M? activation, our results suggest that tumor growth primes M? by inducing expression of these proto-oncogenes. c-myb is expressed in immature M? and is downregulated during M? activation. These observations explain why NH M? expression of c-myb was not induced and are consistent with reports that suggest TBH M? have not reached full developmental maturity. The induction of M? protooncogene expression during cancer may put M? in a primed state, which leads to earlier and stronger production of adverse suppressor and cytotoxic molecules.     

The structural basis of T-cell allorecognition

Foreign allogeneic major histocompatibility complex (MHC) class I and class II molecules elicit an exceptionally vigorous T-cell response. A small component of the alloresponse comprises CD4+ T cells that recognize allogeneic MHC indirectly after processing into peptide fragments that are bound and presented by self-MHC class II. The majority of alloreactive T cells directly recognize intact allogeneic MHC molecules expressed on foreign cells. Some alloreactive T-cell interactions with allogeneic MHC molecules are indifferent to the bound peptide, but evidence suggests that most show specificity to peptide. The vigor and diversity of the direct alloreactive T-cell response can therefore be explained by summation of numerous responses to each of the peptides in the novel set bound by allogeneic MHC molecules. Structural studies definitively show that the overall mechanism of T-cell receptor (TCR) recognition of self-MHC and allogeneic MHC molecules is similar. Many alloreactive T cells recognize several different combinations of MHC and bound peptide that do not necessarily possess structural homology. Flexibility within the TCR structure allows adaptation to the different contact surfaces. Crossreactivity seems to be an intrinsic property of the TCR required, because a single TCR must possess the ability to interact with both self-MHC during positive selection and at least one combination of foreign antigenic peptide presented by self-MHC. Recognition of allogeneic MHC molecules is an inadvertent consequence of the need for TCR crossreactivity.     

Tumor growth changes the contribution of granulocyte-macrophage colony-stimulating factor during macrophage-mediated suppression of allorecognition.

Tumor-bearing host (TBH) macrophages (M phi) suppress T cell alloresponses, and this study suggests granulocyte-macrophage colony-stimulating factor (GM-CSF), a molecule associated with suppressive M phi activity during tumor growth, signals more immunosuppression. In the absence of M phi, GM-CSF increased T cell proliferation in response to alloantigen. However, TBH M phi-mediated suppression of allorecogntion was further induced by GM-CSF. Allogeneic mixed lymphocyte reaction (MLR) cultures, containing normal host (NH) M phi, were either unaffected or enhanced. Prostaglandin E2 (PGE2), a highly suppressive monokine that decreases alloreactivity, did not seem to be involved in the suppression caused by the TBH M phi/GM-CSF interaction. M phi-CSF (M-CSF) addition to cultures did not reverse the suppression caused by TBH M phi and GM-CSF, and inhibition of PGE2 synthesis did not change the response to M-CSF. TBH Ia- M phi, a suppressor population that predominates among splenic M phi during tumor growth, demonstrated significantly lower reactivity in the presence of GM-CSF. In contrast, alloresponses suppressed by NH Ia- M phi demonstrated higher reactivity in the presence of GM-CSF. The data collectively suggest that TBH M phi respond differently to GM-CSF, and that tumor-induced changes in GM-CSF responsiveness affect M phi accessory ability.     

Macrophage development: IV. Effects of blood factors on macrophages from prenatal rat lung cultures

Effects of colony-stimulating factors M-CSF, GM-CSF, G-CSF, and IL-3 were assessed on cells of macrophage lineage present in organ cultured 14-day prenatal rat lungs. Treatment groups were compared between one another and against control lungs grown on standard medium containing 40% fetal bovine serum without added factors, where a monoculture of macrophages rapidly develops from precursors present at explantation, leading to appearance of a large mature population on the pleural surface outside the lungs. Studies were carried out in living cultures and by light and electron microscopy using peroxidase-coupled isolectin B₄ of Griffonia simplicifolia to identify macrophages and their precursors. In the first experiment, 14-day prenatal lung explants (14+0 days) containing macrophage precursors but not matured cells were exposed to individual CSFs for 7 days in an attempt to determine whether precursors are committed irrevocably to the macrophage line or can be altered by exposure to factors promoting significant granulocyte development. In succeeding experiments, 4- and 7-day-old cultures (14+4, 14+7 days) containing matured macrophages were targeted to see whether macrophage survival can be extended beyond expectations in controls and whether mitotic activity is stimulated. Recombinant CSFs were used at dosage levels known to promote colony formation in vitro (200–1,000 CFU/ml). Cultures exposed from prenatal day 14 to M-, GM-, G-CSF, or IL-3 yielded a monoculture of macrophages without exception. Populations developed in the presence of M- or GM-CSF were much larger than in controls or cultures grown with the other blood factors. GM-CSF-exposed cultures produced by far the largest macrophages, among them many multinucleate giant cells. Macrophages developed in the presence of G-CSF were also significantly larger than controls. Growth of the mature macrophage population was greatly stimulated by exposure to M-CSF or GM-CSF but not by IL-3 or G-CSF. Mitotic figures were noted in the coronas of emerged cells surrounding stimulated cultures, compared to none in the controls. Ultrastructurally, macrophages stimulated by M-CSF retained a mature appearance like macrophages in control, IL-3, and G-CSF treatment groups, whereas many in the GM-CSF group became less differentiated. As to long-term survival, a single 14-day explant was grown for 8 days on standard medium (the equivalent date for birth), then placed in a soft agar medium containing M-CSF. Supplemented irregularly by M-CSF and GM-CSF, the culture remained viable until fixed on the 137th “postnatal” day and retained a small population of macrophages. Conclusions: (1) the macrophage lineage from embryonic rat lungs can be manipulated in culture; (2) macrophage precursors in these lungs seem committed to the macrophage line; (3) replication of both immature and mature macrophages is stimulated by M-CSF and GM-CSF; (4) with M-CSF, however, retention of mature characteristics and longevity are favored, whereas with GM-CSF maturity is partly lost and formation of giant cells emphasized. © 1992 Wiley-Liss, Inc.     

Down-regulation of MHC class II molecules and inability to up-regulate class I molecules in murine macrophages after infection with Toxoplasma gondii

Toxoplasma gondii is able to invade phagocytic cells of the monocyte-macrophage lineage and replicates within a parasitophorous vacuole. Since macrophages may activate specific T lymphocytes by presenting pathogen-derived antigens in association with molecules of the MHC, we investigated the in vitro expression of host cell molecules involved in antigen processing and presentation before and during infection of murine bone marrow-derived macrophages (BMM) with T. gondii. Fifty-one hours after addition of T. gondii tachyzoites at different parasite-to-host ratios, up-regulation of total MHC class II molecules by interferon-gamma (IFN-γ) was dose-dependently abrogated in up to 50% of macrophages compared with uninfected control cultures. Quantitative analyses by flow cytometry revealed that the IFN-γ-induced surface expression of class II antigens as well as the IFN-γ-induced up-regulation of class I molecules was significantly decreased in T. gondii-infected macrophage cultures compared with uninfected controls. However, the constitutive expression of MHC class I antigens was not altered after parasitic infection, and infected BMM remained clearly positive for these molecules. After infection of macrophages preactivated with IFN-γ for 48 h, T. gondii also actively down-regulated an already established expression of MHC class II molecules. Furthermore, kinetic analysis revealed that the reduction in intracellular and plasma membrane-bound class II molecules started ≈ 20 h after infection. While MHC class II antigens were most prominently reduced in parasite-positive host cells, culture supernatant from T. gondii-infected BMM cultures also significantly inhibited expression of these molecules in uninfected macrophages. However, down-regulation of MHC class II molecules was not mediated by an increased production of prostaglandin E₂, IL-10, transforming growth factor-beta or nitric oxide by infected BMM compared with uninfected controls. Our data indicate that intracellular T. gondii interferes with the MHC class I and class II antigen presentation pathway of murine macrophages and this may be an important strategy for evasion from the host's immune response and for intracellular survival of the parasite.     

MHC class II molecules transferred between allogeneic dendritic cells stimulate primary mixed leukocyte reactions.

Presentation of antigen to T cells is generally restricted by MHC type but the mixed leukocyte reaction (MLR) was thought to involve direct stimulation by dendritic cells (DC) of allogeneic T cells. However, here we showed that DC bearing allogeneic MHC class II acted synergistically with responder-type DC. Removal of residual DC from 'purified' responder T cell populations was achieved using treatment with DC-specific antibody and complement. These DC-depleted cells showed a significantly reduced response to allogeneic DC which was restored by addition of DC syngeneic with responder T cells. The studies support the concept that a major component of the MLR is the secondary presentation of alloantigens acquired from stimulator DC by DC of responder type. To investigate the reasons why DC and not other cells stimulate an MLR, synergy between DC and other cell types was investigated. Synergy was found exclusively between DC; macrophages, B cells or L cells transfected with MHC class II molecules did not contribute. When allogeneic DC were mixed in culture, transfer of MHC molecules between DC was observed as assessed by flow cytometry. Freshly obtained cell-free supernatants from cultured DC contained MHC class II and stimulated primary allogeneic MLR. DC of responder type acquired allogeneic MHC molecules from the supernatants and stimulated proliferation in syngeneic T cells. The capacity of DC both to shed and to acquire MHC molecules may contribute to their potency in stimulating primary responses, and could explain why passenger DC within allografts provide a potent stimulus for graft rejection.     

Structures on T cells and macrophages involved in interleukin 1 (Il-1) secretion by macrophages upon contact with syngeneic thymocytes

We demonstrate, using a new rosette method of determination of interleukin 1 activity that macrophages secrete Il-1 upon contact with syngeneic thymocytes or with thymocytes homologous in the Ia region of MHC complex. The phenomenon takes place in the absence of foreign antigen. Blocking of class II MHC antigens on macrophages with monoclonal antibodies against structures of the T-cell receptor complex (alpha/beta T-cell receptor-TCR, CD3 and L3T4) inhibits production of Il-1 to the background level. We conclude that secretion of Il-1 from macrophages, upon contact with syngeneic thymocytes, is triggered by a T-cell signal following interaction: TCR-Ia molecules.     

Compressive Force Induces Osteoclast Differentiation via Prostaglandin E2 Production in MC3T3-E1 Cells

In orthodontic tooth movement, prostaglandin E₂ (PGE₂) released from osteoblasts can alter the normal process of bone remodeling. We previously showed that compressive force (CF) controls bone formation by stimulating the production of PGE₂ and Ep2 and/or Ep4 receptors in osteoblasts. The present study was undertaken to examine the effect of CF on the production of PGE₂, cyclooxygenase-2 (COX-2), macrophage colony-stimulating factor (M-CSF), receptor activator of NF-κB ligand (RANKL), and osteoprotegerin (OPG) using osteoblastic MC3T3-E1 cells and to examine the indirect effect of CF on osteoclast differentiation using RAW264.7 cells as osteoclast precursors. MC3T3-E1 cells were cultured with or without continuous CF (1.0 or 3.0 g/cm²) for 24 hr, and PGE₂ production was determined using ELISA. The expression of COX-2, M-CSF, RANKL, and OPG genes and proteins was determined using real-time PCR and ELISA, respectively. Osteoclast differentiation was estimated using tartrate-resistant acid phosphatase (TRAP) staining of RAW 264.7 cells cultured for 10 days with conditioned medium from CF-treated MC3T3-E1 cells and soluble RANKL. As CF increased, PGE₂ production and the expression of COX-2, M-CSF, and RANKL increased, whereas OPG expression decreased. The number of TRAP-positive cells increased as CF increased. Celecoxib, a specific inhibitor of COX-2, blocked the stimulatory effect of CF on TRAP staining and the production of PGE₂, M-CSF, RANKL, and OPG. These results suggest that CF induces osteoclast differentiation by increasing M-CSF production and decreasing OPG production via PGE₂ in osteoblasts.     

Utilization of the MHC Class I (H-2Kb) Purified Molecule and its Synthetic Peptides for Inhibition of Kb-Specific Suppressor T Cells and their Induction In Vivo by the MHC Peptides

Six synthetic peptides of the MHC class I molecule corresponding to individual H-2K^b participants in amino acid sequences of domains α₁ (peptide 1 and 2) and α₂ (peptides 3,4, 5,6) were selected. K^b-specific suppressor T cells (Ts) were induced in vivo in mice, then pretreated with a set of peptides and assayed by proliferation decrease in a three-cell lymphocyte culture (MLC). The effector function of Ts was abolished by the complex of the α₂-domain peptides (but nol by the α₁-domain peptides) and decreased by particular peptides separately (4, 5, 6) of the α₂-domain. Both α₁- and α₂-domain peptides. added in high concentration, decreased otherwise efficient enrichment of Ts during the absorption-elution procedure on the syngeneie macrophage (Mφ) monolayers. A similar significant effect was observed using the purified K^b molecule (100μg/ml) in the allogeneic Mφ monolayer. Interaction between Ts receptors and some MHC peptides indicates in effector Ts activation in vivo by induction with peptides 5 and 6 of the α₂-domain. The fine mechanisms of interaction between MHC class I molecule epitopes and T-cell receptors of each of the T-cell subsets separately are presently being studied.