Two types of allograft-induced cytotoxic macrophage, one against allografts and the other against syngeneic or allogeneic tumor cells

In the 1990s, based on the results of studies using beta(2)M, CD4 or CD8 knockout mice, several groups reported that the main effector cells responsible for skin or organ allograft rejection were non-T, non-NK cells. Similarly, we demonstrated that in an animal model of transplantation of BALB/c (H-2(d)) skin onto or Meth A (H-2(d)) tumor cells into C57BL/6 (H-2(b)) mice, AIM, which expressed iNOS, IL-12, and IL-18, were the main effector cells and also that they were cytotoxic against syngeneic tumor cells. Here, we examined whether the same population of macrophages could react with two distinct types of target cell. When BALB/c skin or Meth A tumor cells were transplanted into C57BL/6 mice, cytotoxic activity against the allograft was induced in the transplantation site on days 5-14 and was recovered in non-adherent cells after a 20-min incubation in a serum-coated dish, suggesting the induction of a type of AIM (AIM-1) in the transplantation site. The AIM-1-expressing receptors for H-2D(d)K(d) antigens had no cytotoxic activity against syngeneic tumor cells. In contrast, AIM-2, which were recovered in the fraction adherent to the serum-coated dish, exhibited cytotoxic activities against various types of tumor cells, whereas they were inactive toward BALB/c skin. AIM expressed iNOS (AIM-1 < AIM-2), IL-12 (AIM-1 > AIM-2), and IL-18 (AIM-2 alone) mRNAs. These results indicate that after allografting, two distinct types of cytotoxic AIM were induced in the transplantation site, one against the allografted skin or tumor (AIM-1) and the other against allogeneic or syngeneic tumor cells (AIM-2).     

Two Distinct Populations of Primary Cytotoxic Cells Infiltrating into Allografted Tumor Rejection Sites: Infiltration of Macrophages Cytotoxic against Allografted Tumor Precedes That of Multiple Sets of Cytotoxic T Lymphocytes with Distinct Specificity to Alloantigens

It has been reported that the rejection of tumor allografts is mainly mediated by cytotoxic T lymphocytes (CTLs). Here, we characterized the cytotoxic effector cells of C57BL/6 (B6; H-2^b) mice infiltrating into the rejection site of the i.p. allografted Meth A fibrosarcoma (or P815 mastocytoma) cells of H-2^d origin. Two types of cytotoxic cells (i.e., CD8⁺ CTLs and macrophages (Mφs)) were identified by flow cytometric fractionation of the infiltrates or by specific in vitro elimination of cells either with antibody (Ab)-coated beads or with an Ab-plus complement. Of particular interest, these effector cells showed distinct and unique target specificities. First, the CTLs were inactive against transplanted tumor (e.g., Meth A) cells, whereas they were cytotoxic against donor-related concanavalin A (Con A) blasts as well as CTLL-2 (H-2^b) cells transfected with a class I gene of H-2^d origin. A cold target competition assay suggested that the CTLs were composed of multiple sets of T cells, each of which specifically recognized different allo-antigens. Second, the Mφs lysed the allografted tumor cells but were inert toward the Con A blasts and the CTLL-2 transfectants. Unexpectedly, the infiltration of Mφs preceded the infiltration of CTLs by several days during the course of rejection. These results indicate that two distinct populations of unique cytotoxic cells (i.e., CTLs and Mφs) are induced in the allografted tumor rejection site, and that the infiltration of cytotoxic Mφs responsible for rejection precedes that of the CTLs cytotoxic against cells expressing donor-related allo-antigens.     

A novel receptor on allograft (H-2d)-induced macrophage (H-2b) toward an allogeneic major histocompatibility complex class I molecule, H-2Dd, in mice

The generation of knockout mice demonstrated that noncytotoxic CD4(+), but not cytotoxic CD8(+), T cells were essential for the rejection of skin or organ allografts. Earlier we reported that allograftinduced macrophages (AIM) in mice lysed allografts with H-2 haplotype specificity, implying screening of grafts by AIM. Here, we isolated a cDNA clone encoding a novel receptor on AIM (H-2D(b)) for an allogeneic major histocompatibility complex (MHC) class I molecule, H-2D(d), by using H-2D(d) tetramer and a monoclonal antibody (mAb; R15) specific for AIM. The cDNA (1,181-bp) encoded a 342-amino acid polypeptide with a calculated molecular mass of 45 kDa and was found to be expressed on AIM, but not on resident macrophages or other cells, infiltrating into the rejection site. HEK293T cells transfected with this cDNA reacted with R15 mAb and H-2D(d), but not H-2L(d), H-2K(d), H-2D(b), H-2K(b), H-2D(k), or H-2K(k), molecules; and the H-2D(d) binding was suppressed by the addition of R15 or anti-H-2D(d) mAb. AIM yielded a specific saturation isotherm in the presence of increasing concentrations of H-2D(d), but not H-2D(b) or H-2D(k), molecules. The dissociation constant of AIM toward H-2D(d) tetramers was 1.9 x 10(-9) M ; and the binding was completely inhibited by the addition of R15 or anti-H-2D(d) mAb. These results reveal that a novel receptor for an allogeneic H-2D(d) molecule was induced on effector macrophages responsible for allograft (H-2(d)) rejection in H-2(b) mice.     

Failure to Reject an Allografted Tumor after Elimination of Macrophages in Mice

After an i.p. transplantation of an allogeneic tumor (Meth A) to C57BL/6 mice, a macrophage (MΦ)-rich, non-T, non-NK cell population is induced as the major infiltrate and cytotoxic cells. We here evaluated the role of the MΦs in the rejection of allografted Meth A cells and characterized the MΦs in comparison with other well-known MΦs. At all time intervals after transplantation, the highest cytotoxic activities against Meth A tumor were obtained with the MΦ-rich population. In addition, the lymphocyte-rich population had a significant but low cytotoxic activity, whereas two other population types, granulocytes and large granular cells, were inactive. When the MΦ-rich or the T cell-depleted MΦ-rich population was i.p. transplanted simultaneously with Meth A cells into untreated C57BL/6 mice, the tumor cells were rejected without growth. After specific elimination of MΦs by in vivo application of dichloromethylene diphosphonate-containing liposomes, the cytotoxic activity against Meth A cells was hardly induced at the transplantation site of Meth A cells and the allografted Meth A tumor continued to grow, indicating that a type of MΦ is the effector cell essential for the rejection. In contrast to other well-known MΦs, the cytotoxic activity against Meth A cells was cell-to-cell contact dependent and soluble factor (e.g., NO and TNF-α) independent. Moreover, the cytotoxic activity of the MΦs (H-2^b) against ⁵¹Cr-labeled Meth A (H-2^d) cells was inhibited by the addition of unlabeled H-2^d, but not H-2^a, H-2^k or H-2^b, lymphoblasts as well as Meth A cells, implying the specific interaction of the MΦs with H-2^d cells.     

Leukocyte integrin-dependent and antibody-independent cytotoxicity of macrophage against allografts

Macrophages (Mphis), but not T cells, infiltrating into the rejection site of either i.p. allografted Meth A (H-2d) fibrosarcoma cells in C57BL/6 (B6) (H-2b) mice or BALB/c (H-2d) skin onto B6 mice are cytotoxic against allografts with H-2d specificity. To determine the mechanisms of specific killing of allografts by allograft-induced Mphi (AIM), we raised approximately 5,000 rat monoclonal antibodies (mAbs) against AIM and selected three of them (R1-73, R2-40 and R1-34), each of which inhibited cytotoxic activity against allografts in a dose-dependent manner. The antigens recognized by R1-73, R2-40 and R1-34 mAbs were defined by immunoprecipitation and Western blot analyses as CD11a, CD18 and CD11b, respectively; and the allografts expressed CD54, a ligand of CD11a or CD11b, suggesting leukocyte integrin-dependent killing. Although Ab-dependent cellular cytotoxicity has been recognized as a mechanism of specific killing by Mphis, the infiltration of AIM into the rejection site of allografts far (approximately 6 days) preceded the appearance of serum IgG Ab specific for the allograft. AIM exhibiting full cytotoxic activity against allografts was also induced in the transplantation site of Fcgamma receptor knockout [(B6x129) F1] mice as well as B10.D2 (H-2 compatible with allograft) and B6-xid (X-linked immunodeficiency with B cell-specific defect) strains of mice. In the latter two strains of mice, the levels of serum IgG Ab to the allograft were negligible. Moreover, the cytotoxic activity of AIM against allografts was not affected by pretreatment of the cells with anti-mouse IgG serum, suggesting Ab-independent cytotoxicity.     

Differential susceptibility of cells expressing allogeneic MHC or viral antigen to killing by antigen-specific CTL

CD8(+) cytotoxic T lymphocytes (CTLs) generated by immunization with allogeneic cells or viral infection are able to lyse allogeneic or virally infected in vitro cells (e.g., lymphoma and mastocytoma). In contrast, it is reported that CD8(+) T cells are not essential for allograft rejection (e.g., heart and skin), and that clearance of influenza or the Sendai virus from virus-infected respiratory epithelium is normal or only slightly delayed after a primary viral challenge of CD8-knockout mice. To address this controversy, we generated H-2(d)-specific CD8(+) CTLs by a mixed lymphocyte culture and examined the susceptibility of a panel of H-2(d) cells to CTL lysis. KLN205 squamous cell carcinoma, Meth A fibrosarcoma, and BALB/c skin components were found to be resistant to CTL-mediated lysis. This resistance did not appear to be related to a reduced expression of MHC class I molecules, and all these cells could block the recognition of H-2(d) targets by CTLs in cold target inhibition assays. We extended our observation by persistently infecting the same panel of cell lines with defective-interfering Sendai virus particles. The Meth A and KLN205 lines infected with a variant Sendai virus were resistant to lysis by Sendai virus-specific CTLs. The Sendai virus-infected Meth A and KLN205 lines were able to block the lysis of Sendai virus-infected targets by CTLs in cold target inhibition assays. Taken together, these results suggest that not all in vivo tissues may be sensitive to CTL lysis.     

Mechanism of target cell lysis by cytotoxic T lymphocytes (CTL) employing RSV-induced H-2 congenic and recombinant mouse tumor cells: demonstration of soluble mediators released from H-2-restricted CTL clones

The secretion and the specificity of cytotoxic mediators from H-2-restricted cytotoxic T lymphocytes (CTL) were examined using non-virus-producing target tumor cells induced by the Schmidt-Ruppin strain of Rous sarcoma virus (SR-RSV) in B10 congenic and recombinant mice. By using rat concanavalin A supernatant, two H-2-restricted CTL clones were established from cytotoxic effector cells of B10.A(5R) mice primed with SR-RSV-induced syngeneic tumor Cell-free supernatants from the H-2-restricted CTL clones cocultured with syngeneic tumor cells had selectively high cytotoxic activity for syngeneic and H-2-compatible tumor cells, but not for H-2-incompatible tumor cells. YAC-1 cells, and B10.A(5R) blasts as defined in the 5-hr 51Cr-release assay. The cytotoxic activity was detected in the cell-free supernatants from the CTL clones cocultured with the CTL-sensitive syngeneic and H-2-compatible tumor cells, but not with the CTL-insensitive tumor cells and YAC-1 cells. The cytotoxic activity of the cell-free supernatant could be adsorbed by the syngeneic tumor cells, but not by YAC-1 and L(s) cells. Thus, the H-2-restricted CTL clones against SR-RSV-induced tumor cells were capable of releasing cytotoxic mediators by coculturing with syngeneic or H-2-compatible tumor cells, and the cytotoxic mediators showed a certain H-2-restricted manner in killing the target cells. These results suggest that the lysis of RSV-induced tumor cells by H-2-restricted CTL can at least in part be mediated by cytotoxic factors.     

Acute rejection of allografted CTL-susceptible leukemia cells from perforin/Fas ligand double-deficient mice

The generation of knockout mice demonstrated that CD4(+), but not CD8(+), T cells were essential for the rejection of allografted skin or heart, presumably because these targets were CTL resistant. In the case of CTL-susceptible targets (e.g., P815 mastocytoma cells and EL-4 or RLmale1 T lymphoma cells), however, it is assumed that the CTL is the effector cell responsible for allograft rejection and that perforin and Fas ligand (FasL) pathways are the killing mechanisms. In the present study, we examined the role of these cytotoxic molecules in the rejection of i.p. allografted CTL-susceptible leukemia cells. Unexpectedly, the allografted leukemia cells were acutely rejected from gld (a mutation of FasL), perforin(-/-), or double-deficient mice. The peritoneal exudate cells from gld or normal mice showed T cell-, TCRalphabeta-, and perforin-dependent cytotoxic activity against the allograft, whereas the exudate cells from perforin(-/-) mice exhibited almost full cytotoxic activity in the presence of Fas-Fc. Furthermore, the infiltrates from double-deficient mice showed a high cytotoxic activity against the allografted cells even in the presence of anti-TCRalphabeta Ab or in the absence of T cells. The cytotoxic cells appeared to be macrophages, because they were Mac-1(+) mononuclear cells with a kidney- or horseshoe-shaped nucleus and because the cytotoxic activity was completely suppressed by the addition of N(G)-monomethyl-l-arginine, an inhibitor of inducible NO synthase. These results indicate that macrophages are ready and available to kill CTL-susceptible allografts when CTLs lack both perforin and FasL molecules.     

Spontaneous rejection of intradermally transplanted non-engineered tumor cells by neutrophils and macrophages from syngeneic strains of mice

It is not surprising that tumors arising spontaneously are rarely rejected by T cells, because in general they lack molecules to elicit a primary T-cell response. In fact, cytokine-engineered tumors can induce granulocyte infiltration leading to tumor rejection. In the present study, we i.d. injected seven kinds of non-engineered tumor cells into syngeneic strains of mice. Three of them (i.e. B16, KLN205, and 3LL cells) continued to grow, whereas four of them (i.e. Meth A, I-10, CL-S1, and FM3A cells) were spontaneously rejected after transient growth or without growth. In contrast to the i.d. injection of B16 cells into C57BL/6 mice, which induces infiltration of TAMs into the tumors, the i.d. injection of Meth A cells into BALB/c mice induced the invasion of cytotoxic inflammatory cells, but not of TAMs, into or around the tumors leading to an IFN-γ-dependent rejection. On day 5, the cytotoxic activity against the tumor cells reached a peak; and the effector cells were found to be neutrophils and macrophages. The i.d. Meth A or I-10 cell-immunized, but not non-immunized, mice rejected i.p.- or i.m.-transplanted Meth A or I-10 cells without growth, respectively. The main effector cells were CTLs; and there was no cross-sensitization between these two kinds of tumor cells, suggesting specific rejection of tumor cells by CTLs from i.d. immunized mice. These results indicate that infiltration of cytotoxic myeloid cells (i.e. neutrophils and macrophages, but not TAMs) into or around tumors is essential for their IFN-γ-dependent spontaneous rejection.     

Mechanisms of Allografted Tumor Rejection: The Roles of T Cells in Allograft Rejection Mediated by a Type of Bone Marrow-Derived Macrophage

Allografted tumor rejection does not occur in the absence of T cells, but the main effector cells responsible for the rejection are allograft-induced macrophages (AIM). We examined the roles of T cells in the AIM-mediated rejection of Meth A (H-2) tumor cells from C57BL/6 (H-2^b) mice. Irradiation of C57BL/6 mice abrogated both the induction of AIM and the allograft rejection. Reconstitution of the irradiated mice with F1 (C57BL/6 X C3H/He: H-2^b/k) bone marrow cells led to the appearance of H-2^b/k haplo-type of AIM exclusively in the rejection site and to allograft rejection, indicating that radiosensitive cells prerequisite for both the induction of AIM and allograft rejection were bone marrow-derived cells, and that the progenitors of AIM existed in the bone marrow cells to be activated into AIM in the rejection site. To understand the role of T cells in the induction of AIM, we used adult-thymectomized, X-irradiated C57BL/6 mice reconstituted with F1 bone marrow (ATXBM). The ATXBM mice could neither induce AIM nor reject allogeneic Meth A cells, whereas adoptive transfer of F1 lymph node T cells to the ATXBM mice restored not only the induction of AIM but also rejection of the allograft. Among the lymph node T cells, CD4⁺, but not CD8⁺, cells were found to be essential for the activation of AIM progenitors to AIM; and CD8⁺ T cells were further required for rejection, at least in part, to enhance the number of AIM in the rejection site.     

Spleen cells from animals neonatally tolerant to H-2Kk antigens recognize trinitrophenyl-modified H-2Kk spleen cells

A.TL mice injected with (A.AL × A.TL)F₁ cells within 24 hours after birth were rendered tolerant to H-2K^k antigens, as evidenced by acceptance of A.TL skin grafts. When spleen cells from these tolerant animals were cocultured with A.AL stimulator cells, no cytotoxic effector cells were generated in a cell-mediated lympholysis assay. However, when the A.AL stimulator cells were derivatized with trinitrophenol, effector cells that displayed a cytotoxic effect against trinitrophenyl-modified H-2K^k target cells were generated. These data indicate that animals tolerant to H-2 determinants but chimeric to only a minor extent possess cytotoxic precursor cells in sufficient frequency to mount a primary in vitro response against trinitrophenol in the context of an allogeneicH-2K region.     

H-2 I alloantigens and recall of memory cytotoxic responses

AQR mice were immunized with H-2K and H-2 I encoded alloantigens presented by (Ax6R)F₁ splenocytes. Spleen cells from these alloimmune mice were subsequently restimulated in vitro with B10.A lymphocytes and/or B10.T(6R) lymphocytes, thus presenting them with the immunizing H-2K and H-2 I alloantigens independently. When stimulated with B10.A lymphocytes, alloimmune lymphocytes develop significant cytotoxicity against the immunizing H-2K target antigens. When stimulated with a similar number of B10.T(6R) spleen cells, alloimmune lymphocytes undergo a prominant proliferative response, but develop little, if any, cytotoxicity against the immunizing H-2 K target antigens. The most efficient restimulation of cytotoxicity occurs when the alloimmune spleen cells are simultaneously restimulated by B10.A and B10.T(6R) lymphocytes. Stimulation with the immunizing H-2 I alloantigens alone is not sufficient for regeneration of detectable cytotoxic responses from alloimmune spleen populations. Stimulation with the immunizing H-2K alloantigens alone appears to be both necessary and sufficient to stimulate alloimmune cytotoxic responses. Although the immunizing H-2 I alloantigens are apparently not required to generate alloimmune cytotoxic responses, they markedly potentiate the cytotoxic responses induced by the immunizing H-2K alloantigens.     

Recognition of Rous sarcoma virus-induced tumor antigens by cytotoxic T lymphocytes (CTL): studies on specificity of killing by CTL employing H-2 congenic and recombinant mouse tumor cells

The specificities of cytotoxic T lymphocytes (CTL) were studied for the analysis of CTL against tumor-specific cell surface antigen(s) (TSSA) of non-virus-producing tumor cells induced by the Schmidt-Ruppin strain of Rous sarcoma virus (SR-RSV) in B10 congenic and recombinant mice. Eight CTL clones were established from immune spleen cells of B10.A(5R) mice. These clones demonstrated six patterns of cytotoxic reactivity in vitro: Two clones showed H-2 restriction in tumor cell lysis. Two other clones had the capacity to lyse syngeneic, H-2K-compatible B10 and H-2-incompatible B10.A(4R) tumor cells, but not YAC-1 cells. One clone had cytotoxic activity against syngeneic, H-2D-compatible B10.D2 tumor cells and YAC-1 cells, but not against H-2-incompatible tumor cells. One clone had cytotoxic activity against syngeneic and YAC-1 tumor cells, but not against either H-2-compatible or H-2-incompatible tumor cells. One clone had lytic activity to syngeneic, H-2-compatible, H-2-incompatible, and YAC-1 tumor cells. Another clone killed H-2-incompatible B10.A(4R) tumor and YAC-1 cells, but not syngeneic or H-2-compatible tumor cells. All these clones strongly expressed surface Thy-1.2 antigens, whereas the expression of Lyt-1.2 and Lyt-2.2 antigens was different from clone to clone. These results demonstrate heterogeneity of both lytic specificity and phenotype of CTL against RSV-induced mouse tumor cells, suggesting the existence of multiple antigenic sites on the RSV TSSA recognized by CTL populations.     

Production of heterologous antibodies to T-killers of mice immunized against H-2 antigens

Rabbit antisera were obtained against cytotoxic small peritoneal lymphocytes (IPEL) of CBA (H-2k) mice immune to alloantigens C57BL/6 (H-2b) and to the enriched 5-day MLC cytotoxic blast lymphocytes (MLC--CL). After appropriate absorption by cells and tissues of intact mice the cytotoxicity of the sera was lost relative to normal lymphoid cells. The absorbed anti-CPL serum inhibited, in the presence of complement, the cytotoxic effect of CPL but not that of MLC--CL on 51Cr-labeled allogeneic macrophages. This inhibition was restricted by idiotypic and strain specificity. Conversely, the absorbed anti-MLC--CL serum inhibited the cytotoxic effect of both CPL and MLC--CL of various mouse strains, irrespective of their immunologic specificity. It is supposed that the effect of the anti-CPL serum is mainly caused by antibodies againts idiotypic determinants of the killer T receptors, whereas the effect of the anti-MLC--CL serum is due to antibodies against differentiation antigens of the proliferating lymphocytes.     

Resistance to cell-mediated cytotoxicity is correlated with reduction of H-2K gene products in AKR leukemia

AKR leukemia cell lines differing in the amount of H-2K and H-2D antigens expressed on the cell surface were used to assess cell-mediated immune responses in syngeneic mice against Gross/AKR murine leukemia virus (MuLV)-induced tumors. Leukemic cells with reduced expression of H-2K^k antigens were inactive as inducers of Gross-MuLV/H-2^k-specific cytotoxic T lymphocytes (CTL) and resistant to lysis by CTL raised against H-2K^k positive AKR leukemia cells. H-2K^k positive leukemias induced cytotoxic effectors, which upon restimulation in vitro, lysed the stimulating and other H-2K^k positive leukemia cells. In antibody inhibition experiments, T-cell-mediated cytotoxicity to these leukemias could only be inhibited by antisera and monoclonal antibodies specific for the H-2K^k antigens. Due to this specific role of H-2K^k antigens in T-cell cytotoxicity to Gross/AKR MuLV-induced tumors, reduced expression of H-2K^k antigens on spontaneous AKR leukemic cells could have important implications for surveillance of these neoplastic cells.Abbreviations used in this paper CTL cytotoxic T lymphocytes - MuLV murine leukemia virus     

Continuously proliferating T killer cells specific for H-2b targets: selection and characterization.

BALB/c (H-2d) thymus-derived lymphocytes sensitized to C57BL/6 (H-2b) alloantigens have been propagated in vitro for over 9 months. These T lymphocytes are specifically cytotoxic to H-2b target cells but are stimulated to proliferate by both H-2b and H-2k spleen cells. This indicates that for these selected cells the antigen requirements for cell proliferation are different from those for cell-mediated cytotoxicity. If not continuously stimulated with allogeneic spleen cells, the cytotoxic cultures fail to divide and rapidly lose their cytotoxic activity. Allogeneic erythrocytes do not stimulate cell proliferation in "quiescent" cell cultures and allogeneic tumor cells do so only in the presence of spleen cells. However, "quiescent" cell cultures display cytotoxicity in the presence of phytohemagglutinin A as do cell cultures which have lost their cytotoxic activity although they proliferate upon allogeneic stimulation. The significance of these findings is discussed.     

Cell types required for H-2-restricted cytotoxic responses generated by trinitrobenzene sulfonate-modified syngeneic cells or trinitrophenyl-conjugated proteins.

Murine spleen cells were fractionated over nylon wool or Sephadex G-10 columns, and the cell types involved in the generation of trinitrophenyl (TNP)-specific, H-2 restricted (TNP-self) cytotoxic effector cells were studied from cultures stimulated with trinitrobenzene sulfonate (TNBS)-modified syngeneic cells, TNP-conjugated soluble proteins such as bovine gamma-globulin (TNP-BGG), or bovine serum albumin (TNP-BSA). Unfractionated or nylon nonadherent responding cells generated such effectors, irrespective of whether the cultures were stimulated with TNBS-modified cells or TNP-conjugated proteins. TNP-modified T lymphocytes, B lymphocytes, and phagocyte-enriched spleen cells were all capable of stimulating TNP-self effectors. TNP-self effectors. TNP-self as well as allogeneic cytotoxic responses were dependent on the presence of a radioresistant non-T cell that was removed by Sephadex G-10 fractionation and was replaced by irradiated, Thy 1.2-negative, glass adherent spleen cells, enriched in phagocytic cells. Results obtained by using glass adherent cells that were allogeneic or semi-syngeneic to the responding cells indicated that H-2 homology was not required for efficient glass adherent cell function, and that the H-2 restriction of TNP-self effectors is not determined by these glass adherent cells.     

Apparent lack of H-2 restriction of allograft rejection.

BALB/c ByJ (H-2d) mice immunized with tail skin grafts of either B10.D2 (H-2d) or B10 (H-2b) demonstrated similar second set rejection of B10.D2 tail skin. This apparent lack of H-2 restriction was not due to the induction of a new population of cytotoxic T lymphocytes (Tc) since 450R given 24 hr before the challenge graft did not abrogate the second set reactivity. Host macrophage processing or anti-Qa-2 reactivity was also not the explanation for the lack of H-2 restriction since immunization of BALB/c Li mice with either B10.D2 or B10 tail skin grafts resulted in second set rejection of B10 tail skin. Shared public H-2 specificities of H-2d and H-2b may result in cross-reactive Tc, thus causing the apparent lack of H-2 restriction. However, no H-2 restriction of allograft rejection is observed when only one public H-2 specificity is shared between the recipient and the allogeneic challenge graft (H-2f and H-2k combination). These results suggest that H-2 restriction of T cell cytotoxicity has little relevance in allograft rejection because 1) one public H-2 specificity is sufficient to cause cross-reactivity or 2) Tc are not the major effectors of allograft rejection.     

Murine CD8+ cytotoxic T lymphocytes lyse Toxoplasma gondii-infected cells

Studies were performed to determine whether CTL against Toxoplasma gondii-infected cells could be induced in a murine model of T. gondii infection in which CD8+ T lymphocytes have been shown to play a major role in resistance against this parasite. In 51Cr release assays, nylon wool nonadherent spleen cells from BALB/c (H-2d) mice immunized with the temperature-sensitive (ts-4) mutant strain of T. gondii were cytotoxic for T. gondii-infected P815 (H-2d) mastocytoma cells but not for uninfected cells. This cytotoxic activity was remarkably increased after in vitro stimulation with T. gondii-infected syngeneic spleen cells. The effector cells were shown to be CD8+ T lymphocytes, because the cytotoxicity was significantly inhibited by depletion of CD8+ T lymphocytes but not by depletion of CD4+ T lymphocytes. This cytotoxic activity was genetically restricted. Spleen cells from T. gondii-immune BALB/c mice were not cytotoxic for T. gondii-infected EL4 (H-2b) thymoma cells, whereas spleen cells from T. gondii-immune C57B1/6 (H-2b) mice were cytotoxic for T. gondii-infected EL4 cells but not for T. gondii-infected P815 cells. The cytolytic activity of CD8+ T lymphocytes against T. gondii-infected cells might be a mechanism whereby these cells confer resistance against T. gondii.     

H-2 Effects on cell-cell interactions in the response to single non-H-2 alloantigens

Mice expressing mutant H-2Kb alleles were tested for their ability to generate cytotoxic effector T-cells specific for the non-H-2 histocompatibility alloantigen H-4.2. Cytotoxic effectors specific for H-4.2 are preferentially restricted by the Kb allele. Mutant Kb alleles were observed to differentially regulate the magnitude of the H-4.2-specific cytotoxic effector response. Mice expressing the Kbm5, Kbm6, Kbm7, and Kbm9 alleles generated cytotoxic T-cells to the same level as mice expressing the wild-type Kb allele. Kbm8 and Kbm11 responders generated intermediate levels of effectors, whereas Kbm1, Kbm3, and Kbm10 responders did not generate detectable levels of cytotoxic effectors. Kbm4 responders produced high levels of H-4.2-specific cytotoxic effectors that were variably reactive with wild-type Kb antigens with no H-4.2. The ability to generate H-4.2-specific effectors generally correlated with (1) the ability of mutant Kb molecules to present H-4.2 to wild-type Kb-restricted effectors, and (2) the position of the respective amino acid interchanges on the Kb molecule. Mutations that altered the amino acid sequence in the vicinity of the disulfide bond in the C1 domain had the greatest deleterious effects on Kb-controlled responsiveness to H-4.2. The only exception was the Kbm11 intermediate responder, which differs from Kbm3 in both responsiveness and in a single amino acid interchange. Therefore, the amino acid sequence in the vicinity of the disulfide bond in the C1 domain plays a prominent role in determining the H-4.2-specific immune response potential. These observations are the first to clearly demonstrate association between particular MHC gene product, amino acid sequences and immune responsiveness.