A new cytotoxic lymphocyte-defined antigen coded by a gene closely linked to theH-3 locus

F₁ complementation results indicate that a new gene, putatively controlling a minor histocompatibility antigen, is closely linked to the minor histocompatibility gene,H-3, in the fifth linkage group of chromosome 2 of the mouse. This gene controls a product that was capable of inducing as well as acting as a target for cytotoxic lymphocytes (CTL). The lytic activity of CTL developed in B10.LP-H-3^b mice specific for the product of the new gene of B10 was restricted to target cells possessing H-2D^b antigens. This contrasts to the H-2K^b-restricted activity of H-3.1 specific CTL.     

Responses against antigens encoded by theH-3 histocompatibility locus: Antigens stimulating class I MHC- and class II MHC-restricted T cells are encoded by separate genes

The purpose of this work was to study the genetic basis of histocompatibility antigens encoded by the mouse minor histocompatibility (H) locusH-3. Both class I major histocompatibility complex (MHC)-restricted cytotoxic T lymphocytes (CTL) and class II MHC-restricted helper T cells (TH) specific for antigens encoded by genes within theH-3 locus were isolated and analyzed. Typing a number of mouse strains for expression of antigens recognized by these TH and CTL suggested that there was a different strain distribution pattern of expression of the antigens recognized by TH compared with those recognized by CTL. Separation of the genes whose products stimulate TH from those whose products stimulate CTL was suggested by: (1) analysis of the strain B10.FS(92NX)/Grf that has undergone recombination within theH-3 region; (2) genetic segregation studies of (B10.UW-H-3 ^b/Sn×C57BL/10Sn)F₂ mice; and (3) F₁ complementation studies in which CTL specific for products of the TH-defined gene(s) could not be detected, even in the absence of immune responses to products of the CTL-defined genes. Taken together, these data suggest that in addition to two genes (B2m andCd-1) within theH-3 region whose products typically stimulate class I MHC-restricted CTL, there is at least one additional gene whose product selectively stimulates class II MHC-restricted TH. This new gene is located telomeric from the CTL-defined genes and between the lociwe andun on chromosome 2. These data demonstrate a novel degree of complexity of theH-3 “locus” and suggest selective presentation of minor H gene products in the context of class I or class II MHC proteins.     

Resistance to H-2-restricted but not to allo-H2-specific graft and cytotoxic T lymphocyte responses in lymphoma mutant

The lymphoma mutant RMA-S escaped graft rejection after transplantation over a minor histocompatibility barrier, whereas it was rejected in H-2 allogeneic mice. The parental control line was rejected in both situations. The mutant, which had been selected against MHC class I molecules retained 5 to 10% of the wild-type H-2Db, Kb, and beta 2-microglobulin expression on the cell surface. It remained sensitive to allo-H-2b CTL in vitro, but was completely resistant to minor histocompatibility antigen-specific, H-2b-restricted CTL. It was equally resistant to other H-2b-restricted responses against internally derived Ag, such as tumor-specific CTL or a CTL clone specific for the influenza virus nucleoprotein. The results indicate a target cell defect that selectively abolishes the sensitivity to H-2-restricted CTL directed against internally processed Ag. This appears sufficient to shift the transplantation response over a minor histocompatibility Ag barrier from rejection to acceptance. There are two possible explanations for the results: 1) a block in the MHC class I-directed pathway for internal Ag processing, and 2) subthreshold H-2/Ag ligand density in relation to triggering requirements of restricted CTL. Regardless of the type of defect, the results demonstrate a difference between allo-H-2-specific and H-2-restricted CTL recognition at the level of the target cell.     

Induction and characterization of minor histocompatibility antigens. Specific primary cytotoxic T lymphocyte responses in vitro

A definite cytotoxic activity was developed in a BALB/c (H-2d) anti-DBA/2 primary mixed leukocyte culture (MLC), which received interleukin 2 (IL-2) on day 3 of culture. This cytotoxic activity was minor histocompatibility antigens (MIHA)-specific at the stimulator level, and was not developed in a syngeneic (BALB/c anti-BALB/c) MLC. The addition of IL-2 on day 3 of culture was crucial; no or very weak cytotoxic activity was developed in MLC receiving IL-2 on day 0 or on both day 0 and day 3. Only appropriate MIHA-allogeneic tumor cells were lysed as the target of the cytotoxic activity. The cytotoxic activity seemed MIHA-specific also at the target level; it lysed tumor cells of DBA/2 mouse origin but not those of BALB/c (syngeneic) origin. Phenotypes of the cytotoxic effector cell were Thy-1+ Lyt-2+. We concluded from these results that MIHA-specific cytotoxic T lymphocytes (CTL) were generated in the MIHA-allogeneic primary MLC. In this newly developed system, we studied genetic and antigenic requirements for primary anti-MIHA CTL responses in vitro. We demonstrated; among spleen cells (SC) of seven B10 H-2-congenic strains only SC of B10.D2 strain whose major histocompatibility complex (MHC) (H-2d) was compatible with the responder MHC effectively stimulated responder BALB/c (H-2d) SC for an anti-MIHA (DBA-C57BL-common) CTL response. Similarly, only SC of two out of seven C x B recombinant inbred strains (C x B.H and C x B.D), which were compatible at the MHC with responder SC, activated responder BALB/c SC for the response. The possibility that cells responding to H-2 alloantigens suppressed the anti-MIHA response was ruled out. Additional experiments showed that compatibility at the H-2K-end or the H-2D-end of the MHC was sufficient for a definite anti-MIHA response. These provided formal evidence that primary anti-MIHA CTL responses in vitro were MHC-restricted at the stimulator level. We then showed that sonication-disrupted SC or Sephadex G-10 column-passed nonadherent SC failed to stimulate responder SC for a primary anti-MIHA CTL response, whereas G-10-passed nonadherent SC responded well to adherent stimulator cells. Further study demonstrated that Ia+ adherent cells were the most active cell type as stimulator. Finally, we confirmed that the primary anti-MIHA CTL responses to adherent stimulator cells was MHC-restricted.     

The target minor H antigen for F1 cytotoxic T lymphocytes induced by Igh-congenic parental spleen cells is coded for by gene linked to H-2

Graft-vs-host reaction (GvHR) induced in (B10.BR X CWB)F1 (BWF1; H-2k/b, Ighb/b) by i.v. injection with CWB (H-2b, Ighb) spleen cells resulted in complete suppression of cytotoxic T lymphocyte (CTL) responsiveness of the F1 host spleen cells (GvHR-associated immunosuppression). In contrast, GvHR induced in BWF1 mice with CSW (H-2b, Ighj; Igh-congenic to CWB) spleen cells did not affect CTL responsiveness of the F1 host spleen cells at all. The BWF1 hosts undergoing the CSW-induced GvHR generated anti-CSW CTL in their spleens, and the subsequent culture of such BWF1 spleen cells with CSW stimulator cells, augmented the CTL activity. The BWF1 anti-CSW CTL lysed both Con A- and LPS-induced splenic blasts from mouse strains carrying the Ighj allele in the context of self H-2Kb. However, determination of the Igh haplotype in the serum IgG and of the susceptibility of the splenic lymphocytes to the BWF1 anti-CSW CTL on backcross mice, which carry either Ighb/j or Ighb/b in the context of H-2b/b or H-2b/k, showed clearly that Ighj and the gene coding for the target antigen for the BWF1 anti-CSW CTL segregated at ratios close to 1:1. The study in which linkage between the gene(s) coding for the target antigen for the BWF1 anti-CSW CTL and H-2 was examined on CWB X (C3H X CWB)F1 backcross mice and (B10.BR X CSW)F1 X B10 mice demonstrated that the gene, most likely a single gene, coding for the target antigen for the BWF1 anti-CSW CTL is located at 8.5 +/- 4.3 cross-over units to the right or left of the H-2 complex. We designated the minor H antigen to be recognized by the BWF1 anti-CSW CTL as H-X+, and we discuss the distinction between the H-X+ locus and the other minor H loci on chromosome 17.     

Cell surface expression of cytotoxic T lymphocyte-defined, AKR/Gross leukemia virus-associated tumor antigens by normal AKR.H-2b splenic B cells

We previously described a system in which H-2Kb-restricted C57BL/6 (B6) cytotoxic T lymphocytes (CTL) could be raised that were specific for tumors, such as the thymic lymphoma AKR.H-2b SL1, that were induced by endogenous AKR/Gross murine leukemia virus and that expressed the Gross cell surface antigen. In this study, certain normal lymphoid cells from AKR.H-2b mice were also found to express target antigens defined by such anti-AKR/Gross virus CTL. AKR.H-2b spleen, but surprisingly not thymus, cells stimulated the production of anti-AKR/Gross virus CTL when employed at either the in vivo priming phase or the in vitro restimulation phase of anti-viral CTL induction. This selective stimulation by spleen vs thymus cells was not dependent on the age of the mice over the range (3 to 28 wk) tested. Both AKR.H-2b spleen and thymus cells, however, were able to stimulate the generation of H-2-restricted B6 anti-AKR minor histocompatibility (H) antigen-specific CTL. Thus, AKR.H-2b spleen cells appeared to display the same sets (minor H and virus-associated) of cell surface antigens recognized by CTL as the AKR.H-2b SL1 tumor, whereas AKR.H-2b thymocytes were selectively missing the virus-associated target antigens, a situation analogous to that of cl. 18-5, a variant subclone of AKR.H-2b SL1 insusceptible to anti-AKR/Gross virus CTL. Like AKR.H-2b thymocytes, neither AKR spleen cells or thymocytes nor B6.GIX + thymocytes were able to stimulate the generation of anti-AKR/Gross virus CTL from primed B6 responder cell populations. In contrast, both T cell-enriched and B cell-enriched preparations derived from AKR.H-2b spleen cells were able to stimulate at the in vitro phase of induction, although B cell-enriched preparations were considerably more efficient. The discordant results obtained with AKR.H-2b spleen cells vs thymocytes were confirmed and extended in experiments in which these cells were employed as target cells to directly assess the cell surface expression of virus-associated, CTL-defined antigens. Thus, AKR.H-2b spleen cells, but not thymocytes, were recognized by anti-AKR/Gross virus CTL when fresh normal cells were tested as unlabeled competitive inhibitors, or when mitogen blasts were tested as labeled targets. Fresh or lipopolysaccharide-stimulated B cell-enriched spleen cells were as efficiently recognized as unseparated spleen cell preparations. Unexpectedly, fresh or Lens culinaris hemagglutinin-stimulated T cell-enriched spleen cell preparations, although susceptible to anti-minor H CTL, were almost as poor as targets for anti-viral CTL as were thymocytes. Together, these results demonstrate the H-2-restricted expression of CTL-defined, endogenous, AKR/Gross virus-associated target antigens by normal AKR.H-2b splenic B cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

CD3- bone marrow cells augment the generation of cytotoxic T lymphocytes showing a preference for the X-chromosome linked gene product of stimulator cells

Responder cells, composed of both a limited number of nylon wool-passed lymph node (NW-LN) cells and an excess number of CD3+ cell-depleted bone marrow (CD3- BM) cells from the same strain of mice, were stimulated with allogeneic spleen cells in vitro. The CD3- BM cells augmented the generation of allogeneic major histocompatibility complex (MHC) class I specific cytotoxic T lymphocytes (CTL) from NW-LN cells. C3H/He (H-2k, C3H background) responder cells were stimulated with either B10.D2 (H-2d, B10 background) or BALB/c (H-2d, BALB background) spleen cells. In the former stimulation, the CTL induced lysed B10.D2 target cells more efficiently than the BALB/c cells. Furthermore, these CTL lysed more (B10.D2 x BALB/c) F1 male target cells than (BALB/c x B10.D2) F1 male. In the latter stimulation, the CTL lysed more BALB/c than B10.D2 cells, and more (BALB/c) x B10.D2) F1 male than (B10.D2 x BALB/c) F1 male. The reciprocal mixed lymphocyte cultures (MLC) were carried out, in which BALB/c responder cells were stimulated with either C3H/He or B10.BR (H-2k, B10 background) spleen cells. In the former stimulation, the CTL induced lysed more C3H/He or (C3H/He x B10.BR) F1 male target cells than B10.BR or (B10.BR x C3H/He) F1 male, and in the latter, the reciprocal results were obtained. These results suggested that the CTL induced had a preference for the X-chromosome linked gene products (Xlgp), besides the specificity for the allogeneic MHC class I, of the mice used as stimulator.     

Possible mechanisms by which the H-2Kbm3 mutation may decrease cytotoxic T-lymphocyte recognition of vesicular stomatitis virus nucleoprotein antigen.

Spleen cells from C57BL/6 (B6) mice generate a strong in vitro cytotoxic T-lymphocyte (CTL) response specific for vesicular stomatitis virus (VSV). Spleen cells from VSV-primed B6-H-2bm3 (bm3) mice, which have a mutation in H-2Kb, require approximately 10-fold more UV-inactivated VSV to generate in vitro secondary anti-VSV CTL, compared with spleen cells from primed B6 mice. Anti-VSV CTL elicited in both bm3 and B6 mice are primarily specific for the viral nucleocapsid protein (N protein), as demonstrated by using recombinant vaccinia viruses that express the VSV N protein. bm3 CTL were found to exhibit only a very low level of lytic activity when tested against autologous VSV-infected concanavalin A spleen cell blasts as well as several H-2b tumor cell lines. The weak anti-VSV response of bm3 CTL was found to be the result of a combination of inefficient recognition of VSV-infected target cells and decreased elicitation of secondary effector cells. VSV-infected bm3 target cells were not killed as well as B6 targets by either bm3 or B6 effectors. This is because of the inefficient recognition of targets, as demonstrated by the fact that VSV-infected bm3 cells were unable to competitively inhibit the lysis of VSV-infected B6 target cells by either bm3 or B6 effectors. By using cells from recombinant mice, it was shown that the CTL response restricted by H-2Kb was low in the bm3 mice, compared with that of the B6 mice. However, the H-2Db-restricted CTL activity was similarly low in both the B6 and bm3 mice. The possibility that the low response to VSV-infected bm3 cells is caused by differences between the bm3 and B6 cells in expression of either viral antigens or H-2K was investigated by radiolabeling and immunoprecipitation. VSV-infected B6 and bm3 cells were found to express equivalent levels of both viral antigens and H-2K. These results indicate that the bm3 mutation alters a functional site on the H-2Kb molecule that is involved in the recognition of VSV-infected cells. The observation that elicitation of bm3 CTL can occur at high antigen doses further suggests that the bm3 mutation results in a lower affinity of H-2K either for viral antigen or for receptor sites on the CTL.     

Pretreatment with minor histocompatibility antigens prevents the development of functional CTL helper cell activity

We have been studying the regulation of allogeneic cytotoxic cells (CTL) in vivo. CBA/J (H-2k, mls d) responder mice are unable to develop CTL after an allogeneic footpad immunization if they are pretreated i.p. with spleen cells from either C3H/HeN (H-2k, mls c) or B10.BR (H-2k, mls b) mice. These mouse strain combinations are H-2 compatible but differ at the Mls and other minor histocompatibility loci. We reported that this state of CTL unresponsiveness is specific and that the allogeneic cells used for footpad immunization and the pretreatment strain must share both minor antigens and part of the MHC. In this paper, we describe some of the characteristic features of this CTL unresponsiveness. The CBA host plays an active role and appears to down-regulate its subsequent response against minor antigens after the initial pretreatment. This statement is based on the following: 1) The inhibition of in vivo CTL generation can be achieved by injecting F1 or irradiated C3H cells, i.e., under conditions where GVHD was not a factor; and 2) the state of unresponsiveness is abolished by host treatment with cyclophosphamide. In addition, we demonstrate that the lack of CTL development in pretreated responder animals is the result of impaired helper cell activity. Draining LNC from unresponsive mice can become functionally cytolytic if cultured in a Con A-activated spleen cell supernatant. However, normal CTL responses were not restored after adult thymectomy or splenectomy. Thus, the state of CTL inhibition that is induced by the minor antigen pretreatment is the result of a host-mediated regulatory circuit.     

Generation of cytotoxic T cells specific for minor histocompatibility antigens by cross challenge in vitro with H-2 disparate adherent cells

Although it is well known that an H-2-restricted cytotoxic T cell response to minor histocompatibility antigens (MIHA) can be primed in vivo with H-2 disparate spleen cells, it has not been previously possible to induce cytotoxic T lymphocyte (CTL) precursors (CTLp) in vitro by this type of challenge. In this work, we demonstrate that the inability to cross challenge in vitro is due to the existence of inhibitory effects that can be obviated by cell fractionation, and to insufficient priming in vivo. BALB/c CTLp (H-2d) that have been repeatedly primed in vivo with B10.D2 can be challenged in vitro with C57BL10/J (H-2b) or B10.BR (H-2k)-adherent cells to generate CTL able to lyse B10.D2 (H-2d) target cells. The H-2 restriction properties of the cross-challenged CTL specific for MIHA were analyzed by using the technique of cold target competition. Within the limits of detection in bulk cultures, the entire response appeared to be H-2 unrestricted, whether the cross challenge was with intact C57BL10/J-adherent cells, or with membrane fragments of C57BL10/J presented by BALB/c adherent cells. The frequency of CTLp responsive to cross challenge was analyzed by limiting dilution, with cold target competition at each cell number to establish the restriction properties of the MIHA-specific CTL induced. We were able to detect two subsets of H-2-unrestricted CTLp responsive to intact C57BL10/J-adherent cells; one present at high frequency (1/250 T cells) and subject to suppressive effects at high cell number, and a second present at lower frequency (1/9800 T cells). There appeared to be a relatively infrequent subset of H-2-restricted CTLp as well (1/52,500 T cells). The frequency of CTLp responsive to cross challenge is of comparable magnitude to the frequency of H-2-restricted CTLp responsive to H-2-matched cells bearing MIHA. These observations are discussed in relationship to immunodominance and clonal dominance effects in the response to MIHA.     

Virus specificity of cytotoxic T lymphocytes generated during acute lymphocytic choriomeningitis virus infection: role of the H-2 region in determining cross-reactivity for different lymphocytic choriomeningitis virus strains

We have compared the relatedness of five different strains of lymphocytic choriomeningitis virus (LCMV) as assessed by LCMV-specific cytotoxic T lymphocytes (CTL). Several different mouse strains were injected with each of the five LCMV strains, and the cross-reactivity of virus-specific CTL generated during the acute infection was tested by killing on a panel of target cells infected with the various LCMV strains. We found that the cross-reactivity pattern of LCMV-specific CTL generated in mice of H-2d haplotype (BALB/c WEHI and DBA/2) was strikingly different from that in mice of H-2b haplotype (C57BL/6 and C3H.Sw/Sn), suggesting that the fine specificity of LCMV-specific CTL is a function of the H-2 region. The characteristic cross-reactivity patterns were also observed in (C57BL/6 X DBA/2)F1 mice, demonstrating that the repertoire of the H-2b- and H-2d-restricted LCMV-specific CTL is not changed as a result of complementation by gene products of the other major histocompatibility haplotype. Studies with congenic BALB.B10 and (BALB.B10 X BALB/c)F1 mice firmly established that the characteristic cross-reactivity patterns of LCMV-specific CTL map to the H-2 region and are not influenced by background genes outside the major histocompatibility locus. These results suggest that LCMV determinants seen in the context of H-2d-restricting elements are different from those seen in the context of H-2b-restricting elements. Moreover, our studies show that CTL can be used as probes for dissecting differences among various LCMV strains, but the degree of relatedness between the different LCMV strains is not absolute when measured by CTL recognition. Since the H-2 region regulates the fine specificity of CTL generated during LCMV infection in its natural host, the degree of cross-protective immunity developed during a viral infection apparently depends on the major histocompatibility haplotype. The importance of these findings lies in understanding susceptibility or resistance of various host populations to viral infections and in designing vaccination programs to provide immunity.     

Generation of helper cell-independent cytotoxic T lymphocytes is dependent upon L3T4+ helper T cells

The role of L3T4+ (CD4+) Th cells in generation of CTL specific for discrete minor histocompatibility Ag was investigated. Suppression of the function of Th cells in vivo by chronic treatment with anti-L3T4 mAb prevented congenic strains of mice from being primed and from generating CTL specific for Ag encoded by the minor histocompatibility loci--H-3, H-1, and B2m. Analysis of proliferative responses and lymphokine secretion of cells from animals primed with one of these minor H Ag, beta 2-microglobulin, but not treated with anti-L3T4 antibodies, indicated that L3T4- class I MHC-restricted T cells were themselves responsible for the very great majority of the observed minor H Ag-specific proliferation and secretion of lymphokines associated with both T cell proliferation and activation of CTL. All together, the data indicate that in responses against discrete minor H Ag, L3T4+Th-independent CTL are generated through an L3T4+Th-dependent pathway.     

Frequency and cross-reactivity od cytolytic T lymphocyte precursors reacting against male alloantigens

It is well established that cytotoxic T lymphocytes (CTL) specific for the male minor histocompatibility antigen (H-Y) are generated by restimulation in vitro of in vivo primed spleen cells from C57BL/6 (H-2b) female mice with syngeneic male spleen cells. When tested on target cells from H-2 different strains, the male-specific C57BL/6 CTL populations exhibited significant lysis of DBA/2 (H-2d), A (H-2a), but not C3H (H-2k), male and female target cells. In an attempt to document this cross-reactivity further at the clonal level, a sensitive technique of limiting dilution analysis was used to determine the specificity of C57BL/6 individual CTL precursors (CTL-P) reactive against the male antigen. The mean frequency of anti-H-Y CTL-P in spleens of primed female mice was about 1/3500. Between one-third to one-tenth of these CTL-P produced a progeny that cross-reacted with H-2d (allogeneic) female target cells. These findings were confirmed by the analysis of the reactivity pattern exhibited by male-specific CTL clones derived by limiting dilution. Of 99 clones tested, 13 were found to cross-react with female DBA/2 target cells. These results thus indicate that a relatively large proportion (greater than 10%) of H-2b CTL-P directed against the H-Y antigen cross-react with target cells expressing H-2d alloantigens in the absence of H-Y antigen.     

Alloantigen-induced cytotoxicity against syngeneic tumor cells: analysis at the clonal level

It has been shown that peritoneal exudate cells (PEC) from BALB/c mice immunized with minor histocompatibility antigens presented by DBA/2 or B10.D2 spleen cells are capable of lysing syngeneic YC8 tumor cells in a 4-hr 51Cr-release assay. In this study, we employed limiting dilution analysis to determine the frequency of CTL precursors (CTL-P) reactive against both the specific DBA/2 (or P815) target and the syngeneic tumor YC8. The mean frequency of anti-DBA/2 CTL-P in PEC from BALB/c mice immunized with DBA/2 was 1/302. Between one-third and one-fifth of limiting dilution microcultures that exhibited lytic activity against DBA/2 lymphoblasts (or P815) were also able to lyse YC8. No lysis of YC8 was observed in the absence of a parallel lysis on DBA/2 lymphoblasts or P815 target cells. T cell clones, derived by micromanipulation from microcultures selected for cytotoxic activity against YC8 and/or P815, maintained either the specific anti-allogeneic or the doubly reactive ( antiallogeneic plus anti-syngeneic tumor) phenotype. Fourteen clones (six specific and eight doubly reactive) were tested for cytotoxic activity on a panel of target cells with different haplotypes. All showed H-2-restricted specificity for minor histocompatibility antigens shared by DBA/2 and B10.D2. The restriction element for some of the clones mapped in the K region of the H-2 complex, whereas for other clones the restriction element mapped in the D region; both K- and D-restricted clones were able to lyse YC8. When the clones that exhibited lysis on YC8 were tested on two other BALB/c tumor targets, LSTRA, a Moloney virus induced lymphoma, and RL male-1, a radiation induced lymphoma, two of seven were found to lyse all three syngeneic tumor targets equally well, but not syngeneic BALB/c blasts. These clones were functionally categorized as conventional CTL because they were unable to proliferate when cultured with antigen in the absence of exogenous lymphokines, and were unable to produce lymphokine with IL 2 activity when stimulated by the appropriate splenocytes. When tested in vivo in a Winn assay, a strong anti-tumor activity against YC8 was exerted by the anti-DBA/2 clones DY4 -3 and DY16 -3. These clones lysed both YC8 and the immunizing target cells in vitro. No in vivo effect in neutralizing YC8 tumor growth was observed with clone D2-1, a clone that lysed DBA/2 targets but not YC8 in vitro.     

Effect of graft-versus-host disease on anti-tumor immunity

BCL1, a spontaneous B cell leukemia of BALB/c origin, is rejected by C.B-20 (Ighb, H-40b) but not BALB/c (Igha, H-40a) mice. Adoptive transfer of C.B-20 anti-BCL1 effector cells specific for the minor histocompatibility Ag H-40a protects irradiated C.B-20 but not BALB/c recipients. Because C.B-20 donor cells could potentially generate graft-vs-host disease (GVHD) in BALB/c recipients, we investigated the possibility that GVHD prevents the anti-tumor effect. GVHD was induced in (C.B-20 X B10.D2)F1 [H-2d, H-40b X H-2d,H-40b] recipients after injection of B10.D2-primed C.B-20 donor cells. GVHD was indicated by the histologic appearance of tissue sections from C.B-20----F1 livers, target organs of GVHD, which showed a marked mononuclear cell infiltrate around the portal tracts and central veins. In addition, splenic lymphocytes from these mice had altered CD4/CD8 ratios and were unable to respond to the polyclonal activators Con A and LPS. The mitogen unresponsiveness was at least partially due to the presence of a suppressor cell, because proliferation of normal spleen cells to Con A and LPS was suppressed upon addition of C.B-20----F1 spleen cells. Further immune dysfunction was evident by the inability of T cells from mice with GVHD to generate a CTL response to H-2 alloantigens. Addition of C.B-20----F1 spleen cells to F1 responder cells at the induction of culture did not prevent generation of CTL, indicating that a suppressor cell was not responsible for the lack of CTL activity. In this setting of GVHD, F1 recipients were able to reject BCL1 upon adoptive transfer of C.B-20 anti-BCL1 effector cells. These data indicate that GVHD-induced immune dysfunction does not inhibit the activity of antileukemia T cells.     

Immunodominance in the graft-vs-host disease T cell response to minor histocompatibility antigens

Immunodominance controls the generation of CTL in the C57BL/6By (B6) anti-BALB.B H-2b-matched strain combination. Despite the potential of responding to numerous individual minor histocompatibility (H) Ag on BALB.B APC, the focus of the CTL response is largely specific for only a limited number of target Ag. These minor H Ag could be distinguished by their differential expression on a panel of target cells from the CXB recombinant inbred strains, the E, G, I, J, and K (all H-2b), which express different composites of the original BALB minor H Ag. A hierarchy was observed in which first-order immunodominant Ag were present on both CXBK and CXBG cells, whereas second-order dominant Ag were found on CXBE, CXBJ, and CXBI cells. To test whether immunodominance also plays a role in the development of lethal graft-vs-host disease (GVHD) directed to multiple minor H Ag, B6 T cells were transplanted along with T cell depleted bone marrow, to irradiated (825 rad) recipients of either the BALB.B or CXB recombinant inbred strains. The results indicate that a hierarchy of immunodominance does exist in GVHD, but it differs from that predicted from the in vitro CTL studies. GVHD was observed in BALB.B, CXBE, CXBI, and CXBJ recipients, but not in CXBG and CXBK recipients. Presensitization of B6 donor mice to CXBG or CXBK splenocytes 3 wk before transplant did not significantly increase the overall GVHD potential in the corresponding CXBG or CXBK recipients. Evidence for second-order immunodominance was provided by the transfer of CXBE T cells and ATBM to irradiated CXBG and BALB.B recipients with resultant, potent GVHD.     

Estimates of the precursor frequency of cytotoxic T lymhocytes against antigens controlled by defined regions of the H-2 gene complex: comparison of the effect of H-2 differences due to intra-H-2 recombination vs mutation.

Lymph node cells were sensitized in a limiting dilution assay against B10.D2 (H-2d) and the frequency of cytotoxic T lymphocyte (CTL.P) precursors was determined. A mean CTL.P frequency of 0.047% was observed when responding strains differed from the stimulators at the entire H-2 gene complex. When intra-H-2 recombinant strains were sensitized against B10.D2, lower frequencies of CTL.P were observed. Responding strains that differed from the stimulators at the H-2K-end only had 2- to 6-fold more CTL.P compared to strains sensitized against the D-end only. In order to study the CTL.P frequency against minor antigenic differences, the B10.D2 (M504-H-2da) mutant strain, which carries a mutation with an antigenic gain-loss in the D-region of H-2d, was examined. This mutant showed an identical CTL.P frequency against H-2d as H-2D-end recombinant strains. Therefore, this H-2 mutant (M504) has either undergone extensive mutation or the qualitative nature of the antigenic loss in this strain results in a high CTL.P frequency against the strain of origin.     

Further evaluation of the pregnancy-linked down-regulation of the paternal antigen-specific splenic cytotoxic T lymphocyte activity in allogeneically pregnant mice.

Cytotoxic T lymphocyte (CTL) activity directed against paternal alloantigen was examined in allogeneically pregnant mice using various allogeneic combinations. The spleen cells from pregnant C57BL/6 (H-2b) mice mated with BALB/c (H-2d) male mice generated less anti-H-2d CTL after in vitro sensitization than those from unpregnant or syngeneically mated C57BL/6 mice. Different allogeneic combinations including the incompatibility at only D region of H-2 or minor histocompatibility loci were effective for downregulating the anti-paternal CTL activity in pregnancy. The downregulation of anti-paternal CTL activity induced by allogeneic pregnancy occurred at day 10 to day 18 of pregnancy, most extensively at day 14. The allogeneic pregnancy also downregulated the allogeneic CTL activities that had been amplified by injecting alloantigens before mating.     

Antiretroviral cytolytic T-lymphocyte nonresponsiveness: FasL/Fas-mediated inhibition of CD4(+) and CD8(+) antiviral T cells by viral antigen-positive veto cells

C57BL/6 (H-2(b)) mice generate type-specific cytolytic T-lymphocyte (CTL) responses to an immunodominant Kb-restricted epitope, KSPWFTTL located in the membrane-spanning domain of p15TM of AKR/Gross murine leukemia viruses (MuLV). AKR.H-2(b) congenic mice, although carrying the responder H-2(b) major histocompatibility complex (MHC) haplotype, are low responders or nonresponders for AKR/Gross MuLV-specific CTL, apparently due to the presence of inhibitory AKR. H-2(b) cells. Despite their expression of viral antigens and Kb, untreated viable AKR.H-2(b) spleen cells cause dramatic inhibition of the C57BL/6 (B6) antiviral CTL response to in vitro stimulation with AKR/Gross MuLV-induced tumor cells. This inhibition is specific (AKR.H-2(b) modulator spleen cells do not inhibit allogeneic MHC or minor histocompatibility antigen-specific CTL production), dependent on direct contact of AKR.H-2(b) cells in a dose-dependent manner with the responder cell population, and not due to soluble factors. Here, the mechanism of inhibition of the antiviral CTL response is shown to depend on Fas/Fas-ligand interactions, implying an apoptotic effect on B6 responder cells. Although B6.gld (FasL-) responders were as sensitive to inhibition by AKR.H-2(b) modulator cells as were B6 responders, B6.lpr (Fas-) responders were largely insensitive to inhibition, indicating that the responder cells needed to express Fas. A Fas-Ig fusion protein, when added to the in vitro CTL stimulation cultures, relieved the inhibition caused by the AKR.H-2(b) cells if the primed responders were from either B6 or B6.gld mice, indicating that the inhibitory AKR.H-2(b) cells express FasL. Because of the antigen specificity of the inhibition, these results collectively implicate a FasL/Fas interaction mechanism: viral antigen-positive AKR.H-2(b) cells expressing FasL inhibit antiviral T cells ("veto" them) when the AKR.H-2(b) cells are recognized. Consistent with this model, inhibition by AKR.H-2(b) modulator cells was MHC restricted, and resulted in approximately a 10- to 70-fold decrease in the in vitro expansion of pCTL/CTL. Both CD8(+) CTL and CD4(+) Th responder cells were susceptible to inhibition by FasL+ AKR.H-2(b) inhibitory cells as the basis for inhibition. The CTL response in the presence of inhibitory cells could be restored by several cytokines or agents that have been shown by others to interfere with activation-induced cell death (e.g. , interleukin-2 [IL-2], IL-15, transforming growth factor beta, lipopolysaccharide, 9-cis-retinoic acid) but not others (e.g., tumor necrosis factor alpha). These results raise the possibility that this type of inhibitory mechanism is generalized as a common strategy for retrovirus infected cells to evade immune T-cell recognition.     

Immunodominance in the T cell response to multiple non-H-2 histocompatibility antigens. IV. Partial tissue distribution and mapping of immunodominant antigens

The immunization of C57BL/6 responder mice with spleen cells from H-2-matched BALB.B donors, which differ by multiple non-H-2 histocompatibility (H) antigens, results in the generation of cytotoxic T lymphocytes (CTL) that are specific for only a limited number of immunodominant antigens. Previous analysis of the genes encoding these dominant antigens has not mapped these genes to any of the non-H-2 H loci defined by congenic strains. It would have been expected that the histogenetic techniques employed for congenic strain selection would have preferentially identified the "strongest" H antigens. Therefore, we have investigated the possibility that immunodominant antigens do not belong to the class of non-H-2 H antigens encoded by genes mapping to H loci defined and mapped by congenic strains. The first experiments were aimed at identifying antigens that were expressed by independently derived inbred strains and were cross-reactive with the immunodominant cytotoxic T cell target (CTT-1) antigen of BALB.B. Strong cross-reaction with the C3H.SW (H-2b) strain was observed; the C3H gene encoding this antigen was mapped with BXH recombinant inbred strains. Contrary to the mapping of the CTT-1 gene to chromosome 1 in BALB.B, the C3H gene was shown to map to either chromosome 4 or chromosome 7. This result indicates that identical, or at least extensively cross-reactive, non-H-2 antigens may be encoded by genes mapping to independently segregating loci in different inbred strains. The tissue distribution of immunodominant antigens was approached by determining the reactivity of CTL specific for these antigens with either lymphoid-derived or fibroblast-derived targets. These CTL effectively lysed lymphoblast and lymphoid tumor targets but did not lyse an SV40-transformed fibroblast line that was shown to be efficiently lysed by CTL specific for non-H-2 H antigens defined by congenic strains. Therefore, it was concluded that immunodominant antigens detected by B6 anti-BALB.B CTL have a restricted tissue distribution in comparison to non-H-2 H antigens defined by congenic strains. The implications of these results for our understanding of the origin and heterogeneity of non-H-2 cell-surface antigen recognized by effector T cells are discussed.