Surface markers of T cells causing lethal graft-vs-host disease to class I vs class II H-2 differences

Information was sought on the phenotype of lymphoid cells causing lethal graft-vs-host disease (GVHD) in irradiated mice expressing whole or partial H-2 differences. In all strain combinations tested, pretreating donor lymph node (LN) cells with anti-Thy-1 monoclonal antibodies (MAb) plus complement (C) abolished mortality. With GVHD directed to class I H-2 differences, pretreating LN cells with anti-Lyt-2 MAb prevented mortality, whereas MAb specific for Ly-1 or L3T4 cell surface determinants caused severe mortality. These data imply that lethal GVHD directed to class I H-2 differences is mediated by L3T4-, Lyt-2+ cells; this subset of T cells was shown previously to control GVHD directed to multiple minor histocompatibility antigens, i.e., antigens seen in the context of self-class I molecules. With whole H-2 differences, GVHD appeared to be controlled largely but not exclusively by L3T4+, Lyt-2-T cells. This T cell subset was also the predominant cause of GVHD directed to class II differences. With class II incompatibilities, depleting donor cells of L3T4+ T cells, either by pretreatment with anti-L3T4 MAb + C or by fluorescence activated cell sorter selection, greatly reduced but did not completely abolish GVHD. These data might imply that L3T4-, Lyt-2+ cells have some capacity to elicit anti-class II GVHD. A more likely possibility, however, is that the residual GVHD to class II differences observed with Lyt-2+-enriched cells reflected minor contamination with L3T4+ cells.     

CD4+ T cells generated de novo from donor hemopoietic stem cells mediate the evolution from acute to chronic graft-versus-host disease

Acute and chronic graft-versus-host disease (GVHD) remain the major complications limiting the efficacy of allogeneic hemopoietic stem cell transplantation. Chronic GVHD can evolve from acute GVHD, or in some cases may overlap with acute GVHD, but how acute GVHD evolves to chronic GVHD is unknown. In this study, in a classical CD8+ T cell-dependent mouse model, we found that pathogenic donor CD4+ T cells developed from engrafted hemopoietic stem cells (HSCs) in C57BL/6SJL(B6/SJL, H-2(b)) mice suffering from acute GVHD after receiving donor CD8+ T cells and HSCs from C3H.SW mice (H-2(b)). These CD4+ T cells were activated, infiltrated into GVHD target tissues, and produced high levels of IFN-gamma. These in vivo-generated CD4+ T cells caused lesions characteristic of chronic GVHD when adoptively transferred into secondary allogeneic recipients and also caused GVHD when administered into autologous C3H.SW recipients. The in vivo generation of pathogenic CD4+ T cells from engrafted donor HSCs was thymopoiesis dependent. Keratinocyte growth factor treatment improved the reconstitution of recipient thymic dendritic cells in CD8+ T cell-repleted allogeneic hemopoietic stem cell transplantation and prevented the development of pathogenic donor CD4+ T cells. These results suggest that de novo-generated donor CD4+ T cells, arising during acute graft-versus-host reactions, are key contributors to the evolution from acute to chronic GVHD. Preventing or limiting thymic damage may directly ameliorate chronic GVHD.     

CD4+CD25+ regulatory T cells preserve graft-versus-tumor activity while inhibiting graft-versus-host disease after bone marrow transplantation

Mature donor T cells cause graft-versus-host disease (GVHD), but they are also the main mediators of the beneficial graft-versus-tumor (GVT) activity of allogeneic bone marrow transplantation. Suppression of GVHD with maintenance of GVT activity is a desirable outcome for clinical transplantation. We have previously shown that donor-derived CD4+CD25+ regulatory T cells inhibit lethal GVHD after allogeneic bone marrow transplantation across major histocompatibility complex (MHC) class I and II barriers in mice. Here we demonstrate that in host mice with leukemia and lymphoma, CD4+CD25+ regulatory T cells suppress the early expansion of alloreactive donor T cells, their interleukin-2-receptor (IL-2R) alpha-chain expression and their capacity to induce GVHD without abrogating their GVT effector function, mediated primarily by the perforin lysis pathway. Thus, CD4+CD25+ T cells are potent regulatory cells that can separate GVHD from GVT activity mediated by conventional donor T cells.     

L3T4-positive T cells participate in the induction of graft-vs-host disease in response to minor histocompatibility antigens

The phenotype of T cells that initiate graft-vs-host disease (GVHD) in response to minor histocompatibility antigens (minor HA) was determined in three H-2 compatible strain combinations by using negative selection with monoclonal antibodies to Lyt-2 and L3T4 antigens to test the hypothesis that Lyt-2-positive T cells alone initiate GVHD. The phenotype of T cells required to initiate GVHD was different in each of the three strain combinations studied. Both Lyt-2+ and L3T4+ LP spleen cells were necessary to cause lethal GVHD in C57BL/6 recipients. In the reciprocal transplant, Lyt-2+, but not L3T4+ C57BL/6 spleen cells were sufficient to initiate GVHD in LP recipients. In contrast, L3T4+, but not Lyt-2+ B10.D2 spleen cells were found to initiate GVHD in BALB/c recipients. The optimal response to minor HA requires both Lyt-2+ and L3T4+ T cells because a mixture of the two subsets of spleen cells resulted in a more severe form of GVHD than either subset alone in all three strain combinations studied. This study demonstrates that L3T4+ cells participate in the initiation of GVHD in response to minor HA. The dominant T cell subset that initiates GVHD varies with the specific strain combination tested. The specific minor HA expressed in the transplant recipient, the H-2 type, and possibly non-major histocompatibility complex immune response genes of the donor strain appear to determine the phenotype of the initiator T cells.     

T cell subsets mediating lethal graft versus host disease: demonstration that synergy between CD4+ and CD8+ T cells is the predominant mechanism in low responder rat strains

T cell subsets from rat strains that have been characterized as high and low responders to alloantigen were examined for their capacity to mediate lethal graft versus host disease (GVHD) across strain combinations incompatible for class I, class II, and non-MHC antigens. Inocula of 5 X 10(7) lymph node and spleen cells (LC) from low responder DA (RT1a) and high responder W/F (RT1u) strains caused lethal GVHD in (W/F X DA)F1 hybrids given 6 Gy whole body irradiation. W/F CD4+ (W3/25+) cells (2 X 10(7], equal to the number in 5 X 10(7) LC mediated lethal GVHD but 10(8) DA CD4+ cells were required to cause lethal GVHD. CD8+ (MRC OX8+) cells (5 X 10(7] from W/F rats alone caused lethal GVHD but those from DA rats could not. Mixtures of CD4+ and CD8+ DA T cells, equivalent to the number in 5 X 10(7) LC, did mediate lethal GVHD, demonstrating that synergy between the subsets was the predominant mechanism with DA cells. These results suggest that differences in alloreactivity between the strains tested may be due to alternate requirements for the alloactivation of T cell subsets; the high responder subsets being self-sufficient and the low responder subsets being dependent upon each other.     

Alloreactive memory T cells are responsible for the persistence of graft-versus-host disease

Graft-vs-host disease (GVHD) is caused by a donor T cell anti-host reaction that evolves over several weeks to months, suggesting a requirement for persistent alloreactive T cells. Using the C3H.SW anti-C57BL/6 (B6) mouse model of human GVHD directed against minor histocompatibility Ags, we found that donor CD8(+) T cells secreting high levels of IFN-gamma in GVHD B6 mice receiving C3H.SW naive CD8(+) T cells peaked by day 14, declined by day 28 after transplantation, and persisted thereafter, corresponding to the kinetics of a memory T cell response. Donor CD8(+) T cells recovered on day 42 after allogeneic bone marrow transplantation expressed the phenotype of CD44(high)CD122(high)CD25(low), were able to homeostatically survive in response to IL-2, IL-7, and IL-15 and rapidly proliferated upon restimulation with host dendritic cells. Both allogeneic effector memory (CD44(high)CD62L(low)) and central memory (CD44(high)CD62L(high)) CD8(+) T cells were identified in B6 mice with ongoing GVHD, with effector memory CD8(+) T cells as the dominant (>80%) population. Administration of these allogeneic memory CD8(+) T cells into secondary B6 recipients caused virulent GVHD. A similar allogeneic memory CD4(+) T cell population with the ability to mediate persistent GVHD was also identified in BALB/b mice receiving minor histocompatibility Ag-mismatched B6 T cell-replete bone marrow transplantation. These results indicate that allogeneic memory T cells are generated in vivo during GVH reactions and are able to cause GVHD, resulting in persistent host tissue injury. Thus, in vivo blockade of both alloreactive effector and memory T cell-mediated host tissue injury may prove to be valuable for GVHD prevention and treatment.     

Immunodeficiency in graft-versus-host disease (GVHD). II. Effects of GVHD-induced suppressor cells on CD4+ T cell clones

Lethally irradiated mice transplanted with H-2-matched, minor histocompatibility-disparate bone marrow develop graft-vs-host disease (GVHD) that is associated with severe immunodeficiency. Splenocytes from such mice contain radioresistant cells that profoundly suppress normal lymphocyte function. We now show that GVHD-induced suppressor cells also inhibit the proliferation of CD4+ T cell clones specific for different Ag and class II MHC determinants. These suppressors have a dominant anti-proliferative effect, because they inhibit DNA synthesis in response to receptor-mediated stimulation and growth-promoting lymphokines, without abolishing lymphokine secretion or lymphokine receptor expression by the cloned T cells. The implications of these findings, and the usefulness of T cell clones for studying immune suppression, are discussed.     

Role of T cell subsets in lethal graft-versus-host disease (GVHD) directed to class I versus class II H-2 differences. II. Protective effects of L3T4+ cells in anti-class II GVHD

Detailed information was sought on the capacity of purified B6 L3T4+ cells to elicit lethal graft-versus-host disease (GVHD) in irradiated class II-different class I-identical (C57BL/6 (B6) x bm 12)F1 hosts. When B6 L3T4+ cells were transferred in small doses (10(5) to 10(6) together with donor bone marrow (BM) cells, the recipients all developed acute lethal GVHD and most of the mice died within 2 wk, probably from gut damage; this syndrome was conspicuous only in mice treated with very heavy irradiation, i.e., 1000 rad. In marked contrast to L3T4+ cells given in small doses, transfer of large doses of B6 L3T4+ cells to heavily irradiated (B6 x bm 12)F1 hosts paradoxically resulted in only limited mortality: most of the recipients survived for greater than 6 mo and manifested little or no evidence of ill health. It is suggested that the capacity of large doses of L3T4+ cells to protect mice against lethal GVHD is a reflection of T helper function: the cellular immunity provided by the donor L3T4+ cells enables the host to repel pathogens entering through damaged mucosal surfaces, with the result that GVHD becomes sublethal. The protective function of L3T4+ cells in the B6----bm 12 combination was only seen in hosts given donor BM. With transfer of donor L3T4+ cells plus host BM, even lightly irradiated recipients died rapidly from hemopoietic failure. Because this syndrome failed to occur in mice given a mixture of donor and host BM, it would appear that L3T4+ cells destroyed host lymphohemopoietic cells by direct cytotoxicity rather than via a bystander effect.     

Host NKT cells can prevent graft-versus-host disease and permit graft antitumor activity after bone marrow transplantation

Allogeneic bone marrow transplantation is a curative treatment for leukemia and lymphoma, but graft-vs-host disease (GVHD) remains a major complication. Using a GVHD protective nonmyeloablative conditioning regimen of total lymphoid irradiation and antithymocyte serum (TLI/ATS) in mice that has been recently adapted to clinical studies, we show that regulatory host NKT cells prevent the expansion and tissue inflammation induced by donor T cells, but allow retention of the killing activity of donor T cells against the BCL1 B cell lymphoma. Whereas wild-type hosts given transplants from wild-type donors were protected against progressive tumor growth and lethal GVHD, NKT cell-deficient CD1d-/- and Jalpha-18-/- host mice given wild-type transplants cleared the tumor cells but died of GVHD. In contrast, wild-type hosts given transplants from CD8-/- or perforin-/- donors had progressive tumor growth without GVHD. Injection of host-type NKT cells into Jalpha-18-/- host mice conditioned with TLI/ATS markedly reduced the early expansion and colon injury induced by donor T cells. In conclusion, after TLI/ATS host conditioning and allogeneic bone marrow transplantation, host NKT cells can separate the proinflammatory and tumor cytolytic functions of donor T cells.     

Donor APCs are required for maximal GVHD but not for GVL

Graft-versus-host disease (GVHD) is a major source of morbidity in allogenic stem cell transplantation. We previously showed that recipient antigen-presenting cells (APCs) are required for CD8-dependent GVHD in a mouse model across only minor histocompatibility antigens (minor H antigens). However, these studies did not address the function of donor-derived APCs after GVHD is initiated. Here we show that GVHD develops in recipients of donor major histocompatibility complex class I-deficient (MHC I(-)) bone marrow. Thus, after initial priming, CD8 cells caused GVHD without a further requirement for hematopoietic APCs, indicating that host APCs are necessary and sufficient for GHVD. Nonetheless, GVHD was less severe in recipients of MHC I(-) bone marrow. Therefore, once initiated, GVHD is intensified by donor-derived cells, most probably donor APCs cross-priming alloreactive CD8 cells. Nevertheless, donor APCs were not required for CD8-mediated graft-versus-leukemia (GVL) against a mouse model of chronic-phase chronic myelogenous leukemia. These studies identify donor APCs as a new target for treating GVHD, which may preserve GVL.     

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.     

Donor CD8+ T cells mediate graft-versus-leukemia activity without clinical signs of graft-versus-host disease in recipients conditioned with anti-CD3 monoclonal antibody

Donor CD8(+) T cells play a critical role in mediating graft-vs-leukemia (GVL) activity, but also induce graft-vs-host disease (GVHD) in recipients conditioned with total body irradiation (TBI). In this study, we report that injections of donor C57BL/6 (H-2(b)) or FVB/N (H-2(q)) CD8(+) T with bone marrow cells induced chimerism and eliminated BCL1 leukemia/lymphoma cells without clinical signs of GVHD in anti-CD3-conditioned BALB/c (H-2(d)) recipients, but induced lethal GVHD in TBI-conditioned recipients. Using in vivo and ex vivo bioluminescent imaging, we observed that donor CD8(+) T cells expanded rapidly and infiltrated GVHD target tissues in TBI-conditioned recipients, but donor CD8(+) T cell expansion in anti-CD3-conditioned recipients was confined to lymphohematological tissues. This confinement was associated with lack of up-regulated expression of alpha(4)beta(7) integrin and chemokine receptors (i.e., CXCR3) on donor CD8(+) T cells. In addition, donor CD8(+) T cells in anti-CD3-conditioned recipients were rendered unresponsive, anergic, Foxp3(+), or type II cytotoxic T phenotype. Those donor CD8(+) T cells showed strong suppressive activity in vitro and mediated GVL activity without clinical signs of GVHD in TBI-conditioned secondary recipients. These results indicate that anti-CD3 conditioning separates GVL activity from GVHD via confining donor CD8(+) T cell expansion to host lymphohemological tissues as well as tolerizing them in the host.     

Similarity and difference in the mechanisms of neonatally induced tolerance and cyclophosphamide-induced tolerance in mice

The mechanisms of cyclophosphamide (CP)-induced tolerance were investigated by comparing with those of neonatally induced tolerance. When C3H/He Slc (C3H; H-2k, Mls-1b) mice were given i.v. either AKR/J Sea (AKR; H-2k, Mls-1a) or (AKR x C3H)F1 (AKC3F1; H-2k, Mls-1a/b) spleen cells and treated i.p. with CP 2 days later, a long-lasting skin allograft tolerance to AKR was induced in each case without any signs of graft-vs-host disease (GVHD). However, typical signs of GVHD were observed in the C3H mice neonatally tolerized with AKR spleen cells, but not in those tolerized with AKC3F1 spleen cells. The expression of TCR V beta 6, which is strongly correlated with the reactivity to Mls-1a Ag (of donor AKR origin), in the periphery was quite different between the two types of tolerant C3H mice. Namely, in the lymph nodes of the C3H mice tolerized with AKR spleen cells and CP, only CD4(+)-V beta 6+, but not CD8(+)-V beta 6+, T cells selectively disappeared, whereas both of them were abrogated in the lymph nodes of the C3H mice neonatally tolerized of AKR. By contrast, in the thymus of the two types of tolerant C3H mice, both CD4+CD8- and CD4-CD8+ single-positive thymocytes expressing TCR V beta 6 were clonally deleted, suggesting that the thymic involvement was the same in each type of tolerance. These results suggest that the preferential disappearance of the CD4(+)-V beta 6+ T cells (of host origin) and the effector T cells of GVHD (of donor origin) occurred only in the periphery of the C3H mice tolerized with AKR spleen cells plus CP and was attributable to the destruction of Ag-stimulated T cells by the CP treatment. In contrast, the intrathymic clonal deletion of immature V beta 6+ T cells was a common mechanism for both of the tolerance induction systems.     

Anti-recipient cytotoxic T lymphocyte precursors are present in the spleens of mice with acute graft versus host disease due to minor histocompatibility antigens

A model for bone marrow transplantation across minor histocompatibility barriers was developed by using mouse strains that were H-2 identical and mutually non-reactive in MLC. Acute graft-vs-host disease was induced only when donor lymphoid cells were included in the marrow inoculum, in both C57BL/6 recipients of LP cells and BALB/c recipients of B10.D2/nSN cells. GVHD was prevented by treating the lymphoid cells with anti-Thy 1.2 and C before transplantation. Spleen cells from mice with acute GVHD were not directly cytotoxic to recipient strain target cells. However, when spleen cells from mice with GVHD were boosted in vitro to recipient strain stimulator cells they generated a specific anti-recipient cytotoxic response. Spleen cells from mice without GVHD did not generate a cytotoxic response in vitro. The cytotoxic effector cells and their precursors were shown to be T lymphocytes. This model and the in vitro method described may be useful in further studies of the immunobiology of GVHD due to minor histocompatibility antigens and of transplantation tolerance.     

IFN-gamma and Fas ligand are required for graft-versus-tumor activity against renal cell carcinoma in the absence of lethal graft-versus-host disease

To determine the mechanisms of graft-versus-tumor (GVT) activity in the absence of graft-versus-host disease (GVHD) against a solid tumor, we established two allogeneic bone marrow transplantation models with a murine renal cell carcinoma (RENCA). The addition of 0.3 x 10(6) donor CD8(+) T cells to the allograft increased the survival of tumor-bearing mice without causing GVHD. The analysis of CD8(+) T cells deficient in cytotoxic molecules demonstrated that anti-RENCA activity is dependent on IFN-gamma and Fas ligand (FasL), but does not require soluble or membrane-bound TNF-alpha, perforin, or TRAIL. Recipients of IFN-gamma(-/-) CD8(+) T cells are unable to reject RENCA compared with recipients of wild-type CD8(+) T cells and, importantly, neither group develops severe GVHD. IFN-gamma(-/-) CD8(+) T cells derived from transplanted mice are less able to kill RENCA cells in vitro, while pretreatment of RENCA cells with IFN-gamma enhances class I and FasL expression and rescues the lytic capacity of IFN-gamma(-/-) CD8(+) T cells. These results demonstrate that the addition of low numbers of selected donor CD8(+) T cells to the allograft can mediate GVT activity without lethal GVHD against murine renal cell carcinoma, and this GVT activity is dependent on IFN-gamma and FasL.     

Mls-1a-induced peripheral tolerance to host minor histocompatibility antigens in radiation bone marrow chimeras. Modification of T cell repertoire associated with active suppression and permanent presentation of host antigens.

Minor histocompatibility Ag (mHAg) can be responsible for the development of graft vs host reaction (GVHR) after bone marrow transplantation. In a mouse model, B10.D2 donor immunization against Mls-1a prevents lethal GVHR developed by CD4+ T cells against DBA mHAg in irradiated (DBA/2 x B10.D2)F1 hosts. Such F1 hosts become 100% chimeric and show long term survival (LS mice). The cellular mechanisms underlying the tolerance in LS mice was investigated. It was found that a state of tolerance can be induced in thymectomized F1 hosts. Although spleen cells from LS mice are able to initiate lethal GVHR in third-party H-2k-incompatible hosts, no GVHR is observed in secondary hosts incompatible for specific DBA/2 mHAg. Mixed lymphocyte experiments in vitro confirm that T cells from LS mice are unresponsive toward specific DBA/2 mHAg, although they are able to proliferate in response to H-2 or Mls-1a Ag. The responsiveness to Mls-1a correlates with the presence of V beta 6+ cells in LS mice, probably derived from mature T cells present in the donor inoculum. The tolerance in LS mice is not due to the lack of DBA/2 mHAg presentation; instead, permanent presentation of Ag (Ag I and Ag II) previously described as being responsible for lethal GVHR is consistently observed. A significant protection against GVHR is obtained by transferring normal B10.D2 cells together with spleen cells from LS mice, clearly indicating the contribution of active suppression in the state of tolerance; this is further confirmed by in vitro results obtained in limiting dilution assays. It is concluded that tolerance in chimeric LS mice 1) is due to a peripheral (thymus-independent) mechanism; 2) is specific for mHAg; 3) correlates with unresponsiveness of the repertoire to host mHAg, without alteration of the repertoire for H-2 and Mls-1a Ag; and 4) is associated with an active suppression and with a permanent presentation of at least two mHAg responsible for GVHR mortality.     

Induction of alloreactive CD4 T cell tolerance in molecular chimeras: a possible role for regulatory T cells

Induction of molecular chimerism following reconstitution of mice with autologous bone marrow cells expressing a retrovirally encoded allogeneic MHC class I Ag results in donor-specific tolerance. To investigate the mechanism by which CD4 T cells that recognize allogeneic MHC class I through the indirect pathway of Ag presentation are rendered tolerant in molecular chimeras, transgenic mice expressing a TCR on CD4 T cells specific for peptides derived from K(b) were used. CD4 T cells expressing the transgenic TCR were detected in mice reconstituted with bone marrow cells transduced with retroviruses carrying the gene encoding H-2K(b), albeit detection was at lower levels than in mice receiving mock-transduced bone marrow. Despite the presence of CD4 T cells expressing an alloreactive TCR, mice receiving H-2K(b)-transduced bone marrow permanently accepted K(b) disparate skin grafts. CD4+CD25+ T cells from mice reconstituted with H-2K(b)-transduced bone marrow prevented rejection of K(b) disparate skin grafts when adoptively transferred into immunodeficient mice along with effector T cells, suggesting that induction of molecular chimerism leads to the generation of donor specific regulatory T cells, which may be involved in preventing alloreactive CD4 T cell responses that lead to rejection.     

Induction of central deletional T cell tolerance by gene therapy

Transgenic mice expressing an alloreactive TCR specific for the MHC class I Ag K(b) were used to examine the mechanism by which genetic engineering of bone marrow induces T cell tolerance. Reconstitution of lethally irradiated mice with bone marrow infected with retroviruses carrying the MHC class I gene H-2K(b) resulted in lifelong expression of K(b) on bone marrow-derived cells. While CD8 T cells expressing the transgenic TCR developed in control mice reconstituted with mock-transduced bone marrow, CD8 T cells expressing the transgenic TCR failed to develop in mice reconstituted with H-2K(b) transduced bone marrow. Analysis of transgene-expressing CD8 T cells in the thymus and periphery of reconstituted mice revealed that CD8 T cells expressing the transgenic TCR underwent negative selection in the thymus of mice reconstituted with K(b) transduced bone marrow. Negative selection induced by gene therapy resulted in tolerance to K(b). Thus, genetic engineering of bone marrow can be used to alter T cell education in the thymus by inducing negative selection.     

T cells targeted against a single minor histocompatibility antigen can cure solid tumors

T cells responsive to minor histocompatibility (H) antigens are extremely effective in curing leukemia but it remains unknown whether they can eradicate solid tumors. We report that injection of CD8(+) T cells primed against the immunodominant H7(a) minor H antigen can cure established melanomas in mice. Tumor rejection was initiated by preferential extravasation at the tumor site of interferon (IFN)-gamma-producing H7(a)-specific T cells. Intratumoral release of IFN-gamma had two crucial effects: inhibition of tumor angiogenesis and upregulation of major histocompatibility complex (MHC) class I expression on tumor cells. Despite ubiquitous expression of H7(a), dissemination of a few H7(a)-specific T cells in extralymphoid organs caused neither graft-versus-host disease (GVHD) nor vitiligo because host nonhematopoietic cells were protected by their low expression of MHC class I. Our preclinical model yields unique insights into how minor H antigen-based immunotherapy could be used to treat human solid tumors.     

Multiple splenic lymphoid cell subpopulations regulate H-2 antigen expression on teratocarcinoma cells in vivo

Undifferentiated murine 402AX teratocarcinoma cells do not express MHC antigens when passaged in vitro or in vivo in genetically susceptible host mice. When passaged in vivo in genetically resistant mice, however, the tumor cells become H-2b antigen positive regardless of the H-2 haplotype of the resistant host mouse. The present studies use monoclonal anti-H-2b antibodies to corroborate these earlier findings, which were performed with conventional antisera. Previous studies have established that host bone marrow plus lymphoid cells from resistant primed donors regulate tumor cell H-2b antigen expression. Using bone marrow and mature lymphoid cell reconstitution techniques, the present studies indicate that splenic Ig- cells from genetically resistant host mice are the most efficient lymphoid cell subpopulation in tumor cell H-2b antigen induction. Ig+ spleen cells also reconstitute the capacity to induce teratocarcinoma cell H-2 antigens but are less effective than Ig- spleen cells. Tumor cell H-2 antigen induction in C57BL/6 beige mice is impaired compared to C57BL/6 hosts, which suggests that host NK cells may also be involved in tumor cell H-2 antigen induction. Reconstitution of lethally irradiated resistant hosts for teratocarcinoma cell H-2 antigen expression requires bone marrow plus resistant primed lymphoid cell subpopulations; bone marrow alone is insufficient. These results indicate that multiple splenic lymphoid cell subpopulations requiring a radiosensitive host environment and/or factor for differentiation regulate teratocarcinoma 402AX H-2b antigen expression in vivo in genetically resistant mice.