Induction of antiidiotypic antibodies by donor-specific blood transfusions. Establishment of a human-mouse hybridoma secreting the MLR-inhibiting factor

We describe a patient transfused with 200 ml of donor fresh whole blood three times at 2-week intervals. Three weeks after the last transfusion, transplantation and splenectomy were done at the same time. Splenic cells from this DST pretreated patient were fused with murine myeloma cells (X63-Ag8, 653). With DST pretreatment, various clones were developed in vivo, and finally 69 human immunoglobulin-secreting clones were obtained. Modulation of the alloantigen-specific MLR by supernatants from 69 clones showed various degrees of suppression or augmentation. The hybridoma clone 7 and clone 2, which had been secreting IgG antibody for more than 6 months, showed some degree of suppression in the alloantigen-specific MLR (mean suppression = 63%, 46% respectively). According to the result of MLR, clone 7 antibody was directed against recipient lymphocytes and clone 2 antibody was against donor lymphocytes. Immunoprecipitation was carried out by clone 7-IgG and clone 2-IgG. Clone 7-IgG specifically precipitated 1 molecule from the recipient lymphocyte with a molecular weight of 120 KD, similar to the molecular weight range reported for T cell receptors. Clone 2-IgG precipitated a 20 KD molecule from the donor lymphocyte. The data suggest that DST induces antibodies directed against the blood donor alloantigen-specific receptors on the recipient's T lymphocytes--and, at the same time, induces antibodies against donor lymphocyte antigens. These antibodies may be essential to prolongation of kidney allograft survival following DST.     

伊马替尼联合供者淋巴细胞输注治疗造血干细胞移植后慢性粒细胞白血病复发

目的 探讨伊马替尼联合供者淋巴细胞输注(DLI)治疗异基因造血干细胞移植后慢性粒细胞白血病(CML)复发的效果.方法 3例CML(慢性期)患者,在接受预处理后,例1接受其胞妹外周血造血干细胞移植,例2接受其胞兄的骨髓移植,例3接受其胞弟的骨髓与外周血造血干细胞联合移植.例1移植后采用环孢素A(CsA)和霉酚酸酯(MMF)预防移植物抗宿主病(GVHD),例2采用CsA、短程甲氨蝶呤(MTX)、抗胸腺细胞球蛋白及抗CD25单克隆抗体预防GVHD,例3应用CsA、MTX和MMF预防GVHD.采用细胞遗传学及荧光原位杂交技术动态监测治疗效果.移植后发生血液学复发时,给予伊马替尼口服,并行DLI.结果 例1移植后30 d行DLI,输注CD3+T淋巴细胞0.5×107 /kg,移植后50 d和70 d,再次行DLI,分别输注CD3+ T淋巴细胞1.0 × 107 /kg和2.0×107 /kg,短串联重复序列(STR)检测提示为完全供者嵌合(DC).移植后120 d,疾病进展,给予伊马替尼400 mg/d,同时输注供者CD3+ T淋巴细胞2.5 × 107/kg.移植后180 d,STR检查提示仍为DC.患者最终于移植后17个月因髓外复发死亡.例2的染色体核型于移植后35 d转变为46,XY,XY为100%,BCR-ABL融合基因阴性.移植后100 d,原发病复发.停用免疫抑制剂,输入供者CD3+ T淋巴细胞3.9×107 /kg,同时口服伊马替尼500 mg/d.DLI联合伊马替尼治疗后30 d,患者的染色体核型为46,XY,XY为100%,BCR-ABL融合基因阴性,患者至今无病存活53个月.例3移植后5 d造血功能获得重建,移植后60 d,染色体核型为46,XY.移植后120 d,确诊CML复发,遂给予伊马替尼400 mg/d,并行DLI,共输注供者CD3+ T淋巴细胞8×107 /kg,1个月后,患者的染色体核型再次转为46,XY,患者至今无病存活50个月.结论 伊马替尼联合DLI对造血干细胞移植后CML复发具有一定的治疗效果.     

Infusion of in vitro-generated DN T regulatory cells induces permanent cardiac allograft survival in mice

Previously, we have demonstrated that pretransplant donor lymphocyte infusion (DLI) can activate recipient-derived CD3+CD4-CD8- double negative T regulatory (DN Tr) cells which have a potent immune regulatory function in vitro and in vivo. Here we studied the regulatory ability of DN T cell clones generated from the spleens of nai;ve anti-L(d) transgenic TCR+ (2C x dm2)F1 mice. We were able to identify subsets of DN T cell clones that were able to kill anti-Ld CD8+ T cells, and therefore had regulatory properties, and DN T cells with no regulatory properties. Next, we investigated the ability of these in vitro generated DN T cell clones to enhance cardiac allograft survival. (2C x dm2)F1 transgenic mice were infused with either regulatory or non-regulatory DN T cell clones, or left untreated one day before receiving an Ld-mismatched cardiac grafts from (C57BL/6 x Balb/c)F1 mice. Injection of non-regulatory DN T clone cells did not prolong cardiac graft survival in (2C x dm2)F1 mice when compare to untreated controls. In contrast, all of the cardiac grafts survived more than 100 days in mice that received DN Tr clone cells prior to transplantation. These results demonstrate that DN Tr cells can be generated in vitro and protect cardiac allograft from rejection when infused into recipients prior to transplantation. They also suggest that DN Tr cells may provide a novel therapy for the treatment of allograft rejection.     

Regulatory function of human CD4+ cytolytic T lymphocytes.

Allograft rejection is mediated by both CD4+ and CD8+ T cells. The lytic function of the classic CD8+ cytolytic T lymphocytes (CTL) occurs through recognition of allogeneic major histocompatibility complex (MHC) class I on the surface of the graft. CD4+ CTL recognize MHC class II through a direct recognition pathway or an indirect pathway where MHC peptides are presented in the context of self MHC class II. Lytic CD4+ cells may destroy graft tissue or, we hypothesize, the indirect CD4+ T cell may down regulate CD8+ CTL by recognition of donor MHC peptides presented by self MHC class II expressed on CD8+ T cells. To define the role of CD4+ CTL in allograft outcome we used a CD4+ CTL that is MHC class II restricted, recognizing human leucocyte antigen (HLA)-A1 and HLA-B8 peptides in the context of HLA-DR4. This line (MDSxA1/B8) will lyse DR4+ B lymphoblastoid cells (LCL) pulsed with HLA-A1/B8 peptides (amino acids 60-84 of the alpha1 domain of the MHC class I molecule). These T cells will also lyse peptide-pulsed antigen-specific T cell clones, both CD4+ and CD8+, that express HLA-DR4. These clones must process and present the MHC class I peptides for recognition and lysis to occur. These results suggest a possible mechanism to explain allograft tolerance. Lytic CD4+ T cells, that recognize donor HLA peptides through an indirect antigen presentation pathway, down-regulate donor-specific CTL through peptide-specific lysis resulting in graft tolerance.     

Specific cytotoxic activity of T lymphocyte clones derived from a patient with gliosarcoma

Eleven lymphocyte clones were established from the peripheral blood lymphocytes of a patient with gliosarcoma by means of autologous tumor stimulation and the limiting-dilution technique with recombinant interleukin-2. Ten of the 11 clones were cytotoxic against the autologous tumor cell line GI-1. Seven of the 10 clones were also cytotoxic against allogeneic brain-tumor lines and HeLa cells, one clone was cytotoxic against several target cells, and two clones were specifically cytotoxic against GI-1 and allogeneic brain-tumor cells. One of the 11 clones was not cytotoxic against any target cells tested. Lymphokine-activated killer cells induced by recombinant interleukin-2 alone exhibited cytotoxic activity against all target tumor cells tested. Surface phenotypic analysis revealed that all lymphocyte clones expressed CD3 antigen, some expressed CD4 antigen, and others expressed CD8 antigen. These clones seemed to be antigen-specific cytotoxic T lymphocyte clones. Analysis with these antigen-specific cytotoxic T lymphocyte clones may be useful in the elucidation of tumor-specific or tumor-associated antigens on autologous tumor cells.     

Immunoregulatory role of CD8alpha in the veto effect

BACKGROUND: Allogeneic bone marrow cell (allo-BMC) infusion induces tolerance to incompatible renal allografts in rhesus macaques after depletion of peripheral T lymphocytes with cytolytic anti-T cell antibodies. The tolerogenic effect of allo-BMC, ascribed to a veto mechanism, associates with specific functional deletion of antidonor cytotoxic T lymphocyte precursor (CTLp), and is dependent on a CD8+ donor BMC subset. In previous studies, the CD8 molecule was implicated by loss of suppression after blocking interaction between CD8 on allo-BMC and major histocompatibility complex class Ialpha3 domain on CTLp. CD8 cross-linking on BMC induced secretion of active transforming growth factor-beta1 (TGF-beta1), suggesting a regulatory mechanism(s) operating via a CD8-mediated signaling pathway. METHODS: CD8 on rhesus cells was cross-linked using IgG-conjugated beads, and TGF-beta1 mRNA and protein were quantified. CD8+ cells were tested for veto activity by mixed lymphocyte reaction (MLR)-induced cell-mediated lymphocytotoxicity (CML) assay. Activated rhesus T cells exposed to TGF-beta1 were examined for apoptosis by TdT-mediated end-labeling and annexin staining. RESULTS: CD8 cross-linking induces accumulation of TGF-beta1 mRNA and protein. Both CD3- CD8+CD16+ and CD3+ CD8+CD16- subsets of allo-BMC up-regulate TGF-beta1 mRNA after CD8 cross-linking, and exhibit veto activity. The CD3-CD8+CD16+ subset expresses more TGF-beta1 mRNA and increased veto activity at low BMC/CTLp ratios. Exposure of activated T cells to TGF-beta1 induces apoptosis. CONCLUSIONS: CD8+ allo-BMC are enriched for veto activity and activation via CD8 induces TGF-beta1 mRNA and protein accumulation. These results agree with the hypothesis that paracrine TGF-beta1 may be involved in peripheral deletion of alloreactive CTLp by CD8+ allo-BMC. We suggest that TGF-beta1 overexpression by donor lymphohematopoietic cells may enhance tolerance induction.     

A cytotoxic T-lymphocyte clone derived from mice with progressively growing tumors.

Tumor-specific T-cell clones were derived from spleen cells of mice bearing a syngeneic PHS-5 tumor (a P815 mastocytoma mutant). Cells were expanded in vitro and characterized and assayed for activity against the relevant tumor in vivo. Clone cells were CD4-, CD8+ T lymphocytes, as determined by fluorescence activated cell sorting analysis and were specifically cytotoxic against P815 tumor cells in vitro, as shown in chromium 51 release assays. These cells require both antigen and interleukin 2 to proliferate; neither alone is sufficient, even with the addition of interleukin 1. In an experimental P815 liver metastasis model, the adoptive transfer of GD11 or GD11.17 clone cells and injection of recombinant interleukin 2 (7500 U intraperitoneally) 3 days after infusion of tumor cells reduced the number of tumor nodules, while the adoptive transfer of lymphokine-activated killer cells was ineffective.     

Donor-specific antigen transfusion-mediated skin-graft tolerance results from the peripheral deletion of donor-reactive CD8+ T cells

BACKGROUND: The mechanism of donor-specific transfusion (DST)-induced long-term skin-graft survival is examined in 2CF1 (2C x dm2) transgenic and B6F1 (C57BL/6 x dm2) nontransgenic mice in which CB6F1 (Balb/c x B6) DST and donor skin grafts differ from 2CF1 or B6F1 recipients only at major histocompatibility complex class I Ld. METHODS: Saline (control) or allogeneic CB6F1 spleen cells were injected intravenously into 2CF1 and B6F1 mice. One week later, CB6F1 tail skin was transplanted onto the dorsum of these mice. Fluorescence-activated cell sorter analysis (flow cytometric analysis) of peripheral blood was performed 2 days before DST, 5 days after DST, and 7, 14, 21, 28, and 75 days after skin grafting. Splenocyte responsiveness was measured by in vitro mixed lymphocyte culture and cytotoxic T lymphocyte. Cytokine protein production (interleukin [IL]-2 and interferon-gamma) was measured by enzyme-linked immunosorbent assay. RESULTS: Whereas all CB6F1 skin grafts in control saline-treated 2CF1 and B6F1 mice were rejected, 100% of 2CF1 and B6F1 pretreated with CB6F1 DST accepted the class I Ld disparate donor skin indefinitely. DST followed by a CB6F1 skin graft led to a significant deletion of donor-reactive CD8+ T cells by fluorescence-activated cell sorter analysis and decreased production of the inflammatory cytokines IL-2 and interferon-gamma. The hyporesponsiveness of residual CD8+ T cells in mixed lymphocyte culture and cytotoxic T lymphocyte to Ld after DST was restored to normal by IL-2. CONCLUSION: These findings demonstrate that administration of DST uniformly results in long-term Ld+ skin-allograft acceptance. This tolerance induction is related to both a significant decrease in donor-reactive CD8+ transgenic T cells and anergy of the residual CD8+ T cells.     

Dissociation of tissue destruction induced by cytolytic T cells in vivo and cytotoxicity as measured in vitro

Two forms of local cutaneous graft-versus-host reactions were used to examine the in vivo activity of cytolytic T cells in a large number of antigen systems and mouse strain combinations. In immune lymphocyte transfer reactions (TrRs), CTL were injected intradermally into allogeneic hosts to which they were sensitized; in bystander reactions (ByRs), CTL were mixed with target cells and the mixture injected into hosts syngeneic to the CTL. Both reactions frequently culminate in full-thickness skin destruction. However, CTL highly active in cell-mediated lympholysis assays in vitro sometimes failed to induce significant reactions in vivo, and CTL with negligible CML activity often induced severe, necrotizing lesions. In addition, Clone 58, a non-MHC-specific CD8+ clone that originated from cells extracted from a sponge matrix allograft, lost its CML activity but continued to induce necrotizing TrRs and ByRs. Insofar as these reactions may exemplify the specific (TrR) and nonspecific (ByR) tissue injury that occurs in the rejection process, these findings question the reliability of CML for predicting the ability of CTL to induce the tissue destruction seen in allograft rejection.     

Pretransplant donor peripheral blood mononuclear cells infusion induces transplantation tolerance by generating regulatory T cells

BACKGROUND: It was suggested that maintenance of tolerance to organ transplantation may depend on the formation of T regulatory cells. METHODS: Lewis (LW) rats were made tolerant to a Brown Norway kidney by pretransplant donor peripheral blood mononuclear cells (PBMC) infusion. At greater than 90 days after transplantation, lymph node cells (LN) and graft-infiltrating leukocytes (GIL) alloreactivity was tested in mixed lymphocyte reaction (MLR), coculture, and transwell experiments. GIL phenotype was analyzed by FACS. mRNA expression of cytokines and other markers was analyzed on CD4+ T cells from LN. The tolerogenic potential of tolerant cells in vivo was evaluated by adoptive transfer. RESULTS: Tolerant LN cells showed a reduced proliferation against donor stimulators but a normal anti-third-party alloreactivity. In coculture, these cells inhibited antidonor but not antithird-party reactivity of na?ve LN cells. Interleukin (IL)-10 and FasL mRNA expression was up-regulated in tolerant CD4+ T cells, but an anti-IL-10 monoclonal antibody (mAb) only partially reversed their inhibitory effect. Immunoregulatory activity was concentrated in the CD4+ CD25+ T-cell subset. In a transwell system, tolerant T cells inhibited a na?ve MLR to a lesser extent than in a standard coculture. Regulatory cells transferred tolerance after infusion into na?ve LW recipients. CD4+ T cells isolated from tolerized grafts were hyporesponsive to donor stimulators and suppressed a na?ve MLR against donor antigens. CONCLUSIONS: Donor-specific regulatory T cells play a role in tolerance induction by donor PBMC infusion. Regulatory activity is concentrated in the CD4+ CD25+ subset and requires cell-to-cell contact. Regulatory CD4+ T cells accumulate in tolerized kidney grafts where they could exert a protective function against host immune response.     

Mechanism of suppression of cloned human suppressor T cells

Abstract We report the mechanism of suppression of suppressor T cell clone III-1-C5 using helper T cell clone III-1-B6, mitogen responses and rIL-2. Clone III-1-C5 suppressed the mixed lymphocyte reaction (MLR) by secreting alloantigen non-pecific, MHC non-restricted suppressor factor(s). Clone III-1-C5 did not suppress mitogen (PHA, Con A, PWM) response nor proliferation by exogeneous rIL-2. Clone III-1-C5 suppressed proliferation by clone III-1-B6, which augments proliferation by direct cell to cell contact with responder cells and not by soluble factors. These results indicated that suppressor T cells exhibit suppressive effects not only by inhibiting IL-2 synthesis but by inhibiting the direct effects of helper T-cells.     

Graft hyporeactivity induced by immature donor-derived dendritic cells

Immature dendritic cells (DCs) are deficient in surface co-stimulatory molecules and have been shown to exhibit a 'tolerogenic' potential. We investigated the allostimulatory activity of immature DCs in one-way mixed leukocyte reactions and their capacity to inhibit anti-donor cytolytic activity in the sponge matrix allograft model. Immature DCs (CD80 and CD86 deficient) were derived from bone marrow cells propagated in GM-CSF and TGF-beta1. Mature DCs (CD80+ and CD86+) were derived from bone marrow cells propagated in GM-CSF and IL-4. Either 2 x 10(6) DBA/2J (DBA, H-2d) immature DCs or 2 x 10(6) mature DCs were injected intravenously into C57BL/6J (B6, H-2b) mice 7 days prior to sponge matrix allograft implantation. On day 12, the sponge was harvested and the graft-infiltrating cells were tested in vitro for cytotoxic T lymphocyte (CTL) activity. Immature dendritic cell (DC) infused significantly and markedly inhibited intra-graft CTL activity compared to mature DCs and syngeneic bone marrow control cells. The administration of immature DCs directly into the sponge allograft failed to induce hyporeactivity. Thus, the only systemic infusion of immature donor DCs was able to recapitulate the donor-specific transfusion effect, and the capacity of donor bone marrow cells to induce donor-specific hyporeactivity in the sponge allograft model.     

Involvement of multiple subpopulations of human bone marrow cells in the regulation of allogeneic cellular immune responses

BACKGROUND: The identity of the cells in the human bone marrow that function as effective regulators of in vitro and possibly in vivo cellular immune responses is not well established. METHODS: Cell subpopulations were isolated from cadaver donor vertebral-body bone marrow cells (DBMC) by using immuno-magnetic microbeads and were tested as inhibitors (modulators) in cell-mediated lympholysis (CML) and mixed lymphocyte reaction (MLR) responses of normal peripheral blood lymphocytes stimulated with irradiated cadaver donor spleen cells. RESULTS: Compared with spleen cells as controls, un-irradiated T-cell depleted DBMC inhibited both the MLR and CML responses of allogeneic responder cells in a dose dependent manner (as in our previous reports). The inhibition was also mediated by a number of purified subpopulations including pluripotent CD34+ stem cells, and their CD34 negative early progeny of both lymphoid and myeloid lineages. These included DBMC enriched for non-T-cell lymphoid precursors (NT-LP/DBMC; i.e., DBMC depleted of CD3, CD15, and glycophorin-A positive cells) and DBMC positively selected for CD38+, CD2+, CD5+, and CD1+ lymphoid cells (all were depleted of CD3+ cells) as well as CD33+ (but CD15 negative) myeloid precursors. However, positively selected CD19+ B-cells and CD15+ myeloid cells did not inhibit the MLR and CML responses. The NT-LP/DBMC that had been repeatedly stimulated with irradiated allogeneic peripheral blood lymphocytes caused the strongest inhibition of the MLR and CML responses of the same allogeneic cells with 200 times fewer modulator cells needed than uncultured DBMC (P<0.001). Flow cytometric analysis revealed that majority of cells in these cell lines had become CD3+ TcR-alphabeta+ CD4+ and CD28+ cells. CONCLUSION: A variety of less differentiated cells of various lineages residing in the human bone marrow are immunoregulatory in vitro. Among them, there is at least one subset that can undergo differentiation in vitro into regulatory T cells that can be maintained in long-term cultures.     

Tissue-specific peptides influence human T cell repertoire to porcine xenoantigens

BACKGROUND: Human CD8+ T cells elicit a vigorous response to allo- or xenogeneic MHC class I molecules. However, the influence of a given MHC-bound peptide to the responding allo- or xenoreactive T cell repertoire is not clear. METHODS: In this study, we analyzed individual T cell responses to unique tissue epitopes presented on syngeneic porcine endothelial and lymphoblastoid cells by limiting dilution analysis and analyzed the responding T cell repertoire by T cell receptor beta (TCR Vbeta) chain spectrotyping. RESULTS: Both porcine endothelial and lymphoblastoid cells were able to elicit swine leukocyte antigen (SLA) class I restricted and peptide-dependent cytotoxic T lymphocyte (CTL) responses. The responding human CD8+ T cells showed a heterogenous but limited TCR Vbeta gene usage. Interestingly, although a large portion of the selected TCR Vbeta gene usage in response to endothelial and lymphoblastoid cells were shared (i.e., Vbeta-1, 2, 6.1, 13), unique Vbeta usage was noted in T cells that respond to either endothelial (Vbeta-5.3) or lymphoblastoid cells (Vbeta-5.1, 11), suggesting that porcine tissue-specific epitopes play a role in modulating the responding T cell repertoire. Limiting dilution cloning analysis revealed that a majority (89%) of the CTL clones stimulated by porcine endothelial cells recognized shared peptides presented by both endothelial cells and syngeneic lymphoblastoid cells. However, a significant portion (11%) of the CTL clones recognized unique peptides presented only in the context of SLA class I molecules on endothelial cells. CONCLUSION: These results provide evidence for the first time that tissue-specific peptides can directly influence T cell repertoire in response to the xenogeneic stimulus.     

Mechanism of portal venous tolerant long-term MHC Class I L(d)-specific skin graft survival in transgenic 2CF1 mice

BACKGROUND: Administration of alloantigen via the portal vein (PV) in non-transgenic animals has been shown to promote immunologic tolerance and enhance transplant allograft survival. The underlying mechanisms remain unclear. In 2C x dm2 F1 (2CF1) transgenic mice, the monoclonal antibody, 1B2, identifies specific 2C TCR transgenic CD8+ T cells that are cytotoxic against Class I MHC L(d). In these mice, the specific response by these cells to L(d+) skin grafts after PV administration of L(d+) antigen was determined. MATERIALS AND METHODS: Saline (control) or allogeneic C57BL/6 x BALB/c F1 (CB6F1) spleen cells (25 x 10(6)), which differ from 2CF1 only at L(d), were injected PV into 2CF1 mice. One week later, CB6F1 tail skin was transplanted onto the dorsum of these 2CF1 mice. Skin graft rejection was defined as >50% loss of the graft. Parallel experiments were performed in non-transgenic littermates [B6F1 (C57BL/6 x dm2)]. FACS analysis of 2CF1 peripheral blood for 1B2+, CD4+, and CD8+ T cells was performed 2 days before PV injection (9 days prior to skin grafting), 5 days after PV injection (2 days prior to skin grafting), and 7, 14, 21, 28, and 60 days after skin grafting. FACS analysis of nai;ve, saline control, and CB6F1 PV-treated 2CF1 thymocytes was also performed. Responsiveness of saline (control)-treated and PV-treated 2CF1 splenocytes was measured by in vitro cytotoxic T lymphocyte (CTL). RESULTS: All CB6F1 skin grafts were rejected in <14 days by PV saline controls. However, a single PV injection of donor L(d+) CB6F1 cells was sufficient to induce indefinite CB6F1 (L(d+)) skin allograft survival in 100% of non-transgenic B6F1 and transgenic 2CF1 (anti-L(d)) TCR transgenic recipients. FACS analysis of 1B2+ T cells demonstrated that PV injection of donor antigen followed by a CB6F1 skin graft led to a 70% decrease in peripheral donor-reactive 1B2+ CD8+ T cells by day 7, while central thymocytes were unchanged. CTL of 2CF1 splenocytes following PV CB6F1 demonstrated that they were hyporesponsive to L(d) compared to saline-treated 2CF1 splenocytes. Despite recovery of peripheral CD8+ T cells to near normal levels by 60 days post-transplantation, skin graft survival persisted indefinitely. CONCLUSIONS: Administration of specific PV antigen results in exquisite long-term L(d+) skin allograft acceptance. This tolerance induction is related to a significant peripheral deletion of donor-reactive 1B2+ CD8+ transgenic T cells and anergy of the residual T cells.     

Different specificities of cloned T cells assessed by in vitro proliferation assays and by the ability to mediate skin graft rejection in vivo

The experiments presented here have compared the specificities of T cell clones as determined by in vitro proliferative responses and their specificities as reflected by their ability to mediate skin graft rejection in vivo. Two proliferative T cell clones with distinct in vitro specificities were evaluated for their ability to mediate rejection of skin grafts from C57BL/10 Scn nu/nu mice. Clone 14.11 (L3T4+, Lyt2-) was specifically stimulated to proliferate in vitro by I-Ad determinants, while clone 3.3.10 (also L3T4+, Lyt2-) recognized M1sa products in the context of MHC-encoded cell surface determinants. The results demonstrate that both clone 14.11 and clone 3.3.10 T cells are capable of mediating rejection of DBA/2 (H-2d, M1sa) skin grafts from B10 nu/nu mice. Surprisingly, neither clone 3.3.10 T cells nor clone 14.11 T cells were found to be effective at rejecting skin grafts from the D1.C congenic donor strain of mice (also H-2d, M1sa) from B10 nu/nu mice. Further, clone 14.11 T cells were also found to be ineffective at rejecting B10.D2 (H-2d, M1sb) skin grafts from B10 nu/nu mice. These data indicate the existence of a striking dichotomy between the specificity of alloreactive T cell clones as determined by in vitro proliferation studies and their functional capabilities in vivo.     

Polyclonal rabbit gamma globulins against a human cytotoxic CD4+ T cell clone. I. Clone characteristics and antiblast globulin preparation

Antihuman lymphocyte rabbit (or horse) gamma globulins used in recipients of organ transplantation are prepared against thymocytes or immortalized cell lines, the only two sources so far allowing enough antigen preparation. These cells lack, however, the surface determinants characteristic of alloreactive blasts involved in the rejection process. We have derived long-term cultures of a panel of alloreactive (untransformed) clones from a rejected kidney. Among them, clone 1E7 has been chosen as a cytotoxic CD4+ (CD2+ CD3+ TCR alpha beta+) clone proliferating against HLA-DR8 targets. This clone (clonality assessed on T cell receptor genomic rearrangements) has been grown using weekly stimulations with the kidney donor-derived EBV cell line and recombinant IL-2. Clone cultures have been adapted to mass production after optimization of culture conditions satisfying pharmaceutical requirements. This procedure warranted a reproducible source of antigen since the functional and phenotypic characteristics of the immunizing 1E7 cells remained identical through the life span of the culture. In addition, the study of the total growth capacity of 1E7 cells showed consistent expansion until the 40th cell cycle, ensuring a progeny that will satisfy the large-scale requirement for a clinical trial. Rabbits were injected with 100 x 10(6) 1E7 cells (21, 14, and 7 days before bleeding). Sera were depleted of agglutinin by red blood cell absorption and globulin antiblast (GAB) prepared by SO4Na precipitation and ion exchange chromatography; 50% complement-mediated target cell lysis and 50% inhibition of E rosette formation and alloproliferation were obtained at GAB dilutions of about 1:250-1:500. Prescreened on cynomolgus monkeys, GAB could significantly prolong skin grafts when given prophylactically. Finally GAB have been used in human recipients of kidney grafts for prophylaxis of early rejection. Results of this pilot study are given in a separate report in this issue. In conclusion we have, for the first time, set up a large-scale preparation of polyclonal globulin against a normal human alloreactive clone, and this new reagent should present several advantages over classic antilymphocyte or antithymocyte sera because it contains specificities against activation antigens and has less crossreactivity variation among batches.     

Generation of helper and cytotoxic CD4+T cell clones specific for the minor histocompatibility antigen H-Y, after in vitro priming of human T cells by HLA-identical monocyte-derived dendritic cells

BACKGROUND: There is now convincing evidence that minor histocompatibility antigens (mHag) may play a significant role in the pathogenesis of graft-versus-host disease after HLA-identical bone marrow transplantation. Indeed, in this clinical situation, T cells specific for mHag have been isolated. Here, we addressed whether one can generate mHag-specific T cells in vitro, without any in vivo immunization, among healthy blood donors. METHODS: We used monocyte-derived dendritic cells (Mo-DCs) as antigen presenting cells to induce primary responses between healthy HLA-identical siblings, in mixed lymphocyte dendritic cell reactions (MLDCRs). RESULTS: We show that CD4+ T-cell clones, specific for the mHag H-Y, can be generated in vitro. These clones were derived from a gender-mismatched positive MLDCR pair of HLA-identical siblings and were restricted by the HLA DQB1*0502 molecule. In addition, these CD4+ T clones were also able to lyse allogeneic targets with the same pattern of restriction and specificity than helper function. Finally, acute myeloid leukemia (AML) blast cells were susceptible to lysis by these clones. CONCLUSIONS: Altogether, these results predict that Mo-DCs could help to generate class II-associated, mHag-specific, T-cell lines or clones in vitro, between healthy blood donors, without any need of transplantation-mediated immunization.     

Direct versus Indirect Allorecognition: Visualization of Dendritic Cell Distribution and Interactions During Rejection and Tolerization

Interactions of donor and recipient dendritic cells (DCs) with CD4+ T cells determine the alloantigenic response in organ transplantation, where recipient T cells respond either directly to donor MHC, or indirectly to processed donor MHC allopeptides in the context of recipient MHC molecules. The present study evaluates donor and recipient alloantigen-presenting DC trafficking and their interactions with CD4+ T cells in the lymph nodes (LNs) and the spleen under tolerogenic treatment with anti-CD2 plus anti-CD3 mAb compared with untreated rejecting conditions. CX3CR1(GFP) BALB/c (I-A(d)) donor hearts were transplanted into C57BL/6 (I-A(b)) mice and quantification of donor DC direct (GFP+ or I-A(d+)) and recipient DC indirect (YAe+) trafficking and interactions with host CD4+ T cells was performed by fluorescent microscopy. Our data indicate that although both direct and indirect interactions between CD4+ T cells and donor and recipient DCs occur shortly after engraftment, only indirect presentation persists in the LN, but not the spleen, of tolerized recipients. These data suggest that distinct anatomic lymphoid compartments play a critical role in peripheral tolerance induction and maintenance, and persistent indirect presentation to CD4+ T cells within the LNs is an important process during tolerization.