体外诱导人脐血树突状细胞介导T细胞抗白血病的细胞毒性效应研究

为了研究脐血淋巴细胞能否在体外培养成为特异性杀伤白血病细胞的杀伤性T细胞(CTL),联合细胞因子体外诱导脐血单个核细胞分化为树突状细胞(DC),再吞噬凋亡白血病细胞并将其抗原呈递给相同脐血的T淋巴细胞,得到杀伤性T细胞。用形态学及流式细胞术检测DC。CTL细胞的杀伤功能用乳酸脱氢酶(LDH)释放法测定。结果表明:12份脐血标本均可培养出形态典型的DC,DC的表面标志CD1a 、HLA DR 、CD86 、CD83 表达水平显著升高(P<0.05)。CTL可以杀伤未经培养的白血病细胞(效∶靶=50∶1对AML细胞的平均杀伤率为44.76±17.42%,对ALL细胞的平均杀伤率为8.50±4.25%),对相同患者缓解期的骨髓细胞杀伤率极低。结论: 在外体应用多种细胞因子刺激可诱导脐血单个核细胞分化成典型的DC;负载有白血病抗原的DC可诱导同一脐血的淋巴细胞生成白血病特异的杀伤性T细胞(CTL),所得CTL可特异性杀伤未经培养的白血病细胞而不严重伤害相同患者缓解期的骨髓细胞。     

Specificity of Heteroantisera to Human Acute Leukemia-Associated Antigens

Antisera have been raised to human leukemic blast cells from individual patients in mice rendered tolerant with cyclophosphamide to remission leukocytes from the same individual. 10 antisera were raised against acute myelogenous leukemia (AML) cells and 5 antisera were raised against acute lymphoblastic leukemia (ALL) cells. Antisera to AML cells were absorbed with ALL cells, and antisera to ALL cells were absorbed with AML cells. Unabsorbed and absorbed antisera as well as antisera raised in nontolerant mice were tested for cytotoxicity against various cells of a panel containing myeloblasts from 35 patients with AML, lymphoblasts from 7 patients with ALL, myeloblasts from 7 patients with chronic myelogenous leukemia (CML) in blast crisis, peripheral blood leukocytes from 12 patients with acute leukemia in remission and 30 nonleukemic patients, and nucleated bone marrow cells from 10 nonleukemic patients. Unabsorbed antisera to AML or ALL cells raised in tolerant mice were highly cytotoxic to leukemic blasts cells but significantly less cytotoxic to remission and control cells. Antisera to AML cells absorbed with ALL cells retained measurable cytotoxicity against AML cells but were not cytotoxic to ALL cells or control cells. Similarly, antisera to ALL cells absorbed with AML cells retained significant cytotoxicity only to ALL cells. Control antisera raised in nontolerant mice were cytotoxic to all cells tested. Although species specific, histocompatibility, differentiation, maturation, and cell cycle-associated antigens may be responsible in part for the cytotoxic activity of the unabsorbed antisera, the absorbed antisera are probably detecting antigens specific for their leukemic cell type.     

Lysis of tumor biopsy cells by autologous T lymphocytes activated in mixed cultures and propagated with T cell growth factor

Blood lymphocytes from tumor patients were cocultivated with allogeneic lymphocytes (MLC) or autologous tumor cells (ATS), and their cytotoxicity was characterized. The main objective of the study was the lysis of autologous tumor biopsy cells by such effectors. Lymphocytes of patients activated in MLC lysed allogeneic third-party cells and in some cases also lysed autologous tumor cells. Allogeneic but not autologous PHA blasts were also damaged by these effectors. The cytotoxic potential of MLC-activated lymphocytes from healthy donors was similar; allogeneic tumors and phytohemagglutinin (PHA) blasts but not autologous PHA blasts were lysed. The cytotoxicity of lymphocytes activated in ATS were specific for the stimulator because they acted only on the autologous tumor cells. Allogeneic tumors and autologous and allogeneic PHA blasts were not lysed. The pattern of cytotoxicity with regard to this target panel was maintained when the MLC or ATS cultures were further propagated with TCGF. Results obtained in cold target competition assays suggested (a) activated lymphocyte lyse the third party tumor targets because of alloantigen recognition; (b) in MLC several different sets of alloreactive cytotoxic lymphocytes are present simultaneously; and (c) the alloreactive cells are different than those that act on the autologous tumor cells. Thus, the lysis of allogeneic tumor cells by lymphocytes of the patient is not due to recognition of cross-reacting tumor-related antigens, and the autotumor cytotoxicity of the patients' MLC-activated lymphocytes if performed by specifically reacting cells.     

Generation of leukemia-reactive cytotoxic T lymphocyte clones from the HLA-identical bone marrow donor of a patient with leukemia.

Allogeneic bone marrow transplantation (BMT) has been associated with a graft-vs.-leukemia (GVL) reactivity. Since T cell depletion of the bone marrow graft has decreased the risk of graft-vs.-host disease (GVHD), but has been associated with higher rates of leukemia relapse, GVL reactivity is probably caused by donor-derived T lymphocytes. Previously, we demonstrated that minor histocompatibility (mH) antigen-specific cytotoxic T lymphocyte (CTL) clones, generated from patients after BMT, are capable of major histocompatibility complex-(MHC) restricted lysis of (clonogenic) myeloid leukemic cells. Here, we investigated whether donor-derived leukemia-specific CTL clones can be generated in vitro, before BMT, using irradiated leukemic cells from a patient with acute myeloid leukemia as stimulator cells, and peripheral blood or bone marrow from the HLA genotypically identical sibling donor as responder cells. Several CTL lines were generated that showed specific lysis (> 50%) of the recipient leukemic cells in a 51Cr-release assay. Two of these CTL lines were cloned by limiting dilution in the presence of the irradiated recipient cells. Multiple leukemia-reactive, HLA class I and II-restricted clones with various specificities could be established. These alloreactive, antileukemic CTL clones may cause GVL reactivity after BMT, and may be used as adjuvant immunotherapy in the treatment of leukemia.     

造血生长因子对急性髓系白血病细胞动力学耐药的克服

髓系白血病细胞“细胞动力学耐药”是指处于G_0期或增殖缓慢、细胞周期长于药物接触时间的白血病细胞对某些细胞周期特异性细胞毒药物产生耐药的现象。阿糖胞苷(Ara-C)为目前治疗急性髓系白血病(AML)标准诱导方案的药物之一。它是一种通过抑制DNA的合成,特异性地杀伤处于S期的白血病细胞的细胞周期特异性的细胞毒药物。~3H-胸腺嘧啶核苷体内标记研究证实,在AML存在一部分处于增殖静止状态和增殖缓慢的白血病细胞。体外研究发现,某些造血生长因子(HGF),如干细胞因子,IL-3,GM-CSF和G-CSF,在单用或联合应用条件下,不但能动员髓系白血病细胞进入细胞周期,使其对Ara-C的敏感性增加,细胞周期动力学耐药得以克服,而且对正常造血祖细胞有一定的保护作用。目前,有关HGF克服AML细胞动力学耐药临床研究结果表明,GM-CSF有可能提高患者的无病生存时间,副作用为血小板恢复延迟。显然,为明确HGF在克服AML细胞动力学耐药中的实际效果和可能的副作用,进一步进行HGF单独和联合条件下的大样本随机对照的前瞻性研究是十分必要的;另外,寻找能更有效的克服AML细胞周期耐药的HGF,也是应进一步研究的课题。     

Effects of gamma-irradiation on acute myelogenous leukemia blasts: in vitro studies of proliferation, constitutive cytokine secretion, and accessory cell function during T cell activation

Generation of cellular immune responses against acute myelogenous leukemia (AML) blasts is a possible therapeutic approach in leukemia therapy. However, when using native AML blasts as stimulator cells during ex vivo generation of leukemia-reactive T cells, one has to ensure that the T cell population is not contaminated with proliferating AML blasts. Our results demonstrate that gamma-irradiation could be used to stop AML blast proliferation for all patients investigated. However, gamma-irradiation also caused a dose-dependent reduction in the constitutive AML blast secretion of the potentially T cell stimulatory cytokines IL-1beta, IL-6, and tumor necrosis factor-alpha (TNF-alpha). At the same time, gamma-irradiation resulted in a dose-dependent decrease in anti-CD3-stimulated proliferative responses of T cell clones in the presence of AML blast accessory cells. When using 50 Gy irradiation, however, AML blast expansion was avoided, and anti-CD3 and PHA-stimulated T cell proliferation was detected in the presence of accessory AML blasts for most AML/T cell combinations investigated. When AML blasts were cultured with GM-CSF + IL-4 to develop a dendritic cell phenotype, enhanced T cell proliferation in the presence of in vitro precultured AML blasts was observed for most patients even after 50 Gy irradiation. We conclude that when using native AML blasts as accessory cells during in vitro generation of leukemia-reactive T cells, an irradiation dose of 50 Gy can be used for a majority of AML patients to avoid the risk of leukemia cell expansion during culture and with the maintenance of AML blast accessory cell function. However, when in vitro expanded cells are used in clinical trials, this antiproliferative effect should be documented with appropriate in vitro testing for every patient so that the possibility of decreased sensitivity to gamma-irradiation in exceptional patients is excluded.     

Growth inhibition of clonogenic leukemic precursor cells by minor histocompatibility antigen-specific cytotoxic T lymphocytes

Minor histocompatibility (mH) antigens appear to play a major role in bone marrow transplantation (BMT) using HLA-identical donors. Previously, we reported the isolation of major histocompatibility complex (MHC)-restricted mH antigen-specific cytotoxic T lymphocytes (CTL) from patients with graft-vs.-host disease or rejection after HLA-identical BMT. We have demonstrated that mH antigens can be recognized on hematopoietic progenitor cells, and residual recipient CTL specific for mH antigens expressed on donor hematopoietic progenitor cells may be responsible for graft rejection in spite of intensive conditioning regimens in HLA-identical BMT. Here, we investigated whether mH antigen-specific CTL directed against the mH antigens HA-1 to HA-5 and the male-specific antigen H-Y were capable of antigen-specific inhibition of in vitro growth of clonogenic leukemic precursor cells. We demonstrate that mH antigen-specific CTL against all mH antigens tested can lyse freshly obtained myeloid leukemic cells, that these mH antigen-specific CTL can inhibit their clonogenic leukemic growth in vitro, and that this recognition is MHC restricted. We illustrate that leukemic (precursor) cells can escape elimination by mH antigen-specific CTL by impaired expression of the relevant MHC restriction molecule. We suggest that mH antigen-specific MHC-restricted CTL may be involved in vivo in the graft-vs.-leukemia reactivity after BMT.     

In vitro generation of cytotoxic cells specific for human minor histocompatibility antigens by lymphocytes from a normal donor potentially primed during pregnancy

A normal female donor (H9) is described, whose cells generate strong cytotoxicity against a human minor histocompatibility antigen in vitro. These cytotoxic T lymphocytes are generated after secondary restimulation with cells from an HLA-A, -B, -C, and -DR-matched donor and are HLA restricted (HLA-B7). No other donor could be identified whose cells responded to this antigen. The two children of donor H9 are virtually HLA identical to her and one of the children expresses the relevant minor histocompatibility antigen. These data suggest that priming in vivo during pregnancy has facilitated cytotoxic T cell response to human minor histocompatibility antigens in vitro.     

Antigen heterogeneity of human B and T lymphocytes.

Rhesus monkeys were immunized with normal human lymphoid cells, cultured lymphoid cells, and chronic leukemic lymphocytes. Antisera were analyzed by cytotoxicity and immunofluorescence techniques to study the antigenic characteristics of human lymphocytes. In an attempt to obtain a reagent specifically reactive with T (thymus-derived) lymphocytes, an antispleen antiserum was absorbed with cellf from five B- (bone marrow-derived) cell lines. After absorption, the antiserum killed 60-75% of peripheral blood lymphocytes and 40-50% of tonsil cells, so that there was a relationship between the percentage of killed cells and the proportion of T lymphocytes. However, when cells after cytotoxic treatment were assayed for rosette formation with sheep erythrocytes (a T-cell marker) 5-20% of viable rosette-forming lymphocytes were found. Therefore, this antiserum was cytotoxic for only 75-90% of T cells. From studies performed with antisera prepared against spleen and B-cell lines, we conclude that lymphoblastoid cells are antigenically different and deficient in comparison to normal B lymphocytes. In addition, cultured B-cell lines appear to be antigenically heterogenous, as shown by the cytotoxic activity remaining in antispleen and anti-B-cell lines sera after absorption with various numbers and types of lymphoid cell lines. After absorption with normal lymphocytes, an antiserum produced against chronic lymphatic leukemia cells had specific activity associated with 12 chronic lymphatic leukemia cells tested. Absorption of the same antiserum with leukemic cells from two patients showed that a certain degree of antigenic heterogeneity also exists among chronic leukemic lymphocytes.     

Minor histocompatibility antigen-specific cytotoxic T cell lines, capable of lysing human hematopoietic progenitor cells, can be generated in vitro by stimulation with HLA-identical bone marrow cells

Recipient-antidonor alloreactivity before HLA genotypically identical bone marrow transplantation (BMT) between donor-recipient pairs that are negative in the mixed lymphocyte reaction (MLR), the cell-mediated lympholysis (CML) assay, and the lymphocyte crossmatch was not detectable in the majority of cases, using recipient peripheral blood lymphocytes (PBL) collected before BMT as responder cells and donor PBL as stimulator cells. However, when donor bone marrow mononuclear cells (BMMNC) instead of PBL were used as stimulator cells, we could detect donor-specific alloreactivity in 7 of 10 HLA genotypically identical donor-recipient pairs. To demonstrate that this alloreactivity was minor histocompatibility (mH) antigen specific and not directed against HLA class I splits or variants, two cytotoxic T lymphocyte (CTL) lines were tested in further detail against phytohemagglutinin (PHA) blasts from pairs of HLA genotypically identical siblings positive for the HLA class I restriction molecule. Both CTL lines recognized mH antigens, as illustrated by the differential recognition of PHA blasts of one of the two siblings from several pairs. The potential role of these mH antigen-specific CTLs in bone marrow graft rejection was demonstrated by the mH antigen-specific growth inhibition of hematopoietic progenitor cells from the original bone marrow donor and from HLA class I restriction molecule-positive individuals who expressed the mH antigens on their PBL and BMMNC. Our assay can be used in HLA genotypically identical BMT to detect a recipient-antidonor response, directed against cellularly defined mH antigens expressed on donor HPC, BMMNC, and PBL, before transplantation.     

Interaction of the hemolytic lectin, CEL-III, with cultured human leukemic cell lines

We studied interaction of CEL-III with cultured human leukemic cell lines and lymphocytes from normal adults by evaluating the extent of cytotoxicity and cytoagglutination. Among acute T lymphoblastic leukemia (T-ALL) cell lines, CEL-III displayed increased toxicity against different acute lymphoblastic leukemia (ALL) cell lines as a function of increasing differentiation stage. In the case of acute B lymphoblastic leukemia (B-ALL) cell lines, CEL-III showed strong cytotoxicity against relatively immature cell lines. We found that CEL-III was more toxic for ALL cell lines than leukocytes obtained from peripheral blood of healthy adults. Strong influence of the additional amount of calcium ion on the extent of cytotoxicity was observed. In addition, we describe a new way to evaluate the extent of cytoagglutination in "% of agglutinated cells". These findings make CEL-III a promising candidate in research for lectins which bind to and destroy only the targeted leukemic cells.     

Induction of leukemic-cell-specific cytotoxic T lymphocytes by autologous monocyte-derived dendritic cells presenting leukemic cell antigens

Leukemic-dendritic cells (leukemic-DCs) have certain limitations, which include difficult generation in 30-40% of patients, and low levels of expression of several key molecules. Therefore, an alternative approach using monocyte-derived DCs pulsed with tumor antigens is required. We investigated the possibility of immunotherapy for AML using leukemic-cell-specific cytotoxic T lymphocytes that were stimulated in vitro by autologous DCs pulsed with tumor antigens. To generate DCs, CD14(+) cells were isolated from peripheral blood mononuclear cells using magnetic-activated cell sorting, and cultured in the presence of GM-CSF and IL-4. On day 6, maturation of DCs was induced by addition of cytokine cocktail (TNF-alpha, IL-1beta, IL-6, and prostaglandin E(2)) for 2 days, and then the mature DCs were pulsed with whole leukemic cell lysates or apoptotic leukemic cells. There were no differences in the phenotypic expressions of mature DCs generated by pulsing with or without leukemic antigens. The mature DCs pulsed with tumor cell lysates or apoptotic leukemic cells showed a higher allostimulatory capacity for allogeneic CD3(+) T cells as compared with mature non-pulsed DCs. Autologous CD3(+) T cells stimulated by the mature pulsed DCs showed more potent cytotoxic activities against autologous leukemic cells than those stimulated by mature non-pulsed DCs. These results suggest that use of DCs pulsed with leukemic cell lysates or apoptotic leukemic cells is a feasible alternative immunotherapeutic approach to overcome the limitations of leukemic-DCs for the treatment of AML patients.     

Cytosine arabinoside transport and metabolism in acute leukemias and T cell lymphoblastic lymphoma.

Cytosine arabinoside (araC) has proven efficacy in acute myeloid leukemia (AML), but its place in the treatment of acute lymphoblastic leukemia (ALL) and T lymphoblastic lymphoma is uncertain. The therapeutic potential of araC has been assessed in patients with AML, ALL, and T lymphoblastic lymphoma by measuring the conversion of araC to its active metabolite, the 5'-triphosphate of araC (araCTP), in purified blasts from patients as well as in normal polymorphs and lymphocytes. In all leukemias, araCTP was the major intracellular metabolite of araC. The highest araCTP formation was in blasts from T lymphoblastic lymphoma, which formed threefold more nucleotide than myeloblasts, and in turn myeloblasts formed twofold more araCTP than lymphoblasts from ALL. The mean araCTP formation in myeloblasts was sixfold greater than polymorphs, but in contrast, lymphoblasts and lymphocytes formed low and similar amounts of this nucleotide. Reasons for the sixfold range in araCTP accumulation in the various leukemic blasts were studied. The mean size of myeloblasts was 35-70% larger than lymphoblasts when compared on the basis of protein or intracellular water content, but T lymphoblastic lymphoma blasts and lymphoblasts were the same size. Activities of deoxycytidine kinase, deoxycytidylate deaminase, and pyrimidine nucleoside monophosphate kinase were not different between any of the leukemic cell types. The number of nucleoside transport sites on blasts was estimated by measuring the equilibrium binding of [3H]nitrobenzylthioinosine (NBMPR), which binds with high affinity to the transporter. Scatchard analysis yielded mean values of 27,500 sites/cell for T lymphoblastic lymphoma blasts, 10,000 sites/cell for myeloblasts, and 2,300 sites/cell for lymphoblasts. Our previous work has shown that araC influx correlates with the maximum number of 3H-NBMPR binding sites in leukemic and normal white cells. A strong correlation was observed between the number of nucleoside transport sites per leukemic blast cell and the accumulation of intracellular araCTP from extracellular araC at 1 microM. Membrane transport of araC at the low concentrations (approximately 1 microM), which are achieved therapeutically, is a major rate-limiting step in its conversion to araCTP by leukemic blast cells. Myeloblasts form more araCTP than lymphoblasts because of both higher nucleoside transport capacity and larger cell size. The highest nucleoside transport capacity and largest conversion of araC to araCTP is in T lymphoblastic lymphoma, which suggests that araC may be effective in the treatment of this disease.     

Autologous leukemia-specific T-cell-mediated lymphocytotoxicity in patients with acute myelogenous leukemia

Short-term culture of acute myelogenous leukemia patient's remission lymphocytes with inactivated autologous leukemic blast cells plus allogeneic lymphocytes, generated effector T lymphocytes which were cytotoxic for the specific autologous blast cell in 11 of 14 patients studied. Experiments using Daudi and Molt 4 lymphoblastoid cell lines as third-party helper cell suggest that an HLA D locus incompatability is necessary to provide effective help in this system. Cold target inhibition experiments, crossover studies between pairs of patients, and experiments with allogeneic leukemic blast cells as priming stimulus suggest that the target antigen is only present on the specific autologous blast cell.     

Nonleukemic myeloid dendritic cells obtained from autologous stem cell products elicit antileukemia responses in patients with acute myeloid leukemia

BACKGROUND: Dendritic cell (DC)‐based immunotherapeutic protocols are being developed to treat acute myeloid leukemia (AML). So far, DCs for clinical use are obtained from leukemic blasts or from monocytes, after 6 to 10 days of ex vivo culture. However, DC precursors are easily driven to DCs in short‐term culture. We tested if DC precursors contained in peripheral blood stem cell (PBSC) products obtained from AML patients can be used to induce antileukemia responses. STUDY DESIGN AND METHODS: PBSCs obtained from 30 consecutive AML patients were tested. Myeloid DCs (MDCs) were purified by immunomagnetic selection and screened for cytogenetic and/or molecular abnormalities by fluorescence in situ hybridization (FISH) or polymerase chain reaction (PCR) assays. MDCs were matured and pulsed with autologous blast lysates and tested for stimulatory capability against AML cells. RESULTS: A median of 0.62 × 10⁶ MDCs (range, 0.04‐3.25)/mL were quantified in PBSC products. Isolated MDC expressed Class I and II HLA but CD86, CD54, and CCR5 partially. By FISH or PCR assay, these MDCs lacked cytogenetic or molecular abnormalities detected in leukemia cells at diagnosis. MDCs achieved a maturated stage (mature‐MDCs) after 24‐hour ex vivo culture with tumor necrosis factor‐α and autologous blast lysates. These mature‐MDCs were capable of stimulating autologous peripheral blood effectors to exert cytotoxicity against autologous leukemia cells and HL‐60 cell line. CONCLUSION: We conclude that PBSCs obtained for autologous stem cell transplantation can constitute a novel source of MDCs to design feasible vaccination trials.     

Functional and phenotypic comparison of human T cell leukemia/lymphoma virus positive adult T cell leukemia with human T cell leukemia/lymphoma virus negative Sézary leukemia, and their distinction using anti-Tac. Monoclonal antibody identifying the human receptor for T cell growth factor.

Adult T cell leukemia (ATL) and Sézary leukemia are malignant proliferations of T lymphocytes that share similar cell morphology and clinical features. ATL is associated with HTLV (human T cell leukemia/lymphoma virus), a unique human type C retrovirus, whereas most patients with the Sézary syndrome do not have antibodies to this virus. Leukemic cells of both groups were of the T3, T4-positive, T8-negative phenotype. Despite the similar phenotype, HTLV-negative Sézary leukemic cells frequently functioned as helper cells, whereas some HTLV-positive ATL and HTLV-positive Sézary cells appeared to function as suppressors of immunoglobulin synthesis. One can distinguish the HTLV-positive from the HTLV-negative leukemias using a monoclonal antibody (anti-Tac) that appears to identify the human receptor for T cell growth factor (TCGF). Resting normal T cells and most HTLV-negative Sézary cells were Tac-negative, whereas all ATL cell populations were Tac-positive. The observation that ATL cells manifest TCGF receptors suggests the possibility that an abnormality of the TCGF-TCGF receptor system may partially explain the uncontrolled growth of these cells.     

Graft Versus Leukemia Response Without Graft-versus-host Disease Elicited By Adoptively Transferred Multivirus-specific T-cells

A 12-year-old boy with refractory acute lymphoblastic leukemia received a haploidentical transplant from his mother. As prophylaxis for Epstein-Barr virus (EBV), cytomegalovirus (CMV) and adenovirus, he received ex vivo expanded virus-specific donor T cells 3.5 months after transplant. Four weeks later leukemic blasts bearing the E2A deletion, identified by fluorescent in situ hybridization (FISH), appeared transiently in the blood followed by a FISH-negative hematological remission, which was sustained until a testicular relapse 3.5 months later. Clearance of the circulating leukemic cells coincided with a marked increase in circulating virus-specific T cells. The virus-specific cytotoxic T-cell (CTL) line showed strong polyfunctional reactivity with the patient''s leukemic cells but not phytohemagglutinin (PHA) blasts, suggesting that virus-specific CTL lines may have clinically significant antileukemia activity.     

Ia-bearing T lymphocytes in man. Their identification and role in the generation of allogeneic helper activity

The presence of Ia-like antigens was demonstrated on a small population (2-6%) of highly purified human circulating T lymphocytes by immunofluorescence with a rabbit anti-Ia serum raised against the isolated bimolecular Ia structure. The Ia+ T lymphocytes have no surface or intracellular immunoglobulins. The expansion of this Ia+ T- cell population was encountered in certain patients. Ia antigens were also found on T blasts grown in long-term cultures with conditioned medium generated by phytohemagglutinin-stimulated lymphocytes. In addition, leukemia blasts which stained for Ia antigens and formed E rosettes were identified in the peripheral blood of two leukemic patients. This evidence further supports the existence of Ia-bearing T cells in man. The Ia+ T-lymphocyte population was shown to contain cells responsible for the generation of allogeneic helper activity. Elimination of Ia+ lymphocytes from a purified T-cell population by the anti-Ia antiserum and complement abolished its ability to help an allogeneic B-cell preparation to generate plaque-forming cells against sheep erythrocytes in vitro in the presence of the antigen.     

凝集素美洲商陆和IL-2共同激活的单核细胞抗白血病作用的研究

采用MTT法研究了美洲商陆(PWM)和IL-2共同激活的单核细胞对人类白血病原代培养细胞的体外杀伤作用。结果表明,激活的单核细胞对白血病细胞具有明显的杀伤作用,其杀伤活性可达73.39％-83.73％。杀伤活性的强弱与白血病的细胞类型没有必然的联系;此外,来源于不同个体的白血病细胞对单核细胞杀伤作用的敏感性不同。采用激活的单核细胞对自体骨髓进行净化,用于造血干细胞移植,具有干细胞损失少,净化效果好,毒副作用小等特点,其应用前景良好。     

Recognition of clonogenic leukemic cells, remission bone marrow and HLA-identical donor bone marrow by CD8+ or CD4+ minor histocompatibility antigen-specific cytotoxic T lymphocytes.

We investigated whether minor histocompatibility (mH) antigen-specific cytotoxic T lymphocytes (CTL) can discriminate between leukemic hematopoietic progenitor cells (leukemic-HPC) from AML or CML patients, the HPC from their remission bone marrow (remission-HPC), and normal HPC from their HLA-identical sibling bone marrow donor (donor-HPC). Specific lysis by CD8+ CTL clones was observed not only of the leukemic-HPC but also of the donor-HPC in 3/4 patient/donor combinations expressing mH antigen HA-1, 3/5 combinations expressing mH antigen HA-2, 2/3 combinations expressing mH antigen HA-3, and 2/2 combinations expressing mH antigen HY-A1. In four patient/donor combinations the recognition of the donor-HPC was clearly less than of the leukemic-HPC, indicating differential susceptibility to lysis by these mH CTL clones. In addition, differential recognition of leukemic-HPC and remission-HPC within seven patients was analyzed. In one patient expressing the HA-2 antigen on the leukemic cells the recognition of the remission-HPC was clearly less than of the leukemic-HPC. One CD4+ CTL clone showed specific lysis of the leukemic-HPC from an AML patient and a CML patient as well as of normal remission-HPC and donor-HPC. These results illustrate that in general CD8+ and CD4+ mH antigen specific CTL clones do not differentially recognize leukemic-HPC and normal-HPC. However, differences in susceptibility to lysis of malignant versus normal cells may contribute to a differential GVL effect.