Influence of cytokines and autologous lymphokine-activated killer cells on leukemic bone marrow cells and colonies in AML

We have already shown that cytokine cocktails (IL-1beta, IL-3, IL-6, SCF, GM-CSF) and/or lymphokine-activated killer (LAK) cells can reduce the amounts of clonal, CD34-positive mononuclear bone marrow cells (BM-MNC) in acute myeloid leukemia (AML). In addition, the influence of those cocktails and/or LAK cells on the clonogenic potential of AML BM-MNC was investigated. BM colonies cultured in agar during different stages of the disease were immunophenotyped in situ: 17 patients at diagnosis, 14 patients in complete remission, 8 patients at relapse, 8 healthy donors. A significant reduction in leukemic cells and colonies positive for CD34 after in vitro culture of BM-MNC with cytokine cocktails was achieved with all samples obtained at diagnosis (n = 8, p < 0.01), in 6 of 8 cases in complete remission but only in 2 of 6 cases at relapse. Cytokine cocktails stimulated granulopoiesis as well as B and T lymphopoiesis. Colonies with leukemic phenotype could never be detected in healthy BM. A significant reduction in leukemic colonies was achieved by coculture of BM-MNC (uncultured or cytokine precultured) with autologous LAK cells in all 4 cases at diagnosis and in 1 case at relapse. An additive effect of in vitro cytokine preincubation of BM samples on the leukemia-reducing effect of LAK cells could be demonstrated in all samples studied (p < 0.001; diagnosis: n = 10, relapse: n = 3, complete remission: n = 7). Patients had a better prognosis if CD34-positive colonies in AML could be reduced by cytokine incubation (p = 0.03) or coculture with autologous LAK cells in vitro (p = 0.04). Our data show that cytokines as well as LAK cells alone and in combination can reduce, however not eliminate clonogenic AML cells. Such mechanisms might be responsible for maintaining stable remissions in AML.     

Enrichment of interleukin-2-responsive natural killer progenitors in human bone marrow

Natural killer (NK) cells can be cultured in interleukin-2 (IL-2)- containing medium from selected human bone marrow (BM) cells obtained after the elimination of mature T and NK cells. To isolate and characterize IL-2-responsive NK progenitors in the selected BM cells, we investigated the expression of IL-2 receptors (IL-2R) on these cells. Neither CD25 (IL-2R alpha) nor IL-2R beta antigen was observed on the selected BM cells before culture. However, CD25+ cells without detectable levels of IL-2R beta antigen appeared 24 hours after culture in IL-2-containing medium. Cells were sorted from each fraction of the selected BM cells 24 hours after culture after staining with anti-CD33, anti-CD34, and anti-CD25 monoclonal antibodies. The generation of NK cells (CD3- CD56+ cells) and NK activity were observed only from the CD33-/CD34-/CD25+ cell fraction after culture in IL-2-containing medium. The frequency of IL-2-responsive NK progenitors relative to the fraction was 1/231 (95% confidence range, 1/156 to 1/289), which corresponded to the frequency relative to the total number of selected BM cells when the frequency relative to the CD33-/CD34-/CD25+ cell- fraction was converted according to the percentage of these cells in the total number of selected BM cells. These results indicated that IL- 2-responsive NK progenitors were enriched in the CD33-/CD34-/CD25+ cell fraction.     

Regulation of lymphokine-activated killer activity in T-replete and T-cell-depleted human bone marrow by interleukin 4.

Donor-derived lymphokine-activated killer (LAK) cells appear to play a role in mediating an antileukemia effect in recipients of both T-replete and T-cell-depleted (TCD) bone marrow transplants. LAK activity, however, is subject to regulation by cytokines other than interleukin 2 (IL-2). The purpose of this study was to examine the effect of interleukin 4 (IL-4) on the induction of LAK activity in both T-replete and TCD bone marrow. IL-4 inhibited the induction of LAK activity in a time- and dose-dependent manner in both T-replete and TCD bone marrow cultures, although there appeared to be a differential effect, suggesting that T and non-T LAK precursors have different thresholds of sensitivity to IL-4. Single-cell cytotoxicity assays indicated that IL-4 did not inhibit binding of LAK effectors to targets but did reduce the frequency of lytic conjugates. Kinetic analysis techniques demonstrated that IL-4 decreased the maximal rate of target cell lysis by IL-2-activated LAK precursors and inhibited the rate of lytic programming. These data indicate that IL-4 is able to regulate the induction of LAK activity in both T-replete and TCD bone marrow and may play a role in modulating the generation of effector cells with potential antileukemia reactivity in vivo.     

Characterization of natural killer cells cultured from human bone marrow cells

Human bone marrow (BM) cells, depleted of nylon wool-adherent cells, T cells, and natural killer (NK) cells, were cultured in medium containing recombinant interleukin 2 (rIL2). After 21 or 24 days in culture, numerous lymphoid cells with multiple azurophilic granules and a morphology similar to large granular lymphocytes (LGL) were found. Two-color analysis of surface phenotype showed many of these cells to be NKH1-positive and a limited number of cells had other NK markers such as CD16, CD2, or CD8. The CD3 antigen was not coexpressed with NKH1. The cultured BM cells were cytotoxic for K562, Daudi, and Raji cell lines. The NKH1+, CD2-, CD3-, CD16- cells were sorted and, in addition to having the LGL morphology, were found to be cytotoxic for K562 cells (NK [K562]). The generation of NK(K562) activity was significantly suppressed by 5-bromodeoxyuridine plus ultraviolet light treatment, indicating that DNA synthesis is required. These experiments suggest that the described culture conditions allow differentiation of progenitor cells, into immature, but functionally active, NK cells.     

Assay of lymphokine-activated killer activity generated from bone marrow cells of children with acute lymphoblastic leukemia

We recently reported that low molecular weight B-cell growth factor (LMW-BCGF) plus recombinant interleukin-2 (rIL-2) synergistically induced lymphokine-activated killer (LAK) activity from the bone marrow (BM) cells of children with acute lymphoblastic leukemia (ALL). The kinetics of cell growth, antigenic phenotype, and lytic activity of the generated effector cells were further analyzed in this study. BM cells from ALL patients with active disease and in complete remission (CR) were cultured with a combination of LMW-BCGF and rIL-2. Monoclonal antibodies (anti-CD3 and anti-Leu 19) and immunomagnetic beads were used to separate LAK cells into three subsets: CD3+/Leu 19-, CD3+/Leu 19+, and CD3-/Leu 19+. Cytotoxicity assays with different subsets were performed versus K562, Raji, and autologous leukemic cells, using a 3- hour 51Cr release test. There was a significant cell expansion of 54- fold (mean value) for CD3+ cells and 15-fold for Leu 19+ cells in culture with LMW-BCGF plus rIL-2 for 7 to 14 days, whereas no cell expansion was observed in culture with rIL-2 alone. Although NK activity (K562) was generated from leukemic BM cells in culture with rIL-2 alone, it is only about one third of that generated in culture with rIL-2 plus LMW-BCGF. Analysis of lytic activity of cells generated in the latter cultures demonstrated that CD3-/Leu 19+ cells expressed highest lytic activity against NK-sensitive K562 cells as well as against NK-resistant Raji cells. CD3+/Leu 19+ cells showed median cytotoxicity, and CD3+Leu 19- cells mediated only minimal cytotoxic activity. Also, lytic activity of CD3-/Leu 19+ cells against autologous leukemic blasts was noted in patients with active disease. Our results demonstrate that LAK activity generated from BM cells by LMW-BCGF and r- IL2 is mediated mainly by two types of Leu 19+ cells: CD3-/Leu 19+ NK cells and CD3-/Leu 19+ T cells. Although CD3+ T cells (both Leu 19+ and Leu 19-) mediated less antitumor cytotoxicity than CD3-/Leu 19+ cells, the former cells were the major expanding cell population in culture with LMW-BCGF and rIL-2. The new culture system may be effective in generation of cells with LAK activity for therapeutic use.     

B-lineage colonies from normal, human bone marrow are initiated by B cells and their progenitors.

We have recently described a reproducible method whereby colonies containing cells that secrete immunoglobulin (Ig) can be grown from normal, human, adult bone marrow samples. The present report characterizes the cells that initiate these colonies. It is shown that all clonogenic cells express the CD19 surface antigen, as removal of these cells before plating in the B-cell colony assay abolished the subsequent growth of plaque-forming, B-lineage colonies. Cells from both the CD10+ and CD20+ B-lineage subpopulations initiated the growth of B-cell colonies, as removal of either subset resulted in a 50% reduction in the number of resulting B-cell colonies. The removal of activated B cells (CD23+), plasma cells (PCA-1+), or myeloid cells (CD13+) did not lead to a significant depletion in B-cell colony formation. Pre-B cells that were not yet committed to Ig light chain expression were also able to differentiate and proliferate into Ig-secreting colonies under the culture conditions used. Colonies initiated by these light chain uncommitted cells were distinguished using a replicate protein immunoblotting technique, which detects the simultaneous secretion of Ig kappa and Ig lambda from single colonies. These experiments provide evidence that the CD10 antigen is expressed on B-lineage cells before Ig light chain commitment, whereas CD20 is not. In conclusion, this B-cell colony assay provides a system for studying the differentiation of bone marrow-derived B cells and their precursors into Ig-secreting cells.     

The generation of human natural killer cells from CD34+/DR- primitive progenitors in long-term bone marrow culture

We have adapted the stroma-dependent long-term bone marrow culture (LTBMC) system to study the development of human natural killer cells (NK) from the CD34+/HLA-DR- (CD34+/DR-) BM mononuclear cell (BMMNC) population. The CD34+/DR- population does not express any known antigens associated with myeloid or lymphoid lineage and has been shown by us and others to contain primitive hematopoietic progenitors capable of both self-renewal and differentiation to myeloid lineage. CD34+/DR- cells obtained from normal human BM by fluorescence-activated cell sorting were plated on allogeneic, irradiated BM stromal layers. After 5 weeks of culture in the presence of media containing recombinant interleukin-2 and human serum, 147- +/- 21-fold expansion of cells with the morphologic appearance of large granular lymphocytes was observed. Cultured cells (84.8% +/- 1.5%) expressed the characteristic CD56+/CD3- phenotype of NK. A proportion of CD56+/CD3- cells expressed other markers of lymphoid lineage that have been associated with mature NK, including CD2 (7.8% +/- 1.2%), CD7 (19.5% +/- 2.8), CD8 (3.1% +/- 1.0%), and CD16 (4.5% +/- 1.3%). The cultured cells did not express other antigens associated with T-lymphocyte (CD3, CD5, T-cell receptor [TCR] alpha/beta and TCR gamma/delta), B-lymphocyte (CD19), myeloid (MY8, CD33, and CD71), or monocytoid (CD14 and CD15) lineage and did not express the CD34 antigen associated with hematopoietic progenitors present on the starting population. This NK population was cytotoxic against both K562 (E:T 20:1; 79% +/- 1.9%) and Raji (E:T 20:1; 38% +/- 5.7%) target cell lines. The NK progenitor frequency in the CD34+/DR- cell population determined by limiting dilution of CD34+DR- on stromal layers followed by a functional chromium release assay against K562 targets was 1:169 +/- 50 CD34+/DR- cells. The data suggest that human LTBMC developed to study myeloid differentiation can be modified to study the origin and development of the NK and possibly other lymphoid lineages. Modified cultures show that cells with morphologic, phenotypic, and functional characteristics of NK can be derived from a population of BMMNC with the phenotype of primitive hematopoietic progenitors and without phenotypic evidence of lymphoid- or myeloid- lineage commitment. Further studies will address the cell of origin and the ontogeny of human NK and other lymphoid lineages.     

Generation of human natural killer cells from immature progenitors does not require marrow stromal cells

Human natural killer (NK) cells comprise 10% to 15% of peripheral blood mononuclear cells and have an important role in immune responses against tumors, viral infections, and graft rejection. NK cells originate in bone marrow (BM), but their progenitors and lineage development have not been completely characterized. We studied the generation of NK cells from purified CD34+HLADR- and CD34+HLADR+ BM progenitors and the influence of various cytokines on their production. We show that CD3-CD56+ cytotoxic NK cells can develop from both progenitors populations when interleukin-2 (IL-2) is present in an in vitro suspension culture system containing IL-1 alpha and stem cell factor. Up to 83.8% and 98.6% CD3-CD56+ cells were detected in CD34+HLADR- and CD34+DR+ cultures, respectively, after 5 weeks of culture; significant numbers of NK cells were first detected after 2 weeks. Cytotoxic activity paralleled NK cell numbers; up to 70% specific lysis at an effector:target ratio of 10:1 was observed at 5 weeks. IL-7 also triggered development of CD3-CD56+ cells from these immature progenitors (up to 24% and 55% appeared in CD34+HLADR- and CD34+HLADR+ cultures, respectively). Our data suggest that BM stromas are not necessary for NK cell development and that IL-2 remains essential for this lineage development and differentiation.     

Lysis of human alveolar macrophages by lymphokine-activated killer cells

In order to determine if human LAK cells were cytotoxic against autologous AM phi, we studied the ability of human peripheral blood MNCs, stimulated in vitro with recombinant human IL-2, to lyse AM phi in a four-hour 51Cr-release assay. These cells showed significant cytotoxicity against autologous AM phi. The AM phi which had been cultured for four days served as better targets than freshly isolated AM phi. Kinetic study showed that the lysis of AM phi was proportional to the incubation time of MNCs with IL-2 and that LAK cells against AM phi required two days of in vitro culture with IL-2 for their induction. Freshly isolated MNCs did not lyse AM phi but did lyse K562 target cells, indicating that AM phi are natural killer-resistant. The phenotypes of effector cells against AM phi were found to be CD8+ or CD16+ (or both). These studies indicate that IL-2 can generate LAK cells against autologous AM phi, and this cytolytic activity must be taken into account when IL-2 or LAK cells are used for immunomodulation in patients with cancer.     

Induction of lymphokine-activated killer cells against human leukemia cells in vitro

Summary The induction of lymphokine-activated killer (LAK) cells against fresh human leukemia cells was investigated. Two thirds of the 62 leukemias examined were susceptible to the lytic effect of allogeneic IL-2 induced LAK cells in vitro. No substantial differences could be detected between myeloid or lymphoid leukemias or with regard to the FAB subtype or the immunophenotype. Culturing mononuclear cells from peripheral blood or bonemarrow of leukemia patients with IL-2 resulted in an expansion of residual large granular lymphocytes and development of cytotoxic activity. The combination of IL-2 with IFN-gamma or the presence of tumor cells during the activation process led to an enhancement of LAK cell cytotoxicity. These results suggest that LAK cells may be useful in the treatment of leukemia.Supported by the Deutsche Krebshilfe e.V./Mildred Scheel Stiftung für Krebsforschung, Bonn (W 19/87/Te 1)     

Adherent lymphokine-activated killer cells in chronic myelogenous leukemia: a benign cell population with potent cytotoxic activity

We generated a homogeneous population of cells with cytotoxic activity termed "adherent lymphokine-activated killer" (ALAK) cells from the peripheral blood of nine patients in the chronic phase of Ph1 positive chronic myelogenous leukemia (CML). The selective enrichment of CML ALAK cells depended on their propensity to adhere to plastic and proliferate when cultured in the presence of recombinant interleukin-2 (rIL-2) for 14 days. Culture of peripheral blood mononuclear cells under these conditions resulted in growth of a uniform population of cells with morphologic characteristics of large granular lymphocytes. The NKH1+/CD3- phenotype associated with IL-2-stimulated natural killer (NK) cells was present on 79% +/- 9% of cells. Absence of colony formation in conditions promoting the growth of CFU-GEMM indicated that the CML ALAK population was not contaminated with viable hematopoietic progenitors. Cytogenetic analysis of the CML ALAK population revealed 119/120 Ph1 negative metaphases and l/120 Ph1 positive metaphase in six patients. Southern blot analysis of CML ALAK failed to demonstrate a bcr gene rearrangement in seven patients known to have a bcr gene rearrangement in myeloid cells. Comparison of ALAK populations derived from peripheral blood of CML patients and normals revealed similar cytotoxicity against the NK-sensitive K562 cell line (104 +/- 36 LU v 88 +/- 19 LU; P = NS) and the NK-resistant Raji cell line (93 +/- 26 LU v 98 +/- 28 LU; P = NS). The proliferative capacity of CML ALAK cells (101 +/- 33 fold expansion) exceeds the growth potential of the normal ALAK cells (22.3 +/- 3 fold expansion; P = .02). Direct comparison of equal numbers of CML ALAK cells and a CML LAK cell population produced by incubation of peripheral blood mononuclear cells in rIL-2 for 14 days without adherence revealed that the CML LAK population had significantly lower lytic activity against K562 and Raji cell lines. We are able to expand CML peripheral blood mononuclear cells to provide a population of ALAK cells with potent cytotoxic activity. The CML ALAK population is relatively homogeneous, not contaminated with viable stem cells, not derived from a malignant lineage, and more cytotoxic than equal numbers of CML LAK cells. Further studies are underway to determine if this ALAK population may be effective in autologous killing of chronic myelogenous leukemia stem cells.     

Phenotypical study of human lymphokine-activated killer (LAK) cells

In the present study, T-cell enriched lymphocyte populations were stimulated with recombinant interleukin-2 (IL-2) to obtain lymphokine-activated killer (LAK) cells, and their cytotoxicity was tested against different target cells. The expression of phenotypical markers with a panel of monoclonal antibodies (Moabs) using indirect immunofluorescence techniques and cytofluorometric analysis was studied. The results showed slight variations in T-cell antigen expression and an increase in the expression of immature NK and proliferation associated antigens.     

Target-induced death by apoptosis in human lymphokine-activated natural killer cells

Activated human natural killer (NK) cells undergo rapid apoptotic cell death after ligand binding to the Fc receptor (CD16). We examined whether human NK cells die after engagement in cytolytic functions. Peripheral blood NK cells, with and without prior activation in vitro with interleukin-2 (IL-2), were tested for the occurrence of cell death after incubation with K562, the prototype NK-sensitive target cell. A proportion (15.2%) of NK cells that were stimulated for 3 days with IL- 2 and then incubated for 4 hours with K562 cells showed rapid cell death, but NK cells not stimulated with IL-2 did not. This cell death was found to involve nuclear condensation and fragmentation and DNA cleavage, all of which are characteristic of apoptosis. These data indicate that a proportion of activated human NK cells undergo apoptosis as they engage in target cell lysis. Target-induced NK cell death may represent an important mechanism for regulation of inflammatory processes involving NK cells.     

TCR gamma delta bearing lymphocyte clones with lymphokine-activated killer activity against autologous leukemic cells

Activated T lymphocytes with the T-cell receptor (TCR) gamma delta (CD3+ and TCR delta 1+) exhibit strong cytotoxic activity against the standard natural killer (NK) and lymphokine-activated killer (LAK) sensitive target cells. In order to test the cytotoxic activity of gamma delta T lymphocytes against autologous leukemic cells, 84 clones of gamma delta T lymphocytes were obtained from the peripheral blood of three acute lymphoblastic leukemia (ALL) patients. Forty-four of these T-cell clones were active against an LAK-sensitive cell line and the other 40 were active against K562, an NK target cell line. In each of the three patients, cytotoxic clones against autologous leukemic cells were obtained. Among the 84 clones, ten were able to kill autologous tumor cells, including eight that lyse the LAK-sensitive target and two with NK activity. The clones were highly cytotoxic, stable, and easily expanded in large quantity.     

Immunotherapy of hepatocellular carcinoma with autologous lymphokine-activated killer cells and/or recombinant interleukin-2

Summary Five patients with hepatocellular carcinoma were subjected to immunotherapy: three patients were treated by adoptive immunotherapy with lymphokine-activated killer (LAK) cells and recombinant interleukin-2 (rIL-2), and two patients by systemic administration of rIL-2 alone. In one patient with diffuse-type hepatocellular carcinoma and portal vein thrombosis who was treated by infusion of LAK cells (a total number of 1.5x10¹⁰ cells/13 doses) and continuous rIL-2 administration (a total dose of 1.25x10⁸ units) via a percultaneously placed hepatic arterial catheter, the size of the tumor reduced dramatically and the portal vein thrombosis retracted. In two patients who had LAK cells infused (totals of 6.6x10⁹ cells/4 doses and 3.1x10⁹ cells/2 doses, respectively) during hepatic angiogram followed by systemic administration of rIL-2 twice a day, no clinical improvement was noticed. In two patients who received rIL-2 alone systemically (total doses of 8.9x10⁷ and 5.5x10⁷ units, respectively), neither clinical improvement nor severe side effects were observed. The results suggest that adoptive immunotherapy combined with continuous local administration of rIL-2 via a percutaneously placed hepatic arterial catheter may be an effective therapy without apparent side effects for patients with hepatocellular carcinoma who cannot be treated by conventional cancer therapy.     

Antiproliferative activity of quercetin on normal bone marrow and leukaemic progenitors

We used an in vitro clonogenic assay in semi-solid medium to test the sensitivity of normal bone marrow and acute myeloid and lymphoid leukaemia progenitors to the flavonol quercetin. We have studied 14 acute myeloid (AML) and four acute lymphoid (ALL) leukaemias. All ALL and the vast majority of AML (12/14) had a high sensitivity to quercetin with more than 50% growth inhibition at 2 x 10(-6) M quercetin. One M3-AML was partially quercetin-sensitive displaying 60% surviving AML-colony forming units (CFU-AML) at a quercetin concentration of 10(-5) M. One M1-AML was resistant to the growth inhibitory effect of quercetin at a concentration of 2 x 10(-5) M. The clonogenic efficiency of both AML and ALL positively correlated with leukaemic colony-forming unit (CFU-L) sensitivity to quercetin suggesting that this parameter can be useful in predicting quercetin responsiveness of leukaemic cells. We have also studied the effect of various quercetin concentrations on colony formation by normal bone marrow cells. At a quercetin concentration of 10(-5) M, we observed (in five different experiments) a mean recovery of 53% and 65% of erythroid blast-forming units (BFU-E) and granulocyte-macrophage colony-forming units (CFU-GM), respectively. Thus, normal bone marrow appeared partially resistant to quercetin, being inhibited less than 50% by quercetin concentration higher than 2 x 10(-5). When normal bone marrow were deprived in CD34+ haematopoietic progenitors the resultant population became highly sensitive to quercetin, with a mean recovery of BFU-E and CFU-GM of 5% and 12% of controls respectively in the presence of 2 x 10(-5) M quercetin. Furthermore, CD34 progenitors, positively selected, appeared fully resistant to quercetin concentrations as high as 2 x 10(-5) M. Thus, CD34+ progenitors are a quercetin-resistant component in normal bone marrow. In conclusion, our results further provide a biological basis for the therapeutic use of quercetin, considering that this compound could inhibit leukaemic cell growth without suppressing normal haematopoiesis.     

Aplastic anemia: presence in human bone marrow of cells that suppress myelopoiesis.

Bone marrow from a patient with aplastic anemia was shown by multiple criteria to have a block in early myeloid differentiation. This block was overcome in vitro by elimination of marrow lymphocytes. Furthermore, this differentiation block was transferred in vitro to normal marrow by coculturing with the patient's marrow. We suggest that some cases of aplastic anemia may be due to an immunologically based suppression of marrow cell differentiation rather than to a defect in stem cells or their necessary inductive environment.