Effects of Mpl ligands on platelet production and function in nonhuman primates

Endogenous thrombopoietin (TPO) stimulates platelet production in nonhuman primates dose-dependentbyinducing megakaryocyte development from early marrow hematopoietic progenitors and subsequent proliferation and endoreduplication. Recombinant human TPO, nonpegylated or pegylated recombinant human megakaryocyte growth and development factor produce log-linear responses in peak peripheral platelet counts (or peripheral platelet mass turnover), platelet TPO receptor density, and marrow megakaryocyte volume, ploidy, number and mass. Mpl ligand therapy sustains normal peripheral platelet concentrations following myelosuppressive chemotherapy in baboons and corrects peripheral platelet counts in HIV-infected chimpanzees with severe thrombocytopenia. Whereas Mpl ligands do not directly induce platelet aggregation in vitro, they enhance aggregatory responsiveness of platelets to physiologic agonists both in vitro and transiently ex vivo following treatment with Mpl ligands. However, platelet recruitment into forming thrombus is not augmented by these agents when evaluated in quantitative rabbit or baboon models of platelet-dependent thrombus formation, except for the direct effect of platelet concentration per se. These findings indicate that appropriate dosing of these agents prevents thrombocytopenia without increasing the risk of platelet-dependent thrombo-occlusive complications.     

A combination of stem cell factor and granulocyte colony-stimulating factor enhances the growth of human progenitor B cells supported by murine stromal cell line MS-5

We have developed a long-term culture system using the murine bone marrow stromal cells MS-5 to support the growth of progenitor B cells with CD34^–, CD10⁺, CD19⁺, and cytoplasmic μ chain (Cμ)-negative surface phenotype from human CD34⁺ cells purified from umbilical cord blood (CB). When 10³ CB CD34⁺ cells/well were seeded on MS-5 stromal cells at the beginning of culture in the absence of exogenously added cytokines, progenitor B cells first appeared after 14 days, and the maximal cell production was achieved during the 6th week of culture. Intriguingly, the addition of recombinant human stem cell factor (rhSCF) and granulocyte colony-stimulating factor (rhG-CSF), but not rhIL-7, strikingly enhanced the growth of progenitor B cells from CB CD34⁺ population cultured on MS-5 stromal cells. The culture of progenitor B cells could be maintained until the 6th week of culture when some cells were revealed to have a Cμ⁺ phenotype, and a small number of cells had immunoglobulin μ chain on their cell surface in the presence of both rhSCF and rhG-CSF. When CD34⁺ cells were cultured physically separated from the stromal layer by membrane, supportive effects of MS-5 stromal cells for the growth of progenitor B cells were not observed. These results suggest that the present culture system could generate progenitor B cells to proliferate from CB CD34⁺ cells, that some of these progenitor B cells could differentiate into immature B cells in conjunction with rhSCF and rhG-CSF, and that a species-cross-reactive membrane-bound factor(s), which stimulates early human B lymphopoiesis, may exist in MS-5 stromal cells. Further studies are required to investigate the mechanism how rhG-CSF acts on progenitor B cells to allow their proliferation and differentiation.     

A novel thrombopoietin signaling defect in polycythemia vera platelets

The pathogenesis of polycythemia vera (PV), a disease involving a multipotent hematopoietic progenitor cell, is unknown. Thrombopoietin (TPO) is a newly characterized hematopoietic growth factor which regulates the production of multipotent hematopoietic progenitor cells as well as platelets. To evaluate the possibility that an abnormality in TPO-mediated signal transduction might be involved in the pathogenesis of PV, we examined TPO-induced protein tyrosine phosphorylation using platelets as a surrogate model system. Platelets were isolated from the blood of patients with PV as well as from patients with other chronic myeloproliferative disorders and control subjects. Impaired TPO-mediated platelet protein tyrosine phosphorylation was a consistent observation in patients with PV as well as those with idiopathic myelofibrosis (IMF), in contrast to patients with essential thrombocytosis, chronic myelogenous leukemia, secondary erythrocytosis, iron deficiency anemia, hemochromatosis, or normal volunteers. Thrombin-mediated platelet protein tyrosine phosphorylation was intact in PV platelets as was expression of the appropriate tyrosine kinases and their cognate substrates. However, expression of the platelet TPO receptor, Mpl, as determined by immunoblotting, chemical crosslinking or flow cytometry was markedly reduced or absent in 34 of 34 PV patients and also in 13 of 14 IMF patients. Impaired TPO-induced protein tyrosine phosphorylation in PV and IMF platelets was uniformly associated with markedly reduced or absent expression of Mpl. We conclude that reduced expression of Mpl is a phenotypic characteristic of platelets from patients with PV and IMF. The abnormality appears to distinguish PV from other forms of erythrocytosis and may be involved in the platelet function defect associated with PV.     

Ex vivo expansion of megakaryocyte progenitor cells: cord blood versus mobilized peripheral blood

Thrombocytopenia is a problematic and potentially fatal occurrence after transplantation of cord blood stem cells. This problem may be alleviated by infusion of megakaryocyte progenitor cells. Here, we compared the ability of hematopoietic progenitor cells obtained from cord blood and expanded in culture to that of mobilized peripheral blood cells. The CD34(+) cells were plated for 10 days in presence of thrombopoietin (TPO) alone and combined with stem cell factor (SCF), Flt3-ligand (FL), interleukin-3 (IL-3), IL-6, and IL-11. Cells were analyzed for the CD41 and CD42b expression and for their ploidy status. Ex vivo produced platelets were enumerated. We show that (1) TPO alone was able to induce differentiation of CD34(+) cells into CD41(+) cells, with limited total leucocyte expansion; (2) the addition of SCF to TPO decreased significantly CD41(+) cell percentage in CB, but not in MPB; and (3) in CB, the addition of FL, IL-6, and IL-11 to TPO increased the leukocyte expansion with differentiation and terminal maturation into MK lineage. In these conditions, high numbers of immature CD34(+)CD41(+) MK progenitor cells were produced. Our results thereby demonstrate a different sensitivity of CB and MPB cells to SCF, with limited CB MK differentiation. This different sensitivity to SCF (produced constitutively by BM stromal cells) could explain the longer delay of platelet recovery after CB transplant. Nevertheless, in CB, the combination of TPO with FL, IL-6, and IL-11 allows generation of a suitable number of immature MK progenitor cells expressing both CD34 and CD41 antigens, which are supposed to be responsible for the platelet recovery after transplantation.     

Murine bone marrow stromal cells sustain in vivo the survival of hematopoietic stem cells and the granulopoietic differentiation of more mature progenitors

The study of the human hematopoietic system would be facilitated by availability of a relevant animal model. Because the medullar microenvironment is made of different types of cells, interactions between hematopoietic cells and stromal cells are difficult to analyze in detail. As an approach for establishing an in vivo model to dissect these interactions, we grafted murine bone marrow fibroblastic cells (MS-5 cell line) with hematopoietic cells into the kidney capsule of syngenic mice. To identify the origin of cells present in the graft, we used green fluorescent protein-stable transfected MS-5 cells for the transplantation. To analyze the evolution of stromal cells and identify hematopoietic cells able to develop in these conditions, we performed morphology, histochemistry, and immunohistology on tissue sections at different times after transplantation. When injected alone, MS-5 cells differentiate into adipocytes. When injected with a bone marrow suspension or with isolated CD45+ cells (leukocytes), the stromal cells keep their fibroblastic morphology and their alkaline phosphatase expression and sustain granulopoiesis. When injected with hematopoietic stem cells called c-kit+ Sca-1+ Lin- suspension, clusters of hematopoietic cells are also observed: They do not present any granulopoietic activity and do not belong to B or T population nor to erythroid lineage. They are quiescent, induce bone marrow recovery and survival of lethally irradiated recipients, are able to form macroscopic colonies in the spleen, and are able to form very few colonies in vitro, suggesting that they are hematopoietic stem cells. In conclusion, our results show that reticular fibroblastic stromal cells MS-5 sustain the survival of stem cells and are not able to induce their differentiation. However, they can control differentiation, proliferation, and/or survival of hematopoietic cells engaged in myeloid lineage.     

Megakaryocytopoiesis in vitro: from the stem cells' perspective

Megakaryocytopoiesis is a complex network regulated by different megakaryocyte (MK)-stimulating factors (i.e., thrombopoietin [TPO], stem cell factor [SCF], interleukin 3 [IL-3], IL-6, IL-11 and GM-CSF). Although all of these factors can affect human and murine megakaryocytopoiesis at different levels of MK development, the effect on very primitive hematopoietic stem cells (HSC) is not well understood. We have further characterized the in vitro biological activity of recombinant murine TPO, SCF and IL-3 on the maturation and proliferation of MK progenitors from different murine primitive hematopoietic cells in a fibrin clot system under serum-free conditions. Neither TPO nor SCF alone induced MK colony formation (CFU-MK) from Lin- Sca+ cells. However, isolated large and mature MKs were observed in the presence of TPO. In contrast, IL-3 exerted a potent effect on CFU-MK formation from Lin- Sca+ cells. On this population of HSC, a significant increase of large MK colonies with mature MK were obtained under those conditions in which TPO was combined with IL-3 or SCF plus IL-3. Similar results were obtained with murine bone marrow cells enriched by primitive progenitors from day 3 post-5-fluorouracil treated mice (5-FUBMC). In contrast, TPO-sensitive precursors were detected in fetal liver cells (FLC). These cells differentiate and proliferate to MK progenitors in the presence of TPO. A significant increase in the number of CFU-MK was induced when TPO was combined with either IL-3 or SCF. On these populations of primitive hematopoietic progenitors, IL-3 induced both the proliferation and differentiation of MK progenitors. Because erythropoietin and TPO share similarities between their molecules and their receptors, we studied whether these growth factors may modulate megakaryocytopoiesis from FLC. Flow cytometry analysis of FLC expressing erythroid markers demonstrated that these cells expressed c-Mpl receptor. In our in vitro studies, although EPO by itself did not induce MK colonies from FLC, it enhanced the proliferative activity of TPO. High ploidy and proplatelet-shedding MK were observed in Lin- Sca+ cells, 5-FUBMC and FLC stimulated with TPO alone or in combination with other MK-stimulating factors. Based on these observations, we propose that TPO, IL-3 and SCF constitute early MK-acting factors with differential proliferative and differentiative activities on murine stem cells. TPO by itself does not appear to be involved in the proliferation of MK progenitors from bone marrow HSC. TPO appears to induce in these cells the commitment toward MK differentiation. However, this growth factor may enhance the proliferative activity of IL-3. IL-3 is an early MK-stimulating factor able to induce in vitro the proliferation and differentiation of MK progenitors from HSC.     

The combined administration of daniplestim and Mpl ligand augments the hematopoietic reconstitution observed with single cytokine administration in a nonhuman primate model of myelosuppression

This study evaluated the ability of daniplestim, a high affinity interleukin 3 receptor agonist, to enhance the hematopoietic response of Mpl ligand (Mpl-L) administration in nonhuman primates following severe, radiation-induced myelosuppression. Rhesus monkeys were total body x-irradiated (TBI) to 600 cGy, midline tissue dose. Beginning on day 1 post-TBI, animals were s.c. administered daniplestim (100 microg/kg bid; n = 4), Mpl-L (10 microg/kg qd; n = 3), daniplestim (100 microg/kg bid) plus Mpl-L (10 microg/kg qd) (n = 4) or 0.1% autologous serum (AS) (n = 11) for 18 days. CBCs were monitored for 60 d after TBI. The duration of thrombocytopenia (platelet count; PLT <20,000/microl) was significantly decreased by the administration of daniplestim (6.5 d, p = .01), Mpl-L (3.0 d, p = .003) and the coadministered daniplestim/Mpl-L (1.3 d, p = .001) compared to controls (10.4 d). As monotherapy Mpl-L but not daniplestim significantly improved the PLT nadir (21,000/microl, p = .023 and 5,000/microl, p = .266, respectively) compared to the control (3,000/microl). The combined administration of daniplestim and Mpl-L significantly improved the PLT nadir (28,000/microl, p = .007) compared to both the control cohort (3,000/microl) and the daniplestim only cohort (5,000/microl, p = .043). Recovery of PLT to preirradiation values occurred earlier in the daniplestim only (d 21) or the daniplestim/Mpl-L cohorts (d 18) than in the Mpl-L only or control cohorts (d 28, d 29, respectively). The administration of daniplestim or Mpl-L alone neither shortened the duration of neutropenia (ANC<500/microl) compared to the controls (15.8 d, 16.0 d versus 16.2 d, respectively), nor improved the recovery time of neutrophils to baseline values (d 22, d 25, and d 23, respectively). The ANC nadir was significantly improved by daniplestim alone but not Mpl-L administration (76/microl, p = .001 and 50/microl, p = .093, respectively) compared to the controls (8/microl). Coadministration of daniplestim and Mpl-L significantly improved the ANC nadir (196/microl, p = .001) compared to either the AS- or the monotherapy-treated cohorts. Also the duration of neutropenia observed in the AS-controls (16.2 d) was significantly reduced in the daniplestim/Mpl-L cohort (10.8 d, p = .002). The combined administration of daniplestim and Mpl-L significantly improved hematopoietic recovery and further enhanced the stimulatory effect of cytokine monotherapy, as well as reducing clinical support requirements after radiation-induced bone marrow myelosuppression.     

Early Australian clinical studies with pegylated recombinant human megakaryocyte growth and development factor

Pegylated recombinant human megakaryocyte growth and development factor (PEG-rHuMGDF, an Mpl ligand) is a truncated form of native thrombopoietin currently undergoing clinical development. A series of studies in Australia have examined the safety and biological activities of PEG-rHuMGDF. Administration of PEG-rHuMGDF causes a dose-dependent increase in platelet count but has no effect on white cell count or hematocrit. These platelets are morphologically and functionally normal. When administered following moderately myelosuppressive chemotherapy, PEG-rHuMGDF significantly enhances platelet recovery, although scheduling in relation to chemotherapy may be important in optimizing the full effects. PEG-rHuMGDF mobilizes progenitor cells of multiple hematopoietic lineages, and alters the kinetics of peripheral blood progenitor cell mobilization after chemotherapy and filgrastim. PEG-rHuMGDF is well tolerated and does not cause toxicity similar to that observed with other thrombopoietic cytokines. Numerous studies are underway to help determine the precise role of PEG-rHuMGDF in clinical practice.     

Murine serum obtained from bone marrow-transplanted mice promotes the proliferation of hematopoietic stem cells by co-culture with MS-5 murine stromal cells

To examine whether serum obtained from bone marrow-transplanted mice can selectively expand hematopoietic stem cells (HSCs) among whole bone marrow cells in vitro, whole bone marrow cells were cultured with or without MS-5 murine stromal cells in the presence of serum obtained from transplanted mice on day 3 (day 3 serum) or serum from normal mice for 7 days. When whole bone marrow cells and MS-5 cells were co-cultured in day 3 serum for 7 days, the c-kit-positive, Sca-1-positive, lineage marker-negative cells (KSL cells) expanded approximately 25 times; however, when they were co-cultured in normal serum for 7 days, the KSL cells expanded approximately 1.3 times. Direct contact between the whole bone marrow cells and MS-5 cells was essential for expansion of KSL cells in the co-culture, and it upregulated the expression of some cytokines in MS-5. Above all, the day 3 serum specifically upregulated the expression of SCF, SDF-1 alpha, G-CSF, IL-11 and IL-6 in MS-5. The level of testosterone in the day 3 serum was higher than normal serum and the addition of the testosterone in the culture expanded the KSL cells among whole bone marrow cells on MS-5 cells and also upregulated the expression of SDF-1 alpha, IL-11 and IL-6 in MS-5. These data indicates that the serum of bone marrow-transplanted mice contains a factor(s) that induced changes in the expression levels of various cytokines in MS-5 stromal cells and enabled the MS-5 cells to expand the KSL cells among whole bone marrow cells.     

Differentiation from thymic B cell progenitors to mature B cells in vitro

The role of the thymic microenvironment in the development of murine thymic B cells has yet to be fully clarified. We therefore investigate the microenvironment that supports the development of mature thymic B cells (sIg+/B220+/CD43-B cells) from thymic B cell progenitors with immunophenotypes of sIg-/B220med/CD43+ cells. As we have previously reported, thymic B cells generated from these progenitors in the thymus are CD5+ B cells. We next study the in vitro condition that supports the differentiation of thymic B cell progenitors. Stromal cells (from the bone marrow or thymus), thymus-derived cell lines with the character of thymic nurse cells (TNCs) or thymic epithelial cells (TECs), or the bone marrow-derived cell line (MS-5) are tested for their ability to support B-lymphopoiesis from thymic B cell progenitors. Interestingly, thymic stromal cells (but neither stromal cells from the bone marrow nor stromal cell lines) support the differentiation of thymic B cell progenitors into thymic B cells in the presence of IL-7. Cortical epithelia (but not medullary epithelia, thymic macrophages or dendritic cells) are found to contribute to thymic B cell differentiation. Surface phenotype and Ig rearrangement analyses reveal that mature B cells generated in this condition are primarily CD5+ B cells, indicating that the thymic microenvironment (particularly cortical epithelia) determines the differentiation of thymic B cells.     

The role of recombinant interleukin 11 in megakaryocytopoiesis

Recombinant human interleukin 11 (rHuIL-11) is a multifunctional cytokine with activities on a broad range of hematopoietic cells including primitive stem cells and mature progenitor cells. Analysis of rHuIL-11 in vitro has revealed that its hematopoietic activities are predominantly a result of synergistic interactions with other early-acting factors such as IL-3 and Steel factor. Studies indicate that rHuIL-11 acts directly on purified stem and progenitor cell populations and can support the growth of colony forming units-megakaryocyte in these cultures. In normal animals, rHuIL-11 has a potent effect on cells of the megakaryocyte (MK) lineage. Administration of rHuIL-11 results in a two- to threefold increase in circulating platelets, stimulation of bone marrow (BM) and spleen progenitor numbers, and enhanced MK maturation as measured by a shift to higher ploidy values. rHuIL-11 administration in preclinical models of myelosuppression induced by chemotherapy and/or irradiation has shown a reproducible acceleration of platelet recovery and, in some models, enhanced neutrophil and red blood cell recovery. rHuIL-11 has been tested in a non-human primate myelosuppression model using carboplatin. Administration of rHuIL-11 following carboplatin treatment was found to eliminate the period of severe thrombocytopenia (<20,000 platelets/ml) and enhance the recovery of platelets to normal levels (>100,000/ml). Recently, human clinical trials conducted with rHuIL-11 in patients treated with chemotherapy have demonstrated its potent thrombopoietic activity, including improved platelet nadirs, enhanced platelet recovery and a significant decrease in the number of patients who require platelet transfusions. Combined with the preclinical results, these studies confirm that this cytokine will be an effective agent in the treatment of myelosuppression and thrombocytopenia associated with cancer chemotherapy and BM transplantation.     

Megakaryocyte and platelet structure in thrombocytopoiesis: the effect of cytokines

This paper presents an overview of selected data which the author considers crucial to an understanding of structure/function relationships of megakaryocytes (MK) and platelets. The observation that platelet territories form within the MK cytoplasm and that, therefore, MK and platelet plasma membranes need not be structurally or antigenically identical is substantiated on the basis of results obtained with a variety of experiments. While the predominant site of MK fragmentation is still debated, it is generally accepted that such terms as "proplatelets," "giant platelets" or "megathrombocytes" refer to MK fragments consisting of more than one platelet territory. It is suggested that such fragments be called "compound" platelets to convey a unifying concept. The terms "young" or "immature" could be reserved for platelets which still contain ribosomes, rough endoplasmic reticulum or other organelles not usually seen in circulating platelets. Finally, the structure changes induced by cytokines, such as interleukin 3 (IL-3), IL-6, IL-11 and thrombopoietin have been illustrated.     

Phenotypic characterization of murine thymic microenvironments.

The thymus provides the necessary microenvironments for the differentiation of T lymphocytes. Thymic non-lymphoid cells, such as epithelial cells, macrophages and interdigitating cells are thought to promote sequential stages in T cell differentiation. However, their specific role in each step of T cell differentiation remains to be established. With the development of new monoclonal antibodies it has now become possible to characterize the different thymic stromal cell types. In this review, various aspects of thymic stromal cells and their functions in T cell differentiation are discussed, such as: (1) phenotypic analysis of stromal cells in situ; (2) the application of new "chimeric' monoclonal antibodies which "link' developing thymocytes and stromal cells; (3) perturbation of thymic microenvironments after cyclosporin-A treatment; (4) perturbation of thymic microenvironments in new transgenic mouse lines; (5) phenotypic analysis of in vitro growing stromal cell lines.     

Myelofibrosis: experimental models and human studies

Thrombopoietin (TPO) is the central regulator of megakaryocytopoiesis and thrombocytopoiesis. Preclinical data and human studies have so far shown that the recombinant molecule is safe to administer and associated with very little toxicity. Nevertheless, different experimental animal models have revealed that a chronic exposure to very high doses of TPO could result in myeloproliferative syndromes with a spectrum of pathological features in common with human idiopathic myelofibrosis (PMF). A number of investigators have researched whether TPO or its receptor Mpl were involved in the pathogenesis of human myeloproliferative syndromes which are also characterized by a predominant megakaryocytic involvement, in PMF and primitive essential thrombocythemia. In both diseases, megakaryocyte (MK) progenitors develop autonomously in serum-deprived cultures. This spontaneous MK development is also observed at limiting dilution demonstrating that MK escape the normal regulatory controls. Furthermore, this abnormal MK proliferation and maturation is neither due to an autocrine stimulation by TPO nor by point mutation or deletion in the coding region of the c-mpl gene. This paper will review the data that have been reported to date on the effects of an overexpression of Mpl ligand and related molecules on the induction of experimental myelofibrosis and highlight recent insights into the pathogenesis of PMF.     

Role of CD31/platelet endothelial cell adhesion molecule-1 expression in in vitro and in vivo growth and differentiation of human breast cancer cells

Breast ductal carcinoma in situ is an intraductal proliferation of malignant epithelial cells that diffuse within the ductal system without stromal invasion. Our finding that a subset of these tumors express CD31/platelet endothelial cell adhesion molecule-1 suggests that breast cancer represents an informative model for studying the involvement of the molecule in the morphogenesis, differentiation, and diffusion of this disease. Transfection of CD31 in MDA-MB-231 cells caused reduction in growth, loss of CD44, and acquisition of a ductal morphology. The same effects were maintained in vivo, in which CD31(+) tumors grew with in situ-like aspects, papillary differentiation, and a secretory phenotype. CD44 was down-modulated, with the CD31(+) cells blocked in the G(1) phase. The morphology was highly similar to what was observed in some human CD31(+) ductal carcinomas in situ. MDA-MB-231 mock cells grew in solid sheets, lacking stromal material, and displaying high levels of CD44 and proliferation. CD31(+) cells acquired motility characteristics in in vitro assays, a finding confirmed in vivo by the diffusion of human tumor cells throughout the normal ducts residual in the murine mammary gland. In conclusion, CD31 expression reverts the undifferentiated morphology and aggressive behavior of MDA-MB-231 cells, indicating its active role in the morphogenesis of breast ductal in situ carcinomas.     

The role of platelets during reproduction

The availability of mice with defined defects within the hemostatic system enabled researchers to identify a role the coagulation system for embryonic and placental development. However, the role of platelets during development has only recently been experimentally addressed, giving some insight into potential functions of platelets during development. Thus, a quantitative embryonic platelet defect (severe thrombopenia secondary to NF-E2 deficiency) is associated with an embryonic growth retardation and reduced vascularisation of the placenta. Maternal platelet deficiency is associated with placental hemorrhage, which, however, does not impair embryonic or maternal survival. In vitro studies established that platelets or platelet conditioned medium regulate the invasive properties of human extravillous trophoblast cells and induce a phenotypical switch of trophoblast cells. These data imply that platelets are of relevance during placentation. Conversely, platelets and the formation of platelet-fibrin aggregates are dispensable for the development of the embryo proper, establishing that the lethal phenotypes observed in some embryo slacking coagulation regulators does not result from an inability to form platelet-fibrin aggregates, but likely reflects altered protease dependent signaling during vascular development.     

NK cells differentiated from bone marrow,cord blood and peripheral blood stem cells exhibit similar phenotype and functions

In the present study, we investigated the differentiation of human NK cells from bone marrow, cord blood and mobilized peripheral blood purified CD34⁺ stem cells using a potent culture system. Elutriated CD34⁺ stem cells were grown for several weeks in medium supplemented with stem cell factor (SCF) and IL-15 in the presence or absence of a murine stromal cell line (MS-5). Our data indicate that IL-15 induced the proliferation and maturation of highly positive CD56⁺ NK cells in both types of culture, although murine stromal cells slightly increased the proliferation of NK cells. NK cells differentiated in the presence of MS-5 were mostly CD56⁺ CD7⁻ and a small subset expressed CD16. These in vitro differentiated CD56⁺ NK cells displayed cytolytic activity against the HLA class I ⁻ target K562. The CD56⁺ CD16⁺ subset also lysed NK-resistant Daudi cells. Neither of these NK subsets were shown to express Fas ligand. Total CD56⁺ cells expressed high amounts of transforming growth factor-β and granulocyte-macrophage colony-stimulating factor, but no IFN-γ. Investigation of NK receptor expression showed that most CD56⁺ cells expressed membrane CD94 and NKG2-A mRNA. PCR analysis revealed that p58 was also expressed in these cells. The role of CD94 in NK cell-mediated cytotoxicity was assessed on human HLA-B7-transfected murine L cells. While a low cytotoxic activity towards HLA-B7 cells was observed, the HLA-DR4 control cells were killed with high efficiency. These studies demonstrate that cytolytic and cytokine-producing NK cells may be derived from adult and fetal precursors by IL-15 and that these cells express a CD94 receptor which may influence their lytic potential.