Cytokine-dependent long-term culture of highly enriched precursors of hematopoietic progenitor cells from human bone marrow.

Human marrow cells positive for the CD34 antigen but not expressing HLA-DR, CD15, or CD71 antigens were isolated. In a liquid culture system supplemented with 48-hourly additions of recombinant interleukins IL-1 alpha, IL-3, IL-6, or granulocyte/macrophage colony-stimulating factor (GM-CSF), these cells were capable of sustaining in vitro hematopoiesis for up to eight weeks. The establishment of an adherent cell layer was never observed. Cultures containing no exogenous cytokine produced clonogenic cells for only 1 wk. IL-1 alpha and IL-6 were alone able to support hematopoiesis for 2 or 3 wk. Cells maintained with GM-CSF proliferated and contained assayable colony-forming cells for 3 or 4 wk, while maximal cellular expansion and generation of assayable progenitor cells occurred in the presence of IL-3 for 4-5 wk. When IL-3 was combined with IL-1 alpha or IL-6, hematopoiesis was sustained for 8 wks. Basophil numbers were markedly increased in the presence of IL-3. These studies indicate that marrow subpopulations can sustain hematopoiesis in vitro in the presence of repeated additions of cytokines. We conclude that a major function of marrow adherent cells in long-term cultures is that of providing cytokines which promote the proliferation and differentiation of primitive hematopoietic cells.

Effect of perturbation of specific folate receptors during in vitro erythropoiesis.

Although antisera to specific placental folate receptors inhibits the uptake of 5-methyltetrahydrofolate into cultured malignant human cells, little is known of the functional significance of folate receptors in normal human cells. Human bone marrow cells were therefore assayed for erythropoietic burst-forming units in the presence of an antihuman placental folate receptor serum and preimmune serum to determine the role of such a receptor in erythroid differentiation. When marrow cells were assayed in the presence of anti-receptor antiserum, there was (i) a threefold increase in erythropoietic burst formation and a twofold increase in the number of cells per erythroid burst; (ii) morphological evidence for nuclear/cytoplasmic dissociation of orthochromatic normoblasts composing erythroid bursts (megaloblastic erythropoiesis); (iii) intracellular folate deficiency with a 70% reduction of intracellular folate in antiserum treated cells as compared with control cells; and (iv) complete reversal of antiserum-induced changes on preincubation of antiserum with purified human placental folate receptor. These data support the conclusion that folate receptors on marrow cells provide an important function in the cellular uptake of folates during in vitro erythropoiesis. This process of folate uptake also appears to play a pivotal role in the differentiation and proliferation of erythroid progenitor cells.

Megaloblastic hematopoiesis in vitro. Interaction of anti-folate receptor antibodies with hematopoietic progenitor cells leads to a proliferative response independent of megaloblastic changes.

We tested the hypothesis that anti-placental folate receptor (PFR) antiserum-mediated effects on hematopoietic progenitor cells in vitro of increased cell proliferation and megaloblastic morphology were independent responses. We determined that (a) purified IgG from anti-PFR antiserum reacted with purified apo- and holo-PFR and specifically immunoprecipitated a single (44-kD) iodinated moiety on cell surfaces of low density mononuclear cells (LDMNC); (b) when retained in culture during in vitro hematopoiesis, anti-PFR IgG (in contrast to PFR-neutralized anti-PFR IgG and nonimmune IgG) consistently led to increased cloning efficiency of colony forming unit-erythroid (CFU-E), burst forming unit-E (BFU-E), CFU-granulocyte macrophage (CFU-GM), and CFU-GEM megakaryocyte (CFU-GEMM), and objectively defined megaloblastic changes in orthochromatic normoblasts from CFU-E- and BFU-E-derived colonies; (c) when anti-PFR antiserum was removed after initial (less than 1 h) incubation with LDMNC, a cell proliferation response was induced, but megaloblastic changes were not evident. (d) Conversely, delay at 4 degrees C for 24 h before long-term plating with antiserum resulted in megaloblastosis without increased cell proliferation; (e) however, 500-fold molar excess extracellular folate concentrations completely abrogated the expected anti-PFR antiserum-induced megaloblastic changes, without altering cell proliferative responses. Thus, although cell proliferative and megaloblastic changes are induced after short-term and prolonged interaction of antibody with folate receptors on hematopoietic progenitors, respectively, they are independent effects.

Stem cell factor.

Stem cell factor (SCF) is the ligand for the tyrosine kinase receptor c-kit, which is expressed on both primitive and mature hematopoietic progenitor cells. In vitro, SCF synergizes with other growth factors, such as granulocyte colony-stimulating factor (G-CSF), granulocyte macrophage-colony-stimulating factor, and interleukin-3 to stimulate the proliferation and differentiation of cells of the lymphoid, myeloid, erythroid, and megakaryocytic lineages. In vivo, SCF also synergizes with other growth factors and has been shown to enhance the mobilization of peripheral blood progenitor cells in combination with G-CSF. In phase I/II clinical studies administration of the combination of SCF and G-CSF resulted in a two- to threefold increase in cells that express the CD34 antigen compared with G-CSF alone. Other potential clinical uses include ex vivo expansion protocols and in vitro culture for gene therapy.

Effects of thrombocytopoiesis-stimulating factor on terminal cytoplasmic maturation of human megakaryocytes.

Aplastic anemia serum (AAS) contains humoral factors that alter both proliferation and maturation of human megakaryocytes (MK). The ability of AAS to augment MK colony formation (colony-forming unit, CFU-MK) was neutralized by an antiserum against MK colony-stimulating factor (MK-CSF), a glycoprotein isolated from AAS. The adsorbed AAS still retained the ability to accelerate cytoplasmic maturation of recognizable MK. Similar experiments were done with thrombocytopoiesis-stimulating factor (TSF) and an anti-TSF antiserum to further define the activity in AAS responsible for accelerating cytoplasmic maturation. Bone marrow fractions enriched for recognizable human MK, but devoid of CFU-MK, were obtained by centrifugal elutriation and placed in short-term liquid cultures. MK progressed through identifiable maturation stages (1-4) more quickly in the presence of either TSF or AAS. TSF slightly enhanced the cloning efficiencies of CFU-MK, but did not alter the number of MK in individual colonies derived from non-adherent, low-density, T-cell-depleted bone marrow. In contrast, granulocyte-macrophage colony-stimulating factor (GM-CSF), interleukin 3 (IL-3), and crude AAS substantially augmented both MK colony formation and cells per colony. TSF also doubled the percent 35S incorporation into platelets of immunothrombocythemic mice, but stimulation was completely abolished by anti-TSF. Anti-TSF antiserum was then used to analyze the promotion of MK colony formation by cytokines. Cloning efficiencies of CFU-MK were reduced to baseline values when TSF was pretreated with anti-TSF; however, the MK colony-stimulating activity (MK-CSA) of GM-CSF, IL-3, or AAS was not altered by adsorption with anti-TSF. In contrast, the cytoplasmic maturation of recognizable MK was slower, and fewer mature stage-4 cells were present at days 1-3 in AAS adsorbed with anti-TSF than MK cultured in AAS treated with normal rabbit serum or untreated AAS. Therefore, TSF appears to be a major factor in AAS that accelerates terminal maturation of human MK. TSF primarily affects megakaryocytopoiesis by promoting MK maturation rather than enhancing CFU-MK proliferation.

Recombinant GM-CSF/IL-3 fusion protein: its effect on in vitro human megakaryocytopoiesis.

An evaluation of the effectiveness of a genetically engineered recombinant granulocyte-macrophage colony-stimulating factor (GM-CSF)/interleukin 3 (IL-3) fusion protein (FP) as a means of delivering cytokine combinations to megakaryocyte (MK) progenitor cells was performed, utilizing a serum-depleted clonal assay system and a long-term bone marrow culture system. The effects of the FP, alone and in combination with a variety of other cytokines, on the primitive MK progenitor cell, the megakaryocyte burst-forming unit (BFU-MK), and the more differentiated megakaryocyte colony-forming unit (CFU-MK) were assessed. Subpopulations of bone marrow cells (CD34+ DR- for BFU-MK and CD34+ DR+ for CFU-MK) served as sources of these two classes of MK progenitor cells. The FP was equivalent to a combination of optimal concentrations of GM-CSF and IL-3 in promoting both the number and size of BFU-MK-derived colonies. The GM-CSF/IL-3 combination, however, promoted the formation of far greater CFU-MK-derived colonies than did the FP alone. The size of MK colonies formed in the presence of the FP or GM-CSF/IL-3 was similar. The ability of the FP to stimulate BFU-MK- but not CFU-MK-derived colony formation was also further augmented by the addition of interleukin 1 alpha (IL-1 alpha). The addition of c-kit ligand (KL) increased both FP-stimulated CFU-MK- and BFU-MK-derived colony numbers but only BFU-MK-derived colony size. In addition, the FP alone sustained long-term megakaryocytopoiesis in vitro to a level equivalent to that of the GM-CSF/IL-3 combination and was superior in this regard to either GM-CSF or IL-3 alone. These data indicate that FP is capable of supporting various stages of human megakaryocytopoiesis. We conclude that such genetically engineered molecules as the FP may prove to be effective means of pharmacologically delivering the biological effects of specific cytokine combinations.

The role of stem cell factor in mobilization of peripheral blood progenitor cells.

Stem cell factor (SCF) is a hematopoietic growth factor which acts on both primitive and mature progenitors cells. In animals, high doses of SCF alone stimulate increases in cells of multiple lineages and mobilize peripheral blood progenitor cells (PBPC). Phase I studies of rhSCF have demonstrated dose related side effects which are consistent with mast cell activation. Based upon in vitro synergy between SCF and G-CSF we have demonstrated the potential of low doses of SCF to synergize with G-CSF to give enhanced mobilization of PBPC. These PBPC have increased potential for both short and long term engraftment in lethally irradiated mice and lead to more rapid recovery of platelets. On going Phase I/II studies with rhSCF plus rhG-CSF for mobilization of PBPC, demonstrated similar increases in PBPC compared to rhG-CSF alone. These data suggest a clinical role of rhSCF in combination with rhG-CSF for optimal mobilization of PBPC.

Cytokine regulation of the human burst-forming unit-megakaryocyte.

The human burst-forming unit-megakaryocyte (BFU-MK) is a primitive megakaryocytic progenitor cell. A marrow cell population enriched for BFU-MK (CD34+ DR-) was obtained by monoclonal antibody labeling and fluorescence-activated cell sorting. CD34+DR- cells were assayed in a serum-depleted, fibrin clot culture system. Recombinant granulocyte-macrophage colony-stimulating factor (rGM-CSF), recombinant interleukin-3 (rIL-3), and megakaryocyte colony-stimulating factor (MK-CSF), partially purified from human plasma, were each individually capable of promoting BFU-MK-derived colony formation. Recombinant erythropoietin, rG-CSF, rIL-4, rIL-6, and thrombocytopiesis stimulating factor, partially purified from human embryonic kidney cell conditioned media, had no stimulatory effect on BFU-MK-derived colony formation when added alone or in various combinations with either GM-CSF, IL-3, or MK-CSF, GM-CSF and IL-3, GM-CSF and MK-CSF, but not IL-3 and MK-CSF had additive actions in promoting BFU-MK-derived colony formation, rIL-1 alpha had no influence alone on BFU-MK cloning efficiency, but had a dose-dependent, synergistic effect with IL-3, but not with GM-CSF or MK-CSF. The synergistic relationship between IL-1 alpha and IL-3 was abrogated by addition of an IL-1 alpha neutralizing antibody but not by a GM-CSF neutralizing antiserum, suggesting that IL-1 alpha acts directly on the BFU-MK and not by stimulating marrow auxiliary cells to secondarily release additional cytokines. Information presented here indicates that the regulatory influence, acting on the different stages of megakaryocyte development, are stage-specific and accomplished by multiple cytokines.

Characterization of the human burst-forming unit-megakaryocyte.

Two classes of human marrow megakaryocyte progenitor cells are described. Colony-forming unit-megakaryocyte (CFU-MK)-derived colonies appeared in vitro after 12-day incubation; burst-forming unit-megakaryocyte (BFU-MK)-derived colonies appeared after 21 days. CFU-MK-derived colonies were primarily unifocal and composed of 11.6 +/- 1.2 cells/colony; BFU-MK-derived colonies were composed of 2.3 +/- 0.4 foci and 108.6 +/- 4.4 cells/colony. CFU-MK and BFU-MK were separable by counterflow centrifugal elutriation. CFU-MK colony formation was diminished by exposure to 5-fluorouracil (5-FU); BFU-MK colony formation was unaffected. CFU-MK and BFU-MK were immunologically phenotyped. CFU-MK expressed the human progenitor cell antigen-1 (HPCA-1, CD34, clone My10) and a major histocompatibility class II locus, HLA-DR, and BFU-MK expressed only detectable amounts of CD34. BFU-MK colony formation was entirely dependent on addition of exogenous hematopoietic growth factors. Recombinant granulocyte macrophage colony-stimulating factor (GM-CSF) and interleukin-3 (IL-3) possessed such colony-stimulating activity, whereas recombinant erythropoietin (Epo), G-CSF, IL-1 alpha, IL-4, and purified thrombocytopoiesis-stimulating factor did not. These studies indicate the existence of a human megakaryocyte progenitor cell, the BFU-MK, which has unique properties allowing it to be distinguished from the CFU-MK.

Serum from patients with various thrombopoietic disorders alters terminal cytoplasmic maturation of human megakaryocytes in vitro.

Human bone marrow was depleted of progenitors (CFU-MK), but enriched for recognizable megakaryocytes (MK), and placed in cultures with serum from either normal donors (NABS) or patients with primary (PTS) or secondary (STS) thrombocytosis, autoimmune thrombocytopenia (ATS) or aplastic anemia (AAS). Mean MK diameters shifted during the 3-4 days of incubation. Endomitotic figure were visible and mean ploidy increased slightly during cytoplasmic maturation, where decreases in immature cells (stages 1 and 2) were accompanied by increases in the mature MK (stages 3 and 4). Cytoplasmic maturation was faster in AAS, ATS and STS than PTS or NABS; mean size and ploidy were similar in all cultures. Recognizable MK were not forced to undergo additional endoreduplication in response to stimulation. Only AAS augmented MK colony formation, which indicated that at least two humoral factors can regulate megakaryocytopoiesis at separate levels, the progenitors and morphologically recognizable MK.

The role of stem cell factor in mobilization of peripheral blood progenitor cells: synergy with G-CSF.

The use of cytokine mobilized peripheral blood progenitor cells (PBPC) in transplantation following chemotherapy has led to enhanced engraftment. Granulocyte-colony stimulating factor (G-CSF) has been shown in a number of clinical studies to be an effective mobilizer of PBPC. Preclinical data in mice and primates have demonstrated a potential role for the use of stem cell factor (SCF) in mobilization of PBPC. In the studies presented here, low doses of SCF are shown to synergize with optimal doses of G-CSF to enhance the number and quality of PBPC compared to G-CSF alone. Phase I studies using r-metHuSCF demonstrated mast cell-related dose limiting effects. The data presented here have led to Phase I/II studies to evaluate the potential use of low doses of SCF in combination with G-CSF for mobilization of PBPC.

Recombinant rat stem cell factor synergizes with recombinant human granulocyte colony-stimulating factor in vivo in mice to mobilize peripheral blood progenitor cells that have enhanced repopulating potential.

Splenectomized mice treated for 7 days with pegylated recombinant rat stem cell factor (rrSCF-PEG) showed a dose-dependent increase in peripheral blood progenitor cells (PBPC) that have enhanced in vivo repopulating potential. A dose of rrSCF-PEG at 25 micrograms/kg/d for 7 days produced no significant increase in PBPC. However, when this dose of rrSCF-PEG was combined with an optimal dose of recombinant human granulocyte colony-stimulating factor (rhG-CSF; 200 micrograms/kg/d), a synergistic increase in PBPC was observed. Compared with treatment with rhG-CSF alone, the combination of rrSCF-PEG plus rhG-CSF resulted in a synergistic increase in peripheral white blood cells, in the incidence and absolute numbers of PBPC, and in the incidence and absolute numbers of circulating cells with in vivo repopulating potential. These data suggest that low doses of SCF, which would have minimal, if any, effects in vivo, can synergize with optimal doses of rhG-CSF to enhance the mobilization of PBPC stimulated by rhG-CSF alone.

CD34+ cell selection from frozen cord blood products using the Isolex 300i and CliniMACS CD34 selection devices.

Ex vivo expansion of cord blood (CB) cells requires CD34+ cell selection before expansion to obtain optimal numbers of progenitor cells. As a preliminary step to preclinical development of CB expansion, we have evaluated two clinical scale selection devices, the Isolex 300i (Baxter Healthcare, Immunotherapy Division) and the CliniMACS (Miltenyi Biotech Inc.), for CD34+ cell selection from frozen CB products. As expansion of CB results in differentiation of cells, there may be a depletion of stem cells. Therefore, only a fraction of the CB should be expanded while a portion of the CB is maintained unmanipulated for infusion. After thawing of 40% fractions of each CB product, we observed >95% viable cells, with a median total WBC count of 1.8 x 10(8) cells. Use of the Isolex 300i resulted in a median purity of 51% CD34+ cells (n=8) and a median recovery of 34% CD34+ cells. Use of the CliniMACS resulted in a median purity of 54% CD34+ cells (n=10) and a median recovery of 80% CD34+ cells. The absolute number of CD34+ cells recovered after selection varied with samples from 6.7 x 10(4) to 3.2 x 10(6) CD34+ cells. Expansion of CD34+ cells from both systems resulted in >20-fold expansion of CFU-GM, with a median of 44-fold expansion. These data demonstrate the feasibility of selecting small fractions of frozen CB products using clinical scale CD34+ cell selection devices.

Effect of c-kit ligand on in vitro human megakaryocytopoiesis.

An evaluation of the effects of a recombinant, soluble form of the c-kit ligand alone and in combination with either granulocyte-macrophage colony-stimulating factor (GM-CSF) or interleukin-3 (IL-3) on the regulation of human megakaryocytopoiesis was performed using a serum-depleted clonal assay system and a long-term bone marrow culture system. The effects of the c-kit ligand on the primitive megakaryocyte (MK) progenitor cell, the burst-forming unit-megakaryocyte (BFU-MK), and the more differentiated colony-forming unit-megakaryocyte (CFU-MK) were determined. The c-kit ligand alone had no megakaryocyte colony-stimulating activity (MK-CSA) but was capable of augmenting the MK-CSA of both GM-CSF and IL-3. The range of synergistic interactions of c-kit ligand varied with the class of MK progenitor cell assayed. In the case of the BFU-MK, the c-kit ligand synergistically augmented the numbers of colonies formed in the presence of IL-3, but not GM-CSF, but increased the size of BFU-MK-derived colonies cloned in the presence of both of these cytokines. However, at the level of the CFU-MK, c-kit ligand synergized with both GM-CSF and IL-3 by increasing both colony numbers and size. Although the c-kit ligand alone exhibited limited potential in sustaining long-term megakaryocytopoiesis in vitro, it synergistically augmented the ability of IL-3, but not GM-CSF, to promote long-term megakaryocytopoiesis. These data indicate that multiple cytokines are necessary to optimally stimulate the proliferation of both classes of MK progenitor cells and that the c-kit ligand plays a significant role in this process by amplifying the MK-CSA of both GM-CSF and IL-3.

Further examination of the effects of recombinant cytokines on the proliferation of human megakaryocyte progenitor cells.

The effect of several recombinant cytokines, including interleukin-3 (IL-3), granulocyte-macrophage colony-stimulating factor (GM-CSF), IL-6, and IL-1 alpha, on megakaryocyte (MK) colony formation by a normal human bone marrow subpopulation (CD34+ DR+), enriched for the MK colony-forming unit (CFU-MK), was studied using a serum-depleted, fibrin clot culture system. IL-3 and GM-CSF, but not IL-6 or IL-1 alpha, stimulated MK colony formation by CD34+ DR+ cells. However, the addition of IL-1 alpha to CD34+ DR+ cultures containing IL-6 resulted in the appearance of CFU-MK-derived colonies, suggesting that IL-6 requires the presence of IL-1 alpha to exhibit its MK colony-stimulating activity (MK-CSA). Addition of neutralizing antibodies to IL-3 and GM-CSF, but not to IL-6 and IL-1 alpha, specifically inhibited the MK-CSA of IL-3 and GM-CSF, respectively. The addition of either anti-IL-6, anti-IL-1 alpha, or anti-IL-3 antisera to cultures containing both IL-6 and IL-1 alpha totally abolished the MK-CSA of the IL-6/IL-1 alpha combination. However, neither anti-IL-3 nor anti-GM-CSF antisera could totally neutralize the additive effect of the combination of IL-3 and GM-CSF on MK colony formation, indicating that these two cytokines act by affecting distinct effector pathways. These results suggest that while IL-3 and GM-CSF can directly affect CFU-MK-derived colony formation, IL-1 alpha and IL-6 act in concert to promote de novo elaboration of IL-3 and thereby promote CFU-MK proliferative capacity.

Engraftment of primates with G-CSF mobilized peripheral blood CD34+ progenitor cells expanded in G-CSF, SCF and MGDF decreases the duration and severity of neutropenia.

We used a primate model of autologous peripheral blood progenitor cell (PBPC) transplantation to study the effect of in vitro expansion on committed progenitor cell engraftment and marrow recovery after transplantation. Four groups of baboons were transplanted with enriched autologous CD34+ PBPC collected by apheresis after five days of G-CSF administration (100 microg/kg/day). Groups I and III were transplanted with cryopreserved CD34+ PBPC and Groups II and IV were transplanted with CD34+ PBPC that had been cultured for 10 days in Amgen-defined (serum free) medium and stimulated with G-CSF, megakaryocyte growth and development factor (MGDF), and stem cell factor each at 100 etag/ml. Group III and IV animals were administered G-CSF (100 microg/kg/day) and MGDF (25 microg/kg/day) after transplant, while animals in Groups I and II were not. For the cultured CD34+ PBPC from groups II and IV, the total cell numbers expanded 14.4 +/- 8.3 and 4.0 +/- 0.7-fold, respectively, and CFU-GM expanded 7.2 +/- 0.3 and 8.0 +/- 0.4-fold, respectively. All animals engrafted. If no growth factor support was given after transplant (Groups II and I), the recovery of WBC and platelet production after transplant was prolonged if cells had been cultured prior to transplant (Group II). Administration of post-transplant G-CSF and MGDF shortened the period of neutropenia (ANC < 500/microL) from 13 +/- 4 (Group I) to 10 +/- 4 (Group III) days for animals transplanted with non-expanded CD34+ PBPC. For animals transplanted with ex vivo-expanded CD34+ PBPC, post-transplant administration of G-CSF and MGDF shortened the duration of neutropenia from 14 +/- 2 (Group II) to 3 +/- 4 (Group IV) days. Recovery of platelet production was slower in all animals transplanted with expanded CD34+ PBPC regardless of post-transplant growth factor administration. Progenitor cells generated in vitro can contribute to early engraftment and mitigate neutropenia when growth factor support is administered post-transplant. Thrombocytopenia was not decreased despite evidence of expansion of megakaryocytes in cultured CD34+ populations.

Stimulation of hematopoiesis in vivo by stem cell factor.

The ligand for c-kit, known as stem cell factor, mast cell growth factor, or kit ligand, plays a central role in normal hematopoietic stem cell, melanocyte, and gametocyte development and function during embryogenesis and in adult life. In vitro, stem cell factor promotes the survival of hematopoietic progenitors and enhances their proliferation in response to specific growth factors. Administration of recombinant soluble stem cell factor to rodents, dogs, and baboons produces a broad array of effects on hematopoiesis, though not all lineages are equally stimulated. At doses of more than 100 micrograms/kg/d stem cell factor stimulates neutrophilia, lymphocytosis, basophilia, and reticulocytosis and increases mast cells in multiple tissues. In vivo mast cell activation can occur. Marrow cellularity is increased and progenitor cells are increased in marrow, spleen, and blood, and marrow-repopulating cells are increased in the circulation of stem cell factor-treated animals. Stem cell factor synergizes with other hematopoietic growth factors in vivo. Low-dose stem cell factor, 25 micrograms/kg/d, that does not elicit a detectable biological response, enhances the effects of granulocyte colony-stimulating factor in vivo, increasing the neutrophilia and circulation of progenitor and marrow-repopulating cells above that which is achieved with either factor alone. In phase I human trials, dose-limiting toxicities, related to mast cell activation, were reached at 25 to 50 micrograms/kg/d of recombinant human stem cell factor. At these doses, progenitor and long-term culture-initiating cells are increased in marrow and increases in circulating levels of progenitor cells of multiple types are observed. Phase I-II trials of low-dose stem cell factor in combination with granulocyte colony-stimulating factor show that the combination increases the circulation of CD34+ cells and colony-forming progenitor cells. Further studies are needed to determine the therapeutic role of stem cell factor and its effects on expansion and maintenance of hematopoietic stem cells in vivo.

Role of cytokines in sustaining long-term human megakaryocytopoiesis in vitro.

An in vitro liquid suspension culture system was used to determine the role of cytokines in sustaining long-term human megakaryocytopoiesis. Bone marrow cells expressing CD34 but not HLA-DR (CD34+DR-) were used as the inoculum of cells to initiate long-term bone marrow cultures (LTBMC). CD34+DR- cells (5 x 10(3)/mL) initially contained 0.0 +/- 0.0 assayable colony-forming unit-megakaryocytes (CFU-MK), 6.2 +/- 0.4 assayable burst-forming unit-megakaryocytes (BFU-MK), and 0.0 +/- 0.0 megakaryocytes (MK). LTBMCs were recharged every 48 hours with granulocyte-macrophage colony-stimulating factor (GM-CSF), interleukin-1 alpha (IL-1 alpha), IL-3, and/or IL-6, alone or in combination. LTBMCs were demidepopulated weekly or biweekly, the number of cells and MK enumerated, and then assayed for CFU-MK and BFU-MK. LTBMCs receiving no cytokine(s) contained no assayable CFU-MK or BFU-MK and no observable MK. LTBMCs receiving GM-CSF, IL-1 alpha, and/or IL-3 contained assayable CFU-MK and MK but no BFU-MK for 10 weeks of culture. The effects of GM-CSF and IL-3, IL-1 alpha and IL-3, but not GM-CSF and IL-1 alpha were additive with regards to their ability to augment the numbers of assayable CFU-MK during LTBMC. LTBMCs supplemented with IL-6 contained modest numbers of assayable CFU-MK for only 4 weeks; this effect was not additive to that of GM-CSF, IL-1 alpha, or IL-3. The addition of GM-CSF, IL-1 alpha, and IL-3 alone or in combination each led to the appearance of significant numbers of MKs during LTBMC. By contrast, IL-6 supplemented cultures contained relatively few MK. These studies suggest that CD34+DR- cells are capable of initiating long-term megakaryocytopoiesis in vitro and that a hierarchy of cytokines exists capable of sustaining this process.

Role of c-kit ligand in the expansion of human hematopoietic progenitor cells.

To test the hypothesis that the c-kit ligand plays an important role in the regulation of early events occurring during human hematopoiesis, we determined the effect of a recombinant form of c-kit ligand, termed mast cell growth factor (MGF), on the high-proliferative potential colony-forming cell (HPP-CFC) and the cell responsible for initiating long-term hematopoiesis in vitro (LTBMIC). MGF alone did not promote HPP-CFC colony formation by CD34+ DR- CD15- marrow cells, but synergistically augmented the ability of a combination of granulocyte-monocyte colony-stimulating factor (GM-CSF) interleukin (IL)-3 and a recombinant GM-CSF/IL-3 fusion protein (FP) to promote the formation of HPP-CFC-derived colonies. MGF had a similarly profound effect on in vitro long-term hematopoiesis. Repeated additions of IL-3, GM-CSF, or FP alone to CD34+ DR- CD15- marrow cells in a stromal cell-free culture system increased cell numbers 10(3)-fold by day 56 of long-term bone marrow culture (LTBMC), while combinations of MGF with IL-3 or FP yielded 10(4)- and 10(5)-fold expansion of cell numbers. Expansion of the number of assayable colony-forming unit-granulocyte-monocyte (CFU-GM) generated during LTBMC was also markedly enhanced when MGF was added in combination with IL-3 or FP. In addition, MGF, IL-3, and FP individually led to a twofold to threefold increase in HPP-CFC numbers after 14 to 21 days of LTBMC. Furthermore, the effects of these cytokines on HPP-CFC expansion during LTBMC were additive. Throughout the LTBMC, cells receiving MGF possessed a higher cloning efficiency than those receiving IL-3, GM-CSF, or FP alone. These data indicate that the c-kit ligand synergistically interacts with a number of cytokines to directly augment the proliferative capacity of primitive human hematopoietic progenitor cells.