Megakaryocyte Colony-forming Units Research Articles

Different Radiosensitive Megakaryocytic Progenitor Cells Exist in Steady-State Human Peripheral Blood

CD34 antigen is a novel marker for human hematopoietic stem/progenitor cells. In the present study, two cell fractions, CD34low and CD34high, were prepared from steady-state human peripheral blood on the basis of CD34 antigen expression. The colony-forming unit megakaryocytes (CFU-Meg) contained in each cell fraction were compared for X-radiation sensitivity and cytokine action. The content of CD34+CD45+ cells in the CD34low and CD34high cell fractions was 74.8% and 88.8%, respectively, and the frequency of thrombopoietin (TPO)-supported CFU-Meg in the CD34low cell fraction was 1.9 times higher than that in CD34high. The CFU-Meg in CD34high were more radiosensitive than those in CD34low, indicating that steady-state human peripheral blood contains different types of CFU-Meg. However, no significant differences were observed between cell fractions in the radiation survival curves of CFU-Meg stimulated by TPO plus cytokines except granulocyte colony-stimulating factor (G-CSF). TPO plus interleukin 3 was the optimal combination for survival of both types of CFU-Meg after X irradiation. The present study also demonstrated that TPO plus G-CSF is able to increase the survival of irradiated CD34low CFU-Meg. These results suggest that two megakaryocytic progenitor populations with different radiosensitivity and cytokine responses are found in steady-state human peripheral blood.

A Phase I Clinical, Pharmacologic, and Biologic Study of Thrombopoietin and Granulocyte Colony-Stimulating Factor in Children Receiving Ifosfamide, Carboplatin, and Etoposide Chemotherapy for Recurrent or Refractory Solid Tumors: A Children's Oncology Group Experience

Ifosfamide, carboplatin, and etoposide (ICE) are associated with grade III/IV dose-limiting thrombocytopenia. The Children's Oncology Group conducted a phase I dose escalation, pharmacokinetic, and biological study of recombinant human thrombopoietin (rhTPO) after ICE in children with recurrent/refractory solid tumors (CCG-09717) to assess the toxicity and maximum tolerated dose of rhTPO administered at 1.2, 2.4, or 3.6 microg/kg per dose. Children received ifosfamide 1,800 mg/m2 on days 0 to 4, carboplatin 400 mg/m2 on days 0 to 1, and etoposide 100 mg/m2 on days 0 to 4. rhTPO was administered i.v. on days +4, +6, +8, +10, and +12 at 1.2, 2.4, or 3.6 microg/kg per dose. rhTPO was well tolerated and maximum tolerated dose was not reached. Median time to platelet recovery > or =100,000/microL of rhTPO at 1.2, 2.4, and 3.6 microg/kg/d was 24 days (22-24 d), 25 days (23-29 d), and 22 days (16-37 d), respectively. Patients required a median of 2 days of platelet transfusions (0-7 days). Mean (+/- SD) rhTPO maximum serum concentrations were 63.3 +/- 9.7 and 89.3 +/- 15.7 ng/mL and terminal half-lives were 47 +/- 13 and 64 +/- 42 hours after 2.4 and 3.6 microg/kg/d, respectively. There was a significant increase in colony-forming unit megakaryocyte upon WBC count recovery. rhTPO was well tolerated. Time to hematologic recovery and median number of platelet transfusions seem to be improved compared with historical controls receiving ICE + granulocyte colony-stimulating factor (CCG-0894).

HIV-1-derived self-inactivating lentivirus vector induces megakaryocyte lineage-specific gene expression

Pluripotent, self-renewing, hematopoietic stem cells are considered good targets for gene modification to treat a wide variety of disorders. However, as many genes are expressed in a stage-specific manner during the course of hematopoietic development, it is necessary to establish a lineage-specific gene expression system to ensure the proper expression of transduced genes in hematopoietic stem cells. In this study, we constructed a VSV-G-pseudotyped, human immunodeficiency virus type 1-based, self-inactivating lentivirus vector that expressed green fluorescent protein (GFP) under the control of the human CD41 (glycoprotein 2b; GP2b) promoter; this activity is restricted to megakaryocytic lineage cells. The recombinant virus was used to infect human peripheral blood CD34 + (hematopoietic stem/progenitor) cells, and lineage-specific gene expression was monitored with GFP measurements. The analysis by FACS determined that GFP expression driven by the GP2b promoter was restricted to megakaryocytic progenitors and was not present in erythrocytes. Furthermore, in the hematopoietic colony-forming assay, GFP expression was restricted to colony-forming units-megakaryocyte (CFU-Meg) colonies under the control of the GP2b promoter, whereas all myeloid colonies (burst-forming units-erythroid, colony-forming units-granulocyte-macrophage, and CFU-Meg) expressed GFP when the transgene was regulated by the cytomegalovirus promoter. These results demonstrated lineage-specific expression after gene transduction of hematopoietic stem cells. The application of this vector system should provide a useful tool for gene therapy to treat disorders associated with megakaryocyte (platelet) dysfunction.

Inhibition of angiotensin I–converting enzyme induces radioprotection by preserving murine hematopoietic short-term reconstituting cells

AbstractAngiotensin I–converting enzyme (ACE) inhibitors can affect hematopoiesis by several mechanisms including inhibition of angiotensin II formation and increasing plasma concentrations of AcSDKP (acetyl-N-Ser-Asp-Lys-Pro), an ACE substrate and a negative regulator of hematopoiesis. We tested whether ACE inhibition could decrease the hematopoietic toxicity of lethal or sublethal irradiation protocols. In all cases, short treatment with the ACE inhibitor perindopril protected against irradiation-induced death. ACE inhibition accelerated hematopoietic recovery and led to a significant increase in platelet and red cell counts. Pretreatment with perindopril increased bone marrow cellularity and the number of hematopoietic progenitors (granulocyte macrophage colony-forming unit [CFU-GM], erythroid burst-forming unit [BFU-E], and megakaryocyte colony-forming unit [CFU-MK]) from day 7 to 28 after irradiation. Perindopril also increased the number of hematopoietic stem cells with at least a short-term reconstitutive activity in animals that recovered from irradiation. To determine the mechanism of action involved, we evaluated the effects of increasing AcSDKP plasma concentrations and of an angiotensin II type 1 (AT1) receptor antagonist (telmisartan) on radioprotection. We found that the AT1-receptor antagonism mediated similar radioprotection as the ACE inhibitor. These results suggest that ACE inhibitors and AT1-receptor antagonists could be used to decrease the hematopoietic toxicity of irradiation.

Induction of megakaryocytopoiesis and thrombocytopoiesis by JTZ-132, a novel small molecule with thrombopoietin mimetic activities

AbstractWe report in this paper that a novel small molecule, JTZ-132, induced growth and differentiation of megakaryocytic progenitor cells and improved thrombocytopenia in myelosuppressed mice. JTZ-132 stimulated proliferation of UT-7/TPO cells, a cell line highly sensitive to thrombopoietin (TPO), and exhibited full efficacy comparable to TPO with an approximate EC50 (median effective concentration) value of 0.43 μM, whereas little proliferation was observed in a TPO-insensitive cell line, UT-7/EPO, and human carcinoma cell line, HCT116. Signal transduction studies revealed that JTZ-132 induced tyrosine phosphorylation of c-Mpl, Janus kinase-2 (JAK2), and signal transducers and activators of transcription 5 (STAT5) in UT-7/TPO cells as well as TPO. JTZ-132 increased the number of megakaryocyte-specific marker, CD61+ and CD41+, cells in cultures of mouse and human bone marrow cells, respectively, and the colonyforming unit megakaryocytes in mouse bone marrow cells. In vivo experiments in x-ray irradiation– or busulfan injection–induced myelosuppressed mice demonstrated that subcutaneously injected JTZ-132 at 30 mg/kg showed significantly higher platelet number at nadir and accelerated platelet recovery without affecting white blood cell number. These data suggest that JTZ-132 is a novel stimulator of megakaryocytopoiesis and thrombocytopoiesis in vitro and in vivo with TPO mimetic activities and that it is useful for the treatment of thrombocytopenia.

Bone and bone marrow interactions: hematological activity of osteoblastic growth peptide (OGP)-derived carboxy-terminal pentapeptide: III. Action on human megakaryocytopoiesis: focus on essential thrombocythemia

The increase of megakaryocytes and platelets that characterizes essential thrombocythemia (ET) appears to be secondary to a deregulation of megakaryocytopoiesis. The carboxy-terminal fragment of osteogenic growth peptide (OGP10–14) promotes bone formation and hemopoiesis, while it inhibits megakaryocytopoiesis. In this paper we show that treatment with synthetic OGP10–14 (sOGP10–14) induces a significant reduction of mid and large colony-forming unit-megakaryocytes (CFU-Mk) in ET patients as well as in controls, and is associated with a significant inhibition of thrombopoietin (TPO)-primed MO-7e megakaryoblastic cells proliferation. These actions appear to be related to sOGP10–14 modulation of TGF-β 1 synthesis and/or secretion, although a direct effect on TGF-β receptor expression cannot be excluded.

The effect of human cytomegalovirus on the formation of CFU-MK in vitro.

To investigate the mechanism and the suppressive effect of human cytomegalovirus (HCMV) on colony forming unit-megakaryocyte (CFU-MK), semi-solid culture system was used to observe the effect of HCMV AD169 strain on CFU-MK's growth of 18 cord blood samples. HCMV DNA and immediate early (IE) protein mRNA in CFU-MK was detected by PCR and reverse transcription-polymerase chain reaction (RT-PCR). Our results showed that HCMV AD169 significantly suppressed the formation of CFU-MK in vitro. Compared with the mock group, the CFU-MK colonies decreased by 21.6%, 33.8% and 46.3%, respectively, in all the 3 infected groups (P<0.05), suggesting the suppression and the titer of the virus was dose-dependent. Both HCMV DNA and the expression of HCMV IE protein mRNA were positively detected in the colony cells of viral infected group. It is concluded that HCMV AD169 strain could inhibit the differentiation and proliferation of CFU-MK by directly infecting their progenitors. There was early transcription of HCMV IE protein in CFU-MK infected by virus.

Ultrastructural study shows morphologic features of apoptosis and para-apoptosis in megakaryocytes from patients with idiopathic thrombocytopenic purpura

AbstractTo investigate whether altered megakaryocyte morphology contributes to reduced platelet production in idiopathic thrombocytopenic purpura (ITP), ultrastructural analysis of megakaryocytes was performed in 11 ITP patients. Ultrastructural abnormalities compatible with (para-)apoptosis were present in 78% ± 14% of ITP megakaryocytes, which could be reversed by in vivo treatment with prednisone and intravenous immunoglobulin. Immunohistochemistry of bone marrow biopsies of ITP patients with extensive apoptosis showed an increased number of megakaryocytes with activated caspase-3 compared with normal (28% ± 4% versus 0%). No difference, however, was observed in the number of bone marrow megakaryocyte colony-forming units (ITP, 118 ± 93/105 bone marrow cells; versus controls, 128 ± 101/105 bone marrow cells; P = .7). To demonstrate that circulating antibodies might affect megakaryocytes, suspension cultures of CD34+ cells were performed with ITP or normal plasma. Morphology compatible with (para-)apoptosis could be induced in cultured megakaryocytes with ITP plasma (2 of 10 samples positive for antiplatelet autoantibodies). Finally, the plasma glycocalicin index, a parameter of platelet and megakaryocyte destruction, was increased in ITP (57 ± 70 versus 0.7 ± 0.2; P = .009) and correlated with the proportion of megakaryocytes showing (para-) apoptotic ultrastructure (P = .02; r = 0.7). In conclusion, most ITP megakaryocytes show ultrastructural features of (para-) apoptosis, probably due to action of factors present in ITP plasma.

Acquired amegakaryocytic thrombocytopenia: Three case reports and a literature review

Acquired amegakaryocytic thrombocytopenia (AAT) is a rare disease characterized by thrombocytopenia due to selective reduction/absence of bone marrow (BM) megakaryocytes. In the BM culture isolated reduction of colony-forming units-megakaryocyte (CFU-Mk) may occur. BM aspirates and trephine biopsies were obtained from all patients and processed by routine methods. In vitro BM culture and cytogenetic analysis was performed in one patient. This article presents three patients with manifested signs of hemorrhagic syndrome due to severe thrombocytopenia caused by an absence/significant reduction of BM megakaryocytes. Existence of systemic or any other disease was excluded in all patients. BM culture of the second patient showed reduction of all hematopoietic progenitors. In the subsequent course of the disease in this patient, signs of dysplastic erythrocytic series and megakaryocytes were also noted, although there were no positive proofs of evolution into myelodysplastic syndrome. AAT is a disease of hematopoietic stem cells manifesting in a certain period as amegakaryocytic thrombocytopenia which subsequently may progress into aplastic anemia or myelodysplastic syndrome. Patients were treated with corticosteroids, lithium carbonate, androgens, vincristine, immunoglobulins, folic acid, platelet and erythrocyte transfusions along with plasma substitution. The first patient reacted positively to the therapy. In two other patients a minimal, short-term therapeutic effect was achieved, followed by improvement of hemorrhagic syndrome and an insignificant increase in platelet count. In one patient the treatment was stopped after 4 months and the other died of bleeding after 4 months. AAT is a rare disease with unpredictable course. This is a case report of three patients with AAT and different therapeutic effects.

Decrease of Smad4 gene expression in patients with essential thrombocythaemia may cause an escape from suppression of megakaryopoiesis by transforming growth factor-beta1.

Essential thrombocythaemia (ET) is characterized by the abnormal and sustained proliferation of megakaryocytes. The mechanism for this lineage-specific expansion in ET, remains unclear. We have previously reported that transforming growth factor-beta1 (TGF-beta1) is involved in negative feedback regulation of megakaryopoiesis in both healthy volunteers (HV) and patients with idiopathic thrombocytopenic purpura (ITP). The present study found that megakaryocyte colony-forming units (CFU-MK) of ET patients were less sensitive to TGF-beta1 than those of HV. The expression of Smad4 (Sma- and Mad-related protein-4) in CFU-MK of ET patients was reduced in comparison with that of HV. Finally, to confirm that the impaired TGF-beta1 sensitivity was caused by reduced expression of Smad4, we examined Smad4-transfected CFU-MK from ET patients in the presence of TGF-beta1, and verified that the transfectants were indeed as susceptible as CFU-MK from HV to TGF-beta1. Thus it was surmised that one of the mechanisms for impaired sensitivity of CFU-MK to TGF-beta1 is the reduced expression of Smad4.

CD34 +CDw90(Thy-1) + subset colocated with mesenchymal progenitors in human normal bone marrow hematon units is enriched in colony-forming unit megakaryocytes and long-term culture-initiating cells

Objective The progress made in the supportive care of allografts and the identification of mesenchymal stem cells in adult human bone marrow (BM) has prompted renewed interest in the use of BM as a form of cell therapy. With the aim of optimizing the collection of BM cells, we evaluated the hematopoietic and mesenchymal immature cell contents of BM hematon units (HUs), which usually are eliminated during graft processing. Materials and methods Hematopoietic CD34 + progenitors from HU and buffy coat (BC) compartments were characterized in short-term culture. The sorted CD34 +CDw90(Thy-1) + primitive subset was assessed in colony-forming cell (CFC) and long-term culture-initiating cell (LTC-IC) assays, then further characterized by the expression of additional antigens. In parallel, we evaluated the colony-forming unit fibroblast (CFU-F) number and phenotyped the fresh adherent (D1-3) cells. Results The plating efficiencies of CD34 + cells derived from HU and BC were identical. However, the HU CD34 +CDw90(Thy-1) + subset was enriched in colony-forming unit megakaryocyte (2.3×), LTC-IC (4.6×), and cells coexpressing CD105 (5×). We found a higher frequency of CFU-F (4.7×), considered to be the mesenchymal stem cell-containing population, correlated with an enrichment in fresh adherent (CD45/GPA) −CD14 − cells. Conclusions We show for the first time that functional properties of the CD34 +CDw90 + subset are related to its in vivo location in HU, which may represent the BM mesenchymal reserve compartment. The location in HU of 35.6%, 59.1%, and 58.7% of CD34 + cells, CD34 +CDw90 + LTC-IC, and CFU-F, respectively, justifies the development of a procedure to collect them in order to reduce the therapeutic BM volume.

Thrombopoietin promotes mixed lineage and megakaryocytic colony-forming cell growth but inhibits primitive and definitive erythropoiesis in cells isolated from early murine yolk sacs

The role of thrombopoietin (Tpo) in promoting hematopoiesis has been extensively studied in late fetal, neonatal, and adult mice. However, the effects of Tpo on early yolk sac hematopoiesis have been largely unexplored. We examined whole embryos or the cells isolated from embryo proper and yolk sacs and identified both Tpo and c-mpl (Tpo receptor) mRNA transcripts in tissues as early as embryonic day 6.5 (E6.5). Presomite whole embryos and somite-staged yolk sac and embryo proper cells were plated in methylcellulose cultures and treated with selected hematopoietic growth factors in the presence or absence of Tpo. Tpo alone failed to promote colony-forming unit (CFU) formation. However, in the presence of other growth factors, Tpo caused a substantial dose-dependent reduction in primitive and definitive erythroid CFU growth in cultures containing E7.5 and E8.0 whole embryos and E8.25 to 9.5 yolk sac-derived cells. Meanwhile, Tpo treatment resulted in a substantial dose-dependent increase in CFU-mixed lineage (CFU-Mix) and CFU-megakaryocyte (CFU-Meg) formation in cultures containing cells from similar staged tissues. Addition of Tpo to cultures of sorted E9.5 yolk sac c-Kit(+)CD34(+) hematopoietic progenitors also inhibited erythroid CFU growth but augmented CFU-Mix and CFU-Meg activity. Effects of Tpo on CFU growth were blocked in the presence of a monoclonal antibody with Tpo-neutralizing activity but not with control antibody. Thus, under certain growth factor conditions, Tpo directly inhibits early yolk sac erythroid CFU growth but facilitates megakaryocyte and mixed lineage colony formation.

Predicting the maximum-tolerated dose of PNU-159548 (4-demethoxy-3′-deamino-3′-aziridinyl-4′-methylsulphonyl-daunorubicin) in humans using CFU-GM clonogenic assays and prospective validation

A haematotoxicity model was proposed by Parchment in 1998 to predict the maximum-tolerated dose (MTD) in humans of myelosuppressive antitumour agents by combining data from in vitro clonogenic assays on haematopoietic progenitors and in vivo systemic exposure data in animals. A prospective validation of this model in humans was performed with PNU-159548, a novel agent showing selective dose-limiting myelosuppression in animals. PNU-159548 and its main metabolite, PNU-169884, were tested in vitro on murine, canine and human colony forming units-granulocyte macrophages (CFU-GM) and in vivo on mice and dogs. The IC90x ratios (ICx=concentration inhibiting x% of colony growth) for CFU-GM and drug plasma protein binding were used to adjust the target plasma concentrations versus time curve (AUC) and predict the human MTD. The predicted MTD was compared with values achieved in phase I studies. Canine CFU-GM were 6-fold more sensitive (P<0.01) and murine CFU-GM 1.7-fold less sensitive (P<0.05) to PNU-159548 treatment than the human progenitors. PNU-169884 behaved similarly to PNU-159548. The predicted MTDs in humans calculated from data in mice and dogs were 15 and 38 mg/m2, respectively. Overall, 61 patients were treated in two phase I studies, at doses ranging from 1.0 to 16 mg/m2. Thrombocytopenia was dose-limiting with a MTD of 14 and 16 mg/m2 in heavily and minimally pretreated/non-pretreated patients, respectively. Adjusting animal MTD data by means of the CFU-GM ratio between species can predict the human MTD with a good quantitative accuracy. Inhibition of common haemopoietic progenitors by PNU-159548 induced neutropenia/thrombocytopenia in animals and thrombocytopenia in patients, probably due to the higher sensitivity to the compound observed in human colony forming units-megakaryocyte (CFU-MK).

Thrombospondin-1 inhibits in vitro megakaryocytopoiesis via CD36

Thrombospondin-1 (TSP-1) is an inhibitor of angiogenesis, inducing apoptosis of the endothelial cells via CD36 signaling mechanism. We investigated CD36 expression and the effect of TSP-1 on megakaryocytopoiesis, with and without pegylated recombinant human megakaryocyte growth and development factor (PEG-rHuMGDF), and with and without blocking TSP-1 binding with receptor CD36 on megakaryocytic cells. Our data showed that TSP-1 induced a dose-dependent growth inhibition in both murine and human colony forming unit-megakaryocyte (CFU-MK) assays and significantly counteracted the mitogenic effect from PEG-rHuMGDF. Moreover, the growth suppression induced by TSP-1 was correlated with CD36 expression in megakaryocytic cell lines, where growth inhibition was demonstrated in CD36 positive (Meg-01, Dami and CHRF-288-11) but not in CD36 negative (M-07e) cell lines. More importantly, the inhibitory effect of TSP-1 on both human CFU-MK and Meg-01 cells was partially but significantly reversed by the addition of FA6-152 (anti-CD36), a blocking antibody which blocks the access of TSP-1 to CD36 receptor, suggesting that the TSP-1-induced inhibition of megakaryocytopoiesis is probably mediated in part by the binding of TSP-1 to CD36 expressed on the megakaryocytic progenitors. Thus, our findings represent the first demonstration that TSP-1 inhibits in vitro megakaryocytopoiesis via interaction with CD36.

Characterization of mouse clonogenic megakaryocyte progenitors.

Although it has been shown that unfractionated bone marrow, hematopoietic stem cells, common myeloid progenitors, and bipotent megakaryocyteerythrocyte progenitors can give rise to megakaryocyte colonies in culture, monopotent megakaryocyte-committed progenitors (MKP) have never been prospectively isolated from the bone marrow of adult mice. Here, we use a monoclonal antibody to the megakaryocyte-associated surface protein, CD9, to purify MKPs from the c-kit(+)Sca-1(-)IL7Ralpha(-)Thy1.1(-)Lin(-) fraction of adult C57BLKa-Thy1.1 bone marrow. The CD9(+) fraction contained a subset of CD41(+)FcgammaR(lo)CD34(+)CD38(+) cells that represent approximately 0.01% of the total nucleated bone marrow cells. They give rise mainly to colony-forming unit-megakaryocytes and occasionally burst-forming unit-megakaryocytes, with a plating efficiency >60% at the single-cell level. In vivo, MKPs do not have spleen colony-forming activity nor do they contribute to long-term multilineage hematopoiesis; they give rise only to platelets for approximately 3 weeks. Common myeloid progenitors and megakaryocyteerythrocyte progenitors can differentiate into MKPs after 72 h in stromal cultures, indicating that MKPs are downstream of these two progenitors. These isolatable MKPs will be very useful for further studies of megakaryopoiesis as well as the elucidation of their gene expression patterns.

Refinement of the colony-forming unit-megakaryocyte (CFU–MK) assay for its application to pharmaco-toxicological testing

In vitro colony-forming unit (CFU) assays can be used in the evaluation of potentially haematotoxic compounds during preclinical testing. The use of undifferentiated haematopoietic cells, able to proliferate and commit towards a specific blood cell lineage, enable selective toxicity to be detected. We optimized the colony-forming unit–megakaryocyte (CFU–MK) assay for toxicological applications. We used a collagen-based colony-forming assay to examine the sensitivity of four cell types: mononuclear human cord blood cells (CBC), mononuclear human bone marrow cells (BMC), cord blood enriched CD34 +CD38 − cells, and bone marrow enriched CD34 +CD38 − cells, to the toxic effects of five drugs known to cause thrombocytopenia in humans. The enrichment of CD34 +CD38 − cells was achieved by using a negative cell separation technique. Our results showed that a comparable toxicity was detected both with CBC, BMC and CD34 +CD38 − cells enriched from cord blood, whereas CD34 +CD38 − cells from bone marrow were more resistant to some drugs. The assay showed a high reproducibility of the endpoint measured (IC 50), independently of the cell type used and donor source. The present study demonstrates that the refined CFU–MK assay is reproducible and can be used for in vitro toxicology studies with CBC as well as BMC.

Immature CD34+CD19− progenitor/stem cells in TEL/AML1-positive acute lymphoblastic leukemia are genetically and functionally normal

AbstractOne important question in stem cell biology of childhood acute lymphoblastic leukemia (ALL) is whether immature CD34+CD19− cells are part of the leukemic cell clone. CD34+CD19− cells from the bone marrow of 9 children with TEL/AML1-positive ALL were purified by flow sorting and subjected to reverse transcriptase–polymerase chain reaction (RT-PCR), fluorescence in situ hybridization, and methylcellulose cultures. In 3 of 8 patients analyzed by RT-PCR, noTEL/AML1-positive cells could be detected in the CD34+CD19− cell fraction. Altogether, the percentage of TEL/AML1-positive cells was low: 1.6% (n = 8; SD 2.2%) by nested real-time RT-PCR and 2.5% (n = 5; SD 2.6%) by fluorescence in situ hybridization. This correlated with the percentage of contaminating CD19+ leukemic cells in the CD34+CD19− cell fraction in 6 control sorts (mean 4.6%, SD 3.6%), indicating that the low levels of leukemic cells detected in the CD34+CD19− cell fraction could be attributed to sorter errors. Methylcellulose cultures in 3 patients provided further evidence that CD34+CD19− cells represent a candidate normal cell population. The clonogenicity of the CD34+CD19− cell fraction was similar to normal progenitors, including growth of primitive granulocyte, erythroid, macrophage, megakaryocyte colony-forming units. Each of 92 colonies from cultures with CD34+CD19− cells tested negative for TEL/AML1. In conclusion, our data support the hypothesis that the leukemia inTEL/AML1-positive childhood ALL originates in a CD19+ lymphoid progenitor. This has many therapeutic implications, eg, for purging of autologous stem cell products, flow cytometric monitoring of minimal residual disease, and targeting immunotherapy against the leukemic cell clone.

Homing and clonogenic outgrowth of CD34(+) peripheral blood stem cells: a role for L-selectin?

After transplantation of hematopoietic stem cells, adhesion molecules play a major role in the multistep process of engraftment in which L-selectin is suggested to be of relevance. A positive correlation previously was found between the number of reinfused L-selectin(+) stem cells and platelet recovery. In the present study, we determined the role of L-selectin in different engraftment steps, i.e., adhesion to endothelial cells, migration, and clonogenic outgrowth by in vitro assays that closely mimic the in vivo situation. Flow adhesion and migration experiments were performed using the human bone marrow endothelial cell line 4LHBMEC and isolated peripheral CD34(+) cells with or without blocking of L-selectin-ligand interaction. Various clonogenic assays, including serum-free colony-forming unit-megakaryocytes (CFU-MK) and burst-forming unit-megakaryocytes (BFU-MK), were performed with sorted L-selectin(+)L-selectin(-) cells or in the presence of antibodies. Blocking of L-selectin on CD34(+) cells did not significantly affect rolling over and firm adhesion to 4LHBMEC. In addition, no role for L-selectin was found in transendothelial migration experiments. Finally, in clonogenic outgrowth of sorted or anti-L-selectin monoclonal antibody-incubated CD34(+) cells, no key role for L-selectin expression could be defined in BFU-MK and CFU-MK assays. Using in vitro assays for CD34(+) stem cell adhesion, migration, and clonogenic capacity, we were not able to define a major role for L-selectin.

Enhanced expansion and maturation of megakaryocytic progenitors by fibronectin.

Megakaryopoiesis occurs as a result of a complex interaction between hemopoietic cells, stromal cells, hemopoietic growth factors and extracellular matrix (ECM). Megakaryocyte growth and development factor (MGDF) or thrombopoietin is the main growth factor that induces megakaryocyte commitment. The role of adhesion proteins in the generation of megakaryocytic progenitors has not been well studied. We isolated CD34(+) cells from umbilical cord (UC) blood and cultured them in serum-free medium containing IL-3, IL-6, SCF and MGDF, with or without fibronectin. Cultures were sampled at Days 4 and 8 for cell count, immunophenotyping by flow cytometry, and megakaryocyte colony-forming units (CFU-Mk) assay. Fibronectin in synergy with MGDF increased both total and CD34(+) cell count. Immunophenotyping of the CD34(+) and CD34(-) cells showed that the percentage expression of CD61 and CD41a on CD34(-) cells was increased by fibronectin compared with CD34(+) cells by Day 8 of culture. The CFU-Mk assay confirmed that fibronectin increased generation of megakaryocytic progenitors by 2.4-fold by Day 8 of culture, but the absolute number was less than that of Day 4 culture. The cells in the CFU-Mk colonies derived from culture containing fibronectin were larger than those from cytokine-only culture. It was concluded that the addition of fibronectin to the culture system enhanced MGDF, induced ex vivo expansion of megakaryocytic progenitors from CD34(+) cells, as well as increasing their maturation towards later stages of megakaryocyte differentiation.

Extracorporeal shock wave promotes growth and differentiation of bone-marrow stromal cells towards osteoprogenitors associated with induction of TGF-beta1.

Extracorporeal shock-wave (ESW) treatment has been shown to be effective in promoting the healing of fractures. We aimed to determine whether ESW could enhance the growth of bone-marrow osteoprogenitor cells. We applied ESW to the left femur of rats 10 mm above the knee at 0.16 mJ/mm2 in a range of between 250 and 2000 impulses. Bone-marrow cells were harvested after ESW for one day and subjected to assessment of colony-forming unit (CFU) granulocytes, monocytes, erythocytes, megakaryocytes (CFU-Mix), CFU-stromal cells (CFU-S) and CFU-osteoprogenitors (CFU-O). We found that the mean value for the CFU-O colonies after treatment with 500 impulses of ESW was 168.2 CFU-O/well (SEM 11.3) compared with 88.2 CFU-O/well (SEM 7.2) in the control group. By contrast, ESW treatment did not affect haematopoiesis as shown by the CFU-Mix (p = 0.557). Treatment with 250 and 500 impulses promoted CFU-O, but not CFU-Mix formations whereas treatment with more than 750 impulses had an inhibiting effect. Treatment with 500 impulses also enhanced the activity of bone alkaline phosphatase in the subculture of CFU-O (p<0.01), indicating a selective promotion of growth of osteoprogenitor cells. Similarly, formation of bone nodules in the long-term culture of bone-marrow osteoprogenitor cells was also significantly enhanced by ESW treatment with 500 impulses. The mean production of TGF-beta1 was 610 pg/ml (SEM 84.6) in culture supernatants from ESW-treated rats compared with 283 pg/ml (SEM 36.8) in the control group. Our findings suggest that optimal treatment with ESW could enhance rat bone-marrow stromal growth and differentiation towards osteoprogenitors presumably by induction of TGF-beta1.