In vivo effects of interleukin-17 on haematopoietic cells and cytokine release in normal mice

In order to gain more insight into mechanisms operating on the haematopoietic activity of the T-cell-derived cytokine, interleukin-17 (IL-17) and target cells that first respond to its action in vivo, the influence of a single intravenous injection of recombinant mouse IL-17 on bone marrow progenitors, further morphologically recognizable cells and peripheral blood cells was assessed in normal mice up to 72 h after treatment. Simultaneously, the release of IL-6, IL-10, IGF-I, IFN-gamma and NO by bone marrow cells was determined. Results showed that, in bone marrow, IL-17 did not affect granulocyte-macrophage (CFU-GM) progenitors, but induced a persistant increase in the number of morphologically recognizable proliferative granulocytes (PG) up to 48 h after treatment. The number of immature erythroid (BFU-E) progenitors was increased at 48 h, while the number of mature erythroid (CFU-E) progenitors was decreased up to 48 h. In peripheral blood, white blood cells were increased 6 h after treatment, mainly because of the increase in the number of lymphocytes. IL-17 also increased IL-6 release and NO production 6 h after administration. Additional in vitro assessment on bone marrow highly enriched Lin- progenitor cells, demonstrated a slightly enhancing effect of IL-17 on CFU-GM and no influence on BFU-E, suggesting the importance of bone marrow accessory cells and secondary induced cytokines for IL-17 mediated effects on progenitor cells. Taken together, these results demonstrate that in vivo IL-17 affects both granulocytic and erythroid lineages, with more mature haematopoietic progenitors responding first to its action. The opposite effects exerted on PG and CFU-E found at the same time indicate that IL-17, as a component of a regulatory network, is able to intervene in mechanisms that shift haematopoiesis from the erythroid to the granulocytic lineage.     

Hematopoiesis in the rat: quantitation of hematopoietic progenitors and the response to iron deficiency anemia

To determine the quantitative effects of iron deficiency on erythropoiesis and to assess the response of erythroid progenitors to sustained anemia, we developed quantitative assays for various hematopoietic progenitors in the adult, Sprague-Dawley rat including erythroid colony- and burst-forming cells (CFU-E and BFU-E), granulocyte/macrophage colony-forming cells (CFU-GM), and megakaryocytic colony-forming cells (CFU-Meg). CFU-E were cultured in methylcellulose and grew best in the presence of fetal calf serum. CFU-GM, BFU-E, and CFU-Meg grew better in normal rat plasma and required the presence of pokeweed mitogen-stimulated rat spleen cell conditioned medium. The numbers of progenitors and nucleated erythroblasts in total marrow were estimated by the ratios of radioactivity in the humerus to the total skeleton as determined by radioiron dilution. The numbers of progenitors and erythroblasts in the spleen were measured by simple dilution. Sustained anemia was brought about through chronic iron deficiency. The response to iron deficiency anemia (IDA) was monitored by the numbers of the various progenitors and their cell cycle characteristics as measured by the tritiated thymidine suicide technique. With IDA, the number of CFU-F in the body (marrow plus spleen) was increased to 3.5 times control, whereas the numbers of BFU-E and CFU-GM were unchanged. There was no difference in the percentage of CFU-E, BFU-E, and CFU-GM in DNA synthesis (68%, 19.4%, and 18.8%, respectively). With iron therapy of IDA, CFU-E numbers in marrow began to decrease by day 1 and fell in a manner reciprocal to changes in the hematocrit. Marrow and spleen erythroblasts, 1.7 times control in IDA, increased further to 3.9 times control by the fourth day after iron administration. There was no change in BFU-E or CFU-GM numbers in response to iron repletion, although the fraction of progenitors increased in the spleen. Thus, IDA does not limit the increase in CFU-E seen with anemia, but does restrict erythroid maturation. Furthermore, the increase in CFU-E and the state of chronic anemia occur without detectable changes in the number of cell cycle state of the more primitive BFU-E.     

Retrovirus-induced feline pure red cell aplasia: the kinetics of erythroid marrow failure

Cats viremic with feline leukemia virus subgroup C (FeLV-C) develop pure red cell aplasia (PRCA) characterized by the loss of detectable late erythroid progenitors (CFU-E) in marrow culture. Normal numbers of early erythroid progenitors (BFU-E) and granulocyte-macrophage progenitors (CFU-GM) remain, suggesting that the maturation of BFU-E to CFU-E is impaired in vivo. We have examined the cell cycle kinetics of BFU-E and their response to hematopoietic growth factor(s) to better characterize erythropoiesis as anemia develops. Within 3 weeks of FeLV-C infection, yet 6-42 weeks before anemia, the traction of BFU-E in DNA synthesis as determined by tritiated thymidine suicide increased to 43 +/- 4% (normal 23 +/- 2%) while there was no change in the cell cycle kinetics of CFU-GM. In additional studies, we evaluated the response of marrow to the hematopoietic growth factor(s) present in medium conditioned by FeLV-infected feline embryonic fibroblasts (FEA/FeLV CM). With cells from normal cats or cats viremic with FeLV-C but not anemic, a 4-fold increase in erythroid bursts was seen in cultures with 5% FEA/FeLV CM when compared to cultures without CM. However, just prior to the onset of anemia, when the numbers of detectable CFU-E decreased, BFU-E no longer responded to FEA/FeLV CM in vitro. BFU-E from anemic cats also required 10% cat or human serum for optimal in vitro growth. These altered kinetics and in vitro growth characteristics may relate to the in vivo block of BFU-E differentiation and PRCA. Finally, when marrow from cats with PRCA was placed in suspension culture for 2 to 4 days in the presence of cat serum and CM, the numbers of BFU-E increased 2- to 4-fold although no CFU-E were generated. By 4 to 7 days, CFU-E were detected, suggesting that conditions contributing to the block of erythroid maturation did not persist. The suspension culture technique provides an approach to study further the defect in erythroid differentiation characteristic of feline PRCA.     

Erythropoietin responses and physical characterization of erythroid progenitor cells in Rauscher virus infected BALB/c mice.

Infection of BALB/c mice with Rauscher leukemia virus (RLV) gives rise to pronounced erythrocytopoiesis manifesting in splenomegaly and is associated with progressive development of anemia. In the spleen erythroid colony forming units (CFU-E) increase exponentially up to 800-fold that of normal levels by the third week of infection. In vitro these CFU-E are dependent on erythropoietin for colony formation, their erythropoietin requirements being higher than that of CFU-E from normal mice. Numbers of CFU-E in spleen and degree of splenomegaly in anemic RLV infected mice were also shown to be modified by red blood cell transfusion, but progression of the disease was not stopped. Erythroid burst forming units (BFU-E) were also responsive to erythropoietin. However, a small proportion of cells also formed BFU-E colonies at concentrations which did not support growth of normal marrow BFU-E. When compared to normal, CFU-E found in RLV-infected spleen have similar velocity sedimentation rates. However, buoyant density separation of leukemic spleen cells indicated that CFU-E were more homogeneous (modal density 1.0695 g/cm3) than CFU-E from normal spleen. Analysis of physical properties of CFU-E and the nonhemoglobinized erythroblast-like cells, which accumulate in the spleen showed that they differed mainly in their distribution of cell diameter. Our findings show that erythroid progenitor cells in RLV infected mice are responsive to erythropoietin in vitro. Also in vivo erythropoiesis appears to be under control of erythropoietin but other factors which lead to progression of RLV disease apparently exist. Most proerythroblast-like cells, which are characteristic of this disease, apparently lack the potential to form colonies and may be more mature than CFU-E.     

Thy-1 is a differentiation antigen that characterizes immature murine erythroid and myeloid hematopoietic progenitors

To determine the role of Thy-1 antigen in murine hematopoietic differentiation, bone marrow was treated with anti-Thy-1.2 antibody and complement or complement alone. Growth of immature hematopoietic progenitors, erythroid burst-forming units (BFU-E), and granulocyte/macrophage colony-forming units (CFU-GM) was greatly reduced following antibody and complement treatment and was not restored by mitogen-stimulated spleen cell supernatants. In contrast, more mature erythroid and myeloid progenitors, the erythroid colony-forming unit (CFU-E) and the macrophage progenitor stimulated by L-cell-conditioned media (LCM), were spared by anti-Thy-1.2 antibody and complement treatment. Here, to separate the effects of anti-Thy-1.2 antibody treatment on accessory cells from those on progenitors, splenic T cells and thymocytes were added to treated marrow at ratios of up to 200%. Growth of BFU-E and CFU-GM was not restored. To more precisely replace required accessory cells, male complement-treated marrow was cocultured with female anti-Thy-1.2 antibody and complement-treated marrow. Even marrow cells failed to restore female BFU-E and CFU-GM growth. Fluorescent-activated cell sorting (FACS) and immune sheep red cell rosetting with anti-Thy-1.2-labeled marrow were then performed to determine if immature hematopoietic progenitors bear Thy-1.2. These techniques revealed enrichment of BFU-E and CFU-GM in the Thy-1.2-positive fraction, demonstrating the presence of Thy-1.2 on early murine hematopoietic progenitors. CFU-E and CFU-M were present in the Thy-1.2-negative fraction following FACS separation. These data demonstrate that Thy-1.2 is a differentiation antigen, present on at least some murine BFU-E and CFU-GM and lost as they mature to CFU-E and CFU-M.     

The effect of erythropoietin on the mature burst forming unit erythroid in mice

The aim of the study was to further delineate the erythropoietin (Ep) dependence of the mature Burst Forming Unit-Erythroid - BFU-E(d4). Experiments were performed in normal and polycythemic CBA mice. BFU-E(d4) were determined by means of the methylcellulose culture technique. It was demonstrated that in plethoric mice the number of BFU-E(d4) is reduced from 9 000/femur and 30 000/spleen found in normal mice to less than 1 000/femur and 2 000/spleen on day 6 post-hypoxia. The number of BFU-E(d4) remained low both in the bone marrow and spleen in mice with posthypoxic polycythemia between days 6 and 11 post-hypoxia. When exogenous Ep was injected into the plethoric mice the number of BFU-E(d4) increased after 24 h both in the bone marrow and spleen. In Ep stimulated polycythemic mice the CFU-E:BFU-E(d4) ratio did not achieve normal values, indicating that although Ep stimulation increased the number of BFU(d4), the number of CFU-E produced per BFU-E(d4) was lower than in normal nonpolycythemic mice. The results obtained indicate that BFU-E(d4) population size depends on the effect of Ep on differentiation and proliferation of erythroid committed precursors.     

Myeloproliferative sarcoma virus (MPSV), a new tool for the study of hematopoiesis

MPSV induces a myeloproliferative syndrome in susceptible mice associated with an invasion of hematopoietic and nonhematopoietic organs with tumor nodules. The effect of the virus on the various hematopoietic precursors (CFU-S, CFU-C, CFU-E, BFU-E) was studied in vivo in the spleen, blood, and bone marrow, and in vitro, using colony assays in semisolid medium. After in vivo and in vitro infection MPSV induces the appearance of CFU-C, independent of added colony-stimulating activity and of pure and mixed BFU-E, independent of burst-promoting activity. MPSV also induces in vivo an amplification of the size and concentration of the hematopoietic system, including hematopoietic stem cells. MPSV infection may also alter the hemapoietic microenvironment. Modification of the disease by total body irradiation followed by bone marrow stem cell reconstitution or by splenectomy is compatible with mediation of the virus effect at the level of hematopoietic microenvironment. MPSV may constitute a new tool to study the regulation of murine hematopoiesis and viral genetic information, which can specifically induce characteristic disturbances of this system.     

Evidence suggesting a stimulatory role for interleukin-10 in erythropoiesis in vitro

Interleukin-10 (IL-10) has been shown to exert anti-inflammatory effects by suppressing macrophage proliferation and inhibiting cytokine production. In this study we show that in the presence of erythropoietin (EPO), the addition of IL-10 results in a significant dose-dependent increase in both Burst Forming Unit-Erythroid (BFU-E) and Colony Forming Unit-Erythroid (CFU-E) colony growth in both serum-containing and serum-free murine cultures in vitro. IL-10 acts at the later stages of erythroid cell proliferation and differentiation as the increase in colony number was greater in CFU-E than in BFU-E, and was similar when IL-10 was added to BFU-E cultures at the time of culture initiation as when its addition to culture was delayed for 7 days. Furthermore, no increase in BFU-E colony number was noted when IL-10, added at the time of culture initiation, was neutralized by the addition to culture of a monoclonal anti-IL-10 antibody up to 7 days later. The increases in BFU-E by IL-10 addition were not the result of prolongation of BFU-E colony lifespan, which was not significantly different in IL-10 treated and control cultures, respectively. Rather IL-10 stimulated the proliferation of erythroid clusters that were now large enough to be recognized as colonies. IL-10-induced stimulation of erythropoiesis appeared to be independent of its inhibitory effects on macrophage function, as stimulation of erythroid colony growth was similar in macrophage-containing and depleted cultures. Studies to determine if the IL-10 effect was direct or indirect yielded equivocal results. A limiting dilution assay suggested a direct effect. However, a log/log dose response curve with IL-10 did not pass through the origin suggesting an indirect effect. These studies indicate that IL-10 acts synergistically with EPO to significantly increase stimulation of erythroid differentiation and proliferation in vitro and may be involved in the regulation of normal erythropoiesis in vivo. © 1996 Wiley-Liss, Inc.     

Myeloproliferative sarcoma virus: its effects on erythropoiesis in adult DBA/2J mice

Adult susceptible mice (DBA/2J) infected with MPSV (myeloproliferative sarcoma virus), a defective RNA tumour virus, develop splenomegaly and progressive disruption of the haematologic system culminating in death. The present study was specifically directed toward determining the effects of the virus on erythroid differentiation. Early and late precursor cells (erythroid burst-forming units; BFU-E and colony-forming units; CFU-E, respectively) were evaluated by the ability of bone marrow and spleen cells to form colonies of fully differentiated erythroid cells in vitro. MPSV caused substantial modification of both the BFU-E and CFU-E populations in the bone marrow and spleen of infected animals. Changes were detected in the CFU-E population preceding any significant increase in spleen weight. In the bone marrow, the proportion of CFU-E cells increased almost twofold by days 5-10 after virus infection but decreased by day 15. In the spleen, CFU-E frequency rose 40-fold by days 10-15 and then declined steadily prior to death. At the peak of CFU-E expansion, a small proportion of the population appeared to be erythropoietin (Ep) independent, although there was no evidence of a complete switch to Ep-independence which occurs in Friend virus-induced erythroleukemia. Dose-response curves showed that none of these data could be explained in terms of a changing responsiveness to Ep. However, evidence is presented that indicates that BFU-E from MPSV-infected animals lose or have a reduced requirement for burst-promoting activity (BPA) relative to normal cells although their progeny still need Ep for terminal erythroid differentiation.     

ISG15 modulates development of the erythroid lineage

Activation of erythropoietin receptor allows erythroblasts to generate erythrocytes. In a search for genes that are up-regulated during this differentiation process, we have identified ISG15 as being induced during late erythroid differentiation. ISG15 belongs to the ubiquitin-like protein family and is covalently linked to target proteins by the enzymes of the ISGylation machinery. Using both in vivo and in vitro differentiating erythroblasts, we show that expression of ISG15 as well as the ISGylation process related enzymes Ube1L, UbcM8 and Herc6 are induced during erythroid differentiation. Loss of ISG15 in mice results in decreased number of BFU-E/CFU-E in bone marrow, concomitant with an increased number of these cells in the spleen of these animals. ISG15(-/-) bone marrow and spleen-derived erythroblasts show a less differentiated phenotype both in vivo and in vitro, and over-expression of ISG15 in erythroblasts is found to facilitate erythroid differentiation. Furthermore, we have shown that important players of erythroid development, such as STAT5, Globin, PLC γ and ERK2 are ISGylated in erythroid cells. This establishes a new role for ISG15, besides its well-characterized anti-viral functions, during erythroid differentiation.     

Transitional change of colony stimulating factor requirements for erythroid progenitors.

The course of the differentiation and proliferation of the human erythroid burst-forming units (BFU-E) to colony-forming units (CFU-E) was directly investigated using a combination of highly purified BFU-E, a liquid culture system, and the following clonal assay. Highly purified human blood BFU-E with a purity of 45-79% were cultured in liquid medium with recombinant human erythropoietin (rEP) and recombinant human interleukin-3 (rIL-3) to generate more differentiated erythroid progenitors. The cultured cells were collected daily for investigating the morphology, the increment in the number of cells and the clonality. Ninety percent of purified BFU-E required not only rEP but also rIL-3 for clonal development. By 7 days of liquid culture, the total cell number increased 237 +/- 20-fold above the starting cells, while erythroid progenitors increased 156 +/- 74-fold. As the incubation time in liquid culture increased, the cells continuously differentiated in morphology. Replating experiments with rEP combined with or without rIL-3 showed the following: 1) The number of erythroblasts that were part of erythroid colonies decreased with accompanying erythroid progenitor differentiation and proliferation. 2) As the incubation time in liquid culture increased, erythroid progenitors had a graded loss of their dependency on rIL-3 and a complete loss of dependency was observed after 3 days of liquid culture. At that time 85% of the erythroid progenitors gave rise to colonies of more than 100 erythroblasts which were equivalent to mature BFU-E. These studies provide a quantitative assessment of the loss of IL-3 dependency by BFU-E and indicate that the size of the generated erythroid colonies and their IL-3 requirement correlate with the erythroid differentiated state.     

Purification of human blood burst-forming units-erythroid and demonstration of the evolution of erythropoietin receptors

To facilitate the direct study of the molecular events that control the development of human burst-forming units-erythroid (BFU-E), we have developed a method to purify BFU-E from peripheral blood. Using density centrifugation, rosetting with a mixture of neuraminidase-treated and IgG-coated sheep erythrocytes, positive panning with anti-My10 monoclonal antibody, overnight adherence to plastic dishes, negative panning with monoclonal antibodies, and density centrifugation, human blood BFU-E were purified from 0.04% to 56.6%, a 1,400-fold purification with a 13% yield. More than 90% of purified BFU-E were recombinant interleukin-3 (rIL-3) dependent, which survived for 48 h with rIL-3 in the absence of recombinant erythropoietin (rEP), and 80% gave rise to erythroid bursts of more than 500 hemoglobinized cells. rEP dependency was not evident until after 72 h of incubation in vitro. The purified cells (day 1) were incubated with rIL-3 and rEP in liquid culture for 24 (day 2), 48 (day 3), and 72 (day 4) h and then were transferred into semisolid cultures and incubated until day 15. The size of the erythroid colonies observed in semisolid cultures decreased continuously in association with the incubation time of day 1 purified cells in liquid cultures. The first appearance of colony-forming units-erythroid (CFU-E) that gave rise to colonies of 8 to 49 cells was observed after 72 h of incubation of day 1 cells in the liquid culture. 125I-rEP was incubated for 5 h at 37 degrees C with purified cells (day 1) or with the cells that had been incubated in liquid culture for an additional 24-72 h, and the presence of erythropoietin (EP) receptors was investigated using autoradiography. Specific binding of 125I-rEP was detected in 19 +/- 7% of the initial day 1 BFU-E. The percentage of 125I-rEP-binding to erythroid progenitor cells and the amount of binding continuously increased as day 1 BFU-E matured. 125I-rEP specific binding was observed with all of the erythroid progenitor cells that had been incubated in liquid culture for 72 h. These data demonstrate that primitive BFU-E have a much lower number of EP receptors than CFU-E and develop an increased concentration of EP receptors in association with their maturation and loss of proliferative capacity.     

Interleukine-17-induced inhibitory effect on late stage murine erythroid bone marrow progenitors

Recent studies have shown that the T cell-derived cytokine, interleukin-17 (IL-17), stimulates hematopoiesis, specifically granulopoiesis inducing expansion of committed and immature progenitors in bone marrow. Our previous results pointed to its role in erythropoiesis too, demonstrating significant stimulation of BFU-E and suppression of CFU-E growth in the bone marrow from normal mice. As different sensitivities of erythroid and myeloid progenitor cells to nitric oxide (NO) were found, we considered the possibility that the observed effects of IL-17 were mediated by NO. The effects of recombinant mouse IL-17, NO donor (sodium nitroprusside - SNP) and two NO synthases inhibitors (L-NAME and aminoguanidine) on erythroid progenitor cells growth, as well as the ability of IL-17 to induce nitric oxide production in murine bone marrow cells, were examined. In addition, we tested whether the inhibition of CFU-E colony formation by IL-17 could be corrected by erythropoietin (Epo), the principal regulator of erythropoiesis. We demonstrated that IL-17 can stimulate low level production of NO in murine bone marrow cells. Exogenously added NO inhibited CFU-E colony formation, whereas both L-NAME and aminoguanidine reversed the CFU-E suppression by IL-17 in a dose-dependent manner. The inhibition of CFU-E by IL-17 was also corrected by exposure to higher levels of Epo. The data obtained demonstrated that at least some of the IL-17 effects in bone marrow related to the inhibition of CFU-E, were mediated by NO generation. The fact that Epo also overcomes the inhibitory effect of IL-17 on CFU-E suggests the need for further research on their mutual relationship and co-signalling.     

Target cells for Friend virus-induced erythroid bursts in vitro

Erythropoietin (Epo) acts on mouse bone marrow cells in vitro in plasma clot or methyl cellulose culture systems to induce the formation of single erythroid colonies, or clusters of erythroid colonies termed bursts. Our laboratory has recently reported the observation that infection of mouse bone marrow cells in vitro with the polycythemia-inducing strain of Friend virus (FV) resulted in the formation of erythroid bursts after 5 days in plasma clot culture in the absence of added Epo. We have now used this system to characterize the target cells for this FV-induced erythroid transformation. The greatest number of FV bursts were observed when marrow cells were obtained from mice whose erythropoiesis had been stimulated by bleeding or phenylhydrazine treatment. Bleeding also resulted in an increase in the number of FV bursts following the infection of spleen cells in vitro. Hypertransfusion of mice, which results in decreased erythropoiesis, yielded a reduced number of FV bursts in vitro, as did prior treatment with actinomycin D. Cell separation studies using velocity sedimentation at unit gravity showed that the cells, which give rise to FV bursts, sedimented with a modal sedimentation velocity between 5.1–8.5 mm/hr. The Epo-dependent colony-forming unit erythroid (CFU-E), which gives rise to a single erythroid colony, also sediments with a modal velocity between 5.1–8.5 mm/hr, while the Epo-dependent day 8 burst-forming unit erythroid (day 8 BFU-E) sediments with a modal velocity between 3.0–6.0 mm/hr. A 20 min incubation of marrow cells with high specific activity ³H-thymidine, prior to virus infection, resulted in a 75–80% reduction in the number of FV bursts. Mixing cells from the upper portion of the gradient, which yielded no FV bursts, with cells from an area in which high numbers of FV bursts were observed did not result in the inhibition of burst formation. These experiments indicate that the primary target cells for FV bursts in vitro are most probably erythroid precursor cells that have matured beyond the day 8 BFU-E and are closely related to the CFU-E.     

Differential proliferative effects of transforming growth factor-beta on human hematopoietic progenitor cells

Transforming growth factor-beta (TGF beta) regulates cell growth and differentiation in numerous cell systems, including several hematopoietic lineages. We used in vitro cultures of highly enriched hematopoietic progenitor cells stimulated by natural and recombinant growth factors to investigate the biologic effects of TGF beta 1 and TGF beta 2 on erythroid (CFU-E and burst-forming unit (BFU)-E), granulocyte-macrophage (CFU-GM) and multilineage (i.e., granulocyte, erythroid, macrophage, and megakaryocyte; CFU-GEMM) colony-forming cells. In the absence of exogenous CSF, neither TGF beta 1 nor TGF beta 2 supported progenitor cell growth. In the presence of recombinant or natural CSF, picomolar concentrations of TGF beta 1 inhibited growth of CFU-E, BFU-E, and CFU-GEMM and enhanced growth of day 7 CFU-GM. Inhibition of CFU-E and BFU-E by human and porcine TGF beta 1 was similar, ranging from 17 to 73% over a concentration range of 0.05 to 1.0 ng/ml, and was largely independent of the type of burst-promoting activity used (rIL-3 vs cell line 5637-conditioned medium). Inhibition of CFU-GEMM ranged from 79 to 98% over a concentration range of 0.25 to 1.0 ng/ml. The inhibitory effect of TGF beta 1 was progressively lost when its addition was delayed for 40 to 120 h, suggesting a mode of action during early cell divisions. In contrast, growth of CFU-GM stimulated by plateau concentrations of human rG-CSF, rGM-CSF, and rIL-3 was enhanced up to 154 +/- 22% by human TGF beta 1. Porcine platelet-derived TGF beta 2 was essentially without effect on the progenitor populations examined. These results support the hypothesis that TGF beta may play role in the regulation of hematopoietic progenitor cell proliferation by differentially affecting individual lineages and is apparently capable of doing so in the relative absence of marrow accessory cells.     

Identification and purification of human erythroid progenitor cells by monoclonal antibody to the transferrin receptor (TU 67)

Anti-TU 67 is a murine monoclonal antibody that recognizes the transferrin receptor. With respect to hematopoietic cells TU 67 is expressed by human multipotent colony-forming cells (CFU-Mix), erythroid progenitor cells (BFU-E and CFU-E) and a fraction of granulocyte/monocyte colony forming cells, but is not expressed by mature hematopoietic cells including erythrocytes, platelets, lymphocytes, and peripheral blood myeloid cells. The TU 67-positive fraction of normal bone marrow, separated by fluorescence-activated cell sorting (FACS) or immune rosettes, contained 87% of the erythroid progenitor cells. Erythroid progenitor cells were enriched up to 50-fold by using a combination of monoclonal antibodies to deplete mature hematopoietic cells, followed by positive selection of BFU-E and CFU-E by TU 67 antibody.     

In vitro effect of glucan on mouse hemopoietic committed progenitor cells

In vitro methylcellulose clonal cell culture assays of granulopoietic and erythropoietic colonies were used to study the primary effect of glucan on the hematopoietic stem cells. Addition of glucan to the cultures inhibits the formation of colony-forming units-erythrocytic (CFU-E), enhances the production of burst forming units-erythrocytic (BFU-E) and has no effect on colony-forming unit-culture (CFU-C). These results indicate that glucan has a direct effect on late and early erythroid precursor cells.     

Transforming growth factor beta: possible roles in the regulation of normal and leukemic hematopoietic cell growth

We have recently demonstrated that transforming growth factor (TGF)-beta 1 and TGF-beta 2 are potent inhibitors of the growth and differentiation of murine and human hematopoietic cells. The proliferation of primary unfractionated murine bone marrow by interleukin-3 (IL-3) and human bone marrow by IL-3 or granulocyte/macrophage colony-stimulating factor (GM-CSF) was inhibited by TGF-beta 1 and TGF-beta 2, while the proliferation of murine bone marrow by GM-CSF or murine and human marrow with G-CSF was not inhibited. Mouse and human hematopoietic colony formation was differentially affected by TGF-beta 1. In particular, CFU-GM, CFU-GEMM, BFU-E, and HPP-CFC, the most immature colonies, were inhibited by TGF-beta 1, whereas the more differentiated unipotent CFU-G, CFU-M, and CFU-E were not affected. TGF-beta 1 inhibited IL-3-induced growth of murine leukemic cell lines within 24 h, after which the cells were still viable. Subsequent removal of the TGF-beta 1 results in the resumption of normal growth. TGF-beta 1 inhibited the growth of factor-dependent NFS-60 cells in a dose-dependent manner in response to IL-3, GM-CSF, G-CSF, CSF-1, IL-4, or IL-6. TGF-beta 1 inhibited the growth of a variety of murine and human myeloid leukemias, while erythroid and macrophage leukemias were insensitive. Lymphoid leukemias, whose normal cellular counterparts were markedly inhibited by TGF-beta, were also resistant to TGF-beta 1 inhibition. These leukemic cells have no detectable TGF-beta 1 receptors on their cell surface. Last, TGF-beta 1 directly inhibited the growth of isolated Thy-1-positive progenitor cells. Thus, TGF-beta may be an important modulator of normal and leukemic hematopoietic cell growth.     

THE ROLE OF ERYTHROPOIETIN IN REGULATION OF POPULATION SIZE AND CELL CYCLING OF EARLY AND LATE ERYTHROID PRECURSORS IN MOUSE BONE MARROW

This study was designed to determine the stage in haemopoietic cell differentiation from multipotential stem cells at which erythropoietin becomes physiologically important. The responses of haemopoietic precursor cells were monitored in the bone marrow of mice under conditions of high (after bleeding) and low (after hypertransfusion) ambient erythropoietin levels. The number of relatively mature erythroid precursors (CFU-E), detected by erythroid colony formation after 2 days of culture, increased three-fold in marrow by the fourth day after bleeding, and decreased three-fold after hypertransfusion. Assessed by sensitivity to killing by a brief exposure to tritiated thymidine (³H-TdR) in vitro, the proliferative activity of CFU-E was high (75% kill) in untreated and bled animals, and was slightly lower (60% kill) after hypertransfusion. The responses of more primitive erythroid progenitors (BFU-E), detected by erythroid colony formation after 10 days in culture, presented a contrasting pattern. After hypertransfusion they increased slightly, while little change was noted until the fourth day after bleeding, when they decreased in the marrow. The same response pattern was observed for the progenitors (CFU-C) detected by granulocyte/macrophage colony formation in culture. The sensitivity of BFU-E to ³H-TdR was normally 30%, and neither increased after bleeding nor decreased after hypertransfusion. However, in regenerating marrow the ³H-TdR sensitivity of BFU-E increased to 63%, and this increase was not affected by hypertransfusion. These results are interpreted as indicating (1) that physiological levels of erythropoietin do not influence the decision by multipotential haemopoietic stem cells to differentiate along the erythroid pathway as opposed to the granulocyte/macrophage pathway; (2) that early erythroid-committed progenitors themselves do not respond to these levels of erythropoietin, but rather are subject to regulation by erythropoietin-independent mechanisms; and (3) that physiological regulation by erythropoietin commences in cells at a stage of maturation intermediate between BFU-E and CFU-E.     

小鼠胎肝基质细胞造血刺激因子体外生物活性研究

本实验对基质细胞造血刺激因子－１（ＳＨＦ－１）的体外生物活性进行了研究。结果表明,ＳＨＦ－１可刺激小鼠骨髓ＣＦＵ－Ｅ、ＢＦＵ－Ｅ、ＣＦＵ－ＧＭ、ＣＦＵ－Ｍｉｘ集落的形成,它产生的这些广泛造血刺激作用是其自身所具活性的直接影响。正常小鼠骨髓细胞与ＳＨＦ－１在体外孵育４ｈ,其中ＣＦＵ－Ｓ的自杀率可提高约１０％,显示它对造血干细胞也有诱导增殖作用。