Effects of erythroid differentiation factor on inhibition of erythroid colony-formation (CFU-E and BFU-E) by the sera and on BPA secretion by peripheral mononuclear cells in patients with chronic renal failure]

The effect of erythroid differentiation factor (EDF) on the colony formation of erythroid cells (CFU-E and BFU-E) inhibited by the sera from the patients with chronic renal failure (CRF) was evaluated by methylcellulose assay. EDF restored the inhibited formation of CFU-E colony irrespective of the absence or presence of the accessory cells. In addition, EDF was considered to recover BFU-E colony formation through the burst promoting activity (BPA) secreted by the adherent cells. A suicide experiment using 3H-thymidine revealed that EDF acted to induce BFU-E from resting phase to S phase of the cell cycle. Moreover, the number of circulating BFU-E and the secretion of BPA by the mononuclear cells, both of which were significantly low in CRF patients, were also moderately increased by the addition of EDF. These data suggest that EDF could be utilized as a therapeutic agent for pathogenetic factors except hypoproduction of erythropoietin on the anemia of the patients with CRF.     

Congenital dyserythropoietic anaemia type II (CDA-II): chromosomal banding studies and adherent cell effects on erythroid colony (CFU-E) and burst (BFU-E) formation

Bone marrow CFU-E and BFU-E from a patient with CDA-II formed erythroid colonies and bursts which contained multinucleated erythroblasts in vitro . Adherent cell depletion of the patient's marrow increased CFU-E derived colonies six-fold (98 ± 17 v. 640 ± 15 per 10⁵ marrow cells plated) and co-culture of CDA-II marrow adherent cells with CDA-II adherent cell depleted marrow significantly suppressed erythroid colony formation. Similar adherent cell suppression of the patient's BFU-E also occurred. Adherent cell depletion of normal marrow did not increase CFU-E derived colony formation (488 ± 63 v. 495 ± 108) and decreased BFU-E derived burst formation. Addition of normal adherent cells to normal marrow increased erythroid colony and burst formation. Karyotype and chromosomal banding studies of the patient's multinucleated cells did not show chromosomal inversions, deletions or translocations.     

The regulatory role of interleukin 2-responsive T lymphocytes on early and mature erythroid progenitor proliferation

To analyze the role of T lymphocytes in human erythropoiesis, we evaluated the effect of recombinant interleukin 2 (IL 2) on marrow CFU- E and BFU-E colony formation in vitro. IL 2 resulted in an increase in CFU-E and BFU-E colony numbers in a dose-dependent manner. This increase could be prevented by anti-Tac, a monoclonal antibody to the IL 2 receptor. Moreover, anti-Tac on its own resulted in an overall decrease in colony numbers. Depletion of marrow adherent cells did not alter the effect of either IL 2 or anti-Tac on colony growth. Following the removal of marrow T lymphocytes, CFU-E and BFU-E colony formation proceeded normally; however, the effects of IL 2 and anti-Tac were markedly diminished. Readdition of T lymphocytes to the cultures restored the IL 2 effect. Although T lymphocytes were not themselves essential for in vitro erythropoiesis, our studies suggest that IL 2 and IL 2-responsive T cells can regulate both early and mature stages of erythroid differentiation.     

Factor with erythroid burst-promoting activity in human urine unlike other hematopoietic growth factors.

A factor with burst-promoting activity (BPA) stimulates the formation of erythroid bursts in the presence of erythropoietin, acting on early erythroid progenitor cells (erythroid burst-forming units, or BFU-E). Here we investigated the biological properties of this factor partially purified from the urine of anemic patients. The human urinary factor did not cause the formation of late erythroid progenitor cells (erythroid colony-forming units, or CFU-E) or enhance such colony formation in the presence of erythropoietin. Thus, the urinary factor was a different substance from erythroid potentiating activity and from activin, which act on both BFU-E and CFU-E. The urinary factor promoted the colony formation of BFU-E from both humans and mice, but the human hematopoietic growth factors such as recombinant interleukin-3, interleukin-6, granulocyte-macrophage colony-stimulating factor, and macrophage colony-stimulating factor did not stimulate the formation of BFU-E derived colonies from mice. The results suggested that the factor in the urine of anemic patients was different from the hematopoietic growth factors identified so far.     

Appearance of adherent cells suppressive to erythropoiesis during an early stage of Plasmodium berghei infection in mice.

We examined the effect of adherent cells from bone marrow or spleen of mice infected with Plasmodium berghei on dyserythropoiesis. Significant reduction in number of erythroid progenitors (erythroid colony-forming units: CFU-E and erythroid burst-forming units: BFU-E) was observed in bone marrow as early as 1 day after P. berghei infection. When adherent cells were removed from bone marrow or spleen cells of infected mice, the number of CFU-E and BFU-E was clearly increased. Furthermore, addition of adherent cells from infected mice to nonadherent cells from normal mice inhibited erythroid colony formation significantly in a dose-dependent manner. These results suggest that the adherent cells obtained from bone marrow or spleen of mice in the early stage of P. berghei-infection have a suppressive effect on erythropoiesis.     

Expression of latent hematopoietic progenitor cells in cultures of newborn and adult baboon liver

The anatomic site of hematopoiesis changes during fetal development from the yolk sac to the liver and finally to the marrow. Factors controlling this switch in the site of hematopoiesis are unknown. We assayed erythroid colony (CFU-E) and erythroid burst (BFU-E) formation in fetal, newborn, and adult baboon liver and marrow to determine the growth requirements of primate hematopoietic progenitor cells from different anatomic sites and developmental stages. We cocultured fetal, newborn, and adult liver and marrow nonadherent cells with adherent cells from these organs to assess the role adherent cells may play in determining the site of hematopoiesis. Fetal liver, fetal marrow, newborn marrow, and adult marrow cultures formed CFU-E and BFU-E colonies in vitro. In contrast, newborn and adult liver cell cultures very rarely formed colonies. However, when newborn or adult liver nonadherent cells were cocultured with marrow adherent cells, CFU-E and BFU-E colonies were detected. The colonies that formed in the newborn and adult liver cultures were derived from the liver and not from the marrow cells or peripheral blood trapped in the liver. These data suggest that in contrast to fetal liver, newborn and adult liver may not be hematopoietic organs in normal primates in vivo because of changes in the growth requirements of hematopoietic progenitor cells present in these organs.     

Dual role of fibronectin in hematopoietic differentiation

The adhesive glycoprotein fibronectin provides anchorage for fibroblasts and hematopoietic progenitor cells in vitro. Fibronectin also demonstrates growth factor activity for fibroblasts; however, there is no available information regarding its role as a hematopoietic growth factor. To distinguish growth factor activity of fibronectin from its anchorage activity for hematopoietic progenitors, we assessed the ability of purified human plasma fibronectin to promote human bone marrow erythroid, granulocyte-macrophage (GM) and mixed granulocyte- erythroid-macrophage-megakaryocyte (GEMM) colony formation in liquid suspension, methylcellulose, and fibrin clots under serum-free conditions. Addition of fibronectin to methylcellulose cultures, or to cultures formed in fibrin clots, using fibrinogen depleted of fibronectin by preadsorption over gelatin-Sepharose and clotted with thrombin, resulted in up to a twofold enhancement of proliferation of erythroid burst-forming units (BFU-E), erythroid colony-forming units (CFU-E), and CFU-GEMM. This effect was concentration-dependent up to a fibronectin supplement of 100 micrograms/mL. By contrast, CFU-GM proliferation was not affected by the addition of fibronectin to the cultures. Fibronectin-adherent marrow cells overlaid with liquid medium formed both early and late-appearing erythroid colonies, whereas similarly cultured plastic-adherent marrow cells did not. Erythroid colony formation was observed in cultures of fibronectin-adherent marrow cells overlaid with methylcellulose but not in cultures of plastic-adherent marrow cells under the same conditions. Finally, the erythroid growth-promoting activity of fibronectin was inhibited by arginyl-glycyl-aspartyl-serine (RGDS), a tetrapeptide that competitively blocks the interaction of fibronectin with its receptor. We conclude that fibronectin plays a dual role in hematopoiesis: providing (a) anchorage for erythroid and primitive progenitors, and (b) as a proliferative stimulus for these hematopoietic cells. Both activities may be mediated by the cell adhesion domain of the molecule.     

Human interleukin (IL)-9 specifically stimulates proliferation of CD34+++DR+CD33- erythroid progenitors in normal human bone marrow in the absence of serum.

The cDNA encoding human interleukin (IL)-9 has recently been cloned and the recombinant molecule found to enhance erythroid colony formation in vitro by bone marrow, peripheral blood, and cord blood cells. In our present report, recombinant human (rhu) IL-9 was evaluated, alone and in combination with other cytokines, for its effect on colony formation by erythroid progenitor (erythroid burst-forming units, BFU-E) and precursor (erythroid colony-forming units, CFU-E) cells in low density (LD), nonadherent LD density T-lymphocyte-depleted (NALT-), and immunofluorescence-sorted CD34+++DR+ and CD34+++DR+CD33- cells from normal human bone marrow. When highly enriched CD34+++DR+ and CD34+++DR+CD33- cells were plated at 200 and 100 cells/ml in the presence of 5% (vol/vol) 5637-cell-conditioned medium and erythropoietin (Epo) under serum-containing conditions, 46 and 51 day-14 BFU-E were observed, respectively. The enhancing effect of rhuIL-9 was similar to that of 5637 CM on colony formation by Epo-dependent BFU-E and CFU-E in these enriched sorted CD34+++DR+ and CD34+++DR+CD33- cells under serum-containing and serum-depleted culture conditions. No significant synergistic or additive effect of rhuIL-9 was noted when used in conjunction with rhu interleukin 3 (rhuIL-3), rhu interleukin 6 (rhuIL-6), and/or rhu granulocyte-macrophage colony-stimulating factor (rhuGM-CSF) under the same culture conditions. The cloning enhancing effect elicited by human IL-9 is Epo dependent, although IL-9 alone sustains the survival of erythroid progenitor cells in vitro, as assessed by delayed additions of Epo to the cultures. The ability of human IL-9 to stimulate BFU-E and CFU-E colony formation using low numbers of highly enriched progenitor cells in serum-depleted conditions demonstrates the direct effect of IL-9 on erythroid progenitors and implicates its potential role in the enhancement of erythropoiesis.     

Tumor necrosis factor-alpha and hematopoietic progenitors: effects of tumor necrosis factor on the growth of erythroid progenitors CFU-E and BFU-E and the hematopoietic cell lines K562, HL60, and HEL cells

Macrophages can modulate the growth of hematopoietic progenitors. We have examined the effects of tumor necrosis factor-alpha, a product of activated macrophages, on human erythroid progenitors (CFU-E, BFU-E) and the hematopoietic cell lines K562, HL60, and HEL cells. Tumor necrosis factor (TNF) significantly inhibited CFU-E and BFU-E growth at concentrations as low as 10(-11)-10(-12) M (0.2 U/ml), although erythroid colony and burst formation were not totally ablated. Preincubation of marrow samples with TNF for 15 min was sufficient to suppress erythroid colony and burst formation. Addition of TNF after the start of culture inhibited CFU-E- and BFU-E-derived colony formation if TNF was added within the first 48 h of culture. Additionally, TNF inhibited the growth of highly purified erythroid progenitors harvested from day 5 BFU-E. The colonies which formed in cultures treated with TNF were significantly smaller than those formed in control cultures. TNF (10(-8)-10(-10) M) also suppressed the growth of the hematopoietic cell lines K562, HL60, and HEL cells, with 40%-60% of the cells being sensitive to TNF. Preincubation of HL60 cells with TNF for 15 min significantly inhibited their growth. K562, HL60, and HEL cells expressed high-affinity receptors for TNF in low numbers (6000-10,000 receptors per cell). Fluorescence-activated cell sorter analysis of TNF binding to HEL cells demonstrated that the majority of these cells expressed TNF receptors. These data suggest that: (1) TNF is a rapid irreversible and extremely potent inhibitor of CFU-E, BFU-E, and hematopoietic cell lines K562, HL60, and HEL cells; (2) TNF appears to be acting on a subpopulation of erythroid cells, predominantly CFU-E, BFU-E, and possibly proerythroblasts; (3) TNF appears not to require accessory cells such as lymphocytes or macrophages to inhibit erythroid progenitors; and (4) the presence of TNF receptors on hematopoietic cells is not sufficient to confer sensitivity to TNF since the majority (80%-95%) of HEL cells express TNF receptors while only 40%-60% are inhibited by TNF.     

Suppression of normal human erythropoiesis by human recombinant DNA-produced alpha-2-interferon in vitro

Interferons (IFN) have been shown to suppress the proliferation of human erythroid progenitors (BFU-E, CFU-E) in vitro. We have previously demonstrated that the inhibition of erythroid colony formation by gamma-IFN in vitro is mediated, in part, through the activation of monocytes and T-lymphocytes. In order to examine the mechanism(s) underlying the inhibitory action of one type of recombinant alpha-IFN (alpha-2-IFN) on erythropoiesis, the effect of different doses (80-10,000 U) of alpha-2-IFN on erythroid colony formation by normal human bone marrow cells in the presence or absence of monocytes and/or T cells was studied. The addition of alpha-2-IFN to whole marrow caused the suppression of BFU-E (10%-68%) and CFU-E (5%-75%) in a dose-dependent fashion. This inhibition occurred with the direct addition of alpha-2-IFN to culture plates but not with brief preincubation of marrow cells with alpha-2-IFN followed by washing of the cells. By contrast, brief exposure of marrow cells to gamma-IFN resulted in significant suppression of erythroid colony formation. The inhibitory action of alpha-2-IFN was not influenced by erythropoietin. Removal of monocytes and/or T cells prior to the addition of alpha-2-IFN failed to significantly reduce the suppressive effects of this molecule (BFU-E: 21%-66%; CFU-E: 20%-83%). Coculture of purified monocytes or T-lymphocytes preexposed to alpha-2-IFN with autologous bone marrow cells did not cause suppression of erythropoiesis; monocytes or T cells similarly treated with gamma-IFN, however, inhibited autologous BFU-E and CFU-E in vitro. These results demonstrate that, unlike gamma-IFN, the inhibitory effect of alpha-2-IFN on erythroid colony formation in vitro is not mediated to any significant degree through monocytes and T-lymphocytes. The suppressive effect of alpha-2-IFN occurs either directly at the erythroid progenitor(s) level and/or through accessory cell(s) other than monocytes and T cells.     

Effects of recombinant human interferon gamma on hematopoietic progenitor cell growth

Human bone marrow BFU-E, CFU-E, and CFU-GM were cultured in the presence of varying concentrations of recombinant human interferon gamma (rHuIFN-gamma). Concentration-dependent inhibition of both erythroid and myeloid precursors by rHuIFN-gamma was demonstrated. A more pronounced suppressive effect of rHuIFN-gamma was seen on the BFU-E than on the CFU-E, with CFU-GM most resistant. rHuIFN-gamma was also added at varying time points during the marrow cultures, demonstrating different time-dependent sensitivities to rHuIFN-gamma; CFU-E were no longer sensitive to rHuIFN-gamma by day 2 of culture, BFU-E by day 6, and CFU-GM by day 9, indicating a loss of sensitivity with maturation. Finally, exposure of marrow cells to rHuIFN-gamma for varying periods of time prior to initiation of hematopoietic cultures failed to inhibit erythroid colony growth in the absence of rHuIFN-gamma in the culture. These studies demonstrate a suppressive effect of rHuIFN-gamma on human erythroid and myeloid progenitor cell growth. This effect appears to be most pronounced on the more primitive stages of committed progenitor cell development.     

Susceptibility of human erythropoietic cells to B19 parvovirus in vitro increases with differentiation

B19 human parvovirus is the etiologic agent of transient aplastic crisis. To better understand B19 virus-induced hematopoietic suppression, we studied the host cell range of the virus using in vitro bone marrow cultures. First, B19 virus replication was examined in the presence of various purified cytokines using DNA dot blot analysis. Replication was detected only in erythropoietin-containing cultures. The other cytokines (granulocyte/macrophage colony-stimulating factor [GM-CSF], G-CSF, M-CSF, interleukin-1 [IL-1], IL-2, IL-3, and IL-6) did not support virus replication, indicating the restriction of B19 virus replication to the erythroid cell lineage. Second, hematopoietic progenitor cells were serially assayed in B19-infected and uninfected bone marrow cultures. At initiation, B19 virus infection caused marked and moderate reduction in colony-forming unit erythroid (CFU-E) and burst-forming unit erythroid (BFU-E) numbers, respectively, without affecting CFU-Mix and CFU-GM numbers. Interestingly, the recovery of the erythroid progenitor numbers was observed at a late stage of cultures despite the sustained reduction in erythroblasts. The cells in the bursts derived from such reappearing BFU-E did not contain the virus genome. Although infectious virus was detected in the culture supernatants, the cultured CFU-E harvested at day 5 was relatively resistant to B19 virus infection compared with the CFU-E in fresh bone marrow. These findings suggest that pluripotent stem cells escaped B19 virus infection and restored the erythroid progenitor cells later in infected cultures. We conclude that the target cells of B19 virus are in the erythroid lineage from BFU-E to erythroblasts, with susceptibility to the virus increasing along with differentiation. Furthermore, the suppression of erythropoiesis and the subsequent recovery of the erythroid progenitor numbers in B19-infected liquid cultures may be analogous in part to the clinical features of B19 virus-induced transient aplastic crisis.     

Enhanced colony formation of human hemopoietic stem cells in reduced oxygen tension

In general, cell cultures, including hemopoietic stem cells, are produced in an atmosphere of various CO2 concentrations in air, although most cells in vivo proliferate and differentiate at lower oxygen tensions. We therefore investigated the effect of reduced oxygen tension on the in vitro colony growth of committed and multipotential hemopoietic progenitor cells from human bone marrow. All hemopoietic progenitor cells (CFU-mix, BFU-E, CFU-E, and CFU-GM) investigated showed enhanced colony growth at lower oxygen tension. CFU-E showed the highest enhancement, followed in order by BFU-E, CFU-mix and CFU-GM. At reduced oxygen tension, the sensitivity of early and late erythroid progenitor cells to erythropoietin was significantly increased, and this can be one of the mechanisms for the enhanced colony growth of erythroid progenitors. In the colony growth of CFU-GM, plating efficiency was also enhanced by the predominant increment of neutrophilic colonies. The lowering of oxygen tension would presumably reduce oxygen toxicity and result in the increased colony growth of human bone marrow stem cells, although the precise mechanisms of oxygen toxicity at the level of hemopoietic stem cells have yet to be elucidated. However, this clonal culture system, using a low oxygen tension, can be a useful means for elucidating the regulatory mechanisms involved in the proliferation and differentiation of hemopoietic progenitor cells in physiological and pathological conditions.     

Effect of murine mast cell growth factor (c-kit proto-oncogene ligand) on colony formation by human marrow hematopoietic progenitor cells.

Purified natural (n) and recombinant (r) murine (mu) mast cell growth factor (MGF, a c-kit ligand) were evaluated alone and in combination with r human (hu) erythropoietin (Epo), rhu granulocyte-macrophage colony-stimulating factor (rhuGM-CSF), rhuG-CSF, and/or rhuM-CSF for effects in vitro on colony formation by multipotential (colony-forming unit-granulocyte, erythroid, monocyte, megakaryocyte [CFU-GEMM]), erythroid (burst-forming unit erythroid [BFU-E]) and granulocyte-macrophage (CFU-GM) progenitor cells from normal human bone marrow. MGF was a potent enhancing cytokine for Epo-dependent CFU-GEMM and BFU-E colony formation, stimulating more colonies and of a larger size than either rhu interleukin-3 (rhuIL-3) or rhuGM-CSF. MGF, especially at lower concentrations, also acted with rhuIL-3 or rhuGM-CSF to enhance Epo-dependent CFU-GEMM and BFU-E colony formation. MGF had little stimulating activity for CFU-GM colonies by itself, but in combination with suboptimal to optimal amounts of rhuGM-CSF enhanced the numbers and the size of CFU-GM colonies in an additive to greater than additive manner. While we did not detect an effect of MGF on CFU-G colony numbers stimulated by maximal concentrations of rhuG-CSF, MGF did enhance the size of CFU-G-derived colonies. MGF did not enhance the activity of rhuM-CSF. In a comparative assay, maximal concentrations of rmu and rhuMGF were equally effective in the enhancement of human bone marrow colony formation, but rhuMGF, in contrast to rmuMGF, did not at the concentrations tested enhance colony formation by mouse bone marrow cells. MGF effects on BFU-E, CFU-GM, and CFU-GEMM may be direct acting ones as MGF-enhanced colony formation by these cells in highly enriched progenitor cell populations of CD34 HLA-DR+ and CD34 HLA-DR+CD33- sorted cells in which greater than or equal to 1 of 2 cells was a BFU-E plus CFU-GM plus CFU-GEMM. MGF appears to be an early acting cytokine that preferentially stimulates the growth of immature hematopoietic progenitor cells.     

The relationship of hemoglobin synthesis to erythroid colony and burst formation.

We have demonstrated that the cyclohexanone method for the extraction of hematin can be used to measure hemoglobin synthesis induced by erythropoietin (epo) in mouse bone marrow cells cultured in medium containing methyl cellulose. The time course of hemoglobin synthesis by mouse marrow cells showed two effects due to epo: an increase in hemoglobin synthesis at day 2, which corresponded to the formation of small erythroid colonies resulting from the CFU-E (colony-forming unit, erythroid), and a very large increase in hemoglobin synthesis, which was maximal at days 7-8 and corresponded to the formation of large erythroid colonies (bursts) resulting from the BFU-E (burst-forming unit, erythroid). The epo dose-response curves for CFU-E colony counts and day-2 hemoglobin synthesis were similar, and the cell-number-response curves for these two paramaters were parallel. The epo dose-response curve for BFU-E colony counts reached a plateau at an epo concentration between 3 and 5 units/ml, whereas the dose-response curve for 6-8-day hemoglobin synthesis did not reach a plateau even at an epo dose of 10 units/ml.     

The effect of estrogens on erythroid stem cells in polycythemic mice

Plethoric mice treated with pharmacological doses of estradiol have decreased concentration of erythropoietin-responsive cells (ERC) in the marrow. We used the methylcellulose-culture system for growth of erythroid stem cells (CFU-E and BFU-E) to define more accurately these estrogen-induced changes. As an animal model we utilized plethoric mice given repeated injections of estradiol cypionate and found that at 14 days after the onset of treatment there was no significant change in the concentration of femoral CFU-E whereas there was a significant decrease of the BFU-E content. Both CFU-E and BFU-E increased progressively in the spleen over a 42-day period. Addition of estradiol directly to the cell-culture system showed no effect on CFU-E growth but induced a significant depression of BFU-E growth. This depression seemed to require the presence of adherent cells. It is our hypothesis that estrogens suppress only the early stages of erythroid proliferation and/or differentiation by a mechanism involving possibly the stromal (adherent) cells of the marrow microenvironment.     

Loss of suppression of normal bone marrow colony formation by leukemic cell lines after differentiation is induced by chemical agents

The human leukemic cell lines K562 and HL-60 were cocultured with normal bone marrow (BM) cells. Coculture with 10(4) K562 or HL-60 cells results in 50% inhibition of normal CFU-E and BFU-E colony formation. However, when the same number of K562 and HL-60 cells is first treated for two to five days with agents that induce their differentiation, a gradual loss in their capacity to inhibit CFU-E and BFU-E colony formation is observed. The inhibitory material in K562 cells is soluble and present in conditioned medium from cultures of these cells. The degree to which leukemic cell suppression of CFU-E and BFU-E growth is reversed is correlated with the time of exposure to the inducing agent. Suppression is no longer evident after five days of prior treatment with inducers. In fact, up to a 90% stimulation of CFU-E growth is observed in cocultures with K562 cells that have been pretreated with 30 to 70 mumol/L hemin for five days. K562 cells treated with concentrations of hemin as low as 30 mumol/L demonstrate increased hemoglobin synthesis and grow normally, but no longer have an inhibitory effect on CFU-E growth. Hence, reversal of normal BM growth inhibition must be caused by the more differentiated state of the K562 cells and not by a decrease in the number of these cells with treatment. Thus, induction of differentiation in cultured leukemic cells not only alters the malignant cell phenotype but also permits improved growth of accompanying normal marrow progenitor cells. Both are desired effects of chemotherapy.     

Characterization of the potentiation effect of activin on human erythroid colony formation in vitro

Activin, also named FSH-releasing protein, was previously shown to induce hemoglobin accumulation in K562 cells and potentiate the proliferation and differentiation of CFU-E in human bone marrow cultures. Present studies indicate that the potentiation effect of activin is lineage specific. In addition to CFU-E, activin caused an increase in the colony formation of BFU-E from either bone marrow or peripheral blood. It had little effect on the colony formation of CFU- GM and the mixed colonies from CFU-GEMM. In serum-depleted culture, the effect of activin was shown to be dose-dependent with doses effective at picomolar concentrations. The potentiation effect of activin was exerted indirectly through mediation of both monocytes and T lymphocytes. Activin was also found to increase specifically the proportion of DNA-synthesizing erythroid progenitors from both bone marrow and peripheral blood. It had little effect on DNA synthesis in CFU-GM and in mitogen-stimulated lymphocytes. Addition of the monocytes or T lymphocytes to their respective depleted subpopulations of mononuclear cells reconstituted the enhancing effect of activin on the colony formation and DNA synthesis of erythroid progenitors. These results strongly suggest a specific role of activin in potentiating the proliferation and differentiation of erythroid progenitors in vitro.     

Effects of dexamethasone on erythroid colony and burst formation from human fetal liver and adult marrow

S ummary . Dexamethasone, a prototypic synthetic glucocorticoid, was added to cultures of human fetal liver and adult marrow cells to assess its effects on erythroid colony and burst formation. Dexamethasone decreased the number of fetal liver erythroid colonies and bursts formed in the presence of erythropoietin, and also decreased the number of cells per colony. The amount and type of haemoglobin produced per cell were unaffected by adding dexamethasone to the cultures. Dexamethasone inhibited the incorporation of ³H-thymidine into DNA in fetal liver cells stimulated with erythropoietin, supporting the hypothesis that dexamethasone inhibits the proliferation but not the differentiation of fetal liver CFU-E and BFU-E. In contrast, addition of dexamethasone to adult bone marrow cultures had a variable effect on erythroid colony and burst formation.     

Interleukin-4 suppresses the interleukin-3 dependent erythroid colony formation from normal human bone marrow cells

Human recombinant interleukin 4 (IL-4) was studied for its effects on the erythroid burst forming unit (BFU-E) from human bone marrow cells. IL-4 alone neither supports nor suppresses the erythropoietin (Epo)-dependent colony formation. Different results were obtained when IL-4 was combined with interleukin-3 (IL-3) in the presence of Epo. IL-4 suppressed the IL-3 supported erythroid colony formation in all cases (an increase of 58 +/- 8% with IL-3 versus an increase of 14 +/- 7% with IL-3 plus IL-4, n = 8). This antagonizing effect was dependent on the continuous presence of IL-4 in the culture medium, but was independent of adherent cells, B-, T-cells, or the presence of serum in the culture medium. Finally, the effects of IL-4 and IL-3 were studied on the 'Epo-independent' BFU-E by adding Epo on day 3. A decline of the IL-3 supported BFU-E was observed in the presence of IL-4 but the degree of reduction was equivalent to the results obtained when Epo was supplied at day 0. These findings indicate that IL-4 acts as suppressive growth factor for the IL-3 supported erythroid colony formation from human bone marrow cells.