Factor-independent erythropoietic progenitor cells in leukemia induced by the myeloproliferative leukemia virus

The myeloproliferative leukemia virus (MPLV), a novel murine retroviral complex that does not transform fibroblasts, has been shown to cause an acute leukemia in adult mice accompanied by a progressive polycythemia. The present study demonstrates that, on in vivo inoculation, MPLV induces a rapid suppression of growth factor requirement for in vitro colony formation by both the late and the primitive erythroid progenitor cells. CFU-e-derived erythrocytic colonies developed and differentiated in semi-solid medium without the addition of erythropoietin (Epo). In addition, the formation of CFU-e colonies was not altered by the presence of specific neutralizing Epo antibodies. In the spleen, the CFU-e pool size increased rapidly up to 30-fold. By day 6 postinfection, 100% of these progenitor cells were Epo-independent. The in vivo effects of MPLV-infection on early erythroid progenitor cell compartments were examined in cultures grown for seven days. The concentration of erythroid progenitor cells was twofold elevated in spleen from MPLV-infected mice. As early as day 4 postinfection, 50% of these progenitors produced fully hemoglobinized colonies in serum-free cultures without the addition of interleukin-3 (IL-3) and Epo. Most spontaneous colonies were large and contained up to 10(5) cells per colony. They were composed of either erythroblasts only (16%) or erythroblasts and megakaryocytes (70%); few of them were multipotential (14%). In the marrow, the total number of BFU-e was reduced and only few factor-independent bursts were observed, suggesting a rapid migration of infected progenitors from marrow to spleen. Furthermore, the data show that abnormal erythropoiesis was due to the replication defective MPLV information and was not influenced by the Fv-2 locus.     

Erythropoiesis in vitro. III. The role of potassium ions in erythroid colony formation.

The role of potassium as an essential promotor of erythroid progenitor growth (BFU-e & CFU-e) from normal murine hematopoietic tissues was studied. Dialyzed fetal calf serum, over a wide range of concentrations, was shown to reduce the numbers of BFU-e and CFU-e that could be cultured from normal murine bone marrow. A dose-dependent addition of 1 M KC1 restored erythroid progenitor colony growth to the levels generally seen when normal, non-dialyzed fetal calf serum was used. Furthermore, when [K] was increased in some human urinary and sheep plasma erythropoietin preparations, the number of erythroid progenitor cells cultured also increased. This influence is crucial to the differentiation of committed stem cells into the erythroid pathway and must therefore be considered in the development of serum-free growth media.     

In vivo erythropoietin requirements of regenerating erythroid progenitors (BFU-e, CFU-e) in bone marrow of mice.

Erythroid progenitors (B-8, B-4, CFU-e) in the femoral marrow of polycythemic mice were measured by in vitro culture assays after a single administration of BCNU or Myleran. BCNU reduced pluripotent stem cells to 40% and erythroid progenitors to less than 5% of normal. B-8, the earliest erythroid progenitors, regenerated without erythropoietin (Epo) completely within 5 days. At 14 days after BCNU, intermediate progenitors (B-4) attained 60% of their normal numbers and CFU-e attained approximately 30%. Daily injections of Epo promptly restored normal B-4 numbers and near-normal CFU-e numbers in BCNU-treated mice. After Myleran, CFU-s remained below 2% of normal for 14 days, and no regeneration of the B-8 occurred with or without daily Epo injections. The findings suggest that regneration of B-8 was dependent on cell inflow from the pluripotent stem cell compartment but was independent of the presence of Epo. Intermediate progenitors (B-4) required Epo and the presence of B-8 for complete and permanent regeneration. CFU-e were the most Epo-dependent of the three progenitors. B-4, recruited by Epo, required after their formation a second exposure to the hormone in order to progress into the CFU-e stage.     

Further studies on the in vitro enhancement of erythroid stem cell (CFU-e and BFU-e) colony formation by ouabain

The cardiac glycoside ouabain has been shown to stimulate erythroid stem cell (CFU-e/BFU-e) colony formation while inhibiting both granulocyte/macrophage precursor cell (CFU-gm) and murine spleen stem cell (CFU-s) colony formation. We have examined the ability of ouabain to increase both CFU-e/BFU-e colony formation by performing time-delay and temperature-dependent studies. After pre-exposure of marrow cells to ouabain (10(-15) M) at temperatures of 27, 37, or 4 degrees C, erythropoietin (Ep) was added after time-delays ranging from 10 s to 60 min. The ouabain-induced increase in CFU-e/BFU-e colony formation was observed up to an Ep-delay of 20 s, after which time the enhancing effect of ouabain was diminished. This increase was also observed when marrow cells were first exposed to Ep prior to a similar delayed exposure to ouabain. The enhancement effect seen with ouabain was also temperature dependent, since at 37 degrees C an earlier time increase in CFU-e/BFU-e colony formation was observed when compared to identical studies performed at either room temperature or 4 degrees C. These studies suggest that ouabain-induced elevations in erythroid stem cell colony formation involve mechanisms that are both time and temperature dependent.     

Erythroid progenitor cell kinetics in chronic haemodialysis patients responding to treatment with recombinant human erythropoietin

The response of bone marrow and peripheral blood erythroid progenitors to human recombinant erythropoietin (rHuEPO) was studied in nine haemodialysed renal failure patients receiving this hormone for the correction of their anaemia. The haematocrit rose in all patients in response to thrice weekly injections of escalating rHuEPO doses (12-192 IU/kg). Both the numbers of CUF-e and BFU-e and their proliferative state in the bone marrow as well as BFU-e numbers in the peripheral blood were estimated before treatment and again after correction of the anaemia, at 16 h following an intravenous dose of rHuEPO. Following treatment bone marrow BFU-e numbers fell to a mean of 24.5% (P less than 0.01) of the pre-treatment values although there was no significant change in CFU-e or circulating BFU-e numbers. The mitotic rate (percentage S-phase cells) estimated by tritiated thymidine suicide rose from 45.2% to 68.4% (P less than 0.05) in the case of CFU-e and from 16.4% to 45.1% (P less than 0.05) for BFU-e following treatment with rHuEPO thus indicating in-vivo sensitivity of both the primitive as well as the mature erythroid progenitors to the hormone. The fall in BFU-e numbers in the bone marrow after several months of treatment may be due to a loss of cells from this progenitor pool by maturation that is uncompensated by replacement from the pluripotential stem cell compartment.     

Stromal cell-associated erythropoiesis

A novel cover slip-transfer culture system was designed to study the functional roles of stromal cells in hemopoiesis, particularly erythropoiesis. Human bone marrow stromal cell colonies were allowed to develop on small glass cover slips in liquid medium. The cover slips, along with the stromal cell colonies and progenitors attached to them were then transferred to a new tissue culture dish and overlaid with methylcellulose culture medium. No exogenous colony-stimulating factors except erythropoietin were supplied. Large erythroid bursts, comprising multiple subcolonies, developed on the stromal cells. In order to determine if stromal fibroblasts together with erythropoietin and serum proteins could support erythroid development, human bone marrow cells depleted of monocytes, macrophages, and T lymphocytes were allowed to adhere to monolayers of a homogeneous fibroblastoid human stromal cell strain ST-1 grown on cover slips. The cover slips were then washed to remove nonadherent cells, transferred to a new culture dish, and overlaid with methylcellulose culture medium containing fetal calf serum and erythropoietin. In this modified system as well, primitive erythroid progenitors migrated extensively on and within the stroma to form huge colonies of hemoglobinized erythroblasts that proceeded to enucleate. Our results indicate that (1) ST-1 cells together with serum proteins and erythropoietin can support the development of large erythroid bursts; (2) erythroid progenitors and precursors adhere to and migrate on and within the extracellular matrix elaborated by ST-1 cells; (3) erythroid progenitors are more adherent to the ST-1 cells or the extracellular matrix than are the more mature cells and possibly the myeloid progenitors.     

Effects of an aplastic anemia urinary extract on mouse erythroid progenitor cells in vivo

We investigated the in vivo effects of a crude extract from the urine of aplastic anemia patients (AA urinary extract) on erythroid precursor cells in the femoral bone marrow and spleens of normal adult mice. A single intraperitoneal injection of AA urinary extract induced a significant increase in the number of splenic erythroid burst-forming units (BFU-e) and erythroid colony-forming units (CFU-e) within 24 h after injection. We then injected pure recombinant erythropoietin (Epo) equivalent to the amount present in the urinary extract. This addition increased the number of splenic CFU-e by almost the same degree as the amount induced by the AA urinary extract 24 h after injection, but failed to elicit any change in the number of splenic BFU-e. In other studies, mice were injected with the same amount of lipopolysaccharide (LPS) and/or pure Epo as that present in the AA urinary extract. Experiments with Limulus amebocyte lysate-adsorbed (endotoxin-depleted) or nonadsorbed (endotoxin-containing) AA urinary extracts showed that endotoxin contamination interfered with the increase in numbers of marrow CFU-e and enhanced the increase in splenic CFU-e numbers induced by pure Epo or Epo activity in the AA urinary extract. The number of splenic BFU-e, however, was not affected by administration of LPS and/or Epo or by adsorbed endotoxin. These data suggest that AA urinary extract contains a stimulating activity for mouse splenic BFU-e, and that this activity is not attributable to the Epo activity or endotoxin contamination within the urinary extract.     

Apoptosis and polycythemia vera

Polycythemia vera is an acquired clonal myeloproliferative disorder characterized by increased numbers of erythroid cells, often with a concomitant rise in neutrophils and/or megakaryocytes. Normally, erythropoietin is essential for the survival and proliferation of erythroid progenitors; however in polycythemia vera the erythroid progenitor cells can survive and develop in the absence of erythropoietin. Members of the Bcl-2 family of apoptosis regulators have been shown to mediate the erythropoietin-dependent survival of erythroid cells. In this article, recent advances in understanding the mechanisms used by erythroid progenitors from patients with polycythemia vera to control apoptosis, are discussed.     

Heterogeneity of erythropoietin-dependent erythrocytosis: case report in a child and synopsis of primary erythrocytosis syndromes

To investigate the pathogenesis of polycythaemia in a child with isolated, primary erythrocytosis, we measured serum erythropoietin activity and in vitro erythroid progenitor cell responsiveness to erythropoietin. Unstimulated erythropoietin activity was markedly elevated (1.8 IU/ml), and isovolaemic phlebotomy induced a four-fold increment above this level. In contrast to findings in our index case with this syndrome, normal erythroid colony growth patterns were present in patient marrow cultures. The primary mechanism of polycythaemia in this individual is similar to that reported in the index case: an inappropriately elevated regulatory set point for erythropoietin production. Since an additional defect of progenitor cell hypersensitivity to erythropoietin is not always present, we conclude that abnormalities at single or multiple sites of the erythropoietic regulatory axis may occur in primary erythropoietin-dependent erythrocytosis.     

Contamination of erythropoietin by endotoxin: in vivo and in vitro effects on murine erythropoiesis.

Endotoxin was detected in all erythropoietin preparations tested and was removed from four lots, without loss of erythropoietic activity, by adsorption with limulus amebocyte lysate. Comparison of adsorbed (endotoxin-depleted) and nonadsorbed (endotoxin-containing) erythropoietin preparations demonstrated significant inhibition of CFU-e and BFU-e in vitro by nonadsorbed erythropoietin at concentrations higher than 0.25 U/ml and 2.0 U/ml, respectively. CFU-e and BFU-e were inhibited significantly by readdition in vitro of 10(-5)-10(-3) mug of endotoxin per unit of limulus-adsorbed erythropoietin. Administration of saline or 6 U of nonadsorbed or adsorbed erythropoietin twice a day for 4 days of CF1 mice resulted in reticulocyte counts of 2.1%, 9.9%, and 15.9%, respectively. Nonadsorbed erythropoietin resulted in a 29% decrease in erythropoiesis, a 42% decrease in CFU-e, and a 16% increase in granulopoiesis in the marrow, whereas adsorbed erythropoietin caused a 28% increase in erythropoiesis, no significant change in CFU-e and a 19% decrease in granulopoiesis in the marrow. Both preparations resulted in marked increases in splenic erythropoiesis and granulopoiesis. The effects of adsorbed erythropoietin are similar to those produced following stimulation of hematopoiesis by endogenous erythropoietin. Hemopoietic changes induced by nonadsorbed erythropoietin in vivo and in vitro are affected substantially by contamination of the erythropoietin preparations with endotoxin.     

Temporal response of murine pluripotent stem cells and myeloid and erythroid progenitor cells to low-dose glucan treatment

B6D2F1 female mice were intravenously administered 0.4 mg of glucan. 1, 5, 11, and 17 days later, the total nucleated cellularity (TNC) and the numbers of pluripotent hemopoietic stem cells (CFU-s), granulocyte-macrophage progenitor cells (GM-CFC), and erythroid colony-forming (CFU-e) and burst-forming (BFU-e) cells were assayed in the bone marrow and spleen. Bone marrow TNC was not altered, but splenic TNC increased approximately twofold on day 5 and remained increased on days 11 and 17 after glucan treatment. The concentrations of bone marrow and splenic CFU-s and GM-CFC both significantly increased (p less than 0.01) by 5 days after glucan administration; however, they returned to control levels by day 17. Splenic CFU-e concentration increased on days 5, 11, and 17, whereas splenic BFU-e concentration increased only on day 11 after treatment. By contrast, bone marrow CFU-e and BFU-e concentrations were either unaffected or slightly decreased by glucan treatment. When peripheral blood was assayed for CFU-s and GM-CFC, no detectable increase in the concentrations of these progenitors was noted at any time after glucan treatment. The relevance of these effects of low-dose (0.4 mg) glucan treatment is discussed with respect to previously reported effects of higher-dose (e.g., 4.0 mg) glucan treatment.     

Measurement of human serum erythropoietin by erythroid colony-forming technique using fetal mouse liver cells

A quantitative bioassay for serum erythropoietin in anemic patients was established with erythroid colony-forming technique using methyl cellulose. Fetal mouse liver contains many erythropoietin-dependent erythroid colony-forming cells (CFU-E) with the concentration as well as sensitivity to erythropoietin being the highest at 13–14 days of gestation. Linearity in the erythropoietin response curve for the number of colonies from CFU-E in fetal livers of 13–14 days gestation was obtained for erythropoietin concentrations in the culture medium of 3.9 to 125 mU/ml. When newborn liver cells were used instead, the linearity occurred at 31.2 to 250 mU/ml. Measurement of erythropoietin by the erythroid colony-forming technique for sera from patients with various anemias was compared with that of the assay method using radioiron incorporation into heme in the suspension culture of fetal mouse liver cells. There was a good correlation between the values of both assay methods (r = 0.856, p < 0.001). Also, levels of erythropoietin measured by this assay method showed the expected inverse relationship to the hemoglobin concentration in the sera from the patients.     

Use of cell separation and short-term culture techniques to study erythroid cell development.

Cell populations highly enriched for the different stages of erythroid cell maturation were obtained by three sequential operations: harvesting of erythroid cells after induction of erythroid hyperplasia in the spleens of mice, elimination of the more mature erythrocytes by immunologic techniques, and separation of the residual nucleated erythroid cells as a function of size by the velocity sedimentation technique. The resulting cell fractions were studied both directly and after overnight incubation in the presence or absence of erythropoietin. In short-term culture, erythropoietin stimulated proliferation of pronormoblasts and basophilic normoblasts but probably not cells at later stages of differentiation. Erythropoietin also appeared to recruit increased numbers of pronormoblasts. In this experimental system, erythroid cell differentiation was able to proceed in the absence of erythropoietin, but without proliferation of these early erythroid cells. These techniques have provided a model system for the study of erythroid cells at different stages of maturation isolated from a uniform source at one point in time. The morphologic observations indicated that erythropoietin stimulates erythroid cell proliferation at several early stages of the maturation pathway.     

Insulin stimulates erythroid colony formation independently of erythropoietin

Summary . The effect of insulin on the proliferation of late stage erythroid precursor cells (CFU-e) from fetal mouse liver and aduit bone marrow was studied in a serum-free culture system. Insulin in supraphysiological concentrations (> 10 ^?8m ) stimulated erythroid colony formation independently of Ep. The combined effect of Ep and insulin was smaller than the surn of their single effects. The number of colonies obtained with insulin was linearly related to the number of plated cells. These results suggest that insulin stimulates erythroid colony formation by a direct action on CFU-e.     

Changes of the phenotype of erythroid progenitor cells (BFU-E, CFU-E) and their progenies during early steps of differentiation

Early differentiation processes of human erythroid progenitor cells (BFU-e, CFU-e) have been studied during in vitro proliferation using a panel of monoclonal antibodies with known reactivity on different levels of the erythroid cell line. Two antibodies recognizing structures on BFU-e (VIP-2b, BMA 021), two antibodies reactive with CFU-e and nucleated red cells (5F1, CLB-Ery-3) and one antibody directed against glycophorin A (VIE-G4) were used for this study. Normal human bone marrow cells were induced to proliferation in an erythroid progenitor cell assay and, after different periods of incubation, agar cultures were treated with these antibodies and complement. Thereafter, the remaining erythroid cells were incubated again to continue their proliferation with the same stimulators as before. The changes of the phenotype of BFU-e and CFU-e progenies during in vitro proliferation were determined by the reduction of colony formation in comparison with untreated control cultures. Our results indicate that the loss of HLA-DR antigens and the p45 structure is accompanied by the acquisition of structures recognized by the antibodies 5F1 and CLB-Ery-3. After 5-7 d of incubation BFU-e derived progenies exhibit the same antigenic structure as has been found for CFU-e. Glycophorin A expression could only be demonstrated at a late differentiation stage of the erythroid cell lineage.     

CD4 Expression by erythroid precursor cells in human bone marrow

Flow cytometry was used to assess CD4 expression in 62 consecutive bone marrow specimens from patients with a variety of clinical conditions. Using a lysed-whole-blood technique for labeling with monoclonal antibodies, two populations of CD4+ cells were identified within the lymphocyte/blast-cell fraction in 58 (94%) of these specimens. These consisted of (1) a population of T helper cells with high density expression of CD4 and (2) a second population of cells with low-density expression of CD4, which ranged from 1% to 36% of the gated cells. This latter population was present regardless of age, sex, or clinical condition including 21 of 21 specimens (100%) categorized as unremarkable bone marrows both morphologically and by flow cytometry and in four of four patients (100%) with human immunodeficiency virus- type 1 (HIV-1) infection. Coexpression of the erythroid lineage marker, glycophorin A, with the majority of cells in this second population was demonstrated in all 11 randomly selected samples using two-color flow cytometric analysis. These cells also expressed low levels of the myeloid markers, CD13 and CD33, but CD34 expression could not be demonstrated. These results provide evidence for expression of CD4 on cells of erythroid lineage in human marrow, and offer a potential mechanism for direct infection of erythroid precursor cells and deranged erythropoiesis in patients with HIV-1 infection.     

Differential expression of receptors for interleukin-3 on subsets of CD34-expressing hematopoietic cells of rhesus monkeys

The target cell specificity of interleukin-3 (IL-3) was examined by flow cytometric analysis of IL-3 receptor (IL-3R) expression on rhesus monkey bone marrow (BM) cells using biotinylated IL-3. Only 2% to 5% of unfractionated cells stained specifically with the biotinylated IL-3 and most of these cells were present within the CD34+ subset. IL-3Rs were detected on small CD34dull/RhLA-DRbright/CD10+/CD27+/CD2-/++ +CD20- cells, which probably represent B-cell precursors. IL-3R+ CD34- BM cells, which were detected at low frequencies, consisted of small CD20dull/surface-IgM+/RhLA-DR+ cells. These cells represented immature B lymphocytes, whereas CD20bright mature B cells were IL-3R-. The highest IL-3R levels were detected on CD34dull/RhLA-DRbright blast-like cells. These cells differentiated into monocytes, neutrophils, and basophils after IL-3 and/or granulocyte-macrophage colony-stimulating factor (GM-CSF) stimulation in vitro. The CD34bright/IL-3R- subset contained all clonogenic erythroid and myeloid progenitors (burst- forming unit-erythroid and colony-forming unit-culture), whereas CD34bright/IL-3Rdull cells differentiated into monocytes, neutrophils, and erythroid cells after shorter culture periods. This finding showed that IL-3R expression increases during monocyte and granulocyte differentiation. Results of three-color experiments indicated that IL- 3Rs are expressed on CD34bright/RhLA-DRbright cells as well as on CD34bright/RhLA-DRdull cells, with the latter population expression approximately twofold to threefold lower IL-3R levels. A large fraction (> 30%) of single-cell/well-sorted CD34bright/RhLA-DRdull cells formed multilineage colonies after 2 to 4 weeks of stimulation with IL-3, GM- CSF, Kit ligand, and IL-6. Individual colonies contained cells that still expressed CD34 as well as differentiated monocytes, granulocytes, and erythroid cells. These results confirmed that the CD34bright/RhLA- DRdull subset was enriched for immature, multipotent progenitor cells, whereas the CD34bright/RhLA-DRbright population mainly contained lineage-committed precursors. The results are consistent with the concept that IL-3Rs are induced at very early stages of hematopoiesis, as identified by high expression of CD34 and low expression of RhLA-DR. IL-3R expression continues to be low during differentiation into lineage-committed progenitors; gradually increases on differentiating progenitor cells for B cells, granulocytes, monocytes, and, possibly also, erythrocytes; but finally declines to undetectable levels during terminal differentiation into mature cells of all lineages in peripheral blood, with the exception of basophils.(ABSTRACT TRUNCATED AT 400 WORDS)     

Natural killer cells suppress human erythroid stem cell proliferation in vitro

To determine the role of natural killer (NK) cells in the regulation of human erythropoiesis, we studied the effects of NK-enriched cell populations on the in vitro proliferation of erythroid stem cells at three different levels of maturation (day 14 blood BFU-E, day 5-6 marrow CFU-E, and day 10-12 marrow BFU-E). NK cells were enriched from blood by Percoll density gradient centrifugation and by fluorescence- activated cell sorting (FACS), using the human natural killer cell monoclonal antibody, HNK-1. The isolated enriched fractions were cocultured with autologous nonadherent marrow cells or blood null cells and erythropoietin in a methylcellulose erythroid culture system. Cells from low-density Percoll fractions (NK-enriched cells) were predominantly large granular lymphocytes with cytotoxic activity against K562 targets 6-10-fold greater than cells obtained from high- density Percoll fractions (NK-depleted cells). In coculture with marrow nonadherent cells (NA) at NK:NA ratios of 2:1, NK-enriched cells suppressed day 5-6 CFU-E to 62% (p less than 0.025) of controls, whereas NK-depleted cells slightly augmented CFU-E to 130% of controls (p greater than 0.05). In contrast, no suppression of day 10-12 marrow BFU-E was observed employing NK-enriched cells. The NK CFU-E suppressor effects were abolished by complement-mediated lysis of NK-enriched cells with the natural killer cell antibody, HNK-1. Highly purified HNK- 1+ cells separated by FACS suppressed marrow CFU-E to 34% (p less than 0.025) and marrow BFU-E to 41% (p less than 0.025) of controls. HNK- cells had no significant effect on either BFU-E or CFU-E growth. NK- enriched cells were poor stimulators of day 14 blood BFU-E in comparison to equal numbers of NK-depleted cells or T cells isolated by E-rosetting (p less than 0.01). Interferon boosting of NK-enriched cells abolished their suboptimal burst-promoting effects and augmented their CFU-E suppressor effects. These studies provide evidence for a potential regulatory role of NK cells in erythropoiesis. The NK suppressor effect is maximal at the level of the mature erythroid stem cell CFU-E. These findings may explain some hypoproliferative anemias that develop in certain NK cell-activated states.