Circulating Granulocytic and Erythroid Progenitor Cells in Chronic Granulocytic Leukaemia

S ummary . We used a standard methyl cellulose method to assay erythroid progenitor cells in the blood of 35 patients with untreated CGL and of 18 normal controls. In 28 patients we simultaneously assayed granulocyte/nionocyte committed progenitor cells (CFU-c) by an agar method. Circulating erythroid burst-forming units (HFU-e) in CGL wcre increased above normal by a factor of about 180; CFU-c were increascd by a factor of about 9000. Both BFU-e and CFU-c numbers were linearly related to the total leucocyte count in individual patients but not to numbers of circulating blast cells. There was a positive correlation in individual patients between CFU-c and BFU-e numbers. Circulating BFU-e and erythroid colony-forming cells (CFU-e) were unable to proliferate in vitro in the absence of erythropoietin. We conclude that erythroid progenitor cells are involved in the'clonal expansion'that characterizes CGL, but apparently to a lesser extent than are granulocyte/monocyte progenitor cells.     

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.     

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.     

In vitro myelotoxicity of 2',3'-dideoxynucleosides on human hematopoietic progenitor cells

Three nucleoside analogues, 2',3'-dideoxyadenosine (ddA), 2',3'-dideoxyinosine (ddI), and 2',3'-dideoxycytosine (ddC), were evaluated for their potential myelotoxic effects to normal human hematopoietic progenitor cells. The myeloid (granulocyte-monocyte colony-forming units, CFU-gm) and erythroid (erythroid burst-forming units, BFU-e: and erythroid colony-forming units, CFU-e) committed progenitor cells were exposed to the agents for a 1-h period prior to culture in a microcapillary assay or continuously exposed during the entire culture period. Both ddA and ddI (100 microM) were mildly toxic (less than 50% colony inhibition) to human CFU-gm, BFU-e, and CFU-e following either 1-h or continuous exposures. Marrow progenitor sensitivities to ddA and ddI were indistinguishable. Colony inhibition ranged from 47% to 67% for 1-h ddC exposure (100 microM), values that were comparable to ddA and ddI. Continuous exposure to ddC was highly myelotoxic to human hematopoietic progenitors, with concentrations of 10 and 100 microM suppressing colony formation by 79%-92% and 93%-97%, respectively. These results demonstrate that 1-h and continuous exposures to ddA and ddI were similarly myelotoxic to human hematopoietic cells, whereas a 1-h exposure to ddC was equivalent to ddA and ddI, yet continuous ddC exposure was extremely toxic to marrow cell progenitors.     

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.     

Separation of erythroid progenitor cells in mouse bone marrow by isokinetic-gradient sedimentation.

Isokinetic-gradient sedimentation employing a shallow linear gradient of Ficoll in tissue culture medium was used to isolate erythroid progenitor cells (CFU-e) from mouse bone marrow. Following gradient sedimentation, 34% of the total nucleated cells and 48% of the CFU-e applied to the gradient were recovered, and three distinct modal populations of CFU-e could be distinguished. The slowest-migrating population did not require exposure to exogenous erythropoietin in order to form erythroid colonies in vitro. The other two modal populations of CFU-e required exposure to exogenous erythropoietin for differentiation. One of these, constituting 64% of the hormone-dependent CFU-e recovered, migrated with the bulk of the marrow cells, whereas the other migrated ahead of the bulk of the marrow cells. This latter population, which contained 34% of the CFU-e, was recovered with 11% of the marrow cells, representing a twofold to threefold enrichment. BFU-e migrated more slowly than the erythropoietin-dependent CFU-e. Resedimentation studies suggested that the two erythropoietin-dependent CFU-e populations were distinct modal populations. When cells from the fastest-migrating population of erythropoietin-dependent CFU-e were cocultured with unseparated marrow cells, a further twofold to threefold enhancement of erythroid colony formation was obtained. Comparison of isokinetic-gradient sedimentation with discontinuous and continuous albumin density-gradient sedimentation revealed that isokinetic-gradient sedimentation was a more efficient method than the former and a more rapid method than the latter for isolating CFU-e from mouse bone marrow.     

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.     

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.     

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.     

Hydroxyurea promotes the reduction of spontaneous BFU-e to normal levels in SS and S/beta thalassemic patients

We have studied the effects of hydroxyurea on growth and differentiation of early erythroid progenitor cells (BFU-e) from peripheral blood of sickle cell disease patients (five SS and two Hb S/beta-thalassemia) in the presence or absence of exogenous stimulating factors. When the mononuclear cells from the sickle cell disease patients were cultured at diagnosis (before hydroxyurea treatment), there was an increased number of BFU-e in relation to controls (p < 0.05, Wilcoxon test) when cells were grown in the presence or absence of 5637 conditioned medium and erythropoietin. Colonies that developed in the absence of added growth factors were considered "spontaneous". A significant difference was observed after hydroxyurea treatment in the number of BFU-e obtained in the presence and absence of stimulus, with a higher reduction in the spontaneous BFU-e number. As expected, there was an increased Hb F level in these patients when compared with their pretreatment levels. There was no correlation between spontaneous BFU-e and hemoglobin levels in all patients studied.     

Direct evidence for interaction between human erythroid progenitor cells and a hemoglobin switching activity present in fetal sheep serum.

An activity that induces Hb F to Hb A switching in human cells is present in fetal sheep serum. To test directly the role of cell-to-environment interactions in hemoglobin switching and to define the level of erythroid cell differentiation at which this activity operates, colony transfer experiments were done. Clones grown in the presence of switching activity-containing medium (fetal sheep serum) or control medium (fetal calf serum) were transferred, at the 16- to 30-cell stage, to either fetal sheep serum or fetal calf serum plates and Hb F synthesis was determined in the fully mature erythroid bursts. Fetal calf serum-to-fetal calf serum transfers produced colonies with the high Hb F levels characteristic of undisturbed fetal calf serum-grown clones. Fetal sheep serum-to-fetal calf serum transfers resulted in significant decrease in Hb F synthesis, revealing an interaction between hemoglobin switching activity and cells at an early stage of progenitor cell development. The reduction of Hb F synthesis in fetal calf serum-to-fetal sheep serum transfers indicated that hemoglobin switching activity interacts with cells at later stages of progenitor cell development. Maximal decrease in Hb F synthesis was observed in fetal sheep serum-to-fetal sheep serum transfers, indicating that optimal effects on Hb switching are obtained when the environment that induces Hb switching is present throughout the development of progenitor cells. By splitting single early clones into two parts and transferring them to either a fetal sheep serum or a fetal calf serum environment, these interactions were further demonstrated in the progeny of a single erythroid burst-forming unit. Since all clone transfers were done on cell-free plates, the results of fetal calf serum-to-fetal sheep serum and of fetal sheep serum-to-fetal sheep serum transfers indicated that the switching activity does not require helper cells for its action. These studies show directly that (i) Hb F synthesis is controlled at the level of progenitors and (ii) it involves interactions between progenitor cells and their environment.     

Effect of recombinant human tumor necrosis factor on the colony growth of human leukemia progenitor cells and normal hematopoietic progenitor cells

The effects of recombinant human tumor necrosis factor (rH-TNF) on the colony growth of human leukemia progenitor cells (L-CFU), granulocyte- macrophage progenitor cells (CFU-GM), and erythroid progenitor cells (BFU-E) were studied. L-CFU was assayed with leukemia cells obtained from patients with acute myelogenous leukemia. CFU-GM and BFU-E were assayed with bone marrow cells obtained from hematologically normal donors and patients with acute leukemia or non-Hodgkin's lymphoma in complete remission. A dose-dependent growth inhibition of L-CFU as well as CFU-GM and BFU-E was observed by rH-TNF at concentrations of 1 to 100 U/mL. The inhibitory effect on L-CFU was significantly greater than that on CFU-GM. No correlation was observed between the inhibitory effect on L-CFU and the number of colonies formed in the cultures without rH-TNF. Preincubation of the progenitor cells in culture medium containing 20% fetal calf serum with up to 1,000 U/mL of rH-TNF for 24 hours did not result in the inhibition of colony growth of L-CFU or CFU- GM. The inhibitory effect of rH-TNF was neutralized by an anti-rH-TNF murine monoclonal antibody.     

Adult hemoglobins are synthesized in murine fetal hepatic erythropoietic cells

The hemoglobins present in murine fetal hepatic erythroblasts on days 12-15 of gestation were studied by biochemical and immunocytologic techniques. In addition, fetal hepatic hemopoietic progenitor cells obtained from normal and mutant f/f mouse fetuses on days 11-13 of gestation were cultured in vitro with added erythropoietin and adult spleen cell conditioned medium to form large erythroid colonies. In all instances, adult hemoglobin synthesis was detected in the fetal hepatic erythroblasts and in the erythroid cell cultures in vitro. The tumor promoter, 12-O-tetradecanoylphorbol 13-acetate, enhanced the fetal hepatic erythroid colony growth in vitro, but did not alter the hemoglobin phenotypic expression.     

In vitro erythropoiesis. II. Cytochemical enumeration of erythroid stem cells (CFU-e and BFU-e) from normal mouse and human hematopoietic tissues.

A procedure which provides more accuracy in the identification and scoring of in vitro derived erythroid colonies (i.e. BFU-e and CFU-e) from normal mouse and human marrow and spleen cells has been developed. Up to now identification of erythroid colonies has been based on staining with acidified benzidine which consistently displays "background staining" of granulocyte/macrophage colonies. The staining reaction with these reagents is such that identification of erythroid colonies is less than precise. The modified benzidine procedure described herein eliminates the staining reactivity of granulocyte/macrophage colonies and specifically reacts with only those cells that contain hemoglobin. Furthermore, individual colonies and/or cells may readily be counterstained and examined by high resolution light microscopy.     

A case of acquired pure red cell anemia studied by cloning of erythroid progenitor cells in vitro

A 70-year-old woman developed typical clinical symptoms of pure red cell anemia (PRCA) following a history of rheumatoid arthritis (RA). The patient's bone marrow erythropoietic progenitors cells were cloned in a micro agar culture system several times over a period of 11 months, revealing a diminished frequency of bone marrow erythroblasts paralleled by a markedly reduced number of CFU-e and BFU-e in vitro. No inhibitory activity in the patient's IgG fraction could be detected either by preincubation with IgG and/or rabbit complement, or in the continuous presence of IgG. Depletion of T lymphocytes from the patient's bone marrow cells led to an improved in vitro erythroid proliferation. Cytostatic therapy with cyclophosphamide clinically induced a marked increase in the bone marrow erythroblast and reticulocyte number, correlated in vitro by normalization of CFU-e levels and increase in the number of BFU-e. Nevertheless, BFU-e values never attained normal levels, which could be attributed to a reduced stem cell pool resulting from previous therapy with cyclophosphamide and/or antirheumatic drugs. Two independent factors, a reduced pool of committed stem cells as well as an autoimmune cell-mediated suppression, may both contribute to the pathomechanism of the disease in this patient.     

T cells and erythroid burst forming units in chronic lymphocytic leukemia

Substantial evidence exists indicating T cell abnormalities in chronic lymphocytic leukemia (CLL). There is also evidence that the T cell is an important source of burst promoting activity (BPA) for the peripheral blood (PB) erythroid burst forming unit (BFU-e). We studied the BPA of T cells and response of BFU-e in normals and untreated early stage B cell CLL patients in a methylcellulose colony assay. Normal null cell cultures grew significantly more BFU-e than CLL null cell cultures. Addition of autologous T cells to normal or CLL null cells significantly increased BFU-e only in normals. Allogeneic coculture of T cells from CLL patients with null cells from normals yielded normal responses of BFU-e in five of six cases. In contrast, allogeneic coculture of normal T cells with CLL null cells yielded a normal response in only one of six studies. Furthermore, adding increasing quantities of autologous or normal allogeneic T cells to CLL null cells did not augment the BFU-e response. Accounting for the expanded lymphocyte pool in CLL, BFU-e are decreased in concentration but the absolute number is normal or increased. The decrease in concentration could be secondary to expansion of the null cell fraction in CLL by pre-B cells. CLL T cells appeared to augment normal allogeneic PB BFU-e in a normal fashion, whereas, in several cases, CLL BFU-e were hyporesponsive to autologous or normal allogeneic T cells. It is therefore apparent that in untreated early stage B cell CLL, erythroid progenitor cells are present in the peripheral blood but are diluted in an expanded null cell compartment and may, in some cases, be hyporesponsive to T cell BPA. T cell BPA of CLL T cells in this early stage of disease is preserved.     

Increased Haemopoietic Cell Survival in Vitro Induced by a Human Marrow Fibroblast Factor

S ummary. Human marrow fibroblasts were grown in vitro and examined for effects on human and mouse haemopoietic cells. When human marrow cells were incubated with fibroblasts or with fibroblast-conditioned medium for 1 week and then assayed for committed granulocyte/monocyte (CFU-c) and erythroid (BFU-e) progenitor cells, the numbers of CFU-c and BFU-e were considerably increased compared with controls. In contrast, human marrow-fibroblast-conditioned medium, when added directly to CFU-c or BFU-e assay cultures, had no effect on colony formation by these progenitor cells. As these results suggest that the fibroblast-derived factor may be acting on a relatively primitive progenitor cell, possibly a pluripotent haemopoietic stem cell, the effect of this factor on mouse pluripotent haemopoietic stem cells (CFU-s) was examined. Human marrow-fibroblast-conditioned medium considerably enhanced CFU-s survival after a 24 h incubation and increased the proportion of CFU-s in cell-cycle. The increase in CFU-s survival depended on the concentration of the fibroblast-conditioned medium but not on the age of the fibroblast culture. The evidence suggests therefore that human marrow fibroblasts produce a factor that acts on a human myeloid progenitor cell more primitive than BFU-e and CFU-c, possibly the pluripotent haemopoietic stem cell.     

Erythropoietin controls heme metabolic enzymes in normal human bone marrow culture

Erythropoietin (Epo) was found to act as a concentration-dependent inducer of aminolevulinic acid (ALA) synthase and porphobilinogen (PBG) deaminase in normal human bone marrow in culture. Epo increased enzymatic activities in individual plated nucleated cells. At a low concentration of Epo, heme oxygenase activity did not change in human bone marrow erythroid progenitor cells. However, Epo at a concentration of 2 U/ml increased heme oxygenase as demonstrated by an increase in both the enzyme protein and its mRNA. In experiments with an inhibitor of heme synthesis, succinylacetone (SA), Epo failed to stimulate erythroid colony-forming unit (CFU-E) growth, but this CFU-E inhibition by SA was completely overcome by the addition of hemin. Epo nevertheless potentiated induction of ALA synthase in the presence of SA. Hemin exerted its regulatory role by negative feedback on ALA synthase in the presence of SA and Epo. Heme potentiated Epo action and resulted in the increase of human marrow erythroid progenitor cell proliferation and differentiation and a concomitant stimulation of ALA synthase and PBG deaminase. The potentiating effects of hemin on CFU-E growth were observed in human bone marrow cells cultured in media supplemented with fetal calf serum or serum-free media with interleukin 3 (IL-3). These results indicate that Epo is a potent inducer of ALA synthase and PBG deaminase in normal human bone marrow. In addition, our results may explain the mechanisms by which heme potentiates Epo or IL-3 enhancement of erythropoiesis. 1) Heme may stimulate the translation of several globin and nonglobin mRNAs, including those of ALA synthase and PBG deaminase; 2) as endogenous cellular heme synthesis reaches optimal levels, heme exerts its regulatory role on ALA synthase by negative feedback inhibition. Additionally, an increase in cellular heme may lead to an increase in its own degradation by induction of heme oxygenase.     

Effects of B cell stimulatory factor-1/interleukin 4 on hematopoietic progenitor cells

B cell stimulatory factor-1 (BSF-1)/Interleukin 4 (IL 4) is a T cell product originally characterized on the basis of its actions on B lymphocytes. Recently it has been reported that BSF-1 activates T cell and mast cell lines. We now provide evidence that BSF-1, purified to homogeneity, also has a broad spectrum of activity on hematopoietic progenitor cells (HPC). However, like its action on B cells, prolierative effects were only observed when BSF-1 was combined with an additional factor. Thus BSF-1, in costimulation with recombinant G-CSF, enhances the proliferation of granulocyte-macrophage progenitor cells (CFU-GM). BSF-1 increases the proliferation of CFU-e in the presence of recombinant erythropoietin (rEPO). Furthermore, BSF-1 induces, together with rEPO, colony formation by primitive erythroid (BFU-e) and multipotent (CFU-mix) progenitor cells comparable to that observed with rEPO and interleukin 3 (IL 3). BSF-1 is also active as a megakaryocyte colony-stimulating factor; in combination with recombinant interleukin 1, rEPO or the supernatant of the T cell hybridoma FS7-20.6.18, BSF-1 induces megakaryocyte colony formation (CFU-Mk). The same factors that synergize with BSF-1 also enhance CFU-Mk proliferation induced by IL 3. Although the precise mechanisms of action of BSF-1 on HPC is not yet known, we propose that BSF-1 represents an activation factor for HPC and prepares the progenitor cells to respond to specific growth or differentiation factors.     

Diamond-Blackfan Syndrome: Evidence for T-Cell Mediated Suppression of Erythroid Development and a Serum Blocking Factor Associated with Remission

Diamond-Blackfan syndrome may be a disorder of cellular immunity. Lymphocytes from some patients are capable of suppressing erythropoiesis in cultures of normal bone marrow. We studied two adults with this disorder, both in complete unmaintained remission, using a technique for cloning peripheral blood erythroid precursors (BFU-E) in culture. The BFU-E may be early, erythropoietin sensitive, erythroid committed stem cell. Under culture conditions, which employ fetal calf serum, neither patients cells formed normal numbers of erythroid colonies. Controls yielded 15.3 +/- 5.2 BFU-E/2.5 X 10(5) mononuclear cells. Culture of patients cells using autologous serum, promoted more normal growth of BFU-E (21.4 +/- 6.9 and 7.3 +/- 2.3 BFU-E/2.5 X 10(5) cells). Patient mononuclear cells, cocultured normal cells, generally suppressed BFU-E generation. Cocultures of normals were not inhibitory. Removal of T-lymphocytes from patient mononuclear cells permitted normal growth of BFU-E in coculture with controls. T-cells depleted Diamond-Blackfan mononuclear cells showed BFU-E formation in fetal calf and autologous serum. Diamond-Blackfan T-cells inhibited BFU-E formation by normal mononuclear cells. The cellular defect in Diamond-Blackfan syndrome persists during complete remission and may be mediated by lymphocytes. The development of a serum factor which blocks the suppressive effects on erythroid precursors of a subpopulation of autologous T-cells may be responsible for the development of remission in our patients.