Ability of plasma from patients with immune thrombocytopenic purpura (ITP) to promote the growth of megakaryocyte progenitors from normal bone marrow.

The ability of plasma from ITP patients (before and after splenectomy) to support the growth of megakaryocyte progenitors was compared with that from healthy subjects. Plasma Factor Index-Megakaryocyte PFI-Mk (ITP) which expressed resultant colony growth was significantly lower before splenectomy, but it normalized after splenectomy. (PFI-Mk) (ITP) did not relate neither to megakaryocyte nor to platelet counts. A positive correlation has been observed between megakaryocyte and platelet numbers in healthy subjects and in ITP patients after splenectomy, but not before splenectomy. The proportion of immature megakaryocytes was markedly higher in ITP marrow before splenectomy. This study indicates, that in ITP apart from antibodies directed to platelets and megakarocytes a low plasma stimulatory activity affected megakaryocytopoiesis.     

The influence of T lymphocyte subsets and humoral factors on colony formation by human bone marrow and blood megakaryocyte progenitor cells in vitro

Cellular and humoral influences of T lymphocytes on human megakaryocyte colony formation in vitro were assessed by using a microagar system. Megakaryocyte colony formation from nonadherent low density T lymphocyte-depleted (NALDT-) bone marrow cells was increased significantly after the addition of aplastic anemia serum (AAS) or purified megakaryocyte colony-stimulating factor (Meg-CSF). The addition of conditioned medium obtained from phytohemagglutinin-stimulated T lymphocytes replaced, at least partially, the requirement for AAS or purified Meg-CSF for the growth of megakaryocyte colonies. The cellular influence of T lymphocytes and T lymphocyte subsets on megakaryocyte colony formation was assessed by removing either T cells from nonadherent peripheral blood mononuclear cells with monoclonal OKT4, OKT8, or OKT3 antibodies plus complement, or by adding back populations of bone marrow or blood T4+ or T8+ lymphocytes, isolated by means of fluorescence-activated cell sorting, respectively, to NALDT--bone marrow or -blood cells. When sorted T cell subpopulations were added to a fixed number of NALDT--bone marrow or -peripheral blood cells in the presence of AAS or Meg-CSF, T4+ cells enhanced megakaryocyte colony formation and T8+ cells decreased it. These studies demonstrate that although the stimulation of megakaryocytic progenitor cells by Meg-CSF may not require the presence of monocytes or T lymphocytes, T4+ lymphocytes enhance and T8+ lymphocytes down-regulate megakaryocyte colony formation induced by Meg-CSF. These observations suggest that the immune system is capable of modulating the proliferative response of human megakaryocytic progenitor cells to Meg-CSF.     

Anti-thoracic duct lymphocyte globulin stimulates human megakaryocytopoiesis in vitro

Anti-thoracic duct lymphocyte globulin (ALG) therapy is effective in patients with aplastic anemia. We examined the effect of ALG on human megakaryocyte progenitor cells (colony-forming unit-megakaryocyte, CFU-Meg) in vitro. Normal human bone marrow mononuclear cells (MNC) were cultured in plasma clots with varying concentrations of ALG or non-immunized horse IgG. After 12 days of culture, significant megakaryocyte colony formation was observed in cultures containing ALG but not in cultures containing non-immunized horse IgG. The peak stimulatory effect seemed to occur with 10-25 micrograms/ml of ALG. When marrow MNC, depleted of adherent and T cells, were cultured in plasma clots with ALG, its stimulatory effect on megakaryocytopoiesis decreased markedly. Finally, it was demonstrated that ALG stimulated marrow MNC to produce a factor stimulatory for CFU-Meg. The in vitro megakaryocytopoietic stimulatory effect of ALG may be related to its clinical efficacy in some patients with aplastic anemia.     

The nature of 12-O-tetradecanoylphorbol-13-acetate (TPA)-stimulated hemopoiesis, colony stimulating factor (CSF) requirement for colony formation, and the effect of TPA on [125I]CSF-1 binding to macrophages

The tumor-promoting phorbol diester, 12-O-tetradecanoylphorbol-13-acetate (TPA) was found to act both independently of and synergistically with the mononuclear phagocyte specific colony stimulating factor (CSF-1) to stimulate the formation of macrophage colonies in cultures of mouse bone marrow cells. In contrast, TPA did not synergize with other CSF subclasses that stimulate the formation of eosinophil, eosinophil-neutrophil, neutrophil, neutrophil-macrophage, and macrophage colonies, nor with either of the two factors required for megakaryocyte colony formation, megakaryocyte CSF, and megakaryocyte colony potentiator. In serum-free mouse bone marrow cell cultures TPA retained the ability to independently stimulate macrophage colony formation. However, TPA-stimulated colony formation was suboptimal and delayed in serum-free cultures that could support optimal colony formation in the presence of CSF-1. In addition, TPA did not directly compete with [125I]CSF-1 at 4 degrees C for its specific, high-affinity receptor on mouse peritoneal exudate macrophages. However, a 2-hour preincubation of the cells with TPA at 37 degrees caused almost complete loss of the receptor. Thus, TPA is able to mimic CSF-1 in its effects on CSF-1 responsive cells in some aspects (the spectrum of target cells, the morphology of resulting colonies, and the ability to down-regulate the CSF-1 receptor) but it is not able to mimic CSF-1 in other ways (TPA alone cannot stimulate the full CSF-1 response, TPA does not stimulate the most primitive CSF-1 responsive cells, and TPA does not bind to the CSF-1 receptor).     

Kinetic analysis of megakaryocyte numbers and ploidy levels in developing colonies from mouse bone marrow cells

Abstract. The kinetics of megakaryocyte formation from mouse bone marrow cells in semi-solid medium was studied directly in the culture dish by staining the cells for acetylcholinesterase after drying the cultures. A WEHI-3 cell-conditioned medium (WEHI-3 CM) was used as a general source of stimulus for megakaryocyte colony formation. The addition of peritoneal exudate supernatant as well as WEHI-3 CM increased the frequency of megakaryocyte colonies detected. Colonies containing acetylcholinesterase-positive cells were first detected at day 3. Maximum numbers of 25–40 megakaryocyte colonies per 10⁵ nucleaet mouse bone marrow cells were observed from days 7 to 11. The mean number of cells within each colony increased progressively with time of culture, and a modal range of 11–20 cells was obtained by day 7. Between 3 and 200 cells per colony were generally detected. A continuous distribution of the number of megakaryocytes per colony suggests that the clonable precursor cells are not synchronized either with respect to maturation stage or with respect to their capability to undergo nuclear endoreduplication. The addition of peritoneal exudate supernatant to the cell cultures increased the DNA levels of megakaryocytes grown in the presence of WEHI-3 CM but did not affect the number of cells per colony. The DNA content of colony megakaryocytes was measured after staining the cells with Feulgen reagent. A modal DNA value of 8 N was observed between days 4 and 7 for megakaryocytes stimulated with WEHI-3 CM. In the presence of both WEHI-3 CM and peritoneal exudate supernatant, the DNA content of megakaryocytes increased with the time of cell culture. Modal DNA values increased from 8 N at days 4 and 5, to 16 N by day 6. In these optimally stimulated cultures, 44% of colony megakaryocytes were 32 N or greater, a proportion higher than in normal bone marrow, but similar to that seen in the marrow of acutely thrombocytopenic animals. It is concluded that megakaryocytopoiesis in cell cultures is not a strictly controlled process with respect to cell division and endomitosis and that when certain culture conditions are employed, megakaryocyte development in vitro might reflect that seen in a stressed animal condition.     

Kinetics of megakaryocyte progenitor cells in idiopathic thrombocytopenic purpura

The number and proliferative state of megakaryocyte progenitor cells (CFU-Meg) were compared between 13 patients with idiopathic thrombocytopenic purpura (ITP) and hematologically normal controls. The mean frequency of CFU-Meg assayed by the plasma clot method was 27.8 +/- 12.2 (+/- SD)/2 x 10(5) bone marrow light-density cells for the ITP patients, which did not differ significantly from the control value of 31.9 +/- 16.1. The percentage of CFU-Meg in DNA synthesis estimated by the 3H-thymidine suicide technique was 41.3% +/- 9.2% in ITP, which was significantly greater than the control value of 27.1% +/- 7.4% (P less than 0.01). The megakaryocyte counts for histological sections prepared from bone marrow aspirates from the ITP patients and controls were 34.5 +/- 8.5/mm2 and 11.2 +/- 5.8/mm2, respectively, with the difference being highly significant (P less than 0.001). These results suggest that increased cycling activity in a quantitatively unchanged CFU-Meg pool may lead to increased megakaryocytes in the bone marrow of ITP patients.     

The effect of vitamin D3 metabolites on normal and leukemic bone marrow cells in vitro

We studied the effects of 1,25-dihydroxyvitamin D3 and other metabolites of vitamin D3 on the maturation in liquid culture and on colony formation in semisolid media of marrow and buffy coat cells from patients with myeloid leukemias and from normal individuals. After incubation with 1,25-dihydroxy-vitamin D3, a proportion of both normal and leukemic myeloid cells resembled cells of the monocyte-macrophage lineage; these cells expressed alpha-naphthylacetate esterase and were able to phagocytize and kill candida organisms. When granulocyte-macrophage progenitor cells (CFU-GM) were incubated with 1,25-dihydroxyvitamin D3, the number of monocyte-macrophage colonies was increased and the number of granulocyte colonies was reduced; megakaryocyte colony formation (CFU-Mk) was inhibited substantially; and there was no effect on erythroid (BFU-E) or multilineage (CFU-GEMM) progenitor cell colony formation. We propose that 1,25-dihydroxyvitamin D3 may induce cells that are normally committed to differentiate along the granulocytic pathways to differentiate instead along the monocyte-macrophage pathway. If these in vitro observations reflect the in vivo activity of 1,25-dihydroxyvitamin D3, it may be involved in the modulation of collagen deposits in the bone marrow.     

Immature megakaryocytes in the mouse: In vitro relationship to megakaryocyte progenitor cells and mature megakaryocytes

An assay describing conditions for the maturation of single immature megakaryocytes in vitro is reported. Enriched populations of small, relatively immature megakaryocytes have been found to develop into single, mature megakaryocytes by 60 hours in semisolid agar cultures. Continued incubation of these cells did not lead to the formation of colonies within 5–7 days. Maturation was indicated by increasing cell size and cytoplasmic and acetylcholinesterase content. Factors stimulating the development of immature megakaryocytes were found in preparations of human embryonic kidney cell-conditioned media (a source of in vivo Thrombopoietic Stimulatory Factor), peritoneal exudate cell-conditioned medium, lung-conditioned medium, or bone marrow cellular sources of activity (adherent cells or cells that sediment at 5–6 mm hr^-1). Immature megakaryocytes cultured serum free responded to sources of an auxiliary megakaryocyte potentiating activity by developing into single, large megakaryocytes but did not respond to a megakaryocyte colony-stimulating factor devoid of detectable potentiator activity present in WEHl-3-conditioned medium. In contrast, serum-free proliferation of the megakaryocyte progenitor cell required both megakaryocyte colony-stimulating factor and the auxiliary potentiator activity. In the presence of megakaryocyte colony-stimulating factor alone, progenitor cells did not form colonies of easily detectable megakaryocytes. However, groups of cells comprised entirely of small acetylcholinesterase containing immature megakaryocytes were observed, thus establishing that megakaryocyte colony development passes through a stage of immature cells prior to detectable megakaryocyte development and that some acetylcholinesterase-containing cells can undergo cellular division.     

Stimulation by normal and leukemic mouse sera of colony formation in vitro by mouse bone marrow cells

Using a modification of the agar gel method for bone marrow culture, serum from various strains of mice has been tested for colony stimulating activity. Ninety percent of sera from AKR mice with spontaneous or transplanted lymphoid leukemia and 40–50% of sera from normal or preleukemic AKR mice stimulated colony formation by C57B1 bone marrow cells. Sera from 6% of C3H and 30% of C57B1 mice stimulated similar colony formation. The incidence of sera with colony stimulating activity rose with increasing age. All colonies were initially mainly granulocytic in nature but later became pure populations of mononuclear cells. Bone marrow cells exhibited considerable variation in their responsiveness to stimulation by mouse serum. Increasing the serum dose increased the number and size of bone marrow cell colonies and with optimal serum doses, 1 in 1000 bone marrow cells formed a cell colony. Preincubation of cells with active serum did not stimulate colony formation by washed bone marrow cells. The active factor in serum was filterable, non-dialysable and heat and ether labile.     

Interactions between purified GM-CSF, purified erythropoietin and spleen conditioned medium on hemopoietic colony formation in vitro.

Preincubation of C57BL adult marrow cells or CBA fetal liver cells with a 250-fold excess concentration of purified GM-CSF failed to reduce the frequency of cells forming eosinophil, megakaryocyte or erythroid colonies in subsequent agar cultures. When excess concentrations of purified GM-CSF were added to agar cultures stimulated by pokeweed mitogen-stimulated spleen conditioned medium (SCM), no reduction was observed in the frequency of eosinophil, megakaryocyte or erythroid colonies. Addition of 4 units of purified erythropoietin (EPO) to cultures of fetal liver or adult marrow cells stimulated by SCM increased the number of erythroid colonies but did not reduce the number of non-erythroid colonies or the non-erythroid content of mixed erythroid colonies. Although neither GM-CSF nor EPO alone was able to stimulate erythroid colony formation in agar cultures of fetal liver cells, small numbers of large erythroid colonies were stimulated to develop in cultures containing both purified regulators. Purified GM-CSF was also able to support the survival in vitro of a small proportion of erythroid colony-forming cells in fetal liver populations cultured initially in the absence of SCM and the survival of some eosinophil and megakaryocyte colony-forming cells in similar cultures of adult marrow cells. The results do not support the hypothesis that GM-CSF and EPO compete for a common pool of uncommitted progenitor cells. On the contrary, the data indicate that GM-CSF und EPO are able to collaborate in stimulating the proliferation of some erythropoietic cells. Furthermore, purified GM-CSF appears to be able to support temporarily the survival and/or initial proliferation of at least some cells forming erythroid, eosinophil and megakaryocyte colonies, even though GM-CSF is unable to stimulate the formation of colonies of these types.     

Characterization of human megakaryocytic colony formation in human plasma

We have analysed the contribution to megakaryocyte colony formation in methylcellulose made by human plasma, serum, media conditioned by phytohemagglutinin (PHA) stimulated leukocytes (PHA-LCM), erythropoietin (EPO) preparations, and platelets. The culture system was used as a bioassay for megakaryocyte colony stimulating activity (Meg-CSA) in plasma samples of patients with perturbed megakaryocytopoiesis. Preparations of heparinized platelet-poor plasma yielded the most consistent results. Platelet-poor plasma of normal subjects will at best facilitate the occasional growth of small megakaryocyte colonies. Colony frequency and size are reproducibly enhanced in the presence of PHA-LCM as a source of exogenous Meg-CSA. Commercially available EPO preparations may vary in their content of activities that influence megakaryocyte colony formation. Addition of these preparations to cultures that contain plasma and PHA-LCM usually does not enhance colony formation. In contrast to platelet-poor plasma, platelet rich plasma and serum are less supportive of megakaryocyte colony growth. It is suggested that this loss of activity may be related to the release of inhibitors by activated platelets or alternatively caused by absorption of activities by platelets. Plasma samples from patients with megakaryocytopoietic dysfunction may contain components that promote colony formation without addition of PHA-LCM or EPO. This phenomenon is consistently observed for patients with severe aplastic anemia and bone marrow transplant recipients after completion of their ablative preparative regimen.     

Inhibition of agar colony formation by partially purified granulocyte extracts (chalone)

Granulocytic extracts (GE) of different sources, presumably containing the granulocytic chalone, were prepared in different laboratories and purified to some extent. They specifically inhibited the formation of granulocyte and macrophage colonies in agar. The effect was however most pronounced on granulocyte and mixed granulocyte-macrophage colonies, and less on macrophage types. Addition of GE to bone marrow cells at the time of plating in agar, as well as short incubation of the cells together with GE prior to plating, inhibited subsequent colony formation. The inhibitory effect could easily be reversed by washing the cells with an excess of medium prior to plating during the first hour of preincubation, but not after five hours. Increasing the doses of colony stimulating activity (CSA) (at low doses of GE) released the inhibitory effect, but not at high doses of GE. The inhibitory effect of GE on colony formation was dose dependent down to almost 100% inhibition. No apparent cytotoxic effect of GE on bone marrow cells could be found and lymphoblastic cells were not inhibited. Extracts containing a specific inhibitor of erythropoiesis (EIF) stimulated myelopoietic colony formation in agar.     

Effect of antibodies to denatured DNA on the human bone marrow cells forming colonies in semi-solid agar]

gamma-globulin from rabbit sera containing antibodies to denatured DNA or cytidine suppressed the efficiency of colony formation in agar cultures of human bone marrow cells. The antibodies to DNA isolated from the immune sera by the immunosorbent produced an analogous effect. gamma-globulin from the sera of intact animals and immune sera after the removal of antibodies to denatured DNA from them produced a different effect. gamma-globulin in a concentration of 0.28 and 5 mg failed to influence the colony-formation of 2.10(5) explanted nucleus-containing cells, by stimulated the colony growth when added in a concentration of 15 mg.     

Maturation and regulation of megakaryocytopoiesis.

The in vitro cloning technique for detecting megakaryocyte precursor cells was employed to compare stimuli known to influence megakaryocytopoiesis. Preparations of thrombopoietic stimulating factor (TSF) did not directly stimulate the growth of megakaryocyte colonies (CFU-m) but increased the frequency of CFU-m when TSF was added to the cultures with a constant amount of megakaryocyte colony stimulating factor. Platelets or platelet homogenates did not influence the frequency of CFU-m or the size of individual colonies. Analysis of cell surface properties of megakaryocytes obtained either by isolation from bone marrow or from in vitro colonies revealed species differences. The possibility that megakaryocytopoiesis and platelet release are regulated both within the marrow as well as by humoral factors is discussed.     

The human lung fibroblast cell line, MRC-5, produces multiple factors involved with megakaryocytopoiesis

The human lung fibroblast cell line MRC-5 constitutively produces a megakaryocyte potentiator activity, identified in murine bone marrow liquid culture assays for acetylcholinesterase and megakaryocyte colony assays in the presence of low concentrations of IL-3. The production levels of this activity were increased after stimulation with the phorbol ester analog, mezerein, and the calcium ionophore, A23187. Complete purification of a protein having this activity from conditioned media of induced MRC-5 cells was achieved using gel filtration and ion exchange chromatography. The first 14 residues of the purified protein identified by amino-terminal sequencing were identical to the first 14 residues of IL-6. Recombinant human IL-6 was tested and found to promote megakaryocyte growth. IL-1 beta, another component detected in MRC-5 conditioned media, was unable to promote megakaryocyte colony formation but did reduce the concentration of IL-6 necessary to support megakaryocyte colony formation. Immunoprecipitation using rabbit antiserum prepared against IL-6 removed the megakaryocyte growth activity found in MRC-5 conditioned media. Thus, connective tissue cells such as fibroblasts in the bone marrow may co-stimulate thrombocytopoiesis via IL-6 and, possibly, via IL-1 production.     

Megakaryocyte colony-stimulating factor (Mk-CSF): its physiologic significance

Megakaryocyte colony-stimulating activity (Mk-CSA) is required for in vitro megakaryocyte colony formation. Its in vivo significance in megakaryocytopoiesis is unknown. We studied 12 patients undergoing bone marrow transplantation (BMT) at our institution. The bone marrow megakaryocyte progenitor cells (CFU-Mk), the serum level of Mk-CSA, and the platelet count on the 28th day after BMT were studied. Patients with elevated Mk-CSA levels had less CFU-Mk in their bone marrow than did patients with a normal or decreased Mk-CSA (p less than 0.01). Animal experiments using murine models have documented that several purified molecules including erythropoietin, multi-CSF and GM-CSF possess Mk-CSA. The in vitro Mk-CSF of WEHI-3-conditioned medium is multi-CSF. The in vivo significance for megakaryocytopoiesis of these factors is not clear. In the human system, Mk-CSA is increased in conditions with decreased bone marrow megakaryocytes. Recombinant human or primate CSFs have in vitro Mk-CSA utilizing both human and murine cells as targets. However, the presence of these activities does not fully explain the Mk-CSA in human serum rich in Mk-CSA. The precise regulation of human blood cell levels and the studies discussed suggest that there is a specific Mk-CSF that responds to in vivo changes in megakaryocyte numbers. Proof of its physiologic role awaits the isolation of a pure factor.     

Possible role of the T-cells in regulating in situ hematopoiesis

The aim of the study was to reveal the possible role of T cells in the negative regulation of hematopoiesis. The main experimental approach included incubation of bone marrow cells obtained from mice of different strains with the anti-serum against a specific marker of suppressor T cells--antigen I-J. Anti-I-Jk serum-treated cells and cells treated with nontoxic normal mouse serum or non-treated cells (controls) were further incubated with complement and tested for their CFUs content, using Till & McCulloch exocolonization technique. Treatment with anti-I-Jk serum had a stimulating effect on the CFUs colony formation in mice of the appropriate haplotype (CBA, AKR, A/Sn) bearing I-Jk, but not I-Jb (CC57Br) allele. The same results were obtained in transfer experiments using spleen cells; only in this case stimulating effect was observed in 7-8-day CFUs, while with the marrow transplant augmentation it was seen both 7-8 and 11-12 days following grafting. The seeding efficiency of CFUs was not changed after incubation with anti-I-J serum. The data prove that indigenous for the spleen and bone marrow of mice cells expressing I-J determinants are involved in the negative regulation of hematopoiesis in situ.     

Improvement of culture conditions for human megakaryocytic and pluripotent progenitor cells by low oxygen tension

The effect of low oxygen tension on the growth of human hemopoietic progenitor cells in bone marrow was investigated using the semisolid methylcellulose colony assay. The clonal growth of granulocyte-macrophage progenitors (CFU-gm), early (BFU-e) and late (CFU-e) erythroid progenitors, megakaryocyte progenitors (CFU-meg) and pluripotent progenitors (CFU-mix) improved more markedly incubation at the low oxygen tension (5%) than in conventional air (20%). The thiol compound 2-mercaptoethanol had a strong additive effect on colony growth in conventional air, but little or no effect in the low oxygen tension. These results suggest that enhancement of colony growth in the low oxygen tension may be due to a decrease in the production of oxygen intermediates.     

The effect of cytokines on the ploidy of megakaryocytes

The effects of recombinant cytokines on the ploidy of human megakaryocytes derived from megakaryocyte progenitors were studied using serum-free agar cultures. Nonadherent and T cell-depleted marrow cells were cultured for 14 days. Megakaryocyte colonies were identified in situ by the alkaline phosphatase anti-alkaline phosphatase technique, using monoclonal antibody against platelet IIb/IIIa. The ploidy of individual megakaryocytes in colonies was determined by microfluorometry with DAPI (4',6-diamidino-2-phenylindole) staining. Recombinant human interleukin 3 (rhIL-3) and recombinant human granulocyte-macrophage colony-stimulating factor (rhGM-CSF) supported megakaryocyte colony formation in a dose-dependent manner. However, both rhIL-3 and rhGM-CSF had no definite ability to increase the ploidy values. Recombinant human erythropoietin (rhEpo) or recombinant human macrophage colony-stimulating factor (rhM-CSF) by itself did not stimulate the growth of megakaryocyte progenitors. rhEpo or rhM-CSF, however, stimulated increases in the number, size and ploidy values of megakaryocyte colonies in the presence of rhIL-3 or rhGM-CSF. Recombinant human interleukin 6 (rhIL-6) showed no capacity to generate or enhance megakaryocyte colony formation when added to the culture alone or in combination with rhIL-3. rhIL-6, however, increased the ploidy values in colonies when added with rhIL-3. These results show that rhEpo, rhM-CSF and rhIL-6 affect endomitosis and that two factors are required for megakaryocyte development.     

Effects of B-lymphocytes from different organs on hemopoietic colony formation in the spleen by bone marrow cells]

The influence of B-lymphocytes from various sources on splenic colony formation was studied in the syngeneic system. B-lymphocytes were obtained by panning with IgG-fraction of rabbit anti-mouse Ig, absorbed on Petri dishes. In addition, adherent cells, Thy-1+ and SC-1+ were eliminated from the fraction of Ig(+)-cells. SC-1- and SC-1+ fractions, containing, respectively, stem cells and T-lymphocyte precursors, were obtained by panning with IgG-fraction of rabbit anti-SC-1 serum. SC-1- cells transferred to irradiated syngeneic mice did not induce colony formation in the spleen. Introduction of SC-1- and SC-1+ cells induced formation of colonies. A similar helper effect occurred when SC-1(-)-cells were introduced with bone marrow or lymph node B-cells, but not with splenic B-cells. Splenic, but not bone marrow and lymph node B-cells inhibited colony formation by combination of SC-1- and SC-1+ cells. All effects of Ig+ cells were abolished by treatment of cells with rabbit anti-MBLA serum. Thus, B-cells of various origin can either enhance or inhibit colony formation. The enhancing of inhibitory effect after B (MBLA+)-cells elimination from suspension of bone marrow and lymph node (but not spleen) Ig(+)-cells resulted from the activity of B-contrasuppressors.