Limiting dilution clonal assay of human bone marrow hematopoietic progenitors (granulocytes-macrophages)

We have developed a limiting dilution assay for human bone marrow hematopoietic precursor (granulocytes-macrophages) in microwells. Bone marrow cells were fractionated by discontinuous Percoll gradients and diluted in culture medium containing colony-stimulating factors. They were diluted and cultured in medium containing colony-stimulating factor and 10(-5) M hydrocortisone in microwells over a range of cell densities that allowed calculation of the frequency of growth-inducible precursors. After 10 days, the wells were examined for clonal growth. Clonal proliferation followed the single-hit model of the Poisson distribution. More progenitors were detected in this assay than in simultaneous methylcellulose colony assays or agar cultures. Thymidine suicide experiments led to an increase in the frequency of progenitors detected in this assay, but a decrease in the frequency of methylcellulose colonies. This system may detect additional, less mature progenitors than are detected in semisolid culture systems.     

Erythroid stem cells in Friend-virus infected mice

The erythropoietic stem cell compartment was studied in Friend-virus (polycythemic strain, FV-P) infected DBA/2 and NMRI mice with the CFUE and BFUE technique. Early after infection there was a depression in CFUE number in bone marrow and spleen, followed by an increase of the CFUE concentration, earlier and more pronounced in the spleen than in the marrow. Three days after FV-P infection an erythropoietin (Ep) independent CFUE population started to grow and replaced the normal Ep-dependent population within 8 to 12 days. The shift to Ep independency was not gradual. CFUE colonies of FV-P infected bone marrow cells were two to three times larger than control colonies after three days in vitro incubation. BFUE colonies increased in number during the first days of infection, but were totally lost after more than ten days. After velocity sedimentation of bone marrow cells of FV-P infected animals, however, the BFUE containing fractions showed normal BFUE colony growth and normal Ep sensitivity. In unfractionated bone marrow cell cultures BFUE colony growth could be observed later than ten days post infection when the cultures were refed with medium. It was therefore concluded that the loss of BFUE colony growth after FV-P infection was an in vitro artefact due to inadequate culture conditions.     

Pre CFU-F in bone marrow cultures from children with hematopoietic disease including acute leukemia

Stromal precursor cells from bone marrow aspirates of children have been studied in culture. In 7 day liquid cultures normal individuals and patients with acute leukemia in remission grew 110 +/- 50 CFU-F and 100 +/- 40 CFU-F (colony forming unit--fibroblasts) respectively, per 6 X 10(5) buffy coat mononuclear cells. Staining with monoclonal antibodies suggests that stromal cells from CFU-F colonies are fibroblasts. CFU-F colony growth from the bone marrow of patients with active leukemia was low. After cultivation periods of more than 21 days, we observed, in addition, still more immature, clonogenic fibroblast precursor cells, "pre CFU-F", and round cells attached to stromal cells from pre CFU-F colonies. From the round cells, we have passaged pre CFU-F and CFU-GM (colony forming unit--granulocytic, monocytic) in secondary cultures. Our observations are in agreement with the concept that the bone marrow stromal cell matrix serves as a sanctuary for reversibly attached clonogenic cells of both the hematopoietic and fibroblast lineages.     

Effect of opioid peptides on proliferation and differentiation of skeletogenic cells of rabbit bone marrow in vitro

The influence of opioid peptides DSLET and DAGO in doses 10(-5), 10(-7) or 10(-10) mg per 1 ml of the medium on colony formation in the culture of stromal bone marrow fibroblast precursors was investigated 5. 10(-6) bone marrow cells were placed in plastic containers (Costar). 12 day old cell cultures were fixed with ethanol and stained with hematoxyline-eosin. Effectiveness of fibroblast colony formation (EFFC) was detected. Grown fibroblast colonies were stained after Gomory for alkaline phosphatase. Opioid peptides DSLET and DAGO in the used doses exerted no influence on EFFC and percentage phosphatase-positive colonies, which casts doubt on a presumable direct action of opioid peptides on stromal bone marrow cell-precursors. But it does not seem unlikely that opioid peptides may affect stromal bone marrow precursors of fibroblasts through the cell environment, particularly, via macrophages.     

Fibroblast colonies in monolayer cultures of human bone marrow

In a liquid culture of human bone marrow, the development of fibroblast colonies takes place on days 6 to 9. Twenty percent fetal calf serum is used as the stimulus for fibroblast colony growth. Human bone marrow cells are plated as 2 × 10₅ cells in the culture. Normal human bone marrow yields 47 ± 4 fibroblasts colonies per 2 × 10₅ cells plated. Bone marrow fibroblast cultures using agar or methylcellulose restrict colony formation. Marked colony suppression was observed in acute leukemia, and a discrete colony number was observed in hypoplastic anemia. This fibroblast culture method should be applied to a larger number of patients to determine whether it has a pathognomonic value and clinical significance.     

The possible pathways of IL-2 stimulation of colony formation by bone marrow cells irradiated in vitro

The authors have made an attempt to find out the reasons of IL-2 stimulation of spleen colony growth by in vitro (1 Gy) irradiated bone marrow cells. It was shown that the effect of IL on haemopoiesis manifests itself with merely small radiation doses implying that the influence of the preparation makes the process of haemopoietic organ repopulation start at a higher level of cell survival, which is presumably related to a more active repair of radiation-induced CFUs damages: this leads, with other things being equal (e.g. proliferation rate and f factor), to a higher yield of colonies than it is observed with the recipients protected with the exposed bone marrow only.     

Renewal of hematopoietic stem cell clones in long-term bone marrow cultures

In long-term cultures of murine bone marrow, clonal succession of hemopoietic cells was observed as measured by karyologic analysis. There were high oscillations in self-renewal of CFUs in the cultures. A close correlation between the CFUmix karyotype and mitotic non-adherent cells in culture (but not between these cell types and CFUs) was revealed.     

Adipose conversion of mouse bone marrow fibroblasts in vitro: their alkaline phosphatase activity

By an in vitro colony assay and cytochemical staining, we investigated the capacity of mouse bone marrow fibroblasts to differentiate into adipocytes and to express alkaline phosphatase (ALP) activity. Glucocorticoids enhanced colony formation of the fibroblasts, and stimulated their adipose conversion (55-65% of the colonies became adipocyte-positive), but they did not affect ALP activity. The fibroblasts became heterogeneous in size and morphology after growing in vitro then differentiated into adipocytes. All the cell types had ALP activity, and more than 95% of the colonies contained ALP-positive cells. ALP staining was strongest in cells in the early stage of adipose conversion, gradually decreasing with maturation. Our results indicate that the majority of the mouse bone marrow fibroblasts that formed colonies under our culture conditions are preadipocytes. We conclude that these fibroblasts originate from adventitial reticular cells present in bone marrow stroma because reticular cells have been reported to possess high ALP activity and have been suggested to differentiate into adipocytes.     

Factors affecting the generation of mast cells from multipotential colony-forming cells

The cells responsible for the long-term in vitro generation of murine mast cells have been examined. Sequential analysis of all colony types obtained from cultures of spleen or bone marrow cells showed that only colonies derived from multipotential cells (mixed-erythroid colonies) or mast cell progenitors, contained cells responsible for mast cell generation in liquid cultures. Primary colony growth and subsequent maintenance of mast cells in liquid cultures was dependent upon pokeweed mitogen-stimulated spleen cell-conditioned medium (SCM). Mixed-erythroid colonies from 14-day cultures of spleen cells had the greatest capacity for mast cell generation. Analysis by clone splitting and transfer to high (20%) and low (2.5%) concentrations of SCM showed that the concentration of SCM used in either the primary colony culture or subsequent liquid culture phase altered both the proliferative capacity of the mast cells generated and the frequency of mast cell progenitors within individual mixed-erythroid colonies. Thus, mixed-erythroid colonies stimulated with 2.5% SCM contained the highest proportion of mast cell progenitors (34% of colonies) and when stimulated with 20% SCM, approximately fourfold higher numbers of mast cells were produced at weekly intervals from liquid cultures maintained in 2.5% SCM compared to parallel liquid cultures containing 20% SCM. These studies confirm the hemopoietic origin of mast cells and demonstrate that a factor(s) in SCM is able to modulate their proliferative potential.     

Elimination from bone marrow of a supplementary population participating in the proliferation of pluripotent hematopoietic stem cells using mouse brain antiserum

Changes in the number of spleen exo-colonies and post-radiation repopulation of hematopoietic organs were studied in recipients upon injection of bone marrow treated with anti-brain serum (ABS) with and without thymocytes on days 9-14. It was shown that on days 9-11 colony formation in mice injected bone marrow treated with ABS was much lower than the control level. However, by day 14 the number of colonies increased drastically as compared to the control. Thymocyte supplementation normalized colony formation at any time of observation. Similar pattern is noted in post-radiation repopulation of spleen and bone marrow of mice injected bone marrow pretreated with ABS with or without thymocytes. It is assumed that ABS inactivates bone marrow cells participating in the regulation of CFUs proliferation.     

Automated counting of bacterial colony forming units on agar plates

Manual counting of bacterial colony forming units (CFUs) on agar plates is laborious and error-prone. We therefore implemented a colony counting system with a novel segmentation algorithm to discriminate bacterial colonies from blood and other agar plates.A colony counter hardware was designed and a novel segmentation algorithm was written in MATLAB. In brief, pre-processing with Top-Hat-filtering to obtain a uniform background was followed by the segmentation step, during which the colony images were extracted from the blood agar and individual colonies were separated. A Bayes classifier was then applied to count the final number of bacterial colonies as some of the colonies could still be concatenated to form larger groups. To assess accuracy and performance of the colony counter, we tested automated colony counting of different agar plates with known CFU numbers of S. pneumoniae, P. aeruginosa and M. catarrhalis and showed excellent performance.     

The influence of dietary protein deficiency on haemopoietic cells in the mouse.

These experiments examined the effect of a diet limited only in protein (4% by weight) on haemopoietic stem cells in mice. This diet places severe restrictions on growth and cell proliferation and this was reflected in lower numbers of colony forming units (CFUs) and in vitro colony forming cells (CFCs). Differences were apparent in the response of different organs to this stress; for instance, the incidence of spleen CFUs fell sharply from around 40/mg spleen tissue to 1-4/mg spleen tissue after 3 weeks on a low protein diet. This selective loss did not occur in bone marrow where total CFUs remained proportional to cellular content. Yet a third pattern was shown by thymus CFUs--although the numbers were low these increased from 16/thymus in normal mice to 132/thymus in deprived mice. This was the only organ examined which showed an increase. The effects of a return to a high protein (18%) diet showed that the spleen was the most responsive organ. By day 5 after the return to 18% protein the spleen contained as many CFUs per million cells as the bone marrow. During this time the content of CFU in the spleen had increased some 50-fold whereas bone marrow CFUs only doubled. The spleen assumes the major reconstructive role during the refeeding process.     

THE INFLUENCE OF DIETARY PROTEIN DEFICIENCY ON HAEMOPOIETIC CELLS IN THE MOUSE

These experiments examined the effect of a diet limited only in protein (4% by weight) on haemopoietic stem cells in mice. This diet places severe restrictions on growth and cell proliferation and this was reflected in lower numbers of colony forming units (CFUs) and in vitro colony forming cells (CFCs). Differences were apparent in the response of different organs to this stress; for instance, the incidence of spleen CFUs fell sharply from around 40/mg spleen tissue to 1 -4/mg spleen tissue after 3 weeks on a low protein diet. This selective loss did not occur in bone marrow where total CFUs remained proportional to cellular content. Yet a third pattern was shown by thymus CFUs–although the numbers were low these increased from 16/thymus in normal mice to 132/thymus in deprived mice. This was the only organ examined which showed an increase. The effects of a return to a high protein (18 %) diet showed that the spleen was the most responsive organ. By day 5 after the return to 18% protein the spleen contained as many CFUs per million cells as the bone marrow. During this time the content of CFU in the spleen had increased some 50-fold whereas bone marrow CFUs only doubled. The spleen assumes the major reconstitutive role during the refeeding process.     

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.     

Hemoglobin switching in sheep and goats. VI. Commitment of erythroid colony-forming cells to the synthesis of betaC globin

Bone marrow from mature goats and sheep was cultured in plasma clots, and three erythropoietin (ESF)-dependent responses-growth (colony formation), differentiation (globin production), and initiation of hemoglobin C (alpha2beta2C) synthesis--were quantitated. ESF concentrations below 0.01 U/ml supported colony growth and adult hemoglobin production in cultures of goat marrow, while maximal hemoglobin C synthesis (70%), as measured between 72 and 96 h in culture, required a 100-fold higher ESF concentration. Sheep marrow was cultured in a medium enriched to enhance growth and to permit complete maturation of colonies. These colonies active in hemoglobin synthesis between 24 and 96 h produced mainly adult hemoglobin, and only between 96 and 120 h did sheep colonies develop which produced mainly hemoglobin C (up to 70%). A similar heterogeneity may exist among goat colonies. Thus, when goat bone marrow was fractionated by unit gravity sedimentation, more hemoglobin C synthesis was observed in colonies derived from cells of intermediate sedimentation velocity than in colonies derived from the most rapidly sedimenting cells. Brief exposure of sheep (in vivo) and goat (in vitro) bone marrow to a high ESF concentration committed precursor cells to the generation of colonies which, even at low ESF concentration, produced hemoglobin C. Committment to hemoglobin phenotype appears to be an early and probably irreversible event in the development of an erythroid cell.     

DNA topoisomerase inhibitors block erythropoiesis and delay hemoglobinization in vitro

To examine the importance of topological constraints on DNA during erythroid development, we measured the effects of camptothecin and teniposide, two tumoricidal agents which are also specific inhibitors of type I and type II topoisomerases respectively, on the formation of hematopoietic colonies by cultured human bone marrow cells. When added to bone marrow culture, each inhibitor alone impairs the formation of early BFU-E-derived colonies, late CFU-E-derived colonies and mixed hematopoietic (CFU-GEMM-derived) colonies by up to 100%. Inhibition of colony formation is directly related to the time of inhibitor addition and the inhibitor concentration tested. Although either inhibitor alone reduces colony formation by 90%, when added together at a submaximal concentration, camptothecin and teniposide exert a synergistic suppressive effect. Furthermore, addition of topoisomerase inhibitors to culture impairs hemoglobinization of colony erythroblasts in a time-dependent fashion. In contrast to the effects of topoisomerase inhibitors, the antiproliferative agent aphidicolin reduces erythroid colony number and size without altering hemoglobinization of colony erythroblasts. Since neither topoisomerase inhibitor alters the morphology of cultured cells, the capacity of cells to exclude trypan blue or the potential to form erythroid colonies through the interval required for the first progenitor cell division, it is unlikely that camptothecin or teniposide are cytotoxic to hematopoietic cells. Human mononuclear cells enriched in bone marrow lymphocytes and nucleated erythroblasts from both human and mouse sources release DNA into the detergent soluble fraction. Release requires functional topoisomerases and is altered by acute exposure to topoisomerase inhibitors. Our results suggest that topoisomerases are critical not only to proliferation but also to differentiation of human marrow erythroid progenitor cells and stem cells in culture.     

Cimetidine induced pancytopenia. Effect on human CFU-MIX colony formation

We describe a 26 year-old male with a pancytopenia possibly due to cimetidine. Using progenitor cell culture techniques we investigated the mechanism of this bone marrow toxicity. Our results show a cimetidine dose-dependent inhibition of normal human CFU-GM colony formation as described by Fitchen and Koeffler in 1980. No differences in growth inhibition were found between the patients' recovery marrow and the controls. Toxicity on normal human CFU-MIX colony formation was, however, far more pronounced. At concentrations as low as 5 micrograms/ml the numbers of CFU-MIX colonies were decreased by almost 20% and more than 30% in cultures of two normal bone marrow samples. A significant decrease in CFU-MIX colony size was measured even at therapeutic levels (0.5 micrograms/ml). No obvious decrease in CFU-GM colony size was noticed at low concentrations. Experiments with T-cell- and monocyte-depleted bone marrow samples gave similar results: a pronounced inhibition of the CFU-MIX colony formation at low concentrations of cimetidine whereas the CFU-GM formation was less affected. It is therefore very unlikely that Accessory cells play part in the cimetidine induced CFU-MIX inhibition. Our results suggest the existence of H2 histamine receptors on human CFU-MIX (= multipotent progenitor cell). Blocking these receptors prevents the multipotent progenitor cell from going into the DNA-synthesis phase of the cell cycle.     

Osteoblast migration on poly(alpha-hydroxy esters)

We investigated the migration of rat calvaria osteoblast populations on poly(alpha-hydroxy ester) films for up to 14 days to determine effects of substrate composition and culture conditions on the migratory characteristics of osteoblasts. Initial osteoblast culture conditions included cell colonies formed by seeding a high (84,000 cells/cm(2)) or low (42,000 cells/cm(2)) density of isolated osteoblasts on the polymer films, and bone tissue cultures formed by plating bone chips directly on the substrates. High density osteoblast colonies cultured and allowed to migrate and proliferate radially on 85:15 poly(DL-lactic-co-glycolic acid) (PLGA) films, 75:25 PLGA films, and tissue culture polystyrene controls demonstrated that the copolymer ratio in the polymer films did not affect the rate of increase in substrate surface area (or culture area) covered by the growing cell colony. However, the rate of increase in culture area was dependent on the initial osteoblast seeding density. Initial cell colonies formed with a lower osteoblast seeding density on 75:25 PLGA resulted in a lower rate of increase in culture area, specifically 4.9 +/- 0.3 mm(2)/day, versus 14.1 +/- 0.7 mm(2)/day for colonies seeded with a higher density of cells on the same polymer films. The proliferation rate for osteoblasts in the high and low density seeded osteoblast colonies did not differ, whereas the proliferation rate for the osteoblasts arising from the bone chips was lower than either of these isolated cell colonies. Confocal and light microscopy revealed that the osteoblast migration occurred as a monolayer of individual osteoblasts and not a calcified tissue front. These results demonstrated that cell seeding conditions strongly affect the rates of osteoblast migration and proliferation on biodegradable poly(alpha-hydroxy esters). (c) 1996 John Wiley & Sons, Inc.     

Differentiation of stem cells from different parts of the hematopoietic system of adult thymectomized CBA mice stimulated with thymarin or cortexine

Essential differences were detected in differentiation of GFUs from bone marrow and peripheral blood. It was shown that as a result of thymectomy of adult animals the ability of bone marrow CFUs to form granulocytic colonies decreased and that of splenic CFUs to form erythroid colonies increased. The immunostimulating low-molecular-weight polypeptides, thymarin and cortexine , normalized the differentiation of CFUs from bone marrow and spleen but interfered with the formation of erythroid colonies from CFUs of peripheral blood of thymectomized mice.