Growth of erythroid colonies in agar cultures of normal human bone marrow

The use of methylcellulose (MC) gels or plasma clots, for the support of human erythropoiesis in vitro, is associated with several technical disadvantages. Substitution of soft agar offers the prospect of overcoming these difficulties. In comparative studies, normal human bone marrow cells were cultured with erythropoietin (Epo) in agar (0.1%-0.3%) and MC. Concentrations of 0.175% and 0.2% agar proved to be optimal with respect to the combination of cloning efficiency and colony density. Further morphological examination revealed that subcolony formation in erythroid 'bursts' was influenced by gel viscosity. In additional experiments, miniaturising the assay system, to 0.25 ml culture volumes, increased cloning efficiency and reduced Epo utilization. These results confirm and expand earlier observations, and support a preference for the general use of agar in human erythroid cell cultures.     

Anti-HIV drugs: comparative toxicities in murine fetal liver and bone marrow erythroid progenitor cells

The toxicity of anti-HIV drugs, 3'-azido-3'-deoxythymidine (zidovudine, AZT), 2',3'-dideoxycytidine (DDC), 2',3'-dideoxy-2',3'-didehydrothymidine (d4T) and ribavirin was studied in vitro in murine fetal liver cells (FLC) and in bone marrow cells. These studies indicate that d4T is the least toxic drug and ribavirin is the most toxic agent in both models. However, the murine FLC system was found to be a more sensitive model for the assessment of toxicity of anti-HIV agents towards erythroid progenitor cells as indicated by the IC50 values.     

Proliferation and differentiation of normal granulopoietic cells in continuous bone marrow cultures.

Modified conditions are reported for successful continuous bone marrow cultures with stem cell self-renewal and granulocyte-macrophage differentiation. Cells cultured over several weeks were found to be identical to freshly isolated bone marrow cells. Polymorphic neutrophils derived from cultures and primary bone marrow neutrophils both showed C3 AND IgG receptors and both actively phagocytosed foreign particles. Cultured and normal CFU-c were identical, both in their dose responsiveness to CFS and in their sedimentation rate characteristics.     

Pluripotential stem cell replication in continuous human, prosimian, and murine bone marrow culture

Prolonged replication of pluripotential stem cells and committed progenitor cells is sustained for prolonged periods in a murine marrow culture system. Alterations in stem cell replication and differentiation are observed after infection of the cultures with Friend virus and Kirsten sarcoma virus consistent with transformation of pluripotential stem cells in the first case and transformation of the macrophage component of the hemopoietic microenvironment in the second. Prolonged myelopoiesis and CFU-c proliferation was also observed in continuous human and prosimian marrow cultures, suggesting the applicability of this technique for analysis of stem cell control and in vitro leukemogenesis in species other than the mouse.     

Generation of natural killer cell lines from murine long-term bone marrow cultures

Functionally active natural killer (NK) cells with the ability to lyse 51Cr-labeled YAC-1 lymphoma target cells are no longer detectable by 1 wk of culture in cultured marrow cells harvested from Dexter-type long-term marrow cultures (LMC). Interferon, which enhances NK cell-mediated target cell lysis, fails to induce NK activity from LMC cells even at high effector to target cell ratios. However, such LMC cells, when placed in secondary cultures in the presence of Con A-splenic leukocyte-conditioned medium (spleen-CM) generated a population of cells with NK activity within 1 wk. Kinetic studies showed that the generation of NK activity was not due simply to proliferation of a few surviving NK cells, but suggested derivation from NK precursors through clonal expansion and functional maturation. This NK activity was further shown to be associated with a subpopulation of cells bearing surface Thy-1, Ly-5, and NK-1 as well as asialo-GM1 antigens but lacking Ly-1 antigen. The expression of Ly-2 antigen, however, was variable. Electron microscopy studies of isolated asialo-GM1-positive cells showed a uniform lymphoblastoid morphology with large cytoplasmic to nuclear ratios and prominent electron dense cytoplasmic granules characteristic of large granular lymphocytes. In support of the NK nature of such cultured cells was the ability of anti-asialo-GM1 and complement to abrogate, and of interferon to augment, target cell lysis. Isolated cell lines also showed target selectivity similar to NK cells. The implications of the studies on further analysis of the nature of NK precursors is discussed.     

In-vitro circadian rhythm of murine bone marrow progenitor production

Hematopoietic processes display 24h rhythms both in rodents and in human beings. We hypothesized these rhythms to be in part generated by a circadian oscillator within the bone marrow. The ability of murine bone marrow granulo-monocytic (GM) precursors to form colonies following colony-stimulating factor (rm GM-CSF) exposure was investigated in liquid culture samples obtained every 3 h for a span of up to 198 h. The CFU-GM count varied rhythmically over the first 4 d of culture, with a reproducible maximum in the early morning hours, similar to that observed in vivo. These experiments provide the first evidence that bone marrow progenitors sustain in vitro circadian rhythmicity, and they demonstrate the presence of a circadian time-keeping system within these cells. The results support the potential usefulness of bone marrow cultures for investigating chronopharmacologic effects of anticancer drugs and cytokines on this target system.     

In-vitro circadian rhythm of murine bone marrow progenitor production

Hematopoietic processes display 24h rhythms both in rodents and in human beings. We hypothesized these rhythms to be in part generated by a circadian oscillator within the bone marrow. The ability of murine bone marrow granulo-monocytic (GM) precursors to form colonies following colony-stimulating factor (rm GM-CSF) exposure was investigated in liquid culture samples obtained every 3 h for a span of up to 198 h. The CFU-GM count varied rhythmically over the first 4 d of culture, with a reproducible maximum in the early morning hours, similar to that observed in vivo. These experiments provide the first evidence that bone marrow progenitors sustain in vitro circadian rhythmicity, and they demonstrate the presence of a circadian time-keeping system within these cells. The results support the potential usefulness of bone marrow cultures for investigating chronopharmacologic effects of anticancer drugs and cytokines on this target system.     

Frequent harvesting from perfused bone marrow cultures results in increased overall cell and progenitor expansion

The establishment of prolific long-term human bone marrow cultures has led to the development of hematopoietic bioreactor systems. A single batch expansion of bone marrow mononuclear cell populations leads to a 10- to 30-fold increase in total cell number and in the number of colony forming units-granulocyte/macrophage (CFU-GMs), and a four- to tenfold increase in the number of long-term culture initiating cells (LTC-ICs). In principle, unlimited expansion of cells should be attainable from a pool of stem cells if all the necessary requirements leading to stem cell maintenance and division are met. In this article, we take the first step toward the identification of factors that limit single batch expansion of ex vivo bone marrow cells in perfusion-based bioreactor systems. One possible constraint is the size of the growth surface area required. This constraint can be overcome by harvesting half the cell population periodically. We found that harvesting cells every 3 to 4 days, beginning on day 11 of culture, led to an extended growth period. Overall calculated cell expansion exceeded 100-fold and the CFU-GM expansion exceeded 30-fold over a 27-day period. These calculated values are based on growth that could be obtained from the harvested cell population. Growth of the adherent cell layer was stable, whereas the nonadherent cell population diminished with increasing number of passages. These results show that the bioreactor protocols published to date are suboptimal for long-term cultivation, and that further definition and refinement is likely to lead to even greater expansion of hematopoietic cell populations obtained from bone marrow. More importantly, these results show that the LTC-IC measured during the single pass expansion do have further expansion potential that can be realized by frequent harvesting. Finally, the present culture conditions provide a basis for an assay system for the identifications provide a basis for an assay system for the identification of the factors that determine the long-term maintenance and replication of human stem cells ex vivo. (c) 1994 John Wiley & Sons, Inc.     

Detection of murine bone marrow granulocyte/macrophage progenitor cells (GM-CFU) in serum-free cultures stimulated with purified M-CSF or GM-CSF

Colony formation by mouse granulocyte/macrophage progenitors (GM-CFU) responding to purified colony-stimulating factors (CSF) in serum-free cultures is described. Analysis of the lipid requirements for colony growth stimulated by purified macrophage CSF (M-CSF) demonstrated that cholesterol is essential. Linoleic acid further promoted colony growth only if cholesterol was present, but phospholipid was inhibitory. More colonies were obtained in serum-free cultures, than in serum-supplemented controls. This difference could not be attributed to a change in the range of sensitivity to M-CSF. Stimulation of GM-CFU with granulocyte/macrophage CSF (GM-CSF) required further supplementation with hydrocortisone for optimal expression of colony-forming capacity in serum-free cultures. Hydrocortisone slightly inhibited colony growth stimulated with M-CSF. Under these culture conditions, the number of GM-CFU responding to GM-CSF was twice that obtained with M-CSF.     

Hemoglobin and ferritin synthesis in erythroid cells in prolonged marrow cell cultures

A method is described which maintains viable erythroid cells in tissue culture for periods from nine to twenty days. These cells appear predominantly as small round cells with scanty cytoplasm. They synthesize both heme and globin and are relatively more numerous free in suspension than in the adherent monolayer. Ferritin isomorph may serve as a convenient marker in tissue culture of cells of erythroid origin, suggesting that such cells may persist despite a completely transformed appearance and a loss of the ability to produce hemoglobin.     

Comparative analysis of the effects of the unpurified preparations of murine erythropoietin and human recombinant erythropoietin on erythroid and granulocyte-macrophage progenitor cells in semi-solid mouse bone marrow cultures]

Effects of unpurified murine erythropoietin and unpurified human recombinant erythropoietin on the growth of erythroid--BFU-E and granulocyte--macrophage progenitor cells--CFU--GM from the mouse bone marrow were compared using a methylcellulose culture system. Average erythropoietin titers for murine serum and supernatant human recombinant erythropoietin were 16 U/ml and 33 U/ml, respectively. The maximal stimulation was observed at 1-2 U/ml culture recombinant erythropoietin and 0.5 U/ml culture murine erythropoietin. Murine erythropoietin was more effective then human one. Murine and human recombinant erythropoietin had no significant effect on the number of CFU-GM colonies. But human recombinant erythropoietin could be preferentially used when studying the mechanism of erythropoiesis in man and animals because there were erythropoiesis inhibitors in mouse serum.     

Characterization of capsid and noncapsid proteins of B19 parvovirus propagated in human erythroid bone marrow cell cultures.

The major capsid and noncapsid proteins of the pathogenic parvovirus B19, propagated in vitro, were detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, immunoprecipitation, and immunoblot of the erythroid fraction of infected human bone marrow cell cultures. There were two capsid proteins of 58 kilodaltons (kDa; the major species) and 84 kDa (the minor species). Newly synthesized capsid viral proteins were present in the supernatants of infected cultures. The major noncapsid protein of 77 kDa was localized to the nucleus.     

The in vitro differentiation of a bipotential glial progenitor cell.

We have studied the properties of a glial progenitor cell from 7-day-old rat optic nerve that differentiates in vitro into an oligodendrocyte if cultured in serum-free medium and into an astrocyte if cultured in foetal calf serum (FCS). Using galactocerebroside as a marker of oligodendrocyte differentiation and glial fibrillary acidic protein as a marker of astrocyte differentiation, we show that the acquisition of these marker molecules occurs rapidly in culture and requires both RNA and protein synthesis. We provide evidence that the effect of FCS on the development of the glial progenitor cell is not due to its influence on cell-substrate adherence or actin filament organization and is not mimicked by an increase in intracellular cyclic AMP, cyclic GMP or pH. The progenitor cell contains vimentin filaments and retains them on becoming an astrocyte but loses them on becoming an oligodendrocyte. Most importantly, we show that the choice of developmental pathway taken by the bipotential glial progenitor cells in culture is reversible for 1-2 days and then becomes fixed, at least under the conditions we studied.     

Pre-irradiation of tissue culture flasks leads to diminished stem and progenitor cell production in long-term bone marrow cultures

Abstract. Empty plastic tissue culture flasks were exposed to X-irradiation doses of 0.3–10.0 Gy, prior to the establishment of long-term bone marrow cultures. During the course of a 10 week culture period, all irradiated plastic flasks exhibited a dramatic decrease in the number of both haemopoietic stem cells and myeloid progenitor cells, in the non-adherent layer, when compared with controls. This decrease was not due to a decrease in the number of non-adherent cells produced. Histological examination of non-adherent cells showed an increase in mature granulocytic cells with few blast cells. Morphologically, the adherent layers of irradiated flasks demonstrated a delay in appearance or absence of fat cell production. X-irradiation of glass tissue culture flasks had no deleterious effect.     

Effect of medium osmolality on the growth of murine continuous marrow cultures

The effect of medium osmolality was examined in primary, continuous bone-marrow cultures established from TO strain mice. The non-adherent cell population increased exponentially between weeks 2 and 5 and thereafter declined steadily. The number of CFU-GM followed a similar pattern but showed greater variability. The optimum osmolality in 4 week old cultures was found to be about 345 mosmol/kg which was higher than the plasma osmolality (n = 20; mean = 323.3 mosmol/kg; range = 313-331). Maximum non-adherent cell numbers were found at about 345 mosmol/kg (better than half-maximum between 320 and 370 mosmol/kg). CFU-GM numbers in the culture supernatant were maximal at about 355 mosmol/kg (better than half-maximum between 320 and 400 mosmol/kg). An adherent layer developed over a wider range of osmolality than supported granulopoiesis (better than half-maximum between 258 and 402 mosmol/kg). It was necessary to increase the osmolality of Fischer's medium in order to obtain maximum growth.     

The mast cell-committed progenitor. In vitro generation of committed progenitors from bone marrow

Mast cell-committed progenitors are detected in the unique microenvironment of the mesenteric lymph node (MLN) of Nippostrongylus brasiliensis-infected mice but not in naive bone marrow. We have determined that MLN cells, after infection, produce high levels of IL-3, IL-4, and IgE, presumably in the form of immune complexes with antigens produced by the infecting helminth. After N. brasiliensis infection, peak production of these factors occurs several days before the peak appearance of mast cell-committed progenitors in the MLN. To determine if these factors play a role in mast cell commitment, we recreated these conditions, in vitro. Naive bone marrow cells were cultured with combinations of IL-3, IL-4, and IgE immune complexes, or on IgE-coated plates, and then assayed for acquisition of the ability to form mast cell colonies when supplemented with fibroblast-conditioned medium alone. IL-3 and IgE immune complexes, and, unexpectedly, IgE immune complexes alone were found to be capable of producing mast cell-committed progenitors, i.e., cells responsive to fibroblast-conditioned medium alone, from bone marrow, whereas IL-4 did not enhance production of mast cell-committed progenitors from bone marrow. Production of IFN-gamma peaked at the same time point as committed progenitor activity and may be responsible for down regulating the response.     

Cloning of early erythroid and mixed myeloid/erythroid human bone marrow progenitor cells: comparison of different sources of burst-promoting activity (BPA)

The ability of conditioned media from the 5637 cell line and human placenta (HPCM) to stimulate the in vitro growth of human early erythroid and mixed myeloid/erythroid clones was tested and compared to phytohemagglutinin-stimulated leukocyte supernatants (PHA-LCM). Both 5637 supernatant and PHA-LCM were equally effective with a linear dose-response relationship. HPCM at various concentrations did not exhibit burst-promoting activity (BPA). Thus, "pluripoietin"-containing media provide a large-scale source of BPA similar in its biological activity to standard sources used for studying human hematopoiesis in vitro.     

Haematopoietic stem cell content of murine bone marrow, spleen, and blood. Limiting dilution analysis of diffusion chamber cultures

Suspensions of mouse bone marrow cells, spleen cells, and blood leucocytes were cultured in diffusion chambers in dilution series in order to establish the minimum concentrations of haematopoietic stem cells (HSC). The observed frequencies of empty chambers after seven days of culture conformed to the expected frequencies of a null response in a Poisson distribution. The proportions of empty chambers could therefore be used to estimate the concentrations of HSC in the cell suspensions. The following numbers of HSC per 10⁵ cells were found (with 95% confidence limits): Bone marrow: 50 (44–56). Spleen: 3.5 (2.8–4.3). Blood leucocytes: 1.4 (1.2–1.8). The mean (± standard error) HSC-content per femur, spleen, and milliliter blood when pooling cells from three to six donor mice was 8240 ± 600, 7660 ± 490, and 56 ± 6.5 respectively. For comparison, the HSC concentrations were also determined with the spleen colony technique; the ratio between the HSC-concentrations of bone marrow, spleen, and blood determined with the diffusion chamber technique was similar to that determined with the spleen colony technique.     

Effects of cyclic pressure on bone marrow cell cultures

The present in-vitro study used bone marrow cell cultures and investigated the effects of cyclic pressure on osteoclastic bone resorption. Compared to control (cells maintained under static conditions), the number of tartrate resistant acid phosphatase (TRAP)-positive, osteoclastic cells was significantly (p<0.05) lower when, immediately upon harvesting, bone marrow cells were exposed to cyclic pressure (10-40 kPa at 1.0 Hz). In contrast, once precursors in bone marrow cells differentiated into osteoclastic cells under static culture conditions for 7 days, subsequent exposure to the cyclic pressure of interest to the present study did not affect the number of osteoclastic cells. Most important, exposure of bone marrow cells to cyclic pressure for 1 h daily for 7 consecutive days resulted in significantly (p<0.05) lower osteoclastic bone resorption and in lowered mRNA expression for interleukin-1 (IL-1) and tumor necrosisfactor-a (TNF-a), cytokines that are known activators of osteoclast function. In addition to unique contributions to osteoclast physiology, the present study provided new evidence of a correlation between mechanical loading and bone homeostasis as well as insight into the molecular mechanisms of bone adaptation to mechanical loading, namely cytokine-mediated control of osteoclast functions.