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.     

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.     

Simian immunodeficiency virus inhibits bone marrow hematopoietic progenitor cell growth.

The pathogenic mechanisms underlying the depressed hematopoietic functions seen in human immunodeficiency virus-infected individuals were explored in rhesus monkeys infected with the simian immunodeficiency virus of macaques (SIVmac). Bone marrow hematopoietic progenitor cell colony formation, both granulocyte/macrophage (CFU-GM) and erythrocyte (BFU-E), was shown to be decreased in number in SIVmac-infected rhesus monkeys. SIVmac was readily isolated from bone marrow cells of infected monkeys and was shown to be harbored in macrophages rather than T lymphocytes. The in vitro infection of normal bone marrow cells by SIVmac inhibited colony formation. A striking in vivo correlation between increased SIVmac load in bone marrow cells and decreased hematopoietic progenitor cell colony growth was also shown. Finally, inhibition of SIVmac replication in bone marrow macrophages resulted in increased progenitor cell colony growth from bone marrow cells. These results suggest that the infection of bone marrow macrophages by the acquired immunodeficiency syndrome (AIDS) virus may contribute to depressed bone marrow hematopoietic progenitor cell growth. Moreover, inhibition of AIDS virus replication in these macrophages might induce significant improvement in hematopoietic function.     

Spontaneous growth of colonies with mature T lineage phenotype from T-cell-depleted bone marrow precursors in a patient with a lymphoproliferative disorder of the large granular lymphocytes

Bone marrow cells from a patient with pancytopenia and a lymphoproliferative disorder of large granular lymphocytes (LGL) were cultured and tested for their hemopoietic colony-forming potential. Neither erythroid nor granulocyte-macrophage colony formation could be obtained from unfractionated, or LGL-depleted bone marrow cell preparations. However, a spontaneous growth of lymphoid colonies was observed after culturing LGL-depleted (T3-) bone marrow cell suspensions for 25 days. Pooled colonies expanded with recombinant interleukin-2 yielded a population composed predominantly of mature T cells (T3+, Leu 6-). These findings suggest that some (T3-) T cell precursors may mature in the bone marrow and that, in our patient, LGL may have exerted a suppressor effect on this maturational process.     

Inhibition of human bone marrow lymphoid progenitor colonies by antibodies to VLA integrins.

Studies in animal models suggest that the integrin adhesion protein VLA-4 may play an important role in lymphopoiesis. The relationship between cell adhesion and lymphopoiesis in humans has been difficult to study because of the relative rarity and stringent in vitro growth requirements of lymphoid progenitors from normal adult human bone marrow. To determine the functional significance of VLA-4-mediated adhesion in human lymphopoiesis, we developed a culture system in which a bone marrow-derived adherent layer supports the formation of colonies of terminal deoxynucleotidyl transferase (TdT)-positive lymphoid precursor cells from normal adult human bone marrow. Limiting dilution studies were consistent with clonal origin of these colonies. CFU-TdT were enriched in the CD34+ bone marrow fraction, consistent with CD34 expression by other hematopoietic progenitors. CD34 expression and lack of lineage-specific markers in a significant proportion of the TdT+ colony cells suggest that the TdT+ CFU may represent an uncommitted lymphoid progenitor cell. Development of TdT+ colonies required direct contact with the adherent layer and was significantly inhibited by specific anti-VLA-4 alpha chain antibody, suggesting a functional role for the previously reported VLA-4-dependent adhesion of human B cell precursors to bone marrow-derived fibroblasts.     

Quantitative investigation of stem cell candidates in the bone marrow of growing guinea pigs.

Possible candidates for hemic stem cells were studied in a quantitative investigation of the bone marrow of growing guinea pigs. The stem cell candidates were classified as lymphoid cells of types I-IV, roughly corresponding to small lymphocytes, large lymphocytes, micromyeloblasts and myeloblasts of other authors. The cellular content of the bone marrow of guinea pigs of three different ages was determined. All types of nucleated cells per femur were found to increase with age. When the cellular content was related to the body weight, a peak number of lymphoid cells was found in the intermediate age group with the exception of the lymphoid cells of type III, which reached its peak in the oldest animals. This cell type has been suggested by Dicke et al. as the probable stem cell responsible for colony formation.     

Studies on colony formation in vitro by mouse bone marrow cells. II. Action of colony stimulating factor

An analysis was made of some of the processes involved in the stimulation by colony stimulating factor (CSF) of cluster and colony formation by mouse bone marrow cells in agar cultures in vitro. Colony formation was shown to be related to the concentration and not the total amount of CSF. The concentration of CSF determined the rate of new cluster initiation in cultures and the rate of growth of individual clusters. Colony growth depleted the medium of CSF suggesting that colony cells may utilise CSF during proliferation. Bone marrow cells incubated in agar in the absence of CSF rapidly died or lost their capacity to proliferate and form clusters or colonies. CSF appears (a) to be necessary for survival of cluster-and colony-forming cells or for survival of their proliferative potential, (b) to shorten the lag period before individual cells commence proliferation and (c) to increase the growth rate of individual clusters and colonies.     

Characterization of early B lymphocyte precursors present in long-term bone marrow cultures

Lymphoid precursor cells are present in long-term bone marrow cultures (LTBMC), but their differentiation into mature lymphocytes is blocked. A quantitative assay for B cell precursors in LTBMC, which gives a linear relationship between the number of grafted LTBMC cells and the frequency of B cell colony forming units (CFU-B) in the spleen and bone marrow of immunodeficient CBA/N mice 19 days after reconstitution, is described. Characterization of the B cell precursor indicates that this assay is detecting a very early precursor and not a B lymphocyte or a late pre-B cell. This conclusion is based on the observations that a) pre-B cells transformable by Abelson murine leukemia virus are not present in LTBMC by 3 days postrecharge and CFU-B are absent by 6 days postrecharge; b) late B cell progenitors capable of rapid repopulation of irradiated CBA/N mice are not present in LTBMC, since a lag in the kinetics of B cell reconstitution in animals grafted with LTBMC cells is observed compared with fresh bone marrow cells; c) the B cell precursors in LTBMC have high proliferative potential, since they can stably repopulate recipient mice for at least 8 wk postreconstitution and through two serial passages in irradiated CBA/N recipients; and d) the B cell precursors are large, rapidly sedimenting cells as determined by velocity sedimentation. The serial transplantation experiment further shows that a split is often observed between lymphoid and myeloid reconstituting ability of LTBMC cells. The LTBMC B cell precursor may be a pluripotent stem cell or a lymphoid stem cell, although its differentiative potential remains to be determined.     

Histology of the bone marrow antibody response

The histology of the specific and non-specific antibody response in mouse and rat bone marrow was studied after subcutaneous priming and intravenous boosting with horseradish peroxidase (HRP). Cells producing specific antibody against HRP were found only occasionally in the bone marrow after subcutaneous priming. After the intravenous boost injection their number gradually increased. These anti-HRP forming cells were found as single cells, randomly dispersed throughout the bone marrow. Such a random distribution was also found for cytoplasmic (non-specific) immunoglobulin containing cells. At no time point after immunization could lymphoid aggregates or trapping of immune complexes be observed in the bone marrow of either species. On the basis of these observations it is concluded that the bone marrow forms a suitable microenvironment for immigrating antibody-forming cells but does not contribute actively to the induction of the immune response.     

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.     

Influence of thymectomy on the lymphoid regeneration of hematopoietic bone marrow after sublethal irradiation]

In C57BL mice, bone marrow lymphoid regeneration after a sublethal irradiation is modified by a graft of normal marrow cells. This effect is suppressed in thymectomized mice since a lymphoid peak is observed after a 350 R irradiation; its composition is heterogeneous: small lymphocytes, lymphoblasts and peculier cells named "X cells". The same phenomenon is observed in mice where all the thymocytes and thymus derived and peripheral lymphocytes are destroyed. These results exclude that bone marrow lymphoid regeneration after irradiation is due to a migration of lymphoid cells of thymic origin to the marrow. They could be explained by the effect of a humoral thymic factor on marrow lymphopoiesis.     

Influence of growth hormone on bone marrow adipogenesis in hypophysectomized rats

The hypophysectomized rat has been used as a model to study the effects of growth hormone deficiency on bone. Here, we have investigated the influence of growth hormone administration to hypophysectomized rats (HX) for 6 wk on accumulation of triglycerides in bone marrow and on the differentiation of primary marrow stromal cells into adipocytes under in vitro conditions. We found that hypophysectomy significantly increased triglyceride concentration in bone marrow, which was attenuated by growth hormone administration. Primary bone marrow stromal cells derived from HX rats also had more adipocytes at confluence compared with growth hormone-treated hypophysectomized (GH) rats. When stimulated with 3-isobutyl-1-methylxanthine plus dexamethasone (IBMX-Dex), preadipocyte colony counts increased more significantly in GH rats. Markers of adipocyte differentiation were higher in HX than in control or GH rats at confluence. However, after stimulation with IBMX-Dex, increased expression of markers was seen in GH compared with HX rats. In conclusion, growth hormone administration to hypophysectomized rats attenuated triglyceride accumulation in bone marrow and inhibited the differentiation of stromal cells into adipocytes in vitro.     

Effect of anti-mouse brain serum on the CFUc in actively proliferating bone marrow

With hydroxyurea injected to donor mice a greater inhibition of splenic colony growth occurred after incubation of a bone marrow suspension with the rabbit antimouse brain serum (RAMBS), and restoration of the colony-formation by thymocytes was less pronounced than in normal bone marrow treated with the antibrain serum. The incubation of the bone marrow cells containing CFUc, which actively proliferate after irradiation or stimulation by vinblastine, with the antibrain serum sharply suppressed the splenic colony growth. In this case however, in contrast to normal bone marrow, the administration of thymocytes failed to exert a favourable action on the colony formation. It is suggested that functioning of accessory cells is not associated with the defined cell cycle stage of CFUc and that, in addition to the previously discovered accessory cell population, some other factors, inactivated by the RAMBS serum, are present in the bone marrow the analogue of which is absent in the thymus.     

Blast colony-forming cell binding from CML bone marrow, or blood, on stromal layers pretreated with G-CSF or SCF

Blast colony-forming cells (CFU-BL) represent a specific subpopulation of special primitive progenitors characterized by colony formation only in close contact with a preformed stromal layer. CFU-BL derived from bone marrow of chronic myeloid leukaemia (CML) patients have been proved to adhere poorly to bone marrow derived stromal layers suggesting that the appearance of progenitors and precursors in the circulation is due to a defective adhesion of these cells to the bone marrow microenvironment. In the present experiments the effect of short-term incubation of preformed normal bone marrow stroma on the adherence of CML derived CFU-BL was studied. For stroma cultures bone marrow cells were cultured in microplates in the presence of hydrocortisone. Cultures were used when stromal layers became confluent and no sign of haemopoiesis could be observed. CFU-BL were studied by panning plastic non-adherent mononuclear (PNAMNC) bone marrow or blood cells. 8.9 +/- 2.4 colonies/103 PNAMNC (six experiments) were formed from normal bone marrow on stromal layers and 4.8 +/- 2.1 colonies/103 PNAMNC (five experiments) from CML bone marrow. Colony formation from normal bone marrow was not increased if stromal layers were incubated with 100 ng/mL granulocyte colony-stimulating factor (G-CSF) or stem cell factor (SCF). Incubation of stroma with G-CSF or SCF, however, increased the colony formation of PNAMNC from CML bone marrow or blood significantly. These findings suggest that local concentration of haemopoietic growth factors at the time of panning may influence the attachment of CML progenitors to the stroma.     

Biological aspects of limb transplantation: I. Migration of transplanted bone marrow cells into recipient

The transplanted limb contains bone marrow tissue. The hematopoietic cells contained in the bone of the graft normally differentiate after transplantation and can be released to the recipient. The cells migrate to the recipient bone marrow cavities and lymphoid organs. This causes the immune reaction between the donor and the recipient, which develops not only in the graft itself but also in the recipient immune organs where donor bone marrow cells home. The purpose of this study was to investigate the process of migration of the hematopoietic cells from the donor limb to the recipient bone marrow cavities and lymphoid tissues. The questions the authors asked were: what is the rate of release of bone marrow cells from the transplanted bone, where do the released bone marrow cells home in the recipient, how fast are donor bone marrow cells rejected by the recipient, and can some bone marrow cells homing in the recipient tissues survive and create a state of microchimerism. Experiments were performed on Brown Norway and Lewis inbred rat strains (n = 30). Limb donors received intravenous chromium-51-labeled bone marrow cells. Twenty-four hours later, the limb with homing labeled bone marrow cells was transplanted to an allogeneic or syngeneic recipient. The rate of radioactivity of bone marrow cells released from the graft and homing in recipient tissues was measured after another 24 hours. To eliminate factors adversely affecting homing such as the "crowding effect" and allogeneic elimination of bone marrow cells by natural killer cells, total body irradiation and antiasialo-GM1 antiserum were applied to recipients before limb transplantation. In rats surviving with the limb grafts for 7 and 30 days, homing of donor bone marrow cells was studied by specific labeling of donor cells and flow cytometry as well as by detecting donor male Y chromosome. The authors found that transplantation of the limb with bone marrow in its natural spatial relationship with stromal cells and blood perfusion brings about immediate but low-rate release of bone marrow cells and their migration to recipient bone marrow and lymphoid tissues. Large portions of allogeneic bone marrow cells are rapidly destroyed in the mechanism of allogeneic elimination by radioresistant but antiasialo-GM1-sensitive natural killer cells. Some transplanted bone marrow cells remain in the recipient's tissues and create a state of cellular and DNA microchimerism. A low number of physiologically released donor bone marrow cells do not seem to adversely affect the clinical outcome of limb grafting. Quite the opposite, a slight prolongation of the graft survival time was observed.     

The xid mutation affects hemopoiesis in long term cultures of murine bone marrow

Cells of the humoral immune system are particularly affected by a mutation at the X chromosome linked immunodeficiency disease (xid)locus. Although B cells are made in normal numbers, they fail to become phenotypically and functionally diverse. Consequently, poor antibody responses are mounted to certain types of Ag. There have been some indications that other types of hemopoietic cells may be influenced by the mutation and development of the humoral immune system is unusually dependent on the presence of T lymphocytes. We now describe an analysis of the lympho-hemopoietic environment studied with long term bone marrow cultures. Contrary to expectations, cultures initiated with cells from homozygous female or hemizygous male mice with the mutant allele established more quickly than normal. The accelerated initial growth pattern was clearly linked to the xid mutation. Artificial mixtures of marrow exhibited intermediate growth kinetics. Experiments with H-2 congenic and T6 chromosome marked cells did not reveal an intrinsic dominance of growth in nonadherent xid cells. Similar results were obtained with culture conditions which favored production of myeloid or lymphoid cells. These findings would be consistent with subtle changes in the bone marrow microenvironment resulting from the xid mutation. The pedigree of the mouse strains had a significant influence on lymphopoiesis in long term bone marrow cultures. Lymphocytes of BALB/c origin dominated over CBA/H background cells in cultures established from mixtures of the two, but this did not correlate with any functional deficiency in CBA/H stromal cells. In fact, establishment of an adherent layer was a rate-limiting step in initiating long term cultures and this could be achieved with a low dose inoculum of CBA/H marrow. Even more dramatic effects were found in hemopoietic cells from doubly defective C3H.nu/nu-xid mice. The bone marrow of these athymic animals contained normal numbers of granulocyte/macrophage progenitors. However, lymphoid cultures could not be reproducibly established with their cells and myelopoiesis was never observed in vitro. The relatively simple conditions which pertain in culture make it possible to appreciate effects of mutations and pedigree on hemopoiesis which are unremarkable in intact animals.     

Interleukine-17-induced inhibitory effect on late stage murine erythroid bone marrow progenitors

Recent studies have shown that the T cell-derived cytokine, interleukin-17 (IL-17), stimulates hematopoiesis, specifically granulopoiesis inducing expansion of committed and immature progenitors in bone marrow. Our previous results pointed to its role in erythropoiesis too, demonstrating significant stimulation of BFU-E and suppression of CFU-E growth in the bone marrow from normal mice. As different sensitivities of erythroid and myeloid progenitor cells to nitric oxide (NO) were found, we considered the possibility that the observed effects of IL-17 were mediated by NO. The effects of recombinant mouse IL-17, NO donor (sodium nitroprusside - SNP) and two NO synthases inhibitors (L-NAME and aminoguanidine) on erythroid progenitor cells growth, as well as the ability of IL-17 to induce nitric oxide production in murine bone marrow cells, were examined. In addition, we tested whether the inhibition of CFU-E colony formation by IL-17 could be corrected by erythropoietin (Epo), the principal regulator of erythropoiesis. We demonstrated that IL-17 can stimulate low level production of NO in murine bone marrow cells. Exogenously added NO inhibited CFU-E colony formation, whereas both L-NAME and aminoguanidine reversed the CFU-E suppression by IL-17 in a dose-dependent manner. The inhibition of CFU-E by IL-17 was also corrected by exposure to higher levels of Epo. The data obtained demonstrated that at least some of the IL-17 effects in bone marrow related to the inhibition of CFU-E, were mediated by NO generation. The fact that Epo also overcomes the inhibitory effect of IL-17 on CFU-E suggests the need for further research on their mutual relationship and co-signalling.     

Factors in the cryopreservation of bone marrow cells from children with acute lymphocytic leukemia.

Bone marrow cells from 42 children with acute lymphocytic leukemia in remission and 19 normal adults were preserved in liquid nitrogen for periods of up to 50 weeks. Many factors in the process of cryopreservation were investigated in an attempt to optimize the recovery of the bone marrow colony forming cells. The effect of cryopreservation on the cells which produce colony stimulating activity also was investigated. With optimization of this technique, it was observed that approximately 100% of the bone marrow nucleated cells were recovered and approximately 50% of the total colony forming cells were viable after 50 weeks in liquid nitrogen.     

Human bone marrow colony growth in agar-gel

A technique for growing human bone marrow cell colonies in agar-gel medium is described. “Feeder layers” containing 1 × 10⁶ normal human peripheral white blood cells are used as the stimulus for colony growth. Human bone marrow aspirates are collected in heparinized syringes and plated as 2 × 10⁵ cells on “feeder layers.” Normal human bone marrow yields 32–102 colonies per 2 × 10⁵ cells plated. Colonies are almost exclusively granulocytic. Growth rate of colonies is slower than with mouse bone marrow but colonies reach a comparable size (500–1500 cells) at days 12–16.