Bone marrow osteogenic stem cells: in vitro cultivation and transplantation in diffusion chambers

Fibroblast colonies (clones) were obtained by explantation of bone marrow single-cell suspensions and were used to establish multicolony and single-colony derived fibroblast cultures by successive passaging of either pooled or individual colonies. When transplanted in diffusion chambers after 20-30 cell doublings in vitro, the descendants of fibroblast colony-forming cells (FCFC), whether grown from single or pooled colonies, retained the ability for bone and cartilage formation. The content of osteogenic precursors in the cultured progeny significantly outnumbered the initiating FCFC. Thus the high proliferative potential of bone marrow FCFC and their ability to serve as common precursors of bone and cartilage-forming cells makes them probable candidates for the role of osteogenic stem cells.     

Clonogenic stromal cell count in the bone marrow of mice

The number of fibroblast colonies in bone marrow cultures depends on FCFC concentration in explanted cells and FCFC cloning efficiency. For mouse bone marrow the efficiency of fibroblast colony formation increases in the presence of the feeder (irradiated bone marrow of spleen cells). Colony-stimulating feeder activity does not depend on the presence of phagocytic and stromal cells in the feeder cell population. Trypsinization of the bone marrow leads to the release of additional FCFC and the increase of their concentration in bone marrow cell suspensions.     

Proliferative and differentiation potentials of skeletogenic bone marrow colony-forming cells

The clonal nature of bone marrow fibroblast colonies derived from clonogenic bone marrow osteogenic cells (CFUf) was proved by the chromosome analysis. During subsequent passages of multi-colony derived bone marrow fibroblast strains there occurs a pronounced increase in the cell number and in the number of osteogenic units (tested by transplantation in diffusion chambers). Single colony-derived strains are capable of forming bone and cartilage simultaneously. It follows that CFUf or part of them are clonogenic cells with high proliferative potentials and are common precursors for bone and cartilage tissue. Thus, CFUf may be regarded as osteogenic stem cells.     

The stromal colony-forming cell (CFUf) count in the bone marrow of mice and the clonal nature of the fibroblast colonies they form

The clonal nature of FCFC-derived stromal colonies was tested by chromosomal analysis in mixed cultures of CBA and CBAT6T6 bone marrow cells depleted of macrophages and myeloid cells. Inoculation of the bone marrow cell suspensions in flasks coated with poly-l-lysine has revealed practically no stromal aggregates among the explanted cells. The coincidence of karyotypes within the stromal colonies in the mixed cultures proved that the FCFC-derived colonies were cell clones. It was shown by indirect immunofluorescence with antibodies to type 1 collagen that the mouse bone marrow FCFC-derived colonies consisted of stromal fibroblasts. The cloning efficiency of the bone marrow FCFS depends on the explantation density of cells; a stable colony-forming efficiency could be reached only in the presence of feeder cells (irradiated bone marrow). In the bone marrow cells suspensions obtained by trypsinization the amount of FCFC is markedly higher than in the suspensions of mechanically disaggregated bone marrow cells.     

Differentiation potentials of clonal strains of bone marrow fibroblasts

The clonal nature of CFUf-derived fibroblast colonies was proved by chromosomal analysis of individual colonies and single-colony-derived fibroblast strains using mixed cell cultures from male and female rabbits. CFUf progeny, forming colonies composed of more than 10(3) cells was capable of 20-30 cell doublings during subsequent passages. When transplanted in diffusion chambers, single-colony-derived fibroblast strains formed bone and cartilage simultaneously. Thus, CFUf or part of them can be regarded as bone marrow osteogenic stem cells.     

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.     

Comparative Investigation of Mesenchymal Stem Cells Isolated from the Bone Marrow and Fetal Liver of Mouse and Rat

We studied the properties of cells forming fibroblast colonies from the bone marrow and fetal liver of mouse and rat. Bone marrow and fetal liver cells formed colonies in vitro including fibroblasts as well as a considerable proportion of macrophages. The colonies formed from bone marrow and hepatic cells of rat differed from the murine ones by a higher proportion of fibroblasts. Most colonies derived from the bone marrow of both mouse and rat included a fraction of cells expressing alkaline phosphatase, and hence, capable of osteogenic differentiation; the colonies derived from the fetal liver included low proportions of such cells. The cell layers derived from the colony-forming fibroblasts of both bone marrow and fetal liver of mouse maintained hematopoiesis in the peritoneal cavity of irradiated mice, which indicated that these progenitor cells can form hematopoietic microenvironment.     

Characterization of monolayer and organ cultures of cloned and enriched lymphohematopoietic stromal cell populations

The role of hematopoietic microenvironments in the regulation of maturation and differentiation of hematopoietic cells, although heavily debated, remains uncertain. Several investigators have suggested that the adherent “stromal” cell populations, which grow as colonies in cultures of lymphomyeloid tissues, include the cells involved in such regulatory processes. Grossly, the colonies described by several investigators appear similar morphologically, and the cells giving rise to them have been variously termed (1) fibroblast colony forming cells (FCFC), (2) plaque forming units-culture (PFU-C), (3) macrophage colonies, and (4) marrow stromal cells. FCFC have been reported to re-establish their parent microenvironment when transplanted in an allogeneic system. In this study, cloned and enriched cell populations obtained from such colonies in cultures of murine lymphomyeloid tissues have been characterized by their growth in culture and using morphological, histochemical, and electron microscopic techniques. The results demonstrated that, although the initial stromal colonies appeared to be identical, the constituent cell types varied considerably. Some colonies were comprised primarily of macrophages, while others appeared to contain predominantly fibroblasts; two additional cell types that established colonies have not yet been satisfactorily identified. These results demonstrate the heterogeneity of lymphomyeloid stromal colonies. There is a need for caution in the analysis of experiments in which uncharacterized stromal cell colonies are transplanted or employed as supporting monolayers in culture systems in experiments designed to evaluate the origins and functions of lymphohematopoietic stroma.     

Nonadhesive populations in cultures of mesenchymal stromal cells from hematopoietic organs in mouse and rat

The study of adhesive properties of multipotent mesenchymal stromal cells evaluated from fibroblast colony-forming units in the bone marrow of adult mice and rats in populations of cells attached and unattached to plastic substrate after 2 h to 7 days in culture demonstrated both similarities and differences. The increase in the fibroblast colony-forming units in the adhesive population peaked on day 7 of in vitro culture in both cases; however, nearly no fibroblast colony-forming units were observed in the nonadhesive population from the mouse bone marrow in this period. Conversely, the number of colonies from the rat bone marrow nonadhesive population on day 7 of culture considerably increased, and this nonadhesive population in long-term culture became the source for subsequent nonadhesive subpopulations containing fibroblast colony-forming units. After 7 days of in vitro culture, the suspension of cells isolated from the liver of 17-day-old rat fetuses also contained a fraction of unattached fibroblast colony-forming units. In the nonadhesive subpopulations from the bone marrow and fetal liver, fibroblast colony-forming units were observed up to day 48 and 30, respectively. Stromal cell precursors of nonadhesive subpopulations from the rat bone marrow featured a period of colony formation reduced to 7 days (i.e., they were formed 1.5-2 times faster compared to the primary culture). The total number of fibroblast colony-forming units from all nonadhesive subpopulations was roughly 6 and 7.4 times that of the adhesive population of the primary culture from the bone marrow and fetal liver, respectively. Considering that the mammalian bone marrow remains the preferred source of mesenchymal stromal cells, using nonadhesive subpopulations in the presented culture system can considerably increase the yield of stromal precursor cells     

Effect of 5'-adenosine monophosphate and cyclic 3',5'-adenosine monophosphate on the ability of guinea pig bone marrow precursor cells to form fibroblast-like cell colonies in vitro

The effect of 5'-AMP and cyclic 3',5'-AMP on the ability of cells--precursors of bone marrow to form colonies of fibroblast-like cells in vitro was studied in the guinea pig. No reliable effect of both substances (within the limits of 10(-5) to 10(-8) M) on the formation of fibroblast colonies in vitro by the cells--precursors of bone marrow was shown. No differences were established in the size of colonies between the experimental and control variants.     

Self-maintenance of induced bone tissue]

The capacity for self-maintenance of the bone marrow osteogenic precursor cells from the skeletal bones and from the bones induced by implantation of decalcified bone matrix is compared. Transplantation in diffusion chambers is employed as the test system. Osteogenesis in the bone marrow transplants isolated from the skeletal bone lasts several months, whereas osteogenesis in the bone marrow transplants isolated from induced bone stops after the second month. Fibroblasts arising in the monolayer cultures of the skeletal bone marrow retained their osteogenic potencies after repeated passages. On the contrary, fibroblasts from the monolayer cultures of induced bone marrow lost their osteogenic capacity after the second passage. Thus, contrary to osteogenic precursors of the skeletal bone, osteogenic precursors of induced bone tissue had a very limited self-maintaining capacity after the cessation of induction.     

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.     

Reaction between the mechanocytes of hematopoietic organs in collagen gel

Interactions between stromal mechanocytes of hemopoietic organs were studied at their cultivation in three-dimentional collagen gel. It was demonstrated that cellular cords appearing between fibroblast colonies and between fragments of hemopoietic organs are of fibroblastic nature. They are not resulted from organic or specific peculiarities, or from discharge of substances attracting fibroblasts. A linear dependence between the amount of fibrorow or spleen was noted. Fibroblast colonies formed by the hamster bone marrow and splenic cells, as well as by passaged fibroblasts of the guinea pig bone marrow were obtained. In order to form colonies by the passaged fibroblasts it is necessary to add of irradiated cells. Its effect, besides the medium conditioning, is evidently, in restriction of fibroblast mobility in collagen gel.     

Characterization of reticulofibroblastoid colonies (CFU-RF) derived from bone marrow and long-term marrow culture monolayers

The maintenance of hemopoietic precursors in long-term liquid bone marrow cultures (LTBMC) is associated with the presence of an adherent stromal layer composed of heterogeneous cell populations. We have used a culture assay to promote the growth of one of its cellular components and characterize its properties. Freshly obtained bone marrow cells and cells derived from the adherent layer of LTBMC were grown in methylcellulose-clotted plasma in the presence of phytohemagglutinin-stimulated leukocyte-conditioned medium (PHA-LCM), hydrocortisone (HC), and citrated normal human plasma. Both sources contained cells (CFU-RF) that gave rise to colonies of cells with a reticulofibroblastoid appearance. In the presence of HC, most colonies contained lipid-laden cells. Colonies could be further propagated as adherent layers when transferred into liquid cultures. These cells produced laminin, fibronectin, and collagen types I, III, IV, and V. They were negative for Von Willebrand factor VIII. The ability to synthesize laminin and collagen type IV distinguished these cells from a population of previously described bone marrow fibroblasts (CFU-F). The relationship of CFU-RF to hemopoietic precursors was investigated using patients with chronic myeloid leukemia and bone marrow transplant recipients. Cells within CFU-RF-derived colonies were uniformly negative for the Philadelphia chromosome, thus making it unlikely that they belonged to the malignant hemopoietic clone. CFU-RF-derived colonies in bone marrow transplant recipients were found to be exclusively of host origin. Both observations support the view that CFU-RF is not part of the repertoire of hemopoietic stem cells.     

An in vitro assay for T lymphocyte progenitors (CFU-preT)

Thy-1.2 negative progenitors give rise to Thy-1.2 positive colony cells when mouse bone marrow is cultured in vitro. The bone marrow cells are immobilized in a viscous medium containing methyl cellulose; discrete colonies are identifiable at 2 days and contain 30–60 cells by day 3 of culture. Colonies are tightly packed spheres (raspberries) and grow suspended in the gel. Growth of the raspberry colonies is absolutely dependent upon the presence of the appropriate serum (horse or human; not fetal calf) and conditioned medium from pokeweed mitogen-stimulated mouse spleen cells. As little as 0.1% of the conditioned medium is sufficient to promote raspberry colony growth. Under these conditions, nude mouse bone marrow yields as many colonies (1 per 1,000 nucleated cells plated) as normal marrow. Thymus, lymph node; and spleen (normal or nude) do not form colonies. Colony precursors are predominantly in S phase of the cell cycle, as determined by tritiated thymidine suicide of fresh bone marrow. Their numbers fall with age. Because the cells in colonies are Thy-1 positive, peanut agglutinin-positive, and active in a pre-T cell synergy assay, we conclude that their precursors are early committed T cell progenitors, and propose that they be called CFU-preT.     

Differentiation of human stromal bone marrow cell precursors in monolayer culture

The colonies of human bone marrow fibroblasts in monolayer culture have been studied. It has been shown that there are two types of colonies in the cultures: monolayer and multilayer ones, both having alkaline phosphatase-positive cells. In monolayer colonies one can observe calcium deposition indicative of osteogenic differentiation of human bone marrow stromal cells.     

Osteogenic properties of late adherent subpopulations of human bone marrow stromal cells

The nonadherent (NA) population of bone-marrow-derived mononuclear cells (MNC) has been demonstrated to be a source of osteogenic precursors in addition to the plastic-adherent mesenchymal stromal cells (MSC). In the current study, two subpopulations of late adherent (LA) osteoprogenitors were obtained by subsequent replating of NA cells, and their phenotypic, functional, and molecular properties were compared with those of early adherent (EA) MSC. Approximately 35% of MNC were LA cells, and they acquired a homogeneous expression of MSC antigens later than EA cells. In EA-MSC, the alkaline phosphatase (ALP) activity increased significantly from time of seeding to the first confluence, whereas in LA cells it raised later, after the addition of mineralization medium. All subpopulations were able to produce type I collagen and to deposit extracellular matrix with organized collagen fibrils. The proportion of large colonies with more than 50% of ALP positive cells as well as the calcium content was higher in LA than in EA cells. Molecular analysis highlighted the upregulation of bone-related genes in LA-MSC, especially after the addition of mineralization medium. Our results confirm that bone marrow contains LA osteoprogenitors which exhibit a delay in the differentiation process, despite an osteogenic potential similar to or better than EA-MSC. LA cells represent a reservoir of osteoprogenitors to be recruited to gain an adequate bone tissue repair and regeneration when a depletion of the most differentiated component occurs. Bone tissue engineering and cell therapy strategies could take advantage of LA cells, since an adequate amount of osteogenic MSCs may be obtained while avoiding bone marrow manipulation and cell culture expansion.     

Origin of stromal bone marrow mechanocytes according to the results of typing them by isoantigens and chromosomal markers]

The bone marrow of radiochimaeras and heterotopic bone marrow transplants were used to study the origin of precursors of the fibroblasts growing in the monolayer cultures of hemopoietic tissue. In the bone marrow explants of the (C57BL/6 X CBA) F1 mice, in which the CBA bone marrow was transplanted following the lethal irradiation, the fibroblasts grown in the colonies were of recipient origin judging by isoantigens in the reaction of indirect immunofluorescence with the anti-C57BL/6-serum. At the same time in the bone marrow explants from heterotopic transplants (CBA leads to CBA X C57BL/6) the fibroblasts grown in colonies were of donor origin. The cultures of hemopoietic cells of the bone marrow of females heterotopically transplanted in the singenic male (guinea pigs Huston) contained only fibroblasts which were of donor origin judging by sex chromosomes in the metaphase plates of dividing cells. Hence, the bone marrow precursors of fibroblasts do not depend histogenetically on hemopoietic cells and are not replaced at the expense of repopulating cells of the second partner.     

THE DEVELOPMENT OF FIBROBLAST COLONIES IN MONOLAYER CULTURES OF GUINEA-PIG BONE MARROW AND SPLEEN CELLS

In monolayer cultures of guinea-pig bone marrow and spleen the development of discrete fibroblast colonies takes place on days 9–12. The linear increase in the number of colonies with increasing numbers of explanted cells and the distribution of male and female cells in mixed cultures support the view that fibroblast colonies are clones. The concentration of colony-forming cells in bone marrow and spleen is approximately 10^-5. Bone marrow culture (but not spleen culture) fibroblasts are capable of spontaneous bone formation in diffusion chambers. Fibroblasts from both bone marrow and spleen cultures are inducible to osteogenesis in diffusion chambers in the presence of transitional epithelium.     

Osteogenic potential of rat spleen stromal cells

Evidence is mounting that an increasing number of cell populations in the adult organism already committed and/or differentiated retain the ability to reprogram themselves and give rise to a different phenotype. Bone marrow stromal cells have long been recognized as early progenitor cells for osteoblasts, chondrocytes, hematopoietic-supportive fibroblasts and adipocytes. Recent reports though have demonstrated a potential of cell populations outside the bone marrow environment to sustain bone formation under specific circumstances. The formation of bone nodules in the spleen of IL-5 transgenic mice has been recently reported (Macias et al. (2001): J. Clin. Invest. 107, 949 - 959). We thus postulated that a cell population exists in the spleen that under particular microenvironmental conditions is able to reprogram itself and pursue a fate other than the tissue-specific one. Therefore we isolated and expanded in vitro spleen-derived stromal cells. After expansion, these cells were challenged with culture conditions designed to induce osteogenic differentiation. We hypothesized that the combination of a proliferating factor (fibroblast growth factor 2) and a differentiating hormone (dexamethasone) would allow us to induce spleen-derived stromal cells to proliferate and at the same time to express osteoblast-specific genes. Thus, spleen-derived stromal cells were isolated from rat spleen and expanded in the presence of fibroblast growth factor 2 and dexamethasone. Once primary cultures reached confluence they were either switched to an osteo-inductive medium or implanted in immunodeficient mice. Although no bone formation was observed in in vivo experiments, in vitro spleen-derived stromal cells were able to deposit a mineralized matrix. Gene expression, as revealed by RT-PCR analysis, evidenced that the deposition of a mineralized matrix was concomitant with the expression of CBFA1 and osteocalcin, along with alkaline phosphatase and bone sialoprotein. Our data suggest that rat spleen-derived stromal cells can undergo osteogenic differentiation in a permissive microenvironment.