Enhanced control of proliferation in telomerized cells

Clones of telomerized fibroblasts of adult human skin have earlier been obtained. It was shown that despite their fast growth in mass cultures, these cells poorly form colonies. Conditioned medium, antioxidants, and reduced partial oxygen pressure enhanced their colony formation, but not to the level characteristic of the initial cells. The conditioned medium of telomerized cells enhanced colony formation to a much greater extent than that of the initial cells. A study of proteome of the telomerized fibroblasts has revealed changes in the activities of tens of genes. A general trend consists in weakening and increased lability of the cytoskeleton and in activation of the mechanisms controlling protein degradation. However, these changes are not very pronounced. During the formation of immortal telomerized cells, selection takes place, which appears to determine changes in the expression of some genes. It was proposed that a decrease in the capacity of telomerized cells for colony formation is due to increased requirements of these cells to cell-cell contacts. The rate of cell growth reached that characteristic of mass cultures only in the largest colonies. In this respect, the telomerized fibroblasts resembled stem cells: they are capable of self-maintenance, but “escape” to differentiation in the absence of the corresponding microenvironment (niche), which is represented by other fibroblasts. Nondividing cells in the test of colony formation should be regarded as differentiated cells, since they have no features of degradation, preserve their viability, actively move, grow, phagocytize debris, etc. It was also shown that telomerization did not prevent differentiation of myoblasts and human neural stem cells. Thus, the results obtained suggest the existence of normal mechanisms underlying the regulation of proliferation in the telomerized cells, which opens possibilities of their use in cell therapy, especially in the case of autotransplantation to senior people, when the cell proliferative potential is markedly reduced and accessibility of stem cells is significantly restricted.     

Permissive role of interleukin 3 (IL-3) in proliferation and differentiation of multipotential hemopoietic progenitors in culture

We studied the effects of interleukin-3 (IL-3) on colony formation by hemopoietic progenitors in methylcellulose cultures of spleen cells from 5-fluorouracil (FU)-treated mice. Purified IL-3 supported the growth of various types of multilineage colonies including blast cell colonies. The types of colonies were similar to those supported by pokeweed-mitogen spleen cell conditioned medium (PWM-SCM), except that IL-3 supported eosinophil and neutrophil expression better. Delayed addition of IL-3 to cultures 7 days after cell plating decreased the number of colonies to one-half the number in cultures with IL-3 added on day 0. It did not alter the proliferative and differentiation characteristics of late emerging multipotential blast cell colonies. These observations suggest that IL-3 does not trigger hemopoietic progenitors into active cell proliferation but is necessary for their continued proliferation. This permissive role of IL-3 is consistent with a stochastic model of stem cell proliferation which features random entry into cell cycle. IL-3 also supported the growth of multilineage colonies from single cells isolated from blast cell colonies by micromanipulation. This result shows that IL-3 acts directly on multipotential progenitors. Analysis of colonies derived from paired progenitors revealed disparate lineage expression and was in accordance with the stochastic model of stem cell differentiation.     

Characterization of the growth responses of hamster fibroblasts and chondrogenic cells to fibroblast growth factor

The effects of fibroblast growth factor (FGF) on hamster dermal fibroblasts and chondrogenic cells, both of mesodermal origin, were compared with special reference to growth stimulation and morphological changes in monolayer cultures, and colony formation in semisolid medium. FGF (10 to 200 ng/ml) caused appreciable cell proliferation of dermal fibroblasts but not of chondrogenic cells, while FGF (50-200 ng/ml) caused very marked dose-dependent morphological changes in monolayer cultures and colony formation in semisolid medium of both fibroblasts and chondrogenic cells. It is suggested that FGF is the same type of growth factor as the transforming growth factor(s) because, like the latter, it induces drastic morphological changes of normal mesodermal cells in monolayer cultures and their colony formation in semisolid medium.     

Colony formation in agar by adult bone marrow multipotential hemopoietic cells

Erythroid colony formation in agar cultures of CBA bone marrow cells was stimulated by the addition of pokeweed mitogen-stimulated spleen conditioned medium (SCM). Optimal colony numbers were obtained when cultures contained 20% fetal calf serum and concentrated spleen conditioned medium. By 7 days of incubation, large burst or unicentric erythroid colonies occurred at a maximum frequency of 40–50 per 10⁵ bone marrow cells. In CBA mice the cells forming erythroid colonies were also present in the spleen, peripheral blood, and within individual spleen colonies. A marked strain variation was noted with CBA mice having the highest levels of erythroid colony-forming cells. In CBA mice erythroid colony-forming cells were mainly non-cycling (12.5% reduction in colony numbers after incubation with hydroxyurea or 3H-thymidine). Erythroid colony-forming cells sedimented with a peak of 4.5 mm/hr, compared with CFU-S, which sedimented at 4.25 mm/hr. The addition of erythropoietin (up to 4 units) to cultures containing SCM did not alter the number or degree of hemoglobinisation of erythroid colonies. Analysis of the total number of erythroid colony-forming cells and CFU-S in 90 individual spleen colonies gave a correlation coefficient of r = 0.93 for these two cell types. In addition to benzidine-positive erythroid cells, up to 40% of the colonies contained, in addition, varying proportions of neutrophils, macrophages, eosinophils, and megakaryocytes. Taken together with the close correlation between the numbers of CFU-S in different adult hemopoietic tissues, including individual spleen colonies, the data indicate that the erythroid colony-forming cells expressing multiple hemopoietic differentiation are members of the hemopoietic multipotential stem cell compartment.     

The enhancement of in vitro survival and chondrogenesis of limb bud cells by cartilage conditioned medium

Dissociated stage 21–28 chick embryo limb bud cells showed an increasing ability to produce cartilage colonies in vitro with in vivo maturation. In addition dissociated stage 21–28 chick embryo limb bud cells exposed to cartilage conditioned medium continuously or only for 48 hr prior to subculture showed an enhanced (as much as 15-fold) ability to form differentiated cartilage colonies. By this criterion, cells were more responsive to conditioned medium prior to stage 25. Conditioned medium from fibroblast cultures caused an inhibition of cartilage colony formation, suggesting that the effect is cell-type specific. Besides increasing cartilage colony formation by enhanced cell survival, the incorporation of S³⁵O₄ into isolated glycosaminoglycans is also stimulated when limb bud cells are exposed to cartilage conditioned medium. The results support a model for cell differentiation which involves the enhancement of a particular differentiated capacity by a diffusible cell-type-specific macromolecule.     

Selection using the alpha-1 integrin (CD49a) enhances the multipotentiality of the mesenchymal stem cell population from heterogeneous bone marrow stromal cells

Bone marrow-derived mesenchymal stem cells consist of a developmentally heterogeneous population of cells obtained from colony forming progenitors. As these colonies express the alpha-1 integrin (CD49a), here we single-cell FACS sorted CD49a+ cells from bone marrow in order to create clones and then compared their colony forming efficiency and multilineage differentiation capacity to the unsorted cells. Following selection, 40% of the sorted CD49a+ cells formed colonies, whereas parental cells failed to form colonies following limited dilution plating at 1 cell/well. Following ex vivo expansion, clones shared a similar morphology to the parental cell line, and also demonstrated enhanced proliferation. Further analysis by flow cytometry using a panel of multilineage markers demonstrated that the CD49a+ clones had enhanced expression of CD90 and CD105 compared to unsorted cells. Culturing cells in adipogenic, osteogenic or chondrogenic medium for 7, 10 and 15 days respectively and then analysing them by quantitative PCR demonstrated that CD49a+ clones readily underwent multlineage differentiation into fat, bone and cartilage compared to unsorted cells. These results thus support the use of CD49a selection for the enrichment of mesenchymal stem cells, and describes a strategy for selecting the most multipotential cells from a heterogeneous pool of bone marrow mononuclear stem cells.     

In vitro inhibitory effect of interferon on colony formation of myeloma stem cells

Summary The inhibitory effect of interferon on colony formation of myeloma stem cells in two layer plasma clot-soft agar cultures was studied. Human lymphoblast interferon inhibited in therapeutically attainable concentrations myeloma stem cell proliferation in 50% and human fibroblast interferon in 23% of the 14 myeloma patients in whom in vitro colony formation could be achieved. In interferon-sensitive patients the numbers of myeloma stem cell clusters and colonies were decreased to 34.4%–54.9% of control cultures. In addition, maturation of myeloma stem cells in differentiated plasma cells was reduced by interferon in most of these cases.     

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.     

Differentiation of Mouse Bone Marrow Precursor Cells into Neutrophil Granulocytes by an Activity Separation from WEHI-3 Cell-Conditioned Medium

Colonies comprised exclusively of neutrophil granulocytes have been obtained by growing mouse bone marrow cells in nutrient semisolid agar cultures. A stimulator of predominantly granulocyte colony formation was present in the breakthrough fraction of preparations of colony-stimulating activity separated on DEAE-Sephadex A. The source of colony-stimulating activity was concentrated conditioned medium of a murine myelomonocytic cell line (WEHI-3), which unfractionated stimulated the growth of colonies of granulocytes, macrophages, megakaryocytes, as well as mixed colony types. After stepwise column chromatography of the conditioned medium, the breakthrough fraction was shown to stimulate predominantly granulocyte colony formation, and the fraction eluted with 1 M NaCl was found to induce primarily macrophage colony growth. Colony morphology was independent of the concentration of eluate used. The morphology of colonies varied with increasing concentrations of the breakthrough fraction. At low concentrations, granulocyte colony formation was almost exclusively observed. With increasing concentrations of this fraction, an increasing proportion of the colonies were found to contain macrophages. The effect of concentration of this activity was in marked contrast to previous findings where the incidence of granulocyte colony formation was inversely related to the concentration of colony-stimulating activity. This differential responsiveness of cell to stimulus has previously been interpreted as low concentrations of a growth and differentiation factor being required for macrophage production and high concentrations of the same factor required for granulocyte formation. Separation of these activities by DEAE Sephadex chromatography, and alteration of the dose-response curve, such that granulocyte colony formation varies directly with the amount of stimulator, indicates that the differentiation of these two cell blood lineages may be controlled by separate entities.     

Opposing effects of 12-o-tetradecanoylphorbol 13-acetate on human myeloid and lymphoid cell proliferation

The effect of 12-O-tetradecanoylphorbol 13-acetate (TPA) on human hematopoietic cells has been investigated. It was found that 1–10 ng/ml of TPA totally abrogated erythroid and granulocytic colony growth and, simultaneously in the presence of PHA, stimulated T-lymphocyte colony formation. TPA concentrations insufficient to inhibit myeloid colony growth also failed to stimulate lymphocyte colony formation. Optimal culture conditions for the growth of these colonies required the presence of TPA, PHA, and leukocyte-conditioned medium in the cultures. Cells within the colonies were 80–90% E-rosette positive and by monoclonal antibody characterization contained 45–66% OKT3-positive cells. Colony-forming cells were found in both E-rosette-positive and-negative fractions. Although by cell surface marker characterization the cells within the colonies had properties of T-cells, the exact relationship of cells forming colonies under these conditions to those detected in other T-cell colony assays remain to be determined.     

Noggin maintains pluripotency of human embryonic stem cells grown on Matrigel

Objective:  Spontaneous differentiation of human embryonic stem cell (hESC) cultures is a major concern in stem cell research. Physical removal of differentiated areas in a stem cell colony is the current approach used to keep the cultures in a pluripotent state for a prolonged period of time. All hESCs available for research require unidentified soluble factors secreted from feeder layers to maintain the undifferentiated state and pluripotency. Under experimental conditions, stem cells are grown on various matrices, the most commonly used being Matrigel.
Materials and Methods:  We propose an alternative method to prevent spontaneous differentiation of hESCs grown on Matrigel that uses low amounts of recombinant noggin. We make use of the porosity of Matrigel to serve as a matrix that traps noggin and gradually releases it into the culture to antagonize bone morphogenetic proteins (BMP). BMPs are known to initiate differentiation of hESCs and are either present in the conditioned medium or are secreted by hESCs themselves.
Results:  hESCs grown on Matrigel supplemented with noggin in conditioned medium from feeder layers (irradiated mouse embryonic fibroblasts) retained both normal karyotype and markers of hESC pluripotency for 14 days. In addition, these cultures were found to have increased cell proliferation of stem cells as compared to hESCs grown on Matrigel alone.
Conclusion:  Noggin can be utilized for short term prevention of spontaneous differentiation of stem cells grown on Matrigel.     

Self-renewal and commitment to differentiation of human leukemic promyelocytic cells (HL-60)

More than 80% of cells from a human promyelocytic leukemic cell line (HL-60) possess the capacity for self-renewal as evidenced by their ability to form large primary colonies in semisolid medium and the presence within these colonies of cells capable of subsequent colony formation. Colony development is independent of the normal regulator-the myeloid colony stimulating factor. The observed autostimulation suggests the production of specific growth promoters by the cells. Differentiation either to mature granulocytes or macrophages, induced by various agents, was associated with reduced cloning potential. Nevertheless, colonies containing differentiated cells could be developed either by cloning cells in the presence of suboptimal concentrations of inducer or by adding inducers over colonies developed in its absence. Upon differentiation, there was a morphological change from compact to diffused colony morphology due to cell mobility in the semisolid medium. Even at suboptimal concentrations of inducer more than 95% of the colonies became diffused, indicating clonaI homogeneity of the population with respect to differentiation capacity. The loss of self-renewal was found to be one of the early properties which changed following the initiation of differentiation. The loss preceded not only the overt expression of maturation-specific functions but also cellular commitment to terminal differentiation; shorter contact with the inducer was required to cause loss of self-renewal than to induce an irreversible transition to differentiation. This resulted in cells that lost their self-renewal potential without being able to complete their program of differentiation.     

A self-renewing, bipotential erythroid/mast cell progenitor in continuous cultures of normal murine bone marrow

We have established permanent lines of nonadherent cells from fresh normal mouse bone marrow in media containing pokeweed mitogen-stimulated spleen cell conditioned medium (PWSCM). These lines continuously produced erythropoietic progenitor cells (detected by their ability to form erythroid bursts in semi-solid medium containing erythropoietin) together with cells having characteristics of the mast cell lineage (as demonstrated by metachromatic staining with toluidine blue, histamine content and membrane receptors for IgE). Sixteen such cell lines have been established in sixteen attempts. Cloning experiments were carried out to determine the nature of the progenitor cell(s) responsible for the permanence of these cultures. When cells were cultured in methylcellulose medium containing PWSCM, colonies were observed which reached macroscopic size after 4 weeks of incubation. Replating of individual primary colonies resulted in secondary colony formation, indicating the presence of progenitor cells with self-renewal potential. Forty-seven primary colonies were picked and their cells were suspended in liquid culture medium containing PWSCM. Of these, twenty-one could be expanded to establish permanently growing sublines. Sixteen of these sublines were found to be composed of both erythroid progenitors and mast cells. In five sublines only mast cells could be seen; none of the sublines appeared to be purely erythroid. Karyotypic analysis of mast cells and of erythroid cells of seven sublines derived from individual colonies which arose in cocultures of male and female cells revealed that the mast cells and erythroid cells were both of the same sex in each of the seven sublines; this demonstrates the single cell origin of each colony and of the two lineages derived from it. We conclude that these nonadherent, factor-dependent cell lines are maintained by self-renewal and differentiation of bipotential progenitor cells apparently restricted to the erythroid and mast cell lineages.     

CFU-F circulating in cord blood

CFU-F (colony forming units-fibroblast) were studied from cord blood and, as controls, from normal bone marrow of older children and adults. Numbers of CFU-F in cord blood buffy coat cells are lower by a factor of 10 in comparison to bone marrow CFU-F. Cytomorphology and staining with monoclonal antibody identify the progeny cells of CFU-F as fibroblasts. Cord blood CFU-F derived fibroblasts have properties supporting hematopoiesis: They produce CSF (colony stimulating factor) to which fresh cord blood CFU-GM (colony forming units-granulocytic, monocytic) react by colony formation in a dose-response manner. In addition, fibroblast colonies discharge clonogenic round cells into the medium forming CFU-GM and CFU-F colonies in secondary methyl cellulose cultures. We conclude that fetal blood contains clonogenic stromal cells (CFU-F) that give rise to fibroblasts with properties of hematopoietic support.     

The in vitro behaviour and patterns of colony formation of murine epithelial stem cells

OBJECTIVE: The mechanisms of renewal of skin and mucosal epithelia in vivo are associated with hierarchies of stem and amplifying cells organized in distinct spatial patterns. Stem and amplifying characteristics persist after isolation and growth of human keratinocytes in vitro but the pattern for murine keratinocytes has been less clear. MATERIALS AND METHODS: Murine keratinocytes were grown in low calcium media and examined for their patterns of colony morphologies. RESULTS: We consistently identified three types of colonies, one of which contains concentric zones of amplifying and differentiated cells surrounding a central zone of cells that have patterns of expression and behavioural characteristic of stem cells. This zonal organization facilitated analysis of stem cell formation and loss. Cells in the central stem cell zone undergo rapid symmetric divisions but expansion of this population is partially limited by their peripheral transition into amplifying cells. A striking feature of central zone cells is their enhanced apoptotic susceptibility and stem cell expansion limited by consistently high background rates of apoptosis. This occasionally reaches catastrophic levels with elimination of the entire central zone. CONCLUSION: In vitro amplification of stem cells for the generation of engineered tissue has tended to focus on control of asymmetric division but these findings suggest that development of mechanisms protecting stem cells from apoptotic changes are also likely to be of particular value.     

Formation of eosinophilic-like granulocytic colonies by mouse bone marrow cells in vitro

Formation of granulocytic and macrophage colonies in agar cultures of mouse marrow or spleen cells was stimulated by the addition of medium from pokeweed mitogen-stimulated cultures of mouse spleen cells (PKW-CM). Approximately 5% of the colonies developing were large, dispersed granulocytic colonies (DG-colonies) composed of cells with eosinophilic cytoplasmic granules. The capacity to stimulate DG-colonies was shown by media conditioned by PKW-treated lymphoid and peritoneal cells but not by other cells or organ fragments. Velocity sedimentation studies indicated that cells generating DG-colonies were separable from cells generating regular granulocytic or macrophage colonies. DG-colonies did not survive if transfered to cultures containing other forms of CSF. The active colony stimulating factor in pokeweed mitogen-conditioned medium which stimulates DG-colony formation was antigenically distinct from the factor stimulating granulocytic and macrophage colony formation, was separable electrophoretically from the latter factor and on gel filtration had an apparent molecular weight of 50,000. Although the cells in DG-colonies have not been established to be eosinophils, DG-colonies represent an interesting new system for analysing further aspects of the control of growth and differentiation in hemopoietic populations.     

Influence of oxygen on three different types of telomerized cells derived from a single donor

Three primary cell cultures were derived from a single donor: skin fibroblasts (SF), dermal papilla cells (DP), and mesenchimal stromal cells from lipoaspirate (LA). After a high efficiency introduction of the gene of human telomerase catalytic component (hTERT) in lentiviral construct, we obtained three different strains of immortalized cells. All cells were cultured in a low oxygen (3%) environment. When telomerized cells were grown in atmospheric conditions (21% oxygen), growth retardation was observed after a period of 18–40 days. SF-hTERT and DP-hTERT overcame this retardation. In 30–45 days the rate of their growth became as high as it was in 3% oxygen. LA-hTERT cells were incapable to restore the previous growth rate and after several passages ceased proliferation. We found that telomerized cells were heterogeneous in their ability to form colonies at low density (3 cells per 1 cm²): they made 0–9 population doublings in 7 days. At the same time, mean growth rate of SF-hTERT did not change, while the growth of DP-hTERT and LA-hTERT cells was considerably accelerated in comparison with their growth in mass culture. Transfer of telomerized cells to 21% oxygen reduced their ability to form colonies to a different extent. The total number of cells grown in 21% oxygen was 3 times less than the number grown in 3% oxygen for SF-hTERT and DP-hTERT, and 6 times less for LA-hTERT. Original cells (with the exception of LA) were more sensitive to oxygen level than the corresponding telomerized cells. The total number of cells of all three strains (SF, DP, LA) grown in 21% oxygen was 6–7 times less. We discuss the reasons of incapability of LA-hTERT cells to adapt to atmospheric oxygen.     

A method for cultivating morphologically undifferentiated embryonic stem cells from porcine blastocysts

Variable conditions were tested to determine an in-vitro cultivation method for the formation of morphologically undifferentiated embryonic stem cells from the inner cell mass (ICM) derived outgrowth of porcine blastocysts. Although all 16 Day-9 embryos failed to form colonies, 14 such colonies were obtained from a total of 69 Day-10 embryos when they were co-cultivated with porcine uterine fibroblast (PUF) cells over a 6-day period. The best results were obtained in Dulbecco's modified Eagle medium (DMEM) with 10% fetal calf serum and 10% porcine serum supplemented with bovine insulin and beta-mercaptoethanol, in which six out of seven embryos formed adequate ICM-derived colonies. Since murine fibroblasts were not found to be suitable feeder cells in this procedure, an endocrine synergistic interaction, which promotes embryonic attachment and colony formation, between porcine blastocysts and PUF cells is hypothesized. Continued propagation of the ICM-derived cells was not dependent on these factors; a total of seven cell lines were obtained after three to five subsequent passages on murine feeder-layers that resembled morphologically undifferentiated embryonic cells.