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.     

Analysis of pure and mixed murine mast cell colonies

Mast cells have been proposed to originate from diverse sources, including connective tissues, macrophages, T lymphocytes, and hemopoietic cells. Evidence for a hemopoietic origin of mast cells includes the presence of mast cell precursors in spleen colonies and the presence of mast cells in hemopoietic colonies in culture. Here we report a detailed analysis of mouse spleen mixed hemopoietic colonies containing mast cells. All of the colonies in cultures plated at low cell densities were individually removed for analysis by May-Grunwald-Giemsa staining on day 15 of culture. Examination of five dishes which contained a total of 82 colonies showed 16 pure mast cell colonies and 36 mixed mast cell colonies. Sixteen different combinations of cell types were seen and were not distinguishable from each other in situ. The most diverse type of mixed colony contained macrophages (m), neutrophils (n), eosinophils (e), mast cells (Mast), megakaryocytes (M), erythroid cells (E), and blast cells. The clonal origin of mixed mast cell colonies was established by the replating of single cells obtained from blast cell colonies. Individual cells were removed with a micromanipulator, replated, and allowed to grow for 15 days. Cytospin preparations of 10 such colonies showed diverse combinations of cell lineages which were seen in the different types of mixed mast cell colonies described above. Replating studies of mixed mast cell colonies were carried out and a high incidence of replating was seen. Approximately one half of these colonies formed only mast cell colonies upon replating. Further studies showed that pure mast cell colonies could be serially replated four to five times. The replating efficiency of cells in the primary mast cell colonies varied over a wide range (2.5–44%) with an average replating efficiency of 13%. The data also revealed that cells containing metachromatic granules possess significant proliferative capacity. From these studies of pure and mixed mast cell colonies, we concluded (1) that mast cells are in wide variety of types of mixed colonies and that the in situ identification of mixed colonies is unreliable, (2) that mast cells are derived from pluripotent hemopoietic stem cells, and (3) that mast cells with metachromatic granules can have a high proliferating ability.     

Serum-free culture of primitive murine hemopoietic colony-forming cells

We report the effect of four sources of hemopoietic growth factors, alone or in combination, on colony growth in serum-free cultures of bone marrow from normal mice or marrow from mice pre-treated with 5-fluorouracil (5-FU-bm). The four supplements were: mouse spleen conditioned medium (SCM, a source of multi-lineage colony-stimulating activity, multi-CSA), human placental conditioned medium (HPCM, a source of synergistic activity), pregnant mouse uterus extract (PMUE, a source of M-CSA) and erythropoietin (Epo). First, in cultures of normal marrow, only PMUE and SCM induced significant colony growth when added alone. The majority of those colonies contained granulocytes and macrophages (myeloid colonies). In Epo-supplemented cultures, only SCM supported the growth of erythroid bursts and mixed erythroid-myeloid colonies. HPCM thus appears to be a poor source of multi-CSA. Second, in cultures of 5-FU-bm, few colonies developed if any of the above supplements were added alone. Only SCM + Epo together stimulated the formation of a low number of very large, mixed erythroid/myeloid/megakaryocyte colonies. HPCM, but not SCM, synergized with PMUE to augment myeloid colony numbers. Hence, SCM appears to be a poor source of synergistic activity (SA). In cultures of 5-FU-bm already supplemented with HPCM + PMUE, the addition of Epo did not change total colony numbers but did induce erythroid differentiation in one third of the colonies present. These data suggest that multi-CSA and SA may be expressed by different factors and that 5-FU pre-treated marrow contains: a population of primitive multipotential progenitors which form large, mixed colonies in the presence of SCM + Epo, and a larger Epo-sensitive population which also requires HPCM + PMUE to form mixed colonies.     

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.     

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.     

A stochastic model of self-renewal and commitment to differentiation of the primitive hemopoietic stem cells in culture

We recently identified a murine hemopoietic stem cell colony which consists of undifferentiated (blast) cells and appears to be more primitive than CFU-GEMM in the stem cell hierarchy. The progenitors for the colony which we termed “stem cell colony” possess an extensive self-renewal capacity and the ability to generate many secondary multipotential hemopoietic colonies in culture. We replated a total of 68 stem cell colonies from cultures of murine spleen cells and analyzed the number of stem cell–and granulocyte(neutrophil)-erythrocyte-macrophage-megakaryocyte (GEMM) colony-forming cells in individual stem cell colonies. Of the 68 stem cell colonies, 35 contained progenitors (abbreviated as “S”-cells) for stem cell colonies. The distributions of S-cells and CFU-GEMM in individual stem cell colonies were extremely heterogeneous. Neither the frequency distributions of S-cells nor CFU-GEMM in stem cell colonies could be fitted well by Poisson distribution. Rather, the frequency distribution of the s-cells could be approximated by a geometric distribution and that of CFU-GEMM by an exponential distribution, both of which are variates of the gamma distribution. Our observations are in agreement with those on the distributions of CFU-S in individual spleen colonies and provided support for a stochastic model for stem cell self-renewal and commitment in culture. Application of the theory of the branching process to the distribution of S-cells revealed a distributional parameter “p” of 0.589 which is also in agreement with the earlier report on the p value for reproduction of CFU-S.     

Interactions between purified GM-CSF, purified erythropoietin and spleen conditioned medium on hemopoietic colony formation in vitro.

Preincubation of C57BL adult marrow cells or CBA fetal liver cells with a 250-fold excess concentration of purified GM-CSF failed to reduce the frequency of cells forming eosinophil, megakaryocyte or erythroid colonies in subsequent agar cultures. When excess concentrations of purified GM-CSF were added to agar cultures stimulated by pokeweed mitogen-stimulated spleen conditioned medium (SCM), no reduction was observed in the frequency of eosinophil, megakaryocyte or erythroid colonies. Addition of 4 units of purified erythropoietin (EPO) to cultures of fetal liver or adult marrow cells stimulated by SCM increased the number of erythroid colonies but did not reduce the number of non-erythroid colonies or the non-erythroid content of mixed erythroid colonies. Although neither GM-CSF nor EPO alone was able to stimulate erythroid colony formation in agar cultures of fetal liver cells, small numbers of large erythroid colonies were stimulated to develop in cultures containing both purified regulators. Purified GM-CSF was also able to support the survival in vitro of a small proportion of erythroid colony-forming cells in fetal liver populations cultured initially in the absence of SCM and the survival of some eosinophil and megakaryocyte colony-forming cells in similar cultures of adult marrow cells. The results do not support the hypothesis that GM-CSF and EPO compete for a common pool of uncommitted progenitor cells. On the contrary, the data indicate that GM-CSF und EPO are able to collaborate in stimulating the proliferation of some erythropoietic cells. Furthermore, purified GM-CSF appears to be able to support temporarily the survival and/or initial proliferation of at least some cells forming erythroid, eosinophil and megakaryocyte colonies, even though GM-CSF is unable to stimulate the formation of colonies of these types.     

The in vitro growth of murine high proliferative potential-colony forming cells is not enhanced by growth in a low oxygen atmosphere

The growth of primitive murine hematopoietic progenitors, high proliferative potential colony-forming cells (HPP-CFC), has been reported to be improved in low O2 tension cultures. In this report we investigated the growth of HPP-CFC stimulated by combinations of interleukin (IL)-1, IL-6, kit-ligand (KL), granulocyte (G) colony-stimulating factor (CSF), macrophage-CSF (M-CSF), granulocyte-macrophage-CSF (GM-CSF) and IL-3 in clonal cultures incubated at 7% or 21% O2 tension. Neither the numbers of HPP-CFC colonies nor the number of cells per HPP-CFC colony differed significantly between cultures grown under 7% or 21% O2 tension. The mean number of cells per HPP-CFC colony was found to range from 3.9 x 10(4) to 2.2 x 10(5). The smallest HPP-CFC colonies were stimulated by the cytokine combination IL-1 + IL-6 + KL, whereas the largest colonies were stimulated by a combination of all seven cytokines tested. The growth of erythroid colonies from murine or human bone marrow did, however, show some enhancement when cultured at a lower O2 tension. These results demonstrate that the growth of murine HPP-CFC was not compromised when cultured at ambient O2 concentration.     

Proliferation and differentiation in culture of mast cell progenitors derived from mast cell-deficient mice of genotype W/Wv

Mice of genotype W/Wv have less than 1% of normal mast cells in the skin, stomach, and cecum. In order to further clarify the mechanism of this deficiency, we studied committed mast cell progenitors and multipotent progenitors, which are capable of mast cell differentiation in clonal culture. The relative concentration of mast cell progenitors in the bone marrow, spleen, and peripheral blood of W/Wv mice was similar to that of +/+ mice. However, the cellularity of the marrows of W/Wv mice was 54% of that of their normal littermates. Identification of mast cells was established by metachromatic staining with toluidine blue, transmission electron microscopy, and demonstration of membrane receptors for immunoglobulin E. The time course of colony formation and the morphology of W/Wv mast cell colonies in culture was identical to that of normal littermates. The percentages of mast cells in individual multi-lineage colonies were extremely variable. The histamine content of mast cells derived from W/Wv mice was similar to that of mast cells from +/+ mice. These studies demonstrated the normal capacity for differentiation and proliferation in culture of mast cell progenitors from W/Wv mice.     

IL-9 enhances the growth of human mast cell progenitors under stimulation with stem cell factor

We examined the effects of IL-9 on human mast cell development from CD34(+) cord blood (CB) and peripheral blood cells in serum-deprived cultures. IL-9 apparently enhanced cell production under stimulation with stem cell factor (SCF) from CD34(+) CB cells. A great majority of the cultured cells grown with SCF + IL-9 became positive for tryptase at 4 wk. In methylcellulose cultures of CD34(+) CB cells, IL-9 increased both the number and size of mast cell colonies grown with SCF. Furthermore, SCF + IL-9 caused an exclusive expansion of mast cell colony-forming cells in a 2-wk liquid culture of CD34(+) CB cells, at a level markedly greater than for SCF alone. Clonal cell cultures and RT-PCR analysis showed that the targets of SCF + IL-9 were the CD34(+)CD38(+) CB cells rather than the CD34(+)CD38(-) CB cells. IL-9 neither augmented the SCF-dependent generation of progeny nor supported the survival of 6-wk-cultured mast cells. Moreover, there was no difference in the appearance of tryptase(+) cells and histamine content in the cultured cells between SCF and SCF + IL-9. The addition of IL-9 increased numbers of mast cell colonies grown with SCF from CD34(+) peripheral blood cells in children with or without asthma. It is of interest that mast cell progenitors of asthmatic patients responded to SCF + IL-9 to a greater extent than those of normal controls. Taken together, IL-9 appears to act as a potent enhancer for the SCF-dependent growth of mast cell progenitors in humans, particularly asthmatic patients.     

Stimulation of mouse connective tissue-type mast cells by hemopoietic stem cell factor, a ligand for the c-kit receptor.

The proliferative capacity of mouse connective tissue-type mast cells (CTMC) was analyzed by using a newly discovered c-kit ligand, termed stem cell factor (SCF). More than 90% of CTMC in the peritoneal cavity responded to recombinant rat SCF (rrSCF) and were able to give rise to pure mast cell colonies in methylcellulose culture. Serial observation (mapping) of growth of individual CTMC in culture containing rrSCF confirmed their striking proliferative ability. No serum but accessory cells (non-CTMC cells) in the peritoneal population were required for the clonal growth of CTMC induced by rrSCF in our methylcellulose culture of whole peritoneal cells. The rrSCF-induced mast cell colony formation from peritoneal CTMC was completely inhibited by the addition of anti-c-kit antibody, which can block the binding of SCF to c-kit, to the culture. When IL-3 was combined with rrSCF, mast cell colonies dramatically increased in size. Mapping studies revealed that the combination of the two factors augmented the proliferative rate of CTMC. Approximately 60% of the constituent cells of the mast cell colonies which were formed from peritoneal CTMC in the culture containing rrSCF alone were stained with berberine sulfate, which is a characteristic of CTMC. However, most mast cells which were induced by rrSCF+IL-3 from peritoneal CTMC contained berberine(-)-safranin(-)-Alcian blue(+) granules. Although IL-4 exhibited little synergism with rrSCF in the induction of CTMC proliferation, the addition of IL-4 to the culture containing rrSCF+IL-3 resulted in an increase in mast cells which retained CTMC characteristics.     

Murine B-cell stimulatory factor-1 (BSF-1)/interleukin-4 (IL-4) is a multilineage colony-stimulating factor that acts directly on primitive hemopoietic progenitors

Interleukin-4 (IL-4), which was originally identified as a B-cell growth factor, has been shown to produce diverse effects on hemopoietic progenitors. The present study investigated the effects of purified recombinant murine IL-4 on early hemopoetic progenitors in methylcellulose culture. IL-4 supported the formation of blast cell colonies and small granulocyte/macrophage (GM) colonies in cultures of marrow and spleen cells of normal mice as well as spleen cells of mice treated with 150 mg/kg 5-fluorouracil (5-FU) 4 days earlier. When the blast cell colonies were individually picked and replated in cultures containing WEHI-3 conditioned medium and erythropoietin (Ep), a variety of colonies were seen, including mixed erythroid colonies, indicating the multipotent nature of the blast cell colonies supported by IL-4. To test whether or not IL-4 affects multipotent progenitors directly, we replated pooled blast cells in cultures under varying conditions. In the presence of Ep, both IL-3 and IL-4 supported a similar number of granulocyte/erythrocyte/macrophage/megakaryocyte (GEMM) colonies. However, the number of GM colonies supported by IL-4 was significantly smaller than that supported by IL-3. When colony-supporting abilities of IL-4 and IL-3 were compared using day-4 post-5-FU spleen and day-2 post-5-FU marrow cells, IL-4 supported the formation of fewer blast cell colonies than did IL-3. IL-4 and IL-6 revealed synergy in support of colony formation from day 2 post-5-FU marrow cells. These results indicate that murine IL-4 is another direct-acting multilineage colony-stimulating factor (multi-CSF), similar to IL-3, that acts on primitive hemopoietic progenitors.     

Recombinant murine granulocyte-macrophage (GM) colony-stimulating factor supports formation of GM and multipotential blast cell colonies in culture: comparison with the effects of interleukin-3

We studied the effects of murine recombinant granulocyte-macrophage colony-stimulating factor (GM-CSF) on murine hemopoiesis in methylcellulose culture. The GM-CSF was purified from cultures of Saccharomyces cerevisiae transfected with a cloned murine GM-CSF cDNA. In cultures of spleen cells from normal mice, only granulocyte-macrophage (GM) colonies were supported by GM-CSF. Blast cell colonies were the predominant type in cultures of spleen cells from 5-fluorouracil (5-FU)-treated mice. Dose-response studies revealed that maximal GM and blast cell colony formation is achieved with 100 U/ml GM-CSF. Blast cell colonies revealed variable but high replating efficiencies, and the secondary colonies included multilineage colonies. Serial replating of washed blast cell colonies in cultures with GM-CSF provided evidence for the direct effects of GM-CSF on the proliferation of multipotential blast cells. A combination of GM-CSF and interleukin-3 (IL-3) did not increase the number of blast cell colonies over the level supported by IL-3. This observation indicates that the progenitors for blast cell colonies that responded to GM-CSF are a subpopulation of multipotential progenitors that are supported by IL-3. Cytological studies of colonies derived from GM-CSF and/or IL-3 suggest that the eosinophilopoietic ability of murine GM-CSF is less than that of IL-3.     

Proliferative effects of purified granulocyte colony-stimulating factor (G-CSF) on normal mouse hemopoietic cells

When granulocyte colony-stimulating factor (G-CSF), purified to homogeneity from mouse lung-conditioned medium, was added to agar cultures of mouse bone marrcw cells, it stimulated the formation of small numbers of granulocytic colonies. At high concentrations of G-CSF, a small proportion of macrophage and granulocyte-macrophage colonies also developed. G-CSF stimulated colony formation by highly enriched progenitor cell populations obtained by fractionation of mouse fetal liver cells using a fluorescence-activated cell sorter, indicating that G-CSF probably acts directly on target progenitor cells. Granulocytic colonies stimulated by G-CSF were small and uniform in size, and at 7 days of culture were composed of highly differentiated cells. Studies using clonal transfer and the delayed addition of other regulators showed that G-CSF could directly stimulate the initial proliferation of a large proportion of the granulocvte-macrophage progenitors in adult marrow and also the survival and/or proliferation of some multipotential, erythroid, and eosinophil progenitors in fetal liver. However, G-CSF was unable to sustain continued proliferation of these cells to result in colony formation. When G-CSF was mixed with purified granulocyte-macrophage colony-stimulating factor (GM-CSF) or macrophage colony-stimulating factor (M-CSF), the combination stimulated the formation by adult marrow cells of more granulocyte-macrophage colonies than either stimulus alone and an overall size increase in all colonies. G-CSF behaves as a predominantly granulopoietic stimulating factor but has some capacity to stimulate the initial proliferation of the same wide range of progenitor cells as that stimulated by GM-CSF.     

I. A subpopulation of human urothelial cells is stimulated to proliferate by treatment in vitro with lipoteichoic acid,a cell wall component of Streptococcus faecalis

Urinary tract infection with gram-positive bacteria is common. Avenues for ingress of bacteria into the bladder include luminal and suburothelial infection. Terminally differentiated superficial urothelial cells lining the lumen of the bladder are often shed in response to infection. In contrast, infection-induced altered function of progenitors of urothelial cells residing in the basal layer of the urothelium is likely to have long lasting effects on the structure and function of the urothelium. The main objective of the present studies was to investigate in vitro the possibility that exposure to lipoteichoic acid, a cell wall component of the gram-positive Streptococcus faecalis (LT-2), stimulates basal urothelial cells to proliferate. To simulate conditions that restrict proliferation and inhibit terminal differentiation of urothelial cells in the basal layer, secondary cultures of urothelial cells (UT) were grown on collagen or fibronectin-coated substrate in medium containing low levels of Ca²⁺ (0.2 mM) and growth factors (0.005% bovine pituitary extract [BPE]). Under these conditions, UT cultures displayed a highly reproducible colony size distribution, possibly due to the fact that colonies were progeny of basal cells with various proliferative potentials, retained in vitro. In cultures grown under growth-restricting conditions, the majority of progenitors appeared to be quiescent, just like stem cells in the basal layer of the urothelium. Thus, the population of large colonies (more than six cells/colony), was small when a steady state of growth was achieved, 3–7 days after seeding. Growth factors (0.005–0.5% BPE) caused a dose-dependent increase in this population of large colonies. Moreover, treatment of UT grown under growth-restricting conditions (0.005% BPE) with LT-2 increased steady-state levels of the population of large colonies to levels obtained in cultures growing under optimal conditions with respect to growth factors. These results indicated that the subpopulation of progenitors, quiescent under normal conditions, could be stimulated to proliferate. Two lines of evidence were consistent with the possibility that treatment with LT-2 stimulated proliferation of the subpopulation of progenitors and that large colonies were the progeny of this subpopulation of single cells: (1) treatment with LT-2 increased the percentage of single cells that incorporated bromodeoxyuridine (i.e., proliferated) in a time-dependent manner; (2) An increase in the percentage of large colonies was found following LT-2-triggered proliferation of single cells. We propose that, under normal conditions, cells produced in response to LT-2-triggered proliferation of stem cells are removed from the system due to an increased rate of differentiation followed by apoptosis. Recurrent infection and inflammation may not allow these processes to proceed effectively, resulting in chronic injury to the bladder. Moreover, under conditions in which stem cells accumulate mutations that incapacitate their progeny to undergo apoptosis, LT-triggered proliferation could be a contributing factor to tumorigenesis. © 1996 Wiley-Liss, Inc.     

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.     

Formation of Mononuclear Phagocyte (Macrophage) Colonies by Mouse Spleen Cells in Liquid Culture

The effect of the capsular polysaccharide of Klebsiella pneumoniae type 1 Kasuya strain (CPS-K) on the formation of macrophage colonies in cultures of mouse spleen cells was investigated by the liquid culture technique during an incubation period of 7–8 days. CPS-K markedly inhibited further generation of macrophage colonies when added at any time after the beginning of culture, whereas it showed no destructive effect on macrophage colonies which were already formed before its addition. When CPS-K was present throughout the incubation period, such a low concentration as 0.05 μg/ml significantly inhibited colony formation, and the intensity of its inhibitory effect depended on its dose in the range of 0.005–50 μg/ml. The inhibitory effect persisted even if CPS-K was washed out after spleen cells were kept in contact with 20 μg of CPS-K per ml at 37 C for 6 hr. It was found that the inhibitory effect of CPS-K on colony formation was not mediated through its action on T cells, B cells or macrophages, and that it was not due to the generation of suppressor cells capable of inhibiting colony formation. It is concluded therefore that CPS-K directly inhibits the proliferation of macrophage colony-forming cells. The active substance responsible for the inhibitory effect of CPS-K on colony formation is the neutral polysaccharide fraction of CPS-K.     

Colony formation in agar by multipotential hemopoietic cells.

Agar cultures of CBA fetal liver, peripheral blood, yolk sac and adult marrow cells were stimulated by pokeweed mitogen-stimulated spleen conditioned medium. Two to ten percent of the colonies developing were mixed colonies, documented by light or electron microscopy to contain erythroid, neutrophil, macrophage, eosinophil and megakaryocytic cells. No lymphoid cells were detected. Mean size for 7-day mixed colonies was 1,800-7,300 cells. When 7-day mixed colonies were recloned in agar, low levels of colony-forming cells were detected in 10% of the colonies but most daughter colonies formed were small neutrophil and/or macrophage colonies. Injection of pooled 7-day mixed colony cells to irradiated CBA mice produced low numbers of spleen colonies, mainly erythroid in composition. Karyotypic analysis using the T6T6 marker chromosome showed that some of these colonies were of donor origin. With an assumed f factor of 0.2, the mean content of spleen colony-forming cells per 7-day mixed colony was calculated to vary from 0.09 to 0.76 according to the type of mixed colony assayed. The fetal and adult multipotential hemopoietic cells forming mixed colonies in agar may be hemopoietic stem cells perhaps of a special or fetal type.     

Influence of hydrocortisone on the survival and cluster and colony forming characteristics of normal human granulocyte-macrophage progenitors

This study was performed to determine the colony and cluster forming ability of granulocyte-macrophage (CFU-GM) progenitors of normal human blood low density cells cultured in a liquid culture system in the presence and absence of physiological doses of hydrocortisone (Hc). The CFU-GM recovered from the liquid cultures were assayed in soft agar medium. The results of the assays indicated that time-related development of clusters and colonies over 1-16 days, proliferative responsiveness to a source of colony stimulating activity, number of cells developed per colony, and the cellular composition of clusters and colonies produced from CFU-GM recovered from 14-day-old liquid cultures with 1.0 microM Hc, were all similar to those that developed from the normal human blood low density cells. However, a higher fraction of the CFU-GM in day 14 liquid cultures with 1.0 microM Hc were in DNA synthesis phase compared with the CFU-GM from the peripheral blood. This study confirmed the results of previous studies showing lower numbers of recognizable neutrophilic granulocytes and improved survival/proliferation of CFU-GM at day 14 in liquid cultures with 1.0 microM Hc compared with cultures without Hc. The present results suggest that the normal human blood CFU-GM which persists and proliferates under the influence of Hc in a liquid culture system is similar in ontogeny to the blood CFU-GM, and that the recovery of CFU-GM from liquid cultures under the influence of Hc appears to be exerted through stimulation of proliferation and controlled differentiation.     

Soluble suppressor activity of concanavalin A-activated spleen cells on B-lymphocyte colony formation in vitro.

Supernates from concanavalin A (Con A)-activated mouse spleen cell cultures suppress the formation of B-lymphocyte colonies (BLC) in soft agar culture by 30 to 95%. Con A-induced BLC suppressive culture supernates can be heated at 80 °C for 1 hr without losing activity. The BLC suppressive activity is eliminated totally by trypsin treatment and partly by treatment with β-galactosidase. Activity is unaffected by treatment with DNAse, RNAse, and α-glucosidase. By ultrafiltration the BLC suppressive factor(s) was shown to have a molecular weight greater than 300,000. These data suggest that BLC suppression is mediated by a protein-carbohydrate complex. BLC suppression was obtained when normal spleen cells were preincubated in Con A-activated supernates for only 1 hr at 37 °C. BLC suppressor activity was absent in the supernatant fluid of Con A exposed anti-θ-treated spleen cells, nonadherent spleen cells, extensively washed spleen cells, and spleen cells from nude (athymic) mice suggesting that cells responsible for Con A-induced BLC suppression are adherent, fragile cells of the T lineage. Con A-activated spleen cell supernates do not suppress colony formation in soft agar by normal mouse granulocyte-macrophage precursors, by plasmacytoma cells, T-lymphoma cells, or by carcinoma cells. However, colony formation by Abelson's murine leukemia virus transformed B-lymphoma cells was suppressed by 95% suggesting a relationship between this immature B-lymphoma line and B-lymphocyte colony-forming cells. Con A-activated spleen cell supernates do not suppress lymphocyte activation in liquid culture by phytohemagglutinin, Con A, or lipopolysaccharide. Heat-treated supernates—which inhibited BLC development by 90–95%—did not suppress the plaque formation by spleen cells immunized in vivo or in vitro by sheep red blood cells.