Human placenta-conditioned medium for stimulation of human granulopoietic precursor cell (CFU-C) colony growth in vitro.

Human placenta-conditioned medium (HPCM) has been reported to stimulate colony formation by human granulopoietic stem cells (CFU-C) in vitro. The present work was performed to further characterize this colony formation. The majority of HPCM batches tested stimulated colony growth equivalent to recombined human leukocyte feeder layers with optimal cellular composition. A broad plateau of the dose-response curve of HPCM was found. A linear correlation exists between the number of marrow cells plated and the number of colonies grown. Optimal duration of culture is between 9 and 11 days. Colonies are large and tend to be compact. Admixture of mature granulocytes does not affect the colony growth pattern under optimal culture conditions. These data document that HPCM is a suitable source of colony-stimulating activity for the routine assay of human CFU-C. Due to the constant colony stimulation, HPCM appears particularly valuable for longitudinal studies of human CFU-C.     

In vitro stimulation of human granulopoiesis by purified protein derivative (PPD)

Summary The effect of purified protein derivative (PPD) on human granulopoiesis was studied in an in vitro semisolid culture system of human bone marrow in which PPD was incorporated into the leukocyte feeder layers. We observed that preincubation of the feeder layers with PPD was necessary to induce a significant rise of agar culture colony-forming units (CFU-c) with a maximum of 3 days' preincubation and a dose of 200 g for 10 ⁶ leukocytes. A similar effect was obtained when a conditioned medium from PPD-stimulated leukocytes was used instead of feeder layers. We have found a significant correlation between the skin test response of the leukocyte donors to PPD and the colony-stimulating activity of their leukocytes exposed to PPD: these results suggest that PPD could stimulate human granulopoiesis by an indirect effect on CSF-producing mononuclear cells.     

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.     

Cellular responsiveness to stimulation in vitro: strain differences in hemopoietic colony forming cell responsiveness to stimulating factor and suppression of responsiveness by glucocorticoids

Granulocyte-macrophage colony formation from bone marrow cells in soft agar is dependent upon the presence of a stimulating factor and the number of colonies is related to its concentration. This dose-response effect provided a measurement of the responsiveness to stimulation of colony forming cell populations in marrows from different sources. There were significant differences between the responsiveness of cells from different strains of mice which paralleled the previously observed myelopoietic and immune responsiveness of these strains to stimulation in vivo. Low concentrations of hydrocrotisone reduced the responsiveness of colony forming cells (a) when added to cultures of normal marrow or (b) when cells were taken from hydrocortisone-treated mice and cultured in its absence. The reduction which followed inoculation was not apparent until the 4th day and occurred irrespective of mouse strain, type of drug or route of inoculation and with a dose (100 μg) which did not affect the actual number of colony forming cells in the marrow.     

Analysis of colonies developing in vitro from mouse bone marrow cells stimulated by kidney feeder layers or leukemic serum

An analysis has been made of cell colonies developing in agar cultures from mouse bone marrow cells following stimulation either by neonatal kidney cell feeder layers or AKR lymphoid leukemia serum. Colonies arose by cell proliferation and were mixtures of granulocytic and mononuclear cells. Colonies stimulated by kidney feeder layers reached a mean size of 2000 cells by day 10 of incubation and remained predominantly granulocytic in nature. When bovine serum was substituted for fetal calf serum, cell colonies grew to a smaller size and lost their granulocytic nature, finally becoming almost pure populations of mononuclear cells. Colonies stimulated by AKR leukemic serum reached a mean size of 350 cells by day 10 of incubation. Although these colonies initially were granulocytic in nature, they finally became almost pure populations of mononuclear cells. The colony mononuclear cells actively phagocytosed carbon, and contained metachromatic granules probably derived from ingestion of agar. The mononuclear cells in these colonies may not have been members of the original colony, but may have been incorporated in the colony as it expanded in size, subsequently proliferating in the favourable environment of the colony.     

EFFECTS OF SHORT-TERM CULTURE ON POPULATIONS OF HEMOPOIETIC PROGENITOR CELLS FROM MOUSE MARROW

We have studied the response of progenitor cells in mouse marrow to short-term cultivation in cell culture. In the presence of a feeder layer of mouse renal tubules, the number of granulocyte progenitors able to form colonies in cell culture showed a net increase. No such increase in numbers of stem cells detected by the spleen colony assay was observed under the same conditions, although there was some stimulation of uptake of tritiated thymidine into these cells. A rapid decrease in the numbers of both types of progenitor cells occurred in the cultures in the absence of a feeder layer. However, when marrow cell populations that had been cultivated for 2 days in the absence of a feeder layer were transplanted into irradiated mice, the surviving stem cells detected by the in vivo assay showed a prolonged phase of rapid growth, resulting in a more pronounced 'overshoot' in the growth curve.     

Physical separation of colony stimulating cells from in vitro colony forming cells in hemopoietic tissue

Hemopoietic colony formation in agar occurred spontaneously in mass cultures of marrow cells obtained from a number of species (guinea pig, rat, lamb, rabbit, pig, calf, human and Rhesus monkey). This contrasted with the observation that colony formation by mouse bone marrow exhibited an absolute requirement for an exogenous source of a colony stimulating factor. Analysis of spontaneous colony formation in Rhesus monkey marrow cultures revealed the presence of a cell type in hemopoietic tissue, capable of elaborating colony stimulating factor when used to condition media or as feeder layers. Equilibrium density gradient centrifugation separated colony stimulating cells from in vitro colony forming cells in monkey bone marrow. Separation studies on spleen, blood and marrow characterized the stimulating cells as of intermediate density, depleted or absent in fractions enriched for cells of the granulocytic series and localized in regions containing lymphocytes and monocytes. Adherence column separation of peripheral blood leukocytes showed the stimulating cells to be actively adherent, unlike the majority of lymphocytes, and combined adherence column and density separation indicated that stimulating cells were present in hemopoietic tissue within the population of adherent lymphocytes or monocytes.     

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.     

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.     

Effects of human leukocyte conditioned medium on mouse haemopoietic progenitor cells.

Medium conditioned by human peripheral blood leukocytes (HLCM) was studied for its in vitro effects on haemopoietic progenitor cells (CFU-s and CFU-c) present in mouse bone marrow. HLCM has poor colony stimulating activity in semi-solid cultures of mouse bone marrow cells, but invariably increases the number of colonies obtained in the presence of plateau levels of semi-purified colony stimulating factor (CSF). In liquid cultures, HLCM appears to contain a potent initiator of DNA synthesis in CFU-s, an activity which coincides with an increased CFU-s maintenance and causes a three- to four-fold increase in CFU-c number. It is apparent from this study that HLCM, in addition to stimulating colony formation in cultures of human bone marrow cells, has a profound in vitro effect on primitive haemopoietic progenitor cells of the mouse, which cannot be attributed to CSF.     

Differences in the in vitro growth pattern of fresh and cryopreserved granulo-monopoietic precursors

A study of the in vitro growth model of human granulo-monopoietic precursors (CFU-GM) before and after cryopreservation using both leukocyte feeder layers and GCT conditioned medium as the source of colony stimulating activity (CSA) is reported. The number of colonies produced with fresh cells was linearly related to the amount of marrow seeded with both CSA sources, whereas after cryopreservation this was true with feeder layers, and with GCT only at relatively high cell concentrations. This might indicate the production of granulopoietic stimulators on the part of a second population that is at least partly resistant to freezing. It seems more likely, however, that these results depend mainly on a sublethal damage to CFU-GM induced by freezing, thus making the cells hyporesponsive to some forms of CSA, such as those contained in GCT conditioned medium.     

EFFECTS OF HUMAN LEUKOCYTE CONDITIONED MEDIUM ON MOUSE HAEMOPOIETIC PROGENITOR CELLS

Medium conditioned by human peripheral blood leukocytes (HLCM) was studied for its in vitro effects on haemopoietic progenitor cells (CFU-s and CFU-c) present in mouse bone marrow. HLCM has poor colony stimulating activity in semi-solid cultures of mouse bone marrow cells. but invariably increases the number of colonies obtained in the presence of plateau levels of semi-purified colony stimulating factor (CSF). In liquid cultures, HLCM appears to contain a potent initiator of DNA synthesis in CFU-s. an activity which coincides with an increased CFU-s maintenance and causes a three- to four-fold increase in CFU-c number. It is apparent from this study that HLCM, in addition to stimulating colony formation in cultures of human bone marrow cells, has a profound in vitro effect on primitive haemopoietic progenitor cells of the mouse, which cannot be attributed to CSF.     

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.     

Growth and characterization of T cell colonies from human thymus

A semisolid microculture system was used to study T cell colonies grown from human thymocytes. Colony growth was absolutely dependent upon media conditioned by peripheral blood leukocytes (PBL) in the presence of phytohemagglutinin. Plating efficiency was further enhanced by the addition of a non-T, adherent, radiation-resistant (7500 rad) PBL subpopulation, but was not enhanced by culture supernatants of these cells. The T colony precursor cell in the thymus occurred with a frequency of 8.0 X 10(-3) and had a surface receptor for the OKT3 monoclonal antibody. Thymocyte colony cells were functionally distinct from PBL and the major thymocyte population. The colony cells proliferated in response to T cell mitogens, but only in the presence of exogenous growth factors. The cells stimulated normal PBL in mixed leukocyte culture (MLC), but did not respond to alloantigens in MLC or in assays of spontaneous cytotoxicity. This culture system should prove helpful in the study of human thymocyte differentiation.     

GCT-conditioned medium: An unsuitable stimulus for monitoring granulocyte-macrophage colony-forming cells in cryopreserved bone marrow

Assays of granulocyte-macrophage colony-forming cells provide a means of testing the viability of cryopreserved bone marrow cells intended for autologous transplantation. We have compared two different sources of granulocyte-macrophage colony-stimulating activity, giant cell tumor-conditioned medium (GCT-CM) and peripheral blood leukocyte feeder layers, to determine whether the former is a suitable substitute for leukocyte feeder layers in the assay. The results show that GCT-CM, while providing a comparable stimulus to that provided by leukocyte feeder layers for colony formation by fresh bone marrow samples, is an inadequate stimulus when cryopreserved bone marrow samples are cultured. GCT-CM is not therefore suitable for use in monitoring cryopreserved bone marrow, since there is gross underestimation of the number of colony-forming cells present when this stimulus is used. The results suggest that great care should be taken when selecting alternative sources of granulocyte-macrophage colony-stimulating activity for culture of cryopreserved material.     

The nature of 12-O-tetradecanoylphorbol-13-acetate (TPA)-stimulated hemopoiesis, colony stimulating factor (CSF) requirement for colony formation, and the effect of TPA on [125I]CSF-1 binding to macrophages

The tumor-promoting phorbol diester, 12-O-tetradecanoylphorbol-13-acetate (TPA) was found to act both independently of and synergistically with the mononuclear phagocyte specific colony stimulating factor (CSF-1) to stimulate the formation of macrophage colonies in cultures of mouse bone marrow cells. In contrast, TPA did not synergize with other CSF subclasses that stimulate the formation of eosinophil, eosinophil-neutrophil, neutrophil, neutrophil-macrophage, and macrophage colonies, nor with either of the two factors required for megakaryocyte colony formation, megakaryocyte CSF, and megakaryocyte colony potentiator. In serum-free mouse bone marrow cell cultures TPA retained the ability to independently stimulate macrophage colony formation. However, TPA-stimulated colony formation was suboptimal and delayed in serum-free cultures that could support optimal colony formation in the presence of CSF-1. In addition, TPA did not directly compete with [125I]CSF-1 at 4 degrees C for its specific, high-affinity receptor on mouse peritoneal exudate macrophages. However, a 2-hour preincubation of the cells with TPA at 37 degrees caused almost complete loss of the receptor. Thus, TPA is able to mimic CSF-1 in its effects on CSF-1 responsive cells in some aspects (the spectrum of target cells, the morphology of resulting colonies, and the ability to down-regulate the CSF-1 receptor) but it is not able to mimic CSF-1 in other ways (TPA alone cannot stimulate the full CSF-1 response, TPA does not stimulate the most primitive CSF-1 responsive cells, and TPA does not bind to the CSF-1 receptor).     

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.     

A monoclonal antibody to antigens expressed on MLR-activated T cells inhibits granulocyte macrophage colony formation

A monoclonal antibody specifically reactive with MLR-activated T cells (MLR2) was added to light density normal marrow cells, depleted of adherent cells and T lymphocytes, and plated in soft agar for granulocyte macrophage colony formation. Colonies from MLR2-treated marrow cells were reduced to less than 10% of expected growth. The inhibition was not complement dependent, did not require the continuous presence of MLR2 in culture, and could not be detected also when human placenta-conditioned medium was used in the place of leukocyte feeder layers as a source of colony-stimulating factor (CSF). Co-culture experiments with MLR2 treated and untreated marrow cells further excluded the possibility of an indirect effect of MLR2 on CFU-c via auxiliary cells. The results of this study suggest that myeloid progenitor cells express a lymphoid antigen that is absent on resting or activated B cells and on resting T cells, but is expressed on activated T cells.     

THE IN VITRO DIFFERENTIATION OF DENSITY SUB-POPULATIONS OF COLONY-FORMING CELLS UNDER THE INFLUENCE OF DIFFERENT TYPES OF COLONY-STIMULATING FACTOR

The in vitro proliferation and differentiation of myeloid progenitor cells (CFU-c) in agar culture from CBA/Ca mouse bone marrow cells was studied. Density sub-populations of marrow cells were obtained by equilibrium centrifugation in continuous albumin density gradients. The formation of colonies of granulocytes and/or macrophages was studied under the influence of three types of colony-stimulating factor (CSF) from mouse lung conditioned medium CSF_MLCM), post-endotoxin mouse serum (CSF_ES) and from human urine (CSF_Hu). The effect of the sulphydryl reagent mercaptoethanol on colony development was also examined. The density distribution of CFU-c was dependent on the type of CSF. Functional heterogeneity was found among CFU-c with partial discrimination between progenitor cells forming pure granulocytic colonies and those forming pure macro-phage colonies. Mercaptoethanol increased colony incidence but had no apparent effect on colony morphology or the density distribution of CFU-c.     

Characteristics of in vitro colony formation by cells from haemopoietic tissues

Summary The characteristics of stimulation of colony formationin vitro from cells of mouse haemopoietic tissues has been briefly reviewed. Mouse kidney or embryo feeder cells, media conditioned by the cells from these tissues, normal or leukemic mouse sera, sera from leukemic or infectious mononucleosis patients, human urine and mouse embryo extracts are all sources of colony stimulating activity and their properties have been described. All sources of colony-stimulating activity produce clones of cells of the granulocyte series. In tritiated thymidine treated mice injection of preparations rich in colony-stimulating activity has been shown to produce a neutrophil leucocytosis and accelerate the rate of accumulation of labelled neutrophils in the blood. It is suggested that thein vitro assay can detect factors capable of stimulating granulocyte development.