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 subpopulations 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 CSFMLCM), post-endotoxin mouse serum (CSFES) and from human urine (CSFHu). 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 macrophage colonies. Mercaptoethanol increased colony incidence but had no apparent effect on colony morphology or the density distribution of CFU-c.     

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.     

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.     

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.     

Transforming growth factor beta: possible roles in the regulation of normal and leukemic hematopoietic cell growth

We have recently demonstrated that transforming growth factor (TGF)-beta 1 and TGF-beta 2 are potent inhibitors of the growth and differentiation of murine and human hematopoietic cells. The proliferation of primary unfractionated murine bone marrow by interleukin-3 (IL-3) and human bone marrow by IL-3 or granulocyte/macrophage colony-stimulating factor (GM-CSF) was inhibited by TGF-beta 1 and TGF-beta 2, while the proliferation of murine bone marrow by GM-CSF or murine and human marrow with G-CSF was not inhibited. Mouse and human hematopoietic colony formation was differentially affected by TGF-beta 1. In particular, CFU-GM, CFU-GEMM, BFU-E, and HPP-CFC, the most immature colonies, were inhibited by TGF-beta 1, whereas the more differentiated unipotent CFU-G, CFU-M, and CFU-E were not affected. TGF-beta 1 inhibited IL-3-induced growth of murine leukemic cell lines within 24 h, after which the cells were still viable. Subsequent removal of the TGF-beta 1 results in the resumption of normal growth. TGF-beta 1 inhibited the growth of factor-dependent NFS-60 cells in a dose-dependent manner in response to IL-3, GM-CSF, G-CSF, CSF-1, IL-4, or IL-6. TGF-beta 1 inhibited the growth of a variety of murine and human myeloid leukemias, while erythroid and macrophage leukemias were insensitive. Lymphoid leukemias, whose normal cellular counterparts were markedly inhibited by TGF-beta, were also resistant to TGF-beta 1 inhibition. These leukemic cells have no detectable TGF-beta 1 receptors on their cell surface. Last, TGF-beta 1 directly inhibited the growth of isolated Thy-1-positive progenitor cells. Thus, TGF-beta may be an important modulator of normal and leukemic hematopoietic cell growth.     

Inhibition of early murine hemopoietic progenitor cell proliferation after in vivo locoregional administration of transforming growth factor-beta 1

Transforming growth factor-beta 1 (TGF beta 1) has been shown in vitro to be a potent negative regulator of growth and differentiation of early hemopoietic progenitor cells, but not of more mature progenitors. However, little information is yet available regarding similar effects in vivo. We have developed an approach whereby TGF beta 1 can be administered locoregionally to the bone marrow via direct injection into the femoral artery. Our studies show that intrafemoral administration of a single bolus dose of TGF beta 1 potently inhibits the baseline and IL-3-driven proliferation of bone marrow cells. This inhibition is relatively selective for the earlier multipotential granulocyte, erythroid, megakaryocyte, and macrophage CFU progenitor cells since these are completely inhibited while the more differentiated CFU assayed in culture colonies are inhibited by about 50%. The inhibition of hemopoietic progenitor growth and differentiation is both time and dose dependent with the maximal effect on the marrow observed at 24 h with doses greater than or equal to 5 micrograms/mouse, and the effect is reversed at later times. A possible practical implication of these in vivo results could be the use of TGF beta 1 to protect stem cells in the bone marrow from the myelotoxic effects of chemotherapeutic drugs.     

Colony-forming units in diffusion chambers (CFU-d) and colony-forming units in agar culture (CFU-c) obtained from normal human bone marrow: a possible parent-progeny relationship.

An series of experiments was performed to elucidate the relationship between cells that form granulocytic colonies in fibrin clot diffusion chambers implanted into the peritoneum (i.p.) of irradiated mice (CFU-d) and day 7 and day 14 CFU-U which give rise to colonies after 7 and 14 days in agar cultures in vitro, respectively. Normal human bone marrow cells were cultured in suspension in vitro or in diffusion chambers implanted into irradiated or non-irradiated mice. During these culture conditions there was an initial decrease in the number of CFU-c per culture. This was followed by an increase between day 2 and day 7 of culture. No similar increase of neutrophilic CFU-d was observed. When CFU-d, day 14 and day 7 CFU-c in normal marrow were separated by velocity sedimentation and cultured in suspension culture or in diffusion chambers for 7 days, the maximum increase of day 7 and day 14 CFU-c was observed in slowly sedimenting cell fractions which contained the majority of CFU-d. After 3 days in suspension culture, the maximum increase of day 14 CFU-c was found in fractions which also gave rise to maximum numbers of CFU-c after 7 days. However, day 7 CFU-c were found in fractions which initially contained the majority of day 14 CFU-c. No increase in CFU-d was found in fractions initially containing peak numbers of CFU-c. Between 53 and 71% of CFU-c harvested from diffusion chambers in irradiated mice or from suspension cultures were sensitive to pulse incubation with tritiated thymidine, suggesting that the cells were proliferating during these culture conditions. In diffusion chambers implanted into non-irradiated mice, however, CFU-c were found to be relatively resistant to this treatment (3-11% sensitive to tritiated thymidine). Thus marked increases in CFU-c were also observed during experimental conditions, where no significant DNA synthesis was detected. A reproducible time sequence of increase in CFU-c populations in culture was observed. Day 14 CFU-c and cells that gave rise to clusters on day 7 in agar increased between day 2 and day 4, whereas day 7 CFU-c increased between day 4 and day 7. The results suggested that CFU-d gave rise to CFU-c in culture and that day 14 CFU-c were precursors of day 7 CFU-c.     

COLONY-FORMING UNITS IN DIFFUSION CHAMBERS (CFU-d) AND COLONY-FORMING UNITS IN AGAR CULTURE (CFU-c) OBTAINED FROM NORMAL HUMAN BONE MARROW: A POSSIBLE PARENT–PROGENY RELATIONSHIP

A series of experiments was performed to elucidate the relationship between cells that form granulocytic colonies in fibrin clot diffusion chambers implanted into the peritoneum (i.p.) of irradiated mice (CFU-d) and day 7 and day 14 CFU-c which give rise to colonies after 7 and 14 days in agar cultures in vitro, respectively. Normal human bone marrow cells were cultured in suspension in vitro or in diffusion chambers implanted into irradiated or non-irradiated mice. During these culture conditions there was an initial decrease in the number of CFU-c per culture. This was followed by an increase between day 2 and day 7 of culture. No similar increase of neutrophilic CFU-d was observed. When CFU-d, day 14 and day 7 CFU-c in normal marrow were separated by velocity sedimentation and cultured in suspension culture or in diffusion chambers for 7 days, the maximum increase of day 7 and day 14 CFU-c was observed in slowly sedimenting cell fractions which contained the majority of CFU-d. After 3 days in suspension culture, the maximum increase of day 14 CFU-c was found in fractions which also gave rise to maximum numbers of CFU-c after 7 days. However, day 7 CFU-c were found in fractions which initially contained the majority of day 14 CFU-c. No increase in CFU-d was found in fractions initially containing peak numbers of CFU-c. Between 53 and 71% of CFU-c harvested from diffusion chambers in irradiated mice or from suspension cultures were sensitive to pulse incubation with tritiated thymidine, suggesting that the cells were proliferating during these culture conditions. In diffusion chambers implanted into non-irradiated mice, however, CFU-c were found to be relatively resistant to this treatment (3–11% sensitive to tritiated thymidine). Thus marked increases in CFU-c were also observed during experimental conditions, where no significant DNA synthesis was detected. A reproducible time sequence of increase in CFU-c populations in culture was observed. Day 14 CFU-c and cells that gave rise to clusters on day 7 in agar increased between day 2 and day 4, whereas day 7 CFU-c increased between day 4 and day 7. The results suggested that CFU-d gave rise to CFU-c in culture and that day 14 CFU-c were precursors of day 7 CFU-c.     

Transforming growth factor-beta inhibits the generation of cytotoxic T cells in virus-infected mice

The immunoregulatory effects of human recombinant transforming growth factor (rTGF) beta 1 and human recombinant glioblastoma-derived T cell suppressor factor (rG-TsF)/TGF beta 2 was investigated in mice infected with lymphocytic choriomeningitis virus (LCMV) or vaccinia virus. Starting on the day of infection, i.p. injections of 1 microgram/day or rTGF-beta 1 or rG-TsF/TGF-beta 2 suppressed the generation of virus specific CTL. The effect of TGF-beta on CTL (day 8) was less pronounced when TGF-beta treatment was delayed for 3 days after LCMV infection. rG-TsF/TGF-beta 2 also has an inhibiting effect on CTL-mediated disease in LCMV-infected mice: it prolonged the survival time of mice infected with LCMV and reduced the local swelling reaction after infection into the footpad. These results indicate that rTGF-beta 1 and rG-TsF/TGF-beta 2 influence T cell immune reactivity in vivo.     

Sustained engraftment of mice transplanted with IL-1-primed blood-derived stem cells.

IL-1 is considered the primary mediator of the acute phase response. One of the characteristic manifestations of this response is early neutrophilia that is probably caused by release of mature neutrophils from the bone marrow into the peripheral blood. In the present study, we assessed whether IL-1 had a similar releasing effect on the number of circulating progenitor cells and stem cells. Female BALB/c mice were injected i.p. with increasing (0.1-1.0 micrograms/mouse) concentrations of rhu-IL-1 alpha. IL-1 injection resulted in a marked dose-dependent increase in the number of polymorphonuclear neutrophils, granulocyte-macrophage colony-forming units (CFU-GM), and cells forming spleen colonies (CFU-S day 8 and day 12). The maximal increase was found at 4 to 8 h after injection of 1 micrograms IL-1 per mouse, yielding a mean fivefold elevation in neutrophil count, and a mean 30-fold and 10-fold increase in the number of circulating CFU-GM and CFU-S, respectively. In a subsequent series of experiments, lethally irradiated (8.5 Gy) female recipient animals were transplanted with 5 x 10(5) blood mononuclear cells derived from male IL-1-treated animals. Long-term survival was obtained in 68% of mice transplanted with peripheral blood cells derived from donor animals at 6 h after a single injection of 1 micrograms IL-1. The mean number of circulating CFU-GM in these donor animals was 557/ml blood. At 6 mo after transplantation, greater than 95% of the bone marrow cells were of male origin, as determined using in situ hybridization with a Y-chromosome specific probe. In contrast, long-term survival was reached in less than 10% of mice transplanted with an equal number of blood cells derived from saline-treated controls or donor animals treated with a dose of 0.1 micrograms IL-1. These results indicate that a single injection of IL-1 induces a shift of hematopoietic progenitor cells and marrow repopulating cells into peripheral blood and that these cells can be used to rescue and permanently repopulate the bone marrow of lethally irradiated recipients.     

Augmentation of erythroid burst formation by the addition of thymocytes and other myelo-lymphoid cells

Bone marrow from barrier-sustained specific pathogen-free (SPF) CBA and C57BL/6 mice gave relatively low numbers of BFU-E colonies in methylcellulose culture, as compared to conventional mice. Addition of thymocytes to the marrow cultures increased the yield of BFU-E colonies more than fourfold in SPF mice but only 1.5-fold in conventional mice. Colony size was also increased. Increased yield of BFU-E colonies was also obtained by co-culture of bone marrow with lymph node cells or with bone marrow or spleen cells from 900R whole-body-irradiated mice. The effect appeared to be cellular rather than humoral. It was not reproduced by conditioned medium from thymus or pokeweed mitogen stimulated spleen cells. The helper effect of thymus cells was eliminated or reduced by freezing and thawing, or by 48 hours of incubation after irradiation. Treatment of bone marrow cells in vitro with anti-theta serum and complement did not decrease the number of BFU-E colonies. The putative helper cells appear not to be T cells, were non-adherent to the plastic culture dish, and were cortisone resistant and radioresistant. The low BFU-E colony yield from SPF mouse marrow is presumed to be largely the result of deficiency of these non-T helper cells in SPF bone marrow, rather than of BFU-E progenitor cells.     

Separation of subpopulations of in vitro colony forming cells from mouse marrow by equilibrium density centrifugation

Equilibrium density centrifugation was used to characterise and separate subpopulations of mouse haemopoietic progenitor cells capable of producing colonies of granulocytes and macrophages in vitro. The material used to induce colony formation (CSF) was prepared from an extract of pregnant mouse uteri. This CSF preparation was found to be free of factors modifying the response. Under these culture conditions, in vitro colony forming cells (CFU-c) were found to be relatively homogeneous in their buoyant density. This homogeneity was independent of CSF concentration. A heterogeneous density profile of CFU-c was obtained when various cell fractions were cultured in the presence of CSF and rat blood lysate. The majority of the additional cells which responded to erythrocyte lysate were dense (modal density 1.080 g/cm³) compared to CFU-c which respond to CSF alone (modal density 1.074 g/cm³). It is concluded that in vitro colonies induced by CSF and in vitro colonies grown in the presence of CSF and erythrocyte lysate reflect two different populations of CFU-c.     

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.     

Recombinant TGF-beta1 stimulates bone marrow osteoprogenitor cell activity and bone matrix synthesis in osteopenic, old male mice.

We have previously hypothesized that the osteopenic changes seen in the skeletons of old male BALB/c mice are due to reductions in the availability and/or synthesis of bone TGF-beta which results in fewer, less osteogenic marrow osteoprogenitor cells (CFU-f; OPCs) and lower levels of bone formation. Among other things, this hypothesis would predict that introducing exogenous TGF-beta into old mice (growth factor replacement) should stimulate marrow CFU-f and increase bone formation. In the present study, we have tested this prediction and, indirectly the hypothesis, by injecting human recombinant TGF-beta1, i.p., into both young adult (4 month) and old mice (24 month). The effects of the growth factor on the skeleton were then assessed by measurements of trabecular bone volume, bone formation, fracture healing, and the number, proliferative, apoptotic, and alkaline phosphatase activity of marrow CFU-f/OPCs. Our data show that the introduction of 0.5 or 5.0 ug/day of TGF-beta1 into old mice for 20 days 1) increases trabecular bone volume, bone formation and the mineral apposition rate, 2) augments fracture healing, 3) increases the number and size of CFU-f colonies, and 4) increases proliferation and diminishes apoptosis of CFU-f in primary bone marrow cultures. Importantly, these stimulatory effects of injected growth factor are apparently age-specific, i.e., they are either not seen in young animals or, if seen, are found at much lower levels. While these observations do not exclude other possible mechanisms for the osteopenia of old mice, they provide further support for the hypothesis that, with age, diminished TGF-beta synthesis or availability results in a reduction in the marrow osteoprogenitor pool and bone formation. The findings also demonstrate that the latter changes can be reversed, at least transiently, by introducing exogenous TGF-beta1.     

Effect of a neutrophilia-inducing tumor on hemopoietic stem cells in mice

The influence of neutrophilic stimulation on hemopoietic stem cells was studied in mice with tumor-induced neutrophilia. Transfusions of marrow cells from normal and neutrophilic tumor-bearing mice into lethally irradiated normal and tumor-bearing mice were performed. The number and the erythroid:granuloid (E:G) ratio of day 7 colonies in the recipient spleens and bones as well as the size of spleen colonies of recipient animals were determined. The E:G ratio of spleen and bone marrow colonies between normal and tumor-bearing mouse recipients and the number of spleen colonies did not differ significantly in either experiment. However, spleen colonies which developed in tumor-bearing irradiated mice were significantly larger than those which developed in normal recipients in both experiments. These studies indicated that while the line of differentiation taken by hemopoietic stem cells was not affected by the neutrophilic influence of the tumor, the tumor-bearing host environment appeared to enhance proliferation of transfused stem cells and/or their descendants. The stimulators of granulocytopoiesis in this model of neutrophilia appear to act on a population of progenitor cells more mature than the stem cells capable of forming 7-day colonies in the spleen and bone marrow of irradiated recipient mice.     

Antibody-mediated suppression of bone marrow colony formation in vitro.

Antisera to mouse brain reacts with hematopoietic stem cells in the mouse bone marrow. We have examined the effect of anti-mouse brain serum (AMBS) on the development of in vitro colonies from mouse bone marrow cells. The addition of 5% AMBS to the cultures markedly decreased the numbers of colonies formed to an average of 10% of the number obtained with normal rabbit serum. AMBS suppressed formation induced by colony stimulating factors (CSF) derived from three different sources; serum from endotoxin treated mice, mouse L-cell conditioned media, and human peripheral mononuclear cell conditioned media. The suppressive activity was quantitatively recovered in the IgG fraction of AMBS. Divalent F(ab')2 fragments were as effective as the intact IgG in decreasing colony formation. Fab fragments were not suppressive. These results suggest that colony formation is induced via a dynamic interaction between CSF and the progenitor cell membrane, and that antibody directed at cell membrane antigen(s) interferes with the generation of the induction signal.     

The influence of a granulocytic inhibitor(s) on hematopoiesis in an in vivo culture system.

The in vivo diffusion chamber (DC) technique for mouse marrow culture was used to determine the effect of a granulocyte inhibitor on the proliferation of the pluripotent stem cell(CFU-s) and the granulocyte progenitor cell (CFU-c). Granulocyte conditioned medium was injected intraperitoneally into mice bearing DCs during the initial 48 hr of culture. The early injections of inhibitor resulted in a significantly reduced number of granulocytic progeny formed within the DCs while there was no growth inhibition of mouse fibroblasts cultured under identical conditions. The reduced cell production was due in part to a significant reduction in the self-renewal rate of the CFU-c while no apparent direct effect was observed upon the growth of the CFU-s within the same cultures. These data suggest that the granulocytic inhibitor(s) acted to reduce the proliferation within the CFU-c population and thereby diminished the amplification potential inherent in the initial cell inoculum.     

THE INFLUENCE OF A GRANULOCYTIC INHIBITOR(S) ON HEMATOPOIESIS IN AN IN VIVO CULTURE SYSTEM

The in vivo diffusion chamber (DC) technique for mouse marrow culture was used to determine the effect of a granulocyte inhibitor on the proliferation of the pluri-potent stem cell (CFU-s) and the granulocyte progenitor cell (CFU-c). Granulocyte conditioned medium was injected intraperitoneally into mice bearing DCs during the initial 48 hr of culture. The early injection of inhibitor resulted in a significantly reduced number of granulocytic progeny formed within the DCs while there was no growth inhibition of mouse fibroblasts cultured under identical conditions. The reduced cell production was due in part to a significant reduction in the self-renewal rate of the CFU-c while no apparent direct effect was observed upon the growth of the CFU-s within the same cultures. These data suggest that the granulocytic inhibitor(s) acted to reduce proliferation within the CFU-c population and thereby diminished the amplification potential inherent in the initial cell inoculum.     

GROWTH OF MOUSE AND HUMAN BONE MARROW IN DIFFUSION CHAMBERS IN MICE

Both murine and human bone marrow cells were cultured in plasma clots which were formed inside diffusion chambers implanted into cyclophosphamide- and saline-treated mice. After an initial fall, the number of mouse bone marrow cells and numbers of mouse myeloid stem cells (CFU-C) and agar cluster-forming units rose faster in the cyclophosphamide-treated animals. These hosts also favored formation of myeloid (CFU-D-G) and erythroid (CFU-D-E) colonies and myeloid clusters in the plasma clot. The number and growth rate of mouse CFU-D-G were higher than those of CFU-C from the same marrow population. These observations suggest the existence of humoral factors stimulating granulocyte progenitor cell replication and differentiation. At its best the increment of CFU-D-E number was equivalent to that caused by a single 0·1 unit erythropoietin dose. Culture of normal human marrow cells resulted in colonies in the plasma clot containing only granulocytes and macrophages. Cyclophosphamide-treated host animals were essential for human CFU-D-G development. Plating efficiency for human marrow myeloid colonies was better in the conventional in vitro agar cultures than in diffusion chambers.     

The detection of in vitro monocyte-macrophage colony-forming cells in mouse thymus and lymph nodes.

In vitro monocyte-macrophage colony-forming cells (CFC) have been detected in the thymus (30/10(6) cells) and in the cervical (22/10(6)) and mesenteric (20/10(6)) lymph nodes (LN) of the mouse. Thymus and LN derived CFC differed from bone marrow derived CFU-c in several characteristics parameters: (1) sole specificity of PMUE to induce colony formation (CF), (2) apparent singular line of monocyte-macrophage differentiation, (3) a marked 6- to 10-day lag period prior to initiation of CF, and (4) significantly slower rates of appearance of colonies in culture after initiation of CF. Two of these parameters are shared with those CFC detected within alveolar space, peritoneal exudate and pleural effusion. These are the delay prior to CF and the singular monocyte-macrophage differentiation. These similarities suggested that T-CFC and LN-CFC are probably of similar origin and represent, as suggested by Lin and Stewart ('74), a population of progenitor cells exclusively for monocyte-macrophages.