Mitogen-stimulated Spleen Cell Conditioned Medium Research Articles

Requirement of Smad3 for mast cell growth

The involvement of the TGF-β family in cell growth of bone marrow-derived mast cells (BMMC) cultured with medium containing pokeweed mitogen-stimulated spleen cell-conditioned medium (PWM-SCM) was examined. Doubling time of BMMC from Smad3-null mice was longer than that from wild-type (WT) mice, and the differences tended to be larger with time of culture. Consistent with the results, uptake and reduction of [3-(4,5-dimethylthiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2-(4-sulfophenyl)-2 H-tetrazolium, inner salt; MTS] was lower in Smad3-deficient BMMC. Cell cycle analyses revealed no apparent differences between WT BMMC and Smad3-deficient BMMC, suggesting that longer doubling time in Smad3-deficient BMMC resulted from increased cell death. TGF-β and activin A were supplied by PWM-SCM rather than by self-production by BMMC. Blocking the TGF-β pathway by anti-TGF-β neutralizing antibody or an inhibitor for the type I receptors for ligands including TGF-β and activin, SB431542, inhibited MTS uptake and reduction in WT BMMC, whereas anti-activin A antibody and SB431542 tended to inhibit them in Smad3-deficient BMMC. The present results suggest that TGF-β-induced and Smad3-mediated signaling is essential for maximal cell growth in mast cells, and that the activin pathway may be required for it when mast cell context is modulated by Smad3 depletion.

Identification of a unique membrane-bound molecule on a hemopoietic stem cell line and on multipotent progenitor cells.

Hemopoietic stem cells are a distinct population of cells that can differentiate into multilineages of hemopoietic cells and have long-term repopulation capability. A few membrane-bound molecules have been found to be preferentially, but not uniquely, present on the surface of these primitive cells. We report here the identification of a unique 105-kDa glycoprotein on the surface of hemopoietic stem cell line BL3. This molecule, recognized by the absorbed antiserum, is not present on the surface of myeloid progenitors 32D and FDC-P1 cells, EL4 T cells, and NIH 3T3 fibroblasts. This antiserum can also be used to block the proliferation of BL3 cells even in the presence of mitogen-stimulated spleen cell conditioned medium, which is known to have a stimulating activity on BL3 cells. It can also inhibit development of in vitro, fetal liver cell-derived multilineage colonies, but not other types of colonies, and of in vivo bone marrow cell-derived colony-forming unit spleen foci. These data suggest that gp105 plays an important role in hemopoietic stem cell differentiation.

Immortalized hemopoietic cells with stem cell properties

We have established a hemopoietic cell line, BL3, that possesses a rearranged retroviral genome, which we used as a genetic tag for their engraftment into lethally irradiated mice. Analysis of recipients up to 7 months after engraftment indicates that the marker was present in differentiated cells of various hemopoietic organs, in colony-forming cells, pre-CFU-S-forming cells, and in organs of secondary recipients from bone marrow cells of primary recipients. BL3 cells are Thy-1 +, Sca-1 +, B220 −, Mac-1 -, and Gr-1 −. They express GATA-1 and are able to develop “cobblestones” with stromal cells. They do not express and respond to several hemopoietic growth factors known to facilitate marrow recovery. However, they are negatively regulated by TGFO and can be stimulated by mitogenstimulated spleen cell-conditioned medium. We conclude that BL3 cells possess properties of hemopoietic stem cells, including their capability to contribute to long-term repopulation.

A study of mast cells in autoimmune mice: the proliferative response of autoimmune mast cells to cytokines.

To investigate the mechanisms underlying the increased number of mast cells in autoimmune mice, the proliferative response of autoimmune mast cells to cytokines was examined. Bone marrow cells from autoimmune NZB mice produced scarcely any bone marrow derived mast cells (BMMCs) in the presence of interleukin 3 (IL-3), but were able to generate BMMCs when cultured with pokeweed mitogen-stimulated spleen cell conditioned medium (PWM-SCM). In contrast, NZB BMMCs showed very little proliferation in the presence of PWM-SCM, but proliferated strongly when cultured with stem cell factor (SCF). Non-autoimmune NZW BMMCs showed a strong proliferative response to both IL-3 and PWM-SCM, but proliferated weakly in culture with SCF. Autoimmune NZB x NZW F1 (B/W) BMMCs shared the proliferative activities of both NZB and NZW BMMCs, showing strong proliferation in response to IL-3, PWM-SCM and SCF. All strains (including other non-autoimmune strains) except for NZW demonstrated synergism between PWM-SCM and SCF. This study suggests that the strong proliferative response of autoimmune mast cells to SCF plays a major role in, and that other cytokines are partially responsible for, increasing the number of mast cells in autoimmune mice. These mechanisms are discussed in relation to both constitutive and inducible hematopoiesis.

Clonal proliferation of murine lymphohemopoietic progenitors in culture.

We have used a two-step clonal culture system to unequivocally demonstrate that individual primitive lymphohemopoietic progenitor cells have the capacity for differentiation along either the myeloid or the B-lymphoid lineage. Highly enriched murine marrow cells were plated individually in culture by micromanipulation in the presence of pokeweed mitogen-stimulated spleen cell conditioned medium, erythropoietin, steel factor (SF), and interleukin (IL) 7. Forty-five percent of the single cells formed primary colonies expressing multiple hemopoietic lineages. When aliquots from individual colonies were replated in secondary methyl cellulose culture containing SF and IL-7, 41% of the primary colonies gave rise to lymphocyte colonies. Cells of the lymphocyte colonies were blast-like and B220+, sIg-, Mac-1-, Gr-1-, Ly-1-, L3T4-, Ly-2-, and CD3-. Thirty to 70% of the cells were Thy-1+. mu-chain mRNA was detected in most of the cells by in situ hybridization with an antisense RNA probe. When lymphocyte colonies derived from a single cell were pooled and individually injected into scid mice, donor-type IgM was measurable in the serum of mice and spleens contained donor-type B cells. We then carried out initial screening of growth factors to identify growth factors that might replace pokeweed mitogen-stimulated spleen cell conditioned medium in the primary culture. Combinations of two factors that included SF plus IL-6, IL-11, or granulocyte colony-stimulating factor were all effective in the primary culture in the maintenance of the B-lymphoid potential. Interestingly, IL-3 could neither replace nor act synergistically with SF to support the lymphoid potential of the primary cultures. Our observations demonstrate that many primitive progenitors previously believed to be myeloid-committed also possess B-lymphoid potential. This culture system should prove valuable for elucidation of the mechanisms regulating early stages of lymphohemopoiesis.

In vitro cloning of murine megakaryocyte progenitors (CFU-Meg)

Convenient and reproducible culture systems for murine megakaryocyte progenitor cells (colony-forming unit-megakaryocytes, CFU-Meg) are described. Mouse bone marrow cells are cultured in fibrin clots supplemented with Iscove's modified Dulbecco's medium and fetal bovine serum or in fibrin clots supplemented with serum-free IMDM, bovine serum albumin, transferrin, cholesterol, and L-α-phosphatidylcholine. In the presence of murine interleukin-3 or pokeweed mitogen-stimulated murine spleen cell-conditioned medium, these cultures support CFU-Meg colony formation effectively. The cultivation and counting of colonies in these culture systems is considerably easier when compared with previously reported culture systems.

Mechanism of mast cell deficiency in mutant mice of mi/mi genotype: an analysis by co-culture of mast cells and fibroblasts

Mutant mice of mi/mi genotype are osteopetrotic and are deficient in mast cells. The osteopetrosis of mi/mi mice can be cured by bone marrow transplantation from congenic normal (+/+) mice, and therefore, the cause of the osteopetrosis is attributed to a defect of osteoclasts. Since both osteoclasts and mast cells are the progeny of multipotential hematopoietic stem cells, we examined whether mast cells were defective in mi/mi mice. In spite of the deficiency of mast cells in tissues of mi/mi mice, mast cells did develop when spleen cells of mi/mi mice were cultured with pokeweed mitogen-stimulated spleen cell conditioned medium (PWM-SCM). The proliferative response of cultured mast cells (CMC) derived from mi/mi mice to PWM-SCM was comparable with that of CMC from +/+ mice. In contrast, when CMC were co-cultured with the NIH/3T3 fibroblast cell line in culture medium lacking PWM-SCM, only +/+ CMC entered into the S phase of the cell cycle and were maintained; mi/mi CMC gradually disappeared. Moreover, fibroblasts derived from the skin of mi/mi mice normally supported the proliferation of +/+ CMC. Thus, the mast cell deficiency of mi/mi mice appears to be due to the inability of mi/mi mast cells to respond to the proliferative stimulus presented by fibroblasts.

Mechanism of Mast Cell Deficiency in Mutant Mice of mi/mi Genotype: An Analysis by Co-Culture of Mast Cells and Fibroblasts

Mutant mice of mi/mi genotype are osteopetrotic and are deficient in mast cells. The osteopetrosis of mi/mi mice can be cured by bone marrow transplantation from congenic normal (+/+) mice, and therefore, the cause of the osteopetrosis is attributed to a defect of osteoclasts. Since both osteoclasts and mast cells are the progeny of multipotential hematopoietic stem cells, we examined whether mast cells were defective in mi/mi mice. In spite of the deficiency of mast cells in tissues of mi/mi mice, mast cells did develop when spleen cells of mi/mi mice were cultured with pokeweed mitogen-stimulated spleen cell conditioned medium (PWM-SCM). The proliferative response of cultured mast cells (CMC) derived from mi/mi mice to PWM-SCM was comparable with that of CMC from +/+ mice. In contrast, when CMC were co-cultured with the NIH/3T3 fibroblast cell line in culture medium lacking PWM-SCM, only +/+ CMC entered into the S phase of the cell cycle and were maintained; mi/mi CMC gradually disappeared. Moreover, fibroblasts derived from the skin of mi/mi mice normally supported the proliferation of +/+ CMC. Thus, the mast cell deficiency of mi/mi mice appears to be due to the inability of mi/mi mast cells to respond to the proliferative stimulus presented by fibroblasts.

Analysis of murine megakaryocyte colony size and ploidy: effects of interleukin-3.

Megakaryocytes develop from diploid precursor cells that, after variable numbers of mitoses, cease cell division and then undergo synchronous nuclear endoreduplication (endomitosis). Megakaryocyte colony formation represents an in-vitro model of these processes in which the number and ploidy of colony cells reflect the activity of the mitotic and endomitotic pathways, respectively. We have analyzed the size and ploidization of murine megakaryocyte colonies grown in agar and examined the influence of interleukin-3 (IL-3) on these parameters. Colonies were identified in situ by staining for acetylcholinesterase and the ploidy of colony cells was determined by fluorescence cytophotometry. More than 98% of the megakaryocytes that developed in culture could be analyzed. In cultures of unfractionated marrow cells stimulated by either pokeweed mitogen-stimulated spleen cell-conditioned medium (PWM-SCM, a crude source of megakaryocyte colony-stimulating activity) or IL-3, the modal ploidy of day-5 colony megakaryocytes was 16N (range 2N-128N). The distribution of colony size was described by an inverse exponential relationship. Colony size and geometric mean ploidy were inversely correlated under conditions of maximal stimulation with PWM-SCM and at all concentrations of IL-3 tested. Increasing concentrations of IL-3 in cultures of either unfractionated marrow cells or nonadherent T-lymphocyte-depleted (NATD) marrow cells stimulated similar dose-dependent increases in the mean size and numbers of megakaryocyte colonies but did not significantly alter their ploidy distribution. However, the mean ploidy of colony megakaryocytes in IL-3-stimulated cultures of NATD marrow cells was significantly less (P less than 0.001) than the mean ploidy of megakaryocytes in IL-3-stimulated cultures of unfractionated marrow cells. The mean ploidy of megakaryocytes, which developed in PWM-SCM-stimulated cultures, was not affected by initial accessory cell depletion. We conclude that the size and ploidy characteristics of day-5 murine megakaryocyte colonies are structured as continua and that IL-3 stimulates an increase in mean colony size and numbers without affecting ploidization. T-lymphocytes and adherent cells elaborate an activity which promotes endomitosis in vitro; factors in PWM-SCM can substitute for this activity.

Failure of W/Wv Mouse-Derived Cultured Mast Cells to Enter S Phase Upon Contact With NIH/3T3 Fibroblasts

Although W/Wv mutant mice are profoundly deficient in tissue mast cells, these mice do have cells with similar features of mast cells that develop from their bone marrow cells as efficiently as those from congenic +/+ mice in pokeweed mitogen-stimulated spleen cell-conditioned medium (PWM-SCM). With cultured mast cells (CMCs), we analyzed the mechanism of mast-cell deficiency in tissues of W/Wv mice. CMCs were established from bone marrow cells of W/Wv and congenic +/+ mice with PWM-SCM, and then co-cultured with various mouse fibroblast cell lines without PWM-SCM. All the examined mouse embryo-derived fibroblast cell lines maintained CMCs derived from +/+ mice, but not CMCs from W/Wv mice, for greater than 2 weeks. Mast cells in S phase were observed only in CMCs derived from +/+ mice under these conditions. The poor survival of W/Wv CMCs as compared with +/+ CMCs was not owing to a differential death rate but to the inability of W/Wv CMCs to continue active proliferation on fibroblasts without PWM-SCM. By synchronizing CMCs at the G1 phase of the cell cycle, the defect in W/Wv CMCs was further characterized as a failure to transit G1 and enter the S phase upon contact with fibroblasts. This finding indicates the indispensable function of the W gene product(s) for this response.

Mouse peritoneal macrophages produce CFU-gm and CFU-meg growth-promoting factors.

The effect of peritoneal macrophage-conditioned medium (macrophage CM) from lipopolysaccharide-injected mice on granulocyte-macrophage colony (CFU-gm) and megakaryocyte colony (CFU-meg) formation was examined using a plasma clot culture system. Macrophage CM stimulated mouse bone marrow cells to form CFU-gm and CFU-meg in the presence of pokeweed mitogen-stimulated spleen cell-conditioned medium, but it had no effect on colony formation in the absence of exogenous colony-stimulating factors (CSF). CFU-gm and CFU-meg colony formation was enhanced by low concentrations of exogenous GM-CSF or Meg-CSF alone. These data demonstrate that macrophage CM contains an activity that sensitized CFU-gm and CFU-meg to exogenous CSF.

Fibroblast-dependent growth of mouse mast cells in vitro: duplication of mast cell depletion in mutant mice of W/Wv genotype.

In spite of the apparent depletion of mast cells in tissues of mutant mice of W/Wv genotype, cells with many features of mast cells do develop when bone marrow cells of W/Wv mice are cultured in the presence of pokeweed mitogen-stimulated spleen cell-conditioned medium (PWM-SCM). In order to resolve this discrepancy and facilitate the analysis of the W mutation, we attempted to establish an in vitro system in which the in vivo defect of W/Wv mice can be reproduced. Cultured mast cells (CMC) were developed from bone marrow cells of either W/Wv or congenic +/+ mice, and then co-cultured with NIH/3T3 mouse fibroblasts in media supplemented only with fetal calf serum (i.e., in the absence of PWM-SCM). Under this condition, CMC from +/+ mice continued to divide and were maintained for more than 4 weeks. The supportive effect of NIH/3T3 cells required close-range interactions with CMC and was not due to synthesis of the known mast cell growth factors, interleukins 3 and 4. By contrast, CMC from W/Wv mice were not maintained, and the number of mast cells remaining after 4 weeks of co-culture was only 1% of the normal +/+ counterparts. Thus, the humoral factor-independent and cell contact-dependent system presented here revealed the intrinsic defects in growth and differentiation of CMC derived from W/Wv mice and might be useful for biochemical and molecular analysis of the gene product(s) encoded at the W locus.

Effects of hypoxia on megakaryocytopoiesis and granulopoiesis

Previous studies have reported that exposure of mice to hypoxic conditions results in a decrease in blood platelets. To further explore the effect of hypoxia on megakaryocytopoiesis, megakaryocytes and their progenitor cells (CFU-M) were studied in hypoxic mice. Mice were exposed to hypoxia by enclosure in cages covered with dimethyl-silicone rubber membranes for up to 10 d. At various times during the hypoxic and ex-hypoxic periods the total megakaryocytes and CFU-M were determined in the humerus and spleen. CFU-M were assayed in the soft gel colony forming assay using pokeweed mitogen-stimulated spleen cell conditioned medium (PWCM) as a source of colony stimulating activity. After 10 d of hypoxia, packed red cell volume (PRCV) increased to 148% of control levels and blood platelets decreased to 40% of controls. Total megakaryocytes and CFU-M per humerus decreased to 18% and 50% of controls respectively. 4 d into the ex-hypoxic phase, PRCV was still increased at 128% of controls while marrow megakaryocytes and CFU-M increased to normal levels. Platelet recovery was somewhat slower, returning to normal by d 6. In contrast to the findings in the marrow, total spleen megakaryocytes and CFU-M increased to about 3- and 5-fold of control levels respectively by 6 d of hypoxia. During the exhypoxic phase, CFU-M decreased to normal on d 4, followed by a rebound of 3-fold control values on d 8. Spleen megakaryocytes decreased more slowly, returning to normal by d 10. A marked granulocytosis was observed during the hypoxic phase.(ABSTRACT TRUNCATED AT 250 WORDS)

Normalization of Anti-Tick Response of Mast Cell-Deficient W/W v Mice by Intracutaneous Injection of Cultured Mast Cells

Genetically mast cell-deficient (WB X C57BL/6)F1-W/Wv mice show a defect in manifestation of resistance against larval Haemaphysalis longicornis ticks. In order to obtain direct evidence for anti-tick roles of mast cells, we examined whether intracutaneous injection of cultured mast cells normalized the defect of W/Wv mice. Bone marrow cells of (WB X C57BL/6)F1-+/+ mice were cultured in the presence of pokeweed mitogen-stimulated spleen cell-conditioned medium. More than 95% of the cultured cells were identified as immature mast cells 4 wk after the initiation of the culture; the cells were harvested and directly injected into the skin of W/Wv mice. Mast cells appeared at the injection sites, where the resistance against the ticks was observed. Thus, mast cells developing at the injection sites seem to play an essential role for manifestation of resistance.

Effect of insulin on murine megakaryocytopoiesis in a liquid culture system.

To examine the influence of insulin on megakaryocytopoiesis, we tested its effect on murine bone marrow cultures in a liquid culture system. In the presence of pokeweed mitogen-stimulated spleen cell conditioned medium in culture, insulin markedly enhanced megakaryocyte colony formation and increased the number and size of free megakaryocytes seen after 7 days. Many of the cells in cultures with insulin, however, were classified as immature, since they had a basophilic cytoplasm, a low cytoplasmic/nuclear ratio and low acetylcholinesterase activity. It is suggested that insulin potentiates murine marrow megakaryocytopoiesis in vitro, but that this is not accompanied by differentiation of the cells from the immature to mature state.

Interleukin 4 as an essential factor for in vitro clonal growth of murine connective tissue-type mast cells.

We investigated the biological activity of IL-4 to murine connective tissue-type mast cells (CTMC). When purified peritoneal mast cells, typical CTMC, were incubated with pokeweed mitogen-stimulated spleen cell-conditioned medium (PWM-SCM) in methylcellulose, about one-fifth of mast cells showed clonal growth. Recombinant IL-4 alone did not stimulate the clonal growth, and purified IL-3 alone induced development of a small number of tiny clusters. In contrast, addition of IL-4 to IL-3 increased the number of clusters by a factor of 10. The number and size of clusters induced by the combination of IL-3 and IL-4 were comparable to those of mast cell clusters induced by PWM-SCM. The present results indicate that IL-4 is an essential factor for in vitro clonal growth of CTMC.

Reproducible generation of autonomous malignant sublines from non-tumorogenic murine interleukin 3-dependent mast cell lines.

Murine interleukin 3 (IL-3)-dependent permanent mast cell lines derived from normal mouse bone marrow were established using pokeweed mitogen-stimulated spleen cell conditioned medium (SCM) as a source of IL-3. When propagated continuously in media containing a high concentration of IL-3 (20% SCM or 20 U/ml murine recombinant IL-3 (rIL-3], all the cell lines remained strictly factor-dependent in vitro and non-tumorogenic in vivo. However, we were able to reproducibly generate autonomous sublines from cultures supplemented with low amounts of IL-3 (1% SCM or 2 U/ml rIL-3). Abrogation of exogeneous growth factor dependency was always associated with neoplastic transformation. In newly generated autonomous sublines an autocrine mechanism of growth regulation was evident in vitro.

Production of Granulocyte-Macrophage Colony-Stimulating Factor by Abelson Virus-Induced Tumorigenic Mast Cell Lines

We have recently described a system that supports the development of continuously growing and tumorigenic cell lines after infection of individual multilineage hematopoietic colonies with Abelson murine leukemia virus (A-MuLV). We now provide definitive evidence that these transformed lines express features characteristic of mast cells. Although these lines have been maintained in some cases for more than a year in the absence of exogenous growth factors other than those present in fetal calf serum, colony formation could consistently after 2 months, and variably after 5 months, be shown to be increased several fold when pokeweed mitogen-stimulated spleen cell conditioned medium (CM) was added to the cultures. CM from the A-MuLV-transformed lines was then tested for its ability to stimulate hematopoietic colony formation by cells from both fetal and adult tissues. Four of four randomly selected cell lines produced factors that were active on erythropoietic, granulopoietic, and in some cases pluripotent progenitors. Removal of viral particles from the CM from one of the lines (27d1) by either heat inactivation or high-speed centrifugation did not alter the colony-stimulating activity detected. When CM from 27d1 cells was tested for its ability to stimulate the proliferation of interleukin 3 (IL3) granulocyte-macrophage colony-stimulating factor (GM-CSF)-dependent FDC-P1 cells, a positive result was obtained. This stimulatory activity was not reduced in the presence of neutralizing anti-IL 3 immunoglobulin (Ig), suggesting that the activity detected was GM-CSF and not IL 3. This was confirmed by the lack of expression of the IL 3 gene in 27d1 cells as determined by Northern analysis of 27d1 cell RNA. Furthermore, S1 analysis of mRNA from 27d1 cells as well as two other lines indicated that the GM-CSF gene in all three was transcriptionally active. Taken together, these data suggest that A-MuLV transformation of normal mast cells or their precursors under certain conditions commonly activates the production of GM-CSF.

Production of granulocyte-macrophage colony-stimulating factor by Abelson virus-induced tumorigenic mast cell lines

We have recently described a system that supports the development of continuously growing and tumorigenic cell lines after infection of individual multilineage hematopoietic colonies with Abelson murine leukemia virus (A-MuLV). We now provide definitive evidence that these transformed lines express features characteristic of mast cells. Although these lines have been maintained in some cases for more than a year in the absence of exogenous growth factors other than those present in fetal calf serum, colony formation could consistently after 2 months, and variably after 5 months, be shown to be increased several fold when pokeweed mitogen-stimulated spleen cell conditioned medium (CM) was added to the cultures. CM from the A-MuLV-transformed lines was then tested for its ability to stimulate hematopoietic colony formation by cells from both fetal and adult tissues. Four of four randomly selected cell lines produced factors that were active on erythropoietic, granulopoietic, and in some cases pluripotent progenitors. Removal of viral particles from the CM from one of the lines (27d1) by either heat inactivation or high-speed centrifugation did not alter the colony-stimulating activity detected. When CM from 27d1 cells was tested for its ability to stimulate the proliferation of interleukin 3 (IL3) granulocyte-macrophage colony-stimulating factor (GM-CSF)-dependent FDC-P1 cells, a positive result was obtained. This stimulatory activity was not reduced in the presence of neutralizing anti-IL 3 immunoglobulin (Ig), suggesting that the activity detected was GM-CSF and not IL 3. This was confirmed by the lack of expression of the IL 3 gene in 27d1 cells as determined by Northern analysis of 27d1 cell RNA. Furthermore, S1 analysis of mRNA from 27d1 cells as well as two other lines indicated that the GM-CSF gene in all three was transcriptionally active. Taken together, these data suggest that A- MuLV transformation of normal mast cells or their precursors under certain conditions commonly activates the production of GM-CSF.

Formation of mast cell colonies in methylcellulose by mouse peritoneal cells and differentiation of these cloned cells in both the skin and the gastric mucosa of W/Wv mice: evidence that a common precursor can give rise to both "connective tissue-type" and "mucosal" mast cells.

We investigated the issue of mast cell heterogeneity by cloning mast cell colonies from peritoneal cells in methylcellulose, injecting the cloned cells into the skin and stomach of mast cell-deficient (WB X C57BL/6)F1-W/Wv (WBB6F1-W/Wv) mice, and staining the mast cells that developed in these sites with Berberine sulfate, a fluorescent dye that identifies heparin-containing mast cells. When peritoneal cells of nontreated WBB6F1-+/+ mice were plated in methylcellulose containing pokeweed mitogen-stimulated spleen cell conditioned medium, pure mast cell colonies developed. In contrast, the peritoneal cavity of genetically mast cell-deficient WBB6F1-W/Wv mice lacked the progenitor cells that made mast-cell colonies. The clonal nature of the mast cell colonies was determined by using the giant granules of C57BL/6-bgJ/bgJ mice as a marker: even when mixture of peritoneal cells of C57BL/6-bgJ/bgJ mice and C57BL/6-+/+ mice were plated, all of the resulting colonies consisted of either bgJ/bgJ-type mast cells alone or +/+-type mast cells alone. Individual mast c 11 colonies of WBB6F1-+/+ mouse origin were divided into two parts; one part was directly injected into the wall of the glandular stomach of a WBB6F1-W/Wv mouse, and another part was injected into the skin of the same W/Wv mouse. Injections of 14 of 46 such colonies resulted in development of mast cells in both the "connective tissues" (skin or stomach muscle or both) and the stomach mucosa. Mast cells in the connective tissues were stained with Berberine-sulfate, indicating that they contained heparin, whereas mast cells in the stomach mucosa were not. These results suggest that a single precursor cell can give rise to both "connective tissue-type" and "mucosal" mast cells.