Molecularly cloned and expressed murine T-cell gene product is biologically similar to interleukin-3

Clonal lines of mouse inducer ly1+ly2- inducer T-lymphocytes that depend for growth upon interleukin-2 have been demonstrated to produce a factor that stimulates colony formation by bone marrow granulocyte-macrophage (GM-CFUc) progenitor cells and replication of factor-dependent mast cell/basophil and multipotential hematopoietic cell lines in vitro. The molecularly cloned and expressed gene product for this growth factor demonstrates the following activities in vitro: using fresh bone marrow or purified subpopulations of nonadherent cells from murine continuous bone marrow cultures as target cells: stimulation of colony formation by GM-CFUc, mast cell progenitor cells, multipotential granulocyte/erythroid/megakaryocyte/macrophage progenitor cells (CFU-GEMM) colonies, erythroid progenitor cells forming macroscopic bursts (BFUe), and megakaryocyte progenitor cells (CFU-mega). The gene product also supports growth of previously reported mast cell growth-factor-dependent cell lines and several classes of interleukin-3 (IL-3)-dependent hematopoietic progenitor cell lines that are multipotential (neutrophil/basophil/eosinophil or neutrophil/basophil/erythroid); or committed to granulocyte-macrophage, or mast cell/basophil differentiation. The gene product does not detectably support replication of IL-2-dependent murine T-cell lines. The biologic activity of the gene product was inhibited greater than or equal to 90% by rabbit antisera prepared against purified interleukin-3. The data indicate that this T-cell derived lymphokine gene product is biologically very similar to interleukin-3.     

Pure and mixed erythroid colony formation in vitro stimulated by spleen conditioned medium with no detectable erythropoietin.

Cells from CBA fetal mouse liver formed pure or mixed erythroid colonies in semisolid agarculture after stimulation by medium conditioned by pokeweed mitogen-stimulated mouse spleen cells. In general shape, the erythroid colonies resembled typical 7-day single or multiple (burst) colonies. However one-third to one-half contained, in addition to erythroid cells, macrophages and neutrophils and, less commonly, megakaryocytes or eosinophils. Culture of micro manipulated single colony-forming cells showed these erythroid colonies to be clones. Colony-forming cells declined in frequency with advancing fetal age, but low numbers were detectable in adult bone marrow. Assays of spleen conditioned medium in polycythemic mice failed to detect erythropoietin; the cloning system may detect a fetal type of erythropoietin-independent, erythropoietic cell since few were detected in adult marrow.     

Distribution and differentiation of murine mast cell progenitors determined with soft agar culture

We have examined the distribution and differentiation of mast cell progenitors (mast-CFC) using a sensitive semisolid agar culture stimulated with STIL-3 (leukemic T cell line)-conditioned medium as a source of interleukin 3. The number of mast-CFC in the bone marrow of normal (+/+) mice was much higher than in previously reported data, although the number was almost the same in the spleen and peripheral blood as in previously reported data. Although mast-CFC were detectable in genetically anemic W/Wv mice as well, the concentration in the bone marrow was significantly lower than that of the +/+ mice. In the bone marrow there were more immature mast-CFC forming large-sized colonies (greater than 500 cells), whereas these were very few in the spleen and peripheral blood. Most mast-CFC were in the resting state. We conclude that mast-CFC differentiate to some extent in the bone marrow and then migrate in the peripheral blood to some organs where they proliferate and differentiate.     

Spleen stromal cell lines selectively support erythroid colony formation

Mouse stromal cell lines (MSS lines) have been established from the spleens of newborn mice in culture at a low serum concentration. These MSS lines support the proliferation and differentiation of the erythroid progenitor cells from mouse fetal livers and bone marrow in a semisolid medium in the presence of erythropoietin. Larger colonies of over 1,000 benzidine-positive erythroid cells were developed from the fetal liver cells on the MSS cell layers after 6 days of incubation. These layers also support the maturation of the erythroid cells since the enucleation process of the latter was observed in large erythroid colonies. Metabolically active MSS cells are apparently required to support the proliferation and differentiation of the erythroid progenitor cells, because neither the MSS cells inactivated with fixation nor the conditioned media of MSS cells promoted the erythroid colony formation. These studies demonstrate that MSS lines specifically support the proliferation and differentiation of the erythroid progenitor cells in vitro and that stroma cells may have a critical function in blood formation in the mouse spleen.     

Influence of murine mast cell growth factor (c-kit ligand) on colony formation by mouse marrow hematopoietic progenitor cells.

Purified natural and recombinant murine mast cell growth factor (MGF, a c-kit ligand) were evaluated alone and in combination with other cytokines for effects in vitro on colony formation by multipotential (CFU-GEMM), erythroid (BFU-E) and granulocyte-macrophage (CFU-GM) progenitor cells from BDF1 mouse bone marrow. Both preparations stimulated Epo-dependent CFU-GEMM and enhanced Epo-dependent BFU-E colony numbers and size. MGF had some stimulating activity for CFU-GM. When used in combination with plateau concentrations of pokeweed mitogen mouse spleen cell conditioned medium or granulocyte-macrophage colony stimulating factor (CSF), MGF enhanced in greater than additive fashion colony formation by CFU-GM. MGF also enhanced the size of colonies formed, an enhancement greatest for colonies containing granulocytes and macrophages. MGF did not enhance Macrophage-CSF stimulated colony numbers or size. MGF seems to be an early acting cytokine with preferential effects on the growth of more immature hematopoietic progenitor cells.     

Generation of functional clonal cell lines from human bone marrow stroma.

Five clonal human bone marrow stromal cell lines were isolated from the adherent cell populations in long-term liquid cultures after transfection with the recombinant plasmid pSV3gpt. All the cell-line feeder layers and their conditioned media stimulated the proliferation of committed granulomonocytic stem cells (CFUc) from human bone marrow. The size and number of early erythroid stem cell (BFUe)-derived colonies were significantly increased when in the presence of 10% conditioned medium from the cell lines. Furthermore, a substantial number of mixed colonies with erythroid components were observed in the cultures in the presence of erythropoietin and conditioned medium. These findings suggest that the human bone marrow stromal cell lines obtained after transfection with pSV3gpt may be extremely useful in identifying the hematopoietic factors derived from the hematopoietic microenvironment and in analyzing their mechanism of action.     

bcr-abl-Induced cell lines can switch from mast cell to erythroid or myeloid differentiation in vitro.

The chimeric bcr-abl gene formed by the Philadelphia translocation is thought to initiate chronic myeloid leukemia. Engraftment of mice with bone marrow cells infected with a bcr-abl retrovirus has been shown to elicit multiple hematopoietic disorders, including a clonal but nontransplantable hyperproliferation of erythroid and/or mast cells. Culture of spleen and bone marrow cells from such mice usually yielded mast cell lines, even when erythroid disease dominated the primary animal. The mast cells, which carried the same proviral insert as the primary disease, generally grew slowly and were neither transplantable nor clonogenic in agar until they had been cultured for several months. Unexpectedly, several bcr-abl-induced lines switched in vitro from mast cell to megakaryocytic and/or erythroid character, and one became myeloid. The dramatic phenotypic shifts seem likely to involve changes occurring within progenitor cells maintaining the clone, rather than mutation of mature mast cells. The variant lines exhibited substantial spontaneous differentiation, despite being readily transplantable and therefore fully transformed. The production of hematopoietic growth factors by the mast cell lines and their phenotypic variants may implicate an autocrine loop in their evolution. These novel bcr-abl cell lines should aid in the study of genetic events in the progression from chronic to acute leukemia and facilitate analysis of hematopoietic lineage commitment.     

Myeloproliferative syndrome induced by MPSV in DBA/2 mice: presence of a mixed-colonies promoting activity (MPA) in the spleen

The myeloproliferative syndrome induced by the myeloproliferative sarcoma virus (MPSV) in DBA/2 mice stimulates the proliferation of pluripotent hemopoietic stem cells (HSC) and of progenitors committed toward granulomacrophagic and erythroid cell lines. This stimulation may result from a direct effect of the MPSV on HSC or from an indirect effect via locally secreted factors. Normal isogenic bone marrow cells were incubated in the mixed colony-forming unit system in semisolid medium supplemented with conditioned media obtained after incubating neoplastic spleen cells for 3 days at 37 degrees C. These spleen conditioned media contain an activity that is physically separable from MPSV by ultracentrifugation and which, in the presence of a very low quantity of erythropoietin, can induce in vitro the proliferation and differentiation of pluripotent HSC, detected by this Mix-CFU technique. We termed this activity mixed-colonies promoting activity (MPA). These results suggest that the hyperplasia of the nonlymphoid hematopoietic system in the neoplastic spleen results from an indirect effect of the MPSV on pluripotent HSC via locally secreted factors.     

Presence of mixed colony-forming cells in long-term hamster bone marrow suspension cultures: response to pokeweed spleen conditioned medium

In contrast to the murine system, long-term hamster bone marrow suspension cultures maintain proliferation of both pluripotent and committed stem cells in the absence of an adherent layer and without addition of exogenous factors, such as hydrocortisone. Addition of pokeweed-mitogen-stimulated hamster spleen conditioned medium (SCM) to these long-term suspension cultures produces an increase in the number of mixed colonies assayed in soft-agar, These mixed colonies, which contained four cell lineages--granulocytic, erythroid, megakaryocytic, and macrophage--could be generated from cells grown in suspension for over 6 mo. Addition of SCM also induces an initial rapid expansion of the myeloid compartment, and this expansion results in 70% of the cells being terminally differentiated granulocytes. In contrast, addition of SCM to hamster bone marrow cultures containing both adherent cells and hematopoietic stem cells produced no change in the number of mixed colonies generated in the culture. This system allows the in vitro study of the process of stem cell proliferation and differentiation and also provides a means to examine the relationship of adherent and supernatant bone marrow populations.     

A tumor necrosis factor-responsive long-term-culture-initiating cell is associated with the stromal layer of mouse long-term bone marrow cultures.

Long-term bone marrow cultures provide a model for the study of hematopoiesis. Both an intact, adherent stromal layer and hematopoietic stem cells are necessary components in these cultures. Mycophenolic acid treatment of mouse long-term bone marrow cultures depletes them of all assayable hematopoietic precursors. The residual stromal cells are functional and support hematopoiesis if new progenitor cells are supplied. We now show that these mycophenolic acid-treated stromal cell cultures contain cells capable of hematopoietic differentiation without the addition of new progenitors. When treated with tumor necrosis factor alpha (20-200 units/ml), the apparently pure stromal cultures undergo an intense burst of hematopoietic activity. After 4 days such cultures contain approximately 2 x 10(6) hematopoietic cells and, by 1 week, they are indistinguishable from control long-term cultures that were not treated with mycophenolic acid. These results suggest that the stromal cultures either contain hematopoietic stem cells that are maintained quiescent and mycophenolic acid-resistant, perhaps by intimate contact with the stroma, or contain adherent cells that can be induced to differentiate into hematopoietic stem cells. These stem cells are primitive, in that they are capable of multilineage development in the long-term cultures, but are unable to form spleen colonies or myeloid colonies in semisolid medium. These data demonstrate that the adherent fraction of cultured bone marrow contains very primitive hematopoietic cells and that tumor necrosis factor alpha activates their proliferation and differentiation. They also suggest a strategy for obtaining the earliest progenitors free of other, more mature cell types.     

Erythroid differentiation in vitro is blocked by cyclopamine, an inhibitor of hedgehog signaling

Adult hematopoietic differentiation is a developmental process that employs many of the same molecular mechanisms as embryogenesis. To explore the possibility that hedgehog signaling is involved in the control of hematopoietic differentiation, we screened a panel of human leukemia cell lines for the expression of Patched1 and Smoothened, the receptor and coreceptor for hedgehog ligands. Expression was found in multiple cell lines, and Patched1 expression was detected in normal marrow. Induction of myeloid differentiation in cell lines downregulated expression of both genes. When normal marrow mononuclear cells were grown in semisolid medium in the presence of 10 microM cyclopamine, development of colonies of granulocytic/monocytic lineage was unaffected in terms of both number and morphology. The number of erythroid colonies, however, was significantly reduced (P < 0.01). Furthermore, hemoglobinization was substantially delayed relative to controls in those erythroid colonies that did form. Incubation of hematopoietic progenitors with Shh-N and GM-CSF resulted in increased granulocyte/monocyte colonies (P < 0.01); the increase was blocked by cyclopamine. Incubation of hematopoietic progenitors with Shh-N and stem cell factor resulted in larger erythroid colonies. These results suggest that elements of the hedgehog signaling pathway are involved in the control of hematopoietic differentiation.     

Regulatory mechanism of granulopoiesis in the bone marrow of CSF- producing tumor-bearing nude mice

The regulatory mechanism of differentiation of granulocyte and macrophage precursor cells (G/M CFU-C) in bone marrow and spleen obtained from nude mice bearing colony-stimulating factor (CSF) producing tumor (G-mice), which developed marked granulocytosis, was studied. In these mice, granulopoiesis is enhanced in the spleen, but suppressed in bone marrow. Coculture of G-mouse bone marrow cells with splenic cells of control nude mice (C-mice) and of G-mice resulted in 68% and 62%, respectively, more colonies than expected, while coculture of C-mouse bone marrow cells with these two sources of cell fractions resulted in only 2% and 11% more colonies. In the double-layer agar culture system, bone marrow and splenic cells of C- and G-mice produced a maximal number of colonies containing adequate amounts of human urinary CSF in the upper layer when C-mouse bone marrow cells were added to the lower layer, while these four sources of cells produced a moderate or minimal number of colonies when splenic cells of C- and G- mice or G-mouse bone marrow cells were added to the lower layer. Morphological examination of colonies formed in the upper layer revealed that addition of C-mouse bone marrow cells or irradiated G- mouse bone marrow cells to the lower layer resulted in a massive increment in the number of colonies with pure granulocytes and granulocyte and macrophage mixed (G + G/M) colonies formed by G-mouse bone marrow cells in the upper layer. However, the addition of irradiated C-mouse bone marrow cells or G-mouse bone marrow cells before irradiation to the lower layer did not change G + G/M colony formation by G-mouse bone marrow cells in the upper layer. We could reproduce these findings with conditioned media obtained from 3-day liquid cultures of these cell fractions. This suggests that a diffusible factor may be necessary for inhibition of G + G/M colony formation in G-mouse bone marrow cells. The fine mechanism of such inhibition remains to be clarified.     

Clonal assay of mouse mast cell colonies in methylcellulose culture

When mouse marrow and spleen cells were cultured for over 12 days in methylcellulose containing media conditioned by pokeweed-mitogen- stimulated spleen cells, colonies containing mast cells and blast cells were observed. The characteristic morphology of the colonies and the time course of their development allowed in situ identification of the mast cell colonies. Identification of the mast cells was confirmed by metachromatic staining with toluidine blue and alcian blue, transmission electron microscopy, and by demonstration of the membrane receptors for IgE. Coculture studies with male and female marrow cells strongly indicated the single cell origin of individual colonies. Detailed cytologic analyses of mixed hemopoietic colonies and replating experiments of individual mixed hemopoietic and mast cell colonies clearly established the hemopoietic origin of mast cells. In replating experiments of individual mast cell colonies, those without blast cells did not yield secondary mast cell colonies. This result strongly indicated that morphologically recognizable mast cells have lost their self-renewing capabilities. The quantitative nature of the mast cell colony assay was supported by linearity studies and provides a method for studies of the progenitors of mouse mast cells.     

Relationship of the hematopoietic cycle to the combined activities of a stimulator and a short-lived inhibitor

Substances that circulate in the blood following drug-induced bone marrow aplasia produce a biphasic curve of DNA synthesis in cells in liquid and semisolid cultures which reflect relative concentrations of these growth regulators of hematopoiesis. This net effect magnified by induced marrow failure in human, rat, and mouse is a sinusoidal curve that is the reciprocal of the WBC. Generated in the bone marrow, humoral stimulating activity (HSA) produces peak growth of colonies in agar (CFU-GM) during the proliferative phase of bone marrow recovery, whereas humoral inhibitory activity (HIA), present at the time of marrow maturation, suppresses colony growth. Split femurs from rats given cyclophosphamide (CY) and killed at regular intervals condition media that affect DNA synthesis in a fashion similar to that of HSA-HIA in the rats' sera. In Dexter cultures, HSA is derived from the adherent rather than the hematopoietic cell, whereas HIA is produced by that nonadherent cell. Animals treated with a lethal dose of busulfan (BU) produce large amounts of HSA in vivo until death. Those transplanted with adherent bone marrow cells depleted of hematopoietic cells on day 1 after BU also die, whereas those given nonadherent marrow cells survive and generate HIA at the time of bone marrow recovery. HSA and media conditioned by bone marrow stromal cells causes an increase in spleen colonies (CFU-S), as does HIA. These studies support the contention that the net effect of putative regulators of hematopoiesis, measured in the drug-perturbed state, consist of a constantly present stimulator emanating from bone marrow stroma, and a variable inhibitor produced by maturing hematopoietic bone marrow cells.     

Characterization of hemopoietic activities in media conditioned by a murine marrow-derived adherent cell line, B.Ad

The hemopoietic activities present in medium conditioned by a murine bone marrow-derived adherent cell line (B.Ad) have been studied. B.Ad-conditioned medium stimulated neutrophil, neutrophil-macrophage, and macrophage colonies in agar cultures of bone marrow cells and 90% of this activity was neutralized by antimacrophage colony-stimulating factor (anti-M-CSF). The conditioned medium supported the generation and/or maintenance of spleen colony-forming units (CFU-S) in liquid cultures and synergized with multilineage colony-stimulating factor (Multi-CSF; IL-3) to stimulate colony formation by day-3 post-5-fluorouracil (FU)-treated bone marrow cells. When used as feeder layers, B.Ad cells stimulated erythroid colony-forming units (CFU-E) and markedly enhanced erythroid burst-forming units (BFU-E) stimulation more than did maximal Multi-CSF (IL-3) and Epo stimulation. No CFU-E- or BFU-E-stimulating activities were detected in medium conditioned by B.Ad cells. Similarly, B.Ad-conditioned medium was unable to stimulate Multi-CSF (IL-3) or granulocyte-macrophage (GM)-CSF-dependent cell lines. The data suggest that medium conditioned by this bone marrow-derived adherent cell line contains M-CSF and other factors not detectable as CSFs that either directly or by means of a synergistic mechanism are able to stimulate CFU-S and colony-forming cells (CFC).     

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.     

Hematopoietic cell transformation by a murine recombinant retrovirus containing the src gene of Rous sarcoma virus.

A recombinant murine retrovirus (MRSV) containing the src gene of avian Rous sarcoma virus (RSV) was shown to induce hematopoietic colonies in infected mouse bone marrow. MRSV-induced colony formation followed single-hit kinetics and required mercaptoethanol in the agar medium. Cells from the colonies induced by MRSV could be established as continuous cell lines that demonstrated unrestricted self-renewal in vitro and tumorigenicity in vivo. The transformants, all of which expressed high levels of the Rous sarcoma virus transforming protein, pp60src, appeared to be at an early stage in lymphoid cell differentiation. They lacked Fc receptors and detectable immunoglobulin mu heavy chain synthesis, markers normally associated with committed B cells. The majority of the MRSV-transformed cell lines contained high levels of terminal deoxynucleotidyl transferase, an enzyme present in lymphoid progenitor cells committed to the T-cell lineage. One cell line expressed Thy-1 antigen, but none expressed Lyt-1 and Lyt-2, markers of more differentiated T cells. These findings demonstrate that the src gene is capable of transforming cells of hematopoietic origin.     

Clonal origin of human basophil/mast cells from circulating multipotent hemopoietic progenitors

The origin of the human basophil/mast cell lineage from a pluripotent hematopoietic stem cell has been surmised but never demonstrated. By examining individual hemopoietic colonies in methylcellulose under inverted microscopy and using histochemical stains in conjunction with single-colony histamine assays, we have previously identified basophil/mast cell progenitors in human peripheral blood. We now report that a large proportion of normal human peripheral blood mixed granuloerythropoietic (GEMM) colonies contain histamine, in contrast to a significantly lower frequency of histamine positivity among normal neutrophil-macrophage, eosinophil, erythroid, macrophage, or megakaryocyte colonies. Morphological observations confirmed the presence of basophil/mast cells in the majority of GEMM colonies. In our work, the clonal derivation of basophils/mast cells from circulating multipotent (CFU-GEMM) hemopoietic stem cells was formally demonstrated, using combined histamine and G6PD isoenzyme analysis of single colonies grown in methylcellulose from a normal G6PD heterozygote.     

Simian virus 40-transformed adherent cells from human long-term marrow cultures: cloned cell lines produce cells with stromal and hematopoietic characteristics

Adherent cells from long-term marrow cultures from 23 individuals were transformed with wild-type simian virus 40 (SV40). After transformation, cloned cell lines were developed that even after rigorous subcloning invariably produced both stromal cells and round cells. The stromal cells expressed cytoskeletal filaments similar to those of long-term marrow culture adherent cells and produced interstitial and basal lamina collagen types. The round cells had the electron microscopic appearance of primitive hematopoietic cells and when examined with cytochemical stains and monoclonal antibodies to hematopoietic differentiation antigens had reaction patterns suggestive of cells from several lineages. Most round cells expressed the pan- hematopoietic T-200 determinant, and lesser percentages expressed the early T cell antigens CD-1 and CD-3, HLA-DR determinants, the monocytic antigen recognized by Leu M3, and the myeloid antigens detected by monoclonal antibodies 1G10 and 12.8. In addition, when plated in semisolid medium in the presence of a source of colony-stimulating activity, up to 11% of the cells formed colonies consisting of blastlike cells that also expressed hematopoietic cell surface determinants. The data suggest that adherent cells in long-term marrow cultures contain a cell that after transformation by SV40 obligately produces cells with hematopoietic as well as stromalike features.