Negative regulation of early T lymphopoiesis by interleukin-3 and interleukin-1 alpha

We recently developed a two-step clonal cell culture system for murine lymphohematopoietic progenitors that are capable of producing myeloid and B-lymphoid progenies and characterized their cytokine requirements. We subsequently observed that addition of interleukin-3 (IL-3) or IL-1 alpha to permissive cytokine combinations in primary culture abrogates the B-lymphoid potential but not the myeloid potential of the lymphohematopoietic progenitors. We now describe a similar negative regulation of the T-cell potential of the lymphohematopoietic progenitors. Lin- Ly-6A/E+ marrow cells from 5-fluorouracil-treated mice were plated individually by micromanipulation in methylcellulose culture with steel factor (SF) and IL-11 for 8 days. The resulting colonies were tested for myeloid potential by reculturing part of each colony in secondary myeloid suspension culture. Remainders of individual primary colonies were injected intravenously into scid mice for determination of T- and B-lymphoid potentials. Approximately 10% of the progenitors that differentiated along myeloid lineages in culture reconstituted T- and B-cell compartments in scid mice. However, when scid mice were injected with colonies pooled from cultures containing steel factor, IL-11, and either IL-3 or IL-1 alpha, there was no reconstitution of thymocytes or spleen T cells. These results suggest negative regulatory roles for IL-3 and IL-1 alpha in the early stages of T lymphopoiesis.     

Negative regulation of early B lymphopoiesis by interleukin 3 and interleukin 1 alpha.

We recently developed a two-step methyl cellulose culture system for murine lymphohemopoietic progenitors that are capable of differentiation along the myeloid and B-lymphoid lineages. In this system, two-factor combinations, which include steel factor plus interleukin (IL) 6, IL-11, or granulocyte colony-stimulating factor effectively supported the lymphomyeloid potential of primary colonies. Interestingly, IL-3 could neither replace nor act synergistically with steel factor in maintaining the B-lymphoid potential of the primary colonies although the frequency of colony formation was the same with IL-3 and steel factor. We now report that addition of IL-3 or IL-1 alpha to a permissive system suppresses the B-lymphoid potential of primitive progenitor cells in primary culture in dose-dependent fashion. In vivo transfer of the primary colonies to scid mice confirmed the suppressive effects of IL-3 and IL-1 alpha. In addition, IL-1 alpha inhibited pre-B-cell colony formation in the secondary culture. Once pre-B-cell colonies had formed in secondary culture, neither factor affected the proliferation of the pre-B cells. These results suggest negative regulatory roles for IL-3 and IL-1 alpha in early stages of B lymphopoiesis.     

Identification in culture of a class of hemopoietic colony-forming units with extensive capability to self-renew and generate multipotential hemopoietic colonies.

Mouse marrow and spleen cells formed colonies consisting of 40-1,000 blast cells after 16 days of incubation in methylcellulose culture in the presence of medium conditioned by pokeweed mitogen-stimulated mouse spleen cells. These colonies could be distinguished from other hemopoietic colonies in situ by the complete absence of signs of terminal differentiation. Replating of these colonies (tentatively named stem cell colonies) revealed their self-renewal capacity and the extensive ability to generate secondary colonies, many of which were multipotential hemopoietic colonies. Some of the colonies revealed 100% replating efficiencies. Analyses of individual stem cells colonies revealed concurrent and high incidences of spleen colony-forming units and the macroscopic granulocyte-erythrocyte-macrophage-megakaryocyte colony-forming units (CFU-GEMM) in culture. Replating comparison between the stem cell colonies and GEMM colonies strongly indicated that the progenitors for the stem cell colonies are higher in the hierarchy of stem cell differentiation than are CFU-GEMM. Quantitation of stem cell colonies provides an assay for the class of primitive hemopoietic progenitors described here.     

Lymphohematopoietic progenitors of normal mice

We have identified and characterized the lymphohematopoietic progenitors in the bone marrow of normal mice using a single-step methylcellulose culture assay. Lineage-negative Ly-6A/E (Sca-1)+ progenitors isolated from normal mice were plated in methylcellulose culture containing steel factor (SF), interleukin-7 (IL-7), erythropoietin (Ep), and IL-11. After 16 to 17 days of culture, pre-B- cell-containing multilineage myeloid colonies can be microscopically identified; however, flow-cytometric analysis of individual colonies for B220-positive cells proved superior to in situ microscopic identification of lymphomyeloid colonies. Approximately 10% (6/66) of the mixed colonies without a conspicuous B-cell component had B220- positive cells. The single cell origin of the lymphomyeloid colonies was confirmed by micromanipulation. Although the combination of SF, IL- 7, and Ep was sufficient to support formation of lymphomyeloid colonies, addition of IL-11, granulocyte colony-stimulating factor or IL-12 to the combination of SF, IL-7, and Ep increased the number of lymphomyeloid colonies. IL-1 alpha and IL-3 independently inhibited the expression of the B-lymphoid lineage when added to the combination of SF, IL-7, Ep, and IL-11. Approximately four times more lymphohematopoietic progenitors are present in normal mice than in mice treated with 5-fluorouracil.     

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.     

Synergistic interaction between interleukin-12 and steel factor in support of proliferation of murine lymphohematopoietic progenitors in culture

We have investigated the effects of interleukin (IL)-12 (natural killer cell stimulatory factor/cytotoxic lymphocyte maturation factor) on the proliferation of murine myeloid and lymphohematopoietic progenitors in methylcellulose culture. In the presence of erythropoietin (Ep), IL-12 alone failed to support colony formation by mononuclear and enriched marrow cells of normal mice. Steel factor (SF) alone supported primarily formation of granulocyte/macrophage (GM) colony formation. However, the combination of the two cytokines yielded a significant number of multilineage colonies. When tested on marrow cells from 5- fluorouracil (5-FU)-treated mice, the combination of IL-12 and SF, but not the single factors, was effective in support of formation of various types of colonies. Approximately 25% of these colonies yielded pre-B-cell colonies when replated in secondary culture containing SF and IL-7, indicating that IL-12 can interact with SF in supporting the development of primitive lymphohematopoietic progenitors. These results demonstrate that IL-12, a cytokine believed to be involved in the development of cell-mediated immune responses, has a wider range of activity, including committed myeloid and multipotent lymphohematopoietic progenitors.     

Thrombopoietin, the ligand for the Mpl receptor, synergizes with steel factor and other early acting cytokines in supporting proliferation of primitive hematopoietic progenitors of mice

Recently, the ligand for the Mpl receptor (ML) was identified to be thrombopoietin, the principal regulator of megakaryocytopoiesis and thrombopoiesis. We examined the effects of ML, as a single factor or in combinations with early acting factors such as steel factor (SF), interleukin (IL)-3, IL-1, IL-6, and granulocyte colony-stimulating factor (G-CSF), on colony formation from primitive progenitors of mice. Cells enriched for cell cycle dormant primitive progenitors were isolated from bone marrow cells of 5-fluorouracil (5-FU)-treated mice by a combination of Nycodenz density gradient separation, immunomagnetic selection for lineage-negative cells, and fluorescence- activated cell sorter (FACS) sorting for Ly-6A/E+Kit+ cells. ML, in the presence of erythropoietin, could support the formation of only a few megakaryocyte colonies. However, ML acted synergistically with SF or IL- 3 to support the formation of multiple types of hematopoietic colonies including multilineage colonies. Effects of the combination of ML and SF on multipotential progenitors were not mediated through other cells, as demonstrated by micromanipulation of individual progenitors. In suspension culture, the combination of ML and SF increased the number of multipotential progenitors. ML also acted synergistically with IL- 11, IL-6, or G-CSF to support colony formation in serum-containing, but not in serum-free, cultures. However, the multilineage colony formation seen in serum-containing culture was completely abrogated by addition of ACK2, a neutralizing antibody to Kit protein. Serial observation (mapping studies) of colony development from multipotential progenitors suggested that ML triggers the cell division of dormant progenitors. Based on these observations, we propose that ML can function as an early acting cytokine and stimulate the proliferation of cell cycle dormant progenitors by shortening their G0 period.     

Sequential analysis of hematopoietic reconstitution achieved by transplantation of hematopoietic stem cells

We confirmed that murine hematopoietic stem cells express the c-kit molecule but not lymphohematopoietic lineage markers. These lineage marker-negative c-kit-positive (Lin- c-kit+) cells were further divided according to the uptake of rhodamine-123 (Rh-123). Approximately 1,000 Lin- c-kit+ rhodamine-123dull cells, which contained 4.0 +/- 1.3 and 12.5 +/- 1.9 day 8 and day 12 spleen colony-forming units (CFU-S), respectively, rescued the 100% of lethally irradiated mice. One third of these cells formed colonies in the presence of interleukin-3 plus erythropoietin. The time course of the hematopoietic reconstitution of this primitive hematopoietic stem cell fraction was investigated by using Ly-5 congenic mice. Although myeloid cells and B lymphocytes were detected in the peripheral blood 2 to 3 weeks after transplantation, T lymphocytes were not detected until 4 weeks after transplantation. It is generally assumed that myeloid cells and B lymphocytes grow in the bone marrow and that T lymphocytes must pass through the thymus. For the first 2 to 3 weeks after transplantation, donor-type T lymphocytes were not dominant in the thymus, and most donor type cells were CD4/CD8 double-negative or double-positive (including CD4low and CD8low). Four weeks after transplantation, donor-type T lymphocytes were dominant and the ratio of CD4/CD8 cells had recovered to the normal pattern. However, significant numbers of T lymphocytes were detected in the peripheral blood at this stage. Sequential analysis of hematopoietic reconstitution from primitive stem cells demonstrates that myeloid and B-lymphoid lineages occurred earlier than that of the T-lymphoid lineages.     

Cloning of murine megakaryocyte progenitor cells in a fibrin clot culture system

A fibrin clot culture system was applied to the cloning of mouse megakaryocyte colony-forming cells (CFU-Meg). The culture medium in this new method consists of Iscove's minimal essential medium containing fetal bovine serum, bovine fibrinogen, bovine thrombin, and pokeweed mitogen-stimulated mouse spleen cell-conditioned medium (PWM-SCM). CFU-Meg colony frequency with 10% PWM-SCM was maximal on days 5-6 of culture. Plating efficiencies averaged 36.1 +/- 3.9 and 51.9 +/- 6.0 per 1.5 X 10(5) BDF1 bone marrow cells and 1.0 X 10(6) spleen cells, respectively. The addition of bovine serum albumin to the culture medium had no effect on the efficiency of megakaryocyte colony growth in this culture system. This simplified and reproducible culture system supported not only the growth of colonies composed of megakaryocytes in "synchronous maturation," but also so-called "heterogenous" megakaryocyte colonies composed of cells in all stages of maturation.     

Soluble thrombopoietin receptor (Mpl) and granulocyte colony- stimulating factor receptor directly stimulate proliferation of primitive hematopoietic progenitors of mice in synergy with steel factor or the ligand for Flt3/Flk2

In an effort to establish the specificity of the thrombopoietin (TPO) effects on murine multipotential progenitors, we tested the effects of soluble TPO receptor (sTPOR; sMpl) on multilineage colony formation that was supported by a combination of TPO and steel factor (SF). Surprisingly, sTPOR did not suppress colony formation from primitive progenitors. This led to the discovery that sTPOR synergizes with SF or Flt3/Flk2 ligand (FL) to support the formation of various types of hematopoietic colonies including multilineage colonies. The colonies supported by the combination of sTPOR and SF were capable of expressing both myeloid and B-lymphoid potentials. Studies using micromanipulation and serum-free culture showed that the effects of sTPOR and SF on the primitive progenitors are direct, not mediated by contaminating stromal cells, and not dependent on factors present in the serum. TPOR belongs to the cytokine receptor group that includes granulocyte colony- stimulating factor receptor (G-CSFR) and erythropoietin receptor (EPOR). Therefore, we tested the effects of sG-CSFR and sEPOR on primitive progenitors. sG-CSFR, but not sEPOR, was able to synergize with SF or FL in supporting the proliferation of primitive progenitors. The direct effects of the soluble receptors appear to be mediated through interactions with their respective membrane-bound receptors expressed on the primitive hematopoietic progenitors.     

Growth factor requirement for survival in cell-cycle dormancy of primitive murine lymphohematopoietic progenitors

We used enriched marrow cells from mice administered three doses of 150 mg/kg 5-fluorouracil (5-FU) 1, 3 and 7 days before they were killed to study the effects of different growth factors on the survival of primitive, cell-cycle dormant progenitors in culture. This cell population yielded substantially fewer colonies in response to single growth factors than corresponding preparations from day 2 post-5-FU bone marrow samples, and the majority of progenitors were multipotential in nature. These observations were consistent with the prediction that multiple cycles of 5-FU treatment would further enrich for primitive cells. With this cell population, we found that among all the factors tested, interleukin-3 (IL-3) and steel factor (SF) as single factors are the most effective in supporting survival of dormant primitive progenitors. Interleukin-6 (IL-6), granulocyte colony- stimulating factor (G-CSF), interleukin-11 (IL-11), interleukin-4 (IL- 4), interleukin-1 alpha (IL-1 alpha), and tumor necrosis factor-alpha (TNF-alpha) also supported survival of a few progenitors, but much less effectively than either IL-3 or SF. The hematopoietic progenitors that survived for 1 week in liquid culture supplemented with either IL-3 or SF retained the capability to develop pre-B-cell colonies in secondary culture. Our results demonstrate that survival of dormant murine lymphohematopoietic cells in culture is dependent on the presence of specific growth factors, and that this growth factor requirement can be satisfied well by SF or IL-3.     

Demonstration of permanent factor-dependent multipotential (erythroid/neutrophil/basophil) hematopoietic progenitor cell lines.

Multipotential hematopoietic progenitor cell lines have been established from nonadherent cell populations removed from continuous mouse bone marrow cultures. Clonal sublines of lines B6SUtA or B6JUt derived from single cells formed mixed colonies containing erythroid cells, neutrophil-granulocytes, and basophil/mast cells in semisolid medium containing erythropoietin and conditioned medium from pokeweed mitogen-stimulated spleen cells. Each of several subclones of cell line Ro cl formed colonies containing eosinophils, neutrophil-granulocytes, and basophil/mast cells in semisolid medium. Multipotentiality was maintained in vitro for over 2 1/2 years. In contrast, cell line 32D formed basophil/mast cell colonies with no detectable differentiation to other pathways. Multipotential cell lines did not produce detectable spleen colonies (CFUs) in vivo, nor did intravenous inoculation of up to 5 X 10(7) cells protect lethally irradiated mice from bone marrow failure. Newborn and adult mice inoculated with 5 X 10(7) cells showed no detectable leukemia or solid tumors after one year. Both multipotential and committed basophil/mast cell lines demonstrated absolute dependence upon a source of a growth factor(s) found in medium conditioned by WEHI-3 cells. These cell lines should be of value in studies of the regulation of hematopoietic stem cell differentiation in vitro.     

Thrombopoietin supports proliferation of human primitive hematopoietic cells in synergy with steel factor and/or interleukin-3

We have studied the effects of recombinant human thrombopoietin (TPO; mpl ligand) on the proliferation of human primitive hematopoietic progenitors in vitro. CD34+ cells were enriched for cell-cycle-dormant primitive progenitors by separation on the basis of expression of c-kit and CD38. In the presence of varying combinations of TPO, Steel factor (SF), and interleukin-3 (IL-3), CD34+/c-kit(low)/CD38neg/low cells produced fewer colonies than CD34+/c-kit(low)/CD38high cells. However, when cultured in suspension for 7 days and replated in methylcellulose culture for measurement of colony-forming cells, the former population generated more colony-forming cells than the latter. In suspension culture of CD34+/c-kit(low)/CD38neg/low cells, TPO acted synergistically with SF and/or IL-3 in support of the production of colony-forming cells for granulocyte/macrophage colonies, erythroid colonies, and mixed colonies. Culture studies of individual CD34+/c- kit(low)/CD38neg/low cells provided the evidence for the direct nature of the effects of TPO. When combined with SF, TPO showed stronger stimulation of production of progenitors in suspension culture than other early-acting factors, such as IL-6, IL-11, and granulocyte colony- stimulating factor (G-CSF). TPO may be an important cytokine for in vitro manipulation of human hematopoietic stem cells.     

In vitro and in vivo effects of MDP-Lys(L18) on mouse megakaryocyte progenitor cells (CFU-Meg).

We investigated the in vitro and in vivo effects of MDP-Lys(L18), a derivative of muramyl dipeptide (MDP), on megakaryocyte progenitor cells (megakaryocyte colony-forming units, CFU-Meg) in the mouse bone marrow and spleen. When CFU-Meg culture was performed with a suboptimum concentration (2%) of pokeweed mitogen-stimulated mouse spleen-conditioned medium (PWM-SCM), addition of 0.1-20 micrograms/ml of MDP-Lys(L18) increased the number of megakaryocyte colonies. The size of the megakaryocyte colonies (the number of megakaryocytes per colony) was also significantly increased by the addition of MDP-Lys(L18) under the same culture conditions in comparison with cultures without MDP-Lys(L18). MDP-Lys(L18) itself did not stimulate megakaryocyte colony formation without PWM-SCM, and it failed to enhance megakaryocyte colony formation in cultures with an optimum PWM-SCM concentration (10%). Furthermore, no effect of MDP-Lys(L18) was observed in cultures of phagocytic cell-depleted bone marrow cells. However, MDP-Lys(L18) enhanced megakaryocyte colony formation in cultures of T-lymphocyte-depleted bone marrow cells. The culture supernatant from a macrophage cell line, J774.1, plus MDP-Lys(L18) enhanced in vitro megakaryocyte colony formation in cultures with a suboptimum PWM-SCM concentration. Although interleukin 1 (IL-1)beta in the culture supernatant of J774.1 plus MDP-Lys(L18) was increased in a dose-dependent manner in response to MDP-Lys(L18), the effect of the culture supernatant was not blocked by an anti-IL-1 antibody, and IL-1 beta failed to enhance megakaryocyte colony formation in the presence of suboptimum PWM-SCM levels. The enhancement of megakaryocyte colony formation by MDP-Lys(L18) could be neutralized, however, by an anti-interleukin 6 (IL-6) antibody. Intraperitoneal administration of MDP-Lys(L18) (100 micrograms daily for 3 days) significantly increased the number of bone marrow and spleen megakaryocyte colonies at 24 to 72 h after the final injection. These in vitro and in vivo observations strongly suggest that MDP-Lys(L18) indirectly enhances the proliferation and differentiation of mouse CFU-Meg via colony-stimulating factor(s) other than IL-1, probably as a result of the stimulation of macrophages to produce IL-6.     

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.     

Identification and characterization of 114/A10, an antigen highly expressed on the surface of murine myeloid and erythroid progenitor cells and IL-3-dependent cell lines

Monoclonal antibody (mAb) 114/A10, raised against the murine bone marrow-derived multipotential hemopoietic progenitor cell line B6SUtA, identifies an antigen highly expressed by various interleukin-3 (IL-3)-dependent cell lines, the myelomonocytic cell line WEHI-3, and a large proportion of primary myeloid and erythroid colony-forming cells. Spleen- and bone marrow-derived 114/A10-positive cells were shown to selectively proliferate in vitro in response to pokeweed mitogen-stimulated spleen cell-conditioned medium or recombinant IL-3. Western blot analysis indicated that the antigen recognized by mAb 114/A10 has a mean relative molecular mass of approximately 150,000, although it is extremely heterogeneous in nature, and differs greatly in size range among different cell lines.     

Immunologic stimulation of early murine hematopoiesis and its abrogation by cyclosporin A

Mice injected chronically with antiplatelet serum develop an increase in the number of megakaryocytic progenitor cells compared to animals given normal rabbit serum. To examine the specificity of this response, progenitor cells giving rise to megakaryocyte, granulocyte-macrophage, erythroid, and mixed-cell colonies were assayed after injection of various heterosera or saline. All four colony types increased in the serum-treated groups. Since the in vitro proliferation of hematopoietic progenitor cells is promoted by supernatants of mitogen-stimulated spleen cells, we hypothesized that the immune response following antiserum administration resulted in the in vivo activation of T lymphocytes which produced or led to the production of colony stimulating activities. To test this hypothesis, cyclosporin A, a preferential inhibitor of T lymphocyte function, was given to mice concurrently with antiserum and also added to spleen cell cultures in the presence of pokeweed mitogen. Cyclosporin A abrogated the antiserum- related increases in progenitor cell numbers in vivo and the production of colony stimulating activity in vitro. The results suggest that the immune response related to antiserum administration results in the in vivo production of hematopoietic colony stimulating activities that may be identical to those produced in vitro by mitogen-stimulation of spleen cells.     

NK cell colony formation from human fetal thymocytes

We established a clonal cell culture system for human natural killer (NK) cells from fetal thymocytes. Thymocytes of 16 to 22 gestational weeks were cultured in methylcellulose in the presence of interleukin (IL)-7, IL-15, and steel factor (SF). After 14 days in incubation, large, diffuse colonies consisting of small cells were identified. Cells in the colonies were medium- to large-sized granular lymphocytes, expressing CD56 but not CD3, and revealed lytic activity against K562 cells. Colony-forming units (CFU)-NK were enriched in lineage negative (Lin- ) CD34++ subpopulations of fetal thymocytes, whereas a smaller number of CFU-NK also existed in Lin-CD34+ and Lin-CD34- subpopulations. Cytokine requirement for the NK cell colony formation was examined under serum-free conditions. As a single agent, only IL-15, but not IL-2, IL-7, or SF, supported NK cell colony formation. IL-15 had synergy with IL-7 and SF independently, and the maximal number of colonies were obtained when the three cytokines were present. IL-2 also supported NK cell colony formation in the presence of SF. When IL-2 was added to cultures containing IL-15 alone, IL-15 plus SF, or IL-15, SF, and IL-7, the numbers of NK cell colonies were reduced relative to those without IL-2. These results indicate that IL-2 may regulate IL-15-responsive NK cell progenitors. This clonal culture system will be a useful tool in the investigation of NK cell ontogeny.