Detection of murine adult bone marrow stroma-initiating cells in Lin(-)c-fms(+)c-kit(low)VCAM-1(+) cells.

We attempted to characterize the phenotype of cells which initiate fibroblastic stromal cell formation (stroma-initiating cells: SICs), precursor cells for fibroblastic stromal cells, based on the expression of cell surface antigens. First, we stained adult murine bone marrow cells with several monoclonal antibodies and separated them by magnetic cell sorting. SICs were abundant in the c-kit(+), Sca-1(+), CD34(+), VCAM-1(+), c-fms(+), and Mac-1(-) populations. SICs were recovered in the lineage-negative (Lin(-)) cells but not the Lin(+) cells. When macrophage colony-stimulating factor (M-CSF) was absent from the culture medium, no stromal colony appeared among the populations enriched in SICs. Based on these findings, the cells negative for lineage markers and positive for c-fms (M-CSF receptor) were further divided on the basis of the expression of c-kit, VCAM-1, Sca-1 or CD34 with a fluorescence-activated cell sorter. SICs were found to be enriched in the Lin(-)c-fms(+)c-kit(low) cells and Lin(-)c-fms(+)VCAM-1(+) cells but not in Lin(-)c-fms(+)Sca-1(+) cells and Lin(-)c-fms(+)CD34(low) cells. As a result, the SICs were found to be present at highest frequency in Lin(-)c-fms(+)c-kit(low)VCAM-1(+) cells: a mean of 64% of the SICs in the Lin(-) cells were recovered in the population. In morphology and several characteristics, the stromal cells derived from Lin(-)c-fms(+)c-kit(low)VCAM-1(+) cells resembled fibroblastic cells. The number of Lin(-)c-fms(+)c-kit(low)VCAM-1(+) cells in bone marrow of mice injected with M-CSF was higher than that in control mice. In this study, we identified SICs as Lin(-)c-fms(+)c-kit(low)VCAM-1(+) cells and demonstrated that M-CSF had the ability to increase the cell population in vivo.

Antitumor immunity induced by irradiated tumor cells producing macrophage colony-stimulating factor.

We previously reported that administration into mice of mouse lymphoid leukemia L1210 cells engineered to secrete macrophage colony-stimulating factor (M-CSF) could lead to tumor rejection. Here, we demonstrate that inoculation with irradiated M-CSF-producing cells protects mice against a subsequent challenge with unmodified parental tumor cells. We used 2 experimental protocols: the inoculation with irradiated M-CSF-producing L1210 cells (EM5) before the challenge with parental cells and after the challenge with parental cells. Both protocols effectively improved the survival rate of mice compared with protocols in which irradiated non-M-CSF-producing L1210 cells (EM-mock) were inoculated. Inoculation with 1 x 10(2) irradiated EM5 cells was sufficient to prolong the survival time of mice subsequently challenged with 1 x 10(4) parental cells. In vivo depletion experiments with administration of antibodies suggested the involvement of CD4+ T cells, CD8+ T cells, and natural killer (NK) cells in the antitumor effect. Consistent with these findings, the cytotoxic T lymphocyte activity of splenocytes from EM5-inoculated mice was higher than that from EM-mock-inoculated mice, and L1210 tumors were heavily infiltrated by CD4+ T cells and NK cells as well as macrophages in EM5-inoculated mice.

p56(dok-2) as a cytokine-inducible inhibitor of cell proliferation and signal transduction.

p56(dok-2) acts as a multiple docking protein downstream of receptor or non-receptor tyrosine kinases. However, the role of p56(dok-2) in biological functions of cells is not clear. We found that transcription of the p56(dok-2) gene in macrophages was increased markedly in response to cytokines such as macrophage colony-stimulating factor (M-CSF), granulocyte/macrophage-CSF and interleukin-3 (IL-3). Forced expression of p56(dok-2) inhibited M-CSF-, granulocyte-CSF-, IL-3- and stem cell factor-induced proliferation of myeloid leukemia cells, M-NFS-60. The p56(dok-2)-overexpressing cells showed an impaired induction of c-myc but not of c-jun, junB or c-fos when stimulated with M-CSF. Consistent with these results, the peritoneal cavity of the hairless (hr/hr) strain of mutant mice, whose cells expressed less p56(dok-2) than wild-type mice, contained more macrophages than that of +/hr mice. Moreover, the inhibition of endogenous p56(dok-2) expression in macrophage-like tumor cells, J774A.1, by stable expression of antisense p56(dok-2) mRNA accelerated cell proliferation. The study identifies a novel role for p56(dok-2) as a molecule that negatively regulates signal transduction and cell proliferation mediated by cytokines in a feedback loop.

Effect of cytokines on the proliferation/differentiation of stroma-initiating cells.

A culture system that identifies the precursor of murine bone marrow fibroblastic stromal cells (stroma-initiating cells, SIC) has been developed. In this system, mature fibroblasts are depleted by adherence to plastic dishes and the nonadherent cells are seeded at a low density, which results in the formation of colonies composed of fibroblastic cells. Macrophage colony-stimulating factor (M-CSF) has been shown to accelerate the colony formation in the system. In this study, we examined the stroma-inducing activity of a number of cytokines. Neither granulocyte-CSF, stem cell factor, interleukin (IL)-1, IL-6, transforming growth factor, epidermal growth factor, insulin-like growth factor, platelet-derived growth factor, nor fibroblast growth factor showed the activity. Similarly, tumor necrosis factor (TNF) did not show any stroma-inducing activity, but the factor inhibited the stromal colony formation induced by M-CSF. In this study, we found that granulocyte/macrophage-CSF (GM-CSF) and IL-3, as well as M-CSF had the stroma-inducing activity. Neither an additive nor synergistic effect was observed when the three factors were assayed in various combinations. The stroma-inducing activity of M-CSF, GM-CSF and IL-3 was observed even if lineage-negative bone marrow cells were used as target cells, suggesting that mature hematopoietic cells such as macrophages and granulocytes were not involved in the induction of stromal colony formation by these factors. Our results raise the possibility that GM-CSF and IL-3 as well as M-CSF stimulate the proliferation or differentiation of the precursor of bone marrow fibroblastic stromal cells.

Identification of L-inositol and scyllitol and their distribution in various organs in chrysanthemum.

Two unidentified soluble carbohydrates were isolated from chrysanthemum (Dendranthema x grandiflorum (Ramat.) Kitamura) leaves using HPLC. The compounds were identified as 1 L-chiro-inositol, called L-inositol (1) and scyllo-inositol, called scyllitol (2) from the results of 1H-NMR, 13C-NMR, and CI-MS spectra. L-Inositol and scyllitol were distributed in four cultivars tested. L-Inositol concentration of petals gradually decreased during the flower bud development, but the L-inositol content increased by about 7 times. Scyllitol was detected only at an early stage of flower bud.

In vivo stimulatory effect of macrophage colony-stimulating factor on the number of stroma-initiating cells.

The in vivo effect of human macrophage colony-stimulating factor (M-CSF) on the number of cells that formed stromal colonies in an in vitro culture system (stroma-initiating cells; SICs) was investigated. We found that the number of SICs in the femurs of C57BL/6 mice was significantly increased by the treatment with M-CSF. We also found that the SICs were resistant to at least three different chemotherapeutic reagents, 5-fluorouracil (5-FU), cytarabine, and cyclophosphamide, because the femoral cells of mice treated with these reagents contained higher numbers of SICs than those of untreated mice. M-CSF treatment also increased the number of SICs of the reagent-pretreated mice. The SICs detected in our culture system were present only in Mac-1(-)CD45(-) cells, and the M-CSF treatment of 5-FU-pretreated mice actually increased the number of Mac-1(-)CD45(-) SICs. The Mac-1(-)CD45(-) SICs collected from mice that were pretreated with 5-FU and then treated with M-CSF formed stromal colonies under in vitro culture conditions that did not contain M-CSF but did contain a high concentration of fetal calf serum. This result suggested that SICs collected following the treatment procedure did not necessarily require the presence of M-CSF for their in vitro proliferation. Our study indicated that M-CSF has the ability to increase the number of progenitor or precursor cells for bone marrow stromal cells in vivo system.

Tumor vaccination with macrophage colony-stimulating factor-producing Lewis lung carcinoma in mice.

Expression of various cytokines by cytokine gene-transduced tumor cells has been shown to increase antitumor immunity of tumor-bearing hosts. In the present study, macrophage-colony stimulating factor (M-CSF) cDNA was retrovirally transfected into Lewis lung carcinoma cells (3LL) of C57BL/6 mouse origin, and the effects of M-CSF expression were studied by inoculating syngeneic C57BL/6 mice with M-CSF-expressing 3LL cells. The mice inoculated with the lowest M-CSF-producing 3LL clone showed significant prolongation of the survival compared with wild-type 3LL-Inoculated mice, and 70% or more of the mice inoculated with 3LL clones with higher M-CSF production rejected inoculation. Mice injected with radiation-inactivated M-CSF-expressing 3LL cells before or after Inoculation of wild-type 3LL cells showed prolonged survival compared with mice injected with radiated control 3LL cells before or after transplantation of wild-type cells. In vivo depletion of effector subpopulations by injection of antibodies against CD4+ T cells, CD8+ T cells, or natural killer (NK) cells suggested involvement of NK cells and CD4+ T cells in M-CSF-mediated antitumor cytotoxicity in M-CSF-producing 3LL cells-inoculated mice. Severe combined immunodeficiency (SCID) mice with defective T- and B-cell function showed prolonged survival duration after inoculation with M-CSF-expressing 3LL cells compared with those transplanted with control 3LL cells, and this effect of M-CSF expression by 3LL-cells in SCID mice was also abolished by in vivo depletion of NK cells by antibody injection. These findings together with the previous reports that M-CSF augments antibody-dependent and-independent antitumor cytotoxicity suggest that M-CSF induces tumor immunity in this cytokine-expressing tumor-transplantation model.

Augmentation of antitumor immunity using genetically M-CSF-expressing L1210 cells.

Macrophage colony-stimulating factor (M-CSF) enhances tumoricidal activities of macrophages. We transduced human M-CSF cDNA into the mouse lymphoid cell line, L1210, and examined the antitumor effect of the locally expressed M-CSF. Mice injected with the M-CSF-producing subline showed improved survival in comparison with the mock-transfected cell line or parental cell line plus M-CSF administration (20 microg/kg for 3 days) at inoculated cell numbers of 10(2) or 5 x 10(3). The survival rate at 50 days after injection of 10(6) high M-CSF-expressing cells was 80%, significantly higher than that after injection of the mock-transfected cells, which killed all the mice by day 23. The survival rate appeared to depend on the amount of M-CSF produced. Moreover, all surviving mice after intravenous injection of the M-CSF-expressing sublines were rechallenged with 10(6) parental L1210 cells at day 50, and all survived up to day 100, demonstrating that M-CSF-expressing cells induced immune protection against the parental cells. The same improvement of survival was observed in mouse M-CSF-expressing cell lines. These observations imply that M-CSF cDNA is a candidate gene for use in gene therapy in leukemia.

Augmentation of cancer chemotherapy by preinjection of human macrophage colony-stimulating factor in L1210 leukemic cell-inoculated mice.

Human macrophage colony-stimulating factor (hM-CSF) is a potent stimulator of the effector functions of monocytes/macrophages. We investigated the antitumor effects of this factor in CDF1 male mice inoculated with L1210 cells, a mouse B-cell leukemia line. Mice preinoculated with various numbers of L1210 cells on day 0 were given intravenous injections of vehicle (human serum albumin; HSA) (100 micrograms/kg/day) or hM-CSF (20 micrograms/kg/day) for 3 days from day 1. In mice preinoculated with 10(2) L1210 cells but not with 10(3) or more L1210 cells, a marked increment in survival rate was observed with hM-CSF treatment. We next examined the effect of hM-CSF treatment combined with chemotherapy on the survival of mice that had been preinoculated with 10(5) L1210 cells. In our system, the administration of 4.9 mg/kg adriamycin (ADM) alone slightly prolonged survival of the tumor-bearing mice, but all of the mice died within 20 days. When hM-CSF was injected for 3 days before this ADM treatment, the invasion and proliferation of tumor cells in the liver and spleen were markedly inhibited and 50% of the mice were still alive at day 50. We detected inhibitory activity toward L1210 growth in serum of mice administered with hM-CSF, and the degree of the inhibitory activity was correlated with the level of nitrite (NO2-) in the serum. When L1210 cells were co-cultured with peritoneal macrophages from mice intraperitoneally injected with hM-CSF, the uptake of [3H]thymidine in L1210 cells was inhibited. The inhibition was abolished by the addition of NG-monomethyl-L-arginine, an inhibitor of NO2- synthesis, suggesting that the reactive nitrogen oxide intermediate is involved in hM-CSF-induced inhibition of L1210 growth.