Bone marrow stroma from refractory anemia of myelodysplastic syndrome is defective in its ability to support normal CD34-positive cell proliferation and differentiation in vitro.

We examined the supportive function of stromal cells from patients with refractory anemia (RA) of myelodysplastic syndrome (MDS) on CD34-positive hematopoietic cell proliferation and differentiation using a long-term bone marrow culture (LTMC) system. Primary marrow stromal cells were obtained from 11 MDS RA patients and 12 healthy volunteers, and freshly prepared CD34-positive bone marrow cells from a normal subject were inoculated onto the stroma. There seems to be three broad patterns of hematopoietic cell growth in the LTMCs. In one group, hematopoietic cells were maintained at near normal levels (type A). In the second group, the number of hematopoietic cells increased within the first 5-10 days of culture, but declined to low levels at 15-20 days of culture as compared with normal control (type B). In the third group, the incidence of hematopoietic cells steadily declined from the beginning of the culture (type C). Furthermore, apoptotic change of hematopoietic cells was very frequently observed in cultures with the type C stroma, which were especially defective for supporting CD34 + cell proliferation and differentiation. The expression of CD95 on hematopoietic cells was induced by the type C stroma, however, production of fas ligand by the stromal cells was not observed. These findings suggest a lack of hematopoietic supportive function in some cases of MDS RA and also indicate that there is heterogeneity of stromal function among MDS RA patients.

Stimulatory effects of substance P on CD34 positive cell proliferation and differentiation in vitro are mediated by the modulation of stromal cell function.

Substance P (SP) is a neuropeptide widely distributed in the nervous system. Extensive study has shown SP stimulates production of various cytokines by bone marrow stromal cells, although, the role of SP in hematopoietic phenomena is still unclear. Recently, we established a human cloned stromal cell line, HAS303, which can support hematopoietic stem cell proliferation and differentiation in vitro. We used this culture system to examine the effects of SP. Expression of the mRNAs of neurokinin (NK)-1R, NK-2R and NK-3R, specific SP receptors, on HAS303 cells was demonstrated by the RT-PCR. CD34+ cells isolated from bone marrow were co-cultivated with HAS303 cells in the presence and absence of SP and the total hematopoietic cells and progenitors were counted every 5 days. Introducing SP (10(-8) M) to the co-cultures significantly increased the number of total cells and progenitors compared with control cultures. SP showed no enhancing activity on CD34+ cells cultured alone. SP also stimulated IL-3-dependent colony formation of whole bone marrow MNCs in a soft agar culture system, but showed no such activity on isolated CD34+ cells in this system. These observations suggest that SP stimulated HAS303 cells, activated HAS303 cells, and stimulated the proliferation and differentiation of CD34+ cells. Treating HAS303 cells with SP increased the intracellular Ca2+ concentration and stimulated production of G-CSF, GM-CSF, SCF and IL-6, but not IL-1alpha, IL-1beta and TNF-alpha, but did not enhance proliferation. All these findings suggest that SP mediates hematopoietic cell proliferation and differentiation in vitro by activating stromal cell function.

Effects of vesnarinone on the bone marrow stromal cell-dependent proliferation and differentiation of HL60 cells in vitro.

It has been reported that vesnarinone, a new inotropic agent used in the treatment of cardiac failure, causes agranulocytosis as a side effect. To study the mechanisms by which this complication occurs, vesnarinone was introduced into a coculture system of HL60 and bone marrow (BM) stromal cells, in which HL60 cells were able to differentiate into mature granulocytes with no inducible exogenous factors added to the culture. When HL60 cells were cocultured with the human BM-derived stromal cell line LP101, HL60 cells were induced to differentiate into mature granulocytes, and expression of the mature granulocyte-macrophage surface antigen, CD11b was increased. Conditioned medium (CM) obtained from LP101 cells also showed the capacity to induce the maturation of HL60 cells, in a dose- and time-dependent manner. The differentiation of HL60 cells induced by CM was also determined by morphological analysis, expression of myeloperoxidase, and a nitroblue tetrazolium (NBT) reduction test. When HL60 cells were cocultured with LP101 in the presence of vesnarinone, the CD11b expression was greatly suppressed. CM obtained from vesnarinone-treated LP101 (ves-CM) lost the capacity to induce the differentiation of HL60 cells, at a concentration of 1 microg/mL of vesnarinone. Vesnarinone itself did not affect the proliferation of HL60 cells. Furthermore, the addition of vesnarinone or ves-CM to HL60 cultures incubated with CM did not alter the induction of CD11b expression, suggesting that vesnarinone has no effect on HL60 cells, but that it inhibits stromal cells from producing soluble factor(s) required for the differentiation of HL60 cells to mature granulocytes. All these findings indicate that vesnarinone causes the hematopoietic disorder agranulocytosis, via impairment of stromal function.

Possible involvement of bone marrow stromal cells in agranulocytosis caused by vesnarinone treatment.

Vesnarinone, an oral therapeutic agent for cardiac failure, causes agranulocytosis as a side effect. To elucidate the mechanism of occurrence of the agranulocytosis, we examined the effect of vesnarinone on granulopoiesis using an in vitro human long-term bone marrow culture system. Addition of vesnarinone to the culture decreased the total number of hematopoietic cells, mainly composed of mature granulocytes and macrophages, but increased the number of granulocyte-macrophage progenitor cells (CFU-GM) and CD33-CD34+ cells as compared with an untreated control. Differentiation of CFU-GM was induced by removing the agent from the culture medium, indicating that the effect of vesnarinone was reversible. The agent did not directly affect CFU-GM in the presence of granulocyte-macrophage colony-stimulating factor (GM-CSF). Furthermore, treatment of stromal cells with vesnarinone repressed the production of G, GM, M-CSF, suggesting that the agent may cause a hematopoietic disorder, agranulocytosis, through the impairment of stromal cell function.

Hematopoietic supportive function of human bone marrow stromal cell lines established by a recombinant SV40-adenovirus vector.

We have previously reported the establishment of a variety of human bone marrow stromal cell lines using a recombinant SV40-adenovirus vector. Using this vector, we obtained more clonal stromal cells. Here, we have characterized these cells and analyzed their capacity to support the proliferation and differentiation of hematopoietic cells. The stromal cells were cocultured with nonadherent human bone marrow cells used as hematopoietic cells. The total numbers of hematopoietic cells and CFU-GM in culture were counted every week. Two of the six stromal cell lines, AA101 and HAS303, supported the proliferation and differentiation of hematopoietic cells and CFU-GM for more than 9 weeks. Further, granulocytes, macrophages, and megakaryocytes were detected when cocultured with these cells. When hematopoietic cells were cocultured but separated from the two stromal cell lines by a 0.45-microns millipore membrane to prevent their attachment, almost all CFU-GM disappeared within 7 weeks. The supportive stromal cells produced GM-CSF and IL-6. However, other cell lines producing these humoral factors did not support hematopoietic cell proliferation for such a long time. These findings suggest that these established human bone marrow stromal cell lines will be useful, in that analysis of their supportive function in hematopoietic cell proliferation and differentiation through cell-to-cell interaction will shed some light on this area.