A stromal protein, designated restrictin-P, that specifically kills plasma-like cells was purified to homogeneity and shown to be identical with activin A. The specificity to plasma-like cells stemmed from the ability of restrictin-P/activin A to competitively antagonize the proliferation-inducing effects of interleukin (IL) 6 and IL-11. Restrictin-P further interfered with the IL-6-induced secretion of acute phase proteins by HepG2 human hepatoma cells and with the IL-6-mediated differentiation of M1 myeloblasts. A competition binding assay indicated that restrictin-P did not interfere with the binding of IL-6 to its receptor on plasma-like cells, suggesting that it may act by intervening in the signal transduction pathway of the growth factor. Indeed, concomitant addition of restrictin-P and IL-6 to cytokinedeprived B9 hybridoma cells was followed by sustained overexpression of junB gene until cell death occurred, while IL-6 alone caused a transient increase only. This altered response to IL-6 stimulation was accompanied by a moderate increase in STAT protein activation. Thus, in this study, we identified the plasmacytoma growth inhibitor, restrictin-P, as being activin A of stromal origin. It is shown that activin A is an antagonist of IL-6-induced functions and that it modifies the IL-6 signaling pattern.
We have recently found that the inhibitor of plasmacytoma cell growth, restrictin-P, is a stroma derived activin A and that it is an antagonist of interleukin-6 and interleukin-11. The present study was aimed at determining the mode by which this cytokine kills its target cells. On addition of the cytokine there was little or no net increase in cell number, depending on the specific target cells. All plasmacytoma cell lines tested exhibited a similar time dependent inhibition of DNA synthesis and a G0/G1 shift in the cell cycle. Electron microscope examination revealed classical apoptotic features i.e. chromatin condensation and membrane blebbing. DNA fragmentation, measured qualitatively and quantitatively, occurred in all cytokine treated plasmacytoma cell lines. Bovine activin A had an identical capacity to reduce cell viability, to induce G0/G1 shift and to cause DNA fragmentation. X-ray microanalysis of intracellular ions revealed an increase in calcium ions, following exposure of plasmacytoma cells to restrictin-P, accompanied by a decrease in phosphor ions. The cytotoxicity of the inhibitor was augmented in an additive manner by cycloheximide (CHX) indicating that the process did not require de novo protein synthesis. This study thus shows that restrictin-P/stromal activin A kills its target cells by inducing apoptosis. This effect was mediated by subnanogram concentrations and therefore may represent one physiological function of this pleiotropic cytokine.
The mesenchymal stroma has been shown to play a crucial role in the development of multiple myeloma, partly by secretion of interleukin (IL)-6, that serves as a growth factor for myeloma cells. However, it is still unclear which other stromal molecules are involved in the pathogenesis of this disease. We chose, as a model system, a mouse plasmacytoma cell line, which does not respond to IL-6. We found that the formation of mouse plasmacytoma tumors, in an in vivo skin transplantation model, is facilitated by co-injection of these tumor cells along with a mesenchymal stromal cell. The tumor promoting effect of the stroma was reproduced in an in vitro model; stromal cells induced the proliferation of plasmacytoma cells under serumfree conditions. This growth promotion could not be mimicked by a series of cytokines including IL-6 and insulin-like growth factor (IGF)-I implying a role for yet unidentified stromal factors. The in vivo formation of plasmacytoma tumors was reduced following administration of activin A, a cytokine member of the transforming growth factor (TGF) superfamily. Furthermore, the in vitro growth promoting effect of the stroma was abrogated by basic fibroblast growth factor (bFGF) which induced a higher stromal expression of activin A. Our results thus show that mesenchymal stroma expresses plasmacytoma growth stimulating activities that overcome the low constitutive level of the plasmacytoma inhibitor, activin A. The expression of activin A is upregulated by bFGF rendering the stroma suppressive for plasmacytoma growth. The balance between the expression of these regulators may contribute to mesenchymal stroma activity and influence the progression of multiple myeloma. Leukemia (2001) 15, 1102-1110.
Stromal cells of bone marrow origin produce a variety of known cytokines and some factors exhibiting apparently new biological activities. Several of these were identified by the study of cell to cell interactions and were not found in detectable amounts in media conditioned by the cells. We describe here a culture system that enables the release of stromal cytokines into medium free of any added proteins and supplemented with peptides from casein hydrolysate (0.1%). The absence of serum proteins allows extensive concentration and monitoring of activities that are otherwise undetectable. Stromal cells of the MBA-2.1 clonal cell line were seeded in a stationary bed reactor packed with a carrier of non-woven fabric matrix. After a proliferation phase with serum containing medium, the cells were maintained for over 10 months in protein-free medium. Throughout this extended incubation in the absence of serum or serum replacing proteins, stromal cells retained their viability and continuously released transforming growth factor-beta (TGF-beta), macrophage-colony stimulating factor (M-CSF) and restrictin-P, a cytotoxic factor that specifically arrested the growth of plasmacytoma cells. In addition, interleukin-6 (IL-6) was first undetectable, and later in culture its titer reached a maximum of 180,000 international units (IU)/ml. Concomitantly, the production of restrictin-P diminished and reached its lowest levels at the end of 10 months. The results may imply a possible causal relationship between the expression of IL-6 and restrictin-P, since no similarly significant changes were observed in the titers of M-CSF and TGF-beta. This novel bioreactor system may be adaptable for efficient production of different cytokines under absolute serum-free conditions.
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