Identification of transforming growth factor-beta1-binding protein overexpression in carmustine-resistant glioma cells by MRNA differential display.

BACKGROUND: The authors previously demonstrated the presence of cells in primary human malignant gliomas that intrinsically are resistant to carmustine (BCNU). Numerous studies have identified mechanisms of therapy resistance in these cells; however, the authors' work and that of others suggest that additional mechanisms of resistance exist. METHODS: The authors identified a glioma cell line that lacks detectable methylguanine methyltransferase expression and does not alter its expression of glutathione-S-transferase-pi in response to BCNU chemotherapy. This cell line was used in mRNA differential display experiments to identify genes involved in what to the authors' knowledge were previously undescribed mechanisms of resistance. RESULTS: The overexpression of the gene encoding the transforming growth factor latency binding protein was demonstrated in glioma cells selected for resistance to BCNU, compared with their parental unselected cells. CONCLUSIONS: Transforming growth factor-beta1 has pleiotropic functions in transformed and normal cells. Although activation of TGF-beta1 does not appear to be a causative factor in BCNU resistance in the current study, it may be involved in the growth of these resistant cells.

Nuclear accumulation of FGF-2 is associated with proliferation of human astrocytes and glioma cells.

FGF-2 has been implicated in the neoplastic transformation of glioma cells and in the transition of normal quiescent astrocytes to a proliferating, reactive state. In the present study we have observed that in human glial cells, levels and subcellular localization of FGF-2 are different in quiescent and proliferating cells. FGF-2 was detected in the cytoplasm of non-reactive astrocytes in human brain sections. In contrast FGF-2 was located within the cytoplasm and nuclei of reactive astrocytes in gliotic brain tissue and in neoplastic cells of glioma tumors. In vitro, FGF-2 was found predominantly in the nucleus of subconfluent proliferating astrocytes, but was detected only in the cytoplasm of density arrested quiescent astrocytes. Our results suggest that reduced cell contact stimulates nuclear accumulation of FGF-2, accompanying mitotic activation of reactive human astrocytes. FGF-2 was constitutively localized to the nucleus of continuously proliferating glioma cells independent of cell density. A role for intracellular FGF-2 was further suggested by the observation that glioma cells that are not stimulated to proliferate by extracellular FGF-2 proliferated faster when transfected with FGF-2 expressing vectors. This increased proliferation correlated with nuclear accumulation of FGF-2. Cell proliferation was attenuated by 5'-deoxy-5'-methylthioadenosine, a FGF-2 receptor tyrosine kinase inhibitor that acts within the cell, but was unaffected by myo-inositol hexakis [dihydrogen phosphate] that disrupts FGF-2 binding to plasma membrane receptors. Our results indicate that FGF-2 serves as a nuclear regulator of proliferation in astrocytic cells. In glioma cells, the constitutive presence of FGF-2 in the nucleus may promote proliferation that is insensitive to cell contact inhibition.