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Query: KEGG:D02003 (
NBT
)
1,323
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The
NBT
-II rat carcinoma cell line exhibits two mutually exclusive responses to FGF-1 and
EGF
, entering mitosis at cell confluency while undergoing an epithelium-to-mesenchyme transition (EMT) when cultured at subconfluency. EMT is characterized by acquisition of cell motility, modifications of cell morphology, and cell dissociation correlating with the loss of desmosomes from cellular cortex. The pleiotropic effects of
EGF
and FGF-1 on
NBT
-II cells suggest that multiple signaling pathways may be activated. We demonstrate here that growth factor activation is linked to at least two intracellular signaling pathways. One pathway leading to EMT involves an early and sustained stimulation of pp60c-src kinase activity, which is not observed during the growth factor-induced entry into the cell cycle. Overexpression of normal c-src causes a subpopulation of cells to undergo spontaneous EMT and sensitizes the rest of the population to the scattering activity of
EGF
and FGF-1 without affecting their mitogenic responsiveness. Addition of cholera toxin, a cAMP-elevating agent, severely perturbs growth factor induction of EMT without altering pp60c-src activation, therefore demonstrating that cAMP blockade takes place downstream or independently of pp60c-src. On the other hand, overexpression of a mutated, constitutively activated form of pp60c-src does not block cell dispersion while strongly inhibiting growth factor-induced entry into cell division. Moreover, stable transfection of a dominant negative mutant of c-src inhibits the scattering response without affecting mitogenesis induced by the growth factors. Altogether, these results suggest a role for pp60c-src in epithelial cell scattering and indicate that pp60c-src might contribute unequally to the two separate biological activities engendered by a single signal.
...
PMID:pp60c-src is a positive regulator of growth factor-induced cell scattering in a rat bladder carcinoma cell line. 759 95
Various mechanisms of epithelial cell plasticity in morphogenesis have been studied at the genetic and molecular levels. Several control genes have been identified including genes encoding transcription factors and growth factor receptors. These mechanisms may be reactivated during the progression of carcinomas. One of the mechanisms underlying epithelial plasticity is the epithelial-mesenchymal transition. This process has been extensively studied using the
NBT
-II bladder carcinoma cell line. Cells of this line undergo a reversible transition following exposure to several growth factors including FGF-1,
EGF
, TGFalpha and SF/HGF, which activate tyrosine kinase surface receptors. Two separate transduction pathways have been identified. The transient activation of c-Src is involved in cytoskeleton remodeling whereas the Ras pathway controls the transcription of genes such as the transcription factor Slug which is involved in the internalization of desmosomes. These two pathways cooperate to induce the morphological transition, scattering and locomotion of fibroblast-like cells. Growth/scatter factor-producing
NBT
-II cells are more invasive than cells that do not contain this factor, in orthotopic confrontation assay. In vivo, these cells are very tumorigenic and may confer a more malignant phenotype on parental cells via a community effect. The role of several growth factors and their receptors has been investigated in human bladder carcinomas. A subset of these tumors with poor outcomes produce low levels of FGFR2-IIIb. The synthesis of this receptor de novo in bladder cell lines reduces proliferation in vitro and tumor growth in nude mice. FGFR2-IIIb functions as a tumor suppressor, consistent with the differentiation-inducing capacities of FGF receptors in the suprabasal cells of the skin. FGFR2-IIIb signaling may be involved in the maintenance of E-cadherin, the prototype epithelial adhesion molecule, which is only downregulated in a fraction of tumors with low FGFR2-IIIb synthesis. Human bladder tumors may also activate autocrine loops such as that for EGFR and their ligands, as already demonstrated for murine bladder tumors. Therefore, our results suggest that multifunctional growth factors and their receptors are involved in cell proliferation and epithelial cell plasticity, acting either as positive or negative regulators of tumor progression. The effect on the morphological transition is also clearly relevant to the mechanism governing dissemination and the formation of micrometastatic tumor cells. The extrapolation of these discoveries to human carcinomas should provide markers facilitating the more accurate prediction of the biological behavior of a given tumor and identify clinically and pathologically significant parameters. The identification of critical changes in the growth factor pathways involved in tumor progression will not only provide insight into the genetic and molecular basis of this process, but should also identify targets for new therapies.
...
PMID:Epithelial cell plasticity in development and tumor progression. 1050 44
Cell dissociation and cell migration are the two main components of epithelium-mesenchyme transitions (EMT). We previously demonstrated that Ras is required for the accomplishment of both of these processes during the
EGF
-induced EMT of the
NBT
-II rat carcinoma cell line in vitro. In this study, we examined the downstream targets of Ras that are responsible for the dissociation and motility of
NBT
-II cells. Overexpression of activated forms of c-Raf and MEK1 (a component of the mitogen-activated protein kinase pathway, MAPK) led to cell dissociation, as inferred by the loss of desmosomes from the cell periphery. By contrast, active PI3K, RalA and RalB did not induce desmosome breakdown. The MEK1 inhibitor PD098059 inhibited
EGF
- and Ras-induced cell dispersion, whereas the PI3K inhibitor LY294002 had no effect. Accordingly, among the partial loss-of-function mutants of Ras (RasV12) that were used to distinguish between downstream targets of Ras, we found that the Raf-specific Ras mutants RasV12S35 and RasV12E38 induced cell dissociation. The PI3K- and RalGDS-activating Ras mutants had, in contrast, no effect on cell dispersion. However, MEK1 was unable to promote cell motility, whereas RasV12S35 and RasV12E38 induced cell migration, suggesting that another Ras effector was responsible for cell motility. We found that the small GTPase Rac is necessary for
EGF
-mediated cell dispersion since overexpression of a dominant-negative mutant of Rac1 (Rac1N17) inhibited
EGF
-induced
NBT
-II cell migration. All stimuli that promoted cell migration also induced Rac activation. Finally, coexpression of active Rac1 and active MEK1 induced the motility of
NBT
-II cells, suggesting that Ras mediates
NBT
-II cell scattering through the coordinate activation of Rac and the Raf/MAPK pathway.
...
PMID:Ras induces NBT-II epithelial cell scattering through the coordinate activities of Rac and MAPK pathways. 1204 29
Focal contacts, large macromolecular complexes that link the extracellular matrix and the internal cell cytoskeleton, are thought to govern cell locomotion. However, the maturation process through which focal contacts control the cellular migratory machinery by changes in size and molecular composition remain unclear. Here, we fabricated cell growth substrates that contained linear ECM strips of micron- or submicron-width in order to limit the enlargement of focal contacts. We found that
NBT
-II cells plated on the submicron substrate possessed smaller focal complexes that exhibited a highly dynamic turnover. These cells possessed various leading edges at multiple sites of the cell periphery, which prevented the cell from advancing. In contrast, cells grown on the micron-width substrate possessed large and stable focal adhesions. Most of these cells were elongated bipolar cells that were tethered at both ends and were immobile. Further,
EGF
and ROCK signaling pathways can modulate the cellular migratory responses according to the substrate guidance. On the submicron-width substrate,
EGF
treatment increased the focal contact size and the contractile force, causing these cells to develop one leading edge and migrate along the submicron-sized ECM paths. In contrast, inhibition of ROCK signaling decreased the focal contact size for cells plated on the micron substrate. These cells became less tethered and were able to migrate along or even across the micron-sized ECM paths. Our results indicate that formation and maturation of focal contacts is controlled by both ECM cues and intracellular signaling and they play a central role in directed cell motion.
...
PMID:NBT-II cell locomotion is modulated by restricting the size of focal contacts and is improved through EGF and ROCK signaling. 2474 31
