Hormones and growth factors regulate cell growth via the mitogen-activated protein (MAP) kinase cascade. Here we examine the actions of the hormone somatostatin on the MAP kinase cascade through one of its two major receptor subtypes, the somatostatin receptor 1 (SSTR1) stably expressed in CHO-K1 cells. Somatostatin antagonizes the proliferative effects of fibroblast growth factor in CHO-SSTR1 cells via the SSTR1 receptor. However, in these cells, somatostatin robustly activates MAP kinase (also called extracellular signal regulated kinase; ERK) and augments fibroblast growth factor-stimulated ERK activity. We show that the activation of ERK via SSTR1 is pertussis toxin sensitive and requires the small G protein Ras, phosphatidylinositol 3-kinase, the serine/threonine kinase Raf-1, and the protein tyrosine phosphatase SHP-2. The activation of ERK by SSTR1 increased the expression of the cyclin-dependent protein kinase inhibitor p21(cip1/WAF1). Previous studies have suggested that somatostatin-stimulated protein tyrosine phosphatase activity mediates the growth effects of somatostatin. Our data suggest that SHP-2 stimulation by SSTR1 may mediate some of these effects through the activation of the MAP kinase cascade and the expression of p21(cip1/WAF1).
Somatostatin and its analogs are active in the inhibition of SST receptor-positive endocrine neoplasms, but their activity and mechanism in nonendocrine tumors is not clear. Somatostatin potently inhibited growth of a Kaposi's sarcoma xenograft in nude mice, yet in vitro the tumor cells did not express any known somatostatin receptors and were not growth inhibited by somatostatin. Histological examination revealed limited vascularization in the somatostatin-treated tumors as compared with the controls. Somatostatin was a potent inhibitor of angiogenesis in an in vivo assay. In vitro, somatostatin inhibited endothelial cell growth and invasion. Migration of monocytes, important mediators of the angiogenic cascade, was also inhibited by somatostatin. Both cells types expressed somatostatin receptor mRNAs. These data demonstrate that somatostatin is a potent antitumor angiogenesis compound directly affecting both endothelial and monocytic cells. The debated function of somatostatin in tumor treatment and the design of therapeutic protocols should be reexamined considering these data.
Chemokines are a family of proteins that chemoattract and activate cells by interacting with specific receptors on the surface of their targets. They are grouped into four classes based on the position of key cysteine residues: C, CC, CXC, and CX3C. Stromal cell-derived factor 1 (SDF1), the ligand of the CXCR4 receptor, is a CXC chemokine involved in chemotaxis and brain development that also acts as coreceptor for HIV-1 infection. It has been proposed that CXCR4 is overexpressed and required for proliferation in human brain tumor cells. We previously demonstrated that CXCR4 and SDF1 are expressed in culture of cortical type I rat astrocytes, cortical neurons, and cerebellar granule cells. In this study, we analyzed the expression of CXCR4 and SDF1 in four human brain tumor tissues, showing that CXCR4 is expressed in all tumors analyzed, whereas SDF1 is expressed only in two tumor tissues. We also investigated the possible functions of CXCR4 expressed in rat type I cortical astrocytes, demonstrating that SDF1alpha stimulates the proliferation of these cells in vitro. Moreover, we studied by western blot the intracellular pathway involved in cell proliferation, demonstrating that SDF1alpha induces the ERK1/2 phosphorylation that is reduced by the PD98059 compound, an MEK inhibitor.
In this study, we report the effects of somatostatin on the proliferation of PC C13 thyroid cell line and the intracellular mechanisms involved. We also evaluated the possible alterations, induced by E1A oncogene transformation on the intracellular pathways mediating somatostatin inhibition of cell proliferation. We showed that somatostatin was able to powerfully inhibit insulin- and insulin + TSH-dependent cell proliferation by inducing a block in the G1/S progression in the cell cycle. These cytostatic effects were completely reverted by vanadate, suggesting that somatostatin may induce antiproliferative effects through the modulation of phosphotyrosine phosphatases. In the E1A-transformed cell line, somatostatin was completely ineffective. The lack of somatostatin inhibitory effects on cell proliferation were not due to alterations in the expression of somatostatin receptors, which were regularly expressed and coupled to adenylyl cyclase activity, but were dependent on an alteration in their coupling with the phosphotyrosine phosphatase. In fact, although in PC C13 cells somatostatin increased by 100% phosphotyrosine phosphatase activity, it was completely ineffective in E1A-expressing cells. In conclusion we demonstrated that somatostatin activates phosphotyrosine phosphatases in PC C13 thyroid cells to inhibit cell proliferation and that the stable expression of E1A oncogene in these cells completely abolishes this antiproliferative effect.
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