Shohei Yamashita scite author profile

G proteins of the Ras family function as molecular switches in many signalling cascades; however, little is known about where they become activated in living cells. Here we use FRET (fluorescent resonance energy transfer)-based sensors to report on the spatio-temporal images of growth-factor-induced activation of Ras and Rap1. Epidermal growth factor activated Ras at the peripheral plasma membrane and Rap1 at the intracellular perinuclear region of COS-1 cells. In PC12 cells, nerve growth factor-induced activation of Ras was initiated at the plasma membrane and transmitted to the whole cell body. After three hours, high Ras activity was observed at the extending neurites. By using the FRAP (fluorescence recovery after photobleaching) technique, we found that Ras at the neurites turned over rapidly; therefore, the sustained Ras activity at neurites was due to high GTP/GDP exchange rate and/or low GTPase activity, but not to the retention of the active Ras. These observations may resolve long-standing questions as to how Ras and Rap1 induce different cellular responses and how the signals for differentiation and survival are distinguished by neuronal cells.

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Regulatory Proteins of R-Ras, TC21/R-Ras2, and M-Ras/R-Ras3

Ohba¹,

Mochizuki²,

Yamashita³

et al. 2000

Journal of Biological Chemistry

143

129

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We studied the regulation of three closely related members of Ras family G proteins, R-Ras, TC21 (also known as R-Ras2), and M-Ras (R-Ras3). Guanine nucleotide exchange of R-Ras and TC21 was promoted by RasGRF, C3G, CalDAG-GEFI, CalDAG-GEFII (RasGRP), and CalDAG-GEFIII both in 293T cells and in vitro. By contrast, guanine nucleotide exchange of M-Ras was promoted by the guanine nucleotide exchange factors (GEFs) for the classical Ras (Ha-, K-, and N-), including mSos, RasGRF, CalDAG-GEFII, and CalDAG-GEFIII. GTPase-activating proteins (GAPs) for Ras, Gap1 m , p120 GAP, and NF-1 stimulated all of the R-Ras, TC21, and M-Ras proteins, whereas R-Ras GAP stimulated R-Ras and TC21 but not M-Ras. We did not find any remarkable difference in the subcellular localization of R-Ras, TC21, or M-Ras when these were expressed with a green fluorescent protein tag in 293T cells and MDCK cells. In conclusion, TC21 and R-Ras were regulated by the same GEFs and GAPs, whereas M-Ras was regulated as the classical Ras.The Ras family of GTP-binding proteins consists of the classical Ras (Ha-, K-, and N-), R-Ras, Rap1, Rap2, Ral, Rheb, Rin, Rit, TC21/R-Ras2 (called TC21 hereafter), and M-Ras/R-Ras3 (M-Ras) (1). Compared with the classical Ras, which plays a pivotal role in cell growth and differentiation, less is known about the other members of this family. It is proposed that three proteins, including R-Ras, TC21, and M-Ras, make up a subfamily (2). It has also been noted, however, that M-Ras differs at the carboxyl terminus from both TC21 and R-Ras, which share a conserved amino acid motif designated the R-Ras box (3). Like the classic Ras proteins (Ha-, K-, and N-Ras), all proteins of the R-Ras subfamily transform NIH3T3 cells, albeit less efficiently than does the classic Ras (3-7). Consistent with its transforming activity, overexpression and mutation of TC21 have been reported in tumor tissues or cell lines (8 -10). Furthermore, TC21 and M-Ras inhibit differentiation of C2 skeletal muscle myoblasts, as does Ha-Ras (7, 11). These biological activities are, at least partially, due to the activation of the extracellular signal-regulated kinase/mitogen-activated protein kinase cascade by the R-Ras subfamily proteins. In support of this idea, it is reported that R-Ras subfamily proteins bind to Ras effectors and activate the extracellular signalregulated kinase/mitogen-activated protein kinase cascade (2,3,5,11,12). In contrast to these reports, however, it is also reported that the R-Ras subfamily does not bind to Raf (6,7,13) and that overexpression of R-Ras did not induce DNA synthesis of Swiss3T3 cells or the differentiation of PC12 cells (14).Apart from the similarity to Ras, R-Ras seems to have its unique functions. R-Ras inhibits apoptosis of BaF3 cells induced by cytokine deprivation (15) and stimulates cell adhesion by integrin (16). However, so far, no effector molecules for R-Ras have been reported to explain its specific function.Ras family G proteins cycle between GDP-bound inactive and GTP-bound active states. The GDP-b...

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CalDAG-GEFIII Activation of Ras, R-Ras, and Rap1

Yamashita¹,

Mochizuki²,

Ohba³

et al. 2000

Journal of Biological Chemistry

134

137

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We characterized a novel guanine nucleotide exchange factor (GEF) for Ras family G proteins that is highly homologous to CalDAG-GEFI, a GEF for Rap1 and R-Ras, and to RasGRP/CalDAG-GEFII, a GEF for Ras and R-Ras. This novel GEF, referred to as CalDAG-GEFIII, increased the GTP/GDP ratio of Ha-Ras, R-Ras, and Rap1 in 293T cells. CalDAG-GEFIII promoted the guanine nucleotide exchange of Ha-Ras, R-Ras, and Rap1 in vitro also, indicating that CalDAG-GEFIII exhibited the widest substrate specificity among the known GEFs for Ras family G proteins. Expression of CalDAG-GEFIII was detected in the glial cells of the brain and the glomerular mesangial cells of the kidney by in situ hybridization.

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Rap2 as a Slowly Responding Molecular Switch in the Rap1 Signaling Cascade

Ohba

Mochizuki

Matsuo

et al. 2000

Molecular and Cellular Biology

107

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Rap2 is a member of the Ras family of GTPases and exhibits 60% identity to Rap1, but the function and regulation of Rap2 remain obscure. We found that, unlike the other Ras family proteins, the GTP-bound active form exceeded 50% of total Rap2 protein in adherent cells. Guanine nucleotide exchange factors (GEFs) for Rap1, C3G, Epac (or cyclic AMP [cAMP]-GEF), CalDAG-GEFI, PDZ-GEF1, and GFR efficiently increased the level of GTP-Rap2 both in 293T cells and in vitro. GTPase-activating proteins (GAPs) for Rap1, rap1GAPII and SPA-1, stimulated Rap2 GTPase, but with low efficiency. The half-life of GTP-Rap2 was significantly longer than that of GTP-Rap1 in 293T cells, indicating that low sensitivity to GAPs caused a high GTP/GDP ratio on Rap2. Rap2 bound to the Ras-binding domain of Raf and inhibited Ras-dependent activation of Elk1 transcription factor, as did Rap1. The level of GTP-Rap2 in rat 3Y1 fibroblasts was decreased by the expression of v-Src, and expression of a GTPase-deficient Rap2 mutant inhibited v-Src-dependent transformation of 3Y1 cells. Altogether, Rap2 is regulated by a similar set of GEFs and GAPs as Rap1 and functions as a slowly responding molecular switch in the Rap1 signaling cascade.

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Effect of Honeycomb-Patterned Surface Topography on the Adhesion and Signal Transduction of Porcine Aortic Endothelial Cells

et al. 2007

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Surface topography has vital roles in cellular response. Here, to investigate the mechanism behind cellular response to surface topography, we prepared honeycomb (HC)-patterned films from poly(epsilon-caprolactone) (PCL) with micropatterned surface topography by casting a polymer solution of water-immiscible solvent under high humidity. We characterized the adsorption of fibronectin (Fn) on the film using atomic force microscopy (AFM) and confocal laser scanning microscopy (CLSM). The response of porcine aortic endothelial cells (PAECs) to adsorbed Fn molecules onto HC-patterned films was observed by immunofluorescence labeling of vinculin and the actin fiber of PAECs cultured for 1 and 72 h in serum-free medium. The expression of focal adhesion kinase autophosphorylated at the tyrosine residue (pFAK) at 1 h culture was determined using an immunoprecipitation method. Fn adsorbed selectively around the pore edges to form ring-shaped aggregates. The immunostaining results revealed that PAECs adhered to the HC-patterned films at focal contact points localized around pore peripheries. These points correspond to adsorption sites of Fn. The expression of pFAK after 1 h on the HC-patterned film was 3 times higher than that on a corresponding flat film, indicating that the signaling mediated by the binding between Fn and the integrin receptor was more highly activated on the HC-patterned film. These results suggest that the cellular response to HC-patterned films (e.g., adhesion pattern and phosphorylation of FAK) originates from the regularly aligned adsorption pattern of Fn determined by the pore structure of the film.

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