Neutralizing monoclonal antibody against ras oncogene product p21 which impairs guanine nucleotide exchange.

The neutralizing monoclonal antibody Y13-259 severely hampers the nucleotide exchange reaction between p21-bound and exogenous guanine nucleotides but does not interfere with the association of GDP to p21. These results suggest that the nucleotide exchange reaction is critical for p21 function. Interestingly, the v-ras p21 has a much faster dissociation rate than the p21 of the c-ras proto-oncogene.     

Microinjection of ras p21 induces a rapid rise in intracellular pH.

Quiescent mouse NIH 3T3 cells responded to microinjection of activated ras p21 with a rapid and sustained rise in intracellular pH (approximately 0.17 pH units). The p21-induced pH change was inhibited by amiloride treatment or growth of cells in medium low in sodium, suggesting a role for the Na+/H+ antiporter. Amiloride was found to suppress p21-induced mitosis, also.     

Tissue distribution of smg p25A, a ras p21-like GTP-binding protein, studied by use of a specific monoclonal antibody

We made a monoclonal antibody specifically recognizing smg p25A among many ras p21-like GTP-binding proteins and investigated the tissue distribution of smg p25A by use of this antibody. By immunoblot analysis, smg p25A was detected in rat brain and bovine adrenal medulla but not in bovine adrenal cortex or other rat tissues including thymus, spleen, lung, heart, liver and kidney. However, by immunocytochemical studies, smg p25A was detected not only in the synaptic areas of rat brain and the chromaffin cells of bovine adrenal medulla but also in the endocrine cells of rat pancreatic islets, the acinar cells of rat exocrine pancreas and the exocrine cells of rat submaxillary gland. These results suggest that smg p25A is involved in the regulation of secretory processes not only in synapses but also in other endocrine and exocrine secretory cells.     

Plasma membrane-targeted ras GTPase-activating protein is a potent suppressor of p21ras function.

Although p21ras is localized to the plasma membrane, proteins it interacts with, such as the GTPase-activating proteins (GAPs) ras GAP and neurofibromin (NF1), are not, suggesting that one function of p21ras GTP may be to target such proteins to the plasma membrane. To investigate the effects of targeting ras GAP to the plasma membrane, ras C-terminal motifs sufficient for plasma membrane localization of p21ras were cloned onto the C terminus of ras GAP. Plasma membrane-targeted ras GAP is growth inhibitory to NIH 3T3 fibroblasts and COS cells. This growth inhibition correlates with GAP catalytic activity, since the plasma membrane-targeted C-terminal catalytic domain or the GAP-related domain of neurofibromin is inhibitory, whereas the similarly targeted N-terminal domain is not. Moreover, the inhibition is abrogated by the inactivating mutation L902I, which abolishes ras GAP catalytic activity. Coexpression of oncogenic mutant ras rescues cell viability, but the majority of rescued colonies are phenotypically untransformed. Furthermore, in focus assays, targeted ras GAP suppresses transformation by oncogenic mutant ras, and in reversion assays, targeted ras GAP can revert cells transformed by oncogenic mutant ras. Neither the targeted or nontargeted N-terminal domain nor the L902I mutant of ras GAP has any transforming activity. These data demonstrate that ras GAP can function as a negative regulator of ras and that plasma membrane localization potentiates this activity. However, if ras GAP is involved in the effector functions of p21ras, it can only be part of the effector complex for cell transformation.     

Insulin induction of Xenopus laevis oocyte maturation is inhibited by monoclonal antibody against p21 ras proteins.

Microinjection of transforming p21 ras protein induces maturation of Xenopus laevis oocytes, and the induction is blocked by coinjection of monoclonal antibody (Y13-259) against p21 ras proteins. Similar to other inducing agents, the effect of p21 ras protein is mediated via the appearance of maturation or meiosis-promoting factor activity. In addition, the neutralizing antibody markedly reduces oocyte maturation after insulin induction, whereas it fails to inhibit progesterone induction. Our results suggest that insulin induces maturation of oocytes via a different pathway than that of steroidal agents. The induction by insulin is ras dependent, and the action of ras may be directed at the steps before meiosis-promoting factor autocatalytic activation. These results suggest a role of p21 ras protein in the events associated with amphibian oocyte maturation.     

Detection of the intracellular ras p21 oncogene product by flow cytometry

Rapid identification of the expression of oncogene products in specific cell types could potentially be useful in the diagnosis and treatment of human malignancy. We have now observed that through the use of lysolecithin permeabilization and fluorescence-activated flow cytometry, cells expressing high levels of the v-Ha-ras oncogene product, p21, can readily be distinguished from the nontransformed parent cells in a rapid and quantitative manner.     

Regulation of p21ras activity.

The ras genes encode GTP/GDP-binding proteins that participate in mediating mitogenic signals from membrane tyrosine kinases to downstream targets. The activity of p21ras is determined by the concentration of GTP-p21ras, which is tightly regulated by a complex array of positive and negative control mechanisms. GAP and NF1 can negatively regulate p21ras activity by stimulating hydrolysis of GTP bound to p21ras. Other cellular factors can positively regulate p21ras by stimulating GDP/GTP exchange.     

Amplified expression of p21 ras protein in hormone-dependent mammary carcinomas of humans and rodents

Western blotting analysis was utilized to determine the amount of a ras oncogene product, p21 present in mammary carcinomas of humans and rats. The levels of p21 in hormone-dependent rat tumors was about 7-fold that of hormone-independent tumors. The majority of human breast carcinomas examined had high p21 levels, about 10-fold that of the normal breast tissue; 70% of these tumors were estrogen and progesterone receptor positive. p21 levels in the remaining tumors were 3-fold that of the normal breast tissue, regardless of the receptor status. Fibroadenomas and fibrocystic disease showed p21 levels similar to that of the normal mammary glands. Moreover, the high p21 levels in the mammary carcinomas correlated directly with high GTPase activity, as revealed by the photo-incorporation of 8-N3-[gamma-32P]GTP into the tumor lysates. The results suggest that hormone-dependency of mammary carcinomas may correlate with quantitative change in 'normal' p21 protein.     

An affinity labeling of ras p21 protein and its use in the identification of ras p21 in cellular and tissue extracts

We have carried out photoaffinity labeling of the ras p21 protein, a ras oncogene product, with [alpha-32P]GTP. Based on our studies, a sensitive, rapid, and specific assay for the detection of multiple forms of ras p21 has been developed. The specificity of this protocol is shown by (a) sensitivity of affinity labeling of ras p21 to known inhibitors of GTP binding and (b) immunoprecipitation of affinity labeled protein with anti-ras p21 serum. Detection and semiquantitation of ras p21 by this method is accomplished in less than 24 h and requires as little as 100,000 cells or about 5 mg of tissue sample from skin tumor, liver, and mammary tumor tissues. Furthermore, using this approach, we were able to detect the selective loss of one species of ras p21 in transplanted Morris hepatoma cells.     

Antisense inhibition of ras p21 expression that is sensitive to a point mutation

Many genetic disorders result from a single point mutation, and many tumor oncogenes have been found to be altered by a point mutation. The ability to inhibit selectively the expression of the mutated form of a protein without affecting its normal counterpart is central to many therapeutic strategies, since the normal protein may serve indispensable functions. Antisense oligonucleoside methylphosphonates and their psoralen derivatives directed at either normal human Ha-ras p21 or ras p21 that is mutated at a single base in codon 61 have been examined for their efficacy and specificity as inhibitors of p21 expression. Mixed cultures of cells expressing both forms of p21 were treated with the antisense oligomer complementary to the normal p21 or with the antisense oligomer complementary to the point-mutated p21. Each of the antisense oligomers specifically inhibited expression of only the form of ras p21 to which it was completely complementary and left the other form of p21 virtually unaffected.     

Interaction between the p21ras GTPase activating protein and the insulin receptor.

We investigated the involvement of the p21ras-GTPase activating protein (GAP) in insulin-induced signal transduction. In cells overexpressing the insulin receptor, we did not observe association between GAP and the insulin receptor after insulin treatment nor the phosphorylation of GAP on tyrosine residues. However, after insulin treatment in the presence of the phosphotyrosine phosphatase inhibitor phenylarsine oxide (PAO), 5-10% of GAP was found to be associated with the insulin receptor, and, in addition, a fraction of total GAP was phosphorylated on tyrosine. Using in vitro binding we showed that the N-terminal part of GAP containing the src-homology domains 2 and 3 (SH2-SH3-SH2 region) is involved in binding to the autophosphorylated insulin receptor beta-chain. In vitro binding between GAP and the autophosphorylated insulin receptor occurred independently of PAO pretreatment. These results suggest that GAP can transiently interact with the insulin receptor after insulin treatment, and this interaction is arrested after PAO pretreatment.     

Activation of intracellular kinases in Xenopus oocytes by p21ras and phospholipases: a comparative study.

Signal transduction induced by generations of second messengers from membrane phospholipids is a major regulatory mechanism in the control of cell proliferation. Indeed, oncogenic p21ras alters the intracellular levels of phospholipid metabolites in both mammalian cells and Xenopus oocytes. However, it is still controversial whether this alteration it is biologically significant. We have analyzed the ras-induced signal transduction pathway in Xenopus oocytes and have correlated its mechanism of activation with that of the three most relevant phospholipases (PLs). After microinjection, ras-p21 induces a rapid PLD activation followed by a late PLA2 activation. By contrast, phosphatidylcholine-specific PLC was not activated under similar conditions. When each of these PLs was studied for its ability to activate intracellular signalling kinases, all of them were found to activate maturation-promoting factor efficiently. However, only PLD was able to activate MAP kinase and S6 kinase II, a similar pattern to that induced by p21ras proteins. Thus, the comparison of activated enzymes after microinjection of p21ras or PLs indicated that only PLD microinjection mimetized p21ras signalling. Finally, inhibition of the endogenous PLD activity by neomycin substantially reduced the biological activity of p21ras. All these results suggest that PLD activation may constitute a relevant step in ras-induced germinal vesicle breakdown in Xenopus oocytes.     

Insulin stimulation of gene expression mediated by p21ras activation.

In fibroblasts, insulin is a weak mitogen and does not induce expression of c-fos, c-jun or p33. However, increasing the expression levels of either normal p21Hras or the insulin receptor, but not mutant p21Hras, enables insulin to induce the expression of these genes. In cells expressing elevated levels of insulin receptor, this process involves a rapid increase in p21rasGTP levels (from 20% to 70% GTP as a percentage of total guanine nucleotides). No increase in p21rasGTP levels was observed after PDGF and EGF stimulation of cells expressing high levels of the cognate receptor, stressing the specificity of the insulin-induced increase. We conclude that in fibroblasts, p21ras is an intermediate of the insulin signal transduction pathway involved in the regulation of gene expression and mitogenicity.     

Immunocytochemical localization of ras p21 product in thyroid follicular cells of normal rats using monoclonal antibody RAP-5

Summary The ultrastructural localization ofras p21 product was studied immunocytochemically in thyroid follicular cells of normal rats using pre-embedded peroxidase-labelled antibody techniques and a monoclonal antibody, RAP-5, which had been raised against a synthetic peptide corresponding to amino acid positions 10–17 of theras p21 protein. Theras p21 product was detected in cisternae of rough endoplasmic reticulum, Golgi apparatus and the subapical portion of apical plasma membrane, in which it was most concentrated. This study indicated that the p21 product may be synthesized in the rough endoplasmic reticulum and finally localized at the subapical portion of the thyroid follicular cells, and also that the apical plasma membrane may be a major site for the reception of environmental stimuli.     

Cytological effects of the microinjection of antibody to ras p21 in early cleavage Xenopus embryos

The presence of two ras-related proteins (22 and 23 kDa) was demonstrated in Xenopus embryonic extracts by selective immunoprecipitation using anti-ras monoclonal antibodies 142-24E05 and Y13-259. We further describe the cytological effects of the microinjection of anti-ras monoclonal antibody Y13-259 into early cleavage blastomeres of Xenopus embryos. Injection of the antibody into a blastomere at the two-, four-, or eight-cell stage caused cleavage arrest in the descendants of the injected blastomere. Light microscopy (LM) of cleavage-arrested cells revealed extensive deformation of the cells as well as heterogeneity of distribution of yolk platelets and pigment granules. LM analysis of serial sections of cleavage-arrested cells revealed the presence of multiple nuclei. Although the nuclei expressed similar morphological properties, indicating that they were probably in the same stage of the nuclear cycle, they revealed highly variable chromatin densities. Electron microscope (EM) analysis of the cytoplasm of cleavage-arrested cells revealed the accumulation of vesicles and large membranous elements coincident with cleavage arrest. Furthermore, endoplasmic reticulum (ER) existed in two forms, as closed, circular profiles and as long, linear arrays. Mitochondria were characteristically aligned in single file on both sides of the two types of ER cisternae. EM analysis of nuclei confirmed variations in chromatin organization and suggested the occurrence of unique nuclear envelope fusion among micronuclei in cleavage-arrested cells. Cleavage arrest and changes in cytological features were not observed in the cytoplasm of cells microinjected with normal rat IgG. Thus the immunochemical data and microinjection experiments suggest that ras-like or ras antigenicity exists within rapidly replicating Xenopus blastomeres and may be involved in the organization of a number of its cytoplasmic elements.     

Agonist-induced association of the p21ras GTPase-activating protein with phosphatidylinositol 3-kinase.

The signal transduction properties of the 21-kDa GTP-binding proteins, encoded by the ras genes, are only partly known. In a recent report, we demonstrated that the signaling pathway of p21ras, like that of several growth factors, is closely associated with phosphatidylinositol 3-kinase (PtdIns 3-kinase) activity. We showed that insulin-like growth factor-1 (IGF-1) and insulin increased the phosphatidylinositol 3-kinase activity in immunoprecipitates obtained with anti-phosphotyrosine and anti-ras antibodies in Ha-ras-transformed epithelial cells. Several findings in this previous study suggested that an additional protein was likely to be associated with the PtdIns 3-kinase. The suggestion that p21ras GTPase-activating protein (GAP) acts not only as a regulator of p21ras activity but also as a direct downstream target in the signaling pathway of p21ras led us to investigate the possible association of PtdIns 3-kinase with GAP. The stimulation of Ha-ras-transformed epithelial cells with IGF-1 caused an increased association of PtdIns 3-kinase activity with GAP, as seen by immunoprecipitation with anti-p21ras and anti-GAP antibodies. The 85-kDa regulatory subunit of PtdIns 3-kinase was present in immunoprecipitates obtained with antibodies against GAP and p21ras of IGF-1 stimulated cells. These data suggest that GAP acts as a downstream target for p21ras via its association with PtdIns 3-kinase.     

Effector domain mutations dissociate p21ras effector function and GTPase-activating protein interaction.

The GTPase activity of p21ras is stimulated by GTPase-activating proteins (GAPs) such as p120GAP and the product of the neurofibromatosis 1 gene, which may negatively regulate p21 function. GAPs are also proposed effectors of ras. We have sought activating substitutions in c-H-ras in the region encoding the effector domain, on the rationale that such mutations would dissociate effector function from negative regulation by GAP. One such activating mutation, Pro-34-->Arg, encodes protein that is substantially bound to GTP in vivo. In vitro, this protein is not stimulated by GAPs, and its binding to p120GAP is grossly impaired. The results support the idea that the p21 structural requirements for effector function and GAP interaction are quite different and suggest that some molecule(s) other than p120GAP serves as the ras effector. In contrast to the results obtained with p120GAP, the Pro-34-->Arg p21 species is effectively coupled to the raf-1 product, as judged from electrophoretic mobility shifts of the Raf-1 phosphoprotein.     

Role of the C-terminal region of smg p21, a ras p21-like small GTP-binding protein, in membrane and smg p21 GDP/GTP exchange protein interactions

Limited proteolysis with trypsin of smg p21B, a ras p21-like small GTP-binding protein having the same putative effector domain as ras p21s, produced the N-terminal fragment and the C-terminal tail of Lys-Lys-Ser-Ser-geranylgeranyl-Cys methyl ester. The Mr values of the intact smg p21B, the N-terminal fragment, and the C-terminal tail were estimated to be about 22,000, 20,500, and less than 1,000, respectively, by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Both the GDP- and GTP-bound forms of the intact smg p21B bound to various membranes and phosphatidylserine-linked Affi-Gel. However, both the GDP- and GTP-bound forms of the N-terminal fragment failed to bind to membranes and phosphatidylserine-linked Affi-Gel. In contrast, the C-terminal tail bound to membranes and phosphatidylserine-linked Affi-Gel. The N-terminal fragment contained a GDP/GTP-binding and GTPase domain and exhibited these two activities, but the C-terminal tail did not show any such activity. A GTPase-activating protein for smg p21 stimulated the GTPase activity of both the intact smg p21B and the N-terminal fragment. In contrast, a GDP/GTP exchange protein for smg p21, named GDP dissociation stimulator, stimulated the GDP/GTP exchange reaction of the intact smg p21B but not that of the N-terminal fragment. These results indicate 1) that smg p21B is composed of at least two functionally different domains, the N-terminal GDP/GTP-binding and GTPase domain and the C-terminal membrane-binding domain, 2) that smg p21B binds to membranes through its C-terminal hydrophobic and basic domain, and 3) that this C-terminal domain is also essential for the smg p21 GDP dissociation stimulator action but not for the smg p21 GTPase-activating protein action.     

Two dominant inhibitory mutants of p21ras interfere with insulin-induced gene expression.

Insulin induces a rapid activation of p21ras in NIH 3T3 and Chinese hamster ovary cells that overexpress the insulin receptor. Previously, we suggested that p21ras may mediate insulin-induced gene expression. To test such a function of p21ras more directly, we studied the effect of different dominant inhibitory mutants of p21ras on the induction of gene expression in response to insulin. We transfected a collagenase promoter-chloramphenicol acetyltransferase (CAT) gene or a fos promoter-luciferase gene into NIH 3T3 cells that overexpressed the insulin receptor. The activities of both promoters were strongly induced after treatment with insulin. This induction could be suppressed by cotransfection of two inhibitory mutant ras genes, H-ras(Asn-17) or H-ras(Leu-61,Ser-186). In particular, insulin-induced activation of the fos promoter was inhibited completely by H-ras(Asn-17). These results show that p21ras functions as an intermediate in the insulin signal transduction route leading to the induction of gene expression.