Reversal of transformed phenotype by monoclonal antibodies against Ha-ras p21 proteins

The transforming activities of p21 ras proteins have been determined by micro-injection of these proteins into NIH3T3 cells. In order to facilitate functional studies on the effect of ras proteins on malignant transformation and normal cellular growth, analysis has been made with three monoclonal antibodies (YA6-172, Y13-238 and Y13-259) as originally reported by Furth et al. (J virol 43 (1982) 294). Purified immunoglobulin of Y13-259 has the highest titer of binding to bacterially synthesized p21 ras proteins. Experimental analyses indicate that only Y13-259 antibody will neutralize the transforming activity of the co-injected bacterially synthesized ras protein and the neutralization effect was blocked by co-injection of excess ras protein. In addition, micro-injection of Y13-259 immunoglobulin into transformed NIH3T3 cells (obtained by DNA transfection of NIH3T3 cells with molecularly cloned ras gene) reversed their transformed phenotypes. These results indicate that both bacterially synthesized p21 ras proteins and the natural ras proteins produced in NIH3T3 cells were neutralized by Y13-259 antibody.     

Identification of amino acid residues required for Ras p21 target activation.

The Krev-1 gene has been shown to suppress ras-mediated transformation in vitro. Both ras and Krev-1 proteins have identical effector domains (ras residues 32 to 40), which are required for biological activity and for the interaction of Ras p21 with Ras GTPase-activating protein (GAP). In this study, five amino acid residues flanking the ras effector domain, which are not conserved with the Krev-1 protein, were shown to be required for normal protein-protein interactions and biological activity. The substitution of Krev-1 p21 residues 26, 27, 30, 31, and 45 with the corresponding amino acid residues from Ras p21 resulted in a Krev-1 protein which had ras function in both mammalian and yeast biological assays. Replacement of these residues in Ras p21 with the corresponding Krev-1 p21 amino acids resulted in ras proteins which were impaired biologically or reduced in their affinity for in vitro GAP binding. Evaluation of these mutant ras proteins have implications for Ras p21-GAP interactions in vivo.     

Inhibition of yeast adenylate cyclase by antibodies to ras p21.

Monoclonal antibody Y13-259 to ras p21 was shown to bind to the highly conserved residues in the region 63-73 and to neutralize ras action in the Saccharomyces cerevisiae adenylate cyclase system. Inhibition of adenylate cyclase activity in isolated membranes by antibody Y13-259 occurred after a lag period of 6 min. This lag corresponded to the time necessary for binding of antibody Y13-259 to the membranes in a ras-dependent manner. The mechanism of inhibition appeared to be steric in nature because antibody Y13-259 neutralized ras p21 bound to a stable GTP analogue. Monoclonal antibodies Y13-4 and Y13-128 also inhibited yeast adenylate cyclase activity, and the epitopes for both the these antibodies were localized to ras region 65-75. However, the ras residues essential for binding of antibodies Y13-4 and Y13-128 to ras p21 (positions 65, 66, 68 and 75) were different from those essential for binding of antibody Y13-259 (positions 63, 65, 66, 67, 70 and 73). These results indicate that residues 63-75 constitute a major neutralizing epitope on ras p21.     

H-ras mutants lacking the epitope for the neutralizing monoclonal antibody Y13-259 show decreased biological activity and are deficient in GTPase-activating protein interaction.

We have generated deletion mutants of the H-ras p21 protein which lack residues 58 to 63 or 64 to 68 and contain either the normal glycine or an activating mutation, arginine, at position 12. None of the deleted proteins were recognized by monoclonal antibody Y13-259, and those mutants with activating mutations showed at least a 100-fold reduction in their transforming activities compared with the activities of their nondeleted counterparts. Alterations observed in the in vitro GTPase or GTP interchange properties of the deletion mutants were not consistent with the decrease in their transforming activities. Moreover, each mutant showed normal membrane localization, which is essential for its biological activity. Recently, a newly identified protein, designated GTPase-activating protein (GAP), was found to markedly increase GTPase activity of the normal ras p21 but not of p21 mutants bearing activating lesions (H. Adari, D. R. Lowy, B. M. Willumsen, C. J. Der, and F. McCormick, Science 240:518-521, 1988). We showed that GAP had no effect on the in vitro GTPase activity of the deletion mutants of the normal p21 protein. Since similar deletions in mutants with activating lesions at position 12 or 59 or both showed decreased transforming activity, our results suggest that the recognition site for Y13-259 within the ras p21 molecule influences directly or indirectly the interaction of ras p21 with GAP and that this interaction is critical for biological activity of ras proteins.     

Biochemical characterization of Artemia ras p21

The biochemical properties of Artemia ras proteins (p21) have been studied after immunoprecipitation with the monoclonal antibody Y13-259. The ras products bind GTP and GDP, and have GTPase activity. Artemia p21 was unable to hydrolyze GP₄G, although this dinucleotide exhibits high affinity for the protein. Our results demonstrate that the protein(s) recognized by the Y13-259 antibody in this crustacean behave as typical mammalian ras p21s.     

Low molecular weight GTP-binding proteins in hepatocytes and an assessment of the role of p21ras proteins in the activation of phospholipase D.

A GTP-binding protein with an apparent molecular weight of 25 kDa was detected in hepatocyte extracts using SDS-PAGE and [alpha-32P]GTP. p21ras proteins could only be detected by immunological analysis. The amounts of p21ras proteins present in isolated hepatocytes and in a highly purified preparation of liver plasma membrane vesicles were 0.3 and 4 ng p21ras protein/micrograms membrane protein, respectively. In comparison with the total cell extract, the degree of enrichment of plasma membrane vesicles with p21ras was similar to that of 5'-nucleotidase. The p21ras proteins were tightly associated with the membrane. Treatment of [3H]choline-labelled plasma membranes with an excess concentration of the anti-p21ras antibody Y13-259 failed to inhibit either basal or guanosine 5'-[gamma-thio]triphosphate (GTP[S])-stimulated [3H]choline release. It is concluded that in hepatocytes (a) the majority of p21ras is bound to the plasma membrane and (b) p21ras is not directly involved in the activation by GTP[S] of phospholipase D.     

A synthetic peptide corresponding to a sequence in the GTPase activating protein inhibits p21ras stimulation and promotes guanine nucleotide exchange

Amino acid sequence homology between the GTPase Activating Protein (GAP) and the GTP-binding regulatory protein, Gs alpha, suggests that a specific region of GAP primary structure (residues 891-898) may be involved in its stimulation of p21ras GTP hydrolytic activity (McCormick, F. [1989] Nature 340, 678-679). A peptide, designated p891, corresponding to GAP residues 891-906 (M891RTRVVSGFVFLRLIC906) was synthesized and tested for its ability to inhibit GAP-stimulated p21ras GTPase activity. At a concentration of 25 microM, p891 inhibited GAP activity approximately 50%. Unexpectedly, p891 also stimulated GTP binding to p21N-ras independent of GAP. This stimulation correlated with an enhancement of p21N-ras.GDP dissociation; an approximate 15-fold increase in the presence of 10 microM p891. In contrast, dissociation of the p21N-ras.GTP gamma S complex was unaffected by 10 microM p891. The p21N-ras.GDP complex was unresponsive to 100 microM mastoparan, a peptide toxin shown previously to accelerate GDP dissociation from the guanine nucleotide regulatory proteins, Gi and Go. p21H-ras, as well as the two p21H-ras effector mutants, Ala-38, and Ala-35, Leu-36, also exhibited increased rates of GDP dissociation in the presence of p891. Also tested were three ras-related GTP-binding proteins; rap, G25K and rac. The rap.-GDP complex was unaffected by 10 microM p891. Dissociation of the G25K- and rac.GDP complexes were enhanced slightly; approximately 1.3- and 1.8-fold over control, respectively. Thus, the inhibitory effect of p891 on GAP stimulation of p21ras suggests that amino acids within the region 891-906 of GAP may be essential for interaction with p21ras. In addition, p891 independently affects the nucleotide exchange properties of p21ras.     

Inhibition of the ras p21 GTPase-activating protein-stimulated GTPase activity of c-Ha-ras p21 by smg p21 having the same putative effector domain as ras p21s

ras p21 GTPase-activating protein (GAP) has been proposed to interact with the putative effector domain of ras p21s, and smg p21, a ras p21-like guanine nucleotide binding protein (G protein), has been shown to have the same amino acid sequence as ras p21s in this region. In the present studies, we examined the effects of ras p21 GAP on the GTPase activity of smg p21 purified from human platelets, of smg p21 on the ras p21 GAP-stimulated GTPase activity of c-Ha-ras p21 purified from Escherichia coli, and of c-Ha-ras p21 on the smg p21 GAP1- or -2-stimulated GTPase activity of smg p21. ras p21 GAP stimulated the GTPase activity of c-Ha-ras p21 but not that of smg p21. The GTP-bound form of smg p21, however, inhibited the ras p21 GAP-stimulated GTPase activity of c-Ha-ras p21 in a dose-dependent manner. The half-maximum inhibition by smg p21 was obtained at 0.4 microM which was more potent than previously observed for ras p21 (2-200 microM). The GDP-bound form also inhibited the ras p21 GAP-stimulated GTPase activity of c-Ha-ras p21, but the efficiency was 40-50% that of the GTP-bound form. smg p21 GAP1 and -2 stimulated the GTPase activity of smg p21 but not that of c-Ha-ras p21. c-Ha-ras p21 did not inhibit the smg p21 GAP1- or -2-stimulated GTPase activity of smg p21. These results indicate that ras p21 GAP interacts with smg p21 without the subsequent stimulation of its GTPase activity.     

Intracellular immunization. Cloning and intracellular expression of a monoclonal antibody to the p21ras protein

Following the demonstration that intracellular expression of antibodies ('intracellular immunization') may be utilized to engineer new traits in mammalian cells, we undertook experiments to perturb the function of p21ras proteins, by engineering the intracellular expression of the anti-p21ras antibody Y13-259. The variable regions of this antibody have been cloned and, after verifying their antigen binding activity, expressed in general purpose vectors for the intracellular expression of antibodies. The results confirmed that the cloned antibody has been efficiently expressed both in the secretory and the intracellular forms. Thus, intracellular immunization of mammalian cells against p21ras, or any other antigen for which a monoclonal antibody is available, can now be performed.     

GTPase activating proteins for the smg-21 GTP-binding protein having the same effector domain as the ras proteins in human platelets

Two proteins stimulating the GTPase activity of the smg-21 GTP-binding protein (smg p21) having the same effector domain as the ras proteins (ras p21s) are partially purified from the cytosol fraction of human platelets. These proteins, designated as smg p21 GTPase activating protein (GAP) 1 and 2, do not stimulate the GTPase activity of c-Ha-ras p21. The GAP activity for c-Ha-ras p21 is also detected in the cytosol fraction of human platelets. smg p21 GAP1 and 2 are separated from c-Ha-ras p21 GAP by column chromatographies. The activity of smg p21 GAP1 and 2 is killed by tryptic digestion or heat boiling. The Mr values of smg p21 GAP1 and 2 are similar and are estimated to be 2.5-3.5 x 10(5) by gel filtration analysis. These results indicate that there are two GAPs for smg p21 in addition to a GAP for c-Ha-ras p21 in human platelets.     

Purification and characterization from bovine brain cytosol of two GTPase-activating proteins specific for smg p21, a GTP-binding protein having the same effector domain as c-ras p21s

The smg-21 GTP-binding protein (smg p21) has the same effector domain as the ras proteins (ras p21s) and is identical with the proteins of the rap1A and Krev-1 genes. In this paper, two proteins stimulating the GTPase activity of smg p21 are partially purified from bovine brain cytosol. These proteins, designated as smg p21 GTPase-activating protein (GAP) 1 and 2, are separated from a c-ras p21 GAP described previously by column chromatographies. smg p21 GAP1 and -2 stimulate the GTPase activity of only smg p21 but not that of c-Ha-ras p21 or the rho and smg-25A GTP-binding proteins. smg p21 GAP1 or -2 does not stimulate the dissociation of guanosine 5'-3-O-(thio)triphosphate or GDP from smg p21. smg p21 GAP1 or -2 themselves do not have GTP/GDP binding or GTPase activity. The Mr values of smg p21 GAP1 and -2 are estimated to be 250-400 x 10(3) and 80-100 x 10(3) by gel filtration and sucrose density gradient ultracentrifugation, respectively. The activity of smg p21 GAP1 and -2 is killed by tryptic digestion or heat boiling. These results indicate that bovine brain contains two smg p21 GAPs in addition to c-ras p21 GAP.     

Viral latency and transformation: the strategy of Epstein-Barr virus

Evidence that GAP is an effector of ras action can be summarized as follows: GAP interacts at a site on p21 defined genetically as the effector binding site. Regions of p21 that are nonessential for biological activity are nonessential for GAP interaction. GAP interacts with all known types of p21. (Upstream factors are expected to be specific for individual types). GAP interacts with p21 proteins (normal and mutant) in a GTP-dependent fashion. None of these constitute proof. It remains possible that GAP simply regulates p21-GTP levels, and binds to the same site as the true effector without transmitting a downstream signal. If indeed GAP mediates ras action, the question immediately arises as to the biochemical function of GAP itself. The requirement of ras proteins for membrane localization to exert their effects may be a valuable clue in the search for this function. Perhaps GAP is an enzyme (or is bound to an enzyme) that acts on membrane components in a p21-GTP-dependent manner and in doing so transmits signals to other downstream effectors. The ability of GAP to interact with many members of the ras family would allow many upstream signals to feed into this downstream pathway. Clearly, proof (or disproof) that GAP is downstream of ras is the next step toward clarification of this aspect of ras action; identification of biochemical activities associated with GAP (or the true ras effector) will, we hope, follow soon.     

Ras interaction with the GTPase-activating protein (GAP)

Biologically active forms of Ras complexed to GTP can bind to the GTPase-activating protein (GAP), which has been implicated as possible target of Ras in mammalian cells. In order to study the structural features of Ras required for this interaction, we have evaluated a series of mutant ras proteins for the ability to bind GAP and a series of Ras peptides for the ability to interfere with this interaction. Point mutations in the putative effector region of Ras (residues 32-40) that inhibit biological activity also impair Ras binding to GAP. An apparent exception is the Thr to Ser substitution at residue 35; [Ser-35]Ras binds to GAP as effectively as wild-type Ras even though this mutant is biologically weak in both mammalian and S. cerevisiae cells. In vitro, [Ser-35]Ras can also efficiently stimulate the S. cerevisiae target of Ras, adenylyl cyclase, indicating that other factors may influence Ras/protein interactions in vivo. Peptides having Ras residues 17-44 and 17-32 competed with the binding of Ras to E. coli-expressed GAP with IC50 values of 2.4 and 0.9 microM, respectively, whereas Ras peptide 17-26 was without effect up to 400 microM. A related peptide from the yeast GTP-binding protein YPT1 analogous to Ras peptide 17-32 competed with an IC50 value of 19 microM even though the YPT1 protein itself is unable to bind to GAP. These results suggest that determinants within Ras peptide 17-32 may be important for Ras binding to GAP.     

Monoclonal antibody Y13-259 recognizes an epitope of the p21 ras molecule not directly involved in the GTP-binding activity of the protein.

The p21 products of ras proto-oncogenes are GTP-binding proteins with associated GTPase activity. Recent studies have indicated that ras p21 may be required for the initiation of normal cell DNA synthesis, since microinjection of a monoclonal antibody, Y13-259, blocks serum stimulation of DNA synthesis in quiescent cell cultures (L. S. Mulcahy, M.R. Smith, and D. W. Stacey, Nature [London] 313:241-243, 1985). We localized the structural domain within the p21 molecule recognized by the Y13-259 monoclonal antibody. By analysis of a series of bacterially expressed p21 deletion mutants, the monoclonal antibody was found to interact with a region between positions 70 and 89 in the p21 amino acid sequence. By comparison of the coding sequences of different p21 proteins recognized by this monoclonal antibody, a highly conserved amino acid region between positions 70 and 81 was found to be the most likely site for the epitope detected by the Y13-259 antibody. This monoclonal antibody was further shown not to interfere directly with in vitro biochemical functions of the molecule, including GTP binding, GTPase, and autokinase activities.     

Regulation of a ras-related protein during development of Dictyostelium discoideum.

Recent work has shown that DNA sequences related to the mammalian ras proto-oncogenes are highly conserved in eucaryotic evolution. A monoclonal antibody (Y13-259) to mammalian p21ras specifically precipitated a 23,000-molecular-weight protein (p23) from lysates of Dictyostelium discoideum amoebae. Tryptic peptide analysis indicated that D. discoideum p23 was closely related in its primary structure to mammalian p21ras. p23 was apparently derived by post-translational modification of a 24,000-molecular-weight primary gene product. The amount of p23 was highest in growing amoebae, but declined markedly with the onset of differentiation such that by fruiting body formation there was less than 10% of the amoeboid level. The rate of p23 synthesis dropped rapidly during aggregation, rose transiently during pseudoplasmodial formation, and then declined during the terminal stages of differentiation. There was, therefore, a strong correlation between the expression of the ras-related protein p23 and cell proliferation of D. discoideum.     

Identification of distinct cytoplasmic targets for ras/R-ras and rho regulatory proteins

The protein products of the mammalian ras genes, p21ras, are regulatory guanine nucleotide binding proteins that are involved in the control of cell proliferation, though the exact biochemical processes regulated are unknown. Recently a cytoplasmic protein has been identified that interacts with and increases the GTPase activity of p21ras. It has been shown that this GTPase-activating protein, or GAP, interacts with the effector domain of ras, leading us and others to propose that GAP may be the target for regulation by p21ras. It has become apparent that ras is part of a much larger family of proteins, and at least 15 ras-related genes have now been identified in the mammalian genome. Each encodes a small (about 21 kDa) guanine nucleotide binding protein, but the functions of none of these regulatory molecules are known. We report here that mammalian cytoplasmic extracts contain GAP-like activity toward the products of two other ras-related genes, R-ras and rho. It appears that p23R-ras interacts with the same 125-kDa GAP protein as p21ras whereas p21rho interacts with a distinct 29-kDa protein, rho GAP.     

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.     

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.     

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.     

ralGDS family members interact with the effector loop of ras p21.

Using a yeast two-hybrid system, we identified a novel protein which interacts with ras p21. This protein shares 69% amino acid homology with ral guanine nucleotide dissociation stimulator (ralGDS), a GDP/GTP exchange protein for ral p24. We designated this protein RGL, for ralGDS-like. Using the yeast two-hybrid system, we found that an effector loop mutant of ras p21 was defective in interacting with the ras p21-interacting domain of RGL, suggesting that this domain binds to ras p21 through the effector loop of ras p21. Since ralGDS contained a region highly homologous with the ras p21-interacting domain of RGL, we examined whether ralGDS could interact with ras p21. In the yeast two-hybrid system, ralGDS failed to interact with an effector loop mutant of ras p21. In insect cells, ralGDS made a complex with v-ras p21 but not with a dominant negative mutant of ras p21. ralGDS interacted with the GTP-bound form of ras p21 but not with the GDP-bound form in vitro. ralGDS inhibited both the GTPase-activating activity of the neurofibromatosis gene product (NF1) for ras p21 and the interaction of Raf with ras p21 in vitro. These results demonstrate that ralGDS specifically interacts with the active form of ras p21 and that ralGDS can compete with NF1 and Raf for binding to the effector loop of ras p21. Therefore, ralGDS family members may be effector proteins of ras p21 or may inhibit interactions between ras p21 and its effectors.