Biochemical properties of a highly purified v-rasH p21 protein overproduced in Escherichia coli and inhibition of its activities by a monoclonal antibody

Direct inhibition of RAS: Quest for the Holy Grail?

RAS GTPases (H-, K-, and N-RAS) are the most frequently mutated oncoprotein family in human cancer. However, the relatively smooth surface architecture of RAS and its picomolar affinity for nucleotide have given rise to the assumption that RAS is an "undruggable" target. Recent advancements in drug screening, molecular modeling, and a greater understanding of RAS function have led to a resurgence in efforts to pharmacologically target this challenging foe. This review focuses on the state of the art of RAS inhibition, the approaches taken to achieve this goal, and the challenges of translating these discoveries into viable therapeutics.

Structural Dynamics in Ras and Related Proteins upon Nucleotide Switching

Structural dynamics of Ras proteins contributes to their activity in signal transduction cascades. Directly targeting Ras proteins with small molecules may rely on the movement of a conserved structural motif, switch II. To understand Ras signaling and advance Ras-targeting strategies, experimental methods to measure Ras dynamics are required. Here, we demonstrate the utility of hydrogen-deuterium exchange (HDX) mass spectrometry (MS) to measure Ras dynamics by studying representatives from two branches of the Ras superfamily, Ras and Rho. A comparison of differential deuterium exchange between active (GMPPNP-bound) and inactive (GDP-bound) proteins revealed differences between the families, with the most notable differences occurring in the phosphate-binding loop and switch II. The P-loop exchange signature correlated with switch II dynamics observed in molecular dynamics simulations focused on measuring main-chain movement. HDX provides a means of evaluating Ras protein dynamics, which may be useful for understanding the mechanisms of Ras signaling, including activated signaling of pathologic mutants, and for targeting strategies that rely on protein dynamics.

Evidence that the ras oncogene-encoded p21 protein induces oocyte maturation via activation of protein kinase C

The ras oncogene-encoded p21 protein is known to induce cell maturation of Xenopus laevis oocytes and malignant transformation of NIH 3T3 mouse fibroblasts. The pathways involved in oocytes and NIH 3T3 cells appear to be similar to one another. For example, in both cases, the ras p21-induced cellular events involve increased intracellular levels of the second messengers diacylglycerol and inositol phosphates, the former of which activates protein kinase C (PKC). To investigate the pathway of ras-induced oocyte maturation, we have explored the relationship between p21 protein and PKC. We show that the maturation signal from oncogenic p21 microinjected into Xenopus oocytes is completely blocked by the relatively specific PKC inhibitor CGP 41251, a staurosporine analogue that selectively inhibits PKC, but not by an inactive analogue of staurosporine, CGP 42700. Microinjection of purified PKC or of phorbol ester induces maturation of oocytes. PKC-induced maturation is inhibited by CGP 41251 but not by CGP 42700. Maturation induced by microinjected PKC is also not inhibited by two specific anti-p21 agents, the inactivating anti-p21 monoclonal antibody Y13-259 and the amino acid derivative azatyrosine. Both of these agents block p21-induced cell maturation. These results suggest that ras effects depend upon the action of PKC, whose activation is an event that occurs downstream of p21 in the maturation signal pathway.

Identification and preliminary characterization of protein-cysteine farnesyltransferase

Ras proteins must be isoprenylated at a conserved cysteine residue near the carboxyl terminus (Cys-186 in mammalian Ras p21 proteins) in order to exert their biological activity. Previous studies indicate that an intermediate in the mevalonate pathway, most likely farnesyl pyrophosphate, is the donor of this isoprenyl group. Inhibition of mevalonate synthesis reverts the abnormal phenotypes induced by the mutant RAS2Val-19 gene in Saccharomyces cerevisiae and blocks the maturation of Xenopus oocytes induced by an oncogenic Ras p21 protein of human origin. These results have raised the possibility of using inhibitors of the mevalonate pathway to block the transforming properties of ras oncogenes. Unfortunately, mevalonate is a precursor of various end products essential to mammalian cells, such as dolichols, ubiquinones, heme A, and cholesterol. In this study, we describe an enzymatic activity(ies) capable of catalyzing the farnesylation of unprocessed Ras p21 proteins in vitro at the correct (Cys-186) residue. This farnesylating activity is heat-labile, requires Mg2+ or Mn2+ ions, is linear with time and with enzyme concentration, and is present in all mammalian cell lines and tissues tested. Gel filtration analysis of a partially purified preparation of protein farnesyltransferase revealed two peaks of activity at 250-350 kDa and 80-130 kDa. Availability of an in vitro protein farnesyltransferase assay should be useful in screening for potential inhibitors of ras oncogene function that will not interfere with other aspects of the mevalonate pathway.

Antibodies to synthetic peptide from the residue 33 to 42 domain of c-Ha-ras p21 block reconstitution of the protein with different effectors

Residues 32 to 40, which are conserved among ras proteins from different species, are likely to participate in interactions with the p21 effector system. With the goal of understanding the structural basis of the regulatory functions of c-Ha-ras p21, we produced rabbit antisera against a synthetic peptide corresponding to amino acids 33 to 42 of the protein. The affinity-purified antibodies interacted specifically with p21 and with the antigenic peptide. The epitope recognized by the antibodies appeared to be centered on threonine 35. The antibodies inhibited both in vitro p21-induced production of cyclic AMP in detergent extracts of RAS-defective yeast membranes and GAP-stimulated GTPase activity. However, monoclonal anti-ras antibodies Y13-259 and Y13-238 were not capable of specifically inhibiting interactions of p21 with these two putative effector proteins. The apparent inhibitory effect of Y13-259 on stimulation of p21 by GAP was due to a greatly reduced rate of exchange of nucleotides in the binding pocket of the protein. These findings provide additional support for the essential role of the residue 32 to 40 domain as the true effector site and further evidence of the involvement of GAP as a cellular effector of ras proteins.

Antibodies to synthetic peptide from the residue 33 to 42 domain of c-Ha-ras p21 block reconstitution of the protein with different effectors

Residues 32 to 40, which are conserved among ras proteins from different species, are likely to participate in interactions with the p21 effector system. With the goal of understanding the structural basis of the regulatory functions of c-Ha-ras p21, we produced rabbit antisera against a synthetic peptide corresponding to amino acids 33 to 42 of the protein. The affinity-purified antibodies interacted specifically with p21 and with the antigenic peptide. The epitope recognized by the antibodies appeared to be centered on threonine 35. The antibodies inhibited both in vitro p21-induced production of cyclic AMP in detergent extracts of RAS-defective yeast membranes and GAP-stimulated GTPase activity. However, monoclonal anti-ras antibodies Y13-259 and Y13-238 were not capable of specifically inhibiting interactions of p21 with these two putative effector proteins. The apparent inhibitory effect of Y13-259 on stimulation of p21 by GAP was due to a greatly reduced rate of exchange of nucleotides in the binding pocket of the protein. These findings provide additional support for the essential role of the residue 32 to 40 domain as the true effector site and further evidence of the involvement of GAP as a cellular effector of ras proteins.

Identification of resonances from an oncogenic activating locus of human N-RAS-encoded p21 protein using isotope-edited NMR

A sample of Escherichia coli-expressed human N-RAS-encoded p21, a 21-kDa protein, was selectively labeled with 15N at each of the 14 glycine amide positions. Two-dimensional proton-observe 15N correlation spectra showed one peak for each glycine residue. Five glycine resonances were identified with residues near the nucleotide binding site and provide useful reporters of several oncogene-activating positions. Three of these resonances were assigned to residues 10, 15, and 115 from the spectrum of a sample that was also labeled with [13C]valine. These resonances showed extra splitting or broadening due to the 13C label, which could be eliminated by 13C decoupling. Two other peaks were unambiguously identified as Gly-12 and Gly-13 using a one-dimensional edited nuclear Overhauser experiment and by spectral comparison with an Asp-12 mutant. These assignments have provided several site-specific probes of critical domains in p21.

Characterization of a factor that stimulates hydrolysis of GTP bound to ras gene product p21 (GTPase-activating protein) and correlation of its activity to cell density

The postmicrosomal fraction of the extract from NIH 3T3 and BALB/c 3T3 cells stimulated the hydrolysis of GTP bound to H-ras gene product p21 by severalfold. The stimulation was observed with normal p21 but not with p21 with valine as the 12th residue. This specificity is similar to that of GTPase-activating protein (GAP) for N-ras p21 described by M. Trahey and F. McCormick (Science 238:542-545, 1987). Consistent with this specificity, analysis of p21-bound nucleotides in living cells revealed that almost all normal p21 bound GDP, whereas oncogenic mutant p21s bound both GTP and GDP. Similar activity was also found in various mouse tissues, with brain tissue showing the highest specific activity. When cell extracts were prepared from cultured cells, there was a linear relationship between GAP activity and cell density. These results suggest the factor is involved in the regulation of cell proliferation.

Characterization of a factor that stimulates hydrolysis of GTP bound to ras gene product p21 (GTPase-activating protein) and correlation of its activity to cell density

The postmicrosomal fraction of the extract from NIH 3T3 and BALB/c 3T3 cells stimulated the hydrolysis of GTP bound to H-ras gene product p21 by severalfold. The stimulation was observed with normal p21 but not with p21 with valine as the 12th residue. This specificity is similar to that of GTPase-activating protein (GAP) for N-ras p21 described by M. Trahey and F. McCormick (Science 238:542-545, 1987). Consistent with this specificity, analysis of p21-bound nucleotides in living cells revealed that almost all normal p21 bound GDP, whereas oncogenic mutant p21s bound both GTP and GDP. Similar activity was also found in various mouse tissues, with brain tissue showing the highest specific activity. When cell extracts were prepared from cultured cells, there was a linear relationship between GAP activity and cell density. These results suggest the factor is involved in the regulation of cell proliferation.

Expression of the Aplysia californica rho gene in Escherichia coli: purification and characterization of its encoded p21 product

A new family of highly conserved genes, designated rho, has recently been isolated and characterized (P. Madaule and R. Axel, Cell 41:31-40, 1985). These genes have been found in Saccharomyces cerevisiae, Drosophila melanogaster, rats, and humans, and their 21,000-dalton products are highly homologous. The rho p21 protein shares 35% amino acid homology with the Harvey ras p21 protein and on this basis has been proposed to be a G protein. We expressed the Aplysia californica rho gene in Escherichia coli and purified its p21 protein to more than 90% purity. The availability of the rho protein in high quantities made it possible to establish its high affinity for guanine nucleotides. The rho p21 protein had nucleotide-binding properties similar to those of the ras p21 protein. However, a comparison of these proteins revealed some important differences regarding their specificities and affinities. Finally, the rho p21 protein had GTPase activity almost identical to that of a normal ras p21 protein, the rates being 0.106 and 0.105 mol/min per mol of p21, respectively. Thus, the results suggest that the degree of homology found between the ras and rho genes products most likely is related to the conservation of sequences relevant to their ability to bind and hydrolyze guanine nucleotides. The fact that the rho p21 protein binds and hydrolyzes GTP strongly suggests that it is a G protein with a potential regulatory function conserved in evolution.

Heterologous expression and characterization of the human R-ras gene product

We directly expressed human R-ras 23,000-dalton protein (p23) cDNA in Escherichia coli under the control of the trp promoter. GTP-dependent phosphorylation of a p23 threonine 85 substitution mutant was observed. This result is in direct analogy to the autokinase activity of H-ras and K-ras threonine 59 substitution mutants. Normal p23 protein was detected in the human fibrosarcoma cell line HT1080 by immunoprecipitation with rabbit antibodies raised against an E. coli-expressed R-ras fusion protein. The R-ras p23 protein was found to be 3H labeled in the presence of [9,10(n)-3H]palmitic acid and is associated with the P100 membrane fraction of HT1080 cells. These data suggest that human R-ras p23 has biochemical properties very similar to those of the p21 products of the H-, K-, and N-ras proto-oncogenes. We constructed an R-ras minigene and engineered the expression of normal and mutant alleles from the simian virus 40 early region promoter. Normal and mutant R-ras gene products were authenticated by transient expression in COS-7 cells and immunoprecipitation. The valine 38-substituted R-ras p23 displayed reduced electrophoretic mobility. R-ras p21-like proteins, made by eliminating the first 26 R-ras codons, displayed evident mobility differences between the pro form and mature form, along with a valine 12 substitution-dependent change in electrophoretic mobility. Rat-1 fibroblasts were transfected with normal and mutant R-ras alleles and normal and activated H-ras alleles. Unlike the human T24 bladder oncogene-encoded p21, mutant R-ras alleles do not cause monolayer focus formation or growth in soft agar of rat fibroblasts.

Expression of the Aplysia californica rho gene in Escherichia coli: purification and characterization of its encoded p21 product

A new family of highly conserved genes, designated rho, has recently been isolated and characterized (P. Madaule and R. Axel, Cell 41:31-40, 1985). These genes have been found in Saccharomyces cerevisiae, Drosophila melanogaster, rats, and humans, and their 21,000-dalton products are highly homologous. The rho p21 protein shares 35% amino acid homology with the Harvey ras p21 protein and on this basis has been proposed to be a G protein. We expressed the Aplysia californica rho gene in Escherichia coli and purified its p21 protein to more than 90% purity. The availability of the rho protein in high quantities made it possible to establish its high affinity for guanine nucleotides. The rho p21 protein had nucleotide-binding properties similar to those of the ras p21 protein. However, a comparison of these proteins revealed some important differences regarding their specificities and affinities. Finally, the rho p21 protein had GTPase activity almost identical to that of a normal ras p21 protein, the rates being 0.106 and 0.105 mol/min per mol of p21, respectively. Thus, the results suggest that the degree of homology found between the ras and rho genes products most likely is related to the conservation of sequences relevant to their ability to bind and hydrolyze guanine nucleotides. The fact that the rho p21 protein binds and hydrolyzes GTP strongly suggests that it is a G protein with a potential regulatory function conserved in evolution.

Heterologous expression and characterization of the human R-ras gene product

We directly expressed human R-ras 23,000-dalton protein (p23) cDNA in Escherichia coli under the control of the trp promoter. GTP-dependent phosphorylation of a p23 threonine 85 substitution mutant was observed. This result is in direct analogy to the autokinase activity of H-ras and K-ras threonine 59 substitution mutants. Normal p23 protein was detected in the human fibrosarcoma cell line HT1080 by immunoprecipitation with rabbit antibodies raised against an E. coli-expressed R-ras fusion protein. The R-ras p23 protein was found to be 3H labeled in the presence of [9,10(n)-3H]palmitic acid and is associated with the P100 membrane fraction of HT1080 cells. These data suggest that human R-ras p23 has biochemical properties very similar to those of the p21 products of the H-, K-, and N-ras proto-oncogenes. We constructed an R-ras minigene and engineered the expression of normal and mutant alleles from the simian virus 40 early region promoter. Normal and mutant R-ras gene products were authenticated by transient expression in COS-7 cells and immunoprecipitation. The valine 38-substituted R-ras p23 displayed reduced electrophoretic mobility. R-ras p21-like proteins, made by eliminating the first 26 R-ras codons, displayed evident mobility differences between the pro form and mature form, along with a valine 12 substitution-dependent change in electrophoretic mobility. Rat-1 fibroblasts were transfected with normal and mutant R-ras alleles and normal and activated H-ras alleles. Unlike the human T24 bladder oncogene-encoded p21, mutant R-ras alleles do not cause monolayer focus formation or growth in soft agar of rat fibroblasts.

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.

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.

Biochemical and biological properties of the human N-ras p21 protein

We characterized the normal (Gly-12) and two mutant (Asp-12 and Val-12) forms of human N-ras proteins produced by Escherichia coli. No significant differences were found between normal and mutant p21 proteins in their affinities for GTP or GDP. Examination of GTPase activities revealed significant differences between the mutant p21s: the Val-12 mutant retained 12% of wild-type GTPase activity, whereas the Asp-12 mutant retained 43%. Both mutant proteins, however, were equally potent in causing morphological transformation and increased cell motility after their microinjection into quiescent NIH 3T3 cells. This lack of correlation between transforming potency and GTPase activity or guanine nucleotide binding suggests that position 12 mutations affect other aspects of p21 function.

Biochemical characterization of polypeptides encoded by mutated human Ha-ras1 genes

We expressed six forms of p21-ras polypeptides in Escherichia coli with differing transformation potentials resulting from amino acid substitutions at position 12. The ability of the encoded p21's to autophosphorylate, bind guanine nucleotides, and hydrolyze GTP was assessed. All versions of p21 bound GTP equivalently; the kinase activity, while dependent upon residue 12, did not correlate with the transforming potential of the polypeptide. All transforming versions exhibited an impaired GTPase activity, while a novel nontransforming derivative [p21(pro-12)] possessed an enhanced GTPase activity. These results provide strong support for the proposal that an impairment of the cellular p21 GTPase activity can unmask its transforming potential.

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.

Biochemical and biological properties of the human N-ras p21 protein

We characterized the normal (Gly-12) and two mutant (Asp-12 and Val-12) forms of human N-ras proteins produced by Escherichia coli. No significant differences were found between normal and mutant p21 proteins in their affinities for GTP or GDP. Examination of GTPase activities revealed significant differences between the mutant p21s: the Val-12 mutant retained 12% of wild-type GTPase activity, whereas the Asp-12 mutant retained 43%. Both mutant proteins, however, were equally potent in causing morphological transformation and increased cell motility after their microinjection into quiescent NIH 3T3 cells. This lack of correlation between transforming potency and GTPase activity or guanine nucleotide binding suggests that position 12 mutations affect other aspects of p21 function.

ras p21 deletion mutants and monoclonal antibodies as tools for localization of regions relevant to p21 function

Deletion mutants of the viral Harvey ras oncogene were generated by removing different lengths of the gene from either the amino or the carboxyl terminus. The deletion mutants, ras p21 expressed in Escherichia coli, yielded proteins of approximately 8, 10, 12, 14, 17, 18, 19, and 20 kDa. These proteins were utilized to identify epitopes recognized by a series of recently generated monoclonal antibodies as well as some previously reported monoclonal antibodies. Monoclonal antibodies that inhibited GTP binding, a major biochemical activity of the p21 protein, recognized two major regions of the protein. These regions were localized from amino acids 5 to 69 and 107 to 164, respectively, and were separated by another stretch from residues 70 to 106, whose antigenic determinants were not directly involved in GTP binding. Thus, the mapping of epitopes within the p21 molecule recognized by monoclonal antibodies has made it possible to localize important functional regions within the ras p21 molecule.

Mutations of the ras gene product p21 that abolish guanine nucleotide binding

We have constructed several point mutations affecting the GTP-binding site of p21, the ras-encoded protein. Both lysine (116K) and tyrosine (116Y) mutations of asparagine-116, which, by analogy with the crystal structure of elongation factor Tu (EF-Tu), has critical interactions with the guanine base, abolish GTP binding and transforming activities of p21. These activities are retained by proteins with a mutation at position 117 or 118. Both 116K and 116Y mutant p21s, when overproduced in Escherichia coli, are apparently devoid of GTP-binding and autokinase activities. Similarly, the mutant DNAs do not transform NIH 3T3 cells in a focus-forming assay. By cotransfection with pSV-neo, cell clones resistant to the neomycin analog G418 have been isolated. Cells transfected with 116K or 116Y mutant DNA are contact inhibited. In contrast to competent clones, the defective mutants have no detectable phosphorylated p21. The present results suggest that the basic structure of the GTP-binding site is conserved between p21 and EF-Tu and that this binding site is crucial for ras gene function.

Expression of p21 proteins in Escherichia coli and stereochemistry of the nucleotide-binding site

v-Ha-ras encoded p21 protein (p21V), the cellular c-Ha-ras encoded protein (p21C) and its T24 mutant form p21T were produced in Escherichia coli under the control of the tac promoter. Large amounts of the authentic proteins in a soluble form can be extracted and purified without the use of denaturants or detergents. All three proteins are highly active in GDP binding, GTPase and, for p21V, autokinase activity. Inhibition of [3H]GDP binding to p21C by regio- and stereospecific phosphorothioate analogs of GDP and GTP was investigated to obtain a measure of the relative affinities of the three diphosphate and five triphosphate analogs of guanosine. p21 has a preference for the Sp isomers of GDP alpha S and GTP alpha S. It has low specificity for the Sp isomer of GTP beta S. Together with the data for GDP beta S and GTP gamma S these results are compared with those obtained for elongation factor (EF)Tu and transducin. This has enabled us to probe the structural relatedness of these proteins. We conclude that p21 seems to be more closely related to EF-Tu than to transducin.

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.

Biochemical characterization of polypeptides encoded by mutated human Ha-ras1 genes

We expressed six forms of p21-ras polypeptides in Escherichia coli with differing transformation potentials resulting from amino acid substitutions at position 12. The ability of the encoded p21's to autophosphorylate, bind guanine nucleotides, and hydrolyze GTP was assessed. All versions of p21 bound GTP equivalently; the kinase activity, while dependent upon residue 12, did not correlate with the transforming potential of the polypeptide. All transforming versions exhibited an impaired GTPase activity, while a novel nontransforming derivative [p21(pro-12)] possessed an enhanced GTPase activity. These results provide strong support for the proposal that an impairment of the cellular p21 GTPase activity can unmask its transforming potential.

Mutant ras-encoded proteins with altered nucleotide binding exert dominant biological effects

We report that residues Lys-16 and Asp-119 play critical roles in the guanine nucleotide binding and, consequently, the biological function of the Ha-ras-encoded protein (Ha). Substitution of an asparagine residue for Lys-16 reduces the affinity of Ha for GDP and GTP by a factor of 100 but does not alter the specificity of nucleotide binding. The replacement of Asp-119 with an alanine residue reduces the affinity of Ha for GDP and GTP by a factor of 20 and reduces the relative affinity of Ha for GDP over IDP from 200-500 to 10. Based on these observations, a structural model for the GDP/GTP-binding site of Ha is proposed. By microinjecting purified proteins into NIH 3T3 cells, we observed that the ability of [Ala119]Ha to induce changes characteristic of cellular transformation was much greater than that of normal Ha and similar to that of the oncogenic [Val12, Thr59]Ha. In this assay, [Asn16]Ha and [Val12, Asn16, Thr59]Ha were similar in potency to normal Ha. In yeast cells, Ha proteins with reduced nucleotide affinity exert a dominant temperature-dependent lethality that is avoided by the coexpression of the activated yeast ras gene [Ala18, Val19]RAS2. We interpret the biological consequences of reducing the nucleotide affinity of ras proteins in terms of two opposing factors: a growth-promoting effect, resulting from an increase in the GDP-GTP exchange rate, and a growth-limiting effect, resulting from an increase in the nucleotide-free ras protein species.

Posttranslational processing of p21 ras proteins involves palmitylation of the C-terminal tetrapeptide containing cysteine-186

The p21 proteins of ras oncogenes are synthesized as precursors in the cytosol. After processing, which involves acylation, the products are associated with the plasma membrane in eucaryotic cells. The p21 overproduced in Escherichia coli, however, is not processed by acylation. A synthetic tetrapeptide of the p21 C terminus is used to identify the acylation site in eucaryotic p21 as cysteine-186. The same peptide of bacterial p21 is not acylated. Although p21 of Harvey murine sarcoma virus-transformed NRK cells can be metabolically labeled with either [3H]palmitate or [3H]myristate, the lipid moiety of the hydrophobic peptide is identified as palmitic acid. We suggest that the enzymatic mechanism for p21 palmitylation may be different from N-terminal myristylation of many other membrane proteins.