Biochemical properties of Ha-ras encoded p21 mutants and mechanism of the autophosphorylation reaction

The GTPase activity of the Escherichia coli Ffh protein is important for normal growth

The Escherichia coli (E. coli) Ffh protein is homologous to the 54kDa subunit of the eukaryotic signal recognition particle. We have examined an intrinsic GTPase activity of this protein and have created mutations in one sequence motif (GXXXXGK) of the putative GTP binding site. When glycine-112 was changed to valine (Ffh-G112V), Vmax was reduced to only 4% of the wildtype level. On the other hand, when glutamine-109 was altered to glycine (Ffh-Q109G), the major effect was a 50-fold increase in Km. These results show that the residues Q-109 and G-112 are essential for the binding and hydrolysis of GTP and that they are part of a catalytic site structurally related to that of many other GTPase proteins. Expression of the mutant protein Ffh-G112V in E. coli was highly toxic in the presence of the wildtype protein. In contrast, genetic complementation experiments showed that a viable strain could be constructed where the Ffh-Q109G mutant protein replaced wildtype Ffh. However, expression of the mutant protein had a negative effect on growth rate at 30 degrees C and resulted in elongated cells. These results demonstrate that the GTPase activity of the Ffh protein is required for proper function of the protein in vivo.

RNA1 encodes a GTPase-activating protein specific for Gsp1p, the Ran/TC4 homologue of Saccharomyces cerevisiae

Ran/TC4 is a ras-related GTP-binding protein predominantly located in the nucleus. Ran/TC4 is essential for nuclear transport and is involved in mitotic control. In Saccharomyces cerevisiae a gene highly homologous to Ran/TC4 has been identified and named GSP1. Like all ras-related GTP-binding proteins, Gsp1p undergoes cycles of GTP hydrolysis and GDP/GTP exchange. The switching between the two different nucleotide bound states regulates the function of these GTP-binding proteins. Here we identify the product of the yeast RNA1 gene as the GTPase-activating protein (GAP) of Gsp1p. RNA1 belongs to a group of genes which are conserved in a variety of different organisms. We have expressed and purified recombinant Gsp1p and Rna1p from Escherichia coli. The GTPase activity of Gsp1p is stimulated 10(7)-fold by Rna1p. In addition, we find that the previously identified human RanGAP1 and rna1p from Schizosaccharomyces pombe are also able to induce GTPase activity of Gsp1p. The GTP hydrolysis of Ran is induced by RanGAP1 and rna1p but not by Rna1p. Implications for the suggested functions of Ran/TC4/Gsp1p in nuclear transport and mitotic control are discussed.

Quantitative analysis of the complex between p21ras and the Ras-binding domain of the human Raf-1 protein kinase

The Ras-binding domain (RBD) of human Raf-1 was purified from Escherichia coli, and its interaction with Ras was investigated. Its dissociation constant with p21ras.guanyl-5'-yl imidodiphosphate was found to be 18 nM, with a slight preference for H-ras over K- and N-ras. Oncogenic forms bind with slightly lower affinity. The affinity of RBD for effector region mutants or the GDP-bound form of p21ras is in the micromolar range, which means that 100-fold lower affinity is not sufficient for signal transduction. The rate of the GTPase of p21ras is not modified by RBD. Since P(i) release is found not to be rate limiting, the Ras-Raf signal of the cell may be terminated by the intrinsic GTPase of p21ras.

Biochemical characterization of the essential GTP-binding protein Obg of Bacillus subtilis

An essential guanine nucleotide-binding protein, Obg, of Bacillus subtilis has been characterized with respect to its enzymatic activity for GTP. The protein was seen to hydrolyze GTP with a Km of 5.4 microM and a kcat of 0.0061 min-1 at 37 degrees C. GDP was a competitive inhibitor of this hydrolysis, with an inhibition constant of 1.7 microM at 37 degrees C. The dissociation constant for GDP from the Obg protein was 0.5 microM at 4 degrees C and was estimated to be 1.3 microM at 37 degrees C. Approximately 80% of the purified protein was capable of binding GDP. In addition to hydrolysis of GTP, Obg was seen to autophosphorylate with this substrate. Subsequent release of the covalent phosphate proceeds at too slow a rate to account for the overall rate of GTP hydrolysis, indicating that in vitro hydrolysis does not proceed via the observed phosphoamidate intermediate. It was speculated that the phosphorylated form of the enzyme may represent either a switched-on or a switched-off configuration, either of which may be normally induced by an effector molecule. This enzyme from a temperature-sensitive mutant of Obg did not show significantly altered GTPase activity at the nonpermissive temperature.

Structural determinants for activation of the alpha-subunit of a heterotrimeric G protein

The 1.8 A crystal structure of transducin alpha.GDP, when compared to that of the activated complex with GTP-gamma S, reveals the nature of the conformational changes that occur on activation of a heterotrimeric G-protein alpha-subunit. Structural changes initiated by direct contacts with the terminal phosphate of GTP propagate to regions that have been implicated in effector activation. The changes are distinct from those observed in other members of the GTPase superfamily.

Association of Rap1a and Rap1b proteins with late endocytic/phagocytic compartments and Rap2a with the Golgi complex

Among the small GTPases of the Ras family, Rap proteins exhibit the highest homology with p21Ras. The four Rap proteins so far identified constitute two subgroups, comprising the Rap1(A,B) and the Rap2(A,B) proteins. The intracellular location of Rap1A, Rap1B and Rap2A proteins was investigated in mammalian cells by confocal immunofluorescence microscopy. Using a specific anti-Rap1 affinity-purified antibody, both Rap1A and Rap1B proteins were localized to late endocytic compartments (late endosomes/lysosomes) in fibroblasts. The localization of the Rap1A and B proteins transiently overexpressed with the vaccinia T7 system was identical to that observed for endogenous Rap1 proteins. In contrast, epitope-tagged Rap2A protein colocalized with several markers of the Golgi complex, thus indicating that its site of function was distinct from that of Rap1A. In addition, morphological and subcellular fractionation studies provided evidence for the association of Rap1 proteins with phagosomes displaying biochemical features of late endocytic structures in J774 macrophages. Thus, the localization of Rap1A and Rap1B implicates their involvement in late endocytic/phagocytic processes.

Characterization of the autophosphorylation of Era, an essential Escherichia coli GTPase

Era is an essential protein in Escherichia coli which binds both GTP and GDP and has an intrinsic GTPase activity. Studies on the role of GTP/GDP binding and GTPase activity in an attempt to understand its function lead to the observation that Era is autophosphorylated. The autophosphorylation reaction is specific for GTP and cannot use ATP as a phosphoryl group donor. The reaction velocity is of first order with respect to protein concentration, suggesting an intramolecular mechanism. Autophosphorylation occurs at serine and threonine residues. The major phosphorylated tryptic peptide isolated after autophosphorylation has been identified as ISITSR, from residue 33 to 38. The peptide contains the site of phosphorylation and two potential sites for serine and threonine phosphorylation. Subsequently, both the threonine residue at position 36 and the serine residue at position 37 were altered to alanine. The double mutant Era, but not individual single mutants, was unable to functionally complement the growth of an E. coli strain which cannot produce wild-type Era protein at high temperature. This suggests that either threonine 36 or serine 37 has to exist for the function of Era in vivo. In vivo phosphorylation of Era was also examined by two-dimensional gel electrophoresis. Era has been previously assigned two distinct positions having two different X-Y co-ordinates: one of the spots (H032.0) was identified as phosphorylated Era, indicating that a substantial portion of Era in the cell is indeed phosphorylated. Therefore, Era autophosphorylation is likely to play an important physiological role in the cell.(ABSTRACT TRUNCATED AT 250 WORDS)

T cell epitopes encompassing the mutational hot spot position 61 of p21 ras. Promiscuity in ras peptide binding to HLA

Activated ras carry a point mutation either in codon 12, 13 or 61 which is tumor specific. Peptides derived from this oncoprotein are therefore potential tumor antigens. Essential for the feasibility of using ras-derived peptides in therapy of cancer is whether p21 ras-derived peptides can be processed, bind to human histocompatibility leukocyte antigen (HLA) and be recognized by T cells. Here we report the fine specificity and HLA restriction of several T lymphocyte clones (TLC) specific for a peptide which is derived from the second mutational hot spot in ras encoding residue 61. These TLC were generated from memory T cells present in the blood of a cancer patient and recognized a ras-derived peptide carrying Leu instead of Gln at residue 61. By sequencing of the T cell receptor (TcR) genes three sets of "sister" TLC carrying highly different TcR were identified. Two of the TLC recognized a peptide carrying the 61 Leu mutation presented by HLA-DQ8 and one recognized the same peptide presented by HLA-DQ4. By using truncated peptides derived from residues 51 to 69 of p21 ras, partially overlapping minimal epitopes could be defined. All three TLC recognized the corresponding recombinant mutant p21 ras oncoprotein carrying Leu at residue 61 presented by autologous B-lymphoblastoid cell lines (B-LCL). This demonstrates that naturally derived ras peptides from this region of p21 ras encompass the three epitopes recognized by the TLC. These results indicate that immunogenic ras-derived peptides may be used in immunotherapy of cancer where transforming ras oncoproteins are involved.

In vivo study of engineered G-domain mutants of Escherichia coli translation initiation factor IF2

During the IF2-catalysed formation of the 30S initiation complex, the GTP requirement and its subsequent hydrolysis during 70S complex formation are considered to be essential for translation initiation in Escherichia coli. In order to clarify the role of certain amino acid residues believed to be crucial for the GTP hydrolytic activity of E. coli IF2, we have introduced seven single amino acid substitutions into its GTP-binding site (Gly for Val-400; Thr for Pro-446; Gly, Glu, Gln for His-448; and Asn, Glu for Asp-501). These mutated IF2 proteins were expressed in vivo in physiological quantities and tested for their ability to maintain the growth of an E. coli strain from which the functional chromosomal copy of the infB gene has been deleted. Only one of the mutated proteins (Asp-501 to Glu) was able to sustain cell viability and several displayed a dominant negative effect. These results emphasize that the amino acid residues we substituted are essential for the IF2 functions and demonstrate the importance of GTP hydrolysis in translation initiation. These findings are discussed in relation to a previously proposed theoretical model for the IF2 G-domain.

GTPase activity of small GTP-binding proteins in HL-60 membranes is stimulated by arachidonic acid

The GTPase activity of membranes isolated from differentiated HL-60 cells was investigated to obtain information about the possible involvement of membrane-bound GTP-binding proteins in the regulation of the NADPH oxidase. A more than tenfold increase in the rate of hydrolysis of membrane-bound GTP was observed when cytosol and arachidonic acid were added simultaneously, i.e. under the same conditions where NADPH oxidase becomes activated. There were parallel changes in GTPase and NADPH oxidase activities when the concentration of arachidonic acid or the species of the fatty acid was varied or different detergents were applied. Separation of the GTP-binding proteins of the solubilized membrane by sucrose density gradient centrifugation, allowed us to ascribe the observed effect to the stimulation of the GTPase activity of small GTP-binding proteins by cytosolic component(s). Indirect evidence suggests that, in contrast to the effect upon recombinant ras and ras-GTPase-activating protein, in intact HL-60 membranes the interaction of rap1A with rap-GTPase-activating protein, is strongly enhanced by arachidonic acid.

Nucleotide binding and GTP hydrolysis by the 21-kDa product of the c-H-ras gene as monitored by proton-NMR spectroscopy

Proton-NMR signals in the downfield region (below approximately 10 ppm) have been shown to provide a useful spectroscopic window to monitor the binding of guanine nucleotides to the active site of GTP/GDP-binding proteins via H-bonds, as specified here by the 21-kDa product of the c-H-ras gene (p21). The time course of the intensity change of certain peaks upon addition of GTP to nucleotide-free p21 corresponds to the GTP hydrolysis rate as determined by HPLC. Though there are fewer potential H-bond acceptors in the GDP-bound protein than in the GTP complex, more downfield peaks are found in the former complex, suggesting tighter binding of GDP. Moreover, inspection of the downfield proton-NMR spectra permits rapid detection of subtle changes of the active site induced by complexation with slowly hydrolyzing GTP analogues resulting from mutations of the amino acid sequence, especially in the phosphate binding loop. Our studies strongly suggest that no major conformational change of the phosphate-binding region occurs upon nucleotide complexation that precedes the catalytic step. Besides, it is suspected that the Ser17 hydroxyl group is involved in nucleotide binding and GTP hydrolysis.

Probing the structure and mechanism of Ras protein with an expanded genetic code

Mutations in Ras protein at positions Gly12 and Gly13 (phosphate-binding loop L1) and at positions Ala59, Gly60, and Gln61 (loop L4) are commonly associated with oncogenic activation. The structural and catalytic roles of these residues were probed with a series of unnatural amino acids that have unusual main chain conformations, hydrogen bonding abilities, and steric features. The properties of wild-type and transforming Ras proteins previously thought to be uniquely associated with the structure of a single amino acid at these positions were retained by mutants that contained a variety of unnatural amino acids. This expanded set of functional mutants provides new insight into the role of loop L4 residues in switch function and suggests that loop L1 may participate in the activation of Ras protein by effector molecules.

A universal expression-purification system based on the coiled-coil interaction of myosin heavy chain

We have constructed a series of Escherichia coli expression vectors that produce high yields of fusion proteins containing the C-terminal fragment of light meromyosin (LMM) from rabbit fast skeletal muscle. The fusion proteins retain the ability of LMM to form polymers in low salt and to be soluble in high salt. Thus they can be easily purified from bacterial extracts with a high salt-low salt extraction procedure and still retain their biochemical properties. We demonstrate the utility of this system for the heterologous production and simple purification of LMM fusions of p21H-ras, the neurofibromatosis type I protein and the Tat and protease proteins of HIV-1.

Nucleoside diphosphate kinase does not directly interact with tubulin nor microtubules

Nucleoside diphosphate kinase has been shown to play a role in proliferation and development. Microtubules have been evoked as a possible target of NDP kinase action; in particular it was proposed that NDP kinase could regulate the cellular pool of polymerizable GTP-tubulin by direct phosphorylation of tubulin bound GDP. We show that this reaction does not occur in vitro and also that NDP kinase does not bind to microtubules both in the presence and absence of MAPs. Thus, any possible physiological effect of NDP kinase on microtubule dynamics is exerted only by modulating the concentrations of free guanine nucleotides in the vicinity of microtubules.

Molecular cloning of cDNAs encoding a guanine-nucleotide-releasing factor for Ras p21

The stimulation of a variety of cell surface receptors promotes the accumulation of the active, GTP-bound form of Ras proteins in cells. This is a critical step in signal transduction because inhibition of Ras activation by anti-Ras antibodies or dominant inhibitory Ras mutants blocks many of the effects of these receptors on cellular function. To reach the active GTP-bound state, Ras proteins must first release bound GDP. This rate-limiting step in GTP binding is thought to be catalysed by a guanine-nucleotide-releasing factor (GRF). Here we report the cloning of complementary DNAs from a rat brain library that encode a approximately 140K GRF for Ras p21 (p140Ras-GRF). Its carboxy-terminal region is similar to that of CDC25, a GRF for Saccharomyces cerevisiae RAS. This portion of Ras-GRF accelerated the release of GDP from RasH and RasN p21 in vitro, but not from the related RalA, or CDC42Hs GTP-binding proteins. A region in the amino-terminal end of Ras-GRF is similar to both the human breakpoint cluster protein, Bcr, and the dbl oncogene product, a guanine-nucleotide-releasing factor for CDC42Hs. An understanding of Ras-GRF function will enhance our knowledge of the many signal transduction pathways mediated by Ras proteins.

Rac1, a low-molecular-mass GTP-binding-protein with high intrinsic GTPase activity and distinct biochemical properties

Rac1, a member of the family of low-molecular-mass GTP-binding proteins, functions in phagocytic leukocytes as a component necessary for activation of the respiratory burst. To characterize the biochemical properties of rac1, the protein was expressed as a fusion protein in Escherichia coli and purified to greater than 99% homogeneity by affinity chromatography. Rac1 protein bound maximally bound and hydrolyzed GTP under low free-Mg2+ concentrations. Under those conditions, (45 nm free Mg2+), purified rac1 exhibited a steady-state GTPase activity of 18 nmol.min-1.mg protein-1 (turnover number approximately 0.39 min-1 at 37 degrees C), which is 40-fold higher than H-ras. The high intrinsic GTPase activity of rac1 under low free Mg2+ was mainly due to an increased kcat, the rate constant for hydrolysis of bound GTP, which was 0.29 min-1 for rac1 vs 0.007 min-1 for H-ras (at 20 degrees C). Rac1 also released bound GDP faster than H-ras (koff.GDP = 1.02 min-1 for rac1 vs 0.33 min-1 for H-ras at 20 degrees C). In contrast, rac1 released bound guanosine 5'-[gamma-thio]triphosphate (GTP[S]) at a slower rate than H-ras (koff.GTP[S] approximately 0.04 min-1 for rac1 vs 0.31 min-1 for H-ras at 20 degrees C). Rac1 was a very good substrate for in vitro geranylgeranylation (C20) but not for farnesylation (C15), whereas the converse is true for H-ras. Surprisingly, rac1 was a very poor substrate for in vitro ADP-ribosylation by the C3 component of Clostridium botulinum toxin compared to rhoA. As a further characterization of rac1, a mutant was made in which the Thr115 was replaced by asparagine. This protein (referred to as [Thr115----Asn]rac1) contains the consensus amino acids of all four GTP-binding domains of H-ras. The koff.GDP of [Thr115----Asn]rac1 was reduced to that of H-ras, but [Thr115----Asn]rac1 exhibited essentially identical kcat (0.13 min-1 at 20 degrees C) and koff-GTP[S] (0.03 min-1 at 20 degrees C) values as the wild-type protein. Thus, the region(s) in rac1 which control the dissociation of GTP[S] (and presumably GTP) do not entirely coincide with those controlling GDP dissociation. Biochemical analysis of [Thr115----Asn]rac1 also suggests that the region responsible for the increased kcat of rac1 is not within the consensus amino acids of the four guanine-nucleotide-binding domains.

Expression, purification and biochemical characterisation of the human immunodeficiency virus 1 nef gene product

The human immunodeficiency virus 1 (HIV-1) nef gene encoded by the HIV-1 isolate lymphadenopathy-associated virus type 1 was expressed in Escherichia coli under the control of the tac promoter. The protein is found mainly in the soluble part of the bacterial lysate; a simple two-column purification scheme has been developed allowing isolation of the recombinant protein without using denaturing agents. Analysis of the circular dichroism spectra reveals that the purified protein is folded and has a helix content of 16% and a beta-pleated sheet content of 31%. GTPase activity and binding of guanine nucleotides were measured for Nef and compared with the results obtained under identical experimental conditions for p21rasC, which represents a typical, well-characterized guanine-nucleotide-binding (GNB) protein. Within the limits of error, native Nef does not show GTPase activity and does not bind guanine nucleotides strongly (association constant, Kass less than 5 x 10(3) M-1). An upper limit for the association constant of Nef for ATP was determined by equilibrium dialysis as 5 x 10(3) M-1. Nef can be autophosphorylated by ATP; under the experimental conditions used, 1-2% of the protein become phosphorylated. Correspondingly, our Nef preparation shows a low, but significant, ATPase activity. In conclusion, Nef is not a member of the GNB protein family, but a possible role as a protein kinase cannot be excluded.

Biochemical and biological activity of phosphorylated and non-phosphorylated ras p21 mutants

In contrast to all cellular ras oncogenes which carry a single activating mutation at codon 12, 13 or 61, all known retroviral ras oncogenes have two mutations at codons 12 and 59. To understand the role of the mutation at codon 59, we have constructed plasmids containing genes for Harvey ras: p21(Gly-12,Thr-59) and p21(Val-12,Thr-59). Escherichia coli expressed proteins and their respective phosphorylated (Pi) and non-phosphorylated (non-Pi) proteins were purified to 95% homogeneity by ion-exchange chromatography and gel filtration. GTPase, autophosphorylation and nucleotide exchange activities of the mutants were studied. When the mutants were microinjected into Xenopus oocytes, the non-phosphorylated forms of p21(Gly-12,Thr-59) and p21(Val-12,Thr-59) showed high activity. Surprisingly, their phosphorylated forms were inactive. These results suggest that threonine at position 59 endows the protein with transforming activity but that phosphorylation of the residue inhibits biological activity. A structural interpretation of the observation is presented.

Identification of amino acid residues of Ras protein that are essential for signal-transducing activity but not for enhancement of GTPase activity by GAP

To determine the amino acid residues required for the signal-transducing activity of the human c-Ha-Ras protein, we introduced point mutations at residues 45-54 near the 'effector region' (residues 32-40). We transfected PC12 cells with these mutant genes and also micro-injected the mutant proteins, bound with an unhydrolyzable GTP analog, into PC12 cells. Both procedures showed that Val45----Glu and Gly48----Cys mutations impaired the ability of the Ras protein to induce morphological change of PC12 cells. These mutations did not affect the guanine nucleotide-binding activity or GTPase activity in the absence or presence of bovine GTPase-activating protein (GAP). Therefore, the Val45 and Gly48 residues should be included by definition in the effector region responsible for the signal transduction, while only a subset of the effector-region residues is required for enhancement of the GTPase activity by GAP.

Catalysis of guanine nucleotide exchange on Ran by the mitotic regulator RCC1

The product of the gene RCC1 (regulator of chromosome condensation) in a BHK cell line is involved in the control of mitotic events. Homologous genes have been found in Xenopus, Drosophila and yeast. A human genomic DNA fragment and complementary DNA that complement a temperature-sensitive mutation of RCC1 in BHK21 cells encode a protein of relative molecular mass 45,000 (Mr 45K) which is located in the nucleus and binds to chromatin. We have recently isolated a protein from HeLa cells that strongly binds an anti-RCC1 antibody and has the same molecular mass, DNA-binding properties, and amino-acid sequence as the 205 residues already identified. HeLa cell RCC1 is complexed to a protein of Mr 25K. We have shown that this 25K protein has a sequence homologous to the translated reading frame of TC4, a cDNA found by screening a human teratocarcinoma cDNA library with oligonucleotides coding for a ras consensus sequence, and that the protein binds GDP and GTP. We have referred to this protein as the Ran protein (ras-related nuclear protein). In addition to the fraction of Ran protein complexed to RCC1, a 25-fold molar excess of the protein over RCC1 was found in the nucleoplasm of HeLa cells. Here we show that RCC1 specifically catalyses the exchange of guanine nucleotides on the Ran protein but not on the protein c-Ha-ras p21 (p21ras).

GTP-binding proteins and potassium channels involved in synaptic plasticity and learning

Inhibition of potassium channels is possibly the first step in the sequence of biochemical events leading to memory formation. These channels appear to be regulated directly or indirectly by GTP-binding proteins (G proteins), which may themselves be affected by phosphorylation and dephosphorylation in response to elevated calcium levels or other phenomena resulting from the blockage of the potassium channels. A wide variety of cellular phenomena, from transcriptional changes to axonal transport, are thus capable of being initiated by these events.

Ras proteins activate calcium channels in neuronal cells

Ras (p21) proteins are involved in the control of cell growth and differentiation, but the mechanism by which they exert these effects is not yet known. Here we present evidence that c-Ha-ras (p21(Gly-12)) and its oncogenic mutant T24-ras (p21(Val-12)) selectively induce omega-conotoxin and dihydropyridine-sensitive Ca2+ currents within a few hours after introduction into the cytoplasm of neuroblastoma x glioma hybrid cells. Whereas control cells exhibited a mean Ca2+ current of 250 pA, it amounted to 730 pA in cells pretreated with ras protein. In cells loaded with p21(Gly-12), the effect occurred after 2 hours and was terminated after 8 hours. In contrast, introduction of p21(Val-12) resulted in a prolonged delay (6 hours) of the effect which lasted for more than 24 hours. When ras proteins were preactivated with the non-hydrolysable GTP analog GppNHp, the time courses of both p21(Gly-12) and p21(Val-12) effects were fast and sustained, suggesting that in intact cells (i) the GDP/GTP exchange is faster for p21(Gly-12) compared to p21(Val-12) and (ii) inactivation of p21(Gly-12) is mediated by GAP-induced GTPase activity. T-type Ca2+ currents and K+ currents were unaffected by ras proteins.

The GTPase superfamily: a conserved switch for diverse cell functions

Proteins that bind and hydrolyse GTP are being discovered at a rapidly increasing rate. Each of these many GTPases acts as a molecular switch whose 'on' and 'off' states are triggered by binding and hydrolysis of GTP. Conserved structure and mechanism in myriad versions of the switch--in bacteria, yeast, flies and vertebrates--suggest that all derive from a single primordial protein, repeatedly modified in the course of evolution to perform a dazzling variety of functions.

Mutagenesis of the NH2-terminal domain of elongation factor Tu

Mutagenesis was carried out in the N-terminal domain of elongation factor Tu (EF-Tu) to characterize the structure-function relationships of this model GTP binding protein with respect to stability, the interaction with GTP and GDP, and the catalytic activity. The substitutions were introduced in elements around the guanine nucleotide binding site or in the loops defining this site, in the intact molecule or in the isolated N-terminal domain (G domain). The double substitution Val88----Asp and Leu121----Lys, two residues situated on two vicinal alpha-helices, influences the basic activities of the truncated factor to a limited extent, probably via long-range interactions, and induces a destabilisation of the G domain structure. The functional alterations brought about by substitutions on the consensus sequences 18-24 and 80-83 highlight the importance of these residues for the interaction with GTP/GDP and the GTPase activity. Mutations concerning residues interacting with the guanine base lead to proteins in large part insoluble and inactive. In one case, the mutated protein (EF-TuAsn135----Asp) inhibited the growth of the host cell. This demonstrates the crucial role of the base specificity for the active conformation of EF-Tu. The obtained results are discussed in the light of the three-dimensional structure of EF-Tu.

Three-dimensional structures of H-ras p21 mutants: molecular basis for their inability to function as signal switch molecules

The X-ray structures of the guanine nucleotide binding domains (amino acids 1-166) of five mutants of the H-ras oncogene product p21 were determined. The mutations described are Gly-12----Arg, Gly-12----Val, Gln-61----His, Gln-61----Leu, which are all oncogenic, and the effector region mutant Asp-38----Glu. The resolutions of the crystal structures range from 2.0 to 2.6 A. Cellular and mutant p21 proteins are almost identical, and the only significant differences are seen in loop L4 and in the vicinity of the gamma-phosphate. For the Gly-12 mutants the larger side chains interfere with GTP binding and/or hydrolysis. Gln-61 in cellular p21 adopts a conformation where it is able to catalyze GTP hydrolysis. This conformation has not been found for the mutants of Gln-61. Furthermore, Leu-61 cannot activate the nucleophilic water because of the chemical nature of its side chain. The D38E mutation preserves its ability to bind GAP.

Inhibition of GTPase activating protein stimulation of Ras-p21 GTPase by the Krev-1 gene product

Krev-1 is known to suppress transformation by ras. However, the mechanism of the suppression is unclear. The protein product of Krev-1, Rap1A-p21, is identical to Ras-p21 proteins in the region where interaction with guanosine triphosphatase (GTPase) activating protein (GAP) is believed to occur. Therefore, the ability of GAP to interact with Rap1A-p21 was tested. Rap1A-p21 was not activated by GAP but bound tightly to GAP and was an effective competitive inhibitor of GAP-mediated Ras-GTPase activity. Binding of GAP to Rap1A-p21 was strictly guanosine triphosphate (GTP)-dependent. The ability of Rap1A-p21 to bind tightly to GAP may account for Krev-1 suppression of transformation by ras. This may occur by preventing interaction of GAP with Ras-p21 or with other cellular proteins necessary for GAP-mediated Ras GTPase activity.

Structure of the guanine-nucleotide-binding domain of the Ha-ras oncogene product p21 in the triphosphate conformation

The crystal structure of the guanine-nucleotide-binding domain of p21 (amino acids 1-166) complexed to the guanosine triphosphate analogue guanosine-5'-(beta, gamma-imido)triphosphate (GppNp) has been determined at a resolution of 2.6 A. The topological order of secondary structure elements is the same as that of the guanine-nucleotide-binding domain of bacterial elongation factor EF-Tu. Many interactions between nucleotide and protein have been identified. The effects of point mutations and the conservation of amino-acid sequence in the guanine-nucleotide-binding proteins are discussed.

Crystallization and preliminary X-ray analysis of the human c-H-ras-oncogene product p21 complexed with GTP analogues

The catalytic domain (amino acid residues 1 to 166) of the human ras-oncogene product p21 complexed with the GTP analogues beta,gamma-imido-GTP (GMPPNP), beta,gamma-methylene-GTP (GMPPCP), and guanosine-5'-(gamma-thiotriphosphate) (GTP gamma S) have been been crystallized. Crystals of the GMPPNP and GMPPCP complexes are well suited for high resolution X-ray crystallography. They belong to space group P3(1)21 (or its enantiomorph P3(2)21) with unit cell axes a=b=40.3 A and c = 162.2 A.