GTP hydrolysis mechanisms in ras p21 and in the ras-GAP complex studied by fluorescence measurements on tryptophan mutants

We have substituted leucine 56 or tyrosine 64 of p21 ras with a tryptophan. The intrinsic fluorescence of this tryptophan was used as an internal conformational probe for time-resolved biochemical studies of the ras protein. The slow intrinsic GTPase, GDP/GTP exchange induced by the SDC25 "exchange factor", and the fast GTP hydrolysis induced by GAP were studied. Tryptophan fluorescence of mutated ras is very sensitive to magnesium binding, GDP/GTP exchange, and GTP hydrolysis (changes in tyrosine fluorescence of wild-type ras are also observed but with a lower sensitivity). Nucleotide affinities, exchange kinetics, and intrinsic GTPase rates of the mutated ras could be measured by this method and were found to be close to those of wild-type ras. The SDC25 gene product enhances GDP/GTP exchange in both mutants. In both mutants, a slow fluorescence change follows the binding of GTP gamma S; its kinetics are close to those of the intrinsic GTPase, suggesting that a slow conformational change precedes the GTPase and is the rate-limiting step, as proposed by Neal et al. (1990) (Proc. Natl. Acad. Sci. U.S.A. 87, 3562-3565). GAP interacts with both mutant ras proteins and accelerates the GTPase of (L56W)ras but not that of (Y64W)ras, suggesting a role for tyrosine 64 in GAP-induced GTP hydrolysis. However, GAP does not accelerate the slow conformational change following GTP gamma S binding in either of the mutated ras proteins. This suggests that the fast GAP-induced catalysis of GTP hydrolysis that is observed with (L56W)ras bypasses the slow conformational change associated with the intrinsic GTPase and therefore might proceed by a different mechanism.     

Mutations in the GTP-binding site of GS alpha alter stimulation of adenylyl cyclase

Mutational replacements of specific residues in the GTP-binding pocket of the 21-kDa ras proteins (p21ras) reduce their GTPase activity. To test the possibility that the cognate regions of G protein alpha chains participate in GTP binding and hydrolysis, we compared signaling functions of normal and mutated alpha chains (termed alpha s) of Gs, the stimulatory regulator of adenylyl cyclase. alpha s chains were expressed in an alpha s-deficient S49 mouse lymphoma cell line, cyc-. alpha s in which leucine replaces glutamine 227 (corresponding to glutamine 61 of p21ras) constitutively activates adenylyl cyclase and reduces the kcat for GTP hydrolysis more than 100-fold. There is a smaller reduction in GTPase activity in another mutant in which valine replaces glycine 49 (corresponding to glycine 12 of p21ras). This mutant alpha s is a poor activator of adenylyl cyclase. Moreover, the glycine 49 protein, unlike normal alpha s, is not protected against tryptic cleavage by hydrolysis resistant GTP analogs; this finding suggests impairment of the mutant protein's ability to attain the active (GTP-bound) conformation. We conclude that alpha s residues near glutamine 227 and glycine 49 participate in binding and hydrolysis of GTP, although the GTP binding regions of alpha s and p21ras are not identical.     

Hydrolysis of GTP by the alpha-chain of Gs and other GTP binding proteins

The functions of G proteins--like those of bacterial elongation factor (EF) Tu and the 21 kDa ras proteins (p21ras)--depend upon their abilities to bind and hydrolyze GTP and to assume different conformations in GTP- and GDP-bound states. Similarities in function and amino acid sequence indicate that EF-Tu, p21ras, and G protein alpha-chains evolved from a primordial GTP-binding protein. Proteins in all three families appear to share common mechanisms for GTP-dependent conformational change and hydrolysis of bound GTP. Biochemical and molecular genetic studies of the alpha-chain of Gs (alpha s) point to key regions that are involved in GTP-dependent conformational change and in hydrolysis of GTP. Tumorigenic mutations of alpha s in human pituitary tumors inhibit the protein's GTPase activity and cause constitutive elevation of adenylyl cyclase activity. One such mutation replaces a Gln residue in alpha s that corresponds to Gln-61 of p21ras; mutational replacements of this residue in both proteins inhibit their GTPase activities. A second class of GTPase inhibiting mutations in alpha s occurs in the codon for an Arg residue whose covalent modification by cholera toxin also inhibits GTP hydrolysis by alpha s. This Arg residue is located in a domain of alpha s not represented in EF-Tu or p21ras. We propose that this domain constitutes an intrinsic activator of GTP hydrolysis, and that it performs a function analogous to that performed for EF-Tu by the programmed ribosome and for p21ras by the recently discovered GTPase-activating protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Guanine nucleotide binding properties of the mammalian RalA protein produced in Escherichia coli

The simian ralA cDNA was inserted in a ptac expression vector, and high amounts of soluble ral protein were expressed in Escherichia coli. The purified p24ral contains 1 mol of bound nucleotide/mol of protein that can be exchanged against external nucleotide. The ral protein exchanges GDP with a t 1/2 of 90 min at 37 degrees C in the presence of Mg2+, and has a low GTPase activity (0.07 min-1 at 37 degrees C). We have also studied its affinity for various guanine nucleotides and analogs. NMR measurements show that the three-dimensional environment around the nucleotide is similar in p21ras and p24ral. In addition to these studies on the wild-type ral protein, we used in vitro mutagenesis to introduce substitutions corresponding to the Val12, Val12 + Thr59, and Leu61 substitutions of p21ras. These mutant ral proteins display altered nucleotide exchange kinetics and GTPase activities, however, the effects of the substitutions are less pronounced than in the ras proteins. p24ralVal12 + Thr59 autophosphorylates on the substituted Thr, as a side reaction of the GTP hydrolysis, but the rate is much lower than those of the Thr59 mutants of p21ras. These results show that ras and ral proteins have similar structures and biochemical properties. Significant differences are found, however, in the contribution of the Mg2+ ion to GDP binding, in the rate of the GTPase reaction and in the sensitivity of these two proteins to substitutions around the phosphate-binding site, suggesting that the various "small G-proteins" of the ras family perform different functions.     

Structural changes induced in p21Ras upon GAP-334 complexation as probed by ESEEM spectroscopy and molecular-dynamics simulation

BACKGROUND: The means by which the protein GAP accelerates GTP hydrolysis, and thereby downregulates growth signaling by p21Ras, is of considerable interest, particularly inasmuch as p21 mutants are implicated in a number of human cancers. A GAP "arginine finger," identified by X-ray crystallography, has been suggested as playing the principal role in the GTP hydrolysis. Mutagenesis studies, however, have shown that the arginine can only partially account for the 10(5)-fold increase in the GAP-accelerated GTPase rate of p21. RESULTS: We report electron spin-echo envelope modulation (ESEEM) studies of GAP-334 complexed with GMPPNP bound p21 in frozen solution, together with molecular-dynamics simulations. Our results indicate that, in solution, the association of GAP-334 with GTP bound p21 induces a conformational change near the metal ion active site of p21. This change significantly reduces the distances from the amide groups of p21 glycine residues 60 and 13 to the divalent metal ion. CONCLUSIONS: The movement of glycine residues 60 and 13 upon the binding of GAP-334 in solution provides a physical basis to interpret prior mutagenesis studies, which indicated that Gly-60 and Gly-13 of p21 play important roles in the GAP-dependent GTPase reaction. Gly-60 and Gly-13 may play direct catalytic roles and stabilize the attacking water molecule and beta,gamma-bridging oxygen, respectively, in p21. The amide proton of Gly-60 could also play an indirect role in catalysis by supplying a crucial hydrogen bonding interaction that stabilizes loop L4 and therefore the position of other important catalytic residues.     

Ras p21 proteins with high or low GTPase activity can efficiently transform NIH/3T3 cells

We sought to determine whether decreased in vitro GTPase activity is uniformly associated with ras p21 mutants possessing efficient transforming properties. Normal H-ras p21-[Gly12-Ala59] as well as an H-ras p21-[Gly12-Thr59] mutant exhibited in vitro GTPase activities at least fivefold higher than either H-ras p21-[Lys12-Ala59] or H-ras p21-[Arg12-Thr59] mutants. Microinjection of as much as 6 X 10(6) molecules/cell of bacterially expressed normal H-ras p21 induced no detectable alterations of NIH/3T3 cells. In contrast, inoculation of 4-5 X 10(5) molecules/cell of each p21 mutant induced morphologic alterations and stimulated DNA synthesis. Moreover, the transforming activity of each mutant expressed in a eukaryotic vector was similar and at least 100-fold greater than that of the normal H-ras gene. These findings establish that activation of efficient transforming properties by ras p21 proteins can occur by mechanisms not involving reduced in vitro GTPase activity.     

Crystal structures at 2.2 A resolution of the catalytic domains of normal ras protein and an oncogenic mutant complexed with GDP

The biological functions of ras proteins are controlled by the bound guanine nucleotide GDP or GTP. The GTP-bound conformation is biologically active, and is rapidly deactivated to the GDP-bound conformation through interaction with GAP (GTPase Activating Protein). Most transforming mutants of ras proteins have drastically reduced GTP hydrolysis rates even in the presence of GAP. The crystal structures of the GDP complexes of ras proteins at 2.2 A resolution reveal the detailed interaction between the ras proteins and the GDP molecule. All the currently known transforming mutation positions are clustered around the bound guanine nucleotide molecule. The presumed "effector" region and the GAP recognition region are both highly exposed. No significant structural differences were found between the GDP complexes of normal ras protein and the oncogenic mutant with valine at position 12, except the side-chain of the valine residue. However, comparison with GTP-analog complexes of ras proteins suggests that the valine side-chain may inhibit GTP hydrolysis in two possible ways: (1) interacting directly with the gamma-phosphate and altering its orientation or the conformation of protein residues around the phosphates; and/or (2) preventing either the departure of gamma-phosphate on GTP hydrolysis or the entrance of a nucleophilic group to attack the gamma-phosphate. The structural similarity between ras protein and the bacterial elongation factor Tu suggests that their common structural motif might be conserved for other guanine nucleotide binding proteins.     

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.     

Kinetic analysis of the hydrolysis of GTP by p21N-ras. The basal GTPase mechanism

The rate constants have been determined for elementary steps in the basal GTPase mechanism of normal p21N-ras (Gly-12) and an oncogenic mutant (Asp-12): namely GTP binding, hydrolysis, phosphate release, and GDP release. By extrapolation from data at lower temperatures, the GTP association rate constant at 37 degrees C is 1.4 x 10(8) M-1 s-1 for the normal protein and 4.8 x 10(8) M-1 s-1 for the mutant. Other rate constants were measured directly at 37 degrees C, and three processes have similar slow values. GTP dissociation is at 1.0 x 10(-4) s-1 (normal) and 5.0 x 10(-4) s-1 (mutant). The hydrolysis step is at 3.4 x 10(-4) s-1 (normal) and 1.5 x 10(-4) s-1 (mutant). GDP dissociates at 4.2 x 10(-4) s-1 (normal) and 2.0 x 10(-4) s-1 (mutant). GDP association rate constants are similar to those for GTP, 0.5 x 10(8) M-1 s-1 for normal and 0.7 x 10(8) M-1 s-1 for mutant. Both hydrolysis and GDP release therefore contribute to rate limitation of the basal GTPase activity. There are distinct differences (up to 5-fold) between rate constants for the normal and mutant proteins at a number of steps. The values are consistent with the reduced GTPase activity for this mutant and suggest little difference between normal and mutant proteins in the relative steady-state concentrations of GTP and GDP complexes that may represent active and inactive states. The results are discussed in terms of the likely role of p21ras in transmembrane signalling.     

The pre-hydrolysis state of p21(ras) in complex with GTP: new insights into the role of water molecules in the GTP hydrolysis reaction of ras-like proteins

BACKGROUND: In numerous biological events the hydrolysis of guanine triphosphate (GTP) is a trigger to switch from the active to the inactive protein form. In spite of the availability of several high-resolution crystal structures, the details of the mechanism of nucleotide hydrolysis by GTPases are still unclear. This is partly because the structures of the proteins in their active states had to be determined in the presence of non-hydrolyzable GTP analogues (e.g. GppNHp). Knowledge of the structure of the true Michaelis complex might provide additional insights into the intrinsic protein hydrolysis mechanism of GTP and related nucleotides. RESULTS: The structure of the complex formed between p21(ras) and GTP has been determined by X-ray diffraction at 1.6 A using a combination of photolysis of an inactive GTP precursor (caged GTP) and rapid freezing (100K). The structure of this complex differs from that of p21(ras)-GppNHp (determined at 277K) with respect to the degree of order and conformation of the catalytic loop (loop 4 of the switch II region) and the positioning of water molecules around the gamma-phosphate group. The changes in the arrangement of water molecules were induced by the cryo-temperature technique. CONCLUSIONS: The results shed light on the function of Gln61 in the intrinsic GTP hydrolysis reaction. Furthermore, the possibility of a proton shuffling mechanism between two attacking water molecules and an oxygen of the gamma-phosphate group can be proposed for the basal GTPase mechanism, but arguments are presented that render this protonation mechanism unlikely for the GTPase activating protein (GAP)-activated GTPase.     

The GAP-related domain of the neurofibromatosis type 1 gene product interacts with ras p21

The neurofibromatosis type 1 (NF1) protein contains a region of significant sequence similarity to ras p21 GTPase-activating protein (GAP) and the yeast IRA1 gene product. A fragment of NF1 cDNA encoding the GAP-related domain (NF1 GRD) was expressed, immunoaffinity purified, and assayed for effects on N-ras p21 GTPase activity. The GTPase of wild-type ras p21 was stimulated by NF1 GRD, but oncogenic mutants of ras p21 (Asp-12 and Val-12) were unaffected, and the GTPase of an effector mutant (Ala-38) was only weakly stimulated. NF1 GRD also down-regulated RAS function in S. cerevisiae. The affinity of NF1 GRD for ras p21 was estimated to be 250 nM: this is more than 20-fold higher than the affinity of GAP for ras p21. However, its specific activity was about 30 times lower. These kinetic measurements suggest that NF1 may be a significant regulator of ras p21 activity, particularly at low ras p21 concentrations.     

Molecular dynamics simulations of Gly-12-->Val mutant of p21(ras): dynamic inhibition mechanism.

The mutant p21(ras) protein is a G protein produced by the point-mutated H-ras gene, and this mutant protein has been shown to cause carcinogenesis due to a reduction in its GTPase activity. However, the mechanism underlying this strange phenomenon has still not been elucidated. In our previous study, we have clarified the mechanism of the GTP-->GDP hydrolysis reaction in the wild-type p21(ras) at the atomic level and concluded that GTPase-activating protein plays a significant role in the supply of H2O molecules for the hydrolysis. The structure of the active site in the mutant is the same as that in the wild type. However, by performing molecular dynamic calculations, we found that the structure of the active site of the enzyme substrate complex in the oncogenic mutant p21(ras) continuously changes, and these continuous changes in the active site would make it difficult for the GTP-->GDP hydrolysis reaction to occur in the mutant. These findings can explain the fact that the GTPase activity in the mutant was only 15% of that in the wild type and the fact that GTPase-activating protein has no reaction-activating effect in the mutant. This is a dynamic inhibition mechanism of a vital reaction that can be explained by considering the molecular dynamics.     

Biological and biochemical properties of human rasH genes mutated at codon 61

Using site-directed mutagenesis, we have introduced mutations encoding 17 different amino acids at codon 61 of the human rasH gene. Fifteen of these substitutions increased rasH transforming activity. The remaining two mutants, encoding proline and glutamic acid, displayed transforming activities similar to the normal gene. Overall, these mutants vary over 1000-fold in transforming potency. Increased levels of p21 expression were required for transformation by weakly transforming mutants. The mutant proteins were unaltered in guanine nucleotide binding properties. However, all 17 different mutant proteins displayed equivalently reduced rates of GTP hydrolysis, 8- to 10-fold lower than the normal protein. There was no quantitative correlation between reduction in GTPase activity and transformation, indicating that reduced GTP hydrolysis is not sufficient to activate ras transforming potential.     

Mutation in the beta-tubulin signature motif suppresses microtubule GTPase activity and dynamics, and slows mitosis.

We introduced a threonine-to-glycine point mutation at position 143 in the "tubulin signature motif" 140Gly-Gly-Gly-Thr-Gly-Ser-Gly146 of Saccharomyces cerevisiae beta-tubulin. In an electron diffraction model of the tubulin dimer, this sequence comes close to the phosphates of a guanine nucleotide bound in the beta-tubulin exchangeable E site. Both the GTP-binding affinity and the microtubule (MT)-dependent GTPase activity of tubulin isolated from haploid tub2-T143G mutant cells were reduced by at least 15-fold, compared to tubulin isolated from control wild-type cells. The growing and shortening dynamics of MTs assembled from alphabeta:Thr143Gly-mutated dimers were also strongly suppressed, compared to control MTs. The in vitro properties of the mutated MTs (slower growing and more stable) are consistent with the effects of the tub2-T143G mutation in haploid cells. The average length of MT spindles in large-budded mutant cells was only 3.7 +/- 0.2 microm, approximately half of the size of MT arrays in large-budded wild-type cells (average length = 7.1 +/- 0.4 microm), suggesting that there is a delay in mitosis in the mutant cells. There was also a higher proportion of large-budded cells with unsegregated nuclei in mutant cultures (30% versus 12% for wild-type cells), again suggesting such a delay. The results show that beta:Thr143 of the tubulin signature motif plays an important role in GTP binding and hydrolysis by the beta-tubulin E site and support the idea that tubulins belong to a family of proteins within the GTPase superfamily that are structurally distinct from the classic GTPases, such as EF-Tu and p21(ras). The data also suggest that MT dynamics are critical for MT function in yeast cells and that spindle MT assembly and disassembly could be coordinated with other cell-cycle events by regulating beta-tubulin GTPase activity.     

Synthesis in Escherichia coli of GTPase-deficient mutants of Gs alpha

We have reduced the GTPase activity of the alpha subunit of Gs, the guanine nucleotide-binding regulatory protein that stimulates adenylyl cyclase, by introduction of point mutations analogous to those described in p21ras. Mutants G49V and Q227L differ from the wild type protein in the substitution of Val for Gly49 and Leu for Gln227, respectively (analogous to positions 12 and 61 in p21ras). Wild type and mutant proteins were synthesized in Escherichia coli, purified, and characterized. The rate constants for dissociation of GDP from G49V recombinant Gs alpha (rGs alpha) (0.47/min) and Q227L rGs alpha (0.23/min) differ by no more than 2-fold from that observed for the wild type protein (0.5/min). In marked contrast, the rate constants for hydrolysis of GTP by G49V rGs alpha (0.78/min) and Q227L rGs alpha (0.03-0.06/min) are 4-fold and roughly 100-fold slower than that for wild type rGs alpha (3.5/min). These reductions in the rate of hydrolysis of GTP result in significant fractional occupancy of these proteins by GTP in the presence of the nucleotide, 0.37 for G49V rGs alpha and 0.78 for Q227L rGs alpha, compared to 0.05 for wild type rGs alpha. When reconstituted with cyc- (Gs alpha-deficient) S49 cell membranes or purified adenylyl cyclase, both mutant proteins stimulate adenylyl cyclase activity in the presence of GTP to a much greater extent than does wild type Gs alpha; their maximal ability to activate the enzyme is largely unaltered. The fractional ability of a given Gs alpha polypeptide to active adenylyl cyclase in the presence of GTP correlates well with the fractinal occupancy of the protein by the nucleotide. The mutant subunits appear to interact normally with G protein beta gamma subunits, and their ability to activate adenylyl cyclase is enhanced by interaction with beta-adrenergic receptors. These results indicate that the structural analogy that has been inferred between the guanine nucleotide-binding domains of G proteins and the p21ras family is at least generally correct. They also provide confirmation of the kinetic model of G protein function and document mutations that permit the expression in vivo of constitutively activated G protein alpha subunits.     

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.     

Septin collar formation in budding yeast requires GTP binding and direct phosphorylation by the PAK, Cla4

Assembly at the mother-bud neck of a filamentous collar containing five septins (Cdc3, Cdc10, Cdc11, Cdc12, and Shs1) is necessary for proper morphogenesis and cytokinesis. We show that Cdc10 and Cdc12 possess GTPase activity and appropriate mutations in conserved nucleotide-binding residues abrogate GTP binding and/or hydrolysis in vitro. In vivo, mutants unable to bind GTP prevent septin collar formation, whereas mutants that block GTP hydrolysis do not. GTP binding-defective Cdc10 and Cdc12 form soluble heteromeric complexes with other septins both in yeast and in bacteria; yet, unlike wild-type, mutant complexes do not bind GTP and do not assemble into filaments in vitro. Absence of a p21-activated protein kinase (Cla4) perturbs septin collar formation. This defect is greatly exacerbated when combined with GTP binding-defective septins; conversely, the septin collar assembly defect of such mutants is suppressed efficiently by CLA4 overexpression. Cla4 interacts directly with and phosphorylates certain septins in vitro and in vivo. Thus, septin collar formation may correspond to septin filament assembly, and requires both GTP binding and Cla4-mediated phosphorylation of septins.     

Mechanisms of guanosine triphosphate hydrolysis by Ras and Ras-GAP proteins as rationalized by ab initio QM/MM simulations

The hydrolysis reaction of guanosine triphosphate (GTP) by p21(ras) (Ras) has been modeled by using the ab initio type quantum mechanical-molecular mechanical simulations. Initial geometry configurations have been prompted by atomic coordinates of the crystal structure (PDBID: 1QRA) corresponding to the prehydrolysis state of Ras in complex with GTP. Multiple searches of minimum energy geometry configurations consistent with the hydrogen bond networks have been performed, resulting in a series of stationary points on the potential energy surface for reaction intermediates and transition states. It is shown that the minimum energy reaction path is consistent with an assumption of a two-step mechanism of GTP hydrolysis. At the first stage, a unified action of the nearest residues of Ras and the nearest water molecules results in a substantial spatial separation of the gamma-phosphate group of GTP from the rest of the molecule (GDP). This phase of hydrolysis process proceeds through the low barrier (16.7 kcal/mol) transition state TS1. At the second stage, the inorganic phosphate is formed in consequence of proton transfers mediated by two water molecules and assisted by the Gln61 residue from Ras. The highest transition state at this segment, TS3, is estimated to have an energy 7.5 kcal/mol above the enzyme-substrate complex. The results of simulations are compared to the previous findings for the GTP hydrolysis in the Ras-GAP (p21(ras)-p120(GAP)) protein complex. Conclusions of the modeling lead to a better understanding of the anticatalytic effect of cancer causing mutation of Gln61 from Ras, which has been debated in recent years.     

Fluorescence approaches to the study of the p21ras GTPase mechanism

The use of ribose-modified guanine nucleotides and tryptophan mutants of p21ras, neither of which have significant effect on the kinetic mechanism of the p21ras GTPase and the GAP-activated p21ras GTPase, will now allow a detailed kinetic study of how GAP and other regulatory proteins interact with p21ras. This will lead to a better understanding of how the relative concentrations of 'active' p21ras. GTP and 'inactive' p21ras. GDP are regulated in the cell.     

New insights into the role of conserved, essential residues in the GTP binding/GTP hydrolytic cycle of large G proteins

The GTP hydrolytic (GTPase) reaction terminates signaling by both large (heterotrimeric) and small (Ras-related) GTP-binding proteins (G proteins). Two residues that are necessary for GTPase activity are an arginine (often called the "arginine finger") found either in the Switch I domains of the alpha subunits of large G proteins or contributed by the GTPase-activating proteins of small G proteins, and a glutamine that is highly conserved in the Switch II domains of Galpha subunits and small G proteins. However, questions still exist regarding the mechanism of the GTPase reaction and the exact role played by the Switch II glutamine. Here, we have characterized the GTP binding and GTPase activities of mutants in which the essential arginine or glutamine residue has been changed within the background of a Galpha chimera (designated alpha(T)*), comprised mainly of the alpha subunit of retinal transducin (alpha(T)) and the Switch III region from the alpha subunit of G(i1). As expected, both the alpha(T)*(R174C) and alpha(T)*(Q200L) mutants exhibited severely compromised GTPase activity. Neither mutant was capable of responding to aluminum fluoride when monitoring changes in the fluorescence of Trp-207 in Switch II, although both stimulated effector activity in the absence of rhodopsin and Gbetagamma. Surprisingly, each mutant also showed some capability for being activated by rhodopsin and Gbetagamma to undergo GDP-[(35)S]GTPgammaS exchange. The ability of the mutants to couple to rhodopsin was not consistent with the assumption that they contained only bound GTP, prompting us to examine their nucleotide-bound states following their expression and purification from Escherichia coli. Indeed, both mutants contained bound GDP as well as GTP, with 35-45% of each mutant being isolated as GDP-P(i) complexes. Overall, these findings suggest that the R174C and Q200L mutations reveal Galpha subunit states that occur subsequent to GTP hydrolysis but are still capable of fully stimulating effector activity.