gamma-phosphate protonation and pH-dependent unfolding of the Ras.GTP.Mg2+ complex: a vibrational spectroscopy study

The interdependence of GTP hydrolysis and the second messenger functions of virtually all GTPases has stimulated intensive study of the chemical mechanism of the hydrolysis. Despite numerous mutagenesis studies, the presumed general base, whose role is to activate hydrolysis by abstracting a proton from the nucleophilic water, has not been identified. Recent theoretical and experimental work suggest that the gamma-phosphate of GTP could be the general base. The current study investigates this possibility by studying the pH dependence of the vibrational spectrum of the Ras.GTP.Mg(2+) and Ras.GDP.Mg(2+) complexes. Isotope-edited IR studies of the Ras.GTP.Mg(2+) complex show that GTP remains bound to Ras at pH as low as 2.0 and that the gamma-phosphate is not protonated at pH > or = 3.3, indicating that the active site decreases the gamma-phosphate pK(a) by at least 1.1 pK(a) units compared with solution. Amide I studies show that the Ras.GTP.Mg(2+) and Ras.GDP.Mg(2+) complexes partially unfold in what appear to be two transitions. The first occurs in the pH range 5.4-2.6 and is readily reversible. Differences in the pH-unfolding midpoints for the Ras.GTP.Mg(2+) and Ras.GDP.Mg(2+) complexes (3.7 and 4.8, respectively) reveal that the enzyme-gamma-phosphoryl interactions stabilize the structure. The second transition, pH 2.6-1.7, is not readily reversed. The pH-dependent unfolding of the Ras.GTP.Mg(2+) complex provides an alternative interpretation of the data that had been used to support the gamma-phosphate mechanism, thereby raising the issue of whether this mechanism is operative in GTPase-catalyzed GTP hydrolysis reactions.     

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.     

A novel magnesium-dependent mechanism for the activation of transducin by fluoride

Activation of transducin-GDP by NaF is mainly mediated by aluminofluorde or beryllofluoride complexes acting as GTP gamma-phosphate analogs. In millimolar magnesium, NaF at concentrations above 3 mM is active even in the absence of aluminium or beryllium. This activation has a Hill coefficient of 3 with respect to F-, and its rate is linear with respect to Mg2+ concentrations above 2 mM. Upon fluoride dilution, inactivation rate is hundreds of times faster than for aluminofluoride-activated T alpha GDP. We propose that at high NaF concentrations, 3 hydrogen-bonded fluorides in the gamma-phosphate site of T alpha GDP entrap a magnesium counterion and this induces the transconformation to the T alpha GTP form.     

Structure of Gialpha1.GppNHp, autoinhibition in a galpha protein-substrate complex.

The structure of the G protein Gialpha1 complexed with the nonhydrolyzable GTP analog guanosine-5'-(betagamma-imino)triphosphate (GppNHp) has been determined at a resolution of 1.5 A. In the active site of Gialpha1. GppNHp, a water molecule is hydrogen bonded to the side chain of Glu43 and to an oxygen atom of the gamma-phosphate group. The side chain of the essential catalytic residue Gln204 assumes a conformation which is distinctly different from that observed in complexes with either guanosine 5'-O-3-thiotriphosphate or the transition state analog GDP.AlF4-. Hydrogen bonding and steric interactions position Gln204 such that it interacts with a presumptive nucleophilic water molecule, but cannot interact with the pentacoordinate transition state. Gln204 must be released from this auto-inhibited state to participate in catalysis. RGS proteins may accelerate the rate of GTP hydrolysis by G protein alpha subunits, in part, by inserting an amino acid side chain into the site occupied by Gln204, thereby destabilizing the auto-inhibited state of Galpha.     

Interactions of GTP with the ATP-grasp domain of GTP-specific succinyl-CoA synthetase

Two isoforms of succinyl-CoA synthetase exist in mammals, one specific for ATP and the other for GTP. The GTP-specific form of pig succinyl-CoA synthetase has been crystallized in the presence of GTP and the structure determined to 2.1 A resolution. GTP is bound in the ATP-grasp domain, where interactions of the guanine base with a glutamine residue (Gln-20beta) and with backbone atoms provide the specificity. The gamma-phosphate interacts with the side chain of an arginine residue (Arg-54beta) and with backbone amide nitrogen atoms, leading to tight interactions between the gamma-phosphate and the protein. This contrasts with the structures of ATP bound to other members of the family of ATP-grasp proteins where the gamma-phosphate is exposed, free to react with the other substrate. To test if GDP would interact with GTP-specific succinyl-CoA synthetase in the same way that ADP interacts with other members of the family of ATP-grasp proteins, the structure of GDP bound to GTP-specific succinyl-CoA synthetase was also determined. A comparison of the conformations of GTP and GDP shows that the bases adopt the same position but that changes in conformation of the ribose moieties and the alpha- and beta-phosphates allow the gamma-phosphate to interact with the arginine residue and amide nitrogen atoms in GTP, while the beta-phosphate interacts with these residues in GDP. The complex of GTP with succinyl-CoA synthetase shows that the enzyme is able to protect GTP from hydrolysis when the active-site histidine residue is not in position to be phosphorylated.     

Crystal structures of the small G protein Rap2A in complex with its substrate GTP, with GDP and with GTPgammaS.

The small G protein Rap2A has been crystallized in complex with GDP, GTP and GTPgammaS. The Rap2A-GTP complex is the first structure of a small G protein with its natural ligand GTP. It shows that the hydroxyl group of Tyr32 forms a hydrogen bond with the gamma-phosphate of GTP and with Gly13. This interaction does not exist in the Rap2A-GTPgammaS complex. Tyr32 is conserved in many small G proteins, which probably also form this hydrogen bond with GTP. In addition, Tyr32 is structurally equivalent to a conserved arginine that binds GTP in trimeric G proteins. The actual participation of Tyr32 in GTP hydrolysis is not yet clear, but several possible roles are discussed. The conformational changes between the GDP and GTP complexes are located essentially in the switch I and II regions as described for the related oncoprotein H-Ras. However, the mobile segments vary in length and in the amplitude of movement. This suggests that even though similar regions might be involved in the GDP-GTP cycle of small G proteins, the details of the changes will be different for each G protein and will ensure the specificity of its interaction with a given set of cellular proteins.     

Ras catalyzes GTP hydrolysis by shifting negative charges from gamma- to beta-phosphate as revealed by time-resolved FTIR difference spectroscopy

FTIR difference spectroscopy has been used to determine the molecular GTPase mechanism of the small GTP binding protein Ras at the atomic level. The reaction was initiated by the photolysis of caged GTP bound to Ras. The addition of catalytic amounts of the GTPase activating protein (GAP) reduces the measuring time by 2 orders of magnitude but has no influence on the spectra as compared to the intrinsic reaction. The reduced measuring time improves the quality of the data significantly as compared to previously published data [Cepus, V., Scheidig, A., Goody, R. S., and Gerwert, K. (1998) Biochemistry 37, 10263-10271]. The phosphate vibrations are assigned using 18O-labeled caged GTP. In general, there is excellent agreement with the results of Cepus et al., except in the nu(a)(alpha-PO2-) vibration assignments. The assignments reveal that binding of GTP to Ras induces vibrational uncoupling into mainly individual vibrations of the alpha-, beta-, and gamma-phosphate groups. In contrast, for unbound GTP, the phosphate vibrations are highly coupled and the corresponding absorption bands are broader. This result indicates that binding to Ras forces the flexible GTP molecule into a strained conformation and induces a specific charge distribution different from that in the unbound case. The binding causes an unusual frequency downshift of the GTP beta-PO2- phosphate vibration, whereas the alpha-PO2- and gamma-PO3(2-) phosphate vibrations shift to higher wavenumbers. The frequency downshift indicates a lowering of the bond order of the nonbridged P-O bonds of the beta-phosphate group of GTP and GDP. The bond order changes can be explained by a shift of negative charges from the gamma- to the beta-oxygens. Thereby, the GTP charge distribution becomes more like that in GDP. The charge shift appears to be a key factor contributing to catalysis by Ras in addition to the correct positioning of the attacking water. Ras appears to increase the negative charge at the pro-R beta-oxygen mainly by interaction of Mg(2+) and at the pro-S beta-oxygen mainly by interactions of the backbone NHs of Lys 16, Gly 15, and Val 14. The correct positioning of the backbone NHs of Lys 16, Gly 15, and Val 14, and especially the Lys 16 side chain, of the structural highly conserved phosphate binding loop relative to beta-phosphate therefore seems to be important for the catalysis provided by Ras.     

Neutron Crystal Structure of RAS GTPase Puts in Question the Protonation State of the GTP γ-Phosphate

RAS GTPase is a prototype for nucleotide-binding proteins that function by cycling between GTP and GDP, with hydrogen atoms playing an important role in the GTP hydrolysis mechanism. It is one of the most well studied proteins in the superfamily of small GTPases, which has representatives in a wide range of cellular functions. These proteins share a GTP-binding pocket with highly conserved motifs that promote hydrolysis to GDP. The neutron crystal structure of RAS presented here strongly supports a protonated γ-phosphate at physiological pH. This counters the notion that the phosphate groups of GTP are fully deprotonated at the start of the hydrolysis reaction, which has colored the interpretation of experimental and computational data in studies of the hydrolysis mechanism. The neutron crystal structure presented here puts in question our understanding of the pre-catalytic state associated with the hydrolysis reaction central to the function of RAS and other GTPases.     

Differential effects of magnesium on tubulin-nucleotide interactions

Magnesium-depleted 2-(N-morpholino)ethanesulfonate (Mes), glutamate, tubulin and microtubule-associated proteins were prepared and used to study the effects of exogenously added MgCl2 on tubulin-nucleotide interactions in 0.1 M Mes with microtubule-associated proteins and in 1.0 M glutamate. Endogenous levels of Mg2+ in the systems studied were approximately stoichiometric with the tubulin concentrations and largely derived from the tubulin. We examined the effects of added Mg2+ on tubulin polymerization, GDP inhibition of polymerization, binding of GDP and GTP to tubulin, and GTP hydrolysis. Exogenously added Mg2+ had markedly different effects on these reactions. The order of their sensitivity for a requirement for added Mg2+ was as follows: GTP binding greater than GTP hydrolysis greater than polymerization greater than GDP binding. Inhibition of polymerization by GDP varied inversely with the Mg2+ concentration and was greatest in the absence of the cation. These results indicate that GDP and GDP-Mg2+ interact with similar affinity at the exchangeable site, while GTP-Mg2+ has a higher affinity for tubulin than does free GTP. Nevertheless, under appropriate conditions, free GTP can interact sufficiently well with tubulin to permit both nucleation and elongation reactions.     

Crystallographic evidence for substrate-assisted GTP hydrolysis by a small GTP binding protein

GTP hydrolysis by small GTP binding proteins of the Ras superfamily is a universal reaction that controls multiple cellular regulations. Its enzymic mechanism has been the subject of long-standing debates as to the existence/identity of the general base and the electronic nature of its transition state. Here we report the high-resolution crystal structure of a small GTP binding protein, Rab11, solved in complex with GDP and Pi. Unexpectedly, a Pi oxygen and the GDP-cleaved oxygen are located less than 2.5 A apart, suggesting that they share a proton, likely in the form of a low-barrier hydrogen bond. This implies that the gamma-phosphate of GTP was protonated; hence, that GTP acts as a general base. Furthermore, this interaction should establish at, and stabilize, the transition state. Altogether, we propose a revised model for the GTPase reaction that should reconcile earlier models into a unique substrate-assisted mechanism.     

Hydrogen bond interactions of G proteins with the guanine ring moiety of guanine nucleotides.

We have utilized Raman difference spectroscopy to investigate hydrogen bonding interactions of the guanine moiety in guanine nucleotides with the binding site of two G proteins, EF-Tu (elongation factor Tu from Escherichia coli) and the c-Harvey ras protein, p21 (the gene product of the human c-H-ras proto-oncogene). Raman spectra of proteins complexed with GDP (guanosine 5' diphosphate), IDP (inosine 5' diphosphate), 6-thio-GDP, and 6-18O-GDP were measured, and the various difference spectra were determined. These were compared to the difference spectra obtained in solution, revealing vibrational features of the nucleotide that are altered upon binding. Specifically, we observed significant frequency shifts in the vibrational modes associated with the 6-keto and 2-amino positions of the guanine group of GDP and IDP that result from hydrogen bonding interactions between these groups and the two proteins. These shifts are interpreted as being proportional to the local energy of interaction (delta H) between the two groups and protein residues at the nucleotide binding site. Consistent with the tight binding between the nucleotides and the two proteins, the shifts indicate that the enthalpic interactions are stronger between these two polar groups and protein than with water. In general, the spectral shifts provide a rationale for the stronger binding of GDP and IDP with p21 compared to EF-Tu. Despite the structural similarity of the binding sites of EF-Tu and p21, the strengths of the observed hydrogen bonds at the 6-keto and 2-amino positions vary substantially, by up to a factor of 2.(ABSTRACT TRUNCATED AT 250 WORDS)     

Direct incorporation of guanosine 5'-diphosphate into microtubules without guanosine 5'-triphosphate hydrolysis

Using highly purified calf brain tubulin bearing [8-14C]guanosine 5'-diphosphate (GDP) in the exchangeable nucleotide site and heat-treated microtubule-associated proteins (both components containing negligible amounts of nucleoside diphosphate kinase and nonspecific phosphatase activities), we have found that a significant proportion of exchangeable-site GDP in microtubules can be incorporated directly during guanosine 5'-triphosphate (GTP) dependent polymerization of tubulin, without an initial exchange of GDP for GTP and subsequent GTP hydrolysis during assembly. The precise amount of GDP incorporated directly into microtubules is highly dependent on specific reaction conditions, being favored by high tubulin concentrations, low GTP and Mg2+ concentrations, and exogenous GDP in the reaction mixture. Minimum effects were observed with changes in reaction pH or temperature, changes in concentration of microtubule-associated proteins, alteration of the sulfonate buffer, or the presence of a calcium chelator in the reaction mixture. Under conditions most favorable for direct GDP incorporation, about one-third of the GDP in microtubules is incorporated directly (without GTP hydrolysis) and two-thirds is incorporated hydrolytically (as a consequence of GTP hydrolysis). Direct incorporation of GDP occurs in a constant proportion throughout elongation, and the amount of direct incorporation probably reflects the rapid equilibration of GDP and GTP at the exchangeable site that occurs before the onset of assembly.     

Quantum chemical modeling of the GTP hydrolysis by the RAS–GAP protein complex

We present results of the modeling for the hydrolysis reaction of guanosine triphosphate (GTP) in the RAS–GAP protein complex using essentially ab initio quantum chemistry methods. One of the approaches considers a supermolecular cluster composed of 150 atoms at a consistent quantum level. Another is a hybrid QM/MM method based on the effective fragment potential technique, which describes interactions between quantum and molecular mechanical subsystems at the ab initio level of the theory. Our results show that the GTP hydrolysis in the RAS–GAP protein complex can be modeled by a substrate-assisted catalytic mechanism. We can locate a configuration on the top of the barrier corresponding to the transition state of the hydrolysis reaction such that the straightforward descents from this point lead either to reactants GTP+H₂O or to products guanosine diphosphate (GDP)+H₂PO₄^?. However, in all calculations such a single-step process is characterized by an activation barrier that is too high. Another possibility is a two-step reaction consistent with formation of an intermediate. Here the Pγ-O(Pβ) bond is already broken, but the lytic water molecule is still in the pre-reactive state. We present arguments favoring the assumption that the first step of the GTP hydrolysis reaction in the RAS–GAP protein complex may be assigned to the breaking of the Pγ-O(Pβ) bond prior to the creation of the inorganic phosphate.     

The GTP-binding protein of rod outer segments. II. An essential role for Mg2+ in signal amplification

The role of Mg2+ in the GTP hydrolytic cycle was investigated by using purified subunits (G alpha and G beta, gamma) of the GTP-binding protein isolated from Bufo marinus rod outer segments (ROS). Mg2+ markedly stimulated the rate of GTP and guanosine-5'-O-(3-thiotriphosphate) (GTP gamma-s) binding to G alpha. This effect was especially striking in the presence of very small quantities of illuminated ROS disc membranes. GTP hydrolysis could occur in the absence of Mg2+, and Mg2+ increased the rate of GTP hydrolysis only about 50%. These data indicate that Mg2+ plays a fundamental role in amplification of the photon signal by markedly stimulating the rate of formation of GTP X G alpha complexes by very small amounts of illuminated rhodopsin while producing only a modest increase in the rate of GTP hydrolysis. Following hydrolysis of GTP, GDP X G alpha could reassociate with illuminated or unilluminated ROS disc membranes in the presence or absence of Mg2+. In the absence of guanine nucleotides, release of GDP from G alpha bound to illuminated disc membranes was detected in the presence or absence of Mg2+. Moreover, Mg2+ did not affect the rate of GDP release from membrane-bound G alpha. Illumination of B. marinus crude ROS disc membrane preparations markedly reduced pertussis toxin-mediated ADP-ribosylation of a 39,000 Mr (G alpha) protein in the presence but not in the absence, of Mg2+. Moreover, extensive dialysis of illuminated (but not unilluminated) crude ROS disc membranes against a Mg2+-containing buffer caused a marked reduction in the subsequent ADP-ribosylation of G alpha, even when Mg2+ was not present during the ADP-ribosylation step. This reduction was reversed by the addition of GDP or a GDP analogue (but not GMP or hydrolysis-resistant GTP analogues) during the ADP-ribosylation step. Dialysis of crude ROS disc membrane preparations (illuminated or unilluminated) against a Mg2+ -free buffer did not reduce the subsequent ADP-ribosylation of G alpha. These data indicate that Mg2+, in the presence of photolysed rhodopsin, can stimulate the release of GDP from crude preparations of ROS disc membranes. Four lines of evidence suggest that G alpha and G beta, gamma have Mg2+-binding site(s). When stored at 4 degrees C, in the absence of glycerol, G beta, gamma was more stable in the absence than in the presence of Mg2+.(ABSTRACT TRUNCATED AT 400 WORDS)     

Intragenic suppressor mutations restore GTPase and translation functions of a eukaryotic initiation factor 5B switch II mutant

Structural studies of GTP-binding proteins identified the Switch I and Switch II elements as contacting the gamma-phosphate of GTP and undergoing marked conformational changes upon GTP versus GDP binding. Movement of a universally conserved Gly at the N terminus of Switch II is thought to trigger the structural rearrangement of this element. Consistently, we found that mutation of this Gly in the Switch II element of the eukaryotic translation initiation factor 5B (eIF5B) from Saccharomyces cerevisiae impaired cell growth and the guanine nucleotide-binding, GTPase, and ribosomal subunit joining activities of eIF5B. In a screen for mutations that bypassed the critical requirement for this Switch II Gly in eIF5B, intragenic suppressors were identified in the Switch I element and at a residue in domain II of eIF5B that interacts with Switch II. The intragenic suppressors restored yeast cell growth and eIF5B nucleotide-binding, GTP hydrolysis, and subunit joining activities. We propose that the Switch II mutation distorts the geometry of the GTP-binding active site, impairing nucleotide binding and the eIF5B domain movements associated with GTP binding. Accordingly, the Switch I and domain II suppressor mutations induce Switch II to adopt a conformation favorable for nucleotide binding and hydrolysis and thereby reestablish coupling between GTP binding and eIF5B domain movements.     

Essential role of histidine 84 in elongation factor Tu for the chemical step of GTP hydrolysis on the ribosome

Elongation factor Tu (EF-Tu) is a GTP-binding protein that delivers aminoacyl-tRNA to the A site of the ribosome during protein synthesis. The mechanism of GTP hydrolysis in EF-Tu on the ribosome is poorly understood. It is known that mutations of a conserved histidine residue in the switch II region of the factor, His84 in Escherichia coli EF-Tu, impair GTP hydrolysis. However, the partial reaction which is directly affected by mutations of His84 was not identified and the effect on GTP hydrolysis was not quantified. Here, we show that the replacement of His84 with Ala reduces the rate constant of GTP hydrolysis more than 10(6)-fold, whereas the preceding steps of ternary complex binding to the ribosome, codon recognition and, most importantly, the GTPase activation step are affected only slightly. These results show that His84 plays a key role in the chemical step of GTP hydrolysis. Rate constants of GTP hydrolysis by wild-type EF-Tu, measured using the slowly hydrolyzable GTP analog, GTPgammaS, showed no dependence on pH, indicating that His84 does not act as a general base. We propose that the catalytic role of His84 is to stabilize the transition state of GTP hydrolysis by hydrogen bonding to the attacking water molecule or, possibly, the gamma-phosphate group of GTP.     

Novel protein and Mg2+ configurations in the Mg2+GDP complex of the SRP GTPase ffh

Ffh is the signal sequence recognition and targeting subunit of the prokaryotic signal recognition particle (SRP). Previous structural studies of the NG GTPase domain of Ffh demonstrated magnesium-dependent and magnesium-independent binding conformations for GDP and GMPPNP that are believed to reflect novel mechanisms for exchange and activation in this member of the GTPase superfamily. The current study of the NG GTPase bound to Mg(2+)GDP reveals two new binding conformations-in the first the magnesium interactions are similar to those seen previously, however, the protein undergoes a conformational change that brings a conserved aspartate into its second coordination sphere. In the second, the protein conformation is similar to that seen previously, but the magnesium coordination sphere is disrupted so that only five oxygen ligands are present. The loss of the coordinating water molecule, at the position that would be occupied by the oxygen of the gamma-phosphate of GTP, is consistent with that position being privileged for exchange during phosphate release. The available structures of the GDP-bound protein provide a series of structural snapshots that illuminate steps along the pathway of GDP release following GTP hydrolysis.     

Guanine nucleotide binding properties of rap1 purified from human neutrophils.

The guanine nucleotide binding properties of rap1 protein purified from human neutrophils were examined using both the protein kinase A-phosphorylated and the non-phosphorylated forms of the protein. Binding of GTP[S] (guanosine 5'-[gamma-thio]triphosphate) or GDP was found to be slow in the presence of free Mg2+, but very rapid in the absence of Mg2+. The binding of guanine nucleotides was found to correlate with the loss of endogenous nucleotide from the rap1 protein, which was rapid in the absence of Mg2+. The relative affinities of GTP and GDP for the binding site on rap1 were modulated by the presence of Mg2+, with a preferential affinity (approx. 15-fold) for GTP observed only in the absence of this bivalent cation. The dissociation of GDP from rap1 was not affected by the G-protein beta/gamma-subunit complex. Phosphorylation of rap1 in vitro by protein kinase A did not modify any of the observed nucleotide-binding parameters. Furthermore, the ability of a cytosolic rap1 GTPase-activating protein to stimulate neutrophil rap1 GTP hydrolysis was not modified by phosphorylation. These data suggest that the activation of rap in vivo may be regulated by the release of endogenous GDP, but that phosphorylation by protein kinase A does not affect guanine nucleotide binding or hydrolysis.     

The interactions of cell division protein FtsZ with guanine nucleotides

Prokaryotic cell division protein FtsZ, an assembling GTPase, directs the formation of the septosome between daughter cells. FtsZ is an attractive target for the development of new antibiotics. Assembly dynamics of FtsZ is regulated by the binding, hydrolysis, and exchange of GTP. We have determined the energetics of nucleotide binding to model apoFtsZ from Methanococcus jannaschii and studied the kinetics of 2'/3'-O-(N-methylanthraniloyl) (mant)-nucleotide binding and dissociation from FtsZ polymers, employing calorimetric, fluorescence, and stopped-flow methods. FtsZ binds GTP and GDP with K(b) values ranging from 20 to 300 microm(-1) under various conditions. GTP.Mg(2+) and GDP.Mg(2+) bind with slightly reduced affinity. Bound GTP and the coordinated Mg(2+) ion play a minor structural role in FtsZ monomers, but Mg(2+)-assisted GTP hydrolysis triggers polymer disassembly. Mant-GTP binds and dissociates quickly from FtsZ monomers, with approximately 10-fold lower affinity than GTP. Mant-GTP displacement measured by fluorescence anisotropy provides a method to test the binding of any competing molecules to the FtsZ nucleotide site. Mant-GTP is very slowly hydrolyzed and remains exchangeable in FtsZ polymers, but it becomes kinetically stabilized, with a 30-fold slower k(+) and approximately 500-fold slower k(-) than in monomers. The mant-GTP dissociation rate from FtsZ polymers is comparable with the GTP hydrolysis turnover and with the reported subunit turnover in Escherichia coli FtsZ polymers. Although FtsZ polymers can exchange nucleotide, unlike its eukaryotic structural homologue tubulin, GDP dissociation may be slow enough for polymer disassembly to take place first, resulting in FtsZ polymers cycling with GTP hydrolysis similarly to microtubules.     

QM/MM modeling the Ras-GAP catalyzed hydrolysis of guanosine triphosphate

The mechanism of the hydrolysis reaction of guanosine triphosphate (GTP) by the protein complex Ras-GAP (p21(ras) - p120(GAP)) has been modeled by the quantum mechanical-molecular mechanical (QM/MM) and ab initio quantum calculations. Initial geometry configurations have been prompted by atomic coordinates of a structural analog (PDBID:1WQ1). It is shown that the minimum energy reaction path is consistent with an assumption of two-step chemical transformations. At the first stage, a unified motion of Arg789 of GAP, Gln61, Thr35 of Ras, and the lytic water molecule 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 transition state TS1. At the second stage, Gln61 abstracts and releases protons within the subsystem including Gln61, the lytic water molecule and the gamma-phosphate group of GTP through the corresponding transition state TS2. Direct quantum calculations show that, in this particular environment, the reaction GTP + H(2)O --> GDP + H(2)PO(4) (-) can proceed with reasonable activation barriers of less than 15 kcal/mol at every stage. This conclusion leads to a better understanding of the anticatalytic effect of cancer-causing mutations of Ras, which has been debated in recent years.