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

Giardia gene predicts a 183 kDa nucleotide-binding head-stalk protein

Previously described extended proteins from the cytoskeleton of Giardia lamblia (beta-giardin, median body protein) have been found to be segmented coiled coils with regular structural repeat patterns in their amino acid sequences. Screening a lambda ZAPII library derived from Giardia genomic DNA with an antibody directed against a 34 × 10(3) M(r) giardin isoform selected a gene encoding a much larger polypeptide chain (HPSR2), the sequence of which was determined by chromosome walking the open reading frame. The complete gene has been cloned and expressed as a recombinant protein of 183 × 10(3) M(r). The predicted amino acid sequence of the protein has identifiable features suggesting that it might be a motor protein with an amino-terminal hydrolytic domain attached to a long coiled coil stalk. The presumed head domain is 211 residues and contains a P-loop sequence conserved in purine nucleotide-binding proteins. The remaining 1409 amino acids mainly make up a region of heptad repeats such as in myosin or the kinesin stalk, ending in a small (67 amino acids) carboxy-terminal domain. Fourier analysis of the predicted stalk shows the presence of a strong physical repeat created by regular heptad phase changes dividing the coil into segments of 25 residues. This structure most closely resembles the smaller microtubule-associated median body protein which has segments of 24 residues.

Switching nucleotide specificity of Ha-Ras p21 by a single amino acid substitution at aspartate 119

We examined c-Ha-Ras harboring an aspartate to asparagine substitution at position 119 (mutation D119N). The Asp-119 is part of the conserved NKXD motif shared by members of the regulatory GTPase family. This asparagine residue has been proposed to participate in direct bonding to the guanine ring and to determine the guanine-nucleotide binding specificity. The D119N mutation was found to alter nucleotide specificity of Ha-Ras from guanine to xanthine, an observation that directly supports the essential role of hydrogen bonding between the side chain of the aspartic acid residue and the guanine ring in nucleotide binding specificity. Besides nucleotide binding specificity, the D119N mutation has little or no effect on the interaction of Ha-Ras with SDC25C, SOS1, GAP, or Raf. Neither does it affect the hydrolysis of nucleotide triphosphate. Like xanthine-nucleotide-specific EF-Tu, xanthine-nucleotide-specific Ras and related proteins will be useful tools for elucidating cellular systems containing multiple regulatory GTPases.

Crystal structure of the nuclear Ras-related protein Ran in its GDP-bound form

The Ran proteins constitute a distinct branch of the superfamily of Ras-related GTP-binding proteins which function as molecular switches cycling between GTP-bound 'on' and GDP-bound 'off' states. Ran is located predominantly in the nucleus of eukaryotic cells and is involved in the nuclear import of proteins as well as in control of DNA synthesis and of cell-cycle progression. We report here the crystal structure at 2.3 A resolution of human Ran (Mr 24K) complexed with GDP and Mg2+. This structure reveals a similarity with the Ras core (G-domain) but with significant variations in regions involved in GDP and Mg2+ coordination (switch I and switch II regions in Ras), suggesting that there could be major conformational changes upon GTP binding. In addition to the G-domain, an extended chain and an alpha-helix were identified at the carboxy terminus. The amino-terminal (amino-acid residues MAAQGEP) stretch and the acidic tail (DEDDDL) appear to be flexible in the crystal structure.

Purification and crystallization of the ternary complex of elongation factor Tu:GTP and Phe-tRNA(Phe)

Elongation factor Tu (EF-Tu) is the most abundant protein in prokaryotic cells. Its general function in protein biosynthesis is well established. It is a member of the large family of G-proteins, all of which bind guanosine phosphates (GDP or GTP) as cofactors. In its active GTP bound state EF-Tu binds aminoacylated tRNA (aa-tRNA) forming the ternary complex EF-Tu:GTP:aa-tRNA. The ternary complex interacts with the ribosome where the anticodon on tRNA recognises a codon on mRNA, GTPase activity is induced and inactive EF-Tu:GDP is released. Here we report the successful crystallization of a ternary complex of Thermus aquaticus EF-Tu:GDPNP and yeast Phe-tRNA(Phe) after its purification by HPLC.

Structure of the human ADP-ribosylation factor 1 complexed with GDP

ADP-ribosylation factors (ARFs) are essential and ubiquitous in eukaryotes, being involved in vesicular transport and functioning as an activator of phospholipase D (refs 1, 2) and cholera toxin. The functions of ARF proteins in membrane traffic and organelle integrity are intimately tied to its reversible association with membranes and specific interactions with membrane phospholipids. One common feature of these functions is their regulation by the binding and hydrolysis of GTP. Here we report the three-dimensional structure of full-length human ARF1 (M(r) 21,000) in its GDP-bound non-myristoylated form. The presence of a unique amino-terminal alpha-helix and loop, together with differences in Mg2+ ligation and the existence of a non-crystallographic dimer, set this structure apart from other GTP-binding proteins. These features provide a structural basis for the GTP-dependent modulation of membrane affinity, the lack of intrinsic GTPase activity, and the nature of effector binding surfaces.

Structural determinants of substrate selection by the human insulin-receptor protein-tyrosine kinase

Using NMR spectroscopy to visualise tyrosine phosphorylation kinetics in real time, we have investigated the sequence-dependent determinants of the selectivity of the human insulin receptor protein-tyrosine kinase for different tyrosine residues. The peptides used encompass the multiple-tyrosine-containing autophosphorylation site sequences from the insulin receptor kinase core domain (Tyr1158, Tyr1162 and Tyr1163) and from its specific C-terminal tail domain (Tyr1328 and Tyr1334). Comparison of the phosphorylation kinetics with those found for the tyrosine residues on a peptide comprising the regulatory tyrosine phosphorylation site of cdc2 points to the role of the primary sequence context of the phosphate acceptor. The particularly deleterious influence of a basic residue immediately C-terminal to the tyrosine is discussed in relation to the autophosphorylation properties of the regulatory loop regions of the insulin and epidermal growth factor receptor kinases. The data further suggest that receptor tyrosine kinase active sites and their substrate targets act in concert to ensure that specific downstream effects are activated.

The closed conformation of a highly flexible protein: the structure of E. coli adenylate kinase with bound AMP and AMPPNP

The structure of E. coli adenylate kinase with bound AMP and AMPPNP at 2.0 A resolution is presented. The protein crystallizes in space group C2 with two molecules in the asymmetric unit, and has been refined to an R factor of 20.1% and an Rfree of 31.6%. In the present structure, the protein is in the closed (globular) form with the large flexible lid domain covering the AMPPNP molecule. Within the protein, AMP and AMPPNP, and ATP analog, occupy the AMP and ATP sites respectively, which had been suggested by the most recent crystal structure of E. coli adenylate kinase with Ap5A bound (Müller and Schulz, 1992, ref. 1) and prior fluorescence studies (Liang et al., 1991, ref. 2). The binding of substrates and the positions of the active site residues are compared between the present structure and the E. coli adenylate kinase/Ap5A structure. We failed to detect a peak in the density map corresponding to the Mg2+ ion which is required for catalysis, and its absence has been attributed to the use of ammonium sulfate in the crystallization solution. Finally, a comparison is made between the present structure and the structure of the heavy chain of muscle myosin.

Coupling between catalytic sites and the proton channel in F1F0-type ATPases

F1F0-type ATPases catalyse both ATP-driven proton translocation and proton-gradient-driven ATP synthesis. Recent cryoelectronmicroscopy and low-resolution X-ray studies provide a first glimpse at the structure of this complicated membrane-bound enzyme. The F1 part is roughly globular and linked to the membrane-intercalated F0 part by a narrow stalk domain, which contains the gamma-, delta- and epsilon-subunits along with domains of the b-subunit of the F0 part. Here, we review evidence that conformational and positional changes in the gamma- and epsilon-subunits provide the coupling between catalytic sites and proton translocation within the F1F0 complex.

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.

The functions and consensus motifs of nine types of peptide segments that form different types of nucleotide-binding sites

From an analysis of current data on 16 protein structures with defined nucleotide-binding sites consensus motifs were determined for the peptide segments that form such nucleotide-binding sites. This was done by using the actual residues shown to contact ligands in the different protein structures, plus an additional 50 sequences for various kinases. Three peptide segments are commonly required to form the binding site for ATP or GTP. Binding motif Kinase-1a is found in almost all sequences examined, and functions in binding the phosphates of the ligand. Variant versions, comparable to Kinase-1a, are found in a subset of proteins and appear to be related to unique functions of those enzymes. Motif Kinase-2 contains the conserved aspartate that coordinates the metal ion on Mg-ATP. Motif Kinase-3 occurs in at least four versions, and functions in binding the purine base or the pentose. Two protein structures show ATP-binding at a separate regulatory site, formed by the motifs Regulatory-1 and Regulatory-2. Structures for adenylate kinase and guanylate kinase show three different sequence motifs that form the binding site for a nucleoside monophosphate (NMP). NMP-1 and NMP-2 bind to the pentose and phosphate of the bound ligand. NMP-1 is found in almost all the kinases that phosphorylate AMP, CMP, GMP, dTMP, or UMP. NMP-3a is found in kinases for AMP, GMP, and UMP, while NMP-3b binds only GMP. For the binding of NTPs, three distinct types of nucleotide-binding fold structures have been described. Each structure is associated with a particular function (e.g. transfer of the gamma-phosphate, or of the adenylate to an acceptor) and also with a particular spatial arrangement of the three Kinase segments evident in the linear sequence for the protein.

Comparison of the low energy conformations of an oncogenic and a non-oncogenic p21 protein, neither of which binds GTP or GDP

Oncogenic p21 protein, encoded by the ras-oncogene, that causes malignant transformation of normal cells and many human tumors, is almost identical in sequence to its normal protooncogene-encoded counterpart protein, except for the substitution of arbitrary amino acids for the normally occurring amino acids at critical positions such as Gly 12 and Gln 61. Since p21 is normally activated by the binding of GTP in place of GDP, it has been postulated that oncogenic forms must retain bound GTP for prolonged time periods. However, two multiply substituted p21 proteins have been cloned, neither of which binds GDP or GTP. One of these mutant proteins with Val for Gly 10, Arg for Gly 12, and Thr for Ala 59 causes cell transformation, while the other, similar protein with Gly 10, Arg 12, Val for Gly 13 and Thr 59 does not transform cells. To define the critical conformational changes that occur in the p21 protein that cause it to become oncogenic, we have calculated the low energy conformations of the two multiply substituted mutant p21 proteins using a new adaptation of the electrostatically driven Monte Carlo (EDMC) technique, based on the program ECEPP. We have used this method to explore the conformational space available to both proteins and to compute the average structures for both using statistical mechanical averaging. Comparison of the average structures allows us to detect the major differences in conformation between the two proteins. Starting structures for each protein were calculated using the recently deposited x-ray crystal coordinates for the p21 protein, that was energy-refined using ECEPP, and then perturbed using the EDMC method to compute its average structure. The specific amino acid substitutions for both proteins were then generated into the lowest energy structure generated by this procedure, subjected to energy minimization and then to full EDMC perturbations. We find that both mutant proteins exhibit major differences in conformation in specific regions, viz., residues 35-47, 55-78, 81-93, 96-110, 115-126, and 123-134, compared with the EDMC-refined x-ray structure of the wild-type protein. These regions have been found to be the most flexible in the p21 protein bound to GDP from prior molecular dynamics calculations (Dykes et al., 1993). Comparison of the EDMC-average structure of the transforming mutant with that of the nontransforming mutant reveals major structural differences at residues 10-16, 32-40, and 60-68. These structural differences appear to be the ones that are critical in activation of the p21 protein.(ABSTRACT TRUNCATED AT 400 WORDS)

Nitrogenase and biological nitrogen fixation

Biological nitrogen fixation is catalyzed by the nitrogenase enzyme system which consists of two metalloproteins, the iron (Fe-) protein and the molybdenum-iron (MoFe-) protein. Together, these proteins mediate the ATP-dependent reduction of dinitrogen to ammonia. Recent crystallographic analyses of Fe-protein and MoFe-protein have revealed the polypeptide fold and the structure and organization of the unusual metal centers in nitrogenase. These structure provide a molecular framework for addressing the mechanism of the nitrogenase-catalyzed reaction. General features of the nitrogenase system, including conformational coupling of nucleotide hydrolysis, aspects of the cluster structures, and the general spatial organization of redox centers within the protein subunits, are relevant to a wide range of biochemical systems.

Site-directed mutagenesis, fluorescence, and two-dimensional NMR studies on microenvironments of effector region aromatic residues of human c-Ha-Ras protein

The Tyr residues in positions 32 and 40 of human c-Ha-Ras protein were replaced by site-directed mutagenesis (Y32F, Y32W, Y40K, and Y40W) to examine their roles in the signal-transducing activity and the sensitivity to the GTPase activating protein (GAP). The signal-transducing activity of the oncogenic Ras protein in PC12 cells was lost upon mutations Y32F and Y40K, but retained upon mutations Y32W and Y40W. These results suggest that residues 32 and 40 are both required to have aromatic groups and residue 32 is further required to have a hydrogen donor. On the other hand, three mutations (Y32F, Y32W, and Y40W) caused no appreciable reduction in either GAP-binding affinity or GAP sensitivity. By the Y40K mutation, GAP-binding affinity was slightly lowered, while GAP sensitivity was drastically impaired. Therefore, for residues 32 and 40 of Ras, interactions with GAP appear to be different from those with the target of signal transduction in the PC12 cell. As for the Y32W-Ras protein bound with an unhydrolyzable GTP analogue (GMPPNP), the Trp32 fluorescence is appreciably red-shifted, weaker, and more susceptible to KI quenching as compared to that of the GDP-bound form. Two-dimensional NMR spectroscopy with selectively deuterated Ras proteins revealed fewer and weaker nuclear Overhauser effects on the aromatic protons of Trp32 in the GMPPNP-bound form than in the GDP-bound form. This indicates that the side chain of Trp32 is more exposed to the solvent in the GMPPNP-bound form than in the GDP-bound form.(ABSTRACT TRUNCATED AT 250 WORDS)

Molecular dynamics of the H-ras gene-encoded p21 protein; identification of flexible regions and possible effector domains

We previously reported a complete computer-based three-dimensional structure for residues 1-171 of the Gly 12-containing ras-gene-encoded p21 protein complexed with GDP. This structure was subsequently shown to closely agree with a high-resolution x-ray crystallographic structure of p21. In this communication, we report a molecular dynamics stimulation of the modelled structure in an explicit shell of water molecules to identify domains within the protein that are unusually flexible. These domains represent regions which are most likely to undergo important conformational changes when the protein is activated by binding to GTP or by oncogenic amino acid substitutions such as Val for Gly 12. The starting structure was surrounded with water molecules, temperature-equilibrated and then followed over a 100 ps trajectory during which time the energy converged after about 50 ps. Regions of the protein that were found to have the largest coordinate fluctuations involved residues 12-16, 30-35, 40-52, 60-73, 85-89, 101-109, 119-123, and 127-131. Many of these sequences with high flexibility have been implicated in the functioning of this protein. Since the overall largest fluctuations were observed for residues 101-106 and 119-123, p21 peptides containing these residues (96-110 and 115-126) were synthesized and were found to inhibit strongly the effects of oncogenic p21 protein in an oocyte maturation assay. These results indicate that the flexible p21 sequences may constitute critical functional domains of the activated protein and that this general approach may be useful for identification of important functional domains in proteins.

GTP-dependent association of Raf-1 with Ha-Ras: identification of Raf as a target downstream of Ras in mammalian cells

Ras is involved in signal transduction of various factors for growth, differentiation, and oncogenesis. Recent studies have revealed several proteins that function upstream and downstream of the Ras signaling pathway. However, its immediate downstream target molecular has not yet been identified. In an effort to identify the Ras-associated downstream proteins, we added recombinant Ha-Ras in a GTP-bound form to cell-free lysates and used several antibodies against Ras to immunoprecipitate Ras complexes. We found that a serine/threonine kinase, Raf-1, was coimmunoprecipitated with Ha-Ras by two anti-Ras antibodies (LA069 and Y13-238), whereas a neutralizing antibody against Ras (Y13-259) could not precipitate Raf-1. The coimmunoprecipitation was observed with a complex of Ras and guanosine 5'-[gamma- thio]triphosphate but not with a complex of Ras and guanosine 5'-[beta-thio]diphosphate. The GTP-dependent association of Ha-Ras with Raf-1 was observed with lysates of various types of cultured cells, including NIH 3T3, pheochromocytoma (PC) 12, Ba/F3, and Jurkat T cells, and also with crude extracts from rat brain. Furthermore, Raf-1 was precipitated with a transforming Ha-Ras mutant ([Val12]Ras) and wild-type Ha-Ras but not with an effector-region mutant ([Leu35,ARg37]Ras) that lacks transforming activity. These results indicate that Ras.GTP physically associates with Raf either directly or through other component(s) and strongly suggest that Raf functions in close downstream proximity to Ras in mammalian cells.

The crystal structure of elongation factor EF-Tu from Thermus aquaticus in the GTP conformation

BACKGROUND

Elongation factor Tu (EF-Tu) is a GTP-binding protein that is crucial for protein biosynthesis. In the GTP form of the molecule, EF-Tu binds tightly to aminoacyl-tRNA, forming a ternary complex that interacts with the ribosomal acceptor site. During this interaction, GTP is hydrolyzed, and EF-Tu.GDP is ejected.

RESULTS

The crystal structure of EF-Tu from Thermus aquaticus, complexed to the GTP analogue GDPNP, has been determined at 2.5 A resolution and compared to the structure of Escherichia coli EF-Tu.GDP. During the transition from the GDP (inactive) to the GTP (active) form, domain 1, containing the GTP-binding site, undergoes internal conformational changes similar to those observed in ras-p21. In addition, a dramatic rearrangement of domains is observed, corresponding to a rotation of 90.8 degrees of domain 1 relative to domains 2 and 3. Residues that are affected in the binding of aminoacyl-tRNA are found in or near the cleft formed by the domain interface.

CONCLUSION

GTP binding by EF-Tu leads to dramatic conformational changes which expose the tRNA binding site. It appears that tRNA binding to EF-Tu induces a further conformational change, which may affect the GTPase activity.

Crystal structure of active elongation factor Tu reveals major domain rearrangements

The crystal structure of intact elongation factor Tu (EF-Tu) from Thermus thermophilus has been determined and refined at an effective resolution of 1.7 A, with incorporation of data extending to 1.45 A. The effector region, including interaction sites for the ribosome and for transfer RNA, is well defined. Molecular mechanisms are proposed for transduction and amplification of the signal induced by GTP binding as well as for the intrinsic and effector-enhanced GTPase activity of EF-Tu. Comparison of the structure with that of EF-Tu-GDP reveals major mutual rearrangements of the three domains of the molecule.

Mechanism of GTP hydrolysis by p21N-ras catalyzed by GAP: studies with a fluorescent GTP analogue

The mechanism of the hydrolysis of GTP by p21N-ras and its activation by the catalytic domain of p120 GTPase activating protein (GAP) have been studied using a combination of chemical and fluorescence measurements with the fluorescent GTP analogue, 2'(3')-O-(N-methylanthraniloyl)GTP (mantGTP). Since the concentration of active p21 is important in these measurements, various assays for both total protein and active p21 were investigated. All assays gave good agreement except the filter binding assay of [3H]-GDP bound to p21, which gave values of 35-40% compared to the other methods. Concentrations of p21 were thus based on the absorbance of the mant-chromophore of the p21-mant-nucleotide complexes. The rate constants of the elementary steps of the p21 intrinsic GTPase activity and the GAP activated activity were similar between GTP and mantGTP. Incubation of a stoichiometric complex of p21.mantGTP results in a biphasic decrease in fluorescence. The second phase occurs with the same rate constant as the cleavage step and is accelerated by GAP. No other steps of the mechanism are affected by GAP. Incubation of a stoichiometric complex of p21.mantGpp[NH]p also results in a biphasic decrease in fluorescence even though cleavage does not occur. This is interpreted that the cleavage step of p21.GTP is preceded by and controlled by an isomerization of the p21.GTP complex. GAP accelerates the rate constant of the second fluorescence phase occurring with p21.mantGpp[NH]p. This result shows that GAP accelerates the proposed isomerization which limits GTP cleavage rather than the cleavage step itself.

An NMR comparison of the changes produced by different guanosine 5'-triphosphate analogs in wild-type and oncogenic mutant p21ras

We have used nuclear magnetic resonance spectroscopy to compare the conformational changes produced by replacement of bound GDP by the GTP analogs guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S) and guanylyl (beta, gamma-imido)diphosphate (GMPPNP) in wild-type p21ras as well as the oncogenic mutant (G12D)p21ras. We have used isotope-edited nuclear magnetic resonance spectroscopy to observe the amide resonances of selectively [15N]glycine and [15N]isoleucine labeled p21ras-nucleotide complexes. We find that eight of the nine resonances that respond strongly to GTP gamma S and GMPPNP binding are the same but that the nature of the effect appears different. With GTP gamma S, seven new resonances replace the eight resonances specifically associated with GDP-p21ras, but in GMPPNP-p21ras only two resonances replace the GDP-specific resonances that are lost. The resonance of Gly 60 is clearly shown to be responsive to replacement of GDP by GMPPNP, in addition to glycines 10, 12, 13, 15, and 75 and isoleucines 36, 21, and one other, that were found to respond to GTP gamma S by Miller et al. [Miller, A.-F., Papastavros, M. Z., & Redfield, A.G. (1992) Biochemistry 31, 10208-10216). The two GMPPNP-specific resonances observed appear in positions similar to GTP gamma S-specific resonances, and the GTP gamma S-specific resonances, although not lost altogether, are weaker than the GDP-specific resonances they replace. Thus, the two GTP analogs have similar effects on the spectrum of p21ras, suggesting that the effects are due to features common to both analogs. We propose that active site resonance intensities are specifically attenuated when GTP analogs are bound because interactions with the gamma-phosphate of GTP analogs couple the flexible loops 2 and 4 to the rigid loop 1 of the active site. The conformational heterogeneity and dynamics of loops 2 and 4 would be constrained by loop 1 but also transmitted to it. Coupled conformational exchange on a common intermediate time scale could explain the simultaneous loss of resonances from all three loops in the active site. In our comparison of wild-type and (G12D) GDP-p21ras, we find that the resonance of Ile 36 is not visible in (G12D)p21ras. In (G12D)p21ras, replacement of GDP by GTP gamma S causes the resonances of glycines 10, 13, 15, 60, and 75 and isoleucine 21 and four others to shift from their GDP-specific positions. GTP gamma S-specific resonances are observed for all but two of these.(ABSTRACT TRUNCATED AT 400 WORDS)

Mapping the nucleotide-dependent conformational change of human N-ras p21 in solution by heteronuclear-edited proton-observed NMR methods

Heteronuclear-edited proton-detected NMR methods are used to study the nucleotide-dependent conformational change between GDP- and GTP gamma S-bound forms of human N-ras p21. Amide groups of Asp are used as sensitive probes. When GTP gamma S is substituted for GDP in cellular N-ras p21, the chemical shifts of resonances Asp-47, -126, -154, and Asn-172, as well as Gly-77 and -151, are not sensitive to nucleotide exchange, whereas Asp-30, -33, -38, -54, -57, -69, -92, -105, and -119 are affected. Distinct chemical shift changes of Asp-33, -38, and -69 indicate that substantial structure changes occur in the effector-binding region and the switch II region. Crystallographic studies of H-ras p21 have indicated that the conformational differences are confined to residues 32-38 and 60-76. Our observations indicate that the nucleotide-dependent structural transitions of the protein in solution may not be identical to those in the crystal. They suggest that the peptide beyond Glu-76 participates in a conformational switch, and possibly is involved in effector function. We propose that the region roughly from Asp-92 to -105, and the region of guanine base-binding motif(s), e.g., 116NKXD, are candidate sites recognized by either a GDP/GTP release factor or a GTPase-affected protein.

A rab protein regulates the localization of secretory granules in AtT-20 cells

Low molecular weight (LMW) GTP-binding proteins are hypothesized to play a role in the vectorial transport of intracellular vesicles. Mutational studies in yeast and subcellular localization in mammalian cells suggest that a family of LMW GTP-binding proteins, termed rab, target intracellular vesicles to their appropriate acceptor compartment. In this report, we demonstrate that an elasmobranch homologue of rab3A, o-rab3, plays a significant role in the sequestration of regulated secretory vesicles. When transfected into the murine endocrine cell line AtT-20, the wild-type o-rab3 protein is localized exclusively to the tips of the processes, a region of the cell known to accumulate proteins associated with regulated secretory vesicles. Two mutations, Gln81 to Leu (Q81L) and Asn135 Ile (N135I), which alter GTP binding or rate of hydrolysis, blocked the localization of the o-rab3 protein to the tips of cell processes. These mutations also hindered the sequestration of ACTH-containing secretory vesicles to the process tips but did not affect the basal or stimulated release of ACTH. Moreover, the sequestration of the protein VAMP to the process tip was also hindered by the mutation. The results demonstrate a role for the rab3 proteins in localization, sequestration, and storage of secretory vesicles near their release site.

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.

Activated conformations of the ras-gene-encoded p21 protein. 2. Comparison of the computed and high-resolution x-ray crystallographic structures of Gly-12 p21

The ras-oncogene-encoded p21 protein is a G-protein that has been shown to cause the malignant transformation of normal cells and has been implicated in causing human tumors. p21 is thought to be activated by the binding of GTP in place of GDP to the protein. We have previously constructed the three-dimensional structure of the p21 protein bound to GDP from an available alpha-carbon tracing of this protein using a combination of molecular dynamics and energy minimization (Dykes, et al., J. Biomol. Struct. Dynamics, 9:1025-1044). Until the recent publication of the all-heavy-atom x-ray crystallographic molecular coordinates of p21 residues 1-166 bound to a non-hydrolyzable GTP derivative (GppNp), no all-atom structure of the p21 protein has been available in the Brookhaven National Laboratories Protein Data Bank (PDB). In this communication we compare our computed structure for the p21-GDP complex to this x-ray crystal structure. We find that the two structures agree quite closely with one another, the overall RMS deviation for the backbone being 1.47 A and 2.71 A for all of the atoms. We have identified the regions of the protein that are responsible for the most significant deviations between the two structures, i.e., residues 32-40 and 61-74. We find that the main chain in the 32-40 segment deviates significantly from residue 32 to residue 36 and the side chain phenolic rings of residue 32 differ greatly between the two structures. The 61-74 region is the least-well defined region in the whole protein crystallographically having, by far, the highest temperature factor (B-factor). The backbone and side chain conformations in the 61-74 segment differ markedly, the overall RMS deviation being 3.1 A for the backbone and 5.7 A for all atoms. Both of these regions have been found in x-ray crystallographic studies of p21-GDP and p21-GTP complexes to undergo significant changes in conformation upon the binding of GTP in place of GDP to the protein. We have further compared our computed structure of the p21 protein with the x-ray crystal structure with regard to the conformations of individual segments, in particular, structurally conserved sequences (SCR), i.e., those sequences that have structural and sequence homology to corresponding sequences in the related G-protein, bacterial elongation factor Tu(EF-Tu), and variable loop regions.(ABSTRACT TRUNCATED AT 400 WORDS)

Crystal structures of two mutants of adenylate kinase from Escherichia coli that modify the Gly-loop

Two mutants of adenylate kinase from Escherichia coli have been crystallized and analyzed by X-ray diffraction at resolutions of 3.4 and 2.4 A, respectively. These mutants are Pro-9-->Leu and Gly-10-->Val. They were selected for their positions in the highly conserved Gly-loop forming a giant anion hole for the beta-phosphate of ATP (GTP) in adenylate kinases, H-ras-p21, and other nucleotide-binding proteins. Mutants at these positions of H-ras-p21 cause cancer. In adenylate kinase these mutations cause smallish changes at the active site. Relating the structural changes to the known changes in catalysis indicates that these mutants hinder the induced-fit movements. As a side result we find that mutant Pro-9-->Leu and wild-type form one very similar crystal packing contact that is crystallographic in one case and noncrystallographic in the other, while all other packing contacts and the space groups are quite at variance.

Increasing nitrogenase catalytic efficiency for MgATP by changing serine 16 of its Fe protein to threonine: use of Mn2+ to show interaction of serine 16 with Mg2+

MgATP-binding and hydrolysis are an integral part of the nitrogenase catalytic mechanism. We are exploring the function of MgATP hydrolysis in this reaction by analyzing the properties of the Fe protein (FeP) component of Azotobacter vinelandii nitrogenase altered by site-directed mutagenesis. We have previously (Seefeldt, L.C., Morgan, T.V., Dean, D.R., & Mortenson, L.E., 1992, J. Biol. Chem. 267, 6680-6688) identified a region near the N-terminus of FeP that is involved in interaction with MgATP. This region of FeP is homologous to the well-known nucleotide-binding motif GXXXXGKS/T. In the present work, we examined the function of the four hydroxyl-containing amino acids immediately C-terminal to the conserved lysine 15 that is involved in interaction with the gamma-phosphate of MgATP. We have established, by altering independently Thr 17, Thr 18, and Thr 19 to alanine, that a hydroxyl-containing residue is not needed at these positions for FeP to function. In contrast, an hydroxyl-containing amino acid at position 16 was found to be critical for FeP function. When the strictly conserved Ser 16 was altered to Ala, Cys, Asp, or Gly, the FeP did not support N2 fixation when expressed in place of the wild-type FeP in A. vinelandii. Altering Ser 16 to Thr (S16T), however, resulted in the expression of an FeP that was partially active. This S16T FeP was purified to homogeneity, and its biochemical examination allowed us to assign a catalytic function to this hydroxyl group in the nitrogenase mechanism. Of particular importance was the finding that the S16T FeP had a significantly higher affinity for MgATP than the wild-type FeP, with a measured Km of 20 microM compared to the wild-type FeP Km of 220 microM. This increased kinetic affinity for MgATP was reflected in a significantly stronger binding of the S16T FeP for MgATP. In contrast, the affinity for MgADP, which binds at the same site as MgATP, was unchanged. The catalytic efficiency (kcat/Km) of S16T FeP was found to be 5.3-fold higher than for the wild-type FeP, with the S16T FeP supporting up to 10 times greater nitrogenase activity at low MgATP concentrations. This indicates a role for the hydroxyl group at position 16 in interaction with MgATP but not MgADP. The site of interaction of this residue was further defined by examining the properties of wild-type and S16T FePs in utilizing MnATP compared with MgATP.(ABSTRACT TRUNCATED AT 400 WORDS)

Electron paramagnetic resonance studies of a ras p21-MnIIGDP complex in solution

The number of water molecules bound to Mn2+ in the complex with a variant of Ha ras p21 and GDP has been determined by electron paramagnetic resonance (EPR) measurements in 17O-enriched water. A resolution enhancement method has been used to improve quantitation of the spectral data. These spectroscopic measurements show that Mn2+ has four water ligands in this complex, a result in agreement with the conclusions of a previous paper [Smithers, G. W., Poe, M., Latwesen, D. G., & Reed, G. H. (1990) Arch. Biochem. Biophys. 280, 416-420]. The resolution enhancement method has also been applied in a measurement of the 17O-Mn2+ superhyperfine coupling constant of 17O in the beta-phosphate of the GDP in the ras p21 complex. The intrinsically narrow EPR signals of Mn2+ in the complex with ras p21 and GDP in 2H2O respond to resolution enhancement such that the superhyperfine splitting from the 17O nuclear spin (I = 5/2) becomes visible in the EPR signals. An 17O-Mn2+ superhyperfine coupling constant is obtained from simulation of the resolution-enhanced EPR spectrum.

Activated conformations of the ras-gene-encoded p21 protein. 1. An energy-refined structure for the normal p21 protein complexed with GDP

A complete three-dimensional structure for the ras-gene-encoded p21 protein with Gly 12 and Gln 61, bound to GDP, has been constructed in four stages using the available alpha-carbon coordinates as deposited in the Brookhaven National Laboratories Protein Data Bank. No all-atom structure has been made available despite the fact that the first crystallographic structure for the p21 protein was reported almost four years ago. In the p21 protein, if amino acid substitutions are made at any one of a number of different positions in the amino acid sequence, the protein becomes permanently activated and causes malignant transformation of normal cells or, in some cell lines, differentiation and maturation. For example, all amino acids except Gly and Pro at position 12 result in an oncogenic protein; all amino acids except Gln, Glu and Pro at position 61 likewise cause malignant transformation of cells. We have constructed our all-atom structure of the non-oncogenic protein from the x-ray structure in order to determine how oncogenic amino acid substitutions affect the three-dimensional structure of this protein. In Stage 1 we generated a poly-alanine backbone (except at Gly and Pro residues) through the alpha-carbon structure, requiring the individual Ala, Pro or Gly residues to conform to standard amino acid geometry and to form trans-planar peptide bonds. Since no alpha-carbon coordinates for residues 60-65 have been determined, these residues were modeled by generating them in the extended conformation and then subjecting them to molecular dynamics using the computer application DISCOVER and energy minimization using DISCOVER and the ECEPP (Empirical Conformational Energies for Peptides Program). In Stage 2, the positions of residues that are homologous to corresponding residues of bacterial elongation factor Tu (EF-Tu) to which p21 bears an overall 40% sequence homology, were determined from their corresponding positions in a high-resolution structure of EF-Tu. Non-homologous loops were taken from the structure generated in Stage 1 and were placed between the appropriate homologous segments so as to connect them. In Stage 3, all bad contacts that occurred in this resulting structure were removed, and the coordinates of the alpha-carbon atoms were forced to superimpose as closely as possible on the corresponding atoms of the reference (x-ray) structure. Then the side chain positions of residues of the non-homologous loop regions were modeled using a combination of molecular dynamics and energy minimization using DISCOVER and ECEPP respectively.(ABSTRACT TRUNCATED AT 400 WORDS)

Refined structure of the complex between guanylate kinase and its substrate GMP at 2.0 A resolution

The crystal structure of guanylate kinase from Saccharomyces cerevisiae complexed with its substrate GMP has been refined at a resolution of 2.0 A. The final crystallographic R-factor is 17.3% in the resolution range 7.0 A to 2.0 A for all reflections of the 100% complete data set. The final model has standard geometry with root-mean-square deviations of 0.016 A in bond lengths and 3.0 in bond angles. It consists of all 186 amino acid residues, the N-terminal acetyl group, the substrate GMP, one sulfate ion and 174 water molecules. Guanylate kinase is structurally related to adenylate kinases and G-proteins with respect to its central beta-sheet with connecting helices and the giant anion hole that binds nucleoside triphosphates. These nucleotides are ATP and GTP for the kinases and GTP for the G-proteins. The chain segment binding the substrate GMP of guanylate kinase differs grossly from the respective part of the adenylate kinases; it has no counterpart in the G-proteins. The binding mode of GMP is described in detail. Probably, the observed structure represents one of several structurally quite different intermediate states of the catalytic cycle.

X-ray crystal structures of transforming p21 ras mutants suggest a transition-state stabilization mechanism for GTP hydrolysis

RAS genes isolated from human tumors often have mutations at positions corresponding to amino acid 12 or 61 of the encoded protein (p21), while retroviral ras-encoded p21 contains substitutions at both positions 12 and 59. These mutant proteins are deficient in their GTP hydrolysis activity, and this loss of activity is linked to their transforming potential. The crystal structures of the mutant proteins are presented here as either GDP-bound or GTP-analogue-bound complexes. Based on these structures, a mechanism for the p21 GTPase reaction is proposed that is consistent with the observed structural and biochemical data. The central feature of this mechanism is a specific stabilization complex formed between the Gln-61 side-chain and the pentavalent gamma-phosphate of the GTP transition state. Amino acids other than glutamine at position 61 cannot stabilize the transition state, and amino acids larger than glycine at position 12 would interfere with the transition-state complex. Thr-59 disrupts the normal position of residue 61, thus preventing its participation in the transition-state complex.

Effects of ions on the intrinsic activities of c-H-ras protein p21. A comparison with elongation factor Tu

The influence of the ionic environment on the intrinsic GTPase activity and the guanine-nucleotide interaction of Ha-ras protein p21 were studied in various experimental conditions and compared with the behaviour of elongation factor (EF) Tu. To this purpose, nucleotide-free p21 was prepared, which is much more stable than by any other reported method. Specific differences between p21 and EF-Tu were found in the action of divalent anions which strongly enhance the dissociation rate of p21.GDP without affecting that of EF-Tu. Unlike EF-Tu, the GTPase activity of p21 is only slightly dependent on the presence and concentration of monovalent cations. The concentrations of Mg2+ influencing the dissociation rate of the p21.GDP complex are much higher than for the intrinsic GTPase activity, an effect also observed for EF-Tu. These results point to two distinct roles of Mg2+: as a conformational regulator of the interaction with the substrate and as a key element for the hydrolysis of GTP. The GTPase activity of p21 is not affected by changes in pH over the range 6-9.2, different from that of EF-Tu. However, stabilization by kirromycin confers a pH independence to the GTPase of EF-Tu in the pH range 6.5-10, suggesting that the bell-shaped behaviour of this activity in the absence of the antibiotic is due to denaturation. This implies similar properties in the catalytic mechanism of these two guanine-nucleotide-binding proteins.

NMR study of the phosphate-binding elements of Escherichia coli elongation factor Tu catalytic domain

The phosphoryl-binding elements in the GDP-binding domain of elongation factor Tu were studied by heteronuclear proton observe methods. Five proton resonances were found below 10.5 ppm. Two of these were assigned to the amide groups of Lys 24 and Gly 83. These are conserved residues in each of the consensus sequences. Their uncharacteristic downfield proton shifts are attributed to strong hydrogen bonds to phosphate oxygens as for resonances in N-ras-p21 [Redfield, A. G., & Papastavros, M. Z. (1990) Biochemistry 29, 3509-3514]. The Lys 24 of the EF-Tu G-domain has nearly the same proton and nitrogen shifts as the corresponding Lys 16 in p21. These results suggest that this conserved lysine has a similar structural role in proteins in this class. The tentative Gly 83 resonance has no spectral analogue in p21. A mutant protein with His 84 changed to glycine was fully 15N-labeled and the proton resonance assigned to Gly 83 shifted downfield by 0.3 ppm, thereby supporting the assignment.

The biochemistry of ras p21

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The structure of Ras protein: a model for a universal molecular switch

X-ray crystallography has revealed the molecular architecture of the cellular and oncogenic forms of p21Ha-ras, the protein encoded by the human Ha-ras gene, in both its active (GTP-bound) and in its inactive (GDP-bound) forms. From comparison of these two structures, a mechanism is suggested for the GTPase hydrolysis reaction that triggers the conformational change necessary for signal transduction. The structures have also allowed identification of the structural consequences of point mutations and the way in which they interfere with the intrinsic GTPase activity of p21ras. The p21ras structure is similar to that of the G-domain of elongation factor Tu (EF-Tu) from Escherichia coli, suggesting that p21ras can serve as a good model for other guanine nucleotide binding proteins.