Effects of mutagenesis in the switch I region and conserved arginines of Escherichia coli MnmE protein, a GTPase involved in tRNA modification

MnmE is an evolutionarily conserved, three domain GTPase involved in tRNA modification. In contrast to Ras proteins, MnmE exhibits a high intrinsic GTPase activity and requires GTP hydrolysis to be functionally active. Its G domain conserves the GTPase activity of the full protein, and thus, it should contain the catalytic residues responsible for this activity. In this work, mutational analysis of all conserved arginine residues of the MnmE G-domain indicates that MnmE, unlike other GTPases, does not use an arginine finger to drive catalysis. In addition, we show that residues in the G2 motif (249GTTRD253), which resides in the switch I region, are not important for GTP binding but play some role in stabilizing the transition state, specially Gly249 and Thr251. On the other hand, G2 mutations leading to a minor loss of the GTPase activity result in a non-functional MnmE protein. This indicates that GTP hydrolysis is a required but non-sufficient condition so that MnmE can mediate modification of tRNA. The conformational change of the switch I region associated with GTP hydrolysis seems to be crucial for the function of MnmE, and the invariant threonine (Thr251) of the G2 motif would be essential for such a change, because it cannot be substituted by serine. MnmE defects result in impaired growth, a condition that is exacerbated when defects in other genes involved in the decoding process are simultaneously present. This behavior is reminiscent to that found in yeast and stresses the importance of tRNA modification for gene expression.     

Structural insights into the GTPase domain of Escherichia coli MnmE protein

The Escherichia coli MnmE protein is a 50-kDa multidomain GTPase involved in tRNA modification. Its homologues in eukaryotes are crucial for mitochondrial respiration and, thus, it is thought that the human protein might be involved in mitochondrial diseases. Unlike Ras, MnmE shows a high intrinsic GTPase activity and requires effective GTP hydrolysis, and not simply GTP binding, to be functionally active. The isolated MnmE G-domain (165 residues) conserves the GTPase activity of the entire protein, suggesting that it contains the catalytic residues for GTP hydrolysis. To explore the GTP hydrolysis mechanism of MnmE, we analyzed the effect of low pH on binding and hydrolysis of GTP, as well as on the formation of a MnmE transition state mimic. GTP hydrolysis by MnmE, but not GTP binding or formation of a complex with mant-GDP and aluminium fluoride, is impaired at acidic pH, suggesting that the chemistry of the transition state mimic is different to that of the true transition state, and that some residue(s), critical for GTP hydrolysis, is severely affected by low pH. We use a nuclear magnetic resonance (NMR)-based approach to get insights into the MnmE structure and properties. The combined use of NMR restraints and homology structural information allowed the determination of the MnmE G-domain structure in its free form. Chemical shift structure-based prediction provided a good basis for structure refinement and validation. Our data support that MnmE, unlike other GTPases, does not use an arginine finger to drive catalysis, although Arg252 may play a role in stabilization of the transition state.     

Characterization of human GTPBP3, a GTP-binding protein involved in mitochondrial tRNA modification

Human GTPBP3 is an evolutionarily conserved, multidomain protein involved in mitochondrial tRNA modification. Characterization of its biochemical properties and the phenotype conferred by GTPBP3 inactivation is crucial to understanding the role of this protein in tRNA maturation and its effects on mitochondrial respiration. We show that the two most abundant GTPBP3 isoforms exhibit moderate affinity for guanine nucleotides like their bacterial homologue, MnmE, although they hydrolyze GTP at a 100-fold lower rate. This suggests that regulation of the GTPase activity, essential for the tRNA modification function of MnmE, is different in GTPBP3. In fact, potassium-induced dimerization of the G domain leads to stimulation of the GTPase activity in MnmE but not in GTPBP3. The GTPBP3 N-terminal domain mediates a potassium-independent dimerization, which appears as an evolutionarily conserved property of the protein family, probably related to the construction of the binding site for the one-carbon-unit donor in the modification reaction. Partial inactivation of GTPBP3 by small interfering RNA reduces oxygen consumption, ATP production, and mitochondrial protein synthesis, while the degradation of these proteins slightly increases. It also results in mitochondria with defective membrane potential and increased superoxide levels. These phenotypic traits suggest that GTPBP3 defects contribute to the pathogenesis of some oxidative phosphorylation diseases.     

G-Domain Dimerization Orchestrates the tRNA Wobble Modification Reaction in the MnmE/GidA Complex

MnmE and GidA are involved in the modification of wobble uridine to carboxymethylaminomethyl uridine in certain tRNAs. Malfunctioning of the human orthologs has been implicated in mitochondrial diseases. MnmE is a conserved G protein activated by dimerization. Here, we show that complex formation between MnmE and GidA involves large conformational changes that induce G-domain dimerization of MmnE and that GidA co-stimulates GTP hydrolysis on MnmE. Starting from a structural model of the complex, we identify interface mutations disrupting complex formation or communication. Although GidA does not directly contact the G-domains, conformational changes in MnmE, induced by G-domain dimerization in the triphosphate state, regulate the affinity for GidA. We developed a tRNA modification assay and demonstrate for the first time in vitro that the MnmE/GidA complex catalyzes incorporation of glycine into tRNA. An intact MnmE/GidA complex rather than their sequential action is crucial for in vitro modification. Since only GTP, but not GDP or non-hydrolyzable GTP analogs, drives the MnmE/GidA-catalyzed modification reaction, we conclude that GTP hydrolysis is essential for activity. We finally show that an active GTPase, an intact MnmE/GidA communication, and dimerization of G-domains are necessary for in vivo functioning since mutations disrupting either result in a respiratory deficient phenotype in yeast.     

The tRNA-modifying function of MnmE is controlled by post-hydrolysis steps of its GTPase cycle

MnmE is a homodimeric multi-domain GTPase involved in tRNA modification. This protein differs from Ras-like GTPases in its low affinity for guanine nucleotides and mechanism of activation, which occurs by a cis, nucleotide- and potassium-dependent dimerization of its G-domains. Moreover, MnmE requires GTP hydrolysis to be functionally active. However, how GTP hydrolysis drives tRNA modification and how the MnmE GTPase cycle is regulated remains unresolved. Here, the kinetics of the MnmE GTPase cycle was studied under single-turnover conditions using stopped- and quench-flow techniques. We found that the G-domain dissociation is the rate-limiting step of the overall reaction. Mutational analysis and fast kinetics assays revealed that GTP hydrolysis, G-domain dissociation and P_i release can be uncoupled and that G-domain dissociation is directly responsible for the ‘ON’ state of MnmE. Thus, MnmE provides a new paradigm of how the ON/OFF cycling of GTPases may regulate a cellular process. We also demonstrate that the MnmE GTPase cycle is negatively controlled by the reaction products GDP and P_i. This feedback mechanism may prevent inefficacious GTP hydrolysis in vivo. We propose a biological model whereby a conformational change triggered by tRNA binding is required to remove product inhibition and initiate a new GTPase/tRNA-modification cycle.     

Ffh and FtsY in a Mycoplasma mycoides signal-recognition particle pathway: SRP RNA and M domain of Ffh are not required for stimulation of GTPase activity in vitro

Mycoplasma mycoides contains a signal-recognition particle (SRP) composed of an RNA molecule and an SRP54 homologue (Ffh). We have now identified a mycoplasma homologue to the α subunit of the mammalian SRP receptor and Escherichia coli FtsY. The protein (MmFtsY) was expressed in E. coli and purified to homogeneity. MmFtsY has a weak intrinsic GTPase activity but GTP hydrolysis was markedly stimulated when it was combined with mycoplasma Ffh (MmFfh) and SRP RNA. Also, in the absence of SRP RNA GTPase activity was significantly enhanced. Furthermore, GTP hydrolysis was stimulated when MmFtsY was combined with the N-terminal GTPase domain (N+G) of MmFfh. These findings indicate that basic features of the GTPase activation mechanism are independent of the C-terminal M domain of the MmFfh protein. We propose that the activation is mediated to a large extent by contacts between the GTPase domains of the mycoplasma Ffh and FtsY proteins and that the contribution of the M domain and SRP RNA in the activation mechanism is mainly for modifying the conformation of the MmFfh GTPase domain.     

Identification and characterization of Streptococcus pneumoniae Ffh, a homologue of SRP54 subunit of mammalian signal recognition particle

Recent studies have demonstrated that bacteria possess an essential protein translocation system similar to mammalian signal recognition particle (SRP). Here we have identified the Ffh, a homologue of the mammalian SRP54 subunit from S. pneumoniae. Ffh is a 58-kDa protein with three distinct domains: an N-terminal hydrophilic domain (N-domain), a G-domain containing GTP/GDP binding motifs, and a C-terminal methionine-rich domain (M-domain). The full-length Ffh and a truncated protein containing N and G domains (Ffh-NG) were overexpressed in E. coli and purified to homogeneity. The full-length Ffh has an intrinsic GTPase activity with k(cat) of 0.144 min(-1), and the K(m) for GTP is 10.9 microM. It is able to bind to 4.5S RNA specifically as demonstrated by gel retardation assay. The truncated Ffh-NG has approximately the same intrinsic GTPase activity to the full-length Ffh, but is unable to bind to 4.5S RNA, indicating that the NG domain is sufficient for supporting intrinsic GTP hydrolysis, and that the M domain is required for RNA binding. The interaction of S. pneumoniae Ffh with its receptor, FtsY, resulted in a 20-fold stimulation in GTP hydrolysis. The stimulation was further demonstrated to be independent of the 4.5S RNA. In addition, a similar GTPase stimulation is also observed between Ffh-NG and FtsY, suggesting that the NG domain is sufficient and the M domain is not required for GTPase stimulation between Ffh and FtsY.     

Arginines 29 and 59 of elongation factor G are important for GTP hydrolysis or translocation on the ribosome

GTP hydrolysis by elongation factor G (EF-G) is essential for the translocation step in protein elongation. The low intrinsic GTPase activity of EF-G is strongly stimulated by the ribosome. Here we show that a conserved arginine, R29, of Escherichia coli EF-G is crucial for GTP hydrolysis on the ribosome, but not for GTP binding or ribosome interaction, suggesting that it may be directly involved in catalysis. Another conserved arginine, R59, which is homologous to the catalytic arginine of G(alpha) proteins, is not essential for GTP hydrolysis, but influences ribosome binding and translocation. These results indicate that EF-G is similar to other GTPases in that an arginine residue is required for GTP hydrolysis, although the structural changes leading to GTPase activation are different.     

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)     

Stimulation of the GTPase activity of translation elongation factor G by ribosomal protein L7/12

Elongation factors (EFs) Tu and G are GTPases that have important functions in protein synthesis. The low intrinsic GTPase activity of both factors is strongly stimulated on the ribosome by unknown mechanisms. Here we report that isolated ribosomal protein L7/12 strongly stimulates GTP hydrolysis by EF-G, but not by EF-Tu, indicating a major contribution of L7/12 to GTPase activation of EF-G on the ribosome. The effect is due to the acceleration of the catalytic step because the rate of GDP-GTP exchange on EF-G, as measured by rapid kinetics, is much faster than the steady-state GTPase rate. The unique, highly conserved arginine residue in the C-terminal domain of L7/12 is not essential for the activation, excluding an "arginine finger"-type mechanism. L7/12 appears to function by stabilizing the GTPase transition state of EF-G.     

An Alternative Homodimerization Interface of MnmG Reveals a Conformational Dynamics that Is Essential for Its tRNA Modification Function

The Escherichia coli homodimeric proteins MnmE and MnmG form a functional complex, MnmEG, that modifies tRNAs using GTP, methylene-tetrahydrofolate, FAD, and glycine or ammonium. MnmE is a tetrahydrofolate- and GTP-binding protein, whereas MnmG is a FAD-binding protein with each protomer composed of the FAD-binding domain, two insertion domains, and the helical C-terminal domain. The detailed mechanism of the MnmEG-mediated reaction remains unclear partially due to incomplete structural information on the free- and substrate-bound forms of the complex. In this study, we show that MnmG can adopt in solution a dimer arrangement (form I) different from that currently considered as the only biologically active (form II). Normal mode analysis indicates that form I can oscillate in a range of open and closed conformations. Using isothermal titration calorimetry and native red electrophoresis, we show that a form-I open conformation, which can be stabilized in vitro by the formation of an interprotomer disulfide bond between the catalytic C277 residues, appears to be involved in the assembly of the MnmEG catalytic center. We also show that residues R196, D253, R436, R554 and E585 are important for the stabilization of form I and the tRNA modification function. We propose that the form I dynamics regulates the alternative access of MnmE and tRNA to the MnmG FAD active site. Finally, we show that the C-terminal region of MnmG contains a sterile alpha motif domain responsible for tRNA–protein and protein–protein interactions.     

182 Investigating the mode of action of an essential OBG GTPase,CgtA in bacteria

CgtA is an essential OBG GTPase (Trach & Hoch, 1989) highly conserved from bacteria to eukaryotes. It is a multifunctional protein, involved in DNA replication, chromosome partitioning (Slominska et al., 2002), nutritional stress response, initiation of sporulation, ribosome maturation, etc. Despite being a multifunctional essential protein, its mode of action is not well- characterized and key question remains: how does this protein work in wide varieties of cellular function? The expression of cgtA-mRNA increases on the onset of nutritional stress. Purified CgtA protein shows increased GTPase activity in the presence of ribosome. Our experiment with thiostrepton reveals that, although ribosome is able to trigger the GTPase activity of CgtA, its probable site of GTPase inducing activity is different from other regular translation factors like EF-G, that uses GTP. For structure function study we have generated an energy minimized homology model of the Vibrio cholerae CgtA protein, which reveals two large domains, an OBG-fold and a GTP– hydrolysis domain, with an extended C-terminal part. We compared the amino acid sequence of CgtA across various species in the database, and found that its Glycine98 and the Tyrosine195 residues are 100% conserved in prokaryotes. These amino acids are highly conserved in eukaryotes as well. Gly98 and Tyr195 are located on the hinge region of CgtA comprising of portions of the OBG and the GTP–hydrolysis domains, respectively. To decipher the mode of actions of CgtA and the role of the conserved Gly98 residue, we have replaced the Gly with a relatively larger amino acid, i.e. Asp. Our study reveals that the mutant CgtA(G98D) shows a reduced GTPase activity in presence of ribosome compared to the wild type. This indicates a restricted inter-domain movement of CgtA due to the above point mutation. To understand this phenomenon we are using MD simulations. We will discuss results from MD simulations and other mutation studies as well. Our results indicate that ribosome acts as a modulator for increasing the GTPase activity of CgtA. The perfect conservation of G98 residue is important for the proper functionality of CgtA.     

Role of domains 4 and 5 in elongation factor G functions on the ribosome

Elongation factor G (EF-G) is a large, five domain GTPase that catalyses the translocation of the tRNAs on the bacterial ribosome at the expense of GTP. In the crystal structure of GDP-bound EF-G, domain 1 (G domain) makes direct contacts with domains 2 and 5, whereas domain 4 protrudes from the body of the molecule. Here, we show that the presence of both domains 4 and 5 is essential for tRNA translocation and for the turnover of the factor on the ribosome, but not for rapid single-round GTP hydrolysis by EF-G. Replacement of a highly conserved histidine residue at the tip of domain 4, His583, with lysine or arginine decreases the rate of tRNA translocation at least 100-fold, whereas the binding of the factor to the ribosome, GTP hydrolysis and P(i) release are not affected by the mutations. Various small deletions in the tip region of domain 4 decrease the translocation activity of EF-G even further, but do not block the turnover of the factor. Unlike native EF-G, the mutants of EF-G lacking domains 4/5 do not interact with the alpha-sarcin stem-loop of 23 S rRNA. These mutants are not released from the ribosome after GTP hydrolysis or translocation, indicating that the contact with, or a conformational change of, the alpha-sarcin stem-loop is required for EF-G release from the ribosome.     

Analysis of the GTPase activity and active sites of the NG domains of FtsY and Ffh from Streptomyces coelicolor

Fifty-four homolog(Ffh)and FtsY are the central components of the signal recognitionparticle secretory pathway of bacteria.In this study,the core domain and active sites of FtsY and Ffh fromStreptomyces coelicolor,which are responsible for guanosine triphosphate(GTP)hydrolysis,were identi-fied using site-directed mutagenesis.Mutations were introduced to the conserved GXXGXGK loop of theputative GTP binding site.Mutation of the Lys residue to Gly in both FtsY and Ffh NG domains significantlydecreased the GTPase activity and GTP binding affinity.Furthermore,a structural model of the ternarycomplex of FtsY/Ffh NG domains and the non-hydrolyzable GTP analog guanylyl 5′-(β,γ-methylenediphosphonate)also revealed that each Lys residue in GXXGXGK of FtsY and Ffh provides thepredicted hydrogen bond required for GTP binding.However,in Fts Y not in Ffh,mutation of the first Glyresidue in the GXXGXGK loop disrupted the GTPase activity.In addition,protease-digesting test demon-strated that NG protein with the mutation of Lys residue was decomposed more easily.Western blot analysissuggested that in Streptomyces coelicolor,Fts Y is present in the membrane fraction and Ffh in the cytosolfraction during the mid-log phase of growth.These results indicated that Lys residue in the putative GTPbinding loop was the crucial residue for the GTPase activity of NG domain.     

Domain III of elongation factor G from Thermus thermophilus is essential for induction of GTP hydrolysis on the ribosome

Two elongation factors (EF) EF-Tu and EF-G participate in the elongation phase during protein biosynthesis on the ribosome. Their functional cycles depend on GTP binding and its hydrolysis. The EF-Tu complexed with GTP and aminoacyl-tRNA delivers tRNA to the ribosome, whereas EF-G stimulates translocation, a process in which tRNA and mRNA movements occur in the ribosome. In the present paper we report that: (a) intrinsic GTPase activity of EF-G is influenced by excision of its domain III; (b) the EF-G lacking domain III has a 10(3)-fold decreased GTPase activity on the ribosome, whereas its affinity for GTP is slightly decreased; and (c) the truncated EF-G does not stimulate translocation despite the physical presence of domain IV, which is also very important for translocation. By contrast, the interactions of the truncated factor with GDP and fusidic acid-dependent binding of EF-G.GDP complex to the ribosome are not influenced. These findings indicate an essential contribution of domain III to activation of GTP hydrolysis. These results also suggest conformational changes of the EF-G molecule in the course of its interaction with the ribosome that might be induced by GTP binding and hydrolysis.     

Domain structure and intramolecular regulation of dynamin GTPase.

Dynamin is a 100 kDa GTPase required for receptor-mediated endocytosis, functioning as the key regulator of the late stages of clathrin-coated vesicle budding. It is specifically targeted to clathrin-coated pits where it self-assembles into 'collars' required for detachment of coated vesicles from the plasma membrane. Self-assembly stimulates dynamin GTPase activity. Thus, dynamin-dynamin interactions are critical in regulating its cellular function. We show by crosslinking and analytical ultracentrifugation that dynamin is a tetramer. Using limited proteolysis, we have defined structural domains of dynamin and evaluated the domain interactions and requirements for self-assembly and GTP binding and hydrolysis. We show that dynamin's C-terminal proline- and arginine-rich domain (PRD) and dynamin's pleckstrin homology (PH) domain are, respectively, positive and negative regulators of self-assembly and GTP hydrolysis. Importantly, we have discovered that the alpha-helical domain interposed between the PH domain and the PRD interacts with the N-terminal GTPase domain to stimulate GTP hydrolysis. We term this region the GTPase effector domain (GED) of dynamin.     

Role of Individual Domains and Identification of Internal Gap in Human Guanylate Binding Protein-1

Unlike other GTPases, interferon-gamma-induced human guanylate binding protein-1 has the ability to hydrolyze GTP to both GDP and GMP, with GMP being the major product of the reaction. This protein has two domains, an N-terminal globular domain and a C-terminal helical domain. These two domains are connected by a short intermediate region consisting of a two-stranded β-sheet and a helix. As human guanylate binding protein-1 has been shown to undergo stimulated GTPase activity without external GTPase-activating protein, we sought to understand the roles of each of the two individual domains, the intermediate region, a conserved motif (¹⁰³DXEKGD¹⁰⁸), and the mechanism of the stimulation of GTPase activity. The steady-state assays using radiolabeled [α-³²P]GTP on the wild-type protein suggest that the stimulation of activity primarily occurs during the cleavage of the second phosphate of GTP rather than the first, through allosteric interaction. Using several truncated and mutant proteins, we demonstrate for the first time that both the α-helix of the intermediate region and the ¹⁰³DXEKGD¹⁰⁸ motif play critical roles for the hydrolysis to GMP, but they appear to act in different ways: α-helix acts through structural stabilization by allosteric interaction and, thus, acts as an internal GTPase-activating protein, whereas the motif might act by providing necessary catalytic residues. Our data also show that the N-terminal globular domain is able to perform only the first catalysis (GTP to GDP, an activity associated with basal level), but the helical domain in the full-length protein stimulates the hydrolysis of GTP to GMP with higher GMP formation by preventing the dissociation of GDP-bound enzyme dimer.     

The NUG1 GTPase reveals and N-terminal RNA-binding domain that is essential for association with 60 S pre-ribosomal particles

The putative yeast GTPase Nug1, which is associated with several pre-60 S particles in the nucleolus and nucleoplasm, consists of an N-terminal domain, which is found only in eukaryotic orthologues, and middle and C-terminal domains that are conserved throughout eukaryotes, bacteria, and archaea. Here, we analyzed the role of the eukaryote-specific Nug1 N-domain (Nug1-N). We show that the essential Nug1-N is sufficient and necessary for nucle(ol)ar targeting and association with pre-60 S particles. Nug1-N exhibits RNA binding activity and is genetically linked in an allele-specific way to the pre-60 S factors Noc2, Noc3, and Dbp10. In contrast, the middle domain, which exhibits a circularly permuted GTPase fold and an intrinsic GTP hydrolysis activity in vitro, is not essential for cell growth. The conserved Nug1 C-domain, which has a yet uncharacterized fold, is also essential for ribosome biogenesis. Our findings suggest that Nug1 associates with pre-60 S subunits via its essential N-terminal RNA-binding domain and exerts a non-essential regulative role in pre-60 S subunit biogenesis via its central GTPase domain.     

Influence of individual domains of the translation termination factor eRF1 on induction of the GTPase activity of the translation termination factor eRF3

Translation termination in eukaryotes is governed by two proteins belonging to class 1 (eRF1) and class 2 (eRF3) polypeptide release factors. eRF3 catalyzes hydrolysis of GTP to yield GDP and P_i in the ribosome in the absence of mRNA, tRNA, aminoacyl-tRNA, and peptidyl-tRNA and requires eRF1 for this activity. It is known that eRF1 and eRF3 interact with each other via their C-terminal regions both in vitro and in vivo. eRF1 consists of three domains—N, M, and C. In this study we examined the influence of the individual domains of the human eRF1 on induction of the human eRF3 GTPase activity in the ribosome in vitro. It was shown that none of the N, M, C, and NM domains induces the eRF3 GTPase activity in the presence of ribosomes. The MC domain does induce the eRF3 GTPase activity, but four times less efficiently than full-length eRF1. Therefore, we assumed that the MC domain (and very likely the M domain) binds to the ribosome in the presence of eRF3. Based on these data and taking into account the data available in the literature, a conclusion was drawn that the N domain of eRF1 is not essential for eRF1-dependent induction of the eRF3 GTPase activity. A working hypothesis is formulated that the eRF3 GTPase activity in the ribosome during translation termination is associated with the intermolecular interactions of GTP/GDP, the GTPase center of the large (60S) subunit, the MC domain of eRF1, and the C-terminal region and GTP-binding motifs of eRF3 but without participation of the N-terminal region of eRF1.     

Conformationally restricted elongation factor G retains GTPase activity but is inactive in translocation on the ribosome

Elongation factor G (EF-G) from Escherichia coli is a large, five-domain GTPase that promotes tRNA translocation on the ribosome. Full activity requires GTP hydrolysis, suggesting that a conformational change of the factor is important for function. To restrict the intramolecular mobility, two cysteine residues were engineered into domains 1 and 5 of EF-G that spontaneously formed a disulfide cross-link. Cross-linked EF-G retained GTPase activity on the ribosome, whereas it was inactive in translocation as well as in turnover. Both activities were restored when the cross-link was reversed by reduction. These results strongly argue against a GTPase switch-type model of EF-G function and demonstrate that conformational mobility is an absolute requirement for EF-G function on the ribosome.