Structure-function relationships of elongation factor Tu as studied by mutagenesis.

We have modified elongation factor Tu (EF-Tu) from Escherichia coli via mutagenesis of its encoding tufA gene to study its function-structure relationships. The isolation of the N-terminal half molecule of EF-Tu (G domain) has facilitated the analysis of the basic EF-Tu activities, since the G domain binds the substrate GTP/GDP, catalyzes the GTP hydrolysis and is not exposed to the allosteric constraints of the intact molecule. So far, the best studied region has been the guanine nucleotide-binding pocket defined by the consensus elements typical for the GTP-binding proteins. In this area most substitutions were carried out in the G domain and were found to influence GTP hydrolysis. In particular, the mutation VG20 (in both G domain and EF-Tu) decreases this activity and enhances the GDP to GTP exchange; PT82 induces autophosphorylation of Thr82 and HG84 strongly affects the GTPase without altering the interaction with the substrate. SD173, a residue interacting with (O)6 of the guanine, abolishes the GTP and GDP binding activity. Substitution of residues Gln114 and Glu117, located in the proximity of the GTP binding pocket, influences respectively the GTPase and the stability of the G domain, whereas the double replacement VD88/LK121, located on alpha-helices bordering the GTP-binding pocket, moderately reduces the stability of the G domain without greatly affecting GTPase and interaction with GTP(GDP). Concerning the effect of ligands, EF-TuVG20 supports a lower poly(Phe) synthesis but is more accurate than wild-type EF-Tu, probably due to a longer pausing on the ribosome.(ABSTRACT TRUNCATED AT 250 WORDS)     

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)     

Substitution of histidine-84 and the GTPase mechanism of elongation factor Tu

Mutation of His84, a residue situated in one of the loops forming the guanine nucleotide binding pocket, was introduced in the G domain, the isolated N-terminal half molecule of bacterial elongation factor Tu (EF-Tu), in order to investigate the role of this residue on the basic activities of EF-Tu: the interaction with GDP and GTP and the hydrolysis of GTP. Substitution of His84 by Gly reduces the GTPase activity of the G domain to 5%; this activity can still be stimulated by raising the KCl concentration as the activity of wild-type G domain or the intact molecule. Since the affinities of the mutant protein for GDP and GTP are essentially the same as those of the wild-type G domain, His84 is apparently not involved in the binding of the substrates. Calculations of the change in free energy of activation of the GTPase reaction following substitution of His84 by Gly point to the disruption of a weak hydrogen bond, involved in the catalytic reaction. This probably concerns an interaction via a water molecule. The possible mechanism underlying the GTPase reaction is discussed in light of the three-dimensional structure of EF-Tu, taking into account the situation of Ha-ras p21.     

Affinity labeling of GTP-binding proteins in cellular extracts.

GTP-binding proteins in cellular extracts from Escherichia coli, Thermus thermophilus, yeast, wheat germ or calf thymus were identified using in situ periodate-oxidized [alpha-32P]GTP as affinity label. Site-specific reaction of individual GTP-binding proteins was achieved by cross-linking the protein-bound 2',3'-dialdehyde derivative of GTP with the single lysine residue of the conserved NKXD sequence through Schiff's base formation and subsequent cyanoborohydride reduction. Labeled GTP-binding proteins from prokaryotic or eukaryotic cell homogenates were separated by polyacrylamide gel electrophoresis and visualized by autoradiography. In addition cross-linking of [alpha-32P]GTP with GTP-binding proteins was demonstrated in model systems using different purified GTPases, human c-H-ras p21, transducin from bovine retina, polypeptide elongation factor Tu (EF-Tu) from T. thermophilus and initiation factor 2 (IF2) from T. thermophilus. The described affinity labeling technique can serve as an analytical method for the identification of GTPases belonging to the classes of ras-proteins, elongation and initiation factors, and heterotrimeric signal transducing G-proteins.     

Three-dimensional structure of the ribosomal translocase: elongation factor G from Thermus thermophilus.

The crystal structure of Thermus thermophilus elongation factor G without guanine nucleotide was determined to 2.85 A. This GTPase has five domains with overall dimensions of 50 x 60 x 118 A. The GTP binding domain has a core common to other GTPases with a unique subdomain which probably functions as an intrinsic nucleotide exchange factor. Domains I and II are homologous to elongation factor Tu and their arrangement, both with and without GDP, is more similar to elongation factor Tu in complex with a GTP analogue than with GDP. Domains III and V show structural similarities to ribosomal proteins. Domain IV protrudes from the main body of the protein and has an extraordinary topology with a left-handed cross-over connection between two parallel beta-strands.     

Substitution of aspartic acid-80, a residue involved in coordination of magnesium, weakens the GTP binding and strongly enhances the GTPase of the G domain of elongation factor Tu.

The functional role of Asp80, a residue involved in the coordination of the Mg(2+).guanine nucleotide complex in elongation factor Tu (EF-Tu), has been investigated by its substitution with Asn in the isolated N-terminal domain (G domain). The G domain D80N is characterized by a strong decrease in binding affinity for GTP and magnesium, whereas the affinity for GDP is unchanged. This effect can be mimicked in wild-type G domain by the addition of EDTA. In contrast to this, EDTA does not essentially influence the selective effects of the mutation on the GTP and GDP binding of G domain D80N, indicating that the action of Asp80 is mainly mediated by the GTP-coordinated magnesium ion. The GTPase activity of the G domain D80N is very unstable, but can be markedly stabilized by the addition of glycerol without essentially modifying the specific effects of the mutation. In the absence of glycerol G domain D80N can express a short-lived GTPase activity. The presence of glycerol transforms this evanescent activity into a linear multiple-round activity that under optimal conditions can be almost 2 orders of magnitude higher than the GTPase of wild-type G domain. This enhanced catalytic activity represents the most striking consequence of the mutation and stresses the key role of Asp80 in the GTPase of EF-Tu.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structure-function relationships in the GTP binding domain of EF-Tu: mutation of Val20, the residue homologous to position 12 in p21.

Val20 of elongation factor Tu (EF-Tu), one of the best-characterized GTP binding proteins, is a variable residue within the consensus motif G-X-X-X-X-G-K involved in the interaction with the phosphates of GDP/GTP. To investigate the structure-function relationships of EF-Tu, which is widely used as a model protein, Val20 has been substituted by Gly using oligonucleotide-directed mutagenesis. The most important effects are: (i) a strong reduction of the intrinsic GTPase activity, (ii) a remarkable enhancement of the association and dissociation rates of EF-TuGly20-GDP, mimicking the effect of elongation factor Ts (EF-Ts) and (iii) the inability of ribosomes to influence the intrinsic GTPase of EF-Tu uncoupled from poly(Phe) synthesis. EF-TuGly20 can sustain poly(Phe) synthesis, albeit at a much lower rate than wild-type EF-TuVal20. As with the latter, poly(Phe) synthesis by EF-TuGly20 is inhibited by the antibiotic kirromycin, but differs remarkably in that it is largely independent of the presence of EF-Ts. According to primary sequence alignment, position 20 is homologous to position 12 of ras protein p21. As in p21, this position in EF-Tu is critical, influencing specifically the GDP/GTP interaction as well as other functions. The effect of the mutation displays diversities but also similarities with the situation reported for p21 having the corresponding residues in position 12. The differences observed with two homologous residues, Gly20 and Gly12 in EF-Tu and p21 respectively, show the importance of a variable residue in a consensus element in defining specific functions of GTP binding proteins.     

Phosphorylation by cyclic AMP-dependent protein kinase of a human platelet Mr 22,000 GTP-binding protein (smg p21) having the same putative effector domain as the ras gene products

We have purified to near homogeneity a Mr 22,000 GTP-binding protein from human platelet membranes and identified it as the smg-21 gene product (smg p21), having the same putative effector domain as the ras gene products, which we have purified to near homogeneity from bovine brain membranes and characterized. This purified human platelet smg p21 was phosphorylated by cyclic AMP-dependent protein kinase. About one mol of phosphate was maximally incorporated into one mol of the protein. Only serine residue was phosphorylated. Both the guanosine 5'-(3-O-thio)-triphosphate (GTP gamma S)-bound and GDP-bound forms were phosphorylated with the same reaction velocity. The phosphorylation of smg p21 affected neither its GTP gamma S-binding nor GTPase activity. Human platelet smg p21 was not phosphorylated by protein kinase C. A Mr 24,000 GTP-binding protein partially purified from human platelet membranes was not phosphorylated by cyclic AMP-dependent protein kinase or protein kinase C.     

The GTP-binding peptide of beta-tubulin. Localization by direct photoaffinity labeling and comparison with nucleotide-binding proteins

The binding site of the guanine moiety of GTP on beta-tubulin was located within the peptide consisting of residues 63-77, AILVDLEPGTMDSVR. The result was obtained using direct photoaffinity labeling, peptide sequencing, and limited proteolysis. Peptides were identified by end-labeling with a monoclonal antibody against beta-tubulin whose epitope was located between 3 and 4 kDa from the C terminus. The sequence of the GTP-binding site is consistent with predictions from other GTP-binding proteins such as elongation factor Tu or ras p21.     

Role of the C-terminal region of smg p21, a ras p21-like small GTP-binding protein, in membrane and smg p21 GDP/GTP exchange protein interactions

Limited proteolysis with trypsin of smg p21B, a ras p21-like small GTP-binding protein having the same putative effector domain as ras p21s, produced the N-terminal fragment and the C-terminal tail of Lys-Lys-Ser-Ser-geranylgeranyl-Cys methyl ester. The Mr values of the intact smg p21B, the N-terminal fragment, and the C-terminal tail were estimated to be about 22,000, 20,500, and less than 1,000, respectively, by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Both the GDP- and GTP-bound forms of the intact smg p21B bound to various membranes and phosphatidylserine-linked Affi-Gel. However, both the GDP- and GTP-bound forms of the N-terminal fragment failed to bind to membranes and phosphatidylserine-linked Affi-Gel. In contrast, the C-terminal tail bound to membranes and phosphatidylserine-linked Affi-Gel. The N-terminal fragment contained a GDP/GTP-binding and GTPase domain and exhibited these two activities, but the C-terminal tail did not show any such activity. A GTPase-activating protein for smg p21 stimulated the GTPase activity of both the intact smg p21B and the N-terminal fragment. In contrast, a GDP/GTP exchange protein for smg p21, named GDP dissociation stimulator, stimulated the GDP/GTP exchange reaction of the intact smg p21B but not that of the N-terminal fragment. These results indicate 1) that smg p21B is composed of at least two functionally different domains, the N-terminal GDP/GTP-binding and GTPase domain and the C-terminal membrane-binding domain, 2) that smg p21B binds to membranes through its C-terminal hydrophobic and basic domain, and 3) that this C-terminal domain is also essential for the smg p21 GDP dissociation stimulator action but not for the smg p21 GTPase-activating protein action.     

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.     

Ribosome-independent GTPase activity of translation initiation factor IF2 and of its G-domain.

In the absence of ribosomes, Bacillus stearothermophilus translation initiation factor IF2 (Mr = 82 kDa) and its GTP-binding domain (i.e. the G-domain, Mr = 41 kDa) promote barely detectable hydrolysis of GTP. Upon addition of some aliphatic alcohols, however, the rate of nucleotide cleavage is substantially increased with both IF2 and G-domain, the highest stimulation being observed with 20% (v/v) ethanol. Under these conditions, the rates of ribosome-independent GTP hydrolysis with both IF2 and G-domain are approximately 30-fold lower than the corresponding rates obtained in the presence of ribosomes, while the Km for GTP is approximately the same in all cases. These results indicate that, as with the other two prokaryotic G proteins involved in translation (i.e. elongation factors EF-Tu and EF-G), also in the case of IF2, the GTPase catalytic center resides in the factor and, more specifically, in its G-domain.     

The functional and structural roles of residues Gln114 and Glu117 in elongation factor Tu

The effects of substituting residues Gln114 by Glu and Glu117 by Gln, both situated in the vicinity of the guanine-nucleotide-binding pocket, were investigated in the isolated N-terminal domain (G domain) of elongation factor Tu with respect to the binding of the substrate GDP/GTP, GTPase activity and stability. The major change in the interaction with the guanine nucleotides is a lower affinity for GTP and a reduced GTPase activity when Gln114 is substituted by Glu. This mutation also abolishes most of the selective effects on the GTPase activity induced by the different monovalent cations. Substitution of Glu117 by Gln does not affect the interaction with the guanine nucleotides or the GTPase activity of the G domain in an essential way, but it reduces the stability towards denaturation of the G-domain.GDP complex. Our results therefore suggest, that Gln114 is involved in keeping a functional conformation of the guanine-nucleotide-binding pocket, whereas Glu117 participates in the regulation of the overall conformation of the G domain. Neither of these two residues appears to play a role in the actual GTPase mechanism.     

Purification and characterization from bovine brain cytosol of proteins that regulate the GDP/GTP exchange reaction of smg p21s, ras p21-like GTP-binding proteins

Novel regulatory proteins for smg p21A and -B, ras p21-like GTP-binding proteins (G proteins) having the same putative effector domain as ras p21s, were purified to near homogeneity from bovine brain cytosol and characterized. These regulatory proteins, designated as GDP dissociation stimulator (GDS) 1 and -2, stimulated the dissociation of both [3H]GDP and [35S] guanosine 5'-(3-O-thio)triphosphate (GTP gamma S) from smg p21s to the same extent. smg p21 GDS1 and -2 also stimulated the binding of [35S]GTP gamma S to the GDP-bound form of smg p21s but not that to the guanine nucleotide-free form. These actions of smg p21 GDS1 and -2 were specific for smg p21s and inactive for other ras p21/ras p21-like G proteins including c-Ha-ras p21, rhoB p20, and smg p25A. Neither smg p21 GDS1 nor -2 stimulated the GTPase activity of smg p21s and by itself showed [35S]GTP gamma S-binding or GTPase activity. smg p21 GDS1 and -2 showed very similar physical and kinetic properties and were indistinguishable by peptide map analysis. The Mr values of smg p21 GDS1 and -2 were estimated to be about 53,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and from the S values, indicating that smg p21 GDS1 and -2 are composed of a single polypeptide without a subunit structure. smg p21 GDS1 and -2 were distinguishable from GTPase activating proteins (GAPs) for the ras and rho proteins, and smg p21B, and GDP dissociation inhibitors for smg p25A and the rho proteins previously identified in bovine brain cytosol. These results indicate that bovine brain contains regulatory proteins for smg p21s that stimulate the dissociation of GDP from and thereby the subsequent binding of GTP to smg p21s in addition to smg p21 GAP. It is likely that the conversion from the GDP-bound inactive form of smg p21s to the GTP-bound active form is regulated by smg p21 GDS and that its reverse reaction is regulated by smg p21 GAP.     

Reactive sulfhydryl groups of alpha 39, a guanine nucleotide-binding protein from brain. Location and function

The guanine nucleotide-binding proteins which mediate hormonal inhibition of adenylate cyclase as well as hormonal regulation of other membrane functions are alpha, beta, and gamma heterotrimers which are structurally homologous to each other. In brain, the predominant guanine nucleotide-binding component is a 39-kDa protein whose physiological role is as yet unknown. We have used N-ethylmaleimide to define functionally important sulfhydryl groups on alpha 39. Three cysteine residues in the molecule are reactive in unliganded alpha 39. Alkylation of two of these is reduced when guanosine 5'-(3'-O-thio)triphosphate (GTP gamma S) is bound. We have isolated and sequenced tryptic peptides containing the three reactive cysteines. The octapeptide containing the GTP gamma S-insensitive cysteine is at a position equivalent to amino acids 106-113 of the transducin alpha subunit (Lochrie, M. A., Hurley, J. B., and Simon, M. I. (1985) Science 228, 96-99). However, the equivalent peptide in transducin does not contain a cysteine residue. Alkylation of this cysteine blocks ADP-ribosylation of cysteine 351 by pertussis toxin. However, alkylation does not prevent association of alpha with the beta X gamma subunits nor does it inhibit GTPase activity. The two GTP gamma S-sensitive cysteines are at positions equivalent to cysteines 139 and 286 of the transducin alpha subunit. Alkylation of these residues inhibits GTPase activity. Neither of these GTP gamma S-sensitive cysteines are in those regions of alpha 39 which are highly homologous to the GTP-binding site of elongation factor Tu (Jurnak, F. (1985) Science 230, 32-36). However, both are present in the brain 41-kDa guanine nucleotide-binding protein and in the two transducins. The conservation of these cysteine residues suggests that they are important for the function of the subunits.     

GTPases of translational apparatus

Protein biosynthesis is a complex biochemical process. It integrates multiple steps where different translation factors specifically interact with the ribosome in a precisely defined order. Among the translation factors one can find multiple GTP-binding or G-proteins. Their functioning is accompanied by GTP hydrolysis to the GDP and inorganic phosphate ion Pi. Ribosome stimulates the GTPase activity of the translation factors, thus playing a role analogues to GTPase-activating proteins (GAP). Translation factors--GTPases interact with the ribosome at all stages of protein biosynthesis. Initiation factor 2 (IF2) catalyse initiator tRNA binding to the ribosomal P-site and subsequent subunit joining. Elongation factor Tu (EF-Tu) is responsible for the aminoacyl-tRNA binding to the ribosomal A-site, while elongation factor G (EF-G) catalyses translocation of mRNA in the ribosome by one codon, accompanied by tRNA movement between the binding sites. In its turn, release factor 3 (RF3) catalyse dissociation of the ribosomal complex with release factors 1 or 2 (RF1 or RF2) following the peptide release. This review is devoted to the functional peculiarities of translational GTPases as related to other G-proteins. Particularly, to the putative GTPase activation mechanism, structure and functional cycles.     

Interferon-inducible mouse Mx1 protein that confers resistance to influenza virus is GTPase.

The murine Mx1 protein is an interferon-inducible nuclear protein and confers resistance to influenza virus infection even though the resistance mechanism is yet unclear. The Mx1 protein contains a tripartite GTP-binding domain consisting of GXXXXGKS, DXXG, and T/NKXD motifs. In the GTPase gene superfamily such as p21ras protein, signal-transducing G protein, and translation elongation factor, the GTPase activity plays a key role in each protein function. Here we show that GTPase activity is indeed associated with the intact Mx1 protein purified from Escherichia coli expressing Mx1 cDNA. Amino acid substitution within the GTP-binding motif led to significant reduction in the GTPase activity. Yeast vacuolar protein sorting (VPS1) protein and the rat microtubule-associated mechanochemical enzyme dynamin were found to be homologous to Mx1 not only in the tripartite GTP-binding motif, but also in the amino-terminal region of approximately 300 amino acids in length. The function of Mx1 is discussed in comparison with these proteins.     

A synthetic peptide corresponding to a sequence in the GTPase activating protein inhibits p21ras stimulation and promotes guanine nucleotide exchange

Amino acid sequence homology between the GTPase Activating Protein (GAP) and the GTP-binding regulatory protein, Gs alpha, suggests that a specific region of GAP primary structure (residues 891-898) may be involved in its stimulation of p21ras GTP hydrolytic activity (McCormick, F. [1989] Nature 340, 678-679). A peptide, designated p891, corresponding to GAP residues 891-906 (M891RTRVVSGFVFLRLIC906) was synthesized and tested for its ability to inhibit GAP-stimulated p21ras GTPase activity. At a concentration of 25 microM, p891 inhibited GAP activity approximately 50%. Unexpectedly, p891 also stimulated GTP binding to p21N-ras independent of GAP. This stimulation correlated with an enhancement of p21N-ras.GDP dissociation; an approximate 15-fold increase in the presence of 10 microM p891. In contrast, dissociation of the p21N-ras.GTP gamma S complex was unaffected by 10 microM p891. The p21N-ras.GDP complex was unresponsive to 100 microM mastoparan, a peptide toxin shown previously to accelerate GDP dissociation from the guanine nucleotide regulatory proteins, Gi and Go. p21H-ras, as well as the two p21H-ras effector mutants, Ala-38, and Ala-35, Leu-36, also exhibited increased rates of GDP dissociation in the presence of p891. Also tested were three ras-related GTP-binding proteins; rap, G25K and rac. The rap.-GDP complex was unaffected by 10 microM p891. Dissociation of the G25K- and rac.GDP complexes were enhanced slightly; approximately 1.3- and 1.8-fold over control, respectively. Thus, the inhibitory effect of p891 on GAP stimulation of p21ras suggests that amino acids within the region 891-906 of GAP may be essential for interaction with p21ras. In addition, p891 independently affects the nucleotide exchange properties of p21ras.     

Reactivity of a sulfhydryl group of the ras oncogene product p21 modulated by GTP binding

We have studied the sensitivity of sulfhydryl groups of a highly purified p21 protein of the v-rasH oncogene to a thiol-specific reagent, N-ethylmaleimide (NEM). Approximately 70% of GTP binding and autokinase activities of p21 were inactivated by NEM, and excessive amounts of GTP or GDP protected p21 activities. Thiol titration revealed the presence of one fast reactive cysteine residue, the susceptibility of which is modulated by GTP binding. A total of 4 and 6 residues, respectively, became titratable upon denaturation and reduction, suggesting the presence of a disulfide bond. This GTP-modulated sulfhydryl group was identified as Cys-80 in the following tryptic peptide sequence: NH2-Thr-Gly-Glu-Gly-Phe-Leu-Cys-Val-Phe-Ala-Ile-Asn-Asn-Thr-Lys-COOH. This is based on the comparative tryptic peptide mapping of [14C]NEM-modified p21 in the presence and absence of GTP. The GTP-modulated peptide co-chromatographed with a synthetic peptide of the predicted sequence. Amino acid analysis of the purified [14C]NEM-modified peptide from tryptic digests of p21 also confirmed its identity. This region of p21 shares an extensive sequence homology with various G-proteins and appears to be in the vicinity of the GTP-binding domain of these proteins.     

Regulation of the activity of eukaryotic peptide elongation factor 1 by autocatalytic phosphorylation

Highly purified peptide elongation factor 1 from rabbit reticulocytes liberates the terminal phosphate from [gamma-32P]GTP and incorporates it into its own protein. Approximately one phosphate residue becomes bound by one molecule of the factor. Only the eEF-1 alpha subunit of the factor (Mr 53 000) becomes phosphorylated as revealed by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate followed by autoradiography and by the incubation of [gamma-32P]GTP with individual subunits of the elongation factor separated by chromatofocusing in the presence of 5 M urea. The phosphorylation also takes place, though to a lesser extent, if the factor is incubated with Na2H32PO4, probably due to the presence of endogenous GTP bound in the molecule of the factor. The content of endogenous GTP in various factor preparations was 0.21-0.43 mol/mol factor. Phosphorylation of the peptide elongation factor is ribosome-independent, acid-labile and apparently autocatalytic since no other proteins are required for this reaction. Preincubation of the factor with GTP or with inorganic phosphate results in the phosphorylation of the factor and is followed by an enhanced binding of phenylalanyl-tRNA to 80S ribosomes in the presence of poly(U). This is accompanied by a dephosphorylation of the factor protein and thus the reversible autophosphorylation of the factor apparently activates its binding site for aminoacyl-tRNA. This is supported by the observation that sodium fluoride, which inhibits the dephosphorylation of the factor, blocks the factor-catalyzed binding of aminoacyl-tRNA to ribosomes. The incorporation of phosphate into factor protein also inhibits the formation of an eEF-1 X GDP complex, which is inactive in protein synthesis. Thus GDP liberated by the GTPase activity of the factor cannot affect its binding site for aminoacyl-tRNA. This may be the other reason for the enhanced activity of the phosphorylated factor. The autocatalytic GTP-dependent phosphorylation of the peptide elongation factor 1 apparently modifies its function and may thus play a regulatory role in protein synthesis.