Expression of elongation factor 1 beta' in Escherichia coli and its interaction with elongation factor 1 alpha from silk gland.

Silk gland elongation factor 1 (EF-1) consists of four subunits: alpha, beta, beta', and gamma. EF-1 beta beta' gamma catalyzes the exchange of GDP for GTP on EF-1 alpha and stimulates the binding of EF-1 alpha-dependent aminoacyl-tRNA to ribosomes. The carboxy-terminal regions of the EF-1 beta subunits from various species are highly conserved. We examined the region of EF-1 beta' that binds to EF-1 alpha by in vitro binding assays, and examined the GDP/GTP exchange activity using deletion mutants of a GST-EF1 beta' fusion protein. We thereby suggested a pivotal amino acid region, residues 189-222, of EF-1 beta' for binding to EF-1 alpha.     

Studies on the high molecular weight form of polypeptide chain elongation factor-1 from pig liver. III. Temperature-dependent dissociation into subunits in the presence of GTP

Dissociation of highly purified EF-1 alpha beta gamma (a high molecular weight form of polypeptide chain elongation factor-1) from pig liver into EF-1 alpha and EF-1 beta gamma at various temperatures was examined and the following results were obtained. (i) When dissociation of EF-1 alpha beta gamma was analyzed by gel filtration with Sephacryl S-200, it was found that in the absence of GTP, it did not dissociate at any temperature between 4 and 37 degrees C, whereas in the presence of GTP, it tended to dissociate with elevation of the temperature, and almost complete dissociation was observed at 32 degrees C. This indicated that the dissociation constant of EF-1 alpha beta gamma into EF-1 alpha and EF-1 beta gamma in the presence of GTP increased with increase in the temperature. (ii) When gel filtration was performed in the presence of both GTP and [14C]Phe-tRNA, the formation of a ternary complex of EF-1 alpha . GTP . [14C]Phe-tRNA from EF-1 alpha beta gamma was noted, and its amount was found to increase with elevation of the temperature. (iii) The amount of [14C]Phe-tRNA bound to ribosomes dependent on added EF-1 alpha beta gamma similarly increased with increase in the temperature, as in the case of ternary complex formation, whereas the binding of [14C]Phe-tRNA to ribosomes dependent on free EF-1 alpha proceeded fairly well even at 0 degrees C. From these results we concluded that among the reaction steps in the binding of [14C]Phe-tRNA to ribosomes dependent on EF-1 alpha beta gamma, dissociation of EF-1 alpha beta gamma to form EF-1 alpha . GTP and EF-1 beta gamma in the presence of GTP is the step which is strongly influenced by temperature.     

Interaction of subunits of polypeptide chain elongation factor I from pig liver. Formation of EF-1alpha.EF-1betagamma and EF-1beta complexes

In the preceding papers, we showed that one of the two complementar factors of polypeptide chain elongation factor 1 (EF-1) from pig liver, EF-1alpha, functionally corresponds to bacterial EF-Tu (Nagata, S., Iwasaki, K., and Kaziro, Y. (1976) Arch. Biochem. Biophys. 172, 168), while the other, EF-1betagamma, as well as one of its subunits, EF-1beta, corresponds to bacterial EF-Ts (Motoyoshi, K. and Iwasaki, K. (1977) J. Biochem. 82, 703). Therefore, the interaction between EF-1alpha and EF-1 betagamma or EF-1beta was was examined and the following results were obtained. i) EF-1betagamma catalytically promoted the exchange of [14C]GDP bound to EF-1alpha with exogenous [3H]GDP. ii). In the absence of the exogenous guanine nucleotide, EF-1betagamma as well as EF-1beta could displace GDP bound to EF-1alpha to form an EF-1alpha.EF-1betagamma as well as an EF-1alpha.EF-1beta complex. iii) The occurrence of EF-1alpha.EF-1betagamma and EF-1alpha.EF-1beta complexes was demonstrated by gel filtration on Sephadex G-150. These results strongly indicate that the mechanism of the action of EF-1betagamma or EF-1beta in converting EF-1alpha.GDP into EF-1alpha.GTP is analogous to bacterial EF-Ts, and the reaction is accomplished by the following reactions; EF-1alpha.GDP + EF-1betagamma (or EF-1beta) in equilibrium EF-1alpha.EF-1betagamma (or EF-1beta) + GDP; EF-1alpha.EF-1beta (or EF-1beta) + GTP IN EQUILIBRIUM EF-1alpha.GTP + EF-1betagamma (or EF-1beta).     

Detection and characterization of glutathione S-transferase activity in rice EF-1betabeta'gamma and EF-1gamma expressed in Escherichia coli.

Plant elongation factor EF-1 consists of four subunits (EF-1alphabetabeta'gamma). EF-1alpha. GTP catalyses the binding of aminoacyl-tRNA to the ribosome. EF-1beta and EF-1beta' catalyze the GDP/GTP exchange on EF-1alpha. GDP. However, the function of EF-1gamma, a subunit detected in eukaryotes, but not in prokaryotes remained unknown. This report demonstrates that rice EF-1betabeta'gamma and recombinant EF-1gamma possess glutathione S-transferase (GST) activity. The EF-1betabeta'gamma- or EF-1gamma-dependent GST activity is about one-fiftieth of the rice GST activity. The Km values of EF-1betabeta'gamma, EF-1gamma, and rice GST for glutathione and 1-chloro-2,4-dinitrobenzene are of about the same order. Although recombinant EF-1gamma is heat labile, active EF-1gamma was obtained by purifying it in the presence of 20% glycerol.     

Mapping the functional domains of the eukaryotic elongation factor 1 beta gamma

The functional domains of the eukaryotic elongation factor (EF) 1 beta gamma have been delineated with the use of limited proteolysis, protein microsequencing, gel electrophoresis under non-denaturing conditions and antibodies against EF-1 beta and EF-1 gamma. By means of limited proteolysis, it was possible to obtain large fragments of EF-1 beta. In contrast to amino-terminal fragments, those derived from the carboxy-terminal part of EF-1 beta were still active in enhancing the guanine nucleotide exchange of GDP bound to EF-1 alpha. With the same technique of limited proteolysis, it was possible to isolate a trypsin-resistant core from EF-1 beta gamma containing polypeptide chain fragments derived from both subunits. A polyvalent antiserum against EF-1 beta and two monoclonal antibodies against EF-1 gamma were used to identify the protein fragments in this core. The monoclonal antibodies were shown to recognize different epitopes, one localized on the amino-terminal and another on the carboxy-terminal half of EF-1 gamma. The antiserum against EF-1 beta and one of the monoclonal antibodies (mAb 36E5), which recognized the amino-terminal half of EF-1 gamma, reacted with this trypsin-resistant core. We conclude that the amino-terminal halves of both EF-1 beta and EF-1 gamma are firmly attached to each other, and that the carboxy-terminal part of EF-1 beta interacts with EF-1 alpha.     

Heterogeneity of the retinal G-protein transducin from frog rod photoreceptors. Biochemical identification and characterization of new subunits.

Transducin, a retinal G-protein, has been shown to exist as heterotrimers of alpha (39,000), beta (36,000), and gamma (approximately 7,000) subunits. Blue Sepharose CL-6B column chromatography of a transducin preparation extracted with a metal-free, low salt buffer containing GTP showed three distinct alpha and two distinct beta gamma activities in frog (Rana catesbeiana) rod outer segment. The binding of a hydrolysis-resistant GTP analog in these alpha fractions was proportional to the amount of the M(r) 39,000 protein. The first alpha was eluted in a complex with an inhibitory subunit of cGMP phosphodiesterase, but alpha subunits in the second and the third fractions were not complexed with any proteins. Two-dimensional gel electrophoresis and characterization with regard to the interaction with the inhibitory subunit of cGMP phosphodiesterase suggested that the first and the second alpha s were the same protein; however, the third alpha showed different characters as follows. We designated alpha in the first two fractions as alpha 1, and alpha in the third fraction as alpha 2. Nonlinear regression analysis for the binding of a hydrolysis-resistant GTP analog to both alpha subunits revealed a single class of GTP binding sites with an apparent stoichiometry of 1 mol of GTP/mol of alpha. Compared with alpha 1, alpha 2 required larger amounts of rhodopsin and beta gamma for the binding of a hydrolysis-resistant GTP analog. alpha 2 also showed less binding with the inhibitory subunit of cGMP phosphodiesterase. Both alpha 1 and alpha 2 complexed with beta gamma or beta delta (described below) were substrates for pertussis toxin-dependent ADP-ribosylation. The protein profiles of two beta gamma fractions revealed that the main fraction was composed of a beta gamma complex; however, the second active fraction was composed of beta complexed with delta (M(r) 12,000). Compared with beta gamma, beta delta stimulated GTP binding to alpha 1 at approximately 10-fold higher concentration. Two-dimensional gel electrophoresis revealed five beta and two gamma isoforms in beta gamma. Only one beta isoform was present in beta delta. The diversity of transducin subunits may reflect different signaling pathways in visual signal transduction.     

Moonlighting functions of polypeptide elongation factor 1: from actin bundling to zinc finger protein R1-associated nuclear localization

Eukaryotic polypeptide elongation factor EF-1 is not only a major translational factor, but also one of the most important multifunctional (moonlighting) proteins. EF-1 consists of four different subunits collectively termed EF-1alphabeta beta'gamma and EF-1alphabeta gammadelta in plants and animals, respectively. EF-1alpha x GTP catalyzes the binding of aminoacyl-tRNA to the A-site of the ribosome. EF-1beta beta'gamma (EF-1beta and EF-1beta'), catalyzes GDP/GTP exchange on EF-1alpha x GDP to regenerate EF-1alpha x GTP. EF-1gamma has recently been shown to have glutathione S-transferase activity. EF-2 catalyzes the translocation of peptidyl-tRNA from the A-site to the P-site on the ribosome. Recently, molecular mimicry among tRNA, elongation factors, releasing factor (RF), and ribosome recycling factor (RRF) has been demonstrated and greatly improved our understanding of the mechanism of translation. Moreover, eukaryotic elongation factors have been shown to be concerned or likely to be concerned in various important cellular processes or serious diseases, including translational control, signal transduction, cytoskeletal organization, apoptosis, adult atopic dermatitis, oncogenic transformation, nutrition, and nuclear processes such as RNA synthesis and mitosis. This article aims to overview the recent advances in protein biosynthesis, concentrating on the moonlighting functions of EF-1.     

Kinetic studies on the role of elongation factors 1 beta and 1 gamma in protein synthesis

An equilibrium isotope exchange technique was used to measure in an Artemia system the catalytic influence of elongation factor (EF) 1 beta gamma on the dissociation of GDP from the complex of elongation factor 1 alpha.[3H] GDP in the presence of an excess of free GDP. The kinetic data demonstrate that, in analogy to procaryotes, dissociation of GDP occurs via the formation of a transient ternary complex of EF-1 alpha.GDP.EF-1 beta gamma. The rate constants for the dissociation of GDP from EF-1 alpha.GDP and from the ternary complex EF-1 alpha.GDP.EF-1 beta gamma were found to be 0.7 x 10(-3) and greater than or equal to 0.7 s-1, respectively. The equilibrium association constants of GDP to EF-1 alpha.EF-1 beta gamma and of EF-1 beta gamma to EF-1 alpha.GDP were found to be 2.3 x 10(5) and 4.2 x 10(5) M-1, respectively. Judged from the known elongation rate in vivo and kinetic constants of nucleotide exchange, it was estimated that the recycling of EF-1 alpha may be a rate-controlling step in eucaryotic translation. As a model for GTP exchange, the formation of the ternary EF-1 alpha.guanylyl (beta gamma-methylene)diphosphonate.EF-1 beta gamma complex was also studied. It was observed that both an increase of the level of aminoacyl-tRNA and of temperature favored the dissociation of this complex, thereby enabling EF-1 beta gamma to recycle as a catalyst. This behavior would explain the frequent occurrence of a heavy form of elongation factor 1 in extracts of the eucaryotic cell.     

Purification and characterization of three elongation factors, EF-1 alpha, EF-1 beta gamma, and EF-2, from wheat germ

Three elongation factors, EF-1 alpha, EF-1 beta gamma and EF-2, have been isolated from wheat germ. EF-1 alpha and EF-2 are single polypeptides with molecular weights of approximately 52,000 and 102,000, respectively. The most highly purified preparations of EF-1 beta gamma contain four polypeptides with molecular weights of approximately 48,000, 46,000 and 36,000, 34,000. EF-1 alpha supports poly(U)-directed binding of Phe-tRNA to wheat germ ribosomes and catalyzes the hydrolysis of GTP in the presence of ribosomes, poly(U), and Phe-tRNA. EF-2 catalyzes the hydrolysis of GTP in the presence of ribosomes alone and is ADP-ribosylated by diphtheria toxin to the extent of 0.95 mol of ADP-ribose/mol of EF-2. EF-1 beta gamma decreases the amount of EF-1 alpha required for polyphenylalanine synthesis about 20-fold. EF-1 beta gamma enhances the ability to EF-1 alpha to support the binding of Phe-tRNA to the ribosomes and enhances the GTPase activity of EF-1 alpha. Wheat germ EF-1 alpha, EF-1 beta gamma, and EF-2 support polyphenylalanine synthesis on rabbit reticulocyte ribosomes as well as on yeast ribosomes.     

Role of yeast peptide elongation factor 3 (EF-3) at the AA-tRNA binding step

The stimulatory effect of peptide elongation factor 3 (EF-3), which is uniquely required for the yeast elongation cycle, on the step of binding of aminoacyl-tRNA (AA-tRNA) to ribosomes has been investigated in detail. Yeast EF-1 alpha apparently functions in a stoichiometric manner in the binding reaction of AA-tRNA to the ribosomes. The addition of EF-3 and ATP to this binding system strikingly stimulated the binding reaction, and the stimulated reaction proceeded catalytically with respect to both EF-1 alpha and EF-3, accompanied by ATP hydrolysis, indicating that EF-3 stimulated the AA-tRNA binding reaction by releasing EF-1 alpha from the ribosomal complex, thus recycling it. This binding stimulation by EF-3 was in many respects distinct from that by EF-1 beta gamma. The idea that EF-3 may participate in the regeneration of GTP from ATP and the formed GDP, as indicated by the findings that the addition of EF-3 along with ATP allowed the AA-tRNA binding and Phe polymerization reactions to proceed even in the presence of GDP in place of GTP, was not verified by the results of direct measurement of [32P]GTP formation from [gamma-32P]ATP and GDP under various conditions. Examination of the stability of the bound AA-tRNA disclosed the different binding states of AA-tRNA on ribosomes between in the cases of the complexes formed with EF-1 alpha alone, or factor-independently, and with EF-1 alpha and EF-3.(ABSTRACT TRUNCATED AT 250 WORDS)     

The GTP-binding protein of rod outer segments. I. Role of each subunit in the GTP hydrolytic cycle

The GTP-binding protein of Bufo marinus rod outer segments (ROS) is composed of 3 subunits: G alpha, 39,000; G beta, 36,000; and G gamma, approximately 6,500. A stepwise analysis of the GTP hydrolytic cycle (GTP binding, GTP hydrolysis, and GDP release) was facilitated by using purified subunits of the GTP-binding protein. When G alpha and G beta, gamma concentrations were held constant, the initial rate of guanosine-5'-O-(3-thiotriphosphate) (GTP gamma-s) binding to G alpha was dependent upon the amount of bleached rhodopsin present (as illuminated, urea-washed ROS disc membranes). When G alpha and the quantity of these membranes was held constant, the initial rate of GTP gamma-s binding to G alpha was markedly enhanced by increasing the amount of G beta, gamma. G beta preparations (free of G gamma) also stimulated the binding of GTP gamma-s to G alpha to the same extent as G beta, gamma preparations, suggesting that G gamma is not an essential component of the G beta, gamma-dependent stimulation of the rate of GTP gamma-s binding to G alpha. Nonlinear regression analysis revealed a single class of binding sites with an apparent stoichiometry of 1 mol of site/mol of G alpha under optimal binding conditions. Following GTP binding to G alpha, the GTP X G alpha complex dissociates from G beta, gamma which remains primarily bound to the ROS disc membranes. Moreover, while GTP remains in excess, the rates of GTP hydrolysis exhibited saturation in the presence of increasing amounts of G beta, gamma. Nonlinear regression analysis of these data argues against a direct role for G beta, gamma in the hydrolysis of GTP. Thus, both topologic and kinetic data support the concept that GTP hydrolysis is carried out by G alpha alone. After hydrolysis of GTP, the GDP X G alpha complex returned to the ROS disc membrane when G beta, gamma was present on the membrane surface, in the presence and absence of light. Without guanine nucleotides GDP release occurred in the presence of illuminated ROS disc membranes and G beta, gamma. Guanine nucleotides (GTP gamma-s approximately equal to GTP approximately equal to guanosine 5'-(beta, gamma-imido)triphosphate greater than GDP) could effectively displace GDP from G alpha under these conditions.(ABSTRACT TRUNCATED AT 400 WORDS)     

The solution structure of the guanine nucleotide exchange domain of human elongation factor 1beta reveals a striking resemblance to that of EF-Ts from Escherichia coli.

BACKGROUND: In eukaryotic protein synthesis, the multi-subunit elongation factor 1 (EF-1) plays an important role in ensuring the fidelity and regulating the rate of translation. EF-1alpha, which transports the aminoacyl tRNA to the ribosome, is a member of the G-protein superfamily. EF-1beta regulates the activity of EF-1alpha by catalyzing the exchange of GDP for GTP and thereby regenerating the active form of EF-1alpha. The structure of the bacterial analog of EF-1alpha, EF-Tu has been solved in complex with its GDP exchange factor, EF-Ts. These structures indicate a mechanism for GDP-GTP exchange in prokaryotes. Although there is good sequence conservation between EF-1alpha and EF-Tu, there is essentially no sequence similarity between EF-1beta and EF-Ts. We wished to explore whether the prokaryotic exchange mechanism could shed any light on the mechanism of eukaryotic translation elongation. RESULTS: Here, we report the structure of the guanine-nucleotide exchange factor (GEF) domain of human EF-1beta (hEF-1beta, residues 135-224); hEF-1beta[135-224], determined by nuclear magnetic resonance spectroscopy. Sequence conservation analysis of the GEF domains of EF-1 subunits beta and delta from widely divergent organisms indicates that the most highly conserved residues are in two loop regions. Intriguingly, hEF-1beta[135-224] shares structural homology with the GEF domain of EF-Ts despite their different primary sequences. CONCLUSIONS: On the basis of both the structural homology between EF-Ts and hEF-1beta[135-224] and the sequence conservation analysis, we propose that the mechanism of guanine-nucleotide exchange in protein synthesis has been conserved in prokaryotes and eukaryotes. In particular, Tyr181 of hEF-1beta[135-224] appears to be analogous to Phe81 of Escherichia coli EF-Ts.     

Structural and functional studies of cross-linked Go protein subunits

The guanine nucleotide binding proteins (G proteins) that couple hormone and other receptors to a variety of intracellular effector enzymes and ion channels are heterotrimers of alpha, beta, and gamma subunits. One way to study the interfaces between subunits is to analyze the consequences of chemically cross-linking them. We have used 1,6-bismaleimidohexane (BMH), a homobifunctional cross-linking reagent that reacts with sulfhydryl groups, to cross-link alpha to beta subunits of Go and Gi-1. Two cross-linked products are formed from each G protein with apparent molecular masses of 140 and 122 kDa on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Both bands formed from Go reacted with anti-alpha o and anti-beta antibody. The mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis is anomalous since the undenatured, cross-linked proteins have the same Stokes radius as the native, uncross-linked alpha beta gamma heterotrimer. Therefore, each cross-linked product contains one alpha and one beta subunit. Activation of Go by guanosine 5'-3-O-(thio)triphosphate (GTP gamma S) does not prevent cross-linking of alpha to beta gamma, consistent with an equilibrium between associated and dissociated subunits even in the presence of GTP gamma S. The same cross-linked products of Go are formed in brain membranes reacted with BMH as are formed in solution, indicating that the residues cross-linked by BMH in the pure protein are accessible when Go is membrane bound. Analysis of tryptic peptides formed from the cross-linked products indicates that the alpha subunit is cross-linked to the 26-kDa carboxyl-terminal portion of the beta subunit. The cross-linked G protein is functional, and its alpha subunit can change conformation upon binding GTP gamma S. GTP gamma S stabilizes alpha o to digestion by trypsin (Winslow, J.W., Van Amsterdam, J.R., and Neer, E.J. (1986) J. Biol. Chem. 261, 7571-7579) and also stabilizes the alpha subunit in the cross-linked product. Cross-linked G o can be ADP-ribosylated by pertussis toxin. This ADP-ribosylation is inhibited by GTP gamma S with a concentration dependence that is indistinguishable from that of the control, uncross-linked G o. These two kinds of experiments indicate that alpha o is able to change its conformation even though it cannot separate completely from beta gamma. Thus, although dissociation of the subunits accompanies activation of G o in solution, it is not obligatory for a conformational change to occur in the alpha subunit.     

Peptide elongation factor 1 from yeasts: purification and biochemical characterization of peptide elongation factors 1 alpha and 1 beta (gamma) from Saccharomyces carlsbergensis and Schizosaccharomyces pombe

Cytoplasmic elongation factor 1 alpha (EF-1 alpha) [corrected] was purified to homogeneity in high yield from the two different yeasts Saccharomyces carlsbergensis (S. carls.) and Schizosaccharomyces pombe (S. pombe). The purification was easily achieved by CM-Sephadex column chromatography of the breakthrough fractions from DEAE-Sephadex chromatography of cell-free extracts. The basic proteins have a molecular weight of 47,000 for the S. carls. factor and of 49,000 for the S. pombe factor. While the purified yeast EF-1 alpha s function analogously to other eukaryotic factors and the E. coli EF-Tu in Phe-tRNA binding and polyphenylalanine synthesis, the yeast factor unusually hydrolyzed GTP on yeast ribosomes upon addition of Phe-tRNA in the absence of poly(U) as mRNA. This novelty is probably owing to the yeast ribosomes, which are assumed to lack elongation factor 3-equivalent component(s). Trypsin and chymotrypsin selectively cleaved the two yeast factors to generate resistant fragments with the same molecular weight of 43,000 (by trypsin) and of 44,000 (by chymotrypsin), respectively. Those cleavage sites were characteristically protected by the presence of several ligands bound to EF-1 alpha such as GDP, GTP, and aminoacyl-tRNA. Based on the sequence analysis of the fragments generated by the two proteases, the partial amino acid sequence of the S. carls. EF-1 alpha was deduced to be in accordance with the N-terminal region covering positions (1) to 94 and two Lys residues at the C-terminal end of the predicted total sequence of the Saccharomyces cerevisiae (S. cerev.) factor derived from DNA analysis, except for a few N-terminal residues, confirming the predicted S. cerev. sequence at the protein level. EF-1 beta and EF-1 beta gamma were isolated and highly purified as biologically active entities from the two yeasts. EF-1 beta s from the two yeasts have the same molecular weight of 27,000, whereas component gamma of the S. carls. EF-1 beta gamma showed a higher molecular weight (47,000) than that of the S. pombe factor (40,000). It was also shown that a stoichiometric complex was formed between EF-1 alpha and EF-1 beta gamma from S. pombe. Furthermore, a considerable amount of Phe-tRNA binding activity was distributed in the EF-1H (probably EF-1 alpha beta gamma) fraction from freshly prepared cell-free extracts of yeast.     

Protein synthesis in yeast. Isolation of variant forms of elongation factor 1 from the yeast Saccharomyces cerevisiae

Two species of the elongation factor 1 (EF-1) differing in molecular weight, subunit composition, and isoelectric point have been isolated from cell-free extracts of the yeast Saccharomyces cerevisiae. The ratio of these two forms of EF-1 activity (EF-1 alpha and EF-1H) seem to vary in different strains and upon the growth phase from which the cells have been isolated. The log phase cells of a protease negative yeast strain EJ101 show a distribution of EF-1 alpha and EF-1H in the ratio of 3:1. Another laboratory yeast strain, D-587-4B, shows a distribution pattern of 4:1. The two forms of EF-1 are completely separable by ion exchange, gel permeation, and hydrophobic and affinity chromatography. Yeast EF-1 alpha is a single polypeptide of molecular weight 50,000 and has an isoelectric point of 8.9. The newly identified form of the yeast EF-1 (EF-1H) has a molecular weight of 200,000. The isoelectric point of this protein is around 5.5. Electrophoresis of the partially purified EF-1H in polyacrylamide gel containing sodium dodecyl sulfate indicates the presence of three nonidentical polypeptides having molecular weights of 50,000, 47,000, and 33,000. The three polypeptides are present in the ratio of 2:1:1. EF-1H is readily converted to EF-1 alpha and EF-1 beta gamma on anion exchange columns. The 50,000 dalton component of EF-1H immunologically cross-reacts with the antibody to EF-1 alpha. The other two polypeptides do not. On the basis of molecular weight, EF-1H is 2-3-fold more active than EF-1 alpha in poly(U)-dependent polyphenylalanine synthesis. EF-1H exchanges nucleotide (GDP----GTP) at a faster rate than EF-1 alpha. Both EF-1 alpha and EF-1H exhibit similar binding constants for GDP and GTP although the affinity of EF-1 alpha for guanine nucleotides is several-fold higher than that of EF-1H. The 33,000-dalton component of EF-1H appears to be functionally analogous to EF-1 beta (Ts) isolated from other eukaryotic sources. The function of EF-1 gamma is unknown.     

Phosphorylation of elongation factor 1 (EF-1) and valyl-tRNA synthetase by protein kinase C and stimulation of EF-1 activity

A high Mr complex isolated from rabbit reticulocytes contains valyl-tRNA synthetase and the four subunits of elongation factor 1 (EF-1). Previously, valyl-tRNA synthetase and the alpha, beta, and delta subunits of EF-1 were shown to be phosphorylated in reticulocytes in response to phorbol 12-myristate 13-acetate (PMA). Phosphorylation of the complex was accompanied by an increase in both valyl-tRNA synthetase and EF-1 activity (Venema, R. C., Peters, H. I., and Traugh, J. A. (1991) J. Biol. Chem., 266, 11993-11998). To investigate phosphorylation of the valyl-tRNA synthetase EF-1 complex in vitro by protein kinase C, the complex has been purified to apparent homogeneity from rabbit reticulocytes by gel filtration on Bio-Gel A-5m, affinity chromatography on tRNA-Sepharose, and fast protein liquid chromatography on Mono Q. Valyl-tRNA synthetase and the beta and delta subunits of EF-1 in the complex are highly phosphorylated by protein kinase C (0.5-0.9 mol of phosphate/mol of subunit), while EF-1 alpha is phosphorylated to a lesser extent (0.2 mol/mol). However, the isolated EF-1 alpha subunit is highly phosphorylated (2.0 mol/mol). Phosphopeptide mapping of EF-1 alpha shows that the same sites are modified by protein kinase C in vitro and in PMA-treated cells. Phosphorylation of the valyl-tRNA synthetase.EF-1 complex results in a 3-fold increase in activity of EF-1 as measured by poly(U)-directed polyphenylalanine synthesis; no effect of phosphorylation is detected with valyl-tRNA synthetase and isolated EF-1 alpha. Thus, phosphorylation and activation of EF-1 by protein kinase C, which has been shown to occur in vitro as well as in reticulocytes, may have a role in PMA stimulation of translational rates.     

Biological characterization of various forms of elongation factor 1 from rabbit reticulocytes

Two forms of elongation factor 1 (EF-1) have been tested for a variety of biological functions. One form, EF-1H, is a high-molecular-weight aggregate (M_r > 500,000) containing four distinct polypeptides (α, β, γ, δ). The other form, EF-1α, consists of a single polypeptide which is the same as the α subunit of EF-1H. Both EF-1α and EF-1H function catalytically in binding Phe-tRNA to ribosomes, and in poly(U)-directed polyphenylalanine synthesis. The activity of EF-1α is enhanced in polyphenylalanine synthesis by a complementary component, EF-1βδ. It is also shown that EF-1βδ can facilitate an exchange of EF-1α-bound GDP for GTP. The EF-1α dissociation constants for GDP and GTP were 0.47 and 0.55 μm respectively, while the EF-1H dissociation constants for GDP and GTP were 2.0 and 1.6 μm, respectively. Thus, while EF-1α and EF-1H had approximately the same affinities for GDP and GTP, the EF-1α dissociation constants were about fourfold lower than the EF-1H dissociation constants. Attempts to isolate complexes of EF-1α or EF-1H with GTP and Phe-tRNA or with GTP, Phe-tRNA, and ribosomes were unsuccessful using either Millipore filters, gel filtration, or sucrose density gradients. The results presented in this report, along with studies from other laboratories, strengthen the hypothesis that the general mechanism of the elongation cycle is similar in eucaryotes and procaryotes.     

Effects of Mg2+ and the beta gamma-subunit complex on the interactions of guanine nucleotides with G proteins

Mg2+ interacts with the alpha subunits of guanine nucleotide-binding regulatory proteins (G proteins) in the presence of guanosine-5'-[gamma-thio]triphosphate (GTP-gamma S) to form a highly fluorescent complex from which nucleotide dissociates very slowly. The apparent Kd for interaction of G alpha X GTP gamma S with Mg2+ is approximately 5 nM, similar to the Km for G protein GTPase activity X G beta gamma increases the rate of dissociation of GTP gamma S from G alpha X GTP gamma S or G alpha X GTP gamma S X Mg2+ at low concentrations of Mg2+. When the concentration of Mg2+ exceeds 1 mM, G beta gamma dissociates from G beta gamma X G alpha X GTP gamma S X Mg2+. Compared with the dramatic effect of Mg2+ on binding of GTP gamma S to G alpha, the metal has relatively little effect on the binding of GDP. However, G beta gamma increases the affinity of G alpha for GDP by more than 100-fold. High concentrations of Mg2+ promote the dissociation of GDP from G beta gamma X G alpha X GDP, apparently without causing subunit dissociation. The steady-state rate of GTP hydrolysis is strictly correlated with the rate of dissociation of GDP from G alpha under all conditions examined. Thus, there are at least two sites for interaction of Mg2+ with G protein-nucleotide complexes. Furthermore, binding of G beta gamma and GTP gamma S to G alpha is negatively cooperative, while the binding interaction between G beta gamma and GDP is strongly positive.     

Interaction network of human aminoacyl-tRNA synthetases and subunits of elongation factor 1 complex

Aminoacyl-tRNA synthetases (ARSs) ligate amino acids to their cognate tRNAs. It has been suggested that mammalian ARSs are linked to the EF-1 complex for efficient channeling of aminoacyl tRNAs to ribosome. Here we systemically investigated possible interactions between human ARSs and the subunits of EF-1 (alpha, beta, gamma, and delta) using a yeast two-hybrid assay. Among the 80 tested pairs, leucyl- and histidyl-tRNA synthetases were found to make strong and specific interaction with the EF-1gamma and beta while glu-proly-, glutaminyl-, alanyl-, aspartyl-, lysyl-, phenylalanyl-, glycyl-, and tryptophanyl-tRNA synthetases showed moderate interactions with the different EF-1 subunits. The interactions of leucyl- and histidyl-tRNA synthetase with the EF-1 complex were confirmed by immunoprecipitation and in vitro pull-down experiments. Interestingly, the aminoacylation activities of these two enzymes, but not other ARSs, were stimulated by the cofactor of EF-1, GTP. These data suggest that a systematic interaction network may exist between mammalian ARSs and EF-1 subunits probably to enhance the efficiency of in vivo protein synthesis.     

Rhodopsin and the retinal G-protein distinguish among G-protein beta gamma subunit forms

The beta gamma subunits of G-proteins are composed of closely related beta 35 and beta 36 subunits tightly associated with diverse 6-10 kDa gamma subunits. We have developed a reconstitution assay using rhodopsin-catalyzed guanosine 5'-3-O-(thio)triphosphate (GTP gamma S) binding to resolved alpha subunit of the retinal G-protein transducin (Gt alpha) to quantitate the activity of beta gamma proteins. Rhodopsin facilitates the exchange of GTP gamma S for GDP bound to Gt alpha beta gamma with a 60-fold higher apparent affinity than for Gt alpha alone. At limiting rhodopsin, G-protein-derived beta gamma subunits catalytically enhance the rate of GTP gamma S binding to resolved Gt alpha. The isolated beta gamma subunit of retinal G-protein (beta 1, gamma 1 genes) facilitates rhodopsin-catalyzed GTP gamma S exchange on Gt alpha in a concentration-dependent manner (K0.5 = 254 +/- 21 nM). Purified human placental beta 35 gamma, composed of beta 2 gene product and gamma-placenta protein (Evans, T., Fawzi, A., Fraser, E.D., Brown, L.M., and Northup, J.K. (1987) J. Biol. Chem. 262, 176-181), substitutes for Gt beta gamma reconstitution of rhodopsin with Gt alpha. However, human placental beta 35 gamma facilitates rhodopsin-catalyzed GTP gamma S exchange on Gt alpha with a higher apparent affinity than Gt beta gamma (K0.5 = 76 +/- 54 nM). As an alternative assay for these interactions, we have examined pertussis toxin-catalyzed ADP-ribosylation of the Gt alpha subunit which is markedly enhanced in rate by beta gamma subunits. Quantitative analyses of rates of pertussis modification reveal no differences in apparent affinity between Gt beta gamma and human placental beta 35 gamma (K0.5 values of 49 +/- 29 and 70 +/- 24 nM, respectively). Thus, the Gt alpha subunit alone does not distinguish among the beta gamma subunit forms. These results clearly show a high degree of functional homology among the beta 35 and beta 36 subunits of G-proteins for interaction with Gt alpha and rhodopsin, and establish a simple functional assay for the beta gamma subunits of G-proteins. Our data also suggest a specificity of recognition of beta gamma subunit forms which is dependent both on Gt alpha and rhodopsin. These results may indicate that the recently uncovered diversity in the expression of beta gamma subunit forms may complement the diversity of G alpha subunits in providing for specific receptor recognition of G-proteins.