Effects of the antibiotic pulvomycin on the elongation factor Tu-dependent reactions. Comparison with other antibiotics

The antibiotic pulvomycin is an inhibitor of protein synthesis that prevents the formation of the ternary complex between elongation factor (EF-) Tu.GTP and aminoacyl-tRNA. In this report, novel aspects of its action on EF-Tu are described. Pulvomycin markedly affects the equilibrium and kinetics of the EF-Tu-nucleotide interaction, particularly of the EF-Tu.GTP complex. The binding affinity of EF-Tu for GTP is increased 1000 times, mainly as the consequence of a dramatic decrease in the dissociation rate of this complex. In contrast, the affinity for GDP is decreased 10-fold due to a marked increase in the dissociation rate of EF-Tu.GDP (25-fold) that mimics the action of EF-Ts, the GDP/GTP exchange factor of EF-Tu. The effects of pulvomycin and EF-Ts can coexist and are simply additive, supporting the conclusion that these two ligands interact with different sites of EF-Tu. This is further confirmed on native PAGE by the ability of EF-Tu to bind the EF-Ts and the antibiotic simultaneously. Pulvomycin enhances the intrinsic EF-Tu GTPase activity, like kirromycin, though to a much more modest extent. As with kirromycin, this stimulation depends on the concentration and nature of the monovalent cations, Li(+) being the most effective one, followed by Na(+), K(+), and NH(4)(+). In the presence of pulvomycin (in contrast to kirromycin), aa-tRNA and/or ribosomes do not enhance the GTPase activity of EF-Tu. The property of pulvomycin to modify selectively the conformation(s) of EF-Tu is also supported by its effect on heat- and urea-dependent denaturation, and tryptic digestion of the protein. Specific differences and similarities between the action of pulvomycin and the other EF-Tu-specific antibiotics are described and discussed.     

New antibiotic that acts specifically on the GTP-bound form of elongation factor Tu.

The new thiazolyl peptide antibiotic GE2270 A, isolated from Planobispora rosea strain ATCC 53773, is shown to inhibit bacterial protein biosynthesis in vitro by affecting specifically the GTP-bound form of elongation factor Tu (EF-Tu). The 'off' rate of EF-Tu.GTP is slowed down 400-fold, locking GTP on EF-Tu, whereas EF-Tu.GDP is unaffected. Therefore, on the EF-Tu.guanine nucleotide interaction, GE2270 A mimicks the effect of aa-tRNA. In line with this, the binding of aa-tRNA to EF-Tu.GTP is hindered by the antibiotic, as shown by the absence of a stable ternary complex and the inhibition of the enzymatic binding of aa-tRNA to the ribosome. This blocks the elongation cycle. GE2270 A does not essentially modify the intrinsic GTPase activity of EF-Tu, but impairs the stimulation by ribosomes of this reaction. The negative effect of GE2270 A on the EF-Tu.GTP interaction with aa-tRNA bears similarities with that of the structurally unrelated pulvomycin, whereas marked differences were found by comparing the effects of these two antibiotics on EF-Tu.GDP. This work emphasizes the varieties of the transitional conformations which tune the EF-Tu interaction with GTP and GDP.     

Isolation and characterization of nucleic-acid-like polymers containing glucose from Ehrlich ascites tumor cells

In this work, we have studied the effect of aa-tRNA and derived 3' aminoacylated fragments on the EF-Tu GTPase in the presence of kirromycin, using two systems: without and with ribosomes. The aa-tRNA fragments were obtained by enzymatic digestion. Procedures for the enzymatic preparation of C-A-Val and Val-tRNA Val1 3' half molecule, as well as a purification method for short 3' aminoacylated fragments based on the amino group charge, were newly developed for this work. Aminoacyl-adenosine was found to be able to stimulate the EF-Tu x kirromycin GTPase, but only to a very small extent. Increasing the length of the aminoacylated fragments increased the stimulatory effect as follow: A-Val much less than C-A-Val less than C-C-A-Val less than 3' valyladenosine dodecanucleotide much less than Val-tRNA Val1 3' half molecule less than Val-tRNA Val1. The presence of ribosomes did not affect the order of effectiveness, but increased the basic GTPase activity of EF-Tu x kirromycin and the stimulation by aa-tRNA, its 3' half molecule and even more by its 3' short fragments. The effect of aa-tRNA and derived 3' fragments in the absence of ribosomes was not influenced by MgCl2 concentrations of 5-30 mM whereas, in the presence of ribosomes, low concentrations of MgCl2 (5 mM) greatly reduced the stimulation of aa-tRNA and, to a lesser extent, also the effect of the C-C-A-aa as well as the basic activity of the EF-Tu x kirromycin GTPase. The extent of the stimulation by aa-tRNA, and even more by C-C-A-aa, depends on the nature of the amino acid. Among the aminoacyl side chains tested (Arg-, Phe-, Val-, Met-, Leu-, Lys-) arginine was found to be the most active and leucine the least. Our results show that (a) the 3' aminoacylated extremity is of prime importance for the stimulation of the EF-Tu GTPase, (b) in the 3' extremity there are critical sequences for the interaction with EF-Tu and (c) other domains of the aa-tRNA molecule are capable of influencing this reaction: one of the most important is the region including the T psi C loop and stem.     

Effects of the mutation glycine-222----aspartic acid on the functions of elongation factor Tu

We have studied the properties of a mutant elongation factor Tu, encoded by tufB (EF-TuBo), in which Gly-222 is replaced by Asp. For its purification from the kirromycin-resistant EF-Tu encoded by tufA (EF-TuAr), a method was developed by exploiting the different affinities to kirromycin of the two factors and the competition between kirromycin and elongation factor Ts (EF-Ts) for binding to EF-Tu. The resulting EF-TuBo kirromycin and EF-TuAr EF-Ts complexes are separated by chromatography on diethylaminoethyl-Sephadex A-50. For the first time we have succeeded in obtaining a tufB product in homogeneous form. Compared with wild-type EF-Tu, EF-TuBo displays essentially the same affinity for GDP and GTP, with only the dissociation rate of EF-Tu GTP being slightly faster. Protection of amino-acyl-tRNA (aa-tRNA) against nonenzymatic deacylation by different EF-Tu species indicates that conformational alterations occur in the ternary complex EF-TuBo GTP aa-tRNA. However, the most dramatic modification is found in the EF-TuBo interaction with the ribosome. Its activity in poly(Phe) synthesis as well as in the GTPase activity associated with the interaction of its ternary complex with the ribosome mRNA complex requires higher Mg2+ concentrations than wild-type EF-Tu (Mg2+ optimum at 10-14 vs. 6 mM), even if EF-TuBo can sustain enzymatic binding of aa-tRNA to ribosomes at low Mg2+. The anomalous behavior of EF-TuBo is reflected in a remarkable increase of the fidelity in poly(Phe) synthesis, especially at high Mg2+ concentrations.(ABSTRACT TRUNCATED AT 250 WORDS)     

A chimeric elongation factor containing the putative guanine nucleotide binding domain of archaeal EF-1 alpha and the M and C domains of eubacterial EF-Tu.

A recombinant chimeric elongation factor containing the region of EF-1 alpha from Sulfolobus solfataricus harboring the site for GDP and GTP binding and GTP hydrolysis (SsG) and domains M and C of Escherichia coli EF-Tu (EcMC) was studied. SsG-EcMC did not sustain poly(Phe) synthesis in either S. solfataricus or E. coli assay system. This was probably due to the inability of the chimera to interact with aa-tRNA. The three-dimensional modeling of SsG-EcMC indicated only small structural differences compared to the Thermus aquaticus EF-Tu in the ternary complex with aa-tRNA and GppNHp, which did not account for the observed inability to interact with aa-tRNA. The addition of the nucleotide exchange factor SsEF-1 beta was not required for poly(Phe) synthesis since the chimera was already able to exchange [(3)H]GDP for GTP at very high rate even at 0 degrees C. Compared to that of SsEF-1 alpha, the affinity of the chimera for guanine nucleotides was increased and the k(cat) of the intrinsic GTPase was 2-fold higher. The heat stability of SsG-EcMC was 3 and 13 degrees C lower than that displayed by SsG and SsEF-1alpha, respectively, but 30 degrees C higher than that of EcEF-Tu. This pattern remained almost the same if the melting curves of the proteins being investigated were considered instead. The chimeric elongation factor was more thermophilic than SsG and SsEF-1 alpha up to 70 degrees C; at higher temperatures, inactivation occurred.     

The influence of tRNA located at the P-site on the turnover of EF-Tu.GTP on ribosomes.

The turnover of EF-Tu.GTP on poly-U programmed ribosomes was measured both in the presence and in the absence of N-acetylated Phe-tRNA(Phe) at the P-site. The reaction was uncoupled from protein synthesis by omitting Phe-tRNA(Phe) at the A-site. In this reaction, the ribosome can be considered as an enzyme catalysing the transition of EF-Tu.GTP to EF-Tu.GTP. A constant EF-Tu.GTP concentration is maintained by regenerating GDP to GTP at the expense of phosphoenolpyruvate by pyruvate kinase. The rate constants are determined using a procedure which corrects for the reduction in specific activity of GTP due to regeneration of the nucleotide. Ribosomes with an occupied P-site are more efficient in stimulating the GTPase of EF-Tu.GTP than ribosomes with an empty P-site. The data suggest that this is mainly caused by an increased affinity of EF-Tu.GTP for ribosomes with a filled P-site rather than by an enhanced reactivity of the GTPase centre.     

Mutagenesis of three residues, isoleucine-60, threonine-61, and aspartic acid-80, implicated in the GTPase activity of Escherichia coli elongation factor Tu.

The properties of variants of elongation factor (EF) Tu mutated at three positions implicated in its GTPase activity are presented. Mutation I60A, which reduces one wing of a "hydrophobic barrier" screening off the nucleophilic water molecule found at the GTP gamma-phosphate, causes a reduction of the intrinsic GTPase activity contrary to prediction and has practically no influence on other properties. Mutation D80N, which in the isolated G-domain of EF-Tu caused a strong stimulation of the intrinsic GTPase, reduces this activity in the intact molecule. However, whereas for wild-type EF-Tu complex formation with aa-tRNA reduces the GTPase, EF-Tu[D80N] shows a strongly increased activity when bound to Phe-tRNA. Moreover, ribosomes or kirromycin can stimulate its GTPase up to the same level as for wild-type. This indicates that a local destabilization of the magnesium binding network does not per se cause an increased GTPase but does affect its tight regulation. Interestingly, mutant D80N sequestrates EF-Ts by formation of a more stable complex. Substitutions T61A and T61N induce low intrinsic GTPase, and the stimulation by ribosome is less for T61A than for T61N but still detectable, while kirromycin stimulates the GTPase of both mutants equally. This provides more evidence that stimulation by kirromycin and ribosomes follows a different mechanism. The functional implications of these mutations are discussed in the context of a transition state mechanism for catalysis. An alternative structural explanation for the strong conservation of Ile-60 is proposed.     

Different regions of aminoacyl-tRNA regulate the function of elongation factor Tu

In this work we show that intact aminoacyl-tRNA (aa-tRNA) and its 3' half-molecule, but not its 3' C-C-A-aa fragment, require selective ionic conditions for stimulating the mRNA-independent GTPase of elongation factor Tu (EF-Tu) in the presence of ribosomes.l Stimulation by aa-tRNA and its 3' half-molecule is only observed at 20 and 30 mM Mg2+ and not at 10 mM, where they exert inhibitory activity; by contrast, C-C-A-aa enhances the GTPase activity at all three of these Mg2+ concentrations. Ammonium ion is needed for stimulation by C-C-A-aa, whereas it inhibits the stimulation by aa-tRNA and its 3' half-molecule. The concentration of aminoacylated fragments needed for half-maximum stimulation follows this order: A-Val much greater than C-A-Val greater than C-C-A-Val much greater than 3' Val-tRNA1Val half-molecule greater than Val-tRNA1Val. The extent of maximum stimulation of the EF-Tu GTPase in the presence of ribosomes varies moderately depending on the aa-tRNA species; a clear dependence on the nature of the aminoacyl side chain is observed in the effects of their respective C-C-A-aa fragments tested (C-C-A-Arg, C-C-A-Val, C-C-A-Phe, C-C-A-Met, C-C-A-Lys). In the absence of ribosomes and at low [Mg2+], the one-round GTP hydrolysis by EF-Tu is enhanced by C-C-A-aa fragments, whereas it is inhibited by the corresponding aa-tRNAs. Our results suggest that besides the 3' aminoacylated extremity another region(s) of the aa-tRNA molecule controls the GTPase of EF-Tu. The "unspecific" stimulation by C-C-A-aa and the "specific," aa-tRNA-like effect of the 3' aa-tRNA half-molecule point to the importance of the T chi C loop and stem, as well as of the adjacent regions for the regulation of this function.     

Mg2+ is not catalytically required in the intrinsic and kirromycin-stimulated GTPase action of Thermus thermophilus EF-Tu

The influence of divalent metal ions on the intrinsic and kirromycin-stimulated GTPase activity in the absence of programmed ribosomes and on nucleotide binding affinity of elongation factor Tu (EF-Tu) from Thermus thermophilus prepared as the nucleotide- and Mg(2+)-free protein has been investigated. The intrinsic GTPase activity under single turnover conditions varied according to the series: Mn(2+) (0.069 min(-1)) > Mg(2+) (0.037 min(-1)) approximately no Me(2+) (0.034 min(-1)) > VO(2+) (0.014 min(-1)). The kirromycin-stimulated activity showed a parallel variation. Under multiple turnover conditions (GTP/EF-Tu ratio of 10:1), Mg(2+) retarded the rate of hydrolysis in comparison to that in the absence of divalent metal ions, an effect ascribed to kinetics of nucleotide exchange. In the absence of added divalent metal ions, GDP and GTP were bound with equal affinity (K(d) approximately 10(-7) m). In the presence of added divalent metal ions, GDP affinity increased by up to two orders of magnitude according to the series: no Me(2+) < VO(2+) < Mn(2+) approximately Mg(2+) whereas the binding affinity of GTP increased by one order of magnitude: no Me(2+) < Mg(2+) < VO(2+) < Mn(2+). Estimates of equilibrium (dissociation) binding constants for GDP and GTP by EF-Tu on the basis of Scatchard plot analysis, together with thermodynamic data for hydrolysis of triphosphate nucleotides (Phillips, R. C., George, P., and Rutman, R. J. (1969) J. Biol. Chem. 244, 3330-3342), showed that divalent metal ions stabilize the EF-Tu.Me(2+).GDP complex over the protein-free Me(2+).GDP complex in solution, with the effect greatest in the presence of Mg(2+) by approximately 10 kJ/mol. These combined results show that Mg(2+) is not a catalytically obligatory cofactor in intrinsic and kirromycin-stimulated GTPase action of EF-Tu in the absence of programmed ribosomes, which highlights the differential role of Mg(2+) in EF-Tu function.     

Altered regulation of the guanosine 5'-triphosphate activity in a kirromycin-resistant elongation factor Tu

In the preceding article a mutant elongation factor Tu (EF-TuD2216) resistant to the action of kirromycin was found to display a spontaneous guanosine 5'-triphosphatase (GTPase) activity, i.e., in the absence of aminoacyl transfer ribonucleic acid (tRNA) and ribosome-messenger RNA. This is the first example of an Ef-Tu supporting GTPase activity in the absence of macromolecular effectors and/or kirromycin. In this study we show that this activity is elicited by increasing NH4+ concentrations. As additional effect, the mutation caused an increased affinity of EF-Tu for GTP. Ammonium dependence of the GTPase activity an increased affinity for GTP are two properties also found with wild-type EF-Tu in the presence of kirromycin [Fasano, O., Burns, W., Crechet, J.-B., Sander, G., & Parmeggiani, A. (1978) Eur. J. Biochem. 89, 557-565; Sander, G., Okonek, M., Crechet, J.-B., Ivell, R., Bocchini, V., & Parmeggiani, A. (1979) FEBS Lett. 98, 111-114]. Therefore, both binding of kirromycin to wild-type EF-Tu and acquisition of kirromycin resistance introduce functionally related modifications. Kirromycin at high concentrations (0.1 mM) does not interact with mutant EF-TuD2216.GDP but still does with EF-TuD2216.GTP in agreement with our previous finding that EF-Tu.GTP is the preferential target of the antibiotic in the wild type [Fasano, O., Bruns, W., Crechet, J.-B., Sander, G., & Parmeggiani, A. (1978) Eur. J. Biochem. 89, 557-565). The GTPase activity of mutant EF-Tu in the presence of aminoacyl-tRNA and ribosome.mRNA is much higher than with wild-type EF-Tu and also much less dependent on the presence of mRNA. Miscoding for leucine, measured as poly(U)-directed poly(phenyl-alanine/leucine) synthesis at increasing Mg2+ concentrations, is identical for both wild-type and mutant EF-Tu.     

Psychrophilic elongation factor Tu from the antarctic Moraxella sp. Tac II 25: biochemical characterization and cloning of the encoding gene

The elongation factor Tu was isolated from a psychrophilic eubacterial Antarctic Moraxella strain (MoEF-Tu) and its molecular and functional properties were determined. It catalyzed the synthesis of poly(Phe) and bound specifically guanine nucleotides with an affinity for GDP about 12-fold higher than that for GTP. The affinity toward guanine nucleotides was lower than that of other eubacterial EF-Tu. The intrinsic GTPase activity of MoEF-Tu was hardly detectable but was accelerated by 2 orders of magnitude in the presence of the antibiotic kirromycin (GTPase(k)). Such a property resembled Escherichia coli EF-Tu (EcEF-Tu) even though the affinity of MoEF-Tu for the antibiotic was lower. MoEF-Tu showed a thermophilicity higher than that of EcEF-Tu; its temperature for half-denaturation was 44 degrees C. The MoEF-Tu encoding gene corresponding to E. coli tufA was cloned and sequenced. The translated protein had a calculated molecular weight of 43 288 and contained the GTP-binding sequence motifs. Concerning its primary structure, MoEF-Tu showed sequence identity with E. coli and Thermus thermophilus EF-Tu equal to 84% and 74%, respectively, while the identity with EF-1 alpha from the archaeon Sulfolobus solfataricus was equal to 32%.     

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.     

Role of yeast elongation factor 3 in the elongation cycle

Investigation of the role of the polypeptide chain elongation factor 3 (EF-3) of yeast indicates that EF-3 participates in the elongation cycle by stimulating the function of EF-1 alpha in binding aminoacyl-tRNA (aa-tRNA) to the ribosome. In the yeast system, the binding of the ternary complex of EF-1 alpha.GTP.aa-tRNA to the ribosome is stoichiometric to the amount of EF-1 alpha. In the presence of EF-3, EF-1 alpha functions catalytically in the above mentioned reaction. The EF-3 effect is manifest in the presence of ATP, GTP, or ITP. A nonhydrolyzable analog of ATP does not replace ATP in this reaction, indicating a role of ATP hydrolysis in EF-3 function. The stimulatory effect of EF-3 is, in many respects, distinct from that of EF-1 beta. Factor 3 does not stimulate the formation of a binary complex between EF-1 alpha and GTP, nor does it stimulate the exchange of EF-1 alpha-bound GDP with free GTP. The formation of a ternary complex between EF-1 alpha.GTP.aa-tRNA is also not affected by EF-3. It appears that the only reaction of the elongation cycle that is stimulated by EF-3 is EF-1 alpha-dependent binding of aa-tRNA to the ribosome. Purified elongation factor 3, isolated from a temperature-sensitive mutant, failed to stimulate this reaction after exposure to a nonpermissive temperature. A heterologous combination of ribosomal subunits from yeast and wheat germ manifest the requirement for EF-3, dependent upon the source of the "40 S" ribosomal subunit. A combination of 40 S subunits from yeast and "60 S" from wheat germ showed the stimulatory effect of EF-3 in polyphenylalanine synthesis (Chakraburtty, K., and Kamath, A. (1988) Int. J. Biochem. 20, 581-590). However, we failed to demonstrate the effect of EF-3 in binding aa-tRNA to such a heterologous combination of the ribosomal subunits.     

The structural and functional basis for the kirromycin resistance of mutant EF-Tu species in Escherichia coli.

A structural and functional understanding of resistance to the antibiotic kirromycin in Escherichia coli has been sought in order to shed new light on the functioning of the bacterial elongation factor Tu (EF-Tu), in particular its ability to act as a molecular switch. The mutant EF-Tu species G316D, A375T, A375V and Q124K, isolated by M13mp phage-mediated targeted mutagenesis, were studied. In this order the mutant EF-Tu species showed increasing resistance to the antibiotic as measured by poly(U)-directed poly(Phe) synthesis and intrinsic GTPase activities. The K'd values for kirromycin binding to mutant EF-Tu.GTP and EF-Tu.GDP increased in the same order. All mutation sites cluster in the interface of domains 1 and 3 of EF-Tu.GTP, not in that of EF-Tu.GDP. Evidence is presented that kirromycin binds to this interface of wild-type EF-Tu.GTP, thereby jamming the conformational switch of EF-Tu upon GTP hydrolysis. We conclude that the mutations result in two separate mechanisms of resistance to kirromycin. The first inhibits access of the antibiotic to its binding site on EF-Tu.GTP. A second mechanism exists on the ribosome, when mutant EF-Tu species release kirromycin and polypeptide chain elongation continues.     

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).     

Structural and functional properties of thesaurin a (42Sp50), the major protein of the 42 S particles present in Xenopus laevis previtellogenic oocytes

Thesaurin a is one of two protein components of a 42 S ribonucleoprotein particle that is very abundant in previtellogenic oocytes of Xenopus laevis. The primary function of the 42 S particle is the long-term storage of 5 S RNA and aminoacyl-tRNA. Thesaurin a is homologous to eukaryotic elongation factor 1 alpha (EF-1 alpha) and to prokaryotic elongation factor Tu (EF-Tu). Sequence comparison with EF-1 alpha and EF-Tu of different species indicates that thesaurin a is rather distantly related to all eukaryotic elongation factors. In spite of this, the secondary structure of thesaurin a, deduced from hydrophobic cluster analysis, is remarkably similar to that of EF-1 alpha and EF-Tu. The binding and catalytic properties of thesaurin a are also similar but not identical to those of EF-1 alpha. Like EF-1 alpha, purified thesaurin a binds tRNA, GDP, and GTP. Unlike EF-1 alpha, thesaurin a binds discharged tRNA more tightly than charged tRNA, and GTP more tightly than GDP. Thesaurin a also hydrolyzes GTP and catalyzes the mRNA-dependent binding of aminoacyl-tRNA to 80 S ribosomes. The functional properties of the 42 S particle are in general agreement with those of purified thesaurin a. In particular, the 42 S particle contains GTP and efficiently transfers aminoacyl-tRNA to 80 S ribosomes without addition of exogenous elongation factor.     

The elongation factor Tu binds aminoacyl-tRNA in the presence of GDP

Escherichia coli elongation factor (EF-Tu) binds aminoacyl-tRNAs (aa-tRNA) not only in the presence of GTP but also in the presence of GDP. Complex formation leads to a protection of the aa-tRNA against nonenzymatic deacylation and digestion by pancreatic ribonuclease, as well as to a protection of EF-Tu against proteolysis by trypsin. The equilibrium constant for the binding of Phe-tRNAPheyeast for example to EF-Tu.GDP has been determined to be 0.7 X 10(5) M-1 which is 2 orders of magnitude lower than the equilibrium constant for Phe-tRNAPheyeast binding to EF-Tu.GTP. In the presence of kirromycin, aminoacyl-tRNA binding to EF-Tu.GDP is not affected as much: Phe-tRNAPheyeast is bound with an equilibrium constant of 3 X 10(5) M-1. While there is also a measurable interaction between EF-Tu.GTP and tRNA, such an interaction cannot be detected with EF-Tu.GDP and tRNA, not even at millimolar concentrations. A so far undetected complex formation between aminoacyl-tRNA and EF-Tu.GTP in the presence of pulvomycin, however, could be detected. The results are discussed in terms of the structural requirements of ternary complex formation and in the light of proofreading schemes involving A-site binding on the E. coli ribosome.     

Structure-function relationships of elongation factor Tu. Isolation and activity of the guanine-nucleotide-binding domain

The guanine-nucleotide-binding domain (G domain) of elongation factor Tu(EF-Tu) consisting of 203 amino acid residues, corresponding to the N-terminal half of the molecule, has been recently engineered by deleting part of the tufA gene and partially characterized [Parmeggiani, A., Swart, G. W. M., Mortensen, K. K., Jensen, M., Clark, B. F. C., Dente, L. and Cortese, R. (1987) Proc. Natl Acad. Sci. USA 84, 3141-3145]. In an extension of this project we describe here the purification steps leading to the isolation of highly purified G domain in preparative amounts and a number of functional properties. The G domain is a relatively stable protein, though less stable than EF-Tu towards thermal denaturation (t50% = 41.3 degrees C vs. 46 degrees C, respectively). Unlike EF-Tu, its affinity for GDP and GTP, as well as the association and dissociation rates of the relative complexes are similar, as determined under a number of different experimental conditions. Like EF-Tu, the GTPase of the G domain is strongly enhanced by increasing concentrations of Li+, K+, Na+ or NH+4, up to the molar range. The effects of the specific cations shows similarities and diversities when compared to the effects on EF-Tu. K+ and Na+ are the most active followed by NH+4 and Li+ whilst Cs+ is inactive. In the presence of divalent cations, optimum stimulation occurs in the range 3-5 mM, Mg2+ being more effective than Mn2+ and Ca2+. Monovalent and divalent cations are both necessary components for expressing the intrinsic GTPase activity of the G domain. The pH curve of the G domain GTPase displays an optimum at pH 7-8, similar to that of EF-Tu. The 70-S ribosome is the only EF-Tu ligand affecting the G domain in the same manner as that observed with the intact molecule, although the extent of the stimulatory effect is lower. The rate of dissociation of the G domain complexes with GTP and GDP as well as the GTPase activity are also influenced by EF-Ts and kirromycin, but the effects evoked are small and in most cases different from those exerted on EF-Tu. The inability of the G domain to sustain poly(Phe) synthesis is in agreement with the apparent lack of formation of a ternary complex between the G domain.GTP complex and aa-tRNA.(ABSTRACT TRUNCATED AT 400 WORDS)     

The binding of kirromycin to elongation factor Tu. Structural alterations are responsible for the inhibitory action.

The influence of kirromycin on the elongation factor Tu (EF-Tu) in its binary and ternary complexes was investigated. The equilibrium constant for the binding of the antibiotic to EF-Tu . GDP and EF-Tu . GTP was determined by circular dichroism titrations to be 4 x 10(6) M-1, and to EF-Tu . GTP . aa-tRNA by a combination of circular dichroism titrations and hydrolysis protection experiments to be 2 x 10(6) M-1. In the presence of kirromycin the binding of aminoacyl-tRNAs to EF-Tu . GTP is weakened by a factor of two. The antibiotic changes the conformation of the ternary complex in such a way that the aminoacyl moiety of the aminoacyl-tRNA is more accessible to the non-enzymatic hydrolysis. It is concluded that this structural alteration is responsible for the inhibitory action of the antibiotic.     

Valine 114 replacements in archaeal elongation factor 1 alpha enhanced its ability to interact with aminoacyl-tRNA and kirromycin

Valine 114 in the D(109)AAILVVA sequence of elongation factor 1alpha from the archaeon Sulfolobus solfataricus (SsEF-1alpha) was substituted with an acidic (V114E), basic (V114K), or cavity-forming (V114A) residue, and the effects on the biochemical properties of the factor were investigated. This sequence is well-conserved among most of eukaryal and eubacterial counterparts, and in the three-dimensional structure of SsEF-1alpha, V114 is located in a hydrophobic pocket near the first GDP-binding consensus sequence G(13)XXXXGK[T,S] [Vitagliano, L., Masullo, M., Sica, F., Zagari, A., and Bocchini, V. (2001) EMBO J. 20, 5305-5311]. These mutants displayed functions absent in the wild-type factor. In fact, although they exhibited a rate in poly(Phe) incorporation almost identical to that of SsEF-1alpha, V114K and V114A exhibited an affinity for GDP and GTP higher and a capability to bind heterologous aa-tRNA stronger than that elicited by SsEF-1alpha but similar to that of eubacterial EF-Tu. V114E instead displayed not only a weaker binding capability for aa-tRNA but also a lower affinity for GDP. The intrinsic GTPase activity of V114E was drastically reduced compared to those of SsEF-1alpha, V114K, and V114A. Interestingly, the decreased intrinsic GTPase activity of V114E was partially restored by kirromycin, an effect already observed for the G13A mutant of SsEF-1alpha [Masullo, M., Cantiello, P., de Paola, B., Catanzano, F., Arcari, P., and Bocchini, V. (2002) Biochemistry 41, 628-633]. Finally, the V114A substitution showed only a marginal effect on both the thermostability and thermophilicity of SsEF-1alpha, whereas V114K and V114E replacements strongly destabilized the molecule.