Studies on polypeptide-chain-elongation factors from an extreme thermophile, Thermus thermophilus HB8. 3. Molecular properties.

Molecular properties of the polypeptide chain elongation factors from Thermus thermophilus HB8 have been investigated and compared with those from Escherichia coli. 1. As expected, the factors purified from T. thermophilus were exceedingly heat-stable. Even free EF-Tu not complexed with GDP was stable after heating for 5 min at 60 degrees C. 2. GDP binding activity of T. thermophilus EF-Tu was also stable in various protein denaturants, such as 5.5 M urea, 1.5 M guanidine-HCl, and 4 M LiCl. 3. Amino acid compositions of EF-Tu and EF-G from T. thermophilus were similar to those from E. coli. On the other hand, amino acid composition of T. thermophilus EF-Ts was considerably different from that of E. coli EF-Ts. 4. In contrast to E. coli EF-Tu, T. thermophilus EF-Tu contained no free sulfhydryl group, but one disulfide bond. The disulfide bond was cleaved by sodium borohydride or sodium sulfite under native conditions. The heat stability of the reduced EF-Tu . GDP, as measured by GDP binding activity, did not differ from that of the untreated EF-Tu . GDP. 5. T. thermophilus EF-Ts contained, in addition to one disulfide bond, a sulfhydryl group which could be titrated only after complete denaturation of the protein. 6. Under native conditions one sulfhydryl group of T. thermophilus EF-G was titrated with p-chloromercuribenzoate, while the rate of reaction was very sluggish. The sulfhydryl group appears to be essential for interaction with ribosomes, whereas the ability to form a binary GDP . EF-G complex was not affected by its modification. The protein contained also one disulfide bond. 7. Circular dichroic spectra of EF-Tu from T. thermophilus and E. coli were very similar. Binding of GDP or GTP caused a similar spectral change in both. T. thermophilus and E. coli EF-Tu. On the other hand, the spectra of T. thermophilus EF-G and E. coli EF-G were significantly different, the content of ordered structure being higher in the former as compared to the latter.     

Studies on polypeptide-chain-elongation factors from an extreme thermophile, Thermus thermophilus HB8. 2. Catalytic properties.

Catalytic properties of the elongation factors from Thermus thermophilus HB8 have been studied and compared with those of the factors from Escherichia coli. 1. The formation of a ternary guanine-nucleotide . EF-Tu . EF-Ts complex was demonstrated by gel filtration of the T. thermophilus EF-Tu . EF-Ts complex on a Sephadex G-150 column equilibrated with guanine nucleotide. The occurrence of this type of complex has not yet been proved with the factors from E. coli. 2. The dissociation constants for the complexes of T. thermophilus EF-Tu . EF-Ts with GDP and GTP were 6.1 x 10(-7) M and 1.9 x 10(-6) M respectively. On the other hand, T. thermophilus EF-Tu interacted with GDP and GTP with dissociation constants of 1.1 x 10(-9) M and 5.8 x 10(-8) M respectively. This suggests that the association of EF-Ts with EF-Tu lowered the affinity of EF-Tu for GDP by a factor of about 600 and facilitated the nucleotide exchange reaction. 3. Although the T. thermophilus EF-Tu . EF-Ts complex hardly dissociates into EF-Tu and EF-Ts, a rapid exchange was observed between free EF-Ts and the EF-Tu . EF-Ts complex using 3H-labelled EF-Ts. The exchange reaction was independent on the presence or absence of guanine nucleotides. 4. Based on the above findings, an improved reaction mechanism for the regeneration of EF-Tu . GTP from EF-Tu . GDP is proposed. 5. Studies on the functional interchangeability of EF-Tu and EF-Ts between T. thermophilus and E. coli has revealed that the factors function much more efficiently in the homologous than in the heterologous combination. 6. T. thermophilus EF-Ts could bind E. coli EF-Tu to form an EF-Tu (E. coli) . EF-Ts (T. thermophilus hybrid complex. The complex was found to exist in a dimeric form indicating that the property to form a dimer is attributable to T. thermophilus EF-Ts. On the other hand, no stable complex between E. coli EF-Ts and T. thermophilus EF-Tu has been isolated. 7. The uncoupled GTPase activity of T. thermophilus EF-G was much lower than that of E. coli EF-G. T. thermophilus EF-G formed a relatively stable binary EF-G . GDP complex, which could be isolated on a nitrocellulose membrane filter. The Kd values for EF-G . GDP and EF-G . GTP were 6.7 x 10(-7) M and 1.2 x 10(-5) M respectively. The ternary T. thermophilus EF-G . GDP . ribosome complex was again very stable and could be isolated in the absence of fusidic acid. The stability of the latter complex is probably the cause of the low uncoupled GTPase activity of T. thermophilus EF-G.     

A simplified procedure for the isolation of bacterial polypeptide elongation factor EF-Tu

Polypeptide elongation factor EF-Tu can be isolated from bacterial cell extracts in two fractionation steps. The first is ion-exchange chromatography on DEAE-Sepharose, CL-6B, and the second is gel filtration on AcA 44. The method is illustrated with extracts from Escherichia coli, Bacillus stearothermophilus, and the thermophilic bacterium PS3. The extracts were obtained from lysozyme-treated cells and were processed without high-speed centrifugation or ammonium sulfate fractionation. The procedure is simple and rapid, gives higher yields than previous methods, and is easily scaled to any size preparation. The procedure also produces fractions enriched in the other polypeptide elongation factors EF-Ts and EF-G.     

Guanyl cyclase activity in the EF-T elongation factor of Escherichia coli]

Highly purified EF-Ts from E. coli does contain guanylate cyclase activity, which is absent from other purified transfer factors, such as EF-Tu and EF-G. Guanylate cyclase activity has been characterized by its sensitivity to inhibitors and substrate specificity. Although the physicochemical properties of guanylate cyclase are closely related to those of EF-Ts, it does not appear to be a contaminant of this transfer factor, but a specific enzyme. The possible role of guanylate cyclase in protein synthesis is discussed.     

Ribosomal translocation assayed by the matrix-bound poly(uridylic acid) column technique.

The system of translation of cellulose-bound poly(uridylic acid) by Escherichia coli ribosomes has been used for preparation of pre-translocation state ribosomes in columns. Translocation has been induced by passing the elongation factor G (EF-G) with GTP or its non-cleavable analog (guanosine 5'-[beta, gamma-methylene]triphosphate) through the column. A method for quantitative comparison of translocation rates, and thus of effectiveness of translocation-inducing factors, has been proposed. The method is based on an analysis of the profile of deacylated tRNA elution resulting from translocation in the column. The determination of the rate and amount of translocation has been done under different ionic conditions. It has been found that the Mg2+ concentration is a decisive factor of translocation in vitro: at high Mg2+ (30 mM) EF-G cannot induce translocation, and lowering the Mg2+ concentration (to 10 mM) is required for EF-G to become effective. Sufficiently low Mg2+ (3 mM) itself has proved to induce fast and complete translocation, without EF-G.     

The role of GTP in transient splitting of 70S ribosomes by RRF (ribosome recycling factor) and EF-G (elongation factor G)

Ribosome recycling factor (RRF), elongation factor G (EF-G) and GTP split 70S ribosomes into subunits. Here, we demonstrated that the splitting was transient and the exhaustion of GTP resulted in re-association of the split subunits into 70S ribosomes unless IF3 (initiation factor 3) was present. However, the splitting was observed with sucrose density gradient centrifugation (SDGC) without IF3 if RRF, EF-G and GTP were present in the SDGC buffer. The splitting of 70S ribosomes causes the decrease of light scattering by ribosomes. Kinetic constants obtained from the light scattering studies are sufficient to account for the splitting of 70S ribosomes by RRF and EF-G/GTP during the lag phase for activation of ribosomes for the log phase. As the amount of 70S ribosomes increased, more RRF, EF-G and GTP were necessary to split 70S ribosomes. In the presence of a physiological amount of polyamines, GTP and factors, even 0.6 μM 70S ribosomes (12 times higher than the 70S ribosomes for routine assay) were split. Spermidine (2 mM) completely inhibited anti-association activity of IF3, and the RRF/EF-G/GTP-dependent splitting of 70S ribosomes.     

Two Homologous EF-G Proteins from Pseudomonas aeruginosa Exhibit Distinct Functions

Genes encoding two proteins corresponding to elongation factor G (EF-G) were cloned from Pseudomonas aeruginosa. The proteins encoded by these genes are both members of the EFG I subfamily. The gene encoding one of the forms of EF-G is located in the str operon and the resulting protein is referred to as EF-G1A while the gene encoding the other form of EF-G is located in another part of the genome and the resulting protein is referred to as EF-G1B. These proteins were expressed and purified to 98% homogeneity. Sequence analysis indicated the two proteins are 90/84% similar/identical. In other organisms containing multiple forms of EF-G a lower degree of similarity is seen. When assayed in a poly(U)-directed poly-phenylalanine translation system, EF-G1B was 75-fold more active than EF-G1A. EF-G1A pre-incubate with ribosomes in the presence of the ribosome recycling factor (RRF) decreased polymerization of poly-phenylalanine upon addition of EF-G1B in poly(U)-directed translation suggesting a role for EF-G1A in uncoupling of the ribosome into its constituent subunits. Both forms of P. aeruginosa EF-G were active in ribosome dependent GTPase activity. The kinetic parameters (K _M) for the interaction of EF-G1A and EF-G1B with GTP were 85 and 70 μM, respectively. However, EF-G1B exhibited a 5-fold greater turnover number (observed k _cat) for the hydrolysis of GTP than EF-G1A; 0.2 s^-1 vs. 0.04 s^-1. These values resulted in specificity constants (k _cat ^obs/K _M) for EF-G1A and EF-G1B of 0.5 x 10³ s^-1 M^-1 and 3.0 x 10³ s^-1 M^-1, respectively. The antibiotic fusidic acid (FA) completely inhibited poly(U)-dependent protein synthesis containing P. aeruginosa EF-G1B, but the same protein synthesis system containing EF-G1A was not affected. Likewise, the activity of EF-G1B in ribosome dependent GTPase assays was completely inhibited by FA, while the activity of EF-G1A was not affected.     

Functional interactions of an Escherichia coli ribosomal ATPase.

The gene encoding ribosome-bound ATPase (RbbA), which occurs bound to 70S ribosomes and 30S subunits, has been identified. The amino-acid sequence of RbbA reveals the presence of two ATP-binding domains in the N-terminal half of the protein. RbbA harbors an intrinsic ATPase activity that is stimulated by both 70S ribosomes and 30S subunits. Here we show that purified recombinant RbbA markedly stimulates polyphenylalanine synthesis in the presence of the elongation factors Tu and G (EF-Tu and EF-G) and that the hydrolysis of ATP by RbbA is required to stimulate synthesis. RbbA is reported to have affinity for EF-Tu but not for EF-G. Additionally, RbbA copurifies with 30S ribosomal subunits and can be crosslinked to the ribosomal protein S1. Studies using a spectrum of antibiotics, including some of similar function, revealed that hygromycin, which binds to the 30S subunit, has a significant effect on the ATPase activity and on the affinity of RbbA for ribosomes. A possible role for RbbA in protein-chain elongation is proposed.     

Euglena gracilis chloroplast ribosomes: improved isolation procedure and comparison of elongation factor specificity with prokaryotic and eukaryotic ribosomes

An improved method for the isolation of Euglena chloroplast ribosomes is described which presents a number of advantages over past procedures. First, ribosomes are prepared from whole cell extracts, thus bypassing the need to isolate intact chloroplasts and resulting in a 10-fold improvement in yield. Second, the inclusion of 40 mm Mg²⁺ in the preparation buffers, while stabilizing the chloroplast ribosomes, precipitates and, thereby, virtually eliminates the cytoplasmic 89 S ribosomes. Third, greater than 95% of the chloroplast ribosomes sediment at 68 S rather than as the damaged 53 S particle frequently generated in other preparation procedures. Fourth, even with a high-salt wash to remove endogenous factors, the chloroplast ribosomes still sediment at 68 S and are just as active in in vitro protein synthesis as are E. coli ribosomes. These ribosomes have been tested for activity with elongation factors from prokaryotes, eukaryotes, and the chloroplast itself, and the results have been compared to those obtained with E. coli and wheat germ ribosomes. The data may be summarized as follows: (a) Chloroplast ribosomes use E. coli$\text{EF}\text{-}\text{Tu}\text{Ts}$ and EF-G with the same efficiency as do E. coli ribosomes in protein synthesis, (b) E. coli and chloroplast ribosomes can use Euglena chloroplast EF-G to catalyze translocation, but wheat germ ribosomes cannot, (c) Wheat germ EF-1_H and EF-2 are highly active in polymerization with wheat germ ribosomes, but ribosomes from neither E. coli nor the chloroplast are able to recognize these factors, (d) All three types of ribosomes accept Phe-tRNA from E. coli EF-Tu although to differing degrees. However, neither chloroplast nor E. coli ribosomes recognize wheat germ EF-1_H for the binding of Phe-tRNA.     

ppGpp inhibition of elongation factors Tu, G and Ts during polypeptide synthesis

Summary The inhibition of elongation factors G, Tu and Ts by ppGpp was studied in vitro in a translation system with missense frequency and elongation rate similar to those in vivo. ppGpp inhibits EF-G with K_I=6x10^-5 M. When ppGpp is in twofold excess over GTP and EF-G is the rate-limiting component, the elongation rate is reduced two-fold by ppGpp. EF-Tu is inhibited with K_I=7x10^-7 M in the absence of EF-Ts. When EF-Ts is added, the binding of ppGpp to EF-Tu becomes successively weaker. 1/K_I depends linearly on 1/[Ts] and the intercept at the abscissa gives K_I=4x10^-5 M. This reflects the binding of ppGpp to the binary TuTs complex. The slope reveals that the binding of EF-Ts to the TuMS binary complex is strong (10^-6 M). ppGpp may thus inhibit the cycling of EF-Tu indirectly by the removal of the free EF-Ts by its adsorption to TuMS, as well as directly by simple binding to Tu. EF-Tu inhibition by ppGpp can be fully reversed by high levels of aminoacyl-tRNA only in the presence of EF-Ts and at low ribosomal activity. Our in vitro observations have been extrapolated to in vivo conditions with conclusions as follows: Under strong amino acid starvation ppGpp in two-fold excess over GTP cannot reduce significantly the elongation rate of ribosomes and thereby restore the errors to their normal levels as in the stringent response. Under weak starvation, in contrast, a significant rate reduction can be achieved by the trapping of EF-Ts in complex with TuppGpp.     

Escherichia coli elongation factor G blocks stringent factor

The relationship between the binding domains of elongation factor G(EF-G) and stringent factor (SF) on ribosomes was studied. The binding of highly purified, radioactively labeled, protein factors to ribosomes was monitored with a column system. The data show that binding of EF-G to ribosomes in the presence of fusidic acid and GDP or of the noncleavable analogue GDPCP prevents subsequent binding of SF to ribosomes. In addition, stabilization of the EF-G-ribosome complex by fusidic acid inhibits SF's enzymatic activities. Removal of protein L7/L12 from ribosomes leads to weaker binding of EF-G, while SF's binding and activity are unaffected. In the absence of L7/L12, EF-G-dependent inhibition of SF binding and function is reduced. The data presented in this report suggest that these two factors bind at overlapping, or at least interacting, ribosomal domains.     

Requirements for in vitro reconstruction of protein synthesis

Translation of f2am3 RNA and MS2 RNA in a system containing purified ribosomes and precharged aminoacyl-tRNA, does not occur in the presence of the "known" initiation (IF-1, IF-2 and IF-3), elongation (EF-Tu, EF-Ts and EF-G) and termination (RF-1, RF-2) factors. Translation in this system requires at least three additional protein factors. These are EF-P and the rescue protein as well as a previously undescribed factor we call W, which is found in the high-salt ribosomal eluate.     

The elongation factor G carries a catalytic site for GTP hydrolysis, which is revealed by using 2-propanol in the absence of ribosomes

In the absence of ribosomal particles, elongation factor G (EF-G) promotes very little GTP hydrolysis. After the addition of some aliphatic alcohols to EF-G, the rate of nucleotide cleavage was significantly increased and GTPase activity was easily detectable. The highest stimulation, nearly 16-fold, occurred with 2-propanol at a 20% (v/v) concentration. The reaction showed the characteristics of an enzymatic catalysis, but the rate was three orders of magnitude lower than that of the ribosome-dependent EF-G GTPase activity. Striking similarities between the two activities indicated that the catalysis stimulated by the alcohol was due to EF-G itself. We found that EF-G GTPase activity in the presence of 2-propanol displayed an absolute specificity for GTP as in the presence of ribosomes; the two activities copurified to a constant ratio and exhibited coincident chromatographic and electrophoretic patterns; the temperature for the half-inactivation of EF-G was 59.3 degrees C for both GTPase systems, as well as the kinetic constant for the thermal inactivation process which was found to be 0.05 min-1; and the Km for the GTP in the presence of 2-propanol (59 microM) was similar to that found in the presence of ribosomes. These results indicate that the EF-G molecule carries a catalytic site for GTP hydrolysis, which in the absence of ribosomal particles is activated by an appropriate alcohol/water surrounding medium.     

Mechanism of the ribosome-dependent uncoupled GTPase reaction catalyzed by polypeptide chain elongation factor G.

At low NH4-+ concentrations, 50S ribosomal subunits from E. coli were fully active in the absence of 30S ribosomal subunits, in forming a complex with the polypeptide chain elongation factor G (EF-G) and guanine nucleotide (ternary complex formation), and also in supporting EF-G dependent hydrolysis of GTP (uncoupled GTPase reaction). However, both activities were markedly inhibited on increasing the concentration of the monovalent cation, and at 160 mM NH4-+, the optimal concentration for polypeptide synthesis in a cell-free system, almost no activity was observed with 50S ribosomes alone. It was found that the inhibitory effect of NH4-+ was reversed by addition of 30S subunits. Thus, at 160 mM NH4-+, only 70S ribosomes were active in supporting the above two EF-G dependent reactions, whereas at 20 mM NH4-+, 50S ribosomes were almost as active as 70S ribosomes. Kinetic studies on inhibition by NH4-+ of the formation of 50S ribosome-EF-G-guanine nucleotide complex, indicated that the inhibition was due to reduction in the number of active 50S ribosomes which were capable of interacting with EF-G and GTP at higher concentrations of NH4-+. The inhibitory effects of NH4-+ on ternary complex formation and the uncoupled GTPase reaction were markedly influenced by temperature, and were much greater at 0 degrees than at 30 degrees. A conformational change of 50S subunits through association with 30S subunits is suggested.     

Studies on ATPase(GTPase) intrinsic to E. coli ribosomes

(1) Escherichia coli 70S ribosomes showed intrinsic ATPase and GTPase activities, although they were much lower than those of rat liver ribosomes. The latter activity was higher than the former one. (2) The ATPase activity was inhibited by GTP and GMP-P(NH)P, and the GTPase activity was inhibited by ATP and AMP-P(NH)P, indicating a close relationship between the two enzymes. (3) Elongation components alone or in combination enhanced the ATPase activity, indicating the possible correlation of ribosomal ATPase with elongational components. (4) Vanadate at the concentrations that did not inhibit the GTPase activities of EF-Tu and EF-G, depressed the poly(U)-dependent polyphe synthesis, suggesting that ribosomal ATPase (GTPase) participates in peptide elongation by inducing positive conformational changes of ribosomes required for the attachment of elongational components.     

Mutational analysis of the functional role of the loop region in the elongation factor G fourth domain in the ribosomal translocation

Seven variants of Thermus thermophilus elongation factor G (EF-G) with mutations in loops of domain IV were constructed by PCR. Point mutations Arg504-->Thr, Pro554-->Thr, or Ile534-->Asp did not affect the GTPase and translocational activities of EF-G. Similar results were obtained for mutants with tetra- or hexapeptide inserts in two loops located at the tip and two loops at the base of domain IV. Insertion of tetrapeptide Gly-Ser-Gly-Thr into loop 501--504 at the tip of domain IV dramatically reduced the activity of EF-G in poly(U)-directed polyphenylalanine synthesis on ribosomes, and halved its translocational activity. The intact conformation of loop Thr501-Gly-Gly-Arg504 was assumed to be essential for sterically perfect, efficient interaction of EF-G with the ribosome. The structural and biochemical data on the 30S subunit and EF-G were analyzed to specify the position of EF-G relative to the 30S and 50S ribosomal subunits.     

Evidence for the nuclear location of the gene for chloroplast elongation factor G.

The chloroplast protein synthesis factor responsible for the translocation step of polypeptide synthesis on chloroplast ribosomes (chloroplast elongation factor G [EF-G]) has been detected in whole cell extracts and in isolated chloroplasts from Euglena gracilis. This factor can be detected by its ability to catalyze translocation on 70 S prokaryotic ribosomes such as those from E. coli. Chloroplast EF-G is present in low levels when Euglena is grown in the dark and can be induced more than 20-fold when the organism is grown in the light. The induction of this factor by light is inhibited by cycloheximide, a specific inhibitor of protein synthesis on cytoplasmic ribosomes. However, inhibitors of chloroplast protein synthesis such as streptomycin or spectinomycin have no effect on the induction of this factor by light. Furthermore, chloroplast EF-G can be partially induced by light in an aplastidic mutant (strain W₃BUL) which has neither significant plastid structure nor detectable chloroplast DNA. These data strongly suggest that the genetic information for chloroplast EF-G resides in the nuclear genome, and that this protein is synthesized on cytoplasmic ribosomes prior to compartmentalization within the chloroplasts.     

Stimulation, by two Escherichia coli supernatant proteins, of the initiation of polypeptide synthesis.

Two protein factors (A and B) have been partially purified from Escherichia coli supernatant which, in combination, are more effective than 0.5 M NH4Cl in stimulating ribosomes for AcPhe-tRNA and fMet-tRNA binding, for the puromycin reaction, and for incorporating acetylphenylalanine from AcPhe-tRNA into polypeptide. The factors appear to differ from the initiation factors, the elongation factor EF-T, and ribosomal proteins. Some uncertainty exists as to whether factor B is different from EF-G. To maximize the effect of the factors in initiator tRNA binding, we preincubated the ribosomes with the factors and carried out the binding assay for a short period at 15 degrees C. Maximal stimulation of binding occurred after about a 2-min preincubation at 37 degrees C. Longer preincubation times were required at 15 degrees C, and only slight stimulation was observed after preincubation at 0 degrees C. The extent of stimulation by the factors was not affected when the NH4Cl concentration was increased from 40 to 500 mM in the preincubation. The presence of both the 30S and 50S ribosomal subunits is required for the enhancement of AcPhe-tRNA binding. Polyphenylalanine synthesis carried out without AcPhe-tRNA is inhibited by the factors. It is suggested that the factors may act by inducing a structural rearrangement of the ribosomes.     

Unique antibiotic sensitivity of archaebacterial polypeptide elongation factors.

The antibiotic sensitivity of the archaebacterial factors catalyzing the binding of aminoacyl-tRNA to ribosomes (elongation factor Tu [EF-Tu] for eubacteria and elongation factor 1 [EF1] for eucaryotes) and the translocation of peptidyl-tRNA (elongation factor G [EF-G] for eubacteria and elongation factor 2 [EF2] for eucaryotes) was investigated by using two EF-Tu and EF1 [EF-Tu(EF1)]-targeted drugs, kirromycin and pulvomycin, and the EF-G and EF2 [EF-G(EF2)]-targeted drug fusidic acid. The interaction of the inhibitors with the target factors was monitored by using polyphenylalanine-synthesizing cell-free systems. A survey of methanogenic, halophilic, and sulfur-dependent archaebacteria showed that elongation factors of organisms belonging to the methanogenic-halophilic and sulfur-dependent branches of the "third kingdom" exhibit different antibiotic sensitivity spectra. Namely, the methanobacterial-halobacterial EF-Tu(EF1)-equivalent protein was found to be sensitive to pulvomycin but insensitive to kirromycin, whereas the methanobacterial-halobacterial EF-G(EF2)-equivalent protein was found to be sensitive to fusidic acid. By contrast, sulfur-dependent thermophiles were unaffected by all three antibiotics, with two exceptions; Thermococcus celer, whose EF-Tu(EF1)-equivalent factor was blocked by pulvomycin, and Thermoproteus tenax, whose EF-G(EF2)-equivalent factor was sensitive to fusidic acid. On the whole, the results revealed a remarkable intralineage heterogeneity of elongation factors not encountered within each of the two reference (eubacterial and eucaryotic) kingdoms.     

Purification and characterization of the mitochondrial translocase from Euglena gracilis

The Euglena gracilis mitochondrial protein biosynthetic elongation factor G (EF-Gmt) has been purified in four steps to greater than 50% homogeneity by use of a fusidic acid affinity procedure and conventional chromatographic techniques. The purification scheme results in 1100-fold purification with about 3% recovery of the total EF-G activity present in the postribosomal supernatant prepared from whole cell extracts. E. gracilis EF-Gmt has an approximate molecular weight of 76,000, comparable to that observed for procaryotic translocases. As is the case for other translocases which have been examined, pretreatment of E. gracilis EF-Gmt with N-ethylmaleimide results in a loss of polymerization activity, indicating a role for an essential cysteine residue in catalytic activity. GDP partially protects EF-Gmt from N-ethylmaleimide inactivation. E. gracilis EF-Gmt functions well on both Escherichia coli and E. gracilis chloroplast ribosomes, but has negligible activity on wheat germ cytoplasmic ribosomes. In this respect, it differs significantly from the mitochondrial translocase of yeast which has very little activity on chloroplast ribosomes. When assayed on E. coli ribosomes, E. gracilis EF-Gmt is sensitive to the steroid antibiotic, fusidic acid, at levels similar to that required for inactivation of E. coli EF-G. It is less sensitive than E. gracilis chloroplast EF-G, and is more sensitive than Bacillus subtilis EF-G. When assayed on E. gracilis chloroplast ribosomes, the same trends in sensitivities are observed, although the exact level of fusidic acid required for inactivation is slightly altered.