Evidence of formation of a complex between GTP and elongation factor two and the binding of the complex to a specific site on mammalian ribosomes

Characterization of the ribosomal properties required for formation of a GTPase active complex with the eukaryotic elongation factor 2

The binding stability of the different nucleotide-dependent and -independent interactions between elongation factor 2 (EF-2) and 80S ribosomes, as well as 60S subunits, was studied and correlated to the kinetics of the EF-2- and ribosome-dependent hydrolysis of GTP. Empty reconstituted 80S ribosomes were found to contain two subpopulations of ribosomes, with approximately 80% capable of binding EF-2.GuoPP[CH2]P with high affinity (Kd less than 10(-9) M) and the rest only capable of binding the factor-nucleotide complex with low affinity (Kd = 3.7 x 10(-7) M). The activity of the EF-2- and 80S-ribosome dependent GTPase did not respond linearly to increasing factor concentrations. At low EF-2/ribosome ratios the number of GTP molecules hydrolyzed/factor molecule was considerably lower than at higher ratios. The low response coincided with the formation of the high-affinity complex. At increasing EF-2/ribosome ratios, the ribosomes capable of forming the high-affinity complex was saturated with EF-2, thus allowing formation of the low-affinity ribosome.EF-2 complex. Simultaneously, the GTPase activity/factor molecule increased, indicating that the low-affinity complex was responsible for activating the GTP hydrolysis. The large ribosomal subunits constituted a homogeneous population that interacted with EF-2 in a low-affinity (Kd = 1.3 x 10(-6) M) GTPase active complex, suggesting that the ribosomal domain responsible for activating the GTPase was located on the 60S subunit. Ricin treatment converted the 80S particles to the type of conformation only capable of interacting with EF-2 in a low-affinity complex. The structural alteration was accompanied by a dramatic increase in the EF-2-dependent GTPase activity. Surprisingly, ricin had no effect on the factor-catalyzed GTP hydrolysis in the presence of 60S subunits alone.

Interaction of Cibacron blue F3GA and polynucleotides with ricin A-chain, 60 S ribosomal subunit-inactivating protein

Cibacron blue F3GA, a sulfonated polyaromatic blue dye, inhibited the ability of ricin A-chain to inactivate ribosomes. Difference-spectroscopic study revealed that the dye bound to the A-chain (Kd = 0.72 microM), producing a difference spectrum with a single maximum at 688 nm and two minima at 585 and 628 nm. Such a significant difference spectrum was not observed in the presence of ricin B-chain or intact ricin, neither of which can inactivate ribosomes. Modification of arginine residues in the A-chain with phenylglyoxal showed a correlation between the loss of inhibitory activity on protein synthesis and the loss of difference absorbance produced by the dye-A-chain interaction. Both losses occurred significantly at an early stage of the modification. Furthermore, the dye protected the A-chain against a loss of its inhibitory activity resulting from the modification of arginine residues. These results suggest that the same arginine residues participate both in the interaction with the dye and in the inactivation of ribosomes. Based on these data, the dye appears to interact with the active site of the A-chain. Addition of several polynucleotides, namely rRNA, tRNA, poly(U) and DNA, to the dye-A-chain complex resulted in a marked displacement of the dye, whereas mono- and dinucleotides had little or no effect on the dye-A-chain interaction. These findings indicate the possible existence of a polynucleotide binding site in the active site of the A-chain. A combination of these and other results suggests that the A-chain recognizes and acts on some part of RNA of the 60 S ribosomal subunit.

Reduced ribosomal binding of eukaryotic elongation factor 2 following ADP-ribosylation. Difference in binding selectivity between polyribosomes and reconstituted monoribosomes

The biological activity of elongation factor 2 (EF-2) following NAD+ - and diphtheria-toxin-dependent ADP-ribosylation was studied (i) in translation experiments using the reticulocyte lysate system and (ii) in ribosomal binding experiments using either reconstituted empty rat liver ribosomes or programmed reticulocyte polysomes. Treatment of the lysates with toxin and NAD+ at a NAD+/ribosome ratio of 4 resulted in a 90% inhibition of the amino acid incorporation rate. The inhibition was overcome by the addition of native EF-2. At this level of inhibition more than 90% of the EF-2 present in the lysates was ADP-ribosylated and the total ribosome association of EF-2 was reduced by approx. 50%. All of the remaining unmodified factor molecules were associated with the ribosomes, whereas only about 3% of the ribosylated factor was ribosome-associated. The nucleotide requirement for the binding of EF-2 to empty reconstituted rat liver ribosomes and programmed reticulocyte polysomes was studied together with the stability of the resulting EF-2 X ribosome complexes using purified 125I-labelled rat liver EF-2. With both types of ribosomes, the complex formation was strictly nucleotide-dependent. Stable, high-affinity complexes were formed in the presence of the non-hydrolysable GTP analogue guanosine 5'-(beta, gamma-methylene)triphosphate (GuoPP[CH2]P). In contrast to the reconstituted ribosomes, GTP stimulated the formation of high-affinity complexes in the presence of polysomes, albeit at a lower efficiency than GuoPP[CH2]P. The formation of high-affinity complexes was restricted to polysomes in the pretranslocation phase of the elongation cycle. Low-affinity post-translocation complexes, demonstrable after fixation, were formed in the presence of GTP, GuoPP[CH2]P and GDP. In polysomes, these complexes involved a different population of particles than did the high-affinity complexes. In the binding experiments using reconstituted or programmed ribosomes, the pretranslocation binding of EF-2 observed in the presence of GuoPP[CH2]P was reduced by approx. 50% after ADP-ribosylation, whereas the post-translocation binding in the presence of GDP was unaltered. The data indicate that the inhibition of translocation caused by diphtheria toxin and NAD+ is mediated through a reduced affinity of the ADP-ribosylated EF-2 for binding to ribosomes in the pretranslocation state.

Quantification of the different ribosomal phases during the translational elongation cycle in rabbit reticulocyte lysates

The proportionality of different ribosomal phases during elongation was estimated in the highly effective rabbit reticulocyte lysate system by use of several complementary analytical methods. The stoichiometric amounts of ribosome-bound elongation factors EF-1 and EF-2 were determined as a measure of ribosomal A-site occupation. The results were correlated with the puromycin reactivity of the P-site-located nascent polypeptide chains. Approximately 25% of the ribosomes were associated with EF-2, indicating that their A-sites contained peptidyl-tRNA. About 35% were associated with EF-1, signifying that their A-sites were occupied by aminoacyl-tRNA. The puromycin reactivity of the nascent chains was approximately 40%. From these data it is concluded that 75% of the peptidyl-tRNAs were located in the P-sites and that their puromycin reactivity was limited by the availability of ribosomal A-sites free for puromycin interaction. After guanosine 5'-[beta, gamma-methylene]triphosphate blockage of the translation, the ribosomal content of elongation factors drastically changed. Under these conditions the proportion of EF-1-containing ribosomes increased to approximately 50% while EF-2-containing ribosomes decreased to 5%. Concomitantly, the puromycin reactivity increased to approximately 45%. In contrast to previous assumptions the experiments support the view that the elongation rate is limited by the availability of ribosomal A-sites for the selection of mRNA-cognate aminoacyl-tRNAs.

Nucleotide-mediated interactions of eukaryotic elongation factor EF-2 with ribosomes

Eukaryotic elongation factor EF-2 isolated from rat liver microsomal salt-wash showed two types of nucleotide-dependent interactions with reconstituted empty 80S ribosomes when analyzed by gradient centrifugation. Stable EF-2 X ribosome complexes were only formed with GTP analogues with reduced or no ability to serve as substrates for the EF-2 and ribosome-dependent GTPase. GTP-stimulated complex formation was only demonstrable after glutaraldehyde fixation, unless a GTP-regenerating system was included throughout the gradient centrifugation. GDP and to a lesser extent GMP and guanosine also stimulated the less stable type of complex formation as demonstrable after fixation. Under the same conditions some complex formation was also observed with ATP and its analogue adenosine 5'-[beta,gamma-methylene]triphosphate, although with less efficiency than with the corresponding guanosine nucleotides. The results in combination with available data indicate that EF-2 has two binding states with different affinities on the 80S ribosome: a high-affinity pre-translocation state specific for EF-2 X GTP and a low-affinity post-translocation state, in which EF-2 X GDP is bound to the ribosome in a less stable and specific complex.

Binding of ricin A chain to rat liver ribosomes: relationship to ribosome inactivation

Ricin A chain was radioactively labeled using reductive alkylation, lactoperoxidase catalyzed iodination, and reaction with iodoacetamide or N-ethylmaleimide (NEM). The inhibition of cell-free rat liver protein synthesis by the modified A chains and the ribosome binding characteristics of each of the labeled derivatives was examined. [3H] NEW was found to quantitatively react with the A chain sulfhydryl group normally involved in a disulfide bond with the B chain in intact ricin. Labeling the protein with [3H] NEM had no effect on the in vitro inhibition of protein synthesis by the A chain. [3H] NEM-labeled A chain binds to rat liver ribosomes in a manner which is dependent on the concentrations of NaCl and Mg2+. At optimal Mg2+ concentration (5.5 mM), A chain binding to ribosomes is saturable and fully reversible either by dilution of the reaction mixture or by addition of unlabeled A chain. At 5.5 mM Mg2+, A chain was found to bind to a single site on rat liver ribosomes with a dissociation constant of 6.2 x 10(-8) M. [3H] NEM-labeled A chain did not bind to isolated 40S ribosomal subunits and bound to 60S ribosomal subunits with a 1 : 1 molar stoichiometry and a dissociation constant of 2.2 x 10(-7) M. The relationship between ribosome binding and A chain inhibition of eucaryotic protein synthesis is discussed.

Interactions of guanosine triphosphate analogues with elongation factor G of Escherichia coli

Previous studies from this laboratory have shown that the GTP analogue guanosine 3'-diphosphate 5'-triphosphate (pppGpp) was almost without activity in the translocation reaction catalyzed by elongation factor G (EF-G), while it was fully active with elongation factor T (EF-T) and initiation factor 2 (IF-2). To assess the importance of the 3'-ribose hydroxyl itself in the translocation reaction, we examined polyphenylalamine synthesis and EF-G-dependent formation of N-acetylphenylalanylphenylalanylpuromycin (Ac-Phe2-puromycin) supported by 3'-deoxyguanosine 5'-triphosphate (3'dGTP) and 3'-deoxy-3'-aminoguanosine 5'-triphosphate (3'dNH2GTP). Like pppGpp, these nucleotides were similar to GTP in EF-T and IF-2dependent reactions. We also examined the ability of the dialcohol derived from GTP by periodate oxidation and borohydride reduction (rroGTP) and of ITP to support translocation. These compounds had shown significant, although reduced, activity with EF-T and IF-2. A spectrum of activity was found with these compounds in both poly(Phe) synthesis and Ac-Phe2-puromycin formation. All had significantly reduced activity relative to GTP, but all were significantly more active than pppGpp. A surprising finding was that the activities of all analogues relative to GTP were dependent on the reaction temperature in both poly(Phe) synthesis and Ac-Phe2-puromycin formation; these relative activities were significantly lower at 8 degrees C after than 37 degrees C. Furthermore, the extent of poly(Phe) synthesis with the analogues relative to GTP could be significantly affected by the amounts of EF-G and EF-T in the reaction mixture. Differences were minimized in the presence of rate-limiting EF-T and saturating EF-G and maximized in the presence of rate-limiting EF-G and saturating EF-T. This effect of reducing the level of EF-G in the reaction mixture thus mimicked the effect of lowering the incubation temperature, and a similar observation was made for Ac-Phe2-puromycin formation. GTP-supported formation of Ac-Phe2-puromycin at 8 degress C could be inhibited by 3'dNH2GTP, 3'dGTP, pppGpp, and ITP: these compounds were better inhibitors than they were substrates. Inhibition by other nucleotides was also noted. The GTP analogues were compared to GTP as substrates in EF-G-dependent reactions uncoupled from protein synthesis. Fusidic-acid-dependent binding of nucleotides to ribosomes and ribosome-dependent catalytic nucleotide hydrolysis were both examined, and the activity of the nucleotides as substrates in these ractions showed little correlation with their ability to support translocation.

Regulation of ternary (Met-tRNAf - GTP - eukaryotic initiation factor 2) protein synthesis initiation complex formation by the adenylate energy charge

Formation of the ternary [Met-tRNAf - GTP - eukaryotic initiation factor 2] protein synthesis initiation complex in rabbit reticulocyte ribosomal eluates is dependent on the GTP: GDP ratio and on the adenylate energy charge. The elements controlling ternary initiation complex formation have been studied in a reconstituted system contianing eukaryotic initiation factor 2 and nucleoside diphosphate kinase purified from the ribosomal eluate. The concentration of GTP required for half maximal formation of the ternary initiation complex is 2.5 - 10(6) M; GDP is a potent competitive inhibitor with Ki equals 3.4 - 10(7) M. Sensitive control of ternary initiation complex formation by the adenylate energy charge occurs through nucleoside diphosphate kinase regulation of the GTP : GDP ratio. Over a wide range of GTP : GDP ratios, 50% of maximal ternary initiation complex formation is observed at an adenylate energy charge of 0.85-0.90 resembling that seen in the unfractionated system. Small changes in adenylate energy charge near this value result in significant changes in the extent of ternary initiation complex formation. Since GTP is continually hydrolyzed to GDP during protein synthesis and since GDP is a competitive inhibitor of GTP binding to several of the protein factors necessary for mRNA translation, the synthetic process provides sensitive control by product inhibition. Ribosome-associated nucleoside diphosphate kinase control of GTP regeneration in response to the adenylate energy charge provides one mechanism for linking protein synthesis to the nutrient state and energy charge of the cell.

Inhibition by ricin of protein synthesis in vitro. Ribosomes as the target of the toxin

1. Ricin (a toxic protein from the seeds of Ricinus communis) is a powerful inhibitor of the poly(U)-directed incorporation of phenylalanine into polypeptides catalysed by isolated rat liver ribosomes and elongation factors 1 and 2 (EF 1 and EF 2). The inhibition can be largely overcome by increasing the concentration of ribosomes. 2. The toxin does not affect the binding of phenylalanyl-tRNA to ribosomes catalysed by EF 1, nor does it inhibit the puromycin reaction used as a test for peptide-bond formation catalysed by ribosomes. 3. Ricin inhibits the ribosome-linked GTP hydrolysis catalysed by EF 2. 4. Ribosomes treated with ricin and washed through sucrose gradients containing 0.6m-NH(4)Cl are functionally inactive in those assay systems that are sensitive to the presence of added toxin. 5. It is suggested that ricin brings about an irreversible modification of ribosomes which impairs their ability to interact with EF 2. Since ricin inhibits at a molar concentration much lower than that of ribosomes it probably acts catalytically. No added cofactor is necessary for the inhibitory action of the toxin.

Role of guanine nucleotides in protein synthesis. Elongation factor G and guanosine 5'-triphosphate,3'-diphosphate

The possible role of guanosine 5'-triphosphate,3'-diphosphate (pppGpp) in protein synthesis by Escherichia coli ribosomes and protein factors was examined. Although pppGpp could effectively substitute for GTP in reactions catalyzed by initiation factor 2 (ribosomal binding of fMet-tRNA and formation of N-formylmethionylpuromycin) and elongation factor T (ribosomal binding of Phe-tRNA and formation of dipeptidyl-tRNA), pppGpp poorly supported polyphenylalanine synthesis. The interaction of elongation factor G with pppGpp was, therefore, examined in detail. The nucleotide was found to be almost without activity in the translocation reaction, as measured by formation of N-acetylphenylalanyl-phenylalanylpuromycin. Nevertheless, the rate of the catalytic hydrolysis of pppGpp to guanosine 5'-diphosphate,3'-diphosphate by elongation factor G and ribosomes was about 30% of the rate of hydrolysis of GTP, a rate of hydrolysis that significantly exceeded the rate of translocation with GTP. Moreover, the rates of the fusidic acid-dependent, elongation factor G-dependent binding of pppGpp and ppGpp to ribosomes were about 75 to 85% the rates of GTP and GDP binding, respectively. We also found that dGTP could substitute for GTP in all reactions examined.