Cooperative and antagonistic interactions of peptidyl-tRNA and antibiotics with bacterial ribosomes.

There is a single-site interaction of [methylene-14C]thiamphenicol and [methylene-14C]chloramphenicol with run-off ribosomes with dissociation constants Kd = 6.8 micronM and Kd = 4.6 micronM respectively. Similar affinities for the antibiotics are observed in polysomes totally deprived of nascent peptides, or bearing nascent peptides on the A-site. However, two types of interaction are observed in endogenous polysomes with some ribosomes bearing nascent peptides on the P-site and other in the A-site. The lower-affinity bindings (dissociation constants Kd = 6.4 micronM and Kd = 1.5 micronM for thiamphenicol and chloramphenicol respectively) are due to the ribosomes bearing nascent peptides on the A-site. The higher-affinity bindings (dissociation constants Kd = 2.3 micronM and Kd = 1.5 micronM for thiamphenicol and chloramphenicol, respectively) are due to the ribosomes bearing nascent peptides on the P-site. Therefore binding of nascent peptides to the A-site does not affect the affinities of thiamphenicol and chloramphenicol for the ribosome. On the other hand interaction of the nascent peptides with the P-site of the ribosomes increases the affinities of both antibiotics for the ribosome. Thiamphenicol and chloramphenicol are thus good inhibitors of peptide bond formation in ribosomes and polysomes. Their affinities are increased precisely when the peptidyl-tRNA is placed in the P-site preceeding the peptide bond formation step, which is specifically blocked by the antibiotics. There is a single-site interaction per ribosome for [35S]thiostrepton, which does not appear to be affected by the attachment to the ribosomes of mRNA, tRNA and nascent peptides either to the A or the P-site. [N-methyl-14C]Lincomycin, [N-methyl-14C]erythromycin, [G-3H]streptogramin B and [G-3H]-streptogramin A bind to run-off ribosomes and polysomes totally free from nascent peptides. However, these antibiotics do not interact with ribosomes bearing nascent peptides either in the A or the P-site and therefore are not active on preformed polysomes. Thus lincomycin and streptogramin A only interact with free ribosomes and 50-S subunits and block the early rounds of peptide bond formation prior to polysome formation. Erythromycin and streptogramin B do not inhibit either initiation or the first round of peptide bond formation. However, erythromycin and streptogramin B, prebound to the ribosome, block peptide elongation probably by steric hindrance with the growing oligopeptide chain when this reaches a certain critical length.     

Inhibition of translation in eukaryotic systems by harringtonine.

The Cephalotaxus alkaloids harringtonine, homoharringtonine and isoharringtonine inhibit protein synthesis in eukaryotic cells. The alkaloids do not inhibit, in model systems, any of the steps of the initiation process but block poly(U)-directed polyphenylalanine synthesis as well as peptide bond formation in the fragment reaction assay, the sparsomycin-induced binding of (C)U-A-C-C-A-[3H]Leu-Ac, and the enzymic and the non-enzymic binding of Phe-tRNA to ribosomes. These results suggest that the Cephalotaxus alkaloids inhibit the elongation phase of translation by preventing substrate binding to the acceptor site on the 60-S ribosome subunit and therefore block aminoacyl-tRNA binding and peptide bond formation. However, the Cephalotaxus alkaloids do not inhibit polypeptide synthesis and peptidyl[3H]puromycin formation in polysomes. Furthermore, these alkaloids strongly inhibit [14C]trichlodermin binding to free ribosomes but hardly affect the interaction of the antibiotic with yeast polysomot interact with polysomes and therefore only inhibit cycles of elongation. This explains the polysome run off that has been observed by some workers in the presence of harringtonine.     

70-S ribosomes of Escherichia coli have an additional site for deacylated tRNA binding

Escherichia coli 70-S ribosomes contain a third site for tRNA binding, additional to the A and P sites. This conclusion is based on several findings. Direct measurements showed that in the presence of poly(U), when both A and P sites are occupied by Ac[14C]Phe-tRNAPhe, ribosomes are capable of binding additionally deacylated non-cognate [3H]tRNA. If ribosomes in the preparation are active enough, the total binding of labeled ligands amounted to 2.5 mol/mol ribosomes. In the absence of poly(U), when the A site can not bind, the P site and the 'additional' site can be filled simultaneously with Ac[14C]Phe-tRNAPhe and deacylated [3H]tRNA, or with [3H]tRNA alone; the total binding exceeds in this case 1.5 mol/mol ribosomes. The binding at the 'additional' site is not sensitive to the template. [3H]tRNA bound there is able to exchange rapidly for unlabeled tRNA in solution. Deacylated tRNA is preferred to the aminoacylated one. The binding of AcPhe-tRNAPhe was not observed there at all. The 3'-end adenosine is essential for the affinity. The function of the 'additional' site is not known, but its existence has to be considered when tRNA . ribosome complexes are studied.     

Binding of labeled initiation factor IF-1 to ribosomal particles and the relationship to the mode of IF-1 action in ribosome dissociation.

The binding of labeled initiation factor IF-1 to ribosomal particles has been studied in relation to the mode of action of this factor in the dissociation of 70-S ribosomes. It is demonstrated that IF-1 interacts specifically with active 70-S tight couples and free 30-S subunits. The binding of IF-1 to both 70-S and 30-S particles is not influenced by the Mg2+ concentration and the affinity of the factor for both particles is about the same. The interaction of IF-1 with these particles is highest at low Tris-HCl concentrations. Under these conditions IF-1 shows a slight dissociating activity. Using 3H-labeled IF-1 and 14C-labeled IF-3 the formation of a 30-S-subunit.IF-1 . IF-3 complex from 70-S ribosomes is demonstrated. Our studies show that IF-3 enhances the binding of IF-1 to the 30-S subunit. In contrast to IF-1, which binds about equally well to 70-S and 30-S particles in the absence of IF-3, 14C-labeled IF-3 binds predominantly to the 30-S subunit. This finding confirms the view that IF-3 acts as an anti-association factor. On the other hand, IF-1 enhances the supply of 30-S subunits in the presence of IF-3 by acting on the 30-S moiety of the 70-S ribosome.     

mRNA-binding site of ribosomes at different stages of translation. II. Affinity modification of Escherichia coli ribosomes bya benzylidene derivative of AUGU6 in pre- and post-translation complexes

Affinity labeling of E. coli ribosomes with the 2',3'-O-[4-(N-2-chloroethyl)-N-methyl-amino]benzylidene derivative of AUGU6 (AUGU6-[14C]CHRCl) was studied within the pretranslocational complex ribosome.AUGU6[14C]CHRCl.tRNA(fMet)(P-site).fMetPhe-tR NA(Phe)(A-site) and posttranslocational complex ribosome.AUGU6[14C]CHRCl.fMetPhe-tRNA(Phe)(P-site). Both 30S and 50S subunits were labeled within these complexes, but the extent of 30S subunit modification was 6-8-fold higher than those for 50S subunit. Ribosomal proteins of both subunits were found to be labeled preferentially. Proteins S1, S5, S11, L1 were identified to be crosslinked with AUGU6[14C]CHRCl within the pretranslocational complex and S7--within the posttranslocational complex from the data of two-dimensional electrophoresis in the polyacrylamide gel.     

Analysis of the puromycin reaction. The ribosomal exclusion principle for AcPhe-tRNA binding re-examined

The standard technique for determination of the ribosomal site location of bound tRNA, viz. the puromycin reaction, has been analyzed with regard to its applicability under tRNA saturation conditions. The criteria derived have been used to re-examine the exclusion principle for peptidyl-tRNA binding, which states that only one peptidyl-tRNA (AcPhe-tRNA) can be bound per ribosome although in principle two sites (A and P site) are available. The following results were obtained. The puromycin reaction is only appropriate for a site determination if the reaction conditions prevent one ribosome from performing more than one puromycin reaction. With an excess of AcPhe-tRNA over ribosomes, and in the absence of EF-G, this criterion is fulfilled at 0 degree C, where the P-site-bound material reacts with puromycin (quantitative reaction after 50 h), while the A-site-bound material does not. In contrast, at 37 degrees C the extent of the puromycin reaction can exceed the binding values by 2-4-fold ('repetitive reaction'). In the presence of EF-G a repetitive puromycin reaction is seen even at 0 degree C, i.e. EF-G can already promote a translocation reaction at 0 degree C. However, the extent of translocation becomes negligibly low for short incubation times (up to 60 min) at 0 degree C, if only catalytic amounts of EF-G are used. Using the criteria outlined above, the validity of the exclusion principle for Escherichia coli ribosomes was confirmed pursuing two different experimental strategies. Ribosomes were saturated with AcPhe-tRNA at one molecule per 70S ribosome, and a quantitative puromycin reaction demonstrated the exclusive P-site location of the AcPhe-tRNA. The same result was also found in the presence of viomycin, which blocks the translocation reaction. These findings also indicate that here nearly 100% of the ribosomes participate in AcPhe-tRNA binding to the P site. Precharging the P sites of 70S ribosomes with one Ac[14C]Phe-tRNA molecule per ribosome prevented additional Ac[3H]Phe-tRNA binding. In contrast, 70S particles carrying one molecule of [14C]tRNAPhe per ribosome were able to bind up to a further 0.64 molecule Ac[3H]Phe-tRNA per ribosome.     

The effect of initiation factor IF-1 on the dissociation of 70-S ribosomes of Escherichia coli.

By means of exchange studies, in which 3H-labelled 50-S subunits and unlabelled 70-S ribosomes from Escherichia coli MRE 600 were used, it has been demonstrated that the 30-S subunit is the only target for IF-3 in the dissociation of 70-S ribosomes. The interference of IF-3 with the dynamic equilibrium of 70-S in equilibrium 50-S + 30-S occurs by binding of the factor to the 30-S subunit. The 30-S-IF-3 complex in impaired in the association reaction, which implies that IF-3 is acting as an anti-association factor. The action of IF-1 is two-fold. Firstly IF-1 increases the rate of exhcange of the ribosomal subparticles in the 70-S ribosome without changing the position of the equilibrium. Thus the spontaneous equilibrium is attained more rapidly in the presence of IF-1. This kinetic effect of IF-1 is also demonstrated in the IF-3-mediated dissociation of 70-S ribosomes. Secondly IF-1 is able to increase the IF-3-mediated dissociation. It seems likely that the explanation for the latter phenomenon must be sought in the binding of IF-1 to 70-S ribosomes, resulting in a loosening of the ribosomes structure, as well as to 30-S. IF-3 complex, thaereby slowing down the association reactions of the subunits.     

Binding of tRNA in different functional states to Escherichia coli ribosomes as measured by velocity sedimentation

The binding of initiator and elongator tRNAs to 70-S ribosomes and the 30-S subunits was followed by velocity sedimentation in the analytical ultracentrifuge. fMet-tRNAfMet binds to A-U-G-programmed 30-S subunits, but not to free or misprogrammed particles. Both the formylmethione residue and the initiation factors increase the stability of the 30-S x A-U-G x fMet-tRNAfMet complex. fMet-tRNAfMet is bound only to the P site of the 70-S ribosome even in the absence of A-U-G. Two copies of tRNAPhe or Phe-tRNAPhe are bound to the ribosome with similar affinity. In contrast to a recent report [Rheinberger et al. (1981) Proc. Natl Acad. Sci. USA, 78, 5310-5314], it is shown that three copies of tRNA cannot be bound simultaneously to the ribosome with binding constants higher than 2 x 10(4) M-1. Phe-tRNAPhe when present as the ternary complex Phe-tRNAPhe. EF-Tu x guanosine 5'-[beta,gamma-methylene]triphosphate binds exclusively to the A site. The peptidyl-tRNA analogue, acetylphenylalanine-tRNA, can occupy both ribosomal centers, albeit with a more than tenfold higher affinity for the P site. The thermodynamic data obtained under equilibrium conditions confirm the present view of two tRNA binding sites on the ribosome. The association constants determined are discussed in relation to the mechanism of ribosomal protein synthesis.     

(3H)anisomycin binding to eukaryotic ribosomes

Anisomycin, a well-known inhibitor of eukaryotic ribosomes' peptidyl-transferase activity, specifically binds to the 60 S ribosome subunit. Quantitative studies on [³H]anisomycin binding to yeast and human tonsil ribosomes have shown that a maximum of one molecule of the antibiotic is bound per ribosome in both cases. There is a single type of binding to 60 S subunits but ribosomes themselves are not homogeneous with respect to [³H]anisomycin binding, since the interaction between antibiotic and ribosome occurs with two different affinities. Only ribosomes having the higher type of affinity for [³H]anisomycin are active in catalysing peptide bond formation, as tested in both the puromycin and the fragment reaction assays. Affinity of [³H]anisomycin for ribosomes is higher at 0 °C than at 30 °C. Affinity is decreased in the presence of ethanol.The acetate group in the 3′ position of the pyrrolidine ring of anisomycin is important for the anisomycin—ribosome interaction since deacetylanisomycin appears to have a mode of action similar to anisomycin but has an affinity for the ribosome that is 350 times smaller.The effect of certain peptidyl-transferase inhibitors has been tested on [³H]anisomycin binding to ribosomes. Using either yeast or human tonsil ribosomes a number of sesquiterpene antibiotics of the trichodermin group (trichodermin, trichodennol, fusarenon X and trichothecin) totally block [³H]anisomycin binding whereas puromycin and verrucarin A only partially inhibit the [³H]anisomycin interaction with ribosomes. Gougerotin, blasticidin S and actinobolin have no effect. Tenuazonic acid and sparsomycin inhibit [³H]anisomycin binding to ribosomes but the degree of inhibition differs between yeast and human tonsil ribosomes.     

Characterization of different conformational forms of 30 S ribosomal subunits in isolated and associated states: possible correlations between structure and function.

The reaction pattern with N-[¹⁴C]ethylmaleimide served to follow conformational changes of 30 S ribosomal subunits that are induced by association with 50 S subunits and by the binding of aminoacyl-tRNA to 70 S ribosomes either enzymatically or non-enzymatically.The usefulness of the reaction with N-ethylmaleimide in discerning different conformational forms of the ribosome was previously demonstrated (Ginzburg et al., 1973) in an analysis of inactive and active 30 S subunits (as obtained at low Mg²⁺ and after heat reactivation, respectively). The reaction pattern of the 30 S moiety of 70 S ribosomes differs from the pattern of isolated active subunits (the only form capable of forming 70 S ribosomes) in both the nature of the labeled proteins and in being Mg²⁺-dependent. The reaction at 10 mm-Mg²⁺ reveals the following differences between isolated and reassociated 30 S subunits: (1) proteins S1, S18 and S21 that are not labeled in isolated active subunits, but are labeled in the inactive subunits, are highly reactive in 70 S ribosomes; (2) proteins S2, S4, S12 and S17 that uniquely react with N-ethylmaleimide in active subunits are all rendered inaccessible to modification after association; and (3) proteins S9, S13 and S19, that react in both active and inactive 30 S subunits, are labeled to a lesser extent in the 70 S ribosomes than in isolated subunits. This pattern is altered in two respects when the reaction with the maleimide is carried out at 20 mm-Mg²⁺; protein S18 is not modified while S17 becomes labeled.The differences in reaction pattern are considered as manifesting the existence of different conformational forms of the 30 S subunit in the dissociated and associated states as well as of different forms of 70 S ribosomes. The 30 S moiety of 70 S ribosomes at 10 mm-Mg²⁺ resembles the inactive subunit, while some of the features of the active subunit are preserved in the 70 S ribosome at 20 mmMg²⁺. The structural changes appear to be expressed in the functioning of the ribosome: non-enzymatic binding of aminoacyl-tRNA to active 30 S subunits is suppressed by 50 S subunits at 10 mm but not at 20 mm-Mg²⁺ (Kaufmann &; Zamir, 1972). The fact that elongation factor Tu-mediated binding is not suppressed by 50 S subunits raises the possibility that the function of the elongation factor might involve the facilitation of a conformational change of the ribosome. The analysis of different ribosomal binding complexes with N-ethylmaleimide showed that the binding of poly(U) alone results in a decrease in the labeling of S1 and S18. Binding of aminoacyl-tRNA, on the other hand, is closely correlated with the exposure of S17 for reaction with the maleimide. A model is outlined that accounts for this correlation as well as for the proposed role of elongation factor Tu.     

Effect of neomycin and protein S1 on the binding of streptomycin to the ribosome

The binding of [3H]dihydrostreptomycin to the 70-S ribosome or to the 30-S subunit has been investigated in the presence of neomycin by the Millipore filtration or the equilibrium dialysis procedure. It was observed that dihydrostreptomycin binds equally well to the 30-S subunit and the 70-S ribosome, and that neomycin stimulates the binding of dihydrostreptomycin to the ribosome by increasing the association constant and not by creating new binding sites. Specific removal of protein S1 from the 30-S subunit neither affected the binding of dihydrostreptomycin to the ribosome nor the stimulation of dihydrostreptomycin binding by neomycin.     

The proteins of the messenger RNA binding site of Escherichia coli ribosomes.

Oligo(U) derivatives with [14C]-4-(N-2-chloroethyl-N-methylamino)benzaldehyde attached to 3'-end cis-diol group via acetal bond, p(Up)n-1UCHRCl as well as with [14C]-4-(N-2-chloroethyl-N-methylamino)benzylamine attached to 5'-phosphate via amide bond, ClRCH2NHpU(pU)6 were used to modify 70S E. coli ribosomes near mRNA binding centre. Within ternary complex with ribosome and tRNAPhe all reagents covalently bind to ribosome the extent of modification being 0.1-0.4 mole/mole 70S. p(Up)n-1UCHRCl alkylates either 30S (n=5,7) or both subunits (n=6,8). rRNA is preferentially modified within 30S subunit. ClRCH2NHpU(pU)6 alkylates both subunits the proteins being mainly modified. The distribution of the label among proteins differ for various reagents. S4, S5, S7, S9, S11, S13, S15, S18 and S21 are found to be alkylated within 30S subunit, proteins L1, L2, L6, L7/L12, L19, L31 and L32 are modified in the 50S subunit. Most proteins modified within 30S subunit are located at the "head" of this subunit and proteins modified within 50S subunit are located at the surface of the contact between this subunit and the "head" of 30S subunit at the model of Stoffler.     

Studies on the binding of N-bromoacetylpuromycin and N-bromoacetylaminonucleoside to rat liver ribosomes.

[3H]N-Bromoacetylaminonucleoside and [3H]N-bromoacetylpuromycin have been synthesised as possible alkylating agents in order to study their interactions with rat liver ribosomes. Both compounds bind covalently to ribosomes to a considerable extent. The puromycin derivative binds to the extent of approximately 8 mol per ribosome, while the aminonucleoside derivative binds to the extent of approximately 13 mol per ribosome. Ammonium sulphate precipitation of ribosomes or treatment with puromycin, followed by washing of the ribosomes through NH4Cl-containing sucrose density gradients decreases the binding of both derivatives. Partial unfolding or denaturation of ribosomes by heating at 65 degrees C or through the action of various chemical reagents appears to expose more sites for binding. However, at 15 min of heating the binding of the puromycin derivative decreased by approximately 50% while the binding of the aminonucleoside derivative was almost zero. Binding of both labelled derivatives occurred only with the 50S ribosomal subunit. The extent of binding to the smaller 30S subunit was approximately 4% of that of the 50S subunit. Various other experiments are also described dealing with the binding of [3H]N-acetylphenylalanyl-tRNA to the A site of ribosomes following treatment with the N-bromoacetyl derivatives.     

Spatial proximity of the ribosomal mRNA binding center to the 50S subunit]

4-(N-2-chloroethyl-N-methylamino)benzylamide of 5'-heptaadenylic acid was used for affinity labelling of the ribosome in the vicinity of its mRNA-binding centre. This derivative, similar to the free oligonucleotide, stimulates the binding of [14C]-lysyl-tRNA to ribosomes of E. coli and alkylates ribosomes both the 30S and the 50S subunits. The alkylation of ribosomes is inhibited by pre-incubation of ribosomes with polyadenylic acid, which suggests that the chemical modification is a specific one and occurs in the vicinity of mRNA-binding site. The fact, that a short oligonucleotide having an active group on its 5'end attacks the 50S subunit of ribosome may indicate that the mRNA-binding centre is located in the contact region between ribosomal subunits.     

Implication of arginyl residues in aminoacyl-tRNA binding to ribosomes

Modification of the 50-S subunits of Escherichia coli ribosomes with the arginine reagent phenylglyoxal produces inactivation of peptidyl transferase and inhibition of the binding of C(U)-A-C-C-A-LeuAc, phenylalanyl-tRNA and N-acetylphenylalanyl-tRNA to the ribosome. Hybridization experiments, using 1.25 M LiCl core particles and the corresponding split proteins from untreated and phenylglyoxal-treated 50-S subunits, indicate that inactivation and inhibition of binding are the effects of modification of a protein fraction, the functionality of the RNA moiety being unaffected by the reagent. The split proteins from phenylglyoxal-modified 50-S subunits are incorporated to 1.25 M LiCl core particles as well as those obtained from unmodified subunits, thus excluding the failure to bind as the cause of inactivation. In agreement with the general role played by the arginyl residues as positive binding sites for anionic ligands, the present results indicate that the arginyl residues of a protein fraction from 50-S subunits might be important in the binding of aminoacyl-tRNA and peptidyl-tRNA to ribosomes.     

The binding of Met-tRNAf to isolated 40-S ribosomal subunits and the formation of Met-tRNAf - 80-S-ribosome initiation complexes.

Different forms of 40-S ribosomal subunit, distinguishable by their buoyant densities on CsCl equilibrium density gradients, are formed when derived 40-S ribosomal subunits are incubated with partially purified reticulocyte ribosomal wash proteins. One of these subunits, the 1.37-g-cm-3 form is not present in the cell but the other two forms, the 1.40-g-cm-3 and 1.40-g-cm-3 subunits, are present in cell extracts. 35S label is bound to 1.37-g-cm-3 and 1.40-g-cm-s subunits when [35S]Met-tRANf, GTP and poly(A,U,G) are included in the incubations. The 35S-labelled 40-S subunits recovered, and the amount of 35S label bound to them, are changed if the [35S]Met-tRNAf-40-S-subunit-poly(A,U,G) complexes are first purified on sucrose gradients before analysing them on CsCl. The 1.37-g-cm-3 particle is no longer seen and the total quantity of 35S label on the 40-S subunits is 90% lower after sucrose gradient purification. Between 30% and 40% of the 40-S subunits bind [35S]Met-tRNAf when 1 mM GTP, an excess of ribosomal wash proteins and [35S]Met-tRNAf over derived 40-S subunits, and poly(A,U,G) or AUG is included in the incubations. The omission of poly(A,U,G) or AUG from the incubations substantially lowers the amount of subunit-bound 35S label ultimately recovered. With these incubations less than 10% of the 40-S subunits have bound [35S]Met-tRNAf. [35S]Met-tRNAf binding is affected by the nature of the RNA added. The addition of poly(U), rRNA and native 9-S golbin mRNA is without effect, whereas denatured globin mRNA is stimulatory. Maximum binding is obtained however with AUG. Poly(A,U,G) is less stimulatory than AUG but more stimulatory than denatured mRNA, suggesting that the number as well the accessibility of the AUG initiations condons determines the amount of 35S label bound. Similar results are obtained for the ribosomal-wash-dependent binding of [35S]Met-tRNAf to 80-S ribosomes. Contrary to the binding results, the ability of mRNA to stimulate protein synthesis is dependent on the integrity of the mRNA. Thus, native 9-S globin mRNA but not poly(A,U,G) stimulatex protein synthesis in the wheat germ system. HCHO-treated globin mRNA, although stimulatory, is 45% less effective than native mRNA. The addition of AUG, derived 60-S subunits and extra ribosomal wash is required for the formation of [35S]Met-tRNAf-80-S-ribosome complexes from sucrose-gradient-purified [35S]Met-tRNAf-40-S-subunit complexes. The 80-S ribosome complexes are able to form peptide bonds. Thus, if puromycin is added to the full incubations at zero time, no 35S label is present on the 80-S ribosome. 35S label is released as methionyl-puromycin. If the [35S]Met-tRNAf-40-S-subunit complexes are assembled with poly(A,U,G) or AUG in the incubations and then purified, only derived 60-S subunits are required to form [35S]Met-tRNAf-80-S-ribosome complexes. 35S label is not released from them when puromycin is added to the incubations unless extra ribosomal wash is also added.     

Codon-anticodon interaction at the ribosomal E site

The question of whether or not the tRNA at the third ribosomal binding site specific for deacylated tRNA (E site) undergoes codon-anticodon interaction was analyzed as follows. Poly(U)-programmed ribosomes each carrying two [14C]tRNAPhe molecules were subjected to a chasing experiment using various tRNA species. At 0 degree C Ac[3H]Phe-tRNAPhe did not trigger any chasing whereas deacylated cognate tRNAPhe provoked a strong effect; non-cognate tRNALys was totally ineffective. This indicates that the second [14C]tRNAPhe cannot be present at the A site but rather at the E site (confirming previous observations). In the presence of poly(U) or poly(A) ribosomes bound the cognate tRNA practically exclusively as second deacylated tRNA, i.e. [14C]tRNAPhe and [14C]tRNALys, respectively. Thus, the second deacylated tRNA binds in a codon-dependent manner. [14C]tRNALys at the P site and Ac[3H]Lys-tRNALys at the A site of poly(A)-primed ribosomes were translocated to the E and P sites, respectively, by means of elongation factor G. The E site-bound [14C]tRNALys could be significantly chased by cognate tRNALys but not by non-cognate tRNAPhe, indicating the coded nature of the E site binding. Additional evidence is presented that the ribosome accommodates two adjacent codon-anticodon interactions at either A and P or P and E sites.     

Cooperative effects in the peptidyltransferase center of Escherichia coli ribosomes

We have measured the binding isotherms of C--A--C--C--A(3'NH)-[14C]Phe to the 70S ribosomes and 50S subunits of Escherichia coli and proposed a theoretical model for adsorption when cooperative interaction occurs between ligands that are adsorbed on ribosomes. Analysis of the experimental binding isotherms leads to the following conclusions. A ribosome (or subunit) binds two C--A--C--C--A(3'NH)-Phe molecules. The binding of C--A--C--C--A(3'NH)-Phe to a ribosome (or subunit) is a cooperative process, characterized by a cooperativity coefficient tau = 40 +/- 5 or more. The binding of C--A--C--C--A(3'NH)-AcPhe at the donor site of the peptidyltransferase center (association binding constant 1.5 X 10(6) M-1) and the binding of puromycin at the acceptor site also occur cooperatively with a coefficient of 10-25, the association binding constant of puromycin at the acceptor site being (1-2) X 10(4) M-1. The puromycin association binding constant at the donor site multiplied by the cooperativity coefficient of two interacting puromycin molecules absorbed on a ribosome equals 100-200 M-1.     

Peptidyl transferase of bacterial ribosome: resistance to proteinase K.

70-S ribosomes and 50-S ribosomal subunits from Escherichia coli D10 were treated with proteinase K for increasing periods of time. Peptidyl transferase activity and sparsomycin-induced binding of (U)C-A-C-C-A-[3H]Leu-Ac were tested in the treated particles, the binding of the substrate being more sensitive to the protease than peptide bond formation. Comparison of the amounts of proteins present in the treated particles with the residual activity indicates that only proteins L3 and L14 are released at a similar rate to that at which peptidyl transferase activity is lost. Proteins related to this ribosomal activity by other techniques are lost at a faster rate than the activity itself. In addition, the results indicate that sparsomycin stimulates the binding of the substrate by a different mechanism from that which inhibits peptide bond formation.