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.     

Affinity labelling of Escherichia coli ribosomes with a benzylidene derivative of AUGU6 within initiation and pretranslocational complexes

Affinity labelling of E. coli ribosomes with the 2',3'-O-[4-(N-2-chloroethyl)-N-methylamino]benzylidene derivative of AUGU6 was studied within the initiation complex (complex I) obtained by using fMet-tRNAMetf and initiation factors and within the pretranslocational complex (complex II) obtained by treatment of complex I with the ternary complex Phe-tRNAPhe.GTP.EF-Tu. Both proteins and rRNA of 30 S as well as 50 S subunits were found to be labelled. Sets of proteins labelled within complexes I and II differ considerably. Within complex II, proteins S13 and L10 were labelled preferentially. On the other hand, within complex I, multiple modification is observed (proteins S4, S12, S13, S14, S15, S18, S19, S20/L26 were found to be alkylated) despite the single fixation of a template in the ribosome by interaction of the AUG codon with fMet-tRNAMetf.     

The use of cross-linking platinum reagents in the study of tRNA and mRNA interaction with ribosomes

The use of some bifunctional Pt(II)-containing cross-linking reagents for investigation of structural organization of ribosomal tRNA- and mRNA-binding centres is demonstrated for various types of [70S ribosome.mRNA-tRNA] complexes. It is shown that treatment of the complexes [70S ribosome.Ac[14C]Phe-tRNA(Phe).poly(U)], [70S ribosome.3'-32pCp-tRNA(Phe).poly(U)] and [70S ribosome.f[35S]Met-tRNA(fMet).AUGU6] with Pt(II)-derivatives results in covalent attachment of tRNA to ribosome. AcPhe-tRNA(Phe) and 3'-pCp-tRNA(Phe) bound at the P site were found to be cross-linked preferentially to 30S subunit. fMet-tRNA(fMet) within the 70S initiation complex is cross-linked to both ribosome subunits approximately in the same extent, which exceeds two-fold the level of the tRNA(Phe) cross-linking. All used tRNA species were cross-linked in the comparable degree both to rRNA and proteins of both subunits in all types of the complexes studied. 32pAUGU6 cross-links exclusively to 30S subunit (to 16S RNA only) within [70S ribosome.32pAUGU6.fMet-tRNA(fMet)] complex. In the absence of fMet-tRNAfMet the level of the cross-linking is 4-fold lower.     

Differences in 23 S rRNA-protein neighbourhood in Escherichia coli 70 S ribosomes and 70 S initiation complex. Probing by bifunctional Pt(II)-containing reagent

rRNA-protein cross-links in free E. coli 35S-labeled 70 S ribosomes and in the initiation complex 35S-labeled 70 S ribosome.AUGU6.fMet-tRNA(fMet) were studied with the aid of a new type of binuclear Pt(II) compound - dichlorotetra-ammine(1,6-hexamethylenediaminediplatinum++ +) dichloride. The use of this reagent allowed us to reveal differences in the rRNA-protein neighbourhood in free 70 S ribosomes and in the initiation complex. Proteins L3, L6, L23 and L25 were shown to cross-link to 23 S rRNA only in the initiation complex, whereas proteins L1, L13, L14, L16, L17, L18, L22, L28 and S1 did so in both free ribosomes and the complex. 16 S rRNA was found to be cross-linked preferentially to a single protein, S1, in both states of the ribosomes.     

Affinity modification of Escherichia coli ribosomes with the non-hydrolyzed GTP analog, gamma-[4-N-(2-chloroethyl)-N-methylaminobenzyl]amide of GTP

Substituted gamma-amides of GTP viz. GTP gamma-[4-N-(2-chloro- and gamma-[4-N-(2-hydroxyethyl)-N-methylaminobenzyl]amide (CIRCH2NHpppG and OHRCH2NHpppG, resp.) were shown to be unhydrolisable GTP analogues in the EF-Tu-dependent GTP-ase reaction of ribosomes. The reactive analogue, CIRCH2NHpppG, was used for affinity labelling within the 70S ribosome.poly(U).tRNAPhe(P-site).Phe-tRNAPhe.EF-Tu.CIR[14C]CH2.NHpppG complex. Both 50S and 30S subunits were thus labelled but 50S subunit was modified considerably more than 30C subunit. Labelled were proteins L17, L21, S16, S21, and rRNA of both subunits, 23C rRNA within 50C subunit being labelled preferentially as compared with 50C proteins. No labelling of EF-Tu within the complex was detected.     

Study of the ribosome mRNA-binding region during different stages of translation. I. Functional activity of mRNA analogs, AUGU6 and its benzylidene derivatives, in ribosome-dependent protein synthesis

Hexaribouridylic acid, prepared by digestion of poly(U) with cobra venom endonuclease, and trinucleotide AUG synthesized chemically by triester approach were joined by RNA-ligase to yield a nonaribonucleotide AUGU6 bearing the initiation codon at its 5'-terminus. 2',3'-O-(4-[N-(2-chloro(or hydroxy) ethyl-N-Methylamino])- benzylidene residues were introduced at the 3'-terminus of oligonucleotide AUGU6 and its benzylidene derivatives AUGU6CHRCl or AUGU6CHROH were obtained. The mRNA analogs synthesized were tested for their template activity in the formation of 70S initiation complex. AUGU6, AUGU6CHRC1 and AUGU6CHROH were shown to stimulate factor-dependent binding of fMet-tRNA to ribosomes. The effect of benzylidene fragment on the template activity of AUGU6CHROH in the course of translation process was studied. It was shown that AUGU6CHROH stimulates synthesis of di- and tripeptides with the same efficiency as AUGU6.     

rRNA-protein neighbourhood in Escherichia coli 70 S ribosomes and 70 S initiation complex. Probing by bifunctional Pt(II)-containing reagent

The cleavable homobifunctional reagent dichloro[N,N,N',N'-tetrakis(2-aminoethyl)-1,6-hexamethylenediamminedi platinum (II)] dichloride was used for studying rRNA-protein cross-links in free 35S-labelled 70 S ribosomes and within initiation complex ribosome.AUGU6.fMet-tRNA(fMet). It was shown that the sets of proteins cross-linked to 16 S and 23 S rRNA in free 70 S ribosomes and in 70 S initiation complex do not differ significantly. The authors are the first to demonstrate most of the 23 S rRNA-protein cross-links and some 16 S rRNA-protein cross-links, in particular those with L7/L12 protein.     

Function of initiation factor 1 in the binding and release of initiation factor 2 from ribosomal initiation complexes in Escherichia coli.

1. Studies on the function of initiation factor 1 (IF-1) in the formation of 30 S initiation complexes have been carried out. IF-1 appears to prevent the dissociation of initiation factor 2 (IF-2) from the 30 S initiation complex. The factor has no effect on either the initial binding of IF-2 nor does it increase the amount of IF-2 dependent fMet-tRNA and GTP bound to the 30 S subunit. Bound fMet-tRNA remains stable to sucrose gradient centrifugation even in the absence of IF-1. 2. It is postulated that the presence of IF-2 on the 30 S complex is necessary so that at the time of junction with the 50 S subunit to form a 70 S complex, the 70 S-dependent GTPase activity of IF-2 can hydrolyze GTP. This hydrolysis provides a means by which GTP can be removed to facilitate formation of a 70 S initiation complex active in peptidyl transfer. In support of this postulate, it was observed that 30 S initiation complexes formed in the absence of IF-1 could be depleted of their complexes were still able to accept 50 S subunits to form 70 S complexes which could still donate fMet-tRNA into peptide linkages. These results indicate that 30 S complexes lacking GTP do not require IF-2 for formation of active 70 S complexes. 3. IF-1, which is required to prevent dissociation of IF-2 from the 30 S initiation complex, is also required for release of IF-2 from ribosomes following 70 S initiation complex formation. The mechanisms of the release of IF-2 has been studied in greater detail. Evidence is presented which rules out the presence of a stable IF-2 GDP complex on the surface of the 70 S ribosome following GTP hydrolysis and of any exchange reactions between IF-1 and guanine nucleotides necessary for effecting the release of IF-2. IF-2 remains on the 70 S initiation complexes after release of guanine nucleotides and can be liberated solely by addition of IF-1.     

Photochemical cross-linking of translation initiation factor 3 to Escherichia coli 50S ribosomal subunits

Translation initiation factor 3 (IF-3) was bound noncovalently to Escherichia coli 50S ribosomal subunits. Irradiation of such complexes with near-ultraviolet light (greater than 285 nm) resulted in covalent attachment of initiation factor 3 to the 50S subunit. Photo-cross-linking attained its maximum level of 40% of that which was noncovalently bound after 90 min of irradiation. Cross-linking was abolished in the presence of either 0.5 M NH4C1 or 0.25 mM aurintricarboxylic acid, indicating that specific binding of initiation factor 3 to the ribosome was a prerequisite for subsequent covalent attachment. Further analysis showed that all the IF-3 was covalently bound to a small number of 50S subunit proteins. The major cross-linked proteins were identified as L2, L7/L12, L11, and L27 by immunochemical techniques. These results are discussed in light of the proposed mechanism for IF-3 function.     

Initiation factor IF-3 and the binary complex between initiation factor IF-2 and formylmethionyl-tRNA are mutually exclusive on the 30-S ribosomal subunit.

The formation of 30-S initiation complexes depends strongly on initiation factor IF-3; at molar ratios of IF-3 to 30-S ribosomes up to one a stimulation is observed, whereas at ratios higher than one, initiation complex formation declines strongly. The target of the observed inhibition of fMet-tRNA binding at high concentrations of IF-3 is the 30-S initiation complex itself. On the one hand addition of IF-3 to preformed 30-S initiation complexes leads to a release of bound fMet-tRNA which is linear with the amount of factor added, whereas no effect on isolated 70-S initiation complexes is seen. The release of fMet-tRNA from preformed 30-S initiation complexes is accompanied by a release of IF-2 in a one-to-one molar ratio which is in agreement with our previous findings showing that binding of fMet-tRNA takes place via a binary complex: IF-2 . fMet-tRNA (Eur. J. Biochem. 66, 181--192 and 77, 69--75). On the other hand increasing amounts of both IF-2 and fMet-tRNA relieve the IF-3-induced inhibition of 30-S initiation complex formation. From these findings it is concluded that IF-3 and the IF-2 . fMet-tRNA complex are mutually exclusive on the 30-S ribosome. This implies that under our experimental conditions MS2 RNA binding precedes fMet-tRNA binding if one accepts that the presence of IF-3 on the 30-S subunit is obligatory for messenger binding.     

Initial rate kinetic analysis of the mechanism of initiation complex formation and the role of initiation factor IF-3.

Initial rate kinetics of the formation of ternary complexes of Escherichia coli 30S ribosomal subunits, poly(uridylic acid), and N-acetylphenylalanyl transfer ribonucleic acid in the presence and in the absence of IF-3 are consistent with the hypothesis that the ternary complex is formed through a random order of addition of polynucleotide and aminoacyl-tRNA to separate and independent binding sites on the 30S ribosomes. The transformation of an intermediate into a stable ternary complex which probably entails a rearrangement of the ribosome structure leading to a codon-anticodon interaction represents the rate-limiting step in the formation of the ternary complex. The rate constant of this transformation, as well as the association constants for the formation of the 30S-poly(U) and 30S-N-AcPhe-tRNA binary complexes, are enhanced by the presence of IF-3 which acts as a kinetic effector on reactions which are intrinsic properties of the 30S ribosome. The IF-3-induced modification of these kinetic parameters of the 30S ribosomal subunit can per se explain the effect of IF-3 on protein synthesis without invoking a specific action at the level of the mRNA-ribosome interaction. This seems to be confirmed by the finding that IF-3 can stimulate several-fold the formation of a ternary complex even if one by-passes the ribosome-template binding step by starting with a covalent 30S-polynucleotide binary complex. Furthermore, the above-mentioned changes induced by IF-3 appear to be compatible with the previously proposed idea that the binding of the factor modifies the conformation of the 30S subunit. The random order of addition of substrates determined for the 30S-N-AcPhe-tRNA-poly(U) model system was found to be valid also for the more physiological 30S initiation complex containing poly(A,U.G) and (fMet-tRNA formed at low Mg2+ concentration in the presence of GTP and all three initiation factors.     

Selective high-efficiency cross-linking of mammalian ribosomal proteins with cleavable thiol-directed heterobifunctional reagents: separation and identification of contact sequences of neighboring proteins after CNBr fragmentation

Mammalian ribosomal proteins were cross-linked in situ with the primarily cysteine-selective heterobifunctional reagents N-succinimidyl 2-(4-hydroxy-2-maleimidophenylazo)benzoate (reagent A, maximum range approx. 8 A) and N-succinimidyl 4-(4-hydroxy-3-maleimidophenylazo)[carboxyl-14C]benzoate (reagent B, maximum range approx. 12 A). With reagent B the secondarily attached (N-aryolated) protein becomes labelled specifically at the receptor amino group (lysine). The cross-linked proteins were fragmented with CNBr in attempts to isolate and identify sequences involved in the next-neighbor contacts. Two experimental schemes were adopted. Heavy complexes containing the large protein L4 cross-linked to protein L14 and/or L18 were isolated and treated with CNBr. The split products were submitted to diagonal electrophoresis for separation and identification of the two pairs of contact fragments. Proteins cross-linked with the radiolabelled reagent B were submitted to diagonal electrophoresis. The labelled receptor proteins were excised and treated with CNBr. Fragments carrying the contact sequences were separated by gradient gel electrophoresis and identified by autoradiography. By use of these methods CNBr fragments were isolated containing one or the dual contact sites of the following binary protein complexes: L4-L14, L4-L18, L4-L13a/L18a, L6'-L23, L6-L29, L7-L29, L14-L13a, L21-L18a, and L27-L30 (asterisks indicate the labelled receptor proteins). By varying the site of labelling of the heterobifunctional reagents and the methods of protein fragmentation a complete analysis of the contact sequences of these proteins should be possible.     

Study of the mRNA-binding region of ribosomes at different steps of translation. II. Affinity modification of Escherichia coli ribosomes by benzylidene derivative of AUGU6 in the 70S initiation complex

2',3'-O-(4-[N-(2-chloroethyl)-N-methylamino]) benzylidene derivative of AUGU6 was used for identification of the proteins in the region of the mRNA-binding centre of E. coli ribosomes. This derivative alkylated ribosomes (preferentially 30S ribosomal) with high efficiency within the 70S initiation complex. In both 30S and 50S ribosomal subunits proteins and rRNA were modified. Specificity of the alkylation of ribosomal proteins and rRNA with the reagent was proved by the inhibitory action of AUGU6. Using the method of two-dimensional electrophoresis in polyacrylamide gel the proteins S4, S12, S13, S14, S15, S18, S19 and S20/L26 which are labelled by the analog of mRNA were identified.     

Binding of protein synthesis initiation factor IF1 to 30 S ribosomal subunits: effects of other initiation factors and identification of proteins near the binding site.

The effects of other components of the initiation complex on Escherichia coli initiation factor IFI binding to 30 S ribosomal subunits were studied. Binding of [¹⁴C]IF1 in the absence of other initiation complex components was slight. Addition of either IF2 or IF3 stimulated binding to a variable extent. Maximum binding was observed when both IF2 and IF3 were present. Addition of GTP, fMet-tRNA, and phage R17 RNA caused little or no further stimulation of [¹⁴C]IF1 binding. A maximum of 0.5 molecule of [¹⁴C]IF1 bound per 30 S subunit in the presence of an excess of each of the three factors over 30 S subunits.Complexes of 30 S subunits, [¹⁴C]IF1, IF2, and IF3 were treated with the bifunctional protein cross-linking reagent dimethyl suberimidate in order to identify the ribosomal proteins near the binding site for IF1. Non-cross-linked [¹⁴C]IF1 was removed from the complexes by sedimentation through buffer containing a high salt concentration, and total protein was extracted from the pelleted particles. Approximately 12% of the [¹⁴C]IF1 was recovered in the pellet fraction. The mixture of cross-linked products was analyzed by polyacrylamide/sodium dodecyl sulfate gel electrophoresis. Autoradiography of the gel showed radioactive bands with molecular weights of 21,000, 25,000, and many greater than 120,000. The results indicate that [¹⁴C]IF1 was cross-linked directly to at least two ribosomal proteins. Analysis of the cross-linked mixture by radioimmunodiffusion with specific antisera prepared against each of the 30 S ribosomal proteins showed radioactivity in the precipitin bands formed with antisera against S12 and S19, and in lower yield with those against S1 and S13. Antiserum against IF2 also showed [¹⁴C]IF1 in the precipitin band. The results show that [¹⁴C]IF1 was present in covalently cross-linked complexes containing 30 S ribosomal proteins S1, S12, S13 and S19, and initiation factor IF2. The same ribosomal proteins have been implicated in the binding sites for IF2 and IF3. The results suggest that the three initiation factors bind to the 30 S subunit at the same or overlapping sites.     

Direct cross-links between initiation factors 1, 2, and 3 and ribosomal proteins promoted by 2-iminothiolane

Complexes were prepared containing 30S ribosomal subunits from Escherichia coli and the three initiation factors IF1, IF2, and IF3. In different experiments, each of the factors was radiolabeled with the others unlabeled. The complexes were allowed to react with 2-iminothiolane and then oxidized to promote the formation of intermolecular disulfide bonds, some of which were between factors and ribosomal proteins. Each of the labeled factors becomes covalently cross-linked to the complex as judged by its failure to dissociate when centrifuged in a sucrose gradient containing a high salt concentration. Proteins from the complexes were extracted and analyzed on two-dimensional polyacrylamide gels by nonequilibrium isoelectric focusing and sodium dodecyl sulfate gel electrophoresis. Spots corresponding to cross-linked dimers that contained initiation factors, as indicated on autoradiographs, were cut out and analyzed further. The following cross-linked dimers between factors and ribosomal proteins were identified: IF1-S12, IF1-S18, IF2-S13, IF3-S7, IF3-S11, IF3-S13, and IF3-S19. Cross-links between factors IF1-IF2 and IF3-IF2 were also identified. A model integrating these findings with others on the protein topography of the ribosome is presented.     

Chain initiation factor 3 crosslinks to E. coli 30S and 50S ribosomal subunits and alters the UV absorbance spectrum of 70S ribosomes

We report a direct procedure to determine the proteins near the IF-3 binding site in purified 30S and 50S ribosomal subunits. This procedure introduces only limited numbers of cleavable crosslinks between IF-3 and its nearest neighbors. The cleavable crosslinking reagent, 2-iminothiolane, was used to crosslink IF-3 in place to both 30S and 50S subunits. Ribosomal proteins S9/S11, S12, L2, L5 and L17 were found, by this approach, to be in close proximity to the factor in purified IF-3-subunit complexes. In addition, IF-3 was shown to alter the ultraviolet absorbance spectrum of E. coli 70S ribosomes at 10 mM Mg2+. The magnitude of the observed difference spectrum at a constant IF-3/ribosome ratio of 1.0, is linearly dependent upon ribosome concentration over the range 5 nM - 55 nM. Titration experiments indicated that the observed effect is maximal at an IF-3/ribosome ratio of approximately 1.0. These results are taken to indicate a conformational change in the 70S ribosome induced by IF-3.     

Structural arrangement of tRNA binding sites on Escherichia coli ribosomes, as revealed from data on affinity labelling with photoactivatable tRNA derivatives

A systematic study of protein environment of tRNA in ribosomes in model complexes representing different translation steps was carried out using the affinity labelling of the ribosomes with tRNA derivatives bearing aryl azide groups scattered statistically over tRNA guanine residues. Analysis of the proteins crosslinked to tRNA derivatives showed that the location of the derivatives in the aminoacyl (A) site led to the labelling of the proteins S5 and S7 in all complexes studied, whereas the labelling of the proteins S2, S8, S9, S11, S14, S16, S17, S18, S19, S21 as well as L9, L11, L14, L15, L21, L23, L24, L29 depended on the state of tRNA in A site. Similarly, the location of tRNA derivatives in the peptidyl (P) site resulted in the labelling of the proteins L27, S11, S13 and S19 in all states, whereas the labelling of the proteins S5, S7, S9, S12, S14, S20, S21 as well as L2, L13, L14, L17, L24, L27, L31, L32, L33 depended on the type of complex. The derivatives of tRNA(fMet) were found to crosslink to S1, S3, S5, S7, S9, S14 and L1, L2, L7/L12, L27. Based on the data obtained, a general principle of the dynamic functioning of ribosomes has been proposed: (i) the formation of each type of ribosomal complex is accompanied by changes in mutual arrangement of proteins - 'conformational adjustment' of the ribosome - and (ii) a ribosome can dynamically change its internal structure at each step of initiation and elongation; on the 70 S ribosome there are no rigidly fixed structures forming tRNA-binding sites (primarily A and P sites).     

The ribosomal binding site for eukaryotic elongation factor EF-2 contains 5 S ribosomal RNA

The possible location of RNA in the ribosomal attachment site for the eukaryotic elongation factor EF-2 was analysed. Stable EF-2 · ribosome complexes formed in the presence of the non-hydrolysable GTP analogue GuoPP[CH₂]P were cross-linked with the short (4 Å between the reactive groups) bifunctional reagent, diepoxybutane. Non-cross-linked EF-2 was removed and the covalent factor-ribosome complex isolated. No interaction between EF-2 and 18 S or 28 S rRNA could be demonstrated. However, density gradient centrifugation of the cross-linked ribosomal complexes showed an increased density (1.25 g/cm³) of the factor, as expected from a covalent complex between EF-2 and a low-molecular-weight RNA species. Treatment of the covalent ribosome-factor complexes with EDTA released approx 50% of the cross-linked EF-2 from the ribosome together with the 5 S rRNA · protein L5 complex. Furthermore, the complex co-migrated with the 5S rRNA · L5 particle in sucrose gradients. Polyacrylamide gel electrophoresis showed that EF-2 was directly linked to 5 S rRNA in the 5 S rRNA · L5 complex, as well as in the complexes isolated by density gradient centrifugation. No traces of 5.8 S rRNA or tRNA could be demonstrated. The data indicate that the ribosomal binding domain for EF-2 contains the 5 S rRNA · protein L5 particle and that EF-2 is located in close proximity to 5 S rRNA within the EF-2 · GuoPP[CH₂]P · ribosome complex.     

Cross-linking of elongation factor 2 to rat-liver ribosomal proteins by 2-iminothiolane

Complexes containing rat liver 80S ribosomes treated with puromycin and high concentrations of KCl, elongation factor 2 (EF-2) from pig liver, and guanosine 5'-[beta, gamma-methylene]triphosphate were prepared. Neighboring proteins in the complexes were cross-linked with the bifunctional reagent 2-iminothiolane. Proteins were extracted and then separated into 22 fractions by chromatography on carboxymethylcellulose of which seven fractions were used for further analyses. Each protein fraction was subjected to diagonal polyacrylamide/sodium dodecyl sulfate gel electrophoresis. Nine cross-linked protein pairs between EF-2 and ribosomal proteins were shifted from the line formed with monomeric proteins. The spots of ribosomal proteins cross-linked to EF-2 were cut out from the gel plate and labelled with 125I. The labelled protein was extracted from the gel and identified by three kinds of two-dimensional gel electrophoresis, followed by autoradiography. The following proteins of both large and small subunits were identified: L9, L12, L23, LA33 (acidic protein of Mr 33000), P2, S6 and S23/S24, and L3 and L4 in lower yields. The results are discussed in relation to the topographies of ribosomal proteins in large and small subunits. Furthermore we found new neighboring protein pairs in large subunits, LA33-L11 and LA33-L12.     

Structure-function relationship in Escherichia coli initiation factors. Biochemical and biophysical characterization of the interaction between IF-2 and guanosine nucleotides

Equilibrium dialysis and protection from heat inactivation and proteolysis show that initiation factor 2 (IF-2) interacts not only with GTP but also with GDP and that its conformation is changed upon binding of either nucleotide. The apparent Ka (at 25 degrees C) for the IF-2 X GDP and IF-2 X GTP complexes was 8.0 X 10(4) and 7.0 X 10(3) M(-1), respectively. The lower affinity for GTP is associated with a more negative delta S0. The interaction, monitored by 1HNMR spectroscopy, is characterized by fast exchange and results in line broadening and downfield shift of the purine C-8 and ribose C-1' protons of GTP as well as of the beta, gamma-methylene protons of (beta-gamma-methylene)guanosine 5'-triphosphate. The interaction of guanosine nucleotides with IF-2 requires an H bond donor (or acceptor) group at position C-2 of the purine and involves the beta- and/or gamma-phosphate of the nucleotide while the ribose 2'-OH group or the integrity of the furan ring are less critical. IF-2 binds to ribosomal particles with decreasing affinity: 30 S greater than 70 S greater than 50 S. GTP and GDP have no effect on the binding to 70 S. GTP stimulates the binding to the 30 S and depresses somewhat the binding to the 50 S subunits; GDP has the opposite effect. These results seem to rule out that the release of IF 2 from 70 S is due to a "GDP-conformation" of the factor incompatible with its permanence on the ribosome. The rate and the extent of 30 S initiation complex formation are approximately 2-fold higher with IF-2 X GTP than with IF-2 alone. At low concentrations of IF-2 and 30 S subunits, GDP inhibits this reaction, acting as a strong competitive inhibitor of GTP (Ki = 1.25 X 10(-5)m) and preventing IF-2 from binding to the ribosomal subunit.