tRNA binding stabilizes rat liver 60 S ribosomal subunits during treatment with LiCl

We have shown recently that, in the absence of mRNA, 1 molecule of nonacylated tRNA binds to the large ribosomal subunit of rat liver with a high affinity constant (Buisson, M., Reboud, A.M., Dubost, S., and Reboud, J. P. (1979) Biochem. Biophys. Res. Commun. 90,634-640). In this paper, free and tRNA-bound 60 S subunits were treated with increasing concentrations of LiCl to obtain information on tRNA binding site. The rationale for using deacylated tRNA was that it is assumed to bind to the peptidyl donor site. We observed that tRNA has a strong protective effect on subunit modifications produced by LiCl: tRNA prevents subunit inactivation as measured by puromycin reaction and polyphenylalanine synthesis and it shifts the Li+/Mg2+ ratio value needed to reach 50% inactivation, from 60 to 250; it also prevents ribosomal protein and 5 S RNA release and large sedimentation changes of subunits, induced by LiCl. To explain the mechanism of 60 S subunit stabilization by tRNA, two hypotheses are considered: stabilization can be consequent on direct interaction of tRNA with specific proteins, or on maintenance on subunits of essential cations which are otherwise displaced by Li+, or both.     

tRNA binding sites on the subunits of Escherichia coli ribosomes

Programmed 30 S subunits expose only one binding site, to which the different classes of tRNA (deacylated tRNAPhe, Phe-tRNAPhe, and N-acetylphenylalanyl (AcPhe)-tRNAPhe) bind with about the same affinity. Elongation factor Tu within the ternary complex does not contribute to the binding of Phe-tRNA. Binding of acylated or deacylated tRNA to 30 S depends on the cognate codon; nonprogrammed 30 S subunits do not bind tRNA to any significant extent. The existence of only one binding site/30 S subunit (and not, for example, two sites in 50% of the subunits) could be shown with Phe-tRNAPhe as well as deacylated tRNAPhe pursuing different strategies. Upon 50 S association the 30 S-bound tRNA appears in the P site (except the ternary complex which is found at the A site). Inhibition experiments with tetracycline demonstrated that the 30 S inhibition pattern is identical to that of the P site but differs from that of the A site of 70 S ribosomes. In contrast to 30 S subunits the 50 S subunit exclusively binds up to 0.2 and 0.4 molecules of deacylated tRNAPhe/50 S subunit in the absence and presence of poly(U), respectively, but neither Phe-tRNA nor AcPhe-tRNA. Noncognate poly(A) did not stimulate the binding indicating codon-anticodon interaction at the 50 S site. The exclusive binding of deacylated tRNA and its dependence on the presence of cognate mRNA is reminiscent of the characteristics of the E site on 70 S ribosomes. 30 and 50 S subunits in one test tube expose one binding site more than the sum of binding capacities of the individual subunits. The results suggest that the small subunit contains the prospective P site and the large subunit the prospective E site, thus implying that the A site is generated upon 30 S-50 S association.     

Affinity modification of the 40S subparticle from human placenta with derivatives of pAUG and pAUGU3]

Affinity labeling of 40S subunits from human placenta with 4-(N-2-chloroethyl-N-methylamino)benzylmethyl-[32P]phosphoamide s of oligoribonucleotides pAUG and pAUGU3 was studied. Covalent attachment of these derivatives to 40S subunits within the complexes with 40S subunits, formed in the presence of Met-tRNAf.eIF-2.GTP, was detected. Both rRNA and ribosomal proteins were modified. Fragments of 18S rRNA, containing sites of the reagent attachment were identified: 1058-1164 for pAUG derivative and 976-1057--for pAUG and pAUGU3 ones. The data obtained allowed to conclude that the presence of the neighbouring codon at the A-site, regardless of the presence of the tRNA in it, affects significantly the arrangement of the trinucleotide template in the codon-anticodon interaction region. The large subunit does not cause significant alterations in the structural organization of the codon-anticodon interaction region.     

Eukaryotic initiation complex formation. Evidence for two distinct pathways.

Two distinct pathways have been elucidated which lead to the formation of an AUG-dependent initiation complex. One pathway involves the use of initiation factor M1 (IF-M1) to promote AUG-dependent binding of the initiator tRNA to the 40 S subunit, followed by joining of the 60 S subunit in the presence of IF-M2A, IF-M2B, and GTP. The second pathway involves the IF-MP-directed binding of initiator tRNA to the 40 S subunit via a ternary complex of IF-MP-GTP-Met-tRNAf. This reaction does not require AUG codon. However, subsequent formation of an 80 S initiation complex (as determined by methionyl-puromycin synthesis) required AUG as well as IF-M2A, IF-M2B, and GTP. Since both pathways require the same complementary initiation factors (at the same level), it would appear that the only difference is the manner in which the initiator tRNA is bound to the 40 S subunit, either by IF-M1 or IF-MP. Examination of the requirements for endogenous mRNA-directed methionyl-puromycin synthesis indicates a greater difference between IF-MP and IF-M1 in that only IF-MP was capable of forming an 80 S initiation complex which was sensitive to puromycin.     

Factor requirements for translation initiation on the Simian picornavirus internal ribosomal entry site

The Simian picornavirus type 9 (SPV9) 5'-untranslated region (5' UTR) has been predicted to contain an internal ribosomal entry site (IRES) with structural elements that resemble domains of hepacivirus/pestivirus (HP) IRESs. In vitro reconstitution of initiation confirmed that this 5' UTR contains an IRES and revealed that it has both functional similarities and differences compared to HP IRESs. Like HP IRESs, the SPV9 IRES bound directly to 40S subunits and eukaryotic initiation factor (eIF) 3, depended on the conserved domain IIId for ribosomal binding and consequently for function, and additionally required eIF2/initiator tRNA to yield 48S complexes that formed elongation-competent 80S ribosomes in the presence of eIF5, eIF5B, and 60S subunits. Toeprinting analysis revealed that eIF1A stabilized 48S complexes, whereas eIF1 induced conformational changes in the 40S subunit, likely corresponding to partial opening of the entry latch of the mRNA-binding channel, that were exacerbated by eIF3 and suppressed by eIF1A. The SPV9 IRES differed from HP IRESs in that its function was enhanced by eIF4A/eIF4F when the IRES was adjacent to the wild-type coding sequence, but was less affected by these factors or by a dominant negative eIF4A mutant when potentially less structured coding sequences were present. Exceptionally, this IRES promoted binding of initiator tRNA to the initiation codon in the P site of 40S subunits independently of eIF2. Although these 40S/IRES/tRNA complexes could not form active 80S ribosomes, this constitutes a second difference between the SPV9 and HP IRESs. eIF1 destabilized the eIF2-independent ribosomal binding of initiator tRNA.     

Sucrose modifies ribosomal stability and conformation

High concentrations of sucrose have a strong protective effect on heat-induced modifications of rat liver ribosomal subunits. They prevent to a large extent subunit inactivation, measured by poly (U)-dependent [14C] Phe tRNA binding (40S subunits) and puromycin reaction (60S subunits), subunit unfolding into light forms, and the release of both free and protein-complexed 5S RNA. They also increase the temperature at which subunits start to melt. Our data indicate that sucrose affects subunit conformation.     

Overview: mechanism of translation initiation in eukaryotes

Evidence to date has placed considerable emphasis on protein synthesis initiation as the dominant site of translational control. Two specific aspects are regulated, the binding of the initiator tRNA to the 40S subunits (as a ternary complex with eIF-2 and GTP) and the subsequent binding of mRNA to the complex of the 40S subunit with initiator tRNA. In addition to regulation, eIF-2 and Met-tRNAf are in large part responsible for selection of the initiating AUG codon. The utilization of most host mRNAs requires an m7G cap structure at the 5' end. However, many viral systems appear to use one of two alternate initiation schemes referred to as re-initiation and internal initiation. The function of specific initiation factors is presented and the consequences of altering the activity of these factors is discussed.     

Footprinting mRNA-ribosome complexes with chemical probes.

We footprinted the interaction of model mRNAs with 30S ribosomal subunits in the presence or absence of tRNA(fMet) or tRNA(Phe) using chemical probes directed at the sugar-phosphate backbone or bases of the mRNAs. When bound to the 30S subunits in the presence of tRNA(fMet), the sugar-phosphate backbones of gene 32 mRNA and 022 mRNA are protected from hydroxyl radical attack within a region of about 54 nucleotides bounded by positions -35 (+/- 2) and +19, extending to position +22 when tRNA(Phe) is used. In 70S ribosomes, protection is extended in the 5' direction to about position -39 (+/- 2). In the absence of tRNA, the 30S subunit protects only nucleotides -35 (+/- 2) to +5. Introduction of a stable tetraloop hairpin between positions +10 and +11 of gene 32 mRNA does not interfere with tRNA(fMet)-dependent binding of the mRNA to 30S subunits, but results in loss of protection of the sugar-phosphate backbone of the mRNA downstream of position +5. Using base-specific probes, we find that the Shine-Dalgarno sequence (A-12, A-11, G-10 and G-9) and the initiation codon (A+1, U+2 and G+3) of gene 32 mRNA are strongly protected by 30S subunits in the presence of initiator tRNA. In the presence of tRNA(Phe), the same Shine-Dalgarno bases are protected, as are U+4, U+5 and U+6 of the phenylalanine codon. Interestingly, A-1, immediately preceding the initiation codon, is protected in the complex with 30S subunits and initiator tRNA, while U+2 and G+3 are protected in the complex with tRNA(Phe) in the absence of initiator tRNA. Additionally, specific bases upstream from the Shine-Dalgarno region (U-33, G-32 and U-22) as well as 3' to the initiation codon (G+11) are protected by 30S subunits in the presence of either tRNA. These results imply that the mRNA binding site of the 30S subunit covers about 54-57 nucleotides and are consistent with the possibility that the ribosome interacts with mRNA along its sugar-phosphate backbone.     

Positioning of the mRNA stop signal with respect to polypeptide chain release factors and ribosomal proteins in 80S ribosomes

To study positioning of the mRNA stop signal with respect to polypeptide chain release factors (RFs) and ribosomal components within human 80S ribosomes, photoreactive mRNA analogs were applied. Derivatives of the UUCUAAA heptaribonucleotide containing the UUC codon for Phe and the stop signal UAAA, which bore a perfluoroaryl azido group at either the fourth nucleotide or the 3'-terminal phosphate, were synthesized. The UUC codon was directed to the ribosomal P site by the cognate tRNA(Phe), targeting the UAA stop codon to the A site. Mild UV irradiation of the ternary complexes consisting of the 80S ribosome, the mRNA analog and tRNA resulted in tRNA-dependent crosslinking of the mRNA analogs to the 40S ribosomal proteins and the 18S rRNA. mRNA analogs with the photoreactive group at the fourth uridine (the first base of the stop codon) crosslinked mainly to protein S15 (and much less to S2). For the 3'-modified mRNA analog, the major crosslinking target was protein S2, while protein S15 was much less crosslinked. Crosslinking of eukaryotic (e) RF1 was entirely dependent on the presence of a stop signal in the mRNA analog. eRF3 in the presence of eRF1 did not crosslink, but decreased the yield of eRF1 crosslinking. We conclude that (i) proteins S15 and S2 of the 40S ribosomal subunit are located near the A site-bound codon; (ii) eRF1 can induce spatial rearrangement of the 80S ribosome leading to movement of protein L4 of the 60S ribosomal subunit closer to the codon located at the A site; (iii) within the 80S ribosome, eRF3 in the presence of eRF1 does not contact the stop codon at the A site and is probably located mostly (if not entirely) on the 60S subunit.     

Protein S3 in the human 80S ribosome adjoins mRNA from 3'-side of the A-site codon

The protein environment of mRNA 3' of the A-site codon (the decoding site) in the human 80S ribosome was studied using a set of oligoribonucleotide derivatives bearing a UUU triplet at the 5'-end and a perfluoroarylazide group at one of the nucleotide residues at the 3'-end of this triplet. Analogues of mRNA were phased into the ribosome using binding at the tRNAPhe P-site, which recognizes the UUU codon. Mild UV irradiation of ribosome complexes with tRNAPhe and mRNA analogues resulted in the predominant crosslinking of the analogues with the 40S subunit components, mainly with proteins and, to a lesser extent, with rRNA. Among the 40S subunit ribosomal proteins, the S3 protein was the main target for modification in all cases. In addition, minor crosslinking with the S2 protein was observed. The crosslinking with the S3 and S2 proteins occurred both in triple complexes and in the absence of tRNA. Within triple complexes, crosslinking with S15 protein was also found, its efficiency considerably falling when the modified nucleotide was moved from positions +5 to +12 relative to the first codon nucleotide in the P-site. In some cases, crosslinking with the S30 protein was observed, it was most efficient for the derivative containing a photoreactive group at the +7 adenosine residue. The results indicate that the S3 protein in the human ribosome plays a key role in the formation of the mRNA binding site 3' of the codon in the decoding site.     

A translation-like cycle is a quality control checkpoint for maturing 40S ribosome subunits

Assembly factors (AFs) prevent premature translation initiation on small (40S) ribosomal subunit assembly intermediates by blocking ligand binding. However, it is unclear how AFs are displaced from maturing 40S ribosomes, if or how maturing subunits are assessed for fidelity, and what prevents premature translation initiation once AFs dissociate. Here we show that maturation involves a translation-like cycle whereby the translation factor eIF5B, a GTPase, promotes joining of large (60S) subunits with pre-40S subunits to give 80S-like complexes, which are subsequently disassembled by the termination factor Rli1, an ATPase. The AFs Tsr1 and Rio2 block the mRNA channel and initiator tRNA binding site, and therefore 80S-like ribosomes lack mRNA or initiator tRNA. After Tsr1 and Rio2 dissociate from 80S-like complexes Rli1-directed displacement of 60S subunits allows for translation initiation. This cycle thus provides a functional test of 60S subunit binding and the GTPase site before ribosomes enter the translating pool.     

Number of tRNA binding sites on 80 S ribosomes and their subunits

The ability of rabbit liver ribosomes and their subunits to form complexes with different forms of tRNAPhe (aminoacyl-, peptidyl- and deacylated) was studied using the nitrocellulose membrane filtration technique. The 80 S ribosomes were shown to have two binding sites for aminoacyl- or peptidyl-tRNA and three binding sites for deacylated tRNA. The number of tRNA binding sites on 80 S ribosomes or 40 S subunits is constant at different Mg2+ concentrations (5-20 mM). Double reciprocal or Scatchard plot analysis indicates that the binding of Ac-Phe-tRNAPhe to the ribosomal sites is a cooperative process. The third site on the 80 S ribosome is formed by its 60 S subunit, which was shown to have one codon-independent binding site specific for deacylated tRNA.     

The eukaryotic translation initiation factors eIF1 and eIF1A induce an open conformation of the 40S ribosome

Initiation of translation is the process by which initiator tRNA and the start codon of mRNA are positioned in the ribosomal P site. In eukaryotes, one of the first steps involves the binding of two small factors, eIF1 and eIF1A, to the small (40S) ribosomal subunit. This facilitates tRNA binding, allows scanning of mRNA, and maintains fidelity of start codon recognition. Using cryo-EM, we have obtained 3D reconstructions of 40S bound to both eIF1 and eIF1A, and with each factor alone. These structures reveal that together, eIF1 and eIF1A stabilize a conformational change that opens the mRNA binding channel. Biochemical data reveal that both factors accelerate the rate of ternary complex (eIF2*GTP*Met-tRNA(i)(Met)) binding to 40S but only eIF1A stabilizes this interaction. Our results suggest that eIF1 and eIF1A promote an open, scanning-competent preinitiation complex that closes upon start codon recognition and eIF1 release to stabilize ternary complex binding and clamp down on mRNA.     

Factor-independent interaction of met-tRNA i and ApUpG with 40 S subunits of rat liver ribosomes

The small (40 S) subunit of rat liver ribosomes is capable of binding the initiator tRNA (Met-tRNA_i), in the absence of added protein factors, in marked preference to other aminoacyl-tRNAs. This binding requires magnesium ions, is codon (ApUpG)-specific, is not obtained with 60 S subunits, and is significantly higher than that observed with 80 S ribosomes. The 40 S subunit also exhibits a preference for ApUpG over several other trinucleotides. The reaction is inhibited by 60 S particles; it is also inhibited by compounds that effect chain initiation such as edeine and aurintricarboxylic acid, but not by cycloheximide, tetracycline or KF. All other aminoacyl-tRNAs, including Met-tRNA_m, bind more efficiently to 80 S ribosomes at low MgCl₂ concentrations with EF1 or in high Mg⁺⁺-containing solutions.     

Protein environment of the sense codon of the template in the A site of the human ribosome as inferred from crosslinking to oligoribonucleotide derivatives

The protein environment of each nucleotide of the template codon located in the A site of the human ribosome was studied with UUCUCAA and UUUGUU derivatives containing a Phe codon (UUC and UUU, respectively) and a perfluoroarylazido group at U4, U5, or U6. The analogs were positioned in the ribosome with the use of tRNA(Phe), which is cognate to the UUC or UUU codon and directs it to the P site, bringing a modified codon in the A site with a modified nucleotide occupying position +4, +5, or +6 relative to the first nucleotide of the P-site codon. On irradiation of ribosome complexes with tRNA(Phe) and mRNA analogs with mild UV light, the analogs crosslinked predominantly to the 40S subunit, modifying the proteins to a greater extent than the rRNA. The 18S rRNA nucleotides crosslinking to the analogs were identified previously. Of the small-subunit proteins, S3 and S15 were the major targets of modification in all cases. The former was modified both in ternary complexes and in the absence of tRNA, and the latter, only in ternary complexes. The extent of crosslinking of mRNA analogs to S15 decreased when the modified nucleotide was shifted from position +4 to position +6. The results were collated with the data on ribosomal proteins located at the decoding site of the 70S ribosome, and conclusion was made that the protein environment of the A-site codon strikingly differs between bacterial and eukaryotic ribosomes.     

Stepwise dissociation of yeast 60S ribosomal subunits by LiCl and identification of L25 as a primary 26S rRNA binding protein

Treatment of yeast 60S ribosomal subunits with 0.5 M LiCl was found to remove all but six of the ribosomal proteins. The proteins remaining associated with the (26S + 5.8S) rRNA complex were identified as L4, L8, L10, L12, L16 and L25. These core proteins were split off sequentially in the order (L16 + L12), L10, (L4 + L8), L25 by further increasing the LiCl concentration. At 1.0 M LiCl only ribosomal protein L25 remains bound to the rRNA. Upon lowering the LiCl concentration the core proteins reassociate with the rRNA in the reverse order of their removal. The susceptibility of the ribosomal proteins to removal by LiCl corresponds quite well with their order of assembly into the 60S subunit in vivo as determined earlier [Kruiswijk et al. (1978) Biochim. Biophys. Acta 517, 378-389]. Binding studies in vitro using partially purified L25 showed that this protein binds specifically to 26S rRNA. Therefore our experiments for the first time directly identify a eukaryotic ribosomal protein capable of binding to high-molecular-mass rRNA. Binding studies in vitro using a blot technique demonstrated that core proteins L8 and L16 as well as protein L21, though not present in any of the core particles, are also capable of binding to 26S rRNA to approximately the same extent as L25. About nine additional 60S proteins appeared to interact with the 26S rRNA, though to a lesser extent.     

GTP-independent tRNA Delivery to the Ribosomal P-site by a Novel Eukaryotic Translation Factor

During translation, aminoacyl-tRNAs are delivered to the ribosome by specialized GTPases called translation factors. Here, we report the tRNA binding to the P-site of 40 S ribosomes by a novel GTP-independent factor eIF2D isolated from mammalian cells. The binding of tRNA_i^Met occurs after the AUG codon finds its position in the P-site of 40 S ribosomes, the situation that takes place during initiation complex formation on the hepatitis C virus internal ribosome entry site or on some other specific RNAs (leaderless mRNA and A-rich mRNAs with relaxed scanning dependence). Its activity in tRNA binding with 40 S subunits does not require the presence of the aminoacyl moiety. Moreover, the factor possesses the unique ability to deliver non-Met (elongator) tRNAs into the P-site of the 40 S subunit. The corresponding gene is found in all eukaryotes and includes an SUI1 domain present also in translation initiation factor eIF1. The versatility of translation initiation strategies in eukaryotes is discussed.     

Studies on native ribosomal subunits from rat liver. Evidence for activities associated with native 40S subunits that affect the interaction with acetylphenylalanyl-tRNA, methionyl-tRNAf, and 60S subunits.

The binding of the initiator tRNA Met-tRNAf, and of acetylphenylalanyl-tRNA, has been examined with rat liver 40S subunits derived from 80S ribosomes by dissociation with native 40S subunits sedimented from the postmicrosomal fraction and with native 40S subunits extracted with high salt-containing solutions. Binding of Met-tRNAf and acetylphenylalanyl-tRNA to derived and to salt-extracted native 40S subunits is observed in the presence of the appropriate polynucleotide template and a highly purified binding factor obtain from the soluble fraction of rat liver homogenates (R.L. IF-1). Native 40S subunits bind acetylphenylalanyl-tRNA in a reaction that requires poly(U) but not exogenous binding factor; however, Met-tRNAf is not bound to native subunits, even when supplemented with the soluble binding factor, or under conditions where factor-independent, high Mg2+-stimulated binding is observed with the derived and the salt-washed native 40S subunits. The extract obtained from native 40S subunits promotes the binding of acetylphenylalanyl-tRNA but not Met-tRNAf to derived and to salt-extracted native subunits. The addition of native 40S extract to incubations containing R.L. IF-1, Met-tRNAf, and derived 40S subunits, inhibits the formation of 40S-Met-tRNAf complex. These data suggest that the binding activity that is specific for 40S subunits and initiator tRNA, and an activity that inhibits the interaction with Met-tRNAf specifically, are both associated with native 40S subunits, and can be extracted from them by treatment with high salt-containing solutions. Derived 40S subunits react quantitatively with 60S particles to form 80S ribosomes which do not bind acetylphenylalanyl-tRNA with binding factor R.L. IF-1. Native 40S subunits react only partly with 60S subunits; about half of the native 40S subunit population forms 80S ribosomes which do not subsequently bind acetylphenylalanyl-tRNA; the remaining native 40S subunits which do not react with 60S particles bind acetylphenylalanyl-tRNA but to a lesser extent. When preformed native 40S-acetylphenylalanyl-tRNA complex is incubated with 60S subunits, about half of the subunits form an 80S-acetylphenylalanyl-tRNA complex, while the rest remains as 40S-acetylphenylalanyl-tRNA. The addition of native 40S subunit salt extract to incubations containing preformed 80S ribosomes dissociates the particles to subunits. These data suggest that in addition to the initiator tRNA binding activity and the activity that inhibits Met-tRNAf interaction, part of the native 40S subunit population also contains an activity that dissociates 80S ribosomes.