Specific functional interactions of nucleotides at key -3 and +4 positions flanking the initiation codon with components of the mammalian 48S translation initiation complex

doi:10.1101/gad.1397906

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GENES & DEVELOPMENT 20:624-636, 2006
©2006 by Cold Spring Harbor Laboratory Press; ISSN 0890-9369/ $5.00

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RESEARCH PAPER

Specific functional interactions of nucleotides at key ^-3 and ⁺4 positions flanking the initiation codon with components of the mammalian 48S translation initiation complex

Andrey V. Pisarev¹, Victoria G. Kolupaeva¹, Vera P. Pisareva¹, William C. Merrick², Christopher U.T. Hellen¹ and Tatyana V. Pestova¹^,3

¹ Department of Microbiology and Immunology, State University of New York Downstate Medical Center, Brooklyn, New York 11203 USA; ² Department of Biochemistry, Case Western Reserve University School of Medicine, Cleveland, Ohio 44106, USA

Abstract

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Abstract
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Discussion
Materials and methods
Acknowledgments
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Eukaryotic initiation factor (eIF) 1 maintains the fidelityof initiation codon selection and enables mammalian 43S preinitiationcomplexes to discriminate against AUG codons with a contextthat deviates from the optimum sequence GCC(A/G)CCAUGG, in whichthe purines at ^-3 and ⁺4 positions are most important. We hypothesizethat eIF1 acts by antagonizing conformational changes that occurin ribosomal complexes upon codon-anticodon base-pairing during48S initiation complex formation, and that the role of ^-3 and⁺4 context nucleotides is to stabilize these changes by interactingwith components of this complex. Here we report that U and Gat ⁺4 both UV-cross-linked to ribosomal protein (rp) S15 in48S complexes. However, whereas U cross-linked strongly to C₁₆₉₆and less well to AA_1818-1819 in helix 44 of 18S rRNA, G cross-linkedexclusively to AA_1818-1819. U at ^-3 cross-linked to rpS5 andeIF2 ${alpha}$ , whereas G cross-linked only to eIF2 ${alpha}$ . Results of UV cross-linkingexperiments and of assays of 48S complex formation done using ${alpha}$ -subunit-deficient eIF2 indicate that eIF2 ${alpha}$ 's interaction withthe ^-3 purine is responsible for recognition of the ^-3 contextposition by 43S complexes and suggest that the ⁺4 purine/AA_1818-1819interaction might be responsible for recognizing the ⁺4 position.

[Keywords: Ribosome; translation; initiation; nucleotide context; eIF1; eIF2 ${alpha}$ ]

Received December 2, 2005; revised version accepted January 13, 2006.

Eukaryotic ribosomes locate the initiation codon on most mRNAsby a scanning mechanism. A 43S complex comprising a ribosomal40S subunit, eukaryotic initiation factors (eIFs) 1, 1A, and3, and an eIF2-GTP/Met-tRNA^Met_i complex binds to the 5'-cap-proximalregion of mRNA with the help of eIF4A, eIF4B, and eIF4F andscans downstream to the initiation codon to form a 48S complex.Initiation codon recognition and base-pairing with the Met-tRNA^Met_ianticodon triggers eIF5-mediated hydrolysis of eIF2-bound GTPand, most importantly, subsequent release of phosphate (Algireet al. 2005

). The prevailing model is that this leads to releaseof eIF2-GDP from the 40S subunit, retaining Met-tRNA^Met_i inthe ribosomal P site, after which eIF5B mediates displacementof other factors and joining of the 60S ribosomal subunit toform an 80S ribosome (Pestova et al. 2000

; Unbehaun et al. 2004

The initiation codon is recognized by base-pairing with theanticodon of Met-tRNA^Met_i (Cigan et al. 1988) and is usuallythe first AUG triplet from the mRNA's 5' end. Scanning 40S subunitscan bypass the first AUG triplet if it is <10 nucleotides(nt) from the 5' end of mRNA or if its context deviates fromthe optimum sequence GCC(A/G)CCAUGG, particularly at ^-3 and⁺4 positions (in bold) (Kozak 1986, 1991). These two contextnucleotides are conserved features of mammalian mRNAs and togethercan enhance translation 20-fold; in yeast, the nucleotide contextis less important for initiation codon recognition, and itsonly common feature is a purine at the ^-3 position (Kozak 1986;Cavener and Ray 1991). eIF1 enhances the processivity of scanningand plays the key role in ensuring the fidelity of initiationcodon selection by enabling 43S complexes to discriminate against48S complex formation on non-AUG triplets, on AUG triplets locatednear the 5' end of mRNA, and on AUG triplets with suboptimalcontext (Yoon and Donahue 1992; Pestova et al. 1998; Pestovaand Kolupaeva 2002). It also ensures the fidelity of initiationcodon selection at the later stage of ribosomal subunit joiningby inhibiting premature GTP hydrolysis by eIF2 and by couplinginitiation codon recognition with activation of eIF2's GTPaseactivity (Unbehaun et al. 2004; Valasek et al. 2004; Maag etal. 2005).

eIF1 binds to the interface surface of the 40S subunit betweenthe platform and initiator tRNA, facing the codon-anticodonbase pairs but not contacting them directly (Lomakin et al.2003). This suggests that it promotes scanning and performsits monitoring function indirectly, by influencing the conformationof the platform and the positions of Met-tRNA^Met_i and mRNA inribosomal complexes. To explain eIF1's mechanism of action,we propose that binding of eIF1-43S complexes induces a scanning-competentconformation that is favorable for rejection of codon-anticodonmismatches and does not permit activation of hydrolysis of eIF2-boundGTP by eIF5. However, on recognizing the initiation codon, a43S complex would have to undergo conformational changes uponbase-pairing to form a 48S complex, which would be antagonizedby eIF1. In our model, the conformation of an arrested 48S complexwould be stabilized by codon-anticodon base-pairing and by elementswithin mRNA such as 5'-flanking sequences and context nucleotides.If a 48S complex assembled without eIF1 is insufficiently stable,due to the presence of a noncognate initiation codon, poor contextor to the absence of 5'-flanking sequences, it dissociates ondelayed addition of eIF1 (Pestova and Kolupaeva 2002). An implicationof this model is that the role of context nucleotides (particularlyof ^-3 and ⁺4 positions) is to stabilize an arrested ribosomalcomplex by interacting specifically with its constituents. Hypothesesthat context nucleotides interact with 18S rRNA (e.g., Kozak1986; Cavener and Ray 1991) in a functionally analogous mannerto the Shine-Dalgarno interaction of 16S rRNA and prokaryoticmRNAs have not been substantiated.

In this study we used mRNAs with either 4-thiouridine ("thioU")or 6-thioguanosine ("thioG") at ^-3 and ⁺4 positions (hereafter,[^-3] and [⁺4]) for "zero-length" UV cross-linking of ribosomalproteins, 18S rRNA, and initiation factors in 48S complexesto identify nucleotide-specific interactions of purines andpyrimidines at [^-3] and [⁺4] that could account for the nucleotidecontext rule. U and G at [⁺4] both cross-linked to ribosomalprotein (rp) S15, but whereas U[⁺4] specifically cross-linkedmostly to C₁₆₉₆ and to some extent to AA_1818-1819 in helix 44of 18S rRNA, G[⁺4] cross-linked exclusively to AA_1818-1819.The base specificity of the interaction of the [⁺4] purine withAA_1818-1819 is therefore likely responsible for recognitionof this context nucleotide by 43S complexes, so that in additionto monitoring the fidelity of elongator tRNA selection (Ogleet al. 2001), AA_1818-1819 might also play a role in initiationcodon selection. U[^-3] specifically and equally efficientlycross-linked to rpS5 and to eIF2 ${alpha}$ , whereas G[^-3] cross-linkedexclusively to eIF2 ${alpha}$ . The functional involvement of eIF2 ${alpha}$ in recognizingthe [^-3] nucleotide was confirmed by assaying 48S complex formationin the presence of ${alpha}$ -subunit-deficient eIF2. In the absence ofeIF1, the effect of the lack of eIF2 ${alpha}$ on the efficiency and specificityof 48S complex formation on AUG triplets with different nucleotidecontexts was minor. However, in the presence of eIF1, 43S complexesassembled without eIF2 ${alpha}$ could no longer discriminate the natureof the ^-3 nucleotide, and 48S complex formation was much lessefficient, irrespective of the nucleotide at [^-3]. This suggeststhat interaction of the [^-3] nucleotide with eIF2 ${alpha}$ is generallyimportant for 48S complex formation in the presence of eIF1,but that eIF2 ${alpha}$ interacts more strongly with a purine than witha pyrimidine residue, increasing the resistance of 48S complexesto dissociation by eIF1, and that this accounts for the ^-3 nucleotidecontext rule. The fact that without sucrose density gradientcentrifugation 85%-90% of eIF2 remained associated with 48Scomplexes formed on AUG triplets with G[^-3] after eIF5-inducedhydrolysis of eIF2-bound GTP could account for the resistanceof 48S complexes to eIF1's dissociating influence after GTPhydrolysis and before the actual ribosomal subunit joining.

Results

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Abstract
Results
Discussion
Materials and methods
Acknowledgments
References

48S complex formation on (CAA)nAUG(CAA)m mRNAs containing thioU and thioG

We hypothesized that the role of [^-3] and [⁺4] context nucleotidescould be to stabilize conformational changes in 48S complexesthat occur upon base-pairing, by interacting with elements ofthese complexes. We investigated their interactions with componentsof the 48S complex by UV cross-linking using mRNAs that hada single uridine or guanosine (in addition to the AUG codon)at these positions (Fig. 1A). In two mRNAs the context of AUGtriplets was good (purines at [^-3] and [⁺4]) and in two it wassuboptimal (a pyrimidine at [^-3] or [⁺4]). Flanking AUG codonswith multiple CAA triplets to avoid additional U or G nucleotidesalso minimized secondary structure and increased initiationefficiency. mRNAs were transcribed in vitro in the presenceof thioU or thioG (Fig. 1B), which can be specifically cross-linkedto proteins and nucleic acids by low-energy (360-nm) irradiation,yielding "zero-length" cross-links that represent direct contactswith 48S complex constituents. Differences in the specificity/intensityof cross-links between mRNAs containing either thioU or thioGcould be indicative of the nucleotide specificity of interactions.ThioG is incorporated less efficiently than thioU into transcriptsand may exist in a thiol-thione equilibrium that could leadto its misincorporation (Sergiev et al. 1997; Favre et al. 1998).Toe-printing analysis done in the absence of eIF1 (to avoidpotential differences in efficiency of 48S complex formationdue to context differences of initiation codons) showed that48S complex assembled equally and efficiently on mRNAs containingthioG or thioU, which were therefore functional (Fig. 1C).

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Figure 1. 48S complex formation on thioU- and thioG-containing mRNAs. (A) Sequences of (CAA)_n-AUG-(CAA)_m mRNA derivatives containing U or G at ^-3 and ⁺4 positions (italicized) relative to the A of the initiation codon (bold). (B) Structural formulae of thioU and thioG. (C) Toe-print analysis of 48S complexes assembled as described in Materials and Methods on mRNAs as indicated. Toe-prints due to 48S complexes are shown on the left. Full-length cDNAs are labeled. Lanes C, T, A, G show cDNA sequence corresponding to "⁺4G" mRNA derived using the same primer as for toe-printing.

Contacts of the nucleotide at position [⁺4] of mRNA with components of the 48S complex

mRNA transcripts used for UV cross-linking contained thioU orthioG and were labeled with ³²P-CTP. 48S complexes assembledfrom 40S subunits, eIF2, eIF3, eIF4A, eIF4B, eIF4F, eIF1, eIF1A,and Met-tRNA^Met_i were purified from unincorporated componentsby sucrose density gradient centrifugation and cross-linkedby irradiation at 360 nm. U[⁺2] and G[⁺3] of the initiationcodon base-pair with the Met-tRNA^Met_i anticodon and thus cannotcross-link to other components of 48S complexes, so radiolabelingof factors, ribosomal proteins, and 18S rRNA can be attributedexclusively to interactions with [^-3] and [⁺4] nucleotides.In control experiments, thioU[⁺2] or thioG[⁺3] did not cross-linkto components of 48S complexes assembled on mRNA with U andG only in the initiation codon (V.G. Kolupaeva, A.V. Pisarev,C.U.T. Hellen, and T.V. Pestova, in prep.).

Because eIF1 is a functional analog of prokaryotic IF3 (whichcauses rearrangement of mRNA on 30S subunits) (La Teana et al.1995; Shapkina et al. 2000), mRNA cross-linking was assayedin 48S complexes assembled with and without eIF1. RNase-treatedsamples were analyzed by SDS-PAGE and two-dimensional (2D) gelelectrophoresis to identify cross-linked proteins.

A single protein of the same mobility was cross-linked in 48Scomplexes assembled with or without eIF1 on mRNAs with thioUor thioG at [⁺4] (Fig. 2A,B, lanes 1,3). The specificity ofUV cross-linking of thioU- and thioG-containing mRNAs did notdiffer, but consistent with other studies, thioU cross-linkedmore efficiently than thioG (Nikiforov and Connolly 1992; Fig. 2A,B,lanes 1,3), likely reflecting intrinsic differences incross-linking efficiencies of these thionucleotides. The lowmolecular weight of the cross-linked protein indicated thatit was a ribosomal protein. Covalently bound mRNA nucleotidescause cross-linked ribosomal proteins to shift "northwest" in2D gels. Taking this into consideration, cross-linking to [⁺4]was attributed to rpS15 (Fig. 2C,D). Its identity was confirmedby mass-spectrometry sequencing of EAPPMEKPEVVK and GVDLDQLLDMSYEQLMQLYSARpeptides. rpS15 is a homolog of prokaryotic rpS19, whose positionin the crystal structure of the Thermus thermophilus 30S subunitis shown in Figure 4 (see below).

To identify the approximate region of cross-linking of [^-3]and [⁺4] nucleotides to 18S rRNA, it was extracted after irradiationof 48S complexes, hybridized with DNA oligonucleotides complementaryto different regions, digested with RNase H, and separated byelectrophoresis. Attribution of individual ³²P-labeled UV-cross-linkedfragments of 18S rRNA took into account their reduced mobilitydue to covalently linked mRNA. The exact cross-linked nucleotidewas identified by primer extension.

As with cross-linking to ribosomal proteins, cross-linking of18S rRNA to the [⁺4] nucleotide was identical in 48S complexesassembled with or without eIF1, and thioG cross-linked lessefficiently than thioU (Fig. 3A,B). In contrast to cross-linkingof ribosomal proteins, cross-linking of thioU and thioG at [⁺4]to 18S rRNA differed significantly. Both nucleotides cross-linkedto nucleotides 1652-1863, but further analysis showed that thioG[⁺4]cross-linked exclusively to nucleotides 1815-1863 (Fig. 3A,B,lanes 3), whereas thioU[⁺4] cross-linked to this region weaklybut cross-linked strongly to nucleotides 1652-1796 (Fig. 3A,B,lanes 6). Cross-linking sites were then determined precisely:ThioU[⁺4] cross-linked mostly to C₁₆₉₆ and to some extent toAA_1818-1819, whereas thioG[⁺4] cross-linked only to AA_1818-1819(Fig. 3C-E). In control experiments (Fig. 3C-E, lanes 2), primerextension was done on 48S complexes assembled on mRNAs containingthioU or thioG at [^-3]. The positions of C₁₆₉₆ and AA_1818-1819in h44 of 18S rRNA are shown on the secondary structure of 18SrRNA (Fig. 3F,G) and are mapped onto the corresponding nucleotidesof 16S rRNA in the crystal structure of the T. thermophilus30S subunit (Fig. 4). In conclusion, in 48S complexes, U[⁺4]in mRNA specifically cross-linked to C₁₆₉₆ and to some extentto AA_1818-1819, whereas G[⁺4] cross-linked exclusively to AA_1818-1819.U and G both also cross-linked to rpS15.

Contacts of the nucleotide at position [^-3] of mRNA with components of the 48S complex

Unlike the [⁺4] nucleotide, thioU or thioG at [^-3] did not cross-linkto 18S rRNA, but thioU at [^-3] cross-linked specifically withequal efficiency to two proteins whereas thioG cross-linkedonly to the larger one (Fig. 2A,B, lanes 2,4). As for the [⁺4]nucleotide, cross-linking was identical in 48S complexes formedwith or without eIF1 and was less efficient with thioG thanthioU. The size of the smaller protein ( $~$ 21 kDa) indicated thatit was a ribosomal protein. Taking into consideration the "northwest"shift of cross-linked proteins in 2D gels, we attributed cross-linkingof U[^-3] to rpS5 (Fig. 2E,F). Its identity was confirmed bymass-spectrometry sequencing of QAVDVFPLR and TIAEC^*LADELINAAKpeptides. It is a homolog of prokaryotic rpS7, shown on thecrystal structure of the T. thermophilus 30S subunit (Fig. 4).The $~$ 38-kDa molecular weight of the larger protein indicatedthat it could be eIF2 ${alpha}$ or a subunit of eIF3. To identify it,we assembled 48S complexes using eIF2 with a truncated ${alpha}$ -subunit(" ${Delta}$ eIF2 ${alpha}$ ") from HeLa cells (Fig. 2G) and then exploited the observationthat eIF5-induced hydrolysis of eIF2-bound GTP in 48S complexesreleases eIF2 but not eIF3 (Unbehaun et al. 2004). The N-terminalsequence of ${Delta}$ eIF2 ${alpha}$ (PGLS, identical to that of intact eIF2 ${alpha}$ ) andits mobility in SDS-PAGE indicated that it was C-terminallytruncated by 1.5-2 kDa; such cleavage is mediated by caspases(Satoh et al. 1999). eIF2 containing ${Delta}$ eIF2 ${alpha}$ was $~$ 30% as activein 48S complex formation as intact eIF2 (data not shown). Thelower activity may be due to the substoichiometric amount of ${Delta}$ eIF2 ${alpha}$ in eIF2 compared with eIF2 with intact eIF2 ${alpha}$ (Fig. 2G).The $~$ 38-kDa protein cross-linked to thioU and thioG at [^-3] wasidentified as eIF2 ${alpha}$ by cross-linking 48S complexes assembledwith eIF2 containing ${Delta}$ eIF2 ${alpha}$ on mRNA with thioU[^-3] (which yieldeda cross-linked protein with altered mobility) and by cross-linking48S complexes after incubation with eIF5 (which led to specificloss of this band) (Fig. 2H, lanes 2,3). Cross-linking of eIF2 ${alpha}$ to [^-3] was specific: No cross-linking was observed to [^-4]and only very little to [^-2] (V.G. Kolupaeva, A.V. Pisarev,C.U.T. Hellen, and T.V. Pestova, in prep.). In conclusion, in48S complexes, thioU[^-3] in mRNA cross-links specifically torpS5 and eIF2 ${alpha}$ , whereas thioG[^-3] cross-links exclusively toeIF2 ${alpha}$ .

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Figure 2. Contacts of nucleotides at ^-3 and ⁺4 positions of mRNA with ribosomal proteins and factors in 48S complexes. (A,B) UV cross-linking of ³²P-labeled (CAA)_n-AUG-(CAA)_m mRNAs containing 4-thioU or 6-thioG at [^-3] and [⁺4] as indicated with components of 48S complexes assembled with (A) or without (B) eIF1, assayed by SDS-PAGE and autoradiography. The positions of molecular weight markers (MW) are shown on the left. (C-F) Analysis by 2D electrophoresis of ribosomal proteins UV-cross-linked to ³²P-labeled (CAA)_n-AUG-(CAA)_m mRNAs containing 4-thioU at [⁺4] (C,D) and at [^-3] (E,F). (C,E) Gels of 40S subunit proteins stained with Simply Blue Safe Stain. (D,F) Autoradiographs of gels from C and E. Positions corresponding to radioactive spots (D,F) on stained gels (C,E) are shown in red. The positions of some ribosomal proteins based on sequencing data or according to Madjar et al. (1979

) are indicated. (G) eIF2 with full-length (lanes 2,4) and truncated (lanes 1,3) eIF2 ${alpha}$ assayed by SDS-PAGE and Coomassie staining (lanes 1,2) or immunobloting (lanes 3,4). eIF2 subunits are indicated on the left. (H) UV cross-linking of ³²P-labeled (CAA)_n-AUG-(CAA)_m mRNA derivative containing 4-thioU at [^-3] with components of 48S complexes assembled using eIF2 with intact eIF2 ${alpha}$ (lane 1), eIF2 with truncated eIF2 ${alpha}$ (lane 2), and eIF2 with intact eIF2 ${alpha}$ and eIF5 (lane 3), assayed by SDS-PAGE and autoradiography. Positions of eIF2 ${alpha}$ and rpS5 are indicated on the left.

48S complex formation on CAA-GUS mRNAs with upstream AUGs in different nucleotide contexts in the presence of ${alpha}$ -subunit- and $beta$ -subunit-deficient mammalian eIF2

UV cross-linking data showed that G residues at [⁺4] and [^-3]in mRNA specifically bound AA_1818-1819 of 18S rRNA and eIF2 ${alpha}$ ,respectively. To prove eIF2 ${alpha}$ 's functional role in recognizinginitiation codon context, we compared 48S complex assembly usingcomplete eIF2, eIF2 lacking either eIF2 ${alpha}$ (eIF2 $beta$ ${gamma}$ ) or eIF2 $beta$ (eIF2 ${alpha}$ ${gamma}$ ),or eIF2 $beta$ ${gamma}$ with recombinant eIF2 ${alpha}$ on (CAA)n-AUGbad/bad-GUS, (CAA)n-AUGbad/good-GUS,and (CAA)n-AUGgood/bad-GUS mRNAs. These mRNAs have an unstructured5'-UTR lacking potential near-cognate initiation codons andcontain additional AUG triplets in different contexts upstreamof the GUS initiation codon (Fig. 5A; Pestova and Kolupaeva2002). The AUGbad/bad triplet contained [^-3] and [⁺4] pyrimidines,AUGbad/good had a [^-3] pyrimidine and a [⁺4] purine, and AUGgood/badhad a [^-3] purine and a [⁺4] pyrimidine. Small quantities ofeIF2 $beta$ ${gamma}$ and eIF2 ${alpha}$ ${gamma}$ (Fig. 5B, lanes 2,3) were obtained using standardeIF2 purification procedures (Anthony et al. 1990; Materialsand Methods). eIF1 is the principal factor that allows recognitionof initiation codon context by scanning 43S complexes, so 48Scomplexes were assembled with and without eIF1. 48S complexformation did not depend on when eIF1 was added, and in allexperiments described in this section identical data were obtainedif eIF1 was added simultaneously with other translation componentsor if 48S complexes were first assembled without eIF1 and werethen incubated with eIF1 for 15 min more. Consistent with ourprevious report (Pestova and Kolupaeva 2002), $~$ 90% of 43S complexesassembled with eIF1 and complete eIF2 scanned to the GUS initiationcodon of (CAA)n-AUGbad/bad-GUS mRNA, whereas in the absenceof eIF1, 48S complexes assembled mostly on the first AUGbad/badtriplet despite its poor context (Fig. 5C, lanes 2,3). 48S complexesformed with eIF2 ${alpha}$ ${gamma}$ just as with complete eIF2 (Fig. 5C, lanes4,5). No differences in 48S complex formation were detectedon (CAA)n-AUGbad/good-GUS and (CAA)n-AUGgood/bad-GUS mRNAs inthe presence of eIF2 ${alpha}$ ${gamma}$ or complete eIF2 (data not shown). Consistently,there was no difference in cross-linking of eIF2 ${alpha}$ to thioU orthioG at [^-3] in 48S complexes formed with complete eIF2 oreIF2 ${alpha}$ ${gamma}$ (Fig. 5D, lanes 1,2; data not shown).

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Figure 3. UV cross-linking of 4-thioU and 6-thioG at position ⁺4 of mRNA with 18S rRNA in 48S complexes. (A,B) RNase H digestion of 18S rRNA cross-linked to ³²P-labeled (CAA)_n-AUG-(CAA)_m mRNA derivatives containing 4-thioU or 6-thioG at [⁺4] in 48S complexes assembled with (A) or without (B) eIF1. 18S rRNA was digested in the presence of DNA primers complementary to nucleotides 1634-1651 and 1797-1814, as indicated, and analyzed by electrophoresis in denaturing 12% PAGE and autoradiography. 18S rRNA fragments to which 4-thioU or 6-thioG at [⁺4] of mRNA had cross-linked in 48S complexes are shown on the right. (C-E, lanes 1) Determination of exact sites of cross-linking of (CAA)_n-AUG-(CAA)_m mRNA derivatives containing 4-thioU or 6-thioG at [⁺4] to 18S rRNA in 48S complexes by primer extension analysis. (Lanes 2) In control reactions UV cross-linking was done with 48S complexes assembled on (CAA)_n-AUG-(CAA)_m mRNA derivatives containing 4-thioU or 6-thioG at [^-3]. The positions of RT stop sites are indicated on the right. Lanes C, T, A, and G depict 18S rRNA sequence generated using the same primer. (F) Secondary structure of rabbit 18S rRNA. Positions of cross-linked nucleotides and primers used for RNase H digestion are shown as red and blue bars, respectively. (G) Part of helix 44 of 18S rRNA showing cross-linked nucleotides (red circles).

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Figure 4. Ribosomal proteins and nucleotides in 18S rRNA cross-linked to 4-thioU or 6-thioG at [^-3] or [⁺4] of mRNA in 48S complexes mapped onto corresponding ribosomal proteins and regions of 16S rRNA (gray) in the crystal structure of a complex of mRNA (blue) and the T. thermophilus 30S subunit (Yusupova et al. 2001

). T. thermophilus rpS19 and rpS7 correspond to eukaryotic rpS15 and rpS5 and are red and magenta, respectively. Other ribosomal proteins are light blue. The mRNA nucleotides at [⁺4] and [^-3] are red and magenta, respectively. Positions of nucleotides in 16S rRNA that correspond to C₁₆₉₆ and AA_1818-1819 of 18S rRNA are shown as green and red spheres, respectively.

The role of eIF2 ${alpha}$ in 48S complex formation was investigated using(CAA)n-AUGbad/good-GUS and (CAA)n-AUGgood/bad-GUS mRNAs. Thiscombination of mRNAs containing upstream AUG triplets with onlyone purine at either [^-3] or [⁺4] was optimal for these studiesbecause 48S complex formation on the first AUG triplet of (CAA)n-AUGbad/bad-GUSmRNA in the presence of eIF1 is inefficient even with completeeIF2, and quantitating possible reductions in 48S complex formationwith eIF2 $beta$ ${gamma}$ reliably would be difficult. On the other hand, 48Scomplex formation on the first AUG of (CAA)n-AUGgood/good-GUSmRNA would be too efficient to permit detection of potentialleaky scanning. In addition, (CAA)n-AUGbad/good-GUS and (CAA)n-AUGgood/bad-GUSmRNAs allow the relative effects of purines at different positionson the efficiency of 48S complex formation to be compared. Withcomplete eIF2 and without eIF1, 48S complexes formed almostexclusively on the first AUG triplet on both mRNAs (Fig. 5F,G,lanes 5). In the presence of eIF1, complex formation on thefirst AUG triplet with a [^-3] purine was more efficient, constituting $~$ 80% of 48S complexes whereas 48S complex formation on the firstAUG with a [⁺4] purine constituted $~$ 50% of the total (Fig. 5F,G,lanes 6). The [^-3] purine was therefore relatively more importantfor these mRNAs than that at [⁺4]. In the absence of eIF1, total48S complex formation on the two AUGs for both mRNAs was only10% lower with eIF2 $beta$ ${gamma}$ than with complete eIF2. Initiation on bothmRNAs was slightly leakier: 10%-15% of 48S complexes formedon the GUS AUG with eIF2 $beta$ ${gamma}$ , whereas only $~$ 4% of 48S complexes formedthere with complete eIF2 (Fig. 5F,G, lanes 1,5). Although ithad only a minor effect in the absence of eIF1, the lack ofeIF2 ${alpha}$ strongly affected 48S complex formation in eIF1's presence.Total 48S complex formation with eIF2 $beta$ ${gamma}$ and eIF1 on the two AUGtriplets of both mRNAs was reduced threefold (Fig. 5F,G, cf.lanes 2,6). The relative reduction in 48S complex formationon the first AUG triplet was higher with (CAA)n-AUGgood/bad-GUSmRNA, in which case the ratio between 48S complex formationon the first and second AUG triplets fell to 1:1 from 4:1 inthe presence of complete eIF2 (Fig. 5G, lanes 2,6) and becamesimilar to the ratio of 48S complex formation on the first (withan unfavorable [^-3] pyrimidine) and second AUGs of (CAA)n-AUGbad/good-GUSmRNA (Fig. 5F, lanes 2,6). This result suggests that in theabsence of eIF2 ${alpha}$ , 43S complexes cannot sense the nature of the[^-3] nucleotide. The similar relative efficiencies of 48S complexformation on the two AUG triplets on both mRNAs despite thefirst AUG triplet of (CAA)n-AUGbad/good-GUS mRNA having a favorable[⁺4] purine suggest that the "⁺4 nucleotide rule" might be secondaryto the "^-3 nucleotide rule" and may not function efficientlyin the absence of the eIF2 ${alpha}$ /[^-3] nucleotide interaction. Thefact that 48S complex formation with eIF2 ${alpha}$ -deficient eIF2 wasstrongly reduced on both AUGbad/good and AUGgood/bad suggeststhat interaction of eIF2 ${alpha}$ with the [^-3] nucleotide is, irrespectiveof its nature, generally important for resistance of 48S complexesto dissociation by eIF1. Addition of recombinant eIF2 ${alpha}$ to reactionmixtures containing eIF2 $beta$ ${gamma}$ restored the efficiency of 48S complexformation on both AUG codons to the level observed with completeeIF2 (Fig. 5F,G, lanes 2,4,6). Consistently, recombinant eIF2 ${alpha}$ added to reaction mixtures with eIF2 $beta$ ${gamma}$ was cross-linked to thioUor thioG at [^-3] in 48S complexes (Fig. 5D [lanes 3,4], E).43S complexes became slightly less leaky and fewer 48S complexesassembled on the GUS AUG codon with eIF2 $beta$ ${gamma}$ and recombinant eIF2 ${alpha}$ than with native complete eIF2 (Fig. 5F,G, lanes 4,6). The eIF2 ${alpha}$ N-terminal domain may interact with the [^-3] nucleotide, inwhich case the N-terminal tag may influence this interaction,but we were reluctant to tag the C terminus of eIF2 ${alpha}$ becauseits C-terminal domain interacts with eIF2 ${gamma}$ . In conclusion, thesedata suggest that interaction of eIF2 ${alpha}$ with the [^-3] nucleotideis generally important for 48S complex formation in the presenceof eIF1, and that eIF2 ${alpha}$ likely interacts more strongly with apurine at [^-3], protecting 48S complexes more from dissociationby eIF1.

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Figure 5. Activities of ${alpha}$ -subunit- and $beta$ -subunit-deficient eIF2 in 48S complex formation. (A) Sequence of the 5'-UTR of (CAA)n-AUGbad/bad-GUS, (CAA)n-AUGgood/bad-GUS, and (CAA)n-AUG-bad/good-GUS mRNAs with initiation codons in bold. Context residues ^-3 to ⁺4 are underlined. (B) Coomassie-stained SDS-PAGE with resolved complete, ${alpha}$ -subunit- and $beta$ -subunit-deficient eIF2, and recombinant eIF2 ${alpha}$ . The positions of eIF2 subunits are indicated on the right.(C,F,G) Toe-print analysis of 48S complexes assembled on mRNAs (shown in A) from 40S subunits, Met-tRNA^Met_i, complete, ${alpha}$ -subunit- and $beta$ -subunit-deficient eIF2, and other eIFs as indicated. Full-length cDNAs and toe-prints due to 48S complexes are shown on the side. (D,E) UV cross-linking of ³²P-labeled (CAA)_n-AUG-(CAA)_m mRNA derivatives containing 4-thioU or 6-thioG at [^-3] in 48S complexes assembled using forms of eIF2 as indicated, assayed by SDS-PAGE and autoradiography. eIF2 ${alpha}$ and rpS5 are indicated on the right.

Interaction of eIF2 ${alpha}$ with the [^-3] nucleotide of mRNA in 48S complexes after eIF5-induced hydrolysis of eIF2-bound GTP

Our data suggest that eIF2 ${alpha}$ 's interaction with the [^-3] nucleotidestabilizes 48S complexes against dissociation by eIF1. However,it is generally accepted that eIF5-induced hydrolysis of eIF2-boundGTP leads eIF2 to dissociate from 48S complexes. If eIF1 candissociate aberrant initiation complexes after GTP hydrolysis,then one would expect that if ribosomal subunit joining doesnot occur immediately after this event, then even 48S complexesassembled on AUG triplets with a [^-3] purine would be dissociatedat this stage. However, 48S complexes formed with eIF1 on thegood context AUG codon of the GUS ORF of (CAA)n-AUGbad/bad-GUSmRNA remained intact after 15 min incubation with eIF5 (Fig. 6A,lanes 1,2). This result was not due to a hypothetical inabilityof eIF1 to discriminate the context of the initiation codonafter hydrolysis of eIF2-bound GTP, because $~$ 95% of 48S complexesformed on the first bad context AUG of the same mRNA withouteIF1 could still be dissociated by eIF1 after incubation witheIF5 (Fig. 6B, lanes 2,4). The upstream AUG triplet had poorcontext at [^-3] and [⁺4] whereas the downstream AUG triplethad good context at both positions. The [⁺4] purine could conceivablybe sufficient to stabilize 48S complexes after hydrolysis ofeIF2-bound GTP. However, retaining a purine only at [^-3] ofthe first AUG codon in (CAA)_n-AUGgood/bad-GUS mRNA yielded 48Scomplexes that were as resistant to eIF1-mediated dissociationafter GTP hydrolysis as eIF5-untreated 48S complexes (data notshown). To account for this result, we tested if interactionof the [^-3] purine switches from eIF2 ${alpha}$ to another component ofthe 48S complex after GTP hydrolysis, which could render 48Scomplexes resistant to eIF1-mediated dissociation in the absenceof eIF2. Just as for eIF5-untreated 48S complexes, no specificinteraction was detected between thioG[^-3] and 18S rRNA or anyribosomal protein after eIF5-induced hydrolysis of eIF2-boundGTP (Fig. 6D; data not shown).

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Figure 6. Influence of eIF5-induced hydrolysis of eIF2-bound GTP on 48S complex formation on AUG triplets in good and bad context (A,B) and on UV cross-linking of eIF2 ${alpha}$ to the ^-3 nucleotide of mRNA in 48S complexes (C,D). (A,B) Toe-print analysis of 48S complexes assembled on (CAA)n-AUGbad/bad-GUS mRNA from 40S subunits, Met-tRNA^Met_i, and eIFs as indicated. Toe-prints due to 48S complexes are shown on the left. (C,D) UV cross-linking of ³²P-labeled (CAA)_n-AUG-(CAA)_m mRNA derivatives containing 4-thioU or 6-thioG at [^-3] with components of 48S complexes before and after incubation with eIF5, eIF5B, and 60S subunits, as indicated. In lanes 2 48S complexes incubated with eIF5 were subjected to sucrose density gradient centrifugation before UV cross-linking. Cross-linked proteins were assayed by SDS-PAGE and autoradiography. eIF2 ${alpha}$ and rpS5 are indicated on the right.

Whereas the affinity to aminoacylated tRNA of elongation factorEF-Tu/GTP and EF-Tu/GDP-bound differs by a factor of 10⁴, theaffinity of yeast eIF2-GDP to Met-tRNA^Met_i is only $~$ 20-fold lowerthan of eIF2-GTP: This small difference might lead to incompletedissociation of eIF2 from 40S subunits upon GTP hydrolysis (Kappand Lorsch 2004

). Although eIF2 dissociated entirely from 40Ssubunits in our experiments (Fig. 2H, lane 3; Unbehaun et al.2004

), they all included sucrose density gradient centrifugationof 48S complexes after eIF5-induced hydrolysis of GTP priorto analysis of eIF2's association with 40S subunits. To determinewhether the stringency of sucrose density gradient centrifugationdissociated eIF2 from 40S subunits in these experiments, weassayed its influence on cross-linking of thioU and thioG at[^-3] in mRNA in eIF5-treated 48S complexes. As expected, nocross-linking to eIF2 ${alpha}$ was observed with either mRNA if eIF5-treated48S complexes were subjected to sucrose density gradient centrifugationbefore irradiation (Fig. 6C,D, lanes 1,2). However, if thisstep was omitted, after GTP hydrolysis 30%-35% and 85%-90% ofeIF2 still cross-linked to thioU and to thioG at [^-3], respectively(Fig. 6C,D, lane 3). This indicates that hydrolysis of eIF2-boundGTP does not cause complete dissociation of eIF2 from 48S complexes.Moreover, the extent of eIF2 release depends on the nature ofthe [^-3] nucleotide and is much lower when it is a purine. Additionof eIF5B to a reaction mixture with eIF5 almost completely abrogatedcross-linking of eIF2 ${alpha}$ to thioU[^-3] and reduced cross-linkingto thioG[^-3] by 70% (Fig. 6D, lane 4; data not shown). Theseresults suggest that eIF5B promotes dissociation of eIF2 fromthe 40S subunit after hydrolysis of eIF2-bound GTP, which isnevertheless not complete if the mRNA has a [^-3] purine. Theabsence of UV cross-linking of eIF2 ${alpha}$ to either thioU or thioGat [^-3] after treatment of 48S complexes with eIF5, eIF5B, and60S subunits (Fig. 6D, lane 5; data not shown) indicated completeconversion of 48S complexes into 80S ribosomes and confirmedthat incubation with eIF5 alone or together with eIF5B in identicalconditions (Fig. 6D, lanes 3,4) led to complete hydrolysis ofeIF2-bound GTP. In case some eIF1 was lost from 48S complexesduring their initial purification by sucrose density gradients,we compared the effect of adding eIF5 alone or together witheIF1-48S complexes on UV cross-linking of eIF2 ${alpha}$ to thioG[^-3]:No difference was detected, which means that eIF2 release wasnot affected (data not shown).

eIF5-induced hydrolysis of eIF2-bound GTP, therefore, does notcompletely dissociate eIF2 from 48S complexes, and the factthat the nature of the [^-3] nucleotide influences eIF2 releasesuggests that mRNA stabilizes binding of eIF2-48S complexesafter GTP hydrolysis through interaction of eIF2 ${alpha}$ with the [^-3]nucleotide. The fact that only a small fraction of eIF2 wasreleased from 48S complexes assembled on AUG codons with a [^-3]purine upon hydrolysis of eIF2-bound GTP could account for resistanceof these complexes to dissociation by eIF1 even after treatmentwith eIF5. Interaction of eIF2 ${alpha}$ with the [^-3] purine likely alsocontributes to the stability of 48S complexes after GTP hydrolysiseven in the absence of eIF1, because in this case treatmentwith eIF5 of 48S complexes assembled on a bad context AUG codonled to 65% dissociation (Fig. 6B, lane 3). Association of eIF2with 48S complexes after hydrolysis of eIF2-bound GTP mightalso prevent Met-tRNA^Met_i from dissociating from 40S subunitsbefore ribosomal subunit joining.

Discussion

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Abstract
Results
Discussion
Materials and methods
Acknowledgments
References

eIF1's position on the 40S subunit between the platform andinitiator tRNA suggests that it acts indirectly to ensure thefidelity of initiation codon selection and, specifically, toenable 43S complexes to discriminate against AUG triplets insuboptimal context (Pestova and Kolupaeva 2002; Lomakin et al.2003). The finding that the C-terminal domain of prokaryoticIF3 (which is not homologous to eIF1) can bind the same regionof the 40S subunit and perform many of eIF1's functions in initiationcodon selection, including enabling 43S complexes to recognizeinitiation codon context, also favors an indirect mode of actionfor eIF1 (Lomakin et al. 2006). Our hypothesis that eIF1 actsby antagonizing conformational changes in the 48S complex thatoccur as a result of initiation codon recognition and base-pairingwith the anticodon suggests that the role of the key ^-3 and⁺4 context nucleotides is to stabilize such changes by interactingwith components of the 48S complex. Here, we used UV cross-linkingto characterize and compare the specificity of interactionsof thioU and thioG at these positions with constituents of thiscomplex. In a separate study, we used mRNAs containing singlethioU residues at positions ^-26 to ⁺11 to map the mRNA pathon the 40S subunit in 48S complexes (V.G. Kolupaeva, A.V. Pisarev,C.U.T. Hellen, and T.V. Pestova, in prep.). Its similarity tothe mRNA path on the 70S ribosome as determined by crystallography(Yusupova et al. 2001) justifies using the structure of themRNA/30S subunit complex to model our cross-linking data.

UV cross-linking in 48S complexes formed with and without eIF1

IF3, a functional analog of eIF1, alters the position of mRNAon 30S subunits (La Teana et al. 1995; Shapkina et al. 2000),so we assayed interactions of the ^-3 and ⁺4 nucleotides in 48Scomplexes assembled with and without eIF1. The interactionsof thioU or thioG at both positions were unaffected by eIF1.Even if eIF1 influences the positions of mRNA or Met-tRNA^Met_iin scanning ribosomal complexes, the final conformation of 48Scomplexes with established codon-anticodon base-pairing appearsnot to depend on eIF1's involvement in their assembly. We detectedeIF1 in 48S complexes after eIF5-induced hydrolysis of eIF2-boundGTP (Unbehaun et al. 2004), but the observation that eIF1 wasreleased from minimal yeast initiation complexes following codon-anticodonbase-pairing (Maag et al. 2005) suggests that in mammalian 48Scomplexes, eIF1 might be displaced from its original locationon the 40S subunit but be retained in these complexes by interactionwith eIF3. If this is so, the apparently identical positionof mRNA in 48S complexes assembled with and without eIF1 isnot surprising.

UV cross-linking to the [⁺4] position

Both thioU[⁺4] and thioG[⁺4] cross-linked to rpS15. However,whereas thioU cross-linked weakly to AA_1818-1819 and stronglyto C₁₆₉₆ in h44 of 18S rRNA, thioG cross-linked exclusivelyto AA_1818-1819. Specific mRNA cross-linking to components ofthe 48S complex has not previously been analyzed, so we comparedour data with mRNA cross-linking in eukaryotic 80S complexesphased by cognate tRNA and in prokaryotic 70S complexes. Cross-linkingof thioU[⁺4] to rp15 in 48S complexes was consistent with thesame interaction in 80S complexes (Bulygin et al. 2005). rpS19,the prokaryotic homolog of rpS15, is located in the head ofthe 30S subunit (Fig. 4; Wimberly et al. 2000). Its C-terminaltail points toward the interface side but does not reach theA-site codon, so cross-linking of rpS15 is likely due to N-or C-terminal extensions relative to prokaryotic rpS19.

Cross-linking of mRNA to AA_1818-1819 has been detected withmidrange nucleotide derivatives but not with "zero-length" cross-linkers:No cross-linking of AA_1818-1819 to thioU[⁺4] was observed inphased or unphased 80S complexes (Demeshkina et al. 2000; Bulyginet al. 2005). The equivalent prokaryotic nucleotides (AA_1492-1493in T. Thermophilus) flip out upon binding of cognate aminoacyltRNA to the A-site during elongation and interact with the minorgroove of the first two base pairs of the base-paired codon-anticodonhelix, thereby monitoring the fidelity of elongator tRNA selection(Ogle et al. 2001). Flipping out of AA_1492-1493 also occursduring prokaryotic initiation when IF1 binds to the A-site areaof the 30S subunit; these bases splay apart whereas they stacktogether when cognate tRNA binds to the A-site (Carter et al.2001). Binding of eIF1A, the eukaryotic IF1 homolog (Battisteet al. 2000) or other factors to the 40S subunit might alsoalter the conformation of the upper part of h44 and flip outAA_1818-1819. Such conformational changes could account for "zero-length"cross-linking of thioU and thioG at [⁺4] to AA_1818-1819 in 48Sbut not 80S complexes. Cross-linking of thioU[⁺4] to C₁₆₉₆ in48S complexes was not consistent with cross-linking of thioU[⁺4]to the equivalent of rabbit C₁₆₉₁ in H28 of 18S rRNA in human80S complexes (Bulygin et al. 2005). This discrepancy cannotbe explained by the difference in positions of mRNA in 48S and80S complexes: In our recent experiments C₁₆₉₁ cross-linkedspecifically to thioU[⁺8] in 48S and 80S complexes (V.G. Kolupaeva,A.V. Pisarev, C.U.T. Hellen, and T.V. Pestova, in prep.), consistentwith cross-linking of thioU[⁺8] to the equivalent nucleotide(C₁₃₉₅) in prokaryotic 70S complexes (Rinke-Appel et al. 1993).In prokaryotes, C₁₄₀₀ and AA_1492-1493 (equivalents of rabbitC₁₆₉₆ and AA_1818-1819) are opposite each other, flanking themRNA (Fig. 4). Cross-linking of thioU to both sites suggeststhat structural rearrangements in 48S complexes cause them tobe closer to each other than their equivalents in prokaryotic30S subunit/70S ribosome crystal structures. The inability ofthioG to cross-link to C₁₆₉₆ might be due to its specific interactionwith A₁₈₁₈ and/or A₁₈₁₉, which could cause further structuraladjustments that preclude this cross-link.

UV cross-linking to the [^-3] position

In 48S complexes, neither thioU nor thioG at [^-3] cross-linkedefficiently to 18S rRNA, but thioU[^-3] cross-linked to rpS5and eIF2 ${alpha}$ and thioG[^-3] cross-linked only to eIF2 ${alpha}$ . Cross-linkingof rpS5 to the [^-3] position is consistent with the similarpaths of mRNA on eukaryotic 40S and prokaryotic 30S subunits:In prokaryotic ribosomal complexes, thioU[^-3] cross-links specificallyto rpS7, a homolog of eukaryotic rpS5 (Fig. 4; La Teana et al.1995). Cross-linking of the [^-3] nucleotide to rpS5 was alsoobserved in eukaryotic 80S complexes (Demeshkina et al. 2003);this study also reported its cross-linking to rpS26 (and torpS2 and rpS3, which we suggest was nonspecific, taking intoaccount the positions of prokaryotic analogs of eukaryotic rpS2and rpS3 in the 30S subunit; Wimberly et al. 2000). In contrastto the study by Demeshkina et al. (2003), we saw specific cross-linkingof rpS26 to mRNA in 48S complexes only to thioU at [^-8] to [^-11]but not at all at [^-3] (V.G. Kolupaeva, A.V. Pisarev, C.U.T.Hellen, and T.V. Pestova, in prep.).

The mRNA path in 48S complexes has not been studied, so specificcross-linking of eIF2 ${alpha}$ to [^-3] in mRNA has not been reported.eIF2 ${alpha}$ consists of structured N-terminal and C-terminal domainsthat are mobile relative to each other; the latter binds eIF2 ${gamma}$ (Yatime et al. 2004). eIF2 ${alpha}$ might thus bind the [^-3] nucleotideeither through the N-terminal domain or through its unstructuredC-terminal tail. The absence of the $~$ 10 C-terminal amino acidsof eIF2 ${alpha}$ and, interestingly, of eIF2 $beta$ did not influence this interaction.Consistent with the affinities to Met-tRNA^Met_i of eIF2-GTP andeIF2-GDP differing by only one order of magnitude (Kapp andLorsch 2004), in the absence of sucrose density gradient centrifugation,eIF5-induced hydrolysis of eIF2-bound GTP did not lead to completedissociation of eIF2 from 48S complexes so that 30%-35% and85%-90% of eIF2 ${alpha}$ could still cross-link to thioU[^-3] and thioG[^-3],respectively. The fact that the nature of the [^-3] nucleotideinfluenced its cross-linking to eIF2 ${alpha}$ after eIF5-induced GTPhydrolysis suggests that the eIF2-mRNA interaction influencesrelease of eIF2 during subunit joining. It is possible thatwithout this interaction, GTP hydrolysis would result in greaterand even complete eIF2 dissociation.

The finding that eIF5B enhances release of eIF2 from 48S complexesafter GTP hydrolysis merits special attention. Although unlikeits prokaryotic homolog IF2, binding of eIF5B to Met-tRNA^Met_ihas not been shown directly, this interaction might occur onthe 40S subunit and after binding to 48S complexes, eIF5B mightcompete with eIF2 for interaction with Met-tRNA^Met_i. Weakeningof eIF2/Met-tRNA^Met_i binding after hydrolysis of bound GTP couldpermit an interaction between Met-tRNA^Met_i and the C-terminaldomain IV of eIF5B to be established, and consequently promoterelease of eIF2. However, complete release of eIF2 from 48Scomplexes assembled on mRNA containing thioG[^-3] occurred onlyafter ribosomal subunit joining, which suggests that eIF2 iscompletely released only during the actual ribosomal subunitjoining event promoted by eIF5B. mRNA, therefore, influencesrelease of eIF2 as well as of eIF3 from initiation complexes(Unbehaun et al. 2004).

Activities of ${alpha}$ -subunit- and $beta$ -subunit-deficient eIF2 in 48S complex formation

Specific UV cross-linking to thioG[^-3] in mRNA in 48S complexessuggests that eIF2 ${alpha}$ is involved in recognition of initiationcodon context and thus in initiation codon selection. The functionalityof this interaction was confirmed in experiments on 48S complexformation in the presence of eIF2 ${alpha}$ -deficient eIF2 $beta$ ${gamma}$ on two mRNAs,both containing two AUG triplets, of which the first had a purineresidue either at [^-3] or at [⁺4]. With complete eIF2 but withouteIF1, 48S complexes formed almost exclusively on the first AUGtriplets of both mRNAs, but in the presence of eIF1, 48S complexformation was more efficient on the AUG triplet with the [^-3]purine (80% of total 48S complexes) than with the [⁺4] purine(50% of total 48S complexes). In the absence of eIF1, the lackof eIF2 ${alpha}$ had little effect on the efficiency or specificity of48S complex formation so that 43S complexes stopped efficientlyon the first AUG triplet irrespective of its context. In eIF1'spresence, the lack of eIF2 ${alpha}$ strongly influenced 48S complex formation.First, the combined efficiency of 48S complex formation on twoAUG triplets on both mRNAs was threefold lower than with completeeIF2. Second, whereas the ratio of 48S complexes formed on thefirst AUG triplet with a [^-3] purine and on the second AUG tripletwas 4:1 in the presence of complete eIF2, it fell to 1:1 inthe absence of eIF2 ${alpha}$ and became similar to the ratio of 48S complexformation on mRNA with two AUG triplets in which the first wasflanked by a [^-3] pyrimidine. In the presence of eIF1, 43S complexesassembled without eIF2 ${alpha}$ therefore could not sense the natureof the [^-3] nucleotide and 48S complexes formed with equal efficiencyon AUG triplets whether there was a purine or a pyrimidine at[^-3]. This result confirmed the suggested role for eIF2 ${alpha}$ in discriminatingthe [^-3] context nucleotide. The reduced efficiency of 48S complexformation on the AUG triplet with a [^-3] pyrimidine in the absenceof eIF2 ${alpha}$ also suggests that eIF2 ${alpha}$ 's interaction with the [^-3]nucleotide, irrespective of its nature, is generally importantfor 48S complex formation in the presence of eIF1 but that itis the strength of interaction (which is higher for purines)that is responsible for the [^-3] context rule. Our finding thateIF2 is not fully released from 48S complexes upon eIF5-inducedGTP hydrolysis and that the extent of its release depends onthe nature of the [^-3] nucleotide (being only 10%-15% with Gat this position) could account for the resistance of 48S complexesto eIF1-mediated dissociation after hydrolysis of eIF2-boundGTP and before the ribosomal subunit joining step.

Although interaction of the [⁺4] nucleotide with rpS15 was notbase-specific and rpS15 is also cross-linked to thioU[⁺5] (V.G.Kolupaeva, A.V. Pisarev, C.U.T. Hellen, and T.V. Pestova, inprep.), we cannot exclude the possibility that the rpS15-[⁺4]nucleotide interaction is important for initiation codon selection.We cannot directly test the functional importance of interactionof the [⁺4] nucleotide with AA_1818-1819, but the base specificityof this interaction points to the fact that AA_1818-1819 areinvolved not only in monitoring the fidelity of elongator tRNAselection, but also in selection of the initiation codon duringinitiation. By analogy with eIF2 ${alpha}$ , the interaction of the [⁺4]nucleotide with components of the 48S complex (AA_1818-1819 and/orrp S15) might also be generally important to stabilize 48S complexesassembled on AUG triplets whether they have a purine or a pyrimidineat [⁺4].

Materials and methods

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Abstract
Results
Discussion
Materials and methods
Acknowledgments
References

Plasmids

Vectors for expression of His₆-tagged eIF1, eIF1A, eIF4A, eIF4B,eIF5, and Escherichia coli methionyl-tRNA synthetase, and for(CAA)_n-AUGbad/bad-GUS mRNA transcription have been described(Pestova et al. 1996, 1998, 2000; Pestova and Kolupaeva 2002;Lomakin et al. 2006). The bovine eIF2 ${alpha}$ coding region was amplifiedby PCR from pUKC50 (Green et al. 1991) and cloned between BamH1and HindIII restriction sites of pET28b (Novagen) yielding pET(His₆-eIF2 ${alpha}$ ).Transcription vectors for (CAA)_n-AUG-(CAA)_m mRNA derivativescontaining U or G at [^-3] or [+4] were made by inserting complementaryoligonucleotides corresponding to a T7 promoter, 5'-UTR, codingregion, and SmaI restriction site between the BamH1 and HindIIIsites of pBR322. (CAA)_n-AUGbad/good-GUS and (CAA)_n-AUGgood/bad-GUStranscription vectors were made using the same strategy as forthe (CAA)_n-AUGbad/bad-GUS vector (Pestova and Kolupaeva 2002).

In vitro transcription

All mRNAs were transcribed using T7 RNA polymerase. (CAA)_n-AUGbad/bad-GUS,(CAA)_n-AUGgood/bad-GUS, and (CAA)_n-AUGbad/good-GUS mRNAs weretranscribed as described (Pestova and Kolupaeva 2002). For UVcross-linking experiments, ³²P-labeled derivatives of (CAA)_n-AUG-(CAA)_mmRNA containing 4-thioU or 6-thioG (8 x 10⁶ c.p.m./µg)were transcribed from SmaI-digested plasmids in the presenceof 4-thioUTP (Ambion) or 6-thioGTP (Jena Bioscience), [ ${alpha}$ ³²P]-CTP(222 Tbq/mmol), and a rAC transcription primer (Dharmacon).For toe-printing experiments, derivatives of (CAA)_n-AUG-(CAA)_mmRNA were transcribed from EagI-digested plasmids.

Purification of factors and ribosomal subunits, and aminoacylation of initiator tRNA

40S and 60S subunits, eIF2, eIF3, eIF4F, and eIF5B were purifiedfrom rabbit reticulocyte lysate (RRL) and recombinant eIF1,eIF1A, eIF4A, eIF4B, eIF5, and E. coli methionyl-tRNA synthetasewere expressed in E. coli BL21(DE3) and purified as described(Pestova et al. 1996, 1998, 2000; Lomakin et al. 2006). ${alpha}$ -Subunit-deficienteIF2 was purified as described (Anthony et al. 1990). $beta$ -Subunit-deficienteIF2 is always obtained in small amounts during eIF2 purificationfrom RRL (Pestova et al. 2000) as a peak eluted from MonoQ twofractions earlier than complete eIF2. eIF2 with a truncated ${alpha}$ -subunit was purified in small quantities from HeLa cells usingthe purification procedure previously described for eIF2 fromRRL (Pestova et al. 2000) as a peak eluted from MonoQ slightlyearlier than complete eIF2. Recombinant eIF2 ${alpha}$ was expressed inE. coli BL21(DE3) and purified on Ni²⁺-NTA (Qiagen) and MonoQ.Total native rabbit tRNA (Novagen) was aminoacylated by recombinantmethionyl-tRNA synthetase as described (Pestova et al. 1996).

UV cross-linking experiments

48S complexes were assembled on ³²P-labeled derivatives of (CAA)_n-AUG-(CAA)_mmRNA containing 4-thioU or 6-thioG at [^-3] or [⁺4] by incubating100 ng of mRNA, 10 pmol Met-tRNA^Met_i, 8 pmol 40S subunits, 5µg of different forms of eIF2, 15 µg of eIF3, 2.5of µg eIF4A, 0.5 µg of eIF4B, 2.5 µg of eIF4F,0.2 µg of eIF1A, 0.2 µg of eIF1, and 3 µgof recombinant eIF2 ${alpha}$ (as indicated) in 100 µL of bufferA (20 mM Tris at pH 7.5, 100 mM KAc, 2 mM DTT, 2.5 mM MgAc₂,0.25 mM spermidine) containing 1 mM ATP, 0.4 mM GTP ${gamma}$ S (or 0.4mM GTP when eIF5 was included) for 10 min at 37°C. In reactionmixtures shown in Figures 2H (lane 3) and 6C,D (lanes 2) hydrolysisof eIF2-bound GTP was induced by incubating with 1 µgof eIF5 for 15 min. 48S complexes were purified by centrifugationin a Beckman SW55 rotor for 1h and 40 min at 4°C and 50,000rpm in 10%-30% sucrose density gradients prepared in bufferA. [³²P]-labeled mRNA in ribosomal fractions was monitored byCherenkov counting. Equal amounts of counts ( $~$ 200,000 c.p.m.)of peak fractions were irradiated at 360 nm for 30 min on iceusing a UV-Stratalinker (Stratagene) and used to identify cross-linkedproteins and nucleotides in 18S rRNA. For experiments shownin Figure 6C (lane 3) and D (lanes 3,5), 48S complexes werepurified by sucrose density gradient centrifugation, dilutedthreefold with buffer A + 0.4 mM GTP, incubated for 15 min at37°C with 1 µg of eIF5, 1 µg of eIF5B, or 8pmol 60S subunits, as indicated, and then subjected to UV irradiation.

Identification of cross-linked proteins

To identify UV-cross-linked eIFs, $~$ 20 µL of cross-linkedribosomal fractions containing equal amounts of counts weretreated with RNase A and subjected to electrophoresis in NuPAGE4%-12% Bis-Tris-Gel (Invitrogen) followed by autoradiography.UV-cross-linked ribosomal proteins were identified by acidic-SDS2D gel electrophoresis. Complete cross-linked peak fractions( $~$ 200,000 c.p.m.) were combined, transferred to buffer B (20mM Tris-HCl at pH 7.5, 50 mM KCl, 2 mM MgCl₂, 2 mM DTT, 0.1mM EDTA), concentrated on microcon-YM10 centrifugal filter units(Millipore) to 100 µL of final volume, and treated withRNase A for 30 min at 37°C. These samples were combinedwith 100 µL of 40S subunits (OD₂₆₀ = 100 o.u./mL) in bufferB. Proteins were extracted from these mixtures with 100 mM MgCl₂in 67% acetic acid and precipitated with acetone (Hardy et al.1969). Samples were then resuspended in 8 M urea, 1% 2-mercaptoethanol,10 mM bis-tris acetate (pH 4.2); incubated for 15 min at 37°C;and subjected to first-dimension electrophoresis (Yusupov andSpirin 1988) in 120-mm-long glass tubes with a 2.4-mm innerdiameter. First-dimension gels were incubated for 10 min incathode buffer and combined with second-dimension gels, whichhad been prepared as described (Schagger and von Jägow1987). The separating gel (16.5% T and 3% C) contained 13.3%w/v glycerol. Gels were run for 12 h at 40 mA, stained withSimply Blue Safe Stain (Invitrogen), and destained with waterfor LC-nanospray tandem mass spectrometry of peptides derivedby in-gel tryptic digestion at an in-house facility, or fixedwith 10% methanol/5% glycerol for drying and autoradiography.

Identification of cross-linked nucleotides in 18S rRNA

After irradiating 48S complexes, rRNA, mRNA, and tRNA were phenol-chloroformextracted and ethanol precipitated. Regions of 18S rRNA cross-linkedto ³²P-labeled mRNA were first identified by RNase H digestionof 18S rRNA hybridized with a panel of $~$ 20-mer DNA oligonucleotidescomplementary to different regions of 18S rRNA essentially asdescribed (Dontsova et al. 1992). 18S rRNA fragments were separatedby electrophoresis in 12% denaturing PAGE. Cross-linked anduncross-linked 18S rRNA fragments were visualized by autoradiographyand methylene blue staining, respectively. Cross-linked regionswere identified and attributed to corresponding uncross-linkedfragments of 18S rRNA on stained gels taking into account thereduced mobility of cross-linked rRNA fragments due to covalentlybound 64-nt mRNA. Precise identification of cross-linked nucleotidesin 18S rRNA was done by primer extension inhibition using primers5'-CAAGTTCGACCGTCTTC-3' and 5'-CC TTCCGCAGGTTCACC-3' complementaryto nucleotides 1783-1799 and 1840-1856 of 18S rRNA respectively,chosen on the basis of RNase H digestion.

Toe-printing analysis of 48S initiation complexes

Ribosomal 48S complexes assembled on (CAA)_n-AUGbad/bad-GUS,(CAA)_n-AUGgood/bad-GUS, and (CAA)_n-AUGbad/good-GUS mRNAs, andderivatives of (CAA)_n-AUG-(CAA)_m mRNAs were analyzed by primerextension using AMV RT essentially as described (Pestova andKolupaeva 2002). Reaction mixtures (40 µL) containing2 pmol mRNAs, 5 pmol Met-tRNA^Met_i, 5 pmol 40S subunits, 1.5µg of complete or subunit-deficient eIF2, 1.2 µgof eIF2 ${alpha}$ , 6 µg of eIF3, 1 µg of eIF4A, 0.2 µgof eIF4B, 1 µg of eIF4F, 0.2 µg of eIF1, and 0.2µg of eIF1A as indicated in the figure legends were incubatedin buffer A (+1 mM ATP + 0.4 mM GTP) at 37°C for 10 min,and in some cases for 15 min more with 1 µg of eIF5 or1 µg of eIF5 and 0.3 µg of eIF1 (Fig. 6A,B). Toe-printinganalysis was done using [³²P]dATP and primers 5'-CATGACATTAACC-3'and 5'-CGCGCTTTCCCACCAA CG-3' ${sigma}$ complementary to pBR322 nucleotides4307-4319 and GUS nucleotides 97-114, respectively. cDNA productswere analyzed by electrophoresis through 6% polyacrylamide sequencinggel. PhosphorImager analysis was used to quantify the efficiencyof initiation complex formation. All values presented in Resultsare the average of at least three independent experiments.

Acknowledgments

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Abstract
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Discussion
Materials and methods
Acknowledgments
References

We thank R. Schneider and M. Tuite for generously providingantibodies against eIF2 ${alpha}$ and the bovine eIF2 ${alpha}$ clone, M. Yusupovfor valuable technical advice, and A. Marintchev for helpfuldiscussion. This work was supported by NIH grant R01 GM59660(to T.V.P.) and R01 GM26796 (to W.C.M.).

Footnotes

Article and publication are at http://www.genesdev.org/cgi/doi/10.1101/gad.1397906.

³ Corresponding author.
E-MAIL tatyana.pestova{at}downstate.edu;FAX (718) 270-2656.

References

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Abstract
Results
Discussion
Materials and methods
Acknowledgments
References

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