INTRODUCTION

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The fundamental process of translation initiation has been conserved between prokaryotes and eukaryotes. The initiator Met-tRNA is bound to the small ribosomal subunit, and this complex is localized to the AUG start codon of an mRNA. Three translation initiation factors (IFs) have been identified in prokaryotes (reviewed in references 7 and 18). Factor IF2 is responsible for binding fMet-tRNA_i^Met to the 30S ribosomal subunit. Factor IF1 binds to the 30S subunit and protects the same region of the ribosome (A site) as the elongation factor EF-Tu-GTP-aminoacyl-tRNA complex (28). Although a unique function has not been attributed to IF1, it does promote IF2 activities (reviewed in references 7, 18, 22, and 31. Factor IF3 dissociates ribosomal complexes, presumably to generate a pool of small ribosomal subunits for translation initiation. In addition, IF3 has recently been implicated in the process of ribosome recycling following termination of translation (21). Translation initiation is a much more complex process in eukaryotes than in prokaryotes, and, as might be expected, a larger number of initiation factors are required in eukaryotes (27).

The binding of Met-tRNA_i^Met to the small 40S ribosomal subunit in eukaryotes is facilitated by factor eIF2. Factor eIF1A, formerly known as eIF4C, has been reported to function in subunit dissociation as well as promoting and stabilizing Met-tRNA binding to the 40S subunit (4, 9, 10, 41, 42). In addition, ribosomal toe-printing assays revealed that eIF1A is required for formation of a 48S preinitiation complex in which a 40S subunit with associated initiation factors and Met-tRNA_i^Met is bound at the AUG start codon of an mRNA following ribosome scanning (32).

Translation initiation factor eIF5B shows striking sequence similarity to prokaryotic IF2 and was previously referred to as yIF2 (11) or hIF2 (25) for yeast (Saccharomyces cerevisiae) or human IF2, respectively. It was reported recently that eIF5B plays an important role in the subunit joining step of protein synthesis (33). In yeast, eIF5B is nonessential; however, deletion of the FUN12 gene encoding eIF5B impairs translation initiation in vivo and in vitro and causes a severe slow-growth phenotype (11). This slow-growth phenotype can be partially suppressed by overexpression of tRNA_i^Met, suggesting that eIF5B is important for Met-tRNA_i^Met binding to ribosomes (11). Human eIF5B can functionally substitute for the yeast factor to promote growth in vivo and to restore translation initiation in extracts prepared from fun12 strains (25). Like prokaryotic IF2, eIF5B contains a consensus GTP-binding domain. The factor possesses ribosome-dependent GTPase activity that appears to be required for dissociation of the factor from 80S ribosomes following subunit joining (33). Consistent with an important role for GTP binding by eIF5B, mutations in the GTP-binding domain of human eIF5B impair translation in yeast and human cells (25, 44). Recently, Drosophila melanogaster eIF5B was reported to interact with the DEAD box RNA helicase VAS encoded by the gene vasa (8). Genetic interactions between mutations in VAS and eIF5B suggest that the proteins functionally interact; however, the role of this interaction in translation initiation is not known. An eIF5B/IF2 homolog has also been identified in Archaea, and we found that this protein can partially substitute for the yeast protein both in vivo and in vitro (25). Interestingly, archaeal and eukaryotic eIF1As show strong sequence similarity to prokaryotic IF1 (23). Thus, eIF5B/IF2 and eIF1A/IF1 form a pair of universally conserved translation initiation factors.

A common theme emerging from structural studies of translation factors is mimicry of tRNA. Comparisons of the crystal structures of the prokaryotic translation elongation factor EF-Tu-GTP-Phe-tRNA^Phe ternary complex and elongation factor EF-G-GDP binary complex revealed that domains III and IV of EF-G bore strong resemblance to the anticodon stem and loop of the tRNA in the EF-G ternary complex (29, 30). In addition, the GTP-binding domains of EF-Tu and EF-G could be superimposed in the two structures (29, 30). Given that EF-Tu binds the aminoacyl-tRNA to the ribosomal A site, the structure of EF-G supported the idea that EF-G binds in the ribosomal A site to promote translocation of the peptidyl-tRNA from the A site to the P site during elongation. The structure of the translation termination factor eRF1 from humans also shows some similarities to that of a tRNA molecule; however, the tertiary structure of the putative tRNA-mimicking domains in eRF1 do not resemble that of the corresponding domains in EF-G (1, 14, 39). Likewise, the structural elements comprising the tRNA mimicry domain of the bacterial ribosome recycling factor RRF resemble neither those of EF-G nor those of eRF1 (36). Thus, proteins have developed multiple ways to mimic the structure of a tRNA.

Recently, Brock et al. (7) extended this molecular mimicry hypothesis to translation initiation. Based on amino acid sequence similarity between different segments of the C-terminal regions of EF-G and prokaryotic IF1 or IF2, they proposed that IF1 and IF2 interact with one another and together structurally mimic EF-G. Because Met-tRNA_i^Met is thought to be delivered directly to the ribosomal P site (16, 18), the notion that an IF1-IF2 complex structurally mimics EF-G and binds to the A site on the ribosome is appealing. According to this model, A site binding by the IF1-IF2 complex sterically blocks this site and directs the binding of Met-tRNA_i^Met to the P site. The fact that IF1 binding has been localized to the ribosomal A site supports this model (28). Protein cross-linking studies suggested that IF1 and IF2 can interact when bound to the 30S ribosomal subunit (6); however, a direct interaction between the isolated proteins off the ribosome has not been reported. We were intrigued by the molecular mimicry hypothesis for IF1 and IF2, and, based on the strong sequence conservation of eIF1A and eIF5B with IF1 and IF2, respectively, we decided to test the hypothesis that the eukaryotic factors interact.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Plasmids. A 3.95-kb SalI-SacI DNA fragment carrying the FUN12 gene encoding yeast eIF5B was excised from plasmid pC479 (11) and inserted between the same sites of pUC19 (45) and pRS426 (12) creating plasmids pC1039 and pC1070, respectively. A FLAG epitope (DYKDDDDK) was inserted in place of Glu-16 in eIF5B making use of a natural NspV site. With a 3' primer that contained the NspV site and also encoded the FLAG epitope, an ~0.43-kb SalI-NspV fragment containing the 5' end of FUN12 was amplified by PCR and inserted between the same sites of pC1039 to generate FLAG-tagged FUN12 plasmid pC1041. The SalI-SacI fragment from pC1041 was subcloned into URA3 plasmids pRS316 (38) and pRS426 (12) creating low- and high-copy-number FLAG-FUN12 plasmids pC1005 and pC1064, respectively. The plasmids for expressing N-terminally truncated FLAG-tagged eIF5B_378-1002 were constructed in three steps. First, an ~2.4-kb fragment encoding eIF5B_378-1002 was amplified by PCR using pC1039 as a template, a 5' primer that introduced an NspV site, and a 3' primer containing the SacI site present in pC1039. The PCR product was digested with NspV and SacI and inserted between the same sites of pC1041 creating plasmid pC1042. Finally, an ~2.8-kb SalI-SacI fragment from pC1042 was subcloned to pRS316 and pRS426 generating low- and high-copy-number FLAG-FUN12 (378-1002) plasmids pC1043 and pC1007, respectively. An ~1.63-kb NspV fragment from plasmid pC1070 containing the 5' end of the FUN12 gene and flanking vector sequences was inserted in place of the corresponding fragment in pC1007 generating the high-copy-number URA3 plasmid pC1037 that expressed untagged N-terminally truncated eIF5B_378-1002. Due to the manner in which the N-terminally truncated allele was generated, both eIF5B_378-1002 and FLAG-eIF5B_378-1002 contained the first 15 residues of the native eIF5B at their N termini.

828-918

Yeast strains. The fun12 strains J130 (MATa ura3-52 leu2-3 leu2-112 fun12::hisG) and J133 (MAT ura3-52 leu2-3 leu2-112 fun12::LEU2) were described previously (11). Strain J111 is identical to strain J130. Strain H1895 (MATa leu2-3 leu2-112 ura3-52 trp1-63 gcn2 GCN4-lacZ TRP1) in which the GCN4-lacZ allele is integrated at TRP1 was constructed by replacing the chromosomal GCN2 in strain H1642 with an unmarked gcn2 allele as described previously (15). The TIF11 gene was deleted in H1895 generating strain H2809 (MATa leu2-3 leu2-112 ura3-52 trp1-63 gcn2 tif11 pDSO11 [TIF11, URA3] GCN4-lacZ TRP1), as will be described elsewhere. Strain H2769 (KAY11; MAT his1-29 gcn2-508 ura3-52 leu2-3 leu2-112 tif34-1 HIS4-lacZ ura3-52 YCpL-tif34-HA-1 [tif34-HA-1, LEU2]) is a derivative of strain KAY8 (2) in which plasmid YCpL-TIF34-HA carrying wild-type TIF34 is replaced with plasmid YCpL-tif34-HA-1 carrying a temperature-sensitive allele. Strain TB11B-4-1 (MATa ade1 leu2-3 leu2-112 ura3-52 prt1-1) was provided by G. Johnston. Strains Y187 (MAT gal4- gal80- his3-200 trp1-901 ade2-101 ura3-52 leu2-3,112 met URA3::GAL1-lacZ) and Y190 (MATa leu2-3,112 ura3-52 trp1-901 his3-200 ade2-101 gal4- gal80- URA::GAL1-lacZ LSY2::GAL1-HIS3) were used for yeast two-hybrid analyses (20).

GST pull-down assays. GST (pGEX-4T-2) and GST-eIF1A (pDSO41-1) fusions in Escherichia coli extracts were purified on glutathione-Sepharose 4B beads (Amersham Pharmacia Biotech) in phosphate-buffered saline containing a complete protease inhibitor cocktail (Boehringer Mannheim), 1 mM phenylmethylsulfonyl fluoride (PMSF), and 10 µg of pepstatin A/ml. Yeast cells expressing various forms of eIF5B were broken in lysis buffer (20 mM Tris-HCl [pH 7.4], 1 mM magnesium acetate, 100 mM KCl, 0.1% Triton X-100, complete protease inhibitor cocktail, 1 mM PMSF, and 10 µg of pepstatin A/ml) with acid-washed glass beads by 12 30-s agitations on a vortex mixer at 4°C, with 30 s on ice between mixing cycles. Whole-cell extracts (WCEs) were obtained by clearing the lysates by centrifugation. Postribosomal supernatants (PRSs) were obtained following centrifugation of the WCEs at 200,000 × g for 1 h.

Purification of recombinant forms of eIF5B. The GST-eIF5B fusion proteins were overexpressed in E. coli strain BL21(DE3)pLysS and purified by affinity chromatography using glutathione-Sepharose (Pharmacia). The fusion proteins were eluted in running buffer (25 mM Tris-HCl [pH 7.5], 100 mM NaCl, 5 mM DTT) containing 20 mM reduced glutathione and then dialyzed against running buffer. The eIF5B fragments were cleaved from the carrier protein using thrombin, and the carrier protein was removed by passage through a MonoS column (Amersham Pharmacia Biotech). Finally, the protein was extensively dialyzed against buffer containing 25 mM Tris-HCl, pH 7.5, 100 mM NaCl, 10% glycerol, and 5 mM DTT.

Coimmunoprecipitation assays. For coimmunoprecipitation experiments with eIF1A-HA, 800 µg of yeast WCEs was precipitated with 3 µl of monoclonal anti-HA antibodies (HA.11; Babco) bound to 25 µl of protein A-Sepharose beads in 300 µl of lysis buffer for 2 h at 4°C. Immune complexes attached to the beads were washed four times with 800 µl of lysis buffer and then eluted by boiling for 5 min in red loading buffer (New England Biolabs). Proteins were separated by SDS-PAGE and then electroblotted to nitrocellulose membranes. The eIF1A-HA protein was visualized by probing the membranes with polyclonal anti-HA antiserum (Babco), and eIF5B was visualized by probing the membrane with polyclonal antiserum raised against a GST-eIF5B_396-1002 fusion protein. The immune complexes were detected by ECL (Amersham).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Two-hybrid interaction between eIF5B and eIF1A. We used yeast two-hybrid assays to identify and then localize the eIF1A-interacting region in eIF5B. A series of GAL4 DNA binding domain and GAL4 activation domain fusions containing various truncated fragments of yeast eIF5B were tested for interaction with the appropriate fusions containing the full-length 153-amino-acid yeast eIF1A (43) (Fig. 1). The results demonstrate that the C-terminal half of eIF5B (amino acids 559 to 1002), which lacks the GTP-binding domain, binds to eIF1A. Removal of the last 100 amino acids of this eIF5B fusion eliminated eIF1A binding, whereas eIF5B fusions containing either the C-terminal 250 or 150 residues also bound eIF1A (Fig. 1). Identical results were obtained whether the eIF5B fragments were expressed as GAL4 DNA binding domain or GAL4 activation domain fusions. We conclude that eIF1A and eIF5B can physically interact in vivo and that the C-terminal 100 to 250 residues of eIF5B are necessary and sufficient for this interaction.

View larger version (10K): [in this window] [in a new window]   FIG. 1.   eIF1A interacts with the C terminus of eIF5B in the yeast two-hybrid assay. The schematic at the top depicts full-length yeast eIF5B. The remaining schematics depict the segments of eIF5B tested in the two-hybrid assays, with the numbers referring to the amino acid positions at the termini of the eIF5B fragments. The DNA fragments encoding the indicated portions of yeast eIF5B and full-length yeast eIF1A were inserted in the yeast two-hybrid activation domain vector pGAD424 and the DNA binding domain vector pGBT9. Yeast strain Y187 bearing pGAD424 derivatives was mated with Y190 bearing pGBT9 derivatives, and diploids were isolated on synthetic complete (SC)-Trp-Leu medium. The strength of the protein-protein interactions was measured by stimulation of the HIS3 reporter present in the diploids as assayed by growth on SC-Trp-Leu-His medium containing 30 mM 3-aminotriazole after 9 days at 30°C (++, robust growth; +, weak growth, but above background levels; , background growth equivalent to that empty-vector controls that lack eIF5B and eIF1A sequences). Equivalent results were obtained when the eIF5B fragments were fused to the GAL4 DNA binding domain or to the activation domain. G-domain, GTP-binding domain.

The C terminus of eIF5B is critical for function in vivo. As the two-hybrid results indicated that the C-terminal 100 to 250 residues of eIF5B mediated the interaction with eIF1A, we examined the importance of these residues for eIF5B function in vivo. Yeast strains lacking the FUN12 gene encoding eIF5B exhibit a severe slow-growth phenotype. Previously, we reported that high-level expression of an N-terminally truncated form of yeast eIF5B (residues 378 to 1002), retaining only the GTP-binding and C-terminal domains, fully complemented the slow-growth phenotype of a fun12 strain (11). As shown in Fig. 2, when expressed from a low-copy-number plasmid under the control of the native FUN12 promoter, N-terminally truncated eIF5B_378-1002 retained its complementing activity. When expressed in the same manner, the eIF5B_1-915 mutant protein, lacking the last 77 residues, was severely impaired in its ability to complement the slow-growth phenotype of a fun12 strain (Fig. 2A). eIF5B proteins lacking the C-terminal 175 residues (eIF5B_1-827) or an internal segment of 90 residues near the C terminus (eIF5B_828-918) were completely inactive (Fig. 2A). Because the expression levels of these C-terminally mutated proteins were significantly less than that of the wild type, we expressed eIF5B_1-915 and eIF5B_1-827 from high-copy-number plasmids. As indicated in Fig. 2B, when expressed from a high-copy-number plasmid, eIF5B_1-915 was present at levels that were greater than those of wild-type eIF5B (amino acids 1 to 1002); however, the protein still failed to complement effectively the slow-growth phenotype of a fun12 strain (see Fig. 7A; data not shown). These results reveal that the C-terminal portion of eIF5B is necessary for activity in vivo, consistent with a functionally important interaction between eIF5B and eIF1A mediated by this segment of eIF5B.

View larger version (22K): [in this window] [in a new window]   FIG. 2.   The C terminus of yeast eIF5B is required for activity in vivo. (A) Schematic of yeast eIF5B. Shown are the full-length (F.L.) form and various truncated forms or a form with or an internal deletion. The numbers refer to the amino acid positions in the proteins. Large black box, conserved GTP-binding domain; small black box (left end), N-terminal FLAG epitope tag. The various eIF5B proteins were expressed under the control of the native FUN12 promoter on low-copy-number (L.C.) or high-copy-number (H.C.) plasmids in fun12 strain J111 and tested for the ability to complement the slow-growth phenotype of this strain. Growth rates were assessed by streaking transformants for single colonies on minimal medium. ++++, wild-type growth with visible colonies in streak-outs after 2 days; , fun12 growth with visible colonies in streak-outs after 5 days; ±, slightly larger-sized colonies in streak-outs than observed with fun12 strains after 5 days. The relative expression levels of the eIF5B constructs expressed from low- or high-copy-number plasmids are indicated (ND, not determined). (B) Immunoblot analysis of eIF5B expression. WCEs of transformants of strain J111 expressing the indicated eIF5B construct or vector alone were prepared and subjected to immunoblot analysis using polyclonal antiserum raised against a GST-eIF5B396-1002 fusion protein (shown) as well as monoclonal anti-FLAG antibodies. To control for protein loading, the lower half of the blot was probed with antiserum specific for yeast eIF2. Immune complexes were visualized by ECL.

The C-terminal region of eIF5B interacts directly with eIF1A in vitro. To confirm the eIF5B-eIF1A interaction detected in the two-hybrid assays, we carried out in vitro binding assays. Recombinant GST and GST fused to full-length yeast eIF1A (GST-eIF1A) were expressed in E. coli, bound to glutathione-Sepharose beads, and incubated with WCEs prepared from fun12 strains expressing either eIF5B_378-1002 or eIF5B_378-827 (Fig. 3, middle). The GST-eIF1A fusion, but not GST alone, bound high levels of eIF5B_378-1002 (~20% with the 2× concentration); however, no binding to eIF5B_378-827 was observed (Fig. 3). As both eIF5B and eIF1A have been found to bind ribosomes (33, 41), it was possible that the interaction we detected was bridged by ribosomes and that the two factors do not interact directly. To test if the interaction was dependent on ribosomes, the WCEs were centrifuged at high speed to pellet the ribosomes and the binding assay was repeated using the PRS. Immunoblot analysis using antisera against the yeast ribosomal protein S22 confirmed that the PRS was depleted of ribosomes (data not shown). As shown in Fig. 3 (bottom), GST-eIF1A, but not GST, bound a significant fraction of eIF5B_378-1002 present in the PRS. This result demonstrates that eIF5B and eIF1A can interact independently of the ribosome; however, it remains possible that the functionally important interaction between the two proteins occurs on the ribosome in vivo.

View larger version (34K): [in this window] [in a new window]   FIG. 3.   The C terminus of eIF5B is required for interaction with GST-eIF1A in a yeast WCE. (Top) Schematics of FLAG epitope-tagged eIF5B378-1002 and eIF5B378-827. Small black box (left end), FLAG epitope tag; large black box, GTP-binding domain. (Middle) The indicated GST (lanes 2, 3, 7, and 8) and GST-eIF1A (lanes 4, 5, 9, and 10) fusions attached to glutathione-Sepharose beads were incubated with WCEs from fun12 strain J111 expressing either N-terminally truncated eIF5B378-1002 (pC1043) (lanes 1 to 5) or N- and C-terminally truncated eIF5B378-827 (pC1058) (lanes 6 to 10) from low-copy-number plasmids. Both eIF5B proteins contain an N-terminal FLAG epitope tag. The 1× concentrations for GST and GST-eIF1A were 0.8 and 0.5 mM, respectively. The input (I) lanes represent 10% of the yeast extracts used for the binding assays. Following binding, the beads were pelleted and washed, and the bound proteins were analyzed by SDS-PAGE followed by electroblotting to nitrocellulose membranes. The GST fusion proteins were visualized by Ponceau-S staining (lower panels), and the eIF5B proteins were detected using anti-FLAG peptide antiserum and ECL (upper panels). (Bottom) The indicated GST (lane 2) and GST-eIF1A (lane 3) fusions attached to glutathione-Sepharose beads were incubated with PRSs from fun12 strain J111 expressing FLAG-tagged N-terminally truncated eIF5B378-1002 (pC1043). The concentrations of GST and GST-eIF1A proteins in the binding assays were 1.6 and 1.0 mM, respectively. The input lane represents 10% of the PRS used for the binding assays. The analysis of the binding reactions and visualization of the results were as described above.

View larger version (33K): [in this window] [in a new window]   FIG. 4.   eIF5B interacts directly with eIF1A. The indicated GST and GST-eIF1A fusion proteins expressed in E. coli were purified on glutathione-Sepharose beads and incubated with the following purified recombinant eIF5B fragments: eIF5B396-1002 (A), eIF5B745-1002 (B), eIF5B396-959 (C), and eIF5B396-876 (D). Following binding and washing, 10% of the supernatant fractions (SN) and 100% of the pellet fractions (P) were resolved by SDS-4 to 20% PAGE and visualized by Coomassie staining (left panels). The input (I) lanes contain 10% of the eIF5B fragments used in the binding assays. The concentrations of eIF5B and GST or GST-eIF1A proteins in the binding reaction mixtures are indicated below the results. Because breakdown products of the GST-eIF1A fusion protein comigrated with eIF5B745-1002, the pellet fractions of binding reaction mixtures lacking (P 5B) and containing (P +5B) eIF5B are presented (B). Schematic depictions of the eIF5B constructs and a qualitative summary of the results of these binding assays and of the in vitro translation assays shown in Fig. 5 are presented on the right.

fun12

fun12

fun12

fun12

View larger version (17K): [in this window] [in a new window]   FIG. 5.   The C terminus of eIF5B is required for function in an in vitro translation system. Translation extracts were prepared as described previously (11) from fun12 strain J133 carrying low-copy-number FUN12 plasmid pC479 (FUN12+) or empty vector pRS316 (fun12). Extracts were incubated with 200 ng of luciferase mRNA and the indicated amounts of highly purified recombinant GST or GST-eIF5B fusions. Translational activity was determined, as described previously (11), by measuring luminescence after a 15-min incubation at 26°C. Results are representative of at least two independent experiments.

Coimmunoprecipitation analysis reveals interaction between eIF5B and eIF1A in vivo. Having reconstituted interactions between purified GST-eIF1A and purified eIF5B (Fig. 4) and between bacterially expressed GST-eIF1A and native eIF5B in cell extracts (Fig. 3), we next examined whether we could coimmunoprecipitate eIF5B and eIF1A when both proteins were present in the cell at physiological levels. WCEs were prepared from isogenic strains expressing either native eIF1A or a triple-HA epitope-tagged form of eIF1A (eIF1A-HA; the HA tag is at the C terminus of eIF1A). When eIF1A-HA was expressed from a high-copy-number plasmid, its abundance was comparable to that of the endogenous eIF1A protein present in wild-type strains (Fig. 6A, upper panel; compare lanes 3 and 7). In addition, no growth defects in tif11 strains expressing the eIF1A-HA protein were observed (data not shown), indicating that the epitope does not interfere with eIF1A function in vivo. The WCEs were incubated with anti-HA antibodies prebound to protein A-Sepharose beads, and after extensive washing, the pellet and supernatant fractions were analyzed by SDS-PAGE and immunoblotting. As shown in Fig. 6B, approximately 20 to 40% of the eIF1A-HA was precipitated with the resin, whereas none of the untagged eIF1A was precipitated (Fig. 6B; compare lanes 7 and 3). Approximately 3% of the cellular eIF5B coprecipitated with eIF1A-HA (Fig. 6B, lane 7). Thus, we estimate that the percentage of cellular eIF5B in a complex with eIF1A, when corrected for the efficiency of eIF1A-HA recovery, was 7.5 to 15%.

View larger version (27K): [in this window] [in a new window]   FIG. 6.   eIF5B and eIF1A interact in vivo. (A) Immunoblot analysis of eIF1A and eIF1A-HA expression. WCEs were prepared from the wild-type (WT) strain H1895 and derivatives of the isogenic tif11 strain H2809 containing the high-copy-number (H.C.) plasmid pDSO23 (TIF11 LEU2) encoding eIF1A or pDSO46 (TIF11-HA LEU2) encoding eIF1A-HA. The indicated amounts of WCEs were subjected to SDS-PAGE and analyzed by immunoblotting using polyclonal antisera raised against yeast eIF2B (GCD6) or eIF1A. Immune complexes were visualized by ECL. (B) Coimmunoprecipitation of eIF5B with epitope-tagged eIF1A. WCEs were prepared from the tif11 strains described for panel A, which express either eIF1A or HA epitope-tagged eIF1A (eIF1A-HA) from high-copy-number plasmids. Aliquots containing 800 µg of protein were incubated with monoclonal anti-HA antibodies (HA.11; Babco) prebound to protein A-Sepharose beads, and, after being washed, the bound proteins were analyzed by immunoblotting using anti-HA and anti-eIF5B antisera, as indicated. Input lanes contain 1 or 10% of the starting amount of WCE, the pellet lanes (P) containing 100% of the immunoprecipitated fraction, and the supernatant lanes (SN) contain 5% of the reaction mixtures following removal of the pellet. (C) Coimmunoprecipitation of eIF1A with epitope-tagged eIF5B. WCEs were prepared from fun12 strain J111 expressing, from high-copy-number plasmids, eIF1A and either an untagged (pC1037) or FLAG epitope-tagged (FL; pC1007) form of N-terminally truncated eIF5B378-1002, as indicated. Aliquots containing 800 µg of protein were incubated with anti-FLAG affinity resin, and after being washed the bound proteins were analyzed by SDS-PAGE and immunoblotting using antisera specific for the proteins indicated at the left. The input (I) lanes containing 2% of the starting amount of WCE, and the pellet lanes contain the entire immunoprecipitated fraction.

fun12

Genetic interaction between eIF5B and eIF1A. The results thus far indicated that the C terminus of eIF5B was necessary for its ability to interact with eIF1A, for the support of translation in vitro, and for normal growth of yeast cells. There is evidence that the binding of IF1 and IF2 to ribosomes is coupled in bacterial cells and that release of IF2 from 70S ribosomes is dependent on IF1 (5, 18, 31). By analogy, we suggest that release of eIF1A and eIF5B from 80S initiation complexes in eukaryotic cells may also be coupled. If release of eIF1A from the ribosome is dependent on its interaction with eIF5B, then overexpression of eIF1A in yeast cells lacking eIF5B or expressing eIF5B mutants that fail to interact with eIF1A is expected to interfere with completion of 80S initiation complex formation. The TIF11 gene encoding yeast eIF1A was inserted into a high-copy-number plasmid and transformed into fun12 strains that lack eIF5B and carry either an empty vector, a low-copy-number plasmid that expresses wild-type eIF5B, or a high-copy-number plasmid that expresses eIF5B_1-915. The results in Fig. 4 showing that removal of as few as 43 residues from the C terminus of eIF5B disrupts the interaction with eIF1A indicate that eIF5B_1-915 would not bind to eIF1A. As shown previously (11, 25), fun12 strains exhibit a significant slow-growth phenotype (Fig. 7A; compare sectors 1 and 5). Introduction of the high-copy-number TIF11 plasmid, which overexpressed eIF1A ~50-fold (Fig. 6A), slightly exacerbated the slow-growth phenotype of the fun12 strain (Fig. 7A, sector 2 versus sector 1), although this was not easily observed. A more significant exacerbation of the slow-growth phenotype of a fun12 strain was observed when eIF1A was overexpressed under the control of the yeast GAL1 promoter (D. S. Olsen and A. G. Hinnebusch, unpublished observation). Interestingly, overexpression of eIF1A severely exacerbated the slow growth of the strain expressing eIF5B_1-915 (Fig. 7A, sector 4 versus sector 3). Thus, overexpression of eIF1A impaired growth in a strain expressing C-terminally truncated eIF5B_1-915 more than it did in a strain lacking eIF5B entirely. As shown in Fig. 7B and C, overexpression of eIF1A did not exacerbate the slow-growth phenotype of strains mutated in the TIF34 (p39) and PRT1 (p90) subunits of yeast eIF3 (34). The strong exacerbation of the phenotype of fun12(1-915) versus that of fun12 and the lack of any effect in tif34 and prt1 mutants overexpressing eIF1A support our conclusion that eIF5B and eIF1A functionally interact during translation initiation. Moreover, the toxicity associated with overexpression of eIF1A in the eIF5B mutant strains is consistent with the model that release of eIF1A and eIF5B from 80S initiation complexes is coupled.

View larger version (46K): [in this window] [in a new window]   FIG. 7.   Overexpression of eIF1A strongly exacerbates the growth defect of a strain expressing C-terminally truncated eIF5B. (A) fun12 strain J130 was cotransformed with the high-copy-number (H.C.) LEU2 plasmid pDSO23 bearing the TIF11 gene encoding eIF1A (sectors 2, 4, and 6) or the empty vector pRS425 (sectors 1, 3, and 5) and either the low-copy-number URA3 plasmid pC1005 bearing a FUN12 gene encoding FLAG-tagged eIF5B (sectors 5 and 6), the empty vector pRS316 (sectors 1 and 2), or the high-copy-number plasmid pC1008 expressing the FLAG-tagged, C-terminally truncated eIF5B1-915 (sectors 3 and 4). Transformants were streaked on synthetic dextrose (SD) minimal medium and incubated for 5 days at 30°C. (B and C) Overexpression of eIF1A does not exacerbate eIF3 mutant strains. The temperature-sensitive tif34 (H2769; B) and prt1-1 (TP11B-4-1; C) strains were transformed with the high-copy-number TIF11 plasmid pDSO23, the empty vector pRS425, or the low-copy-number TIF34 (eIF3-p39, YCpU-TIF34 [2]) or PRT1 (eIF3-p90, pJA100 [34]) plasmid, as indicated. The transformants were streaked on SD minimal media with essential supplements and incubated for 5 days at 30°C.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Based on a number of in vivo and in vitro assays, we report that eIF5B and eIF1A, the eukaryotic orthologs of the prokaryotic translation factors IF2 and IF1, physically interact. In addition, the growth defects observed in yeast cells expressing altered forms or levels of eIF1A and eIF5B indicate that these factors functionally interact. It should be noted that relatively high concentrations of the purified factors were necessary to detect complex formation in vitro. It is possible that complex formation between eIF5B and eIF1A in vivo is dependent on the binding of the factors to the ribosome or on contributions from other translation initiation factors that may interact with eIF1A and eIF5B. A few previous reports presented suggestive evidence for an interaction between eIF5B and eIF1A. Early purification studies indicated that eIF1A (then referred to as eIF4C) and eIF5B (then referred to as eIF5) copurified through several ammonium sulfate precipitation and ion-exchange chromatography steps (35). The two factors were finally resolved on sucrose density gradients containing 400 mM KCl. It was unclear whether this copurification indicated a physical interaction between the factors or, more simply, similar chemical properties of the two proteins. In light of our data, we interpret the copurification of eIF1A and eIF5B to reflect the physical and functional interaction between these factors.

Early studies examining cross-linking of bacterial translation factors to the ribosome revealed cross-links between IF1 and IF2, indicating that these factors are in close proximity when bound to the ribosome (6). In support of this idea, IF1 binding to the ribosome is stabilized by IF2 (18). In addition, stable binding of an N-terminally truncated form of IF2 containing the GTP-binding and C-terminal domains to the ribosome is dependent on IF1 (31). Finally, IF1 and IF2 were reported to function together to destabilize the binding of peptidyl-tRNAs to the ribosomal P site (22). Taken together, these data indicate that IF1 and IF2 physically and functionally interact on the ribosome. However, a direct interaction between these prokaryotic factors occurring independently of the ribosome has not been reported. We propose that eIF5B and eIF1A physically interact both on and off the ribosome, and we suggest that the ability of the eukaryotic factors to interact off the ribosome serves to increase translational efficiency in eukaryotic cells.

Interestingly, IF1 binding to the ribosome protects some of the same residues in rRNA that are protected upon binding the EF-Tu-GTP-aminoacyl-tRNA complex (28), suggesting that IF1 binds in the ribosomal A site. As the nuclear magnetic resonance structures of IF1 and eIF1A show extensive similarities with the proteins sharing a core antiparallel -barrel (OB-fold) structure (3, 37), it is reasonable to propose a similar A site-binding function for eIF1A. eIF1A has been reported to promote ribosomal subunit dissociation and to stabilize Met-tRNA_i^Met binding to ribosomes (4, 27, 41, 42). More recently, it was reported that eIF1A acts catalytically to stimulate Met-tRNA_i^Met binding to the 40S subunit (9, 10). In accordance with this idea, eIF1A did not stably associate with the 40S subunit in sucrose gradient analyses (4, 10). However, in previous studies using gel filtration chromatography it was reported that eIF1A was present in 40S preinitation complexes (41). Thus, it appears that eIF1A binding to the 40S subunit is weak but perhaps can be stabilized in the presence of additional initiation factors. The association of eIF1A with the 40S subunit is consistent with the finding that eIF1A, together with eIF1, is necessary for proper positioning and stable binding of 48S preinitiation complexes (containing the 40S subunit, eIF2-GTP-Met-tRNA_i^Met, and associated factors) at the AUG codon of an mRNA (32).

The function of IF2 in translation is somewhat better understood than that of IF1. IF2 interacts with fMet-tRNA_i^Met through its C-terminal region (18, 40), and the factor is thought to promote Met-tRNA_i^Met binding to the small ribosomal subunit. In addition, IF2 increases the affinity of IF1 binding to the ribosome (18). The GTPase activity of IF2 is activated upon subunit joining, and it is thought that the GTPase activity is required for proper positioning of fMet-tRNA_i^Met in the ribosomal P site and for release of IF2 from the ribosome (16, 24, 26).

We showed previously that fun12 yeast strains lacking the IF2 ortholog eIF5B had a defect in translation initiation (11). The fact that the slow-growth phenotype of fun12 strains could be partially suppressed by overexpression of tRNA_i^Met (11) suggested that eIF5B resembles bacterial IF2 in promoting the binding of fMet-tRNA_i^Met to the small ribosomal subunit. However, we have not detected Met-tRNA_i^Met binding to yeast or human eIF5B off the ribosome, and the eukaryotic factors do not appear to promote Met-tRNA_i^Met binding to the ribosome (33; S. K. Choi and T. E. Dever, unpublished observations; T. V. Pestova, personal communication). Recently, we reported that eIF5B is required for ribosomal subunit joining (33). We also showed that eIF5B possesses ribosome-dependent GTPase activity and demonstrated that GTP hydrolysis is required for release of eIF5B from 80S ribosomes following subunit joining. Interestingly, release of IF2 following subunit joining in prokaryotes requires IF1 (5), raising the possibility that release of eIF1A and eIF5B will be coupled during subunit joining in eukaryotes. Our observation that overexpression of eIF1A exacerbates the growth defect in strains expressing eIF5B_1-915 (Fig. 7) is consistent with this idea. We propose that one defect in fun12 strains or in strains expressing inactive eIF5B_1-915 is an impaired release of eIF1A during subunit joining. Thus, overexpression of eIF1A would exacerbate this defect and lead to a more severe slow-growth phenotype.

Molecular mimicry by eIF5B and eIF1A in translation initiation? The observation that elongation factor EF-G shows striking structural similarities to the EF-Tu-GTP-Phe-tRNA^Phe complex led to the intriguing idea of molecular mimicry among translation factors and tRNA molecules (29, 30). It has been proposed that a complex of IF1 and IF2 mimics the structure of EF-G (7), with IF1 interacting with domain III of IF2. Our studies on eIF1A and eIF5B map the site of interaction to the C terminus of eIF5B, which corresponds to domain IV of IF2. Thus, our data are not consistent with the proposed model (7) for the IF1-IF2 complex mimicking EF-G. The observations that co-overexpression of IF1 and IF2 in certain E. coli strains slows growth and that in vitro these proteins cooperate to promote dissociation of peptidyl-tRNAs from translating ribosomes are both consistent with the idea that an IF1-IF2 complex can compete with the EF-Tu-GTP-aminoacyl-tRNA complex for binding to the ribosomal A site (22). As IF1 was shown to bind to the ribosomal A site (28), and in view of our data demonstrating that the IF1 and IF2 orthologs in eukaryotes directly interact, we favor the idea that the IF1-IF2 complex, and by extension the eIF1A-eIF5B complex in eukaryotes, binds to the A site and stabilizes or correctly positions Met-tRNA_i^Met binding in the ribosomal P site.