INTRODUCTION

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The ability of ribosomes to maintain the correct translational reading frame is fundamental to the integrity of translation and, ultimately, to cell growth and viability. The protein translational machinery has evolved to ensure that the intrinsic error rate of reading frame maintenance is extremely low, with error rates on the order of 1 misreading in 5,000 translational events (14, 30, 41). Although it is essential for protein synthesis to be highly accurate, in the last 10 years, a number of cases of directed ribosomal frameshifting have been reported in viruses, including retroviruses, coronaviruses, the L-A double-stranded RNA (dsRNA) virus and the Ty family of viruses in the yeast Saccharomyces cerevisiae, the dsRNA virus of Giardia lamblia, positive-single-stranded RNA viruses of plants, and bacteriophage T7. The efficiency of ribosomal frameshifting determines the relative ratios of Gag to Gag-Pol fusion protein available for viral particle morphogenesis, and changes in ribosomal frameshift efficiencies have major effects on the ability of cells to propagate viruses which use ribosomal frameshifting (reviewed in reference 13). In addition, programmed frameshifting has been utilized by a number of bacterial transposons, as well as in some bacterial cellular genes and the ornithine decarboxylase antizyme gene in mammals (for reviews, see references 9, 13, 20, and 22).

Frameshifting events in viruses typically produce fusion proteins in which the N- and C-terminal domains are encoded by two distinct, overlapping open reading frames. The two cis-acting mRNA elements that are required to promote 1 ribosomal frameshifting have been well defined. A slippery site, X XXY YYZ (the 0 frame is indicated by the spaces) (26), allows the simultaneous slippage of ribosome-bound A- and P-site tRNAs by one base in the 5' direction (24, 25). A structural element, usually an RNA pseudoknot, is located immediately 3' to the slippery site (6, 14, 39). The mRNA pseudoknot structure makes the ribosome pause over the slippery site and is thought to increase the probability of 5' ribosomal movement (37, 42). These signals can direct elongating ribosomes to shift the reading frame with a frequency of 2 to 10% (reviewed in references 13 and 20). Thus, this naturally occurring molecular mechanism provides a powerful experimental system for probing how the maintenance of a translational reading frame is governed.

The dsRNA L-A virus in the yeast S. cerevisiae has two open reading frames. The 5' gag gene encodes the Gag protein, and the 3' pol gene encodes a multifunctional protein domain required for viral RNA packaging and replication. A 1 ribosomal frameshift event is responsible for the production of the Gag-Pol fusion protein. M₁, a satellite dsRNA virus of L-A which encodes a secreted killer toxin, is encapsidated and replicated by using the gene products synthesized by the L-A virus (reviewed in reference 13). The combination of L-A and M₁ constitutes the yeast "killer" virus system.

We are interested in identifying the trans-acting factors that govern programmed 1 ribosomal frameshifting (16). Screens for mutations that increased the programmed 1 ribosomal frameshift efficiencies in yeast cells identified chromosomal mutations that are called mof (for maintenance of frame; 13, 17, 18) and ifs (increased frameshifting; 29). The screen originally used to identify the mof mutants utilized a construct in which the lacZ gene was inserted downstream of the L-A 1 ribosomal frameshift signal and in the 1 reading frame relative to a translational start site. Recent results demonstrated that mof4-1 is a unique allele of the UPF1 gene, which affects both the nonsense-mediated mRNA decay pathway and programmed 1 frameshifting (11).

Among the mof mutants, strains harboring the mof2-1 allele demonstrated the greatest increase in programmed 1 ribosomal frameshifting efficiency and a temperature-sensitive (ts) cell cycle arrest phenotype (18). In this report, we present the results of the cloning of the wild-type MOF2 gene by complementation of the ts phenotype of mof2-1 strains. mof2-1 is a novel allele of SUI1, a gene previously shown to play a role in translation initiation start site selection (43). The results presented here demonstrate that, in addition to possessing a mutant start site selection phenotype, cells harboring the mof2-1 allele also promote increased efficiency of programmed 1 ribosomal frameshifting and paromomycin sensitivity in yeast cells, indicative of a reduction in translation fidelity. Addition of purified wild-type Mof2p/Sui1p to translationally competent extracts of mof2-1 cells is able to reduce 1 ribosomal frameshifting efficiencies back to wild-type levels, demonstrating that the Sui1/Mof2 protein is actively involved in both the initiation and elongation phases of protein synthesis. Expression of the human homolog of this protein in yeast was able to correct all of the mof2-1 phenotypes, demonstrating that the function of this protein is conserved throughout evolution. These results suggest that Mof2p/Sui1p may function as a general component necessary for translational accuracy.

	MATERIALS AND METHODS

Top Abstract Introduction Materials & Methods Results Discussion References

Strains and media. The strains of S. cerevisiae used in this study are listed in Table 1. YPAD, YPG, SD, synthetic complete medium (35), and 4.7 MB plates for testing the killer phenotype were prepared as previously reported (18). Strains Y218 to Y221 were constructed by plasmid shuffling (35). Briefly, strain JD272 was transformed with plasmids carrying different alleles of the MOF2/SUI1 gene, including wild-type MOF2, mof2-1, sui1-1, and huISOSUI1. The chromosomal copy of the MOF2/SUI1 gene was then deleted and replaced with the hisG-URA3-hisG cassette (1). These strains were subsequently plated on media containing 5-fluoro-orotic acid, and ura mutant strains (mof2::hisG) were isolated.

Molecular and genetic methods. Transformations of yeast and Escherichia coli were performed as described previously (12). Cytoductions and the killer test were performed as previously described (17). Genetic crosses, sporulation tetrad analysis, and -galactosidase activity assays were performed as previously described (11, 18). Testing for drug sensitivity of the various strains was performed as previously described (11). Northern blots for monitoring of the killer viruses were performed as previously described (15).

Plasmid constructions. Plasmids p314-JD85-ter, p315-JD85-ter, p314-JD86-ter, and p315-JD86-ter, used for frameshifting -galactosidase assays, were constructed as described before (11). p314-JD85-ter and p315-JD85-ter are the lacZ gene in the 1 reading frame relative to the initiation AUG and preceded by a 1 ribosomal frameshifting sequence from the L-A virus. p314-JD86-ter and p315-JD86-ter are the lacZ gene in the 0 reading frame relative to the initiation AUG and lacking the 1 ribosomal frameshifting sequence. Plasmids pTI24 and pJD115a, (see Fig. 1B) were described previously (16a, 18a).

mof2

Isolation and characterization of the MOF2 gene. The MOF2 gene was cloned from a pYCp50 yeast genomic library. Strain JD742-9B (mof2-1) was transformed with this library, and transformants were screened by replica plating cells and monitoring their growth at either 24 or 37°C for 5 to 7 days. Colonies that grew at both temperatures were retested, and one strain harboring plasmid p18 was isolated. To confirm that the growth phenotype of the mof2-1 strain harboring the plasmid was a consequence of the plasmid, strains that lost the p18 plasmid were identified on 5-fluoro-orotic acid plates and reverted to a ts phenotype. The p18 plasmid was isolated and retransformed into a mof2-1 strain (35). The p18 plasmid rescued the ts growth phenotype of the mof2-1 strain. Subsequent subcloning and sequencing of the yeast genomic DNA fragment in plasmid p18 were used to identify the sequences from the yeast genome bank (see Fig. 1A). The following subclones, containing various DNA fragments, were based on yeast centromere plasmid pYCplac33 (see restriction map of the yeast genomic DNA fragment in Fig. 1): pYCpSLA2(HB) (2.4-kb HindIII-BglII DNA fragment), pYCpHE3.2 (3.2-kb HindIII-EcoRI DNA fragment), pYCpES0.8 (0.8-kb EcoRI-SalI DNA fragment), pYCpKS1.8 (1.8-kb KpnI-SalI DNA fragment), and pYCpBH1.2 (1.2-kb BglII-HindIII DNA fragment).

Identification of the mof2-1 mutation. A PCR strategy was used to identify the mof2-1 allele by using primers 1 and 2 described above and primer 3 (5'-[EcoRI]-GATTTAAAGAGAATTCTTAAGG-3' [the underlined sequence is an EcoRI site]). Genomic DNA (50 to 100 ng) was prepared (35) from the mof2-1 strain and used as the template in a PCR. Primers 1 and 2 were used to synthesize the 1.2-kb DNA fragment to construct pmof2BH, and primers 2 and 3 were used to synthesize the 0.4-kb DNA fragment to construct pmof2EH. Two PCR products from two different PCRs were used in the cloning reaction to minimize artifacts from the PCR. The PCR conditions used were as follows: 95°C for 5 min, 94°C for 1 min, 45 or 50°C for 1 min, and 72°C for 1.5 min for 25 cycles. The DNA fragments from the PCR were purified from a 1.5% agarose gel and used to replace the corresponding DNA fragment of the wild-type MOF2 gene which was on a YCplac33 vector as described above. Plasmids pmof2BH and pmof2EH were transformed into a mof2-1 strain (JD742-9B, Table 1), and the ts phenotype of the transformants was tested. The sequence of the plasmid that failed to rescue the ts phenotype of the mof2-1 allele was obtained to identify the mutation site. A single point mutation was identified from pmof2BH and pmof2EH. Hence, these two plasmids were both named pYCpmof2-1.

Isolation of the human homolog of the MOF2/SUI1 gene. The human homolog of the MOF2/SUI1 gene (huISOSUI1) was obtained by a PCR approach. The primers used in the PCR were 5'-(BamHI)-AGCCGGATCCACCGAGGAAAAGGAACG-3' and 5'-(SalI)-GGGAAAGTCGACTCATTGCAAGGAAATCC-3' (the underlined sequences are BamHI and SalI sites, respectively). Four different sources of human cDNA libraries were used as templates for the PCRs. The conditions for the PCRs were the same as those described above. The products of the PCRs were purified, restriction enzyme digested, and cloned into low-copy yeast expression vector pG-1. All of the four cDNA library templates produced the same size of DNA fragment, and all were cloned and subjected to the functional tests.

Polysome analysis. Cytoplasmic extracts, prepared as described by Baim et al. (3a), were fractionated on 15 to 50% sucrose gradients buffered with 50 mM Tris-acetate (pH 7.4)-50 mM NH₄Cl-12 mM MgCl₂-1 mM dithiothreitol. Gradients were centrifuged in an SW41 rotor at 40,000 rpm for 135 min at 4°C, fractionated, and analyzed by continuous monitoring of A₂₅₄ (33a).

Purification of the Sui1p/Mof2p. The MOF2/SUI1 allele was FLAG tagged at its N terminus and expressed in E. coli cells. E. coli cells harboring FLAG-tagged MOF2/SUI1 were grown at 20°C, and FLAG-Mof2p/Sui1p expression was induced by addition of 1 mM isopropyl--D-thiogalactopyranoside (IPTG). A cytoplasmic extract was prepared and loaded onto a FLAG monoclonal antibody column. Fractions eluted from the column by either the FLAG peptide or glycine were analyzed by sodium dodecyl sulfate (SDS)-14% polyacrylamide gel electrophoresis (PAGE) and either stained with Coomassie blue or immunoblotted with an anti-FLAG monoclonal antibody. The function of purified wild-type Mof2p was tested in an in vitro translation system as described below.

In vitro frameshifting assay. Plasmids pT7-LUC0 and pT7-LUC-1 were linearized with DraI, and a synthetic transcript containing a 7-Methyl-Gppp cap and a poly(A) tail was made by using T7 RNA polymerase and a MessageMachine kit (Ambion). The translation-competent yeast cell extracts were prepared from strains Y218 (wild type) and Y219 (mof2-1), as described by Tarun and Sachs (38), as follows. A yeast S30 cell extract was subjected to Sephadex G-25 superfine chromatography to remove low-molecular-weight translation inhibitors, and the peak void volume fractions were collected and pooled. The endogenous mRNAs were removed from the fractions by treatment with micrococcal nuclease. The in vitro frameshifting reaction mixture contained translation buffer (22 mM HEPES-KOH [pH 7.4], 120 mM potassium acetate, 2 mM magnesium acetate, 0.75 mM ATP, 0.1 mM GTP, 25 mM creatine phosphate, 0.04 mM amino acids, 1.7 mM dithiothreitol), 0.27-mg/ml creatine phosphate kinase, 0.07 mM methionine, 0.07-U/ml RNasin, 1.3-ng/ml mRNA (LUC0 or LUC-1 mRNA), and 70 µg of cell extract. The reactions were performed at 26°C for 1 h, stopped on dry ice, and thawed on ice, and luciferase activities were determined with a Turner 20/20 luminometer. The activity observed after addition of the frameshifting signal-containing LUC mRNA (LUC-1) was normalized to that of the 0-frame control (LUC0) and used to gauge frameshifting efficiencies in these cell extracts. We added 0, 40, 76, or 112 ng of purified Mof2 protein or an equal amount of protein storage buffer or 100 ng of bovine serum albumin (BSA) to the in vitro translation reaction mixtures, and the frameshifting efficiencies were calculated as described above. The functional half-lives of the transcripts (LUC-1 and LUC0) in the in vitro translation system in an individual cell extract, determined by measuring the luciferase activities at different time points after the reaction started, were approximately 40 min.

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Isolation of the MOF2 gene. A YCp50 yeast genomic library was used to clone the wild-type MOF2 gene by complementation of the ts growth phenotype of a mof2-1 strain. Plasmid p18 enabled a mof2-1 strain to grow at 37°C (Fig. 1A). Sequence data obtained from the insert of plasmid p18 confirmed that it harbors the complete SUI1 gene, whose product was shown to be involved in translation start codon selection (43), and all but the 3'-terminal portion of the SLA2 gene, which encodes a membrane cytoskeleton assembly protein (23; Fig. 1A). Further subcloning of this DNA fragment demonstrated that only plasmids containing the wild-type SUI1 gene complemented the ts growth phenotype of mof2-1 cells (Fig. 1A). Following sporulation and dissection of diploids resulting from a cross of ts mof2-1 and sui1-1 strains, analysis of 20 four-spore tetrads demonstrated that all four spores were ts, confirming that mof2-1 and sui1-1 map to the same genetic locus (data not shown).

View larger version (42K): [in this window] [in a new window]   FIG. 1.   Molecular cloning of the MOF2 gene, characterization of the human homolog, and identification of the mof2-1 lesion. (A) At the top is a schematic representation of the 4.0-kb insert isolated from the YCp50 plasmid library (p18). Below are the locations of the SUI1 and SLA2 coding sequences. The open reading frame of SUI1 is indicated as an arrow and a shaded box within the 1.23-kb fragment. The subclones of plasmid p18 (left) and their effects on growth, 1 ribosomal frameshifting efficiency, and the M1 killer phenotype are shown on the right. ND, not done. (B) The elevated -galactosidase activities observed in a mof2-1 strain were a result of elevated programmed 1 frameshifting efficiencies. The 0-frame reporter plasmid (pTI25), the programmed 1 frameshift reporter plasmid (pF8), the frameshift suppression reporter plasmid (pTI24), and the nonsense suppression plasmid (pJD115a) were transformed into either wild-type mof2-1 strains, and the -galactosidase activities were monitored. The ratio of the tester plasmids (pTI24 and pJD115a) to the 0-frame control (pTI125) was determined, and the results are presented as percent pTI25). (C) The human homolog of the MOF2/SUI1 gene was obtained from a human cDNA library and cloned into the pG-1 vector harboring the yeast glyceraldehyde-3-phosphate dehydrogenase (GPD) promoter and phosphatidylglycerol kinase 1 (PGK1) terminator sequences. Functional complementation tests were performed in a mof2-1 strain. (D) Sequence alignment of human, mosquito, rice, yeast, and Methanococcus (methanol) Sui1p/Mof2p homologs. The conserved amino acids are in uppercase. The mutation site of the mof2-1 allele was determined by a PCR strategy described in Materials and Methods. It is localized in the C terminus of the protein coding region and changes Gly105 to Arg. The mutation sites of the sui1 alleles are also shown (43).

Characterization of the MOF2/SUI1 gene. The effects of expressing the MOF2/SUI1 gene in mof2-1 cells on programmed 1 frameshifting and M₁ viral maintenance were monitored. Programmed 1 ribosomal frameshifting efficiency was determined in the mof2-1 strains harboring subclones of plasmid p18. Cells were transformed with either a plasmid that contains the lacZ coding region inserted downstream of a programmed 1 ribosomal frameshifting signal from the yeast L-A virus and in the 1 reading frame relative to a translational start site (1 frameshift reporter) or a control plasmid containing the lacZ gene that lacks the frameshifting signal insertion and is in the 0 reading frame relative to the translational start codon (0-frame control; 14). The efficiencies of 1 ribosomal frameshifting were calculated by determining the ratio of the -galactosidase activities in cells harboring the 1 frameshift reporter plasmid to activities from cells harboring the 0-frame control plasmid (11, 14). The programmed 1 ribosomal frameshifting efficiency was approximately 10% in a mof2-1 strain harboring only the YCplac33 vector or subclones lacking the entire MOF2/SUI1 gene (Fig. 1A, plasmids pYCpES0.8 and pYCpHE3.2). Programmed 1 ribosomal frameshifting efficiencies, however, decreased to approximately 2% in a mof2-1 strain harboring the wild-type MOF2/SUI1 gene. These levels are equivalent to those observed in wild-type cells (Fig. 1A, plasmids p18, pYCpBH1.2, and pYCpKS1.8).

The human homolog of the MOF2/SUI1 gene functions in yeast. A human homolog of the MOF2/SUI1 gene product (huISOSUI1) has recently been identified by assembling expressed sequence tags (21). Several polypeptide fragments sequenced from rabbit reticulocyte eucaryotic initiation factor 1 (eIF-1) were shown to be similar to yeast Sui1p and huISOSUI1 (27). Sequence alignment of the yeast, rice, mosquito, Methanococcus, and human Sui1 proteins shows high levels of amino acid sequence similarity, suggesting that the gene for Sui1 has been well conserved throughout a wide range of organisms and during evolution (21; Fig. 1D).

mof2/sui1

mof2/sui1

Identification and characterization of the mof2-1 lesion in the SUI1 gene. The mutation responsible for the mof2-1 allele was determined by PCR cloning as described previously (11). DNA fragments containing different regions of the MOF2/SUI1 gene were isolated by PCR from the genomic DNA of mof2-1 cells, cloned into a yeast shuttle vector, and transformed into mof2-1 cells (11; see Materials and Methods). The DNA fragment containing the mutation was identified by determining which fragment of the MOF2/SUI1 gene failed to complement the mof2-1 ts growth phenotype. The mof2-1 mutation is near the carboxyl terminus of the protein, converting highly conserved Gly₁₀₅ to Arg (Fig. 1D). As described below, this mutation was confirmed to be responsible for all of the mof2-1 defects. Interestingly, both the mof2-1 and sui alleles were identified in screens that monitored translational fidelity (18, 43). The mutations that affect either translation initiation (sui1 alleles) or programmed 1 frameshifting (mof2-1 allele) are both located very near the carboxyl terminus of the protein in highly conserved amino acids Asp₈₁ and Gln₈₂ within the context LQGDQR (sui1 alleles) (21, 43) or Gly₁₀₅ (mof2-1 allele) within the conserved HGF motif, indicating a potential functional domain in this region.

Strains harboring the mof2-1 allele allow translation initiation at a non-AUG codon. Strains harboring the previously identified sui1 alleles allow translation to begin at a UUG codon in the absence of an AUG start codon (8, 43). We examined whether a strain harboring the mof2-1 allele was also able to initiate translation at a UUG codon by using a set of isogenic strains constructed to eliminate possible differences in the genetic background for the sui1-1 and mof2-1 alleles. Since the MOF2/SUI1 gene is essential for cell survival, the isogenic mof2-1, sui1-1, and wild-type (MOF2⁺/SUI1⁺) strains were constructed by plasmid shuffling (35). Wild-type, sui1-1 or mof2-1 alleles on centromere-based plasmids were introduced into a wild-type strain (JD272) to support cell viability when the MOF2/SUI1 gene was deleted from the chromosome (see Materials and Methods). mof2/sui1 strains carrying either the plasmid-borne sui1-1 or mof2-1 allele were ts for growth, indicating that the plasmid-borne mutant alleles function analogously to their chromosomal counterparts. The strain containing the wild-type MOF2/SUI1 gene was able to grow at both 24 and 37°C.

The mof2-1 allele of SUI1, but not the sui2-1 or SUI3-3 allele, affects programmed ribosomal frameshifting. Since mutations in the MOF2/SUI1 gene affect programmed 1 ribosomal frameshifting, we investigated the possibility that these effects are solely attributable to translation initiation defects. Strains harboring sui2 and SUI3 alleles have the same levels of translation initiation at a UUG codon as those with sui1 alleles, as monitored by using the his4-UUG-lacZ reporter construct (8). Therefore, we asked whether the strains harboring the sui alleles affect programmed 1 ribosomal frameshifting as well. The 1 ribosomal frameshifting reporter constructs were introduced into wild-type, mof2-1, sui1-1, sui2-1, and SUI3-3 strains to determine the effect of these mutations on 1 ribosomal frameshifting efficiency. The results of these experiments indicated that the 1 programmed frameshifting efficiencies in wild-type or mof2-1 cells were 2.3 and 8.5%, respectively, consistent with the results observed previously (Fig. 1A). The sui1-1 allele increased programmed 1 ribosomal frameshifting approximately twofold (Table 4). Although sui2-1 and SUI3-3 have the same or even higher levels of translation initiation at a UUG codon than sui1-1 or mof2-1 (8), these alleles did not affect the efficiency of programmed 1 ribosomal frameshifting significantly (Table 4).

The mof2-1 and sui1-1 mutants do not affect +1 ribosomal frameshifting. The results described above indicate that programmed 1 ribosomal frameshifting is affected in mof2-1 cells. We next determined whether +1 programmed ribosomal frameshifting is also affected by this mutation. Isogenic wild-type (MOF2⁺/SUI1⁺), sui1-1, and mof2-1 strains were transformed with a +1 frameshifting reporter construct which harbors the lacZ reporter gene inserted downstream of a programmed +1 frameshifting signal from the yeast Ty1 retrotransposable element in the +1 reading frame relative to the translational start site (4). The efficiencies of +1 ribosomal frameshifting were measured by determining the ratio of the -galactosidase activities in cells harboring the +1 frameshift reporter plasmid to the activities in cells harboring the 0-frame control plasmid. The results demonstrated that the +1 frameshifting efficiencies in mof2-1, sui1-1, and wild-type cells were all the same (Table 2), indicating that the increased frameshifting efficiency in mof2-1 cells is specific for 1 programmed ribosomal frameshifting rather than a consequence of a general defect in translational fidelity.

The mof2-1 strain is sensitive to paromomycin. Strains harboring mutations that lower translational fidelity have been shown to be hypersensitive to the aminoglycoside antibiotic paromomycin, a drug that is thought to increase the frequency of misreading in yeast (33, 36). The paromomycin sensitivities of the isogenic mof2-1, sui1-1, and wild-type strains were tested. As shown in Fig. 2, drug sensitivity can be monitored by determining the size of the zone of growth inhibition around a drug-containing disc on a lawn of cells. The results demonstrated that mof2-1 cells were more sensitive to paromomycin than were sui1-1 cells. Interestingly, sui1-1 cells had an intermediate level of sensitivity to the drug. This result mirrors our observation that although a mof2-1 strain shows the highest increases in 1 ribosomal frameshifting efficiency, programmed 1 ribosomal frameshifting efficiencies were slightly increased in a sui1-1 strain compared to wild-type cells. Increased paromomycin sensitivity is also consistent with our previous findings which showed cells with the mof4-1 allele of the UPF1 gene to be paromomycin sensitive (11). Thus, the paromomycin sensitivities of mof2-1 and sui1-1 cells further support the possible role of Mof2p/Sui1p in controlling translational fidelity.

View larger version (49K): [in this window] [in a new window]   FIG. 2.   Drug sensitivity tests of isogenic MOF2/SUI1 strains. Cells were grown in C-Trp medium to mid-log phase and diluted to an optical density at 600 nm of 0.4 to 0.5, and a 300-µl volume of cells was spread on the C-Trp plates. A disc containing 2.5 mg of paromomycin was placed on the plate, and the ring of cell growth inhibition around the disc was measured after incubation at 24°C for 4 to 5 days. These experiments were repeated with at least two independent colonies and performed with different concentrations of drugs. WT, wild type.

Strains harboring the mof2-1 allele do not demonstrate a polysome defect. The results described above indicated that the basal levels of -galactosidase expression from HIS4-AUG-lacZ were similar in wild-type and mof2-1 cells, indicating that there were no significant translation initiation defects in the mof2-1 strain (Table 3). To confirm and extend this result, we analyzed the polysomes found in wild-type and mof2-1 cells. Extracts from wild-type and mof2-1 cells were prepared, and polysomes were analyzed on sucrose gradients (see Materials and Methods). The results are shown in Fig. 3. Comparison of the polysome profiles of wild-type and mof2-1 cells demonstrated no dramatic polysome defect (Fig. 3).

View larger version (13K): [in this window] [in a new window]   FIG. 3.   Analysis of polysome profiles from wild-type and mof2-1 cells. Wild-type (MOF2+) and mof2-1 cells were grown and harvested, and cytoplasmic extracts were prepared and fractionated on sucrose gradients as described in Materials and Methods. The A254s indicating the polysome profiles of wild-type and mof2-1 cells are shown.

The defect in 1 ribosomal frameshifting in mof2-1 cells can be recapitulated in an in vitro translation system. To investigate whether Mof2p is directly involved in modulating programmed 1 ribosomal frameshifting, translationally competent yeast cell extracts from wild-type and mof2-1 strains lacking the killer virus were prepared (Materials and Methods; 38). Capped and polyadenylated transcripts containing the luciferase protein coding region either lacking (0-frame control, pT7-LUC0; Fig. 4A) or containing the L-A 1 ribosomal frameshift signal (1 frameshift reporter, pT7-LUC-1; Fig. 4A) were synthesized in vitro (see Materials and Methods). These mRNAs were added to the translation extract, and the amount of luciferase synthesized was determined by a luciferase activity assay (Fig. 4B). Programmed 1 ribosomal frameshifting efficiencies were monitored in vitro by determining the ratio of luciferase activity from the 1 frameshift reporter transcript (pT7-LUC-1) to that from the 0-frame control mRNA (pT7-LUC0). Consistent with the results observed in vivo, extracts prepared from wild-type cells promoted a 1 ribosomal frameshifting efficiency of 2.3% and extracts prepared from a mof2-1 strain had a 1 ribosomal frameshifting efficiency of 9.3% (Fig. 4B). Thus, the increased 1 ribosomal frameshifting observed in strains harboring the mof2-1 allele can be recapitulated in an in vitro translation system. The increase in programmed ribosomal frameshifting was not a consequence of stabilizing the reporter transcripts in these extracts, since the functional half-lives of the pT7-LUC0 and pT7-LUC-1 transcripts were the same in reaction mixtures containing either wild-type or mof2-1 cell extracts (data not shown).

View larger version (17K): [in this window] [in a new window]   FIG. 4.   In vitro frameshifting assay with yeast cell extracts. (A) The capped and polyadenylated in vitro-synthesized transcripts, used for in vitro translation reactions, shown contain the luciferase protein coding region either lacking (0-frame control [LUC0]) or containing (LUC-1) a 1 ribosomal frameshift (RFS) site. (B) Equal amounts (20 ng) of RNA were added to the in vitro translation system with an individual cell extract. The level of protein expression was measured by a luciferase assay, and the efficiency of 1 frameshifting was determined by the ratio of luciferase activity from LUC-1 to that from LUC0. The values shown are averages of at least three independent experiments done in triplicate. WT, wild type.

Purified Mof2p restores wild-type levels of ribosomal frameshifting in extracts prepared from mof2-1 cells. We next examined whether purified Mof2p/Sui1p can correct the programmed 1 ribosomal frameshifting defect in an extract prepared from a mof2-1 strain. The FLAG-MOF2/SUI1 allele, which harbors an epitope tag at the amino terminus of its protein coding region, was constructed and utilized to detect and purify Mof2p/Sui1p. Cells harboring the FLAG-MOF2/SUI1 allele had the same growth and frameshifting phenotypes as cells harboring the wild-type MOF2/SUI1 gene (data not shown). FLAG-MOF2/SUI1 was expressed in E. coli, and cytoplasmic extracts were prepared and applied to an anti-FLAG immunoaffinity chromatography column. Mof2p/Sui1p was subsequently eluted from the antibody column with the FLAG peptide. As shown in the Coomassie blue-stained SDS-PAGE gel in Fig. 5A, fractions eluted from the antibody column by the FLAG peptide contained a single band with an apparent molecular mass of approximately 17 kDa, consistent with previous reports that Sui1p is 16 kDa (32). Furthermore, proteins in the FLAG peptide-eluted fractions were able to react with the anti-FLAG antibody, as detected by immunoblotting (Fig. 5B), indicating that the purified protein was encoded by the FLAG-MOF2/SUI1 allele. Increasing amounts of purified Mof2p/Sui1p were added to the in vitro translation reaction mixtures and programmed 1 ribosomal frameshifting efficiency was determined as described above (Fig. 5C). The results demonstrate that exogenously added Mof2p/Sui1p can reduce the efficiency of programmed 1 ribosomal frameshifting in extracts of mof2-1 cells to the level observed in extracts of wild-type cells (Fig. 5C). As a control, experiments were performed in which 200 ng of BSA was added as a nonspecific control. The results demonstrated that addition of BSA to the reactions did not reduce programmed 1 frameshift efficiencies in a mof2 extract (data not shown). The added Sui1p/Mof2p had no apparent effect on the efficiency of frameshifting in a wild-type cell extract (Fig. 5C). These results strongly suggest that Mof2p/Sui1p is directly involved in regulating the efficiency of programmed 1 ribosomal frameshifting.

View larger version (65K): [in this window] [in a new window]   FIG. 5.   Purification of Mof2p and in vitro frameshifting assay. (A and B) A cytoplasmic extract of E. coli cells expressing FLAG-MOF2/SUI1 was prepared and loaded onto a FLAG monoclonal antibody column. Fractions eluted from the column were separated by SDS-PAGE and monitored by staining with Coomassie blue (A) or immunoblotting with an anti-FLAG monoclonal antibody (B). (C) In vitro frameshifting assay using yeast cell extracts and purified FLAG-Mof2/Sui1 protein. In vitro translation extracts and reactions were prepared as described by Tarun and Sachs (38), with strains Y218 (wild type [WT]) and Y219 (mof2-1 in Y218). Capped and polyadenylated mRNA (LUC-1 and LUC0) were used to program the in vitro translation reactions by using either the wild-type or mof2-1 extract. Zero, 40, 76, or 112 ng of purified Mof2 protein was added to the in vitro translation reaction mixtures (from left to right), and the frameshifting efficiency is defined as the ratio (percentage) of luciferase activity produced from the 1 ribosomal frameshift mRNA (LUC-1) to the luciferase activity produced from the 0-frame control (LUC0). The luciferase activity from the 0-frame control from extracts prepared from either wild-type or mof2 cells was varied between 20 and 30 U. Reactions were prepared in triplicate, and the values shown are averages of two sets of independent experiments. The standard deviations from these experiments are shown. The values to the left of A and B are molecular sizes in kilodaltons.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

We previously identified a set of yeast chromosomal mutants having increased efficiencies of programmed 1 ribosomal frameshifting. We have been characterizing these trans-acting factors to elucidate the role of the protein synthetic machinery in this posttranscriptional regulatory mechanism. In this study, we isolated the MOF2 gene and showed that it is isogenic with SUI1. Sui1p was previously shown to be important in start site selection in translation initiation (43). Our studies on the mof2-1 allele of the SUI1 gene indicate that it is also required to help maintain the appropriate reading frame during the elongation phase of translation. Based on these observations, we hypothesize that Mof2p/Sui1p is a pivotal protein involved in the accuracy of both the initiation and elongation phases of the translation program. The role of the MOF2/SUI1 gene product is probably not unique to yeast, since a human homolog of this gene has been identified and can function in yeast cells. Each of these points will be discussed below.

The human Sui1p homolog, eIF-1, functions in yeast cells to modulate programmed 1 ribosomal frameshifting. The wild-type MOF2 gene was shown to be allelic to SUI1 (Fig. 1). A human homolog of Sui1p/Mof2p, called huISOSUI1 (eIF-1), has recently been identified. huISOSUI1 shares 60% identity and 80% similarity with Mof2p/Sui1p (Fig. 1D) (21). eIF-1 is one of the smallest translation initiation factors defined with an in vitro translation system (40). In vitro studies have shown that eIF-1 stimulates tRNA or mRNA binding to the 40S ribosomal subunit and the 80S ribosomal complex (40). We have shown that the huISOSUI1-encoding gene suppressed the effects of the mof2-1 mutation. A mof2-1 strain harboring the huISOSUI1-encoding gene was viable at 37°C, showed an efficiency of programmed 1 frameshifting equivalent to that of wild-type MOF2/SUI1 cells, and was able to maintain the M₁ killer virus (Fig. 1B and Table 2). Taken together, these results demonstrate that the SUI1/MOF2 gene is conserved between mammalian and yeast cells. Thus, understanding the mechanism of how this conserved protein functions to monitor the translational process in yeast will aid our understanding of the underlying mechanisms governing translation in mammalian systems.

Mof2p/Sui1p is a general monitor of translational fidelity. The mof2-1 allele resulted in elevated 1 ribosomal frameshifting efficiency (Table 2), loss of the M₁ killer virus (Table 2), greater paromomycin sensitivity (Fig. 2), and altered translation initiation codon selection (Table 3). Isolation of the wild-type MOF2 gene demonstrated that it is identical to the previously isolated SUI1 gene. The sui mutants (i.e., sui1, sui2, and SUI3) were originally identified as mutations that allowed an initiator Met-tRNA_i^Met to mismatch base pair with a UUG codon in the absence of an AUG initiator codon (43). The SUI2 and SUI3 genes were shown to encode yeast translation initiation factors eIF-2 and eIF-2, respectively (10, 19). The SUI1 gene product is not part of the eIF-2 complex (43). Recent results have demonstrated that 30% of Sui1p is associated with the eIF-3 complex (32). eIF-3 is thought to stabilize the eIF-2-GTP-Met-tRNA_i^Met complex on the 40S ribosomal subunit and prevent 60S ribosomal subunit joining (31). However, 70% of Sui1p is not associated with eIF-3 and thus may function independently (3).

How is Sui1p/Mof2p involved in monitoring the fidelity of multiple steps in translation? Appropriate recognition of RNA signals is necessary for proper regulation of RNA-mediated posttranscriptional events. Altered recognition of RNA signals can lead to inappropriate regulation of gene expression. Mutations in the MOF2/SUI1 gene allow initiation of translation at non-AUG codons and also reduce a very specific aspect of fidelity during translation elongation. We hypothesize that Mof2p/Sui1p is a key component of a complex that is required to monitor translational fidelity and that mutations in the MOF2/SUI1 gene alter this process by reducing translational fidelity at the level of codon-anticodon recognition.