The suil suppressor locus in Saccharomyces cerevisiae encodes a translation factor that functions during tRNA(iMet) recognition of the start codon.

We initiated a genetic reversion analysis at the HIS4 locus to identify components of the translation initiation complex that are important for ribosomal recognition of an initiator codon. Three unlinked suppressor loci, suil, sui2, and SUI3, that restore expression of both HIS4 and HIS4-lacZ in the absence of an AUG initiator codon were identified. In previous studies, it was demonstrated that the sui2 and SUI3 genes encode mutated forms of the alpha and beta subunits, respectively, of eukaryotic translation initiation factor 2 (eIF-2). In this report, we describe the molecular and biochemical characterizations of the sui1 suppressor locus. The DNA sequence of the SUI1+ gene shows that it encodes a protein of 108 amino acids with a calculated Mr of 12,300. The sui1 suppressor genes all contain single base pair changes that alter a single amino acid within this 108-amino-acid sequence. sui1 suppressor strains that are temperature sensitive for growth on enriched medium have altered polysome profiles at the restrictive temperature typical of those caused by alteration of a protein that functions during the translation initiation process. Gene disruption experiments showed that the SUI1+ gene encodes an essential protein, and antibodies directed against the SUI1+ coding region identified a protein with the predicted Mr in a ribosomal salt wash fraction. As observed for sui2 and SUI3 suppression events, protein sequence analysis of His4-beta-galactosidase fusion proteins produced by sui1 suppression events indicated that a UUG codon is used as the site of translation initiation in the absence of an AUG start codon in HIS4. Changing the penultimate proline codon 3' to UUG at his4 to a Phe codon (UUC) blocks aminopeptidase cleavage of the amino-terminal amino acid of the His4-beta-galactosidase protein, as noted by the appearance of Met in the first cycle of the Edman degradation reaction. The appearance of Met in the first cycle, as noted, in either a sui1 or a SUI3 suppressor strain showed that the mechanism of suppression is the same for both suppressor genes and allows the initiator tRNA to mismatch base pair with the UUG codon. This suggests that the Sui1 gene product performs a function similar to that of the beta subunit of eIF-2 as encoded by the SUI3 gene. However, the Sui1 gene product does not appear to be a required subunit of eIF-2 on the basis of purification schemes designed to identify the GTP-dependent binding activity of eIF-2 for the initiator tRNA. In addition, suppressor mutations in the sui1 gene, in contrast to suppressor mutations in the sui2 or SUI3 gene, do not alter the GTP-dependent binding activity of the eIF-2. The simplest interpretation of these studies is that the sui1 suppressor gene defines an additional factor that functions in concert with eIF-2 to enable tRNAiMet to establish ribosomal recognition of an AUG initiator codon.     

Mutations at a Zn(II) finger motif in the yeast eIF-2 beta gene alter ribosomal start-site selection during the scanning process

We have genetically reverted HIS4 initiator codon mutants in yeast and identified three unlinked genes, sui1, sui2, and SUI3 (suppressors of initiator codon mutants), which when mutated confer the ability to initiate at HIS4 despite the absence of an AUG start codon. Molecular and biochemical characterization shows that SUI3 encodes the beta-subunit of the eukaryotic translation initiation factor eIF-2. SUI3 suppressor genes contain single base changes at a Zn(II) finger motif. This motif is present in a cDNA sequence encoding the human eIF-2 beta gene product. Mutations in SUI3 suppressor alleles change amino acids that are conserved in the yeast and human motifs. Protein sequence analysis shows that a mutant beta-subunit allows initiation at a UUG codon in the absence of an AUG start codon at HIS4. Taken together, these data implicate a nucleic acid-binding domain of eIF-2 as an important component of the "scanning" ribosome that participates in recognition of a start codon.     

Genetic selection for mutations that reduce or abolish ribosomal recognition of the HIS4 translational initiator region.

A unique genetic selection was devised at the HIS4 locus to address the mechanism of translation initiation in Saccharomyces cerevisiae and to probe sequence requirements at the normal translational initiator region that might participate in ribosomal recognition of the AUG start codon. The first AUG codon at the 5' end of the HIS4 message serves as the start site for translation, and the -3 and +4 nucleotide positions flanking this AUG (AXXAUGG) correspond to a eucaryotic consensus start region. Despite this similarity, direct selection for mutations that reduce or abolish ribosomal recognition of this region does not provide any insight into the functional nature of flanking nucleotides. The only mutations identified that affected recognition of this region were alterations in the AUG start codon. Among 150 spontaneous isolates, 26 were shown to contain mutations in the AUG start codon, including all +1 changes (CUG, GUG, and UUG), all +3 changes (AUA, AUC, and AUU), and one +2 change (ACG). These seven mutations of the AUG start codon, as well as AAG and AGG constructed in vitro, were assayed for their ability to support HIS4 expression. No codon other than AUG is physiologically relevant to translation initiation at HIS4 as determined by growth tests and quantitated in his4-lacZ fusion strains. These data and analysis of other his4 alleles are consistent with a mechanism of initiation at HIS4 as proposed in the scanning model whereby the first AUG codon nearest the 5' end of the message serves as the start site for translation and points to the AUG codon in S. cerevisiae as an important component for ribosomal recognition of the initiator region.     

SUI1/p16 is required for the activity of eukaryotic translation initiation factor 3 in Saccharomyces cerevisiae.

A genetic reversion analysis at the HIS4 locus in Saccharomyces cerevisiae has identified SUI1 as a component of the translation initiation complex which plays an important role in ribosomal recognition of the initiator codon. SUI1 is an essential protein of 12.3 kDa that is required in vivo for the initiation of protein synthesis. Here we present evidence that SUI1 is identical to the smallest subunit, p16, of eukaryotic translation initiation factor 3 (eIF-3) in S. cerevisiae. SUI1 and eIF3-p16 comigrate upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis and cross-react with anti-SUI1 and anti-eIF3 antisera. Anti-SUI1 antisera immunoprecipitate all of the subunits of eIF3, whereas antisera against the eIF3 complex and the individual PRT1 and GCD10 subunits of eIF3 immunoprecipitate SUI1. Finally, the N-terminal amino acid sequence of a truncated form of eIF3-p16 matches the sequence of SUI1. eIF3 isolated from a sui1(ts) strain at 37 degrees C lacks SUI1 and fails to exhibit eIF3 activity in the in vitro assay for methionyl-puromycin synthesis. A free form of SUI1 separate from the eIF3 complex is found in S. cerevisiae but lacks activity in the in vitro assay. The results, together with prior genetic experiments, indicate that SUI1 is essential for eIF3 activity and functions as part of eIF3 and in concert with eIF2 to promote eIF2-GTP-Met-tRNAi ternary complex recognition of the initiator codon.     

Suppressors of translation initiation defect in hem12 locus of Saccharomyces cerevisiae

A system for the positive selection of transational initiation suppressors in S. cerevisiae has been developed. A mutant with an ATA initiation codon in the HEM12 gene, encoding uroporphyrinogen decarboxylase, was used to select cis- and trans-acting suppressors. These suppressors partially restore growth on nonfermentable carbon sources, such as glycerol, but still allow the accumulation of porphyrins. All extragenic suppressors are mapped to the SUI1 locus, encoding initiation factor eIF1. The effect of the hem12 mutation is also partially reversed by the known SUI3 suppressor encoding the beta subunit of eIF2. In contrast, the sui2 suppressor encoding the a subunit of eIF2 does not affect the hem12 phenotype. The intragenic suppressors are able to restore the translation of hem12 due to the generation of additional, in frame AUG codons upstream of the hem12-14 mutation. Mutational analysis of the HEM12 leader sequence was also performed to determine the role of small open reading frames (uORFs) present upstream of the HEM12 ORF. Studies on the expression of integrated hem12-1/4-lacZ fusion, devoid of all upstream ATGs, indicate a lack of regulatory effect of uORFs on HEM12 translation.     

Mutational analysis of the HIS4 translational initiator region in Saccharomyces cerevisiae.

We have mutated various features of the 5' noncoding region of the HIS4 mRNA in light of established Saccharomyces cerevisiae and mammalian consensus translational initiator regions. Our analysis indicates that insertion mutations that introduce G + C-rich sequences in the leader, particularly those that result in stable stem-loop structures in the 5' noncoding region of the HIS4 message, severely affect translation initiation. Mutations that alter the length of the HIS4 leader from 115 to 39 nucleotides had no effect on expression, and sequence context changes both 5' and 3' to the HIS4 AUG start codon resulted in no more than a twofold decrease of expression. Changing the normal context at HIS4 5'-AAUAAUGG-3' to the optimal sequence context proposed for mammalian initiator regions 5'-CACCAUGG-3' did not result in stimulation of HIS4 expression. These studies, in conjunction with comparative and genetic studies in S. cerevisiae, support a general mechanism of initiation of protein synthesis as proposed by the ribosomal scanning model.     

Functional elements in initiation factors 1, 1A, and 2β discriminate against poor AUG context and non-AUG start codons

Yeast eIF1 inhibits initiation at non-AUG triplets, but it was unknown whether it also discriminates against AUGs in suboptimal context. As in other eukaryotes, the yeast gene encoding eIF1 (SUI1) contains an AUG in poor context, which could underlie translational autoregulation. Previously, eIF1 mutations were identified that increase initiation at UUG codons (Sui(-) phenotype), and we obtained mutations with the opposite phenotype of suppressing UUG initiation (Ssu(-) phenotype). Remarkably, Sui(-) mutations in eukaryotic translation initiation factor 1 (eIF1), eIF1A, and eIF2β all increase SUI1 expression in a manner diminished by introducing the optimal context at the SUI1 AUG, whereas Ssu(-) mutations in eIF1 and eIF1A decrease SUI1 expression with the native, but not optimal, context present. Therefore, discrimination against weak context depends on specific residues in eIFs 1, 1A, and 2β that also impede selection of non-AUGs, suggesting that context nucleotides and AUG act coordinately to stabilize the preinitiation complex. Although eIF1 autoregulates by discriminating against poor context in yeast and mammals, this mechanism does not prevent eIF1 overproduction in yeast, accounting for the hyperaccuracy phenotype afforded by SUI1 overexpression.     

Escherichia coli translation initiation factor 3 discriminates the initiation codon in vivo

In a genetic selection designed to isolate Escherichia coli mutations that increase expression of the IS 10 transposase gene ( tnp ), we unexpectedly obtained viable mutants defective in translation initiation factor 3 (IF3). Several lines of evidence led us to conclude that transposase expression, per se , was not increased. Rather, these mutations appear to increase expression of the tnp'–'lacZ gene fusions used in this screen, by increasing translation initiation at downstream, atypical initiation codons. To test this hypothesis we undertook a systematic analysis of start codon requirements and measured the effects of IF3 mutations on initiation from various start codons. Beginning with an efficient translation initiation site, we varied the AUG start codon to all possible codons that differed from AUG by one nucleotide. These potential start codons fall into distinct classes with regard to translation efficiency in vivo : Class I codons (AUG, GUG, and UUG) support efficient translation; Class IIA codons (CUG, AUU, AUC, AUA, and ACG) support translation at levels only 1–3% that of AUG; and Class IIB codons (AGG and AAG) permit levels of translation too low for reliable quantification. Importantly, the IF3 mutations had no effect on translation from Class I codons, but they increased translation from Class II codons 3–5-fold, and this same effect was seen in other gene contexts. Therefore, IF3 is generally able to discriminate between efficient and inefficient codons in vivo , consistent with earlier in vitro observations. We discuss these observations as they relate to IF3 autoregulation and the mechanism of IF3 function.     

An AUG initiation codon, not codon–anticodon complementarity, is required for the translation of unleadered mRNA in Escherichia coli

We determined the in vivo translational efficiency of 'unleadered' lacZ compared with a conventionally leadered lacZ with and without a Shine–Dalgarno (SD) sequence in Escherichia coli and found that changing the SD sequence of leadered lacZ from the consensus 5'-AGGA-3' to 5'-UUUU-3' results in a 15-fold reduction in translational efficiency; however, removing the leader altogether results in only a twofold reduction. An increase in translation coincident with the removal of the leader lacking a SD sequence suggests the existence of stronger or novel translational signals within the coding sequence in the absence of the leader. We examined, therefore, a change in the translational signals provided by altering the AUG initiation codon to other naturally occurring initiation codons (GUG, UUG, CUG) in the presence and absence of a leader and find that mRNAs lacking leader sequences are dependent upon an AUG initiation codon, whereas leadered mRNAs are not. This suggests that mRNAs lacking leader sequences are either more dependent on perfect codon–anticodon complementarity or require an AUG initiation codon in a sequence-specific manner to form productive initiation complexes. A mutant initiator tRNA with compensating anticodon mutations restored expression of leadered, but not unleadered, mRNAs with UAG start codons, indicating that codon–anticodon complementarity was insufficient for the translation of mRNA lacking leader sequences. These data suggest that a cognate AUG initiation codon specifically serves as a stronger and different translational signal in the absence of an untranslated leader.     

RNA primary sequence or secondary structure in the translational initiation region controls expression of two variant interferon-beta genes in Escherichia coli

Efficient expression in Escherichia coli (E. coli) of the human interferon-beta gene (IFN-beta) gene and of a chemically synthesized IFN-beta gene variant (506 base pairs; synIFN-beta) adapted to the E. coli codon usage, both fused to the E. coli atpE ribosome-binding site, is controlled either by primary sequence or by mRNA secondary-structure in the translational initiation region. High level expression of the natural human atpE/IFN-beta gene fusion is governed by the nucleotide composition preceding the initiator codon AUG. A single U----C exchange in the -2 or -1 position preceding the initiator codon AUG reduces the translational efficiency from 18% of total cellular protein to only 8% or 4%, respectively, while both U----C substitutions reduce IFN-beta expression below 1%. These sequence alterations interfere with efficient ribosome binding as revealed by toeprinting. They provide further evidence for the influence of the anticodon-flanking regions of tRNA(fMet) upon the initiation rate of translation. In contrast, translation of the synthetic variant atpE/synIFN-beta gene fusion is controlled by a moderately stable stem-loop structure (delta G = -4 kcal/mol; 37 degrees C) located within the coding region and overlapping the 30 S ribosomal subunit attachment site. That the stability of the hairpin interferes with the initiation of translation is inferred from site-directed mutagenesis and toeprint analyses. mRNA half-life in these variants is positively correlated with the rate of translation and involves two major endonucleolytic cleavage site 5'-upstream of the Shine-Dalgarno region.     

Control of start codon choice on a plant viral RNA encoding overlapping genes.

The signals that control initiation of translation in plants are not well understood. To dissect some of these signals, we used a plant viral mRNA on which protein synthesis initiates at two out-of-frame start codons. On the large subgenomic RNA (sgRNA1) of barley yellow dwarf virus-PAV serotype, the coat protein (CP) and overlapping 17K open reading frames (ORFs) are translated beginning at the first and second AUG codons, respectively. The roles of bases at positions -3 and +4 relative to the AUG codons in efficiency of translation initiation were investigated by translation of sgRNA1 mutants in a cell-free extract and by expression of a reporter gene from mutant sgRNA1 leaders in protoplasts. The effects of mutations that disrupted and restored secondary structure encompassing the CP AUG independently of, and in combination with, changes to bases -3 and +4 were also examined. Partial digestion of the 5' end of the sgRNA1 leader with structure-sensitive nucleases gave products that were consistent with the predicted secondary structure. Secondary structure had an overall inhibitory effect on translation of both ORFs. In general, the "Kozak rules" of start codon preference predominate in determining start codon choice. Unexpectedly, for a given CP AUG sequence context, changes that decreased initiation at the downstream 17K AUG also reduced initiation at the CP AUG. To explain this observation, we propose a new model in which pausing of the ribosome at the second AUG allows increased initiation at the first AUG. This detailed analysis of the roles of primary and secondary structure in controlling translation initiation should be of value for understanding expression of any plant gene and in the design of artificial constructs.     

Translation of the F protein of hepatitis C virus is initiated at a non-AUG codon in a +1 reading frame relative to the polyprotein

The hepatitis C virus (HCV) genome contains an internal ribosome entry site (IRES) followed by a large open reading frame coding for a polyprotein that is cleaved into 10 proteins. An additional HCV protein, the F protein, was recently suggested to result from a +1 frameshift by a minority of ribosomes that initiated translation at the HCV AUG initiator codon of the polyprotein. In the present study, we reassessed the mechanism accounting for the synthesis of the F protein by measuring the expression in cultured cells of a luciferase reporter gene with an insertion encompassing the IRES plus the beginning of the HCV-coding region preceding the luciferase-coding sequence. The insertion was such that luciferase expression was either in the +1 reading frame relative to the HCV AUG initiator codon, mimicking the expression of the F protein, or in-frame with this AUG, mimicking the expression of the polyprotein. Introduction of a stop codon at various positions in-frame with the AUG initiator codon and substitution of this AUG with UAC inhibited luciferase expression in the 0 reading frame but not in the +1 reading frame, ruling out that the synthesis of the F protein results from a +1 frameshift. Introduction of a stop codon at various positions in the +1 reading frame identified the codon overlapping codon 26 of the polyprotein in the +1 reading frame as the translation start site for the F protein. This codon 26(+1) is either GUG or GCG in the viral variants. Expression of the F protein strongly increased when codon 26(+1) was replaced with AUG, or when its context was mutated into an optimal Kozak context, but was severely decreased in the presence of low concentrations of edeine. These observations are consistent with a Met-tRNA_i-dependent initiation of translation at a non-AUG codon for the synthesis of the F protein.