Context effects and inefficient initiation at non-AUG codons in eucaryotic cell-free translation systems.

The context requirements for recognition of an initiator codon were evaluated in vitro by monitoring the relative use of two AUG codons that were strategically positioned to produce long (pre-chloramphenicol acetyl transferase [CAT]) and short versions of CAT protein. The yield of pre-CAT initiated from the 5'-proximal AUG codon increased, and synthesis of CAT from the second AUG codon decreased, as sequences flanking the first AUG codon increasingly resembled the eucaryotic consensus sequence. Thus, under prescribed conditions, the fidelity of initiation in extracts from animal as well as plant cells closely mimics what has been observed in vivo. Unexpectedly, recognition of an AUG codon in a suboptimal context was higher when the adjacent downstream sequence was capable of assuming a hairpin structure than when the downstream region was unstructured. This finding adds a new, positive dimension to regulation by mRNA secondary structure, which has been recognized previously as a negative regulator of initiation. Translation of pre-CAT from an AUG codon in a weak context was not preferentially inhibited under conditions of mRNA competition. That result is consistent with the scanning model, which predicts that recognition of the AUG codon is a late event that occurs after the competition-sensitive binding of a 40S ribosome-factor complex to the 5' end of mRNA. Initiation at non-AUG codons was evaluated in vitro and in vivo by introducing appropriate mutations in the CAT and preproinsulin genes. GUG was the most efficient of the six alternative initiator codons tested, but GUG in the optimal context for initiation functioned only 3 to 5% as efficiently as AUG. Initiation at non-AUG codons was artifactually enhanced in vitro at supraoptimal concentrations of magnesium.     

Characterization of ribosome binding on Rous sarcoma virus RNA in vitro.

We determined the sites at which ribosomes form initiation complexes on Rous sarcoma virus RNA in order to determine how initiation of Pr76gag synthesis at the fourth AUG codon from the 5' end of Rous sarcoma virus strain SR-A RNA occurs. Ribosomes bind almost exclusively at the 5'-proximal AUG codon when chloride is present as the major anion added to the translational system. However, when chloride is replaced with acetate, ribosomes bind at the two 5'-proximal AUG codons, as well as at the initiation site for Pr76gag. We confirmed that the 5'-proximal AUG codon is part of a functional initiation site by identifying the seven-amino acid peptide encoded there. Our results suggest that (i) translation in vitro of Rous sarcoma virus virion RNA results in the synthesis of at least two polypeptides; (ii) the pattern of ribosome binding observed for Rous sarcoma virus RNA can be accounted for by the modified scanning hypothesis; and (iii) the interaction between 40S ribosomal subunits or 80S ribosomal complexes is stronger at the 5'-proximal AUG codon than at sites farther downstream, including the initiation site for the major viral proteins.     

Translation of insulin-related polypeptides from messenger RNAs with tandemly reiterated copies of the ribosome binding site

Plasmids have been constructed containing reiterated copies of a 66 bp fragment, loosely referred to as the ribosome binding site, that includes the AUG initiator codon of preproinsulin. The extreme test involved plasmid 255/17, which carried four tandem copies of the ribosome binding site, with all four AUG triplets in the same reading frame as the preproinsulin coding sequence downstream. Initiation at any potential start site would generate a polypeptide precipitable with anti-insulin antiserum, and its size would reveal the AUG(s) active in initiation. One insulin-related polypeptide was synthesized in cells transfected by p255/17; its size corresponded to the product initiated at the first ribosome binding site in the tandem array. Inasmuch as the three downstream AUG triplets, which are not used, occur in a sequence context identical with that around the 5'-proximal AUG triplet, which is used, the position of an AUG triplet relative to the 5' end of the mRNA appears to be important in identifying it as a functional initiator codon.     

Nucleotide sequences of the mRNA''s encoding the vesicular stomatitis virus N and NS proteins.

The complete nucleotide sequences of the vesicular stomatitis virus (VSV) mRNA's encoding the N and NS proteins have been determined from the sequences of cDNA clones. The mRNA encoding the N protein is 1,326 nucleotides long, excluding polyadenylic acid. It contains an open reading frame for translation which extends from the 5'-proximal AUG codon to encode a protein of 422 amino acids. The N and mRNA is known to contain a major ribosome binding site at the 5'-proximal AUG codon and two other minor ribosome binding sites. These secondary sites have been located unambiguously at the second and third AUG codons in the N mRNA sequence. Translational initiation at these sites, if it in fact occurs, would result in synthesis of two small proteins in a second reading frame. The VSV and mrna encoding the NS protein is 815 nucleotides long, excluding polyadenylic acid, and encodes a protein of 222 amino acids. The predicted molecular weight of the NS protein (25,110) is approximately one-half of that predicted from the mobility of NS protein on sodium dodecyl sulfate-polyacrylamide gels. Deficiency of sodium dodecyl sulfate binding to a large negatively charged domain in the NS protein could explain this anomalous electrophoretic mobility.     

Identification of a ribosome-binding site for a leader peptide encoded by Rous sarcoma virus RNA.

A new method for identifying ribosome-binding sites was developed to determine whether AUG codons in the 5'-terminal RNA sequence of Rous sarcoma virus were used to initiate protein synthesis. We found that when translation is inhibited, the major ribosome-binding site on Rous sarcoma virus RNA is at the 5'-proximal AUG codon, even though the primary translational product from this RNA, Pr76gag, is encoded behind the fourth AUG codon 331 bases downstream from the observed initiation site. These results suggest that ribosomes can initiate translation on Rous sarcoma virus RNA at more than one site, thereby producing a seven-amino-acid peptide, as well as the gag gene polyprotein precursor of Mr 76,000.     

Selection of initiation sites by eucaryotic ribosomes: effect of inserting AUG triplets upstream from the coding sequence for preproinsulin.

Recombinant plasmids that direct synthesis of rat preproinsulin under the direction of the SV40 early promoter have been used to probe the mechanism of initiation of translation. Insertion of an upstream AUG triplet that was out-of-frame with respect to the coding sequence for preproinsulin reduced the yield of proinsulin, in keeping with the predictions of the scanning model. The extent to which an upstream AUG codon interfered depended on sequences surrounding the AUG triplet; with two constructs ( p255 /20 and C2) the 5'-proximal AUG codon constituted an absolute barrier: there was no initiation at the downstream start site for preproinsulin. With two other constructs ( p255 /9, p255 /21), however, proinsulin was made despite the presence of an upstream, out-of-frame AUG codon in a favorable context for initiation. In those cases the reading frame set by the first AUG triplet was short, terminating before the start of the preproinsulin coding sequence. The interpretation that ribosomes initiate at the first AUG, terminate, and then reinitiate at the AUG that directly precedes the preproinsulin coding sequence was tested by introducing a point mutation that eliminated the terminator codon: the resulting mutant made no proinsulin.     

Identification of the initiation site of poliovirus polyprotein synthesis.

The complete nucleotide sequence of poliovirus RNA has a long open reading frame capable of encoding the precursor polyprotein NCVP00. The first AUG codon in this reading frame is located 743 nucleotides from the 5' end of the RNA and is preceded by eight AUG codons in all three reading frames. Because all proteins that map at the amino terminus of the polyprotein (P1-1a, VP0, and VP4) are blocked at their amino termini and previous studies of ribosome binding have been inconclusive, direct identification of the initiation site of protein synthesis was difficult. We separated and identified all of the tryptic peptides of capsid protein VP4 and correlated these peptides with the amino acid sequence predicted to follow the AUG codon at nucleotide 743. Our data indicate that VP4 begins with a blocked glycine that is encoded immediately after the AUG codon at nucleotide 743. An S1 nuclease analysis of poliovirus mRNA failed to reveal a splice in the 5' region. We concluded that synthesis of the poliovirus polyprotein is initiated at nucleotide 743, the first AUG codon in the long open reading frame.     

Characterization of the internal initiation of translation on the vesicular stomatitis virus phosphoprotein mRNA

Internal initiation of translation on the vesicular stomatitis virus (VSV) phosphoprotein (P) mRNA leads to the synthesis of a second protein [Herman, R. C. (1986) J. Virol. 58, 797-804]. Characterization of this phenomenon shows that initiation at the 5'-proximal and internal AUG codons has different optima for mono- and divalent cations in the reticulocyte lysate. Whereas 5' initiation is stimulated by increasing concentration of K+ over the endogenous level, internal initiation is inhibited. Internal initiation is much less sensitive to the effects of the cap analogue 7mGpppG in both the reticulocyte lysate and the wheat-germ extract under conditions that reduce 5'-proximal initiation to only about 4-5% of the control level. These results imply that 5'-proximal and internal initiations are distinct biochemical processes.     

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.     

Positions +5 and +6 can be major determinants of the efficiency of non-AUG initiation codons for protein synthesis.

Only rarely do GUG (or CUG or ACG) codons which precede the 5'-proximal AUG function as initiators of protein synthesis, even when they are within a context that contains a purine at position -3 and a G at +4. For example, the upstream GUG of the human parainfluenza virus type 1 (hPIV1) P gene is initiated by ribosomes at high frequency, whereas a seemingly similar GUG codon in the hPIV3 P gene is not used at all. We have examined the reasons for this by expressing chimeric hPIV3/hPIV1 mRNAs, both in vivo and in vitro. A major determinant for efficient GUG utilization was located downstream of the GUG, but this did not appear to be involved in the formation of secondary structure. Rather, the sequence immediately downstream was found to be critical; this determinant was mapped to positions +5 and +6. GUG could be used efficiently for ribosomal initiation when the second codon was GAU but not when it was GUA. Similar results were found when other non-AUG start sites, the Sendai virus P gene ACG and the c-myc-1 CUG, were examined. These results suggest that positions +5 and +6 are important determinants for initiation at non-AUG start sites, and that they are recognized independently of the overall secondary structure of the mRNA.     

Analysis of ribosome binding sites from the s1 message of reovirus: Initiation at the first and second AUG codons

Two ribosome-protected initiation sites from the s1 message of reovirus have been characterized. Comparison of these sites with the previously determined sequence of s1 mRNA (Li et al., 1980) reveals that wheat germ ribosomes select and protect the first two AUG triplets in that message. This is unusual, since ribosomes initiate at a single site, the 5′-proximal AUG, in almost all other eukaryotic messenger RNAs that have been examined. The first AUG codon in s1 mRNA is preceded by a pyrimidine in position ?3, thus distinguishing it from most other eukaryotic messages, which have a purine (usually A) in that position. The behavior of s1 mRNA is consistent with the hypothesis that flanking nucleotides modulate the efficiency with which the migrating 40 S ribosomal subunit recognizes an AUG codon as a stop signal. If the first AUG triplet is flanked by suboptimal sequences, as in s1 mRNA, some 40 S ribosomes bypass that site and initiate at the next AUG downstream. The second AUG in the s1 message conforms to the consensus sequence (A-N-N-A-U-G-G) for eukaryotic initiation sites.