Point mutations define a sequence flanking the AUG initiator codon that modulates translation by eukaryotic ribosomes

By analyzing the effects of single base substitutions around the ATG initiator codon in a cloned preproinsulin gene, I have identified ACCATGG as the optimal sequence for initiation by eukaryotic ribosomes. Mutations within that sequence modulate the yield of proinsulin over a 20-fold range. A purine in position -3 (i.e., 3 nucleotides upstream from the ATG codon) has a dominant effect; when a pyrimidine replaces the purine in position -3, translation becomes more sensitive to changes in positions -1, -2, and +4. Single base substitutions around an upstream, out-of-frame ATG codon affect the efficiency with which it acts as a barrier to initiating at the downstream start site for preproinsulin. The optimal sequence for initiation defined by mutagenesis is identical to the consensus sequence that emerged previously from surveys of translational start sites in eukaryotic mRNAs. The mechanism by which nucleotides flanking the ATG codon might exert their effect is discussed.     

Compilation and analysis of sequences upstream from the translational start site in eukaryotic mRNAs.

5-Noncoding sequences have been tabulated for 211 messenger RNAs from higher eukaryotic cells. The 5'-proximal AUG triplet serves as the initiator codon in 95% of the mRNAs examined. The most conspicuous conserved feature is the presence of a purine (most often A) three nucleotides upstream from the AUG initiator codon; only 6 of the mRNAs in the survey have a pyrimidine in that position. There is a predominance of C in positions -1, -2, -4 and -5, just upstream from the initiator codon. The sequence CCAGCCAUG (G) thus emerges as a consensus sequence for eukaryotic initiation sites. The extent to which the ribosome binding site in a given mRNA matches the -1 to -5 consensus sequence varies: more than half of the mRNAs in the tabulation have 3 or 4 nucleotides in common with the CCACC consensus, but only ten mRNAs conform perfectly.     

Possible role of flanking nucleotides in recognition of the AUG initiator codon by eukaryotic ribosomes.

Sequences flanking the initiator codon in eukaryotic mRNAs are not random. Out of 153 messages examined, 151 have either a purine in position -3, or a G in position +4, or both. Thus, [A/G]XXAUGG emerges as the favored sequence for eukaryotic initiation sites. Nucleotides flanking nonfunctional AUG triplets, which occur in the 5'-noncoding region of a few eukaryotic messages, are different from those found at most functional sites. Whereas most authentic initiator codons are preceded by a purine (usually A) in position -3, most nonfunctional AUGs have a pyrimidine in that position. The observed asymmetry suggests that purines in positions -3 and +4 might facilitate recognition of the AUG condon during formation of initiation complexes. To test this idea, in vitro binding studies were carried out with 32P-labeled oligonucleotides. Binding of AUG-containing oligonucleotides to wheat germ ribosomes was significantly enhanced by placing a purine in position -3 or +4. The scanning model, which postulates that 40S ribosomal subunits attach at the 5'-end of a message and migrate down to the AUG codon, is discussed in light of these new observations. A modified version of the scanning mechanism is proposed.     

Quantification analysis of translation initiation signal in vertebrate mRNAs: effect of nucleotides at positions +4(-)+6 upon efficiency of translation initiation.

Concerning the translation initiation signal in vertebrate mRNAs, a consensus, sequence, (GCC)GCC(A or G) CCATGG, has been proposed, but actual initiation sequences differ from it in a greater or lesser degree. Kozak monitored selection by ribosomes of the first versus second ATG codons as a function of mutations introduced at positions +4, and +6 of the first ATG codon. Codons possessing G at +4 strongly enhanced selection of the first ATG codon. However, ATG codon recognition was unaffected by most mutations in positions and +6. These data were well understood by our quantification analysis.     

Strength of translation initiation signal sequence of mRNA as studied by quantification method: effect of nucleotide substitutions upon translation efficiency in rat preproinsulin mRNA.

Concerning the translation initiation signals in vertebrate mRNAs, both the ATG initiation codon and the sequences flanking the initiation codon are required to direct the position of initiation. A consensus sequence for the signal, (GCC)GCC(A or G)CCATGG, has been proposed, but actual initiation sequences differ from it to a greater or lesser degree. In the present report, the translation initiation signal sequences of rat preproinsulin and its mutant mRNAs were analyzed using a quantification method proposed previously. In this method, each 16 nt sequence in the mRNA was characterized by its sample score, which shows strength of the signal. So far, Kozak has constructed a number of preproinsulin mutant mRNAs in which nucleotides flanking the ATG codon are systematically varied, and measured the translation initiation efficiency in terms of the proinsulin product. Her experimental results were well understood on the basis of the strength of the translation initiation signal sequence.     

Sequence Features Surrounding the Translation Initiation Sites Assigned on the Genome Sequence of Synechocystis sp. Strain PCC6803 by Amino-terminal Protein Sequencing

To characterize the sequence features surrounding the translationinitiation sites on the genome of Synechocystis sp. strain 6803,the total proteins extracted from the cell were resolved bytwo-dimensional electrophoresis, and the amino-terminal sequencesof the relatively abundant protein spots were determined. Bycomparison of the determined amino-terminal sequences with thenucleotide sequence of the entire genome, the translation initiationsites of a total of 72 proteins were successfully assigned onthe genome. The sequence features emerged from the nucleotidesequences at and surrounding the translation initiation siteswere as follows: (1) In addition to the three initiation codons,ATG, GTG, and TTG, evidence was obtained that ATT was also usedas a rare initiation codon; (2) the core sequences (GAGG, GGAGand AGGA) of the Shine-Dalgarno sequence were identified inthe appropriate position preceding the 35 initiation sites (48.6%);and (3) the preferential sequence surrounding the initiationcodons was formulated as 5'-YY[· · ·]R-3'where Y and R denote pyrimidine and purine nucleotides, respectively,and three dots represent the initiation codons. The result obtainedwould provide valuable information for improvement of the gene-findingsoftware, and the approach used in this study should be applicablefor comprehensive analysis of the expression profiles of cellularproteins.     

Proteomic analysis of the cyanobacterium Anabaena sp. strain PCC7120 with two-dimensional gel electrophoresis and amino-terminal sequencing

A protein-gene linkage map of the cyanobacterium Anabaena sp. strain PCC7120 was successfully constructed for 123 relatively abundant proteins. The total proteins extracted from the cell were resolved by two-dimensional electrophoresis, and the amino-terminal sequences of the protein spots were determined. By comparing the determined amino-terminal sequences with the entire genome sequence, the putative translation initiation sites of 87 genes were successfully assigned on the genome. The elucidated sequence features surrounding the translation initiation sites were as follows: (1) GTG and TTG in addition to the ATG were used as rare initiation codons; (2) the core sequences (GAGG, GGAG and AGGA) of the Shine-Dalgarno sequence were identified in the appropriate position preceding the 51 initiation sites (58.6%); (3) the nucleotides at the two regions, from -35 to -33, and from -19 to -17 (relative to the first nucleotide in the initiation codon) were preferentially adenines or thymines; (4) the nucleotides at the region from -14 to -8 were preferentially purines; (5) the nucleotide at position -1 was biased towards non-guanine (96.6%); (6) the nucleotide at the position +5 was preferentially cytosine (63.2%). It was evident that removal of the translation initiator methionine was dependent on the side-chain bulkiness of the penultimate amino acid residue. The predicted putative signal peptide sequences were also indicated. Besides confirming the existence of many predicted proteins, the data will serve as a starting point for the study of signals important in post-translational processing and nucleotide sequences important in the initiation of translation.     

Computer analyses of complete genomes suggest that some archaebacteria employ both eukaryotic and eubacterial mechanisms in translation initiation

The translation initiation mechanism of archaebacteria is still not clearly understood. Our previous work showed that ATG triplets before start codons have been strongly depleted in eukaryotic genomes, presumably because ribosome of eukaryotes scans mRNA from the 5' to 3' direction to find proper start codons. Extra ATG triplets before start codons would confuse the process and thus they have been negatively selected in eukaryotic genomes. In eubacterial genomes, on the other hand, ribosome binds to the Shine-Dalgarno (SD) sequence at once without mRNA scanning, and the characteristic patterns of ATG triplet depletion were not observed (Saito, R., Tomita, M., 1999. On negative selection against ATG triplets near start codons in eukaryotic and procaryotic genomes. J. Mol. Evol. 48, 213-217). The ATG triplet analysis on archaebacterial genomes revealed that Methanococcus jannaschii and Pyrococcus horikoshii show patterns similar to eukaryotes, implying that these species employ scanning of mRNA from the 5' to 3' direction in the process of translation initiation. On the other hand, our earlier study found that these archaea have SD-like sequences, which are complementary to the 3' end sequence of 16S rRNA, as in eubacterial translation initiation (Osada, Y., Saito, R., Tomita, M. Analysis of base-pairing potentials between 16S rRNA and 5' UTR for translation initiation in various procaryotes. Bioinformatics, in press). These two results combined lead us to conclude that these archaea probably use a hybrid mechanism; their ribosome scans mRNAs from the 5' to 3' direction and then 16S rRNA binds to the SD-like sequence of the 5' UTR.