Scanning independent ribosomal initiation of the Sendai virus Y proteins in vitro and in vivo.

The Sendai virus P/C mRNA contains five ribosomal initiation sites between positions 81 and 201 from the 5' end. One of these sites initiates in the P open reading frame (ORF) (ATG/104), whereas four initiate in the C ORF (ACG/81 and ATGs/114, 183, 201), to give a nested set of C proteins (C', C, Y1, Y2). Introduction of new ATGs or physically breaking the mRNA upstream of these natural sites was used in vitro to prevent ribosomal scanning downstream. The results suggest that a minority of the ribosomes which initiate C (ATG/114) and all of those which initiate Y1 and Y2 (ATGs/183 and 201) do so by a scanning independent mechanism. When the leaky ACG/81 site is changed to a non-leaky ATG site in in vivo experiments, ribosomal initiation at Y is again not diminished, whereas that at C as well as at P becomes undetectable. Ribosomal initiation at Y appears to be scanning independent in vitro and in vivo. That at C is partly independent in vitro, but completely dependent in vivo. These results are discussed in terms of a model of internal initiation at Y.     

Ribosomal initiation from an ACG codon in the Sendai virus P/C mRNA.

The Sendai virus P/C mRNA expresses the P and C proteins from alternate reading frames. The C reading frame of this mRNA, however, is responsible for three proteins, C', C and Y, none of which appear to be precursors to each other in vivo. Using site-directed and deletion mutagenesis of the P/C gene cloned in SP6 and in vitro translation of the mRNAs, we show that the 5' most proximal initiation codon of the mRNA is an ACG at position 81, responsible for C' synthesis. The succeeding initiation codons, all ATGs, are responsible for the P protein (position 104), the C protein (position 114) and the Y protein(s) (either positions 183 or 201). Examination of the relative molar amounts of the C', P and C proteins found in vivo suggests that an ACG in an otherwise favorable context is almost as efficient for ribosome initiation as an ATG in a less favored context, but only 10-20% as efficient as an ATG in a more favored context. The judicious choice of increasingly more favorable initiation codons in the P/C gene allows multiple proteins to be made from a single mRNA.     

Identification of a cis-acting element required for shunt-mediated translational initiation of the Sendai virus Y proteins

Shunting is a mechanism that permits translational initiation at internal codons positioned in proximity to a ribosome acceptor sequence. Sendai virus exploits shunting to express a series of proteins that initiate at the fourth and fifth start sites on the P/C mRNA (namely, the Y1 and Y2 proteins, respectively). Shunt-mediated initiation at these sites is codon independent. In an attempt to characterise the acceptor site, an extensive deletion analysis was performed spanning the entire C ORF. Only mutants flanking the Y1/Y2 start sites exhibited altered shunt phenotypes. Some of these significantly enhanced shunting efficiency to the point where the Y1/Y2 proteins were the major translational products of the mRNA. Additionally, removal of a short region just downstream of the Y2 start codon (referred to as Δ10) ablated all Y protein initiation via shunting but had no effect on Y expression when the AUG codons were viewed by a scanning ribosome. Point mutations introduced into this Δ10 sequence severely perturbed shunt-mediated initiation. We also provide evidence that changes in this region of the P/C mRNA may be used to modulate Y protein expression levels in different viral strains.     

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.     

Initiation of translation can occur only in a restricted region of the CYC1 mRNA of Saccharomyces cerevisiae.

The steady-state levels and half-lives of CYC1 mRNAs were estimated in a series of mutant strains of Saccharomyces cerevisiae containing (i) TAA nonsense codons, (ii) ATG initiator codons, or (iii) the sequence ATA ATG ACT TAA (denoted ATG-TAA) at various positions along the CYC1 gene, which encodes iso-1-cytochrome c. These mutational alterations were made in backgrounds lacking all internal in-frame and out-of-frame ATG triplets or containing only one ATG initiator codon at the normal position. The results revealed a "sensitive" region encompassing approximately the first half of the CYC1 mRNA, in which nonsense codons caused Upf1-dependent degradation. This result and the stability of CYC1 mRNAs lacking all ATG triplets, as well as other results, suggested that degradation occurs unless elements associated with this sensitive region are covered with 80S ribosomes, 40S ribosomal subunits, or ribonucleoprotein particle proteins. While elongation by 80S ribosomes could be prematurely terminated by TAA codons, the scanning of 40S ribosomal units could not be terminated solely by TAA codons but could be disrupted by the ATG-TAA sequence, which caused the formation and subsequent prompt release of 80S ribosomes. The ATG-TAA sequence caused degradation of the CYC1 mRNA only when it was in the region spanning nucleotide positions -27 to +37 but not in the remaining 3' distal region, suggesting that translation could initiate only in this restricted initiation region. CYC1 mRNA distribution on polyribosomes confirmed that only ATG codons within the initiation region were translated at high efficiency. This initiation region was not entirely dependent on the distance from the 5' cap site and was not obviously dependent on the short-range secondary structure but may simply reflect an open structural requirement for initiation of translation of the CYC1 mRNA.     

Non-AUG initiation of AGAMOUS mRNA translation in Arabidopsis thaliana

The MADS box organ identity gene AGAMOUS (AG) controls several steps during Arabidopsis thaliana flower development. AG cDNA contains an open reading frame that lacks an ATG triplet to function as the translation initiation codon, and the actual amino terminus of the AG protein remains uncharacterized. We have considered the possibility that AG translation can be initiated at a non-AUG codon. Two possible non-AUG initiation codons, CUG and ACG, are present in the 5' region of AG mRNA preceding the highly conserved MADS box sequence. We prepared a series of AG genomic constructs in which these codons are mutated and assayed their activity in phenotypic rescue experiments by introducing them as transgenes into ag mutant plants. Alteration of the CTG codon to render it unsuitable for acting as a translation initiation site does not affect complementation of the ag-3 mutation in transgenic plants. However, a similar mutation of the downstream ACG codon prevents the rescue of the ag-3 mutant phenotype. Conversely, if an ATG is introduced immediately 5' to the disrupted ACG codon, the resulting construct fully complements the ag-3 mutation. The AG protein synthesized in vitro by initiating translation at the ACG position is active in DNA binding and is of the same size as the AG protein detected from floral tissues, whereas AG polypeptides with additional amino-terminal residues do not appear to bind DNA. These results indicate that translation of AG is initiated exclusively at an ACG codon and prove that non-AUG triplets may be efficiently used as the sole translation initiation site in some plant cellular mRNAs.     

Two alternative translation mechanisms are responsible for the expression of the HCV ARFP/F/core+1 coding open reading frame

HCV-1 produces a novel protein, known as ARFP, F, or core+1. This protein is encoded by an open reading frame (ORF) that overlaps the core gene in the +1 frame (core+1 ORF). In vitro this protein is produced by a ribosomal frameshift mechanism. However, similar studies failed to detect the ARFP/F/core+1 protein in the HCV-1a (H) isolate. To clarify this issue and to elucidate the functions of this protein, we examined the expression of the core+1 ORF by the HCV-1 and HCV-1a (H) isolates in vivo, in transfected cells. For this purpose, we carried out luciferase (LUC) tagging experiments combined with site-directed mutagenesis studies. Our results showed that the core+1-LUC chimeric protein was efficiently produced in vivo by both isolates. More importantly, neither changes in the specific 10-A residue region of HCV-1 (codons 8-11), the proposed frameshift site for the production of the ARFP/F/core+1 protein in vitro, nor the alteration of the ATG start site of the HCV polyprotein to a stop codon significantly affected the in vivo expression of the core+1 ORF. Furthermore, we showed that efficient translation initiation of the core+1 ORF is mediated by internal initiation codon(s) within the core/core+1-coding sequence, located between nucleotides 583 and 606. Collectively, our data suggest the existence of an alternative translation initiation mechanism that may result in the synthesis of a shorter form of the core+1 protein in transfected cells.     

Expression strategy of a phlebovirus: biogenesis of proteins from the Rift Valley fever virus M segment.

The middle (M) RNA segment of Rift Valley fever virus (RVFV) encodes four proteins: the major viral glycoproteins G2 and G1, a 14-kilodalton (kDa) protein, and a 78-kDa protein. These proteins are derived from a single large open reading frame (ORF) present in the virus-complementary M-segment mRNA. We used recombinant vaccinia viruses in which sequences representing the M-segment ORF were engineered as a surrogate system to study phlebovirus protein expression. To investigate the translational initiation codon requirements for synthesis of these proteins, we constructed a series of vaccinia virus recombinants containing specific sequence changes which eliminated select ATG codons found in the region of the ORF preceding the mature glycoprotein-coding sequences (the preglycoprotein region). Examination of phleboviral proteins synthesized in cells infected with these vaccinia virus recombinants clearly showed that the first ATG of the ORF was required for the production of the 78-kDa protein, while synthesis of the 14-kDa protein was absolutely dependent on the second in-phase ATG codon. Efficient biosynthesis of glycoprotein G2 was shown to depend on one or more ATG codons within the preglycoprotein region, but not the first one of the ORF. Synthesis of about one-half of the total glycoprotein G1 was affected by the amino acid changes that eliminated ATG codons, while production of the remainder appeared to be independent of all ATG codons in the preglycoprotein region. These data indicated that the means for glycoprotein G1 biosynthesis was distinct from those of the other three M-segment gene products. The results presented herein suggest that a surprisingly complex expression strategy is employed by the RVFV M segment. Although the full nature of the mechanisms involved in the biogenesis of the four RVFV M-segment proteins remains unclear, it does involve the use of at least two (ATG codons 1 and 2), and likely more, distinct translation start sites within the same ORF to produce its complete complement of gene products.     

Translation of duck hepatitis B virus reverse transcriptase by ribosomal shunting

The duck hepatitis B virus (DHBV) polymerase (P) is translated by de novo initiation from a downstream open reading frame (ORF) that partially overlaps the core (C) ORF on the bicistronic pregenomic RNA (pgRNA). The DHBV P AUG is in a poor context for translational initiation and is preceded by 14 AUGs that could intercept scanning ribosomes, yet P translation is unanticipatedly rapid. Therefore, we assessed C and P translation in the context of the pgRNA. Mutating the upstream C ORF revealed that P translation was inversely related to C translation, primarily due to occlusion of P translation by ribosomes translating C. Translation of the pgRNA was found to be cap dependent, because inserting a stem-loop (BamHI-SL) that blocked >90% of scanning ribosomes at the 5' end of the pgRNA greatly inhibited C and P synthesis. Neither mutating AUGs between the C and P start sites in contexts similar to that of the P AUG nor blocking ribosomal scanning by inserting the BamHI-SL between the C and P start codons greatly altered P translation, indicating that most ribosomes that translate P do not scan through these sequences. Finally, optimizing the P AUG context did not increase P translation. Therefore, the majority of the ribosomes that translate P are shunted from a donor region near the 5' end of the pgRNA to an acceptor site at or near the P AUG, and the shunt acceptor sequences may augment initiation at the P AUG.     

ACG, the initiator codon for a Sendai virus protein

Deletion and site-directed point mutants of the polycistronic P/C mRNA of Sendai virus revealed that one of the nonstructural proteins of this virus, the C' protein, initiates from an ACG codon. This ACG codon occurs in an optimum sequence context and precedes the first AUG of the P/C mRNA. The results presented in this communication are consistent with the concept that the ribosomes scan the P/C mRNA to initiate several proteins from its different initiator codons. The arrangement of several weak initiator codons in tandem in an mRNA, i.e. non-AUG in optimum sequence context and AUG in suboptimum sequence context, may represent an alternate means to regulate gene expression in eukaryotes and their viruses.     

Cooperation between the chloroplast psbA 5′‐untranslated region and coding region is important for translational initiation: the chloroplast translation machinery cannot read a human viral gene coding region

Chloroplast mRNA translation is regulated by the 5′‐untranslated region (5′‐UTR). Chloroplast 5′‐UTRs also support translation of the coding regions of heterologous genes. Using an in vitro translation system from tobacco chloroplasts, we detected no translation from a human immunodeficiency virus tat coding region fused directly to the tobacco chloroplast psbA 5′‐UTR. This lack of apparent translation could have been due to rapid degradation of mRNA templates or synthesized protein products. Replacing the psbA 5′‐UTR with the E. coli phage T7 gene 10 5′‐UTR, a highly active 5′‐UTR, and substituting synonymous codons led to some translation of the tat coding region. The Tat protein thus synthesized was stable during translation reactions. No significant degradation of the added tat mRNAs was observed after translation reactions. These results excluded the above two possibilities and confirmed that the tat coding region prevented its own translation. The tat coding region was then fused to the psbA 5′‐UTR with a cognate 5′‐coding segment. Significant translation was detected from the tat coding region when fused after 10 or more codons. That is, translation could be initiated from the tat coding region once translation had started, indicating that the tat coding region inhibits translational initiation but not elongation. Hence, cooperation/compatibility between the 5′‐UTR and its coding region is important for translational initiation.     

Characterization of the ksgA gene of Escherichia coli determining kasugamycin sensitivity

In the plasmid pUC8ksgA7, the coding region of the ksgA gene is preceded by the lac promoter (Plac) and a small open reading frame (ORF). This ORF of 15 codons is composed of nucleotides derived from the lacZ gene, a multiple cloning site and the ksgA gene itself. The reading frame begins with the ATG initiation codon of lacZ and ends a few nucleotides beyond the ATG start codon of ksgA. The ksgA gene is not preceded by a Shine-Dalgarno (SD) signal. Cells transformed with pUC8ksgA7 produce active methylase, the product of the ksgA gene. Introduction of an in-phase TAA stop codon in the small ORF abolishes methylase production in transformed cells. On the plasmid pUC8ksgA5, which contains the entire ksgA region, the promoter of the ksgA gene was found to reside in a 380 base pair Bgl1-Pvu2 restriction fragment, partly overlapping the ksgA gene, by two independent methods. Cloning of this fragment in front of the galK gene in plasmid pKO1 stimulates galactokinase activity in transformants and its insertion into the expression vector pKL203 makes beta-galactosidase synthesis independent of the presence of Plac. The sequence of the Bgl1-Pvu2 fragment was determined and a putative promoter sequence identified. An SD signal could not be distinguished at a proper distance upstream from the ksgA start codon. Instead, an ORF of 13 codons starting with ATG in tandem with an SD signal and ending 4 codons ahead of the ksgA gene was identified. This suggests that translation of the ORF is required for expression of the ksgA gene.(ABSTRACT TRUNCATED AT 250 WORDS)     

Initiation of herpes simplex virus thymidine kinase polypeptides.

When employed as a transgene reporter, the herpes simplex type 1 virus (HSV1) thymidine kinase gene (tk) is ectopically expressed in mouse testis. The principal testicular mRNA lacks the 5'-end of the tk reading frame. As a result the principal translation products, P2 and P3, are N-terminally truncated. These co-migrate in SDS-PAGE with polypeptides synthesised during HSV1 infection that were previously thought to be initiated at methionine codons ATG46 and ATG60. Prompted by these observations we generated modified tk genes each carrying only one of the first three ATG codons. Transfected cells expressed both full-length enzyme (P1) and P2 when only ATG1 was unmodified, P2 and P3 when only ATG46 was unmodified or P2 and a fourth polypeptide (P4) when only ATG60 was unmodified. Our observations indicate that P3 is initiated at ATG46 rather than ATG60, while P2 is initiated at a non-ATG codon rather than ATG46 and P4 is initiated at ATG60. When either of two putative non-ATG initiation codons was modified P2 was no longer produced. Cells mainly expressing either P1 or P3 exhibited the same sensitivity to Ganciclovir as cells transfected with the unaltered tk gene. P1 and P3 both have TK activity while P4 probably has none.