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.     

The parainfluenza virus type 1 P/C gene uses a very efficient GUG codon to start its C'' protein.

Parainfluenza virus type 1 (PIV1) and Sendai virus (SEN) are very closely related, but the PIV1 P/C gene does not contain the ACG codon which initiates the SEN C' protein. Nevertheless, a protein corresponding to the PIV1 C' protein was observed both in vivo and in vitro. The initiation site of this protein maps upstream of the PIV1 C protein AUG in a region that does not contain an AUG codon. We have used site-directed mutagenesis to demonstrate that the PIV1 C' protein initiates from a GUG codon, four codons upstream of where the ACG is found in SEN. Remarkably, this GUG appears to initiate in vivo almost as frequently as AUG in the same context. However, whereas GUG permits downstream expression of the P and C proteins, AUG in this context does not. The conservation of an upstream non-AUG initiation codon for C' among PIV1 and SEN suggests that it is important for virus replication, even though some paramyxoviruses express only the C protein and others have no C open reading frame at all.     

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.     

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.     

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.     

Plasmid replication in Xenopus eggs and egg extracts: a 2D gel electrophoretic analysis.

We have examined the replication patterns of ribosomal DNA plasmids in vivo and in vitro using Xenopus eggs. Plasmids carrying different parts of the Xenopus ribosomal DNA sequence were allowed to replicate either in vitro in an egg extract or in vivo after microinjection into unfertilized eggs. The replication intermediates were analyzed by the 2D gel electrophoretic technique of Brewer and Fangman (1), using original or modified electrophoresis conditions. With standard electrophoresis conditions, the patterns obtained for restriction fragments larger than 5 kb were unreliable because of artefactually distorted Y arcs and unrecognizable bubble arcs. Interpretable patterns could nevertheless be obtained using suitably modified electrophoresis parameters. Under these conditions, replication was found to initiate and terminate at multiple, random locations on each plasmid both in vivo and in vitro. However, only one or very few of these potential initiation sites are used during the replication of an individual plasmid molecule. We discuss the possible artefacts and misinterpretations that can result when the 2D electrophoresis parameters are not adapted to the size of the fragment examined. We also discuss the relevance of the random replication mode to the mechanisms and the control of DNA replication in eukaryotes.     

Proteolytic processing and translation initiation: two independent mechanisms for the expression of the Sendai virus Y proteins

The four Sendai virus C-proteins (C', C, Y1, and Y2) represent an N-terminal nested set of non-structural proteins whose expression modulates both the readout of the viral genome and the host cell response. In particular, they modulate the innate immune response by perturbing the signaling of type 1 interferons. The initiation codons for the four C-proteins have been mapped in vitro, and it has been proposed that the Y proteins are initiated by ribosomal shunting. A number of mutations were reported that significantly enhanced Y expression, and this was attributed to increased shunt-mediated initiation. However, we demonstrate that this arises due to enhanced proteolytic processing of C', an event that requires its very N terminus. Curiously, although Y expression in vitro is mediated almost exclusively by initiation, Y proteins in vivo can arise both by translation initiation and processing of the C' protein. To our knowledge this is the first example of two apparently independent pathways leading to the expression of the same polypeptide chain. This dual pathway explains several features of Y expression.     

Translation initiation in the HEXB gene encoding the beta-subunit of human beta-hexosaminidase

The human lysosomal enzyme beta-hexosaminidase (EC 3.2.1.52) is a glycoprotein composed of dimers of alpha- and/or beta-subunits. The subunits of the enzymes are synthesized in the rough endoplasmic reticulum and transported through the Golgi apparatus to the lysosome. As such, each subunit contains an amino-terminal signal peptide that directs the nascent polypeptide into the lumen of the endoplasmic reticulum. The signal peptide cleavage site of the beta-polypeptide is known, but its NH2 terminus has not been determined due to the presence of three candidate initiation codons upstream of the cleavage site. In this study, we identified the mRNA cap site, confirming the presence of all three AUGs in the majority of HEXB mRNA. To identify the site of translation initiation, we mutated the three ATGs by deletion and site-directed mutagenesis and showed that all three AUG codons can be used for translation initiation after expression in COS cells. Furthermore, in each case, a fully processed, i.e. mature lysosomal, and enzymatically active beta-hexosaminidase was produced indicating that a functional signal peptide was synthesized. However, expression of a frameshift mutation in the normal construct, created by insertion of a single nucleotide between the first and second ATG, resulted in no significant enzyme activity or beta-subunit protein. We conclude, therefore, that the first in-frame ATG is used exclusively in vivo, in keeping with the scanning model of eukaryotic translation initiation. Interestingly, substitution of all three ATGs with CTG resulted in a significant amount of mature beta-hexosaminidase, showing that under these conditions, initiation could occur from non-AUG codons. Translation initiation from the first AUG gives the prepro-beta-polypeptide a signal peptide of 42 amino acids that has an unusually long hydrophobic core more typical of membrane spanning domains. Such a large hydrophobic core has not been found in other cleavable signal peptides.     

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.     

Interaction of tRNAs with the ribosome at the A and P sites.

In vitro transcribed tRNA(Phe) analogues from Escherichia coli containing up to four randomly distributed A, G, U or C phosphorothioated nucleotides were used to investigate contact patterns with the ribosome in the A and P sites. The tRNAs were biologically active. Molecular iodine (I2) can trigger a break in the sugar-phosphate backbone at phosphorothioated positions of the ribosomal bound tRNAs if contacts with ribosomal components do not prevent access of the iodine. Highly differentiated protection patterns were found which were strikingly different in the A and P sites, respectively. Strong protections accumulated in the T psi C loop and no protection was seen in the extra-arm region in both sites, whereas the phosphates in the anticodon loop are more strongly protected in the A site. Strong common protections in both the A and P sites were found neighbouring universally or semi-universally conserved bases in prominent regions of the tertiary structure of tRNAs: Y11, Y32, U33, psi55, C56, A58 and Y60. These bases are therefore candidates for 'identity elements' in ribosomal tRNA recognition. The data further indicate that tRNAs change their conformations upon binding to either ribosomal site.