5'-untranslated regions with multiple upstream AUG codons can support low-level translation via leaky scanning and reinitiation

Upstream AUGs (uAUGs) and upstream open reading frames (uORFs) are common features of mRNAs that encode regulatory proteins and have been shown to profoundly influence translation of the main ORF. In this study, we employed a series of artificial 5′-untranslated regions (5′-UTRs) containing one or more uAUGs/uORFs to systematically assess translation initiation at the main AUG by leaky scanning and reinitiation mechanisms. Constructs containing either one or two uAUGs in varying contexts but without an in-frame stop codon upstream of the main AUG were used to analyse the leaky scanning mechanism. This analysis largely confirmed the ranking of different AUG contextual sequences that was determined previously by Kozak. In addition, this ranking was the same for both the first and second uAUGs, although the magnitude of initiation efficiency differed. Moreover, ~10% of ribosomes exhibited leaky scanning at uAUGs in the most favourable context and initiated at a downstream AUG. A second group of constructs containing different numbers of uORFs, each with optimal uAUGs, were used to measure the capacity for reinitiation. We found significant levels of initiation at the main ORF even in constructs containing four uORFs, with nearly 10% of ribosomes capable of reinitiating five times. This study shows that for mRNAs containing multiple uORFs/uAUGs, ribosome reinitiation and leaky scanning are efficient mechanisms for initiation at their main AUGs.     

5’UTR中AUG的分布及其对翻译起始的影响

以细菌和古菌基因组5′ UTR序列作为研究对象,分析在5′ UTR 的3个不同阅读框架中三联体AUG的分布,发现无论是细菌还是古菌基因组都在阅读框1中有非常明显的AUG缺失(depletion)。AUG的缺失表明在起始密码子上游的AUG很可能会对基因的翻译起始产生影响。分析得知：绝大部分的AUG都是以uORF(upstream open reading frame)的形式出现的,uAUG(upstream AUG)的数量很少,特别是在阅读框1中,而且在细菌基因组的阅读框1中uAUG较多地出现在了含有SD序列的基因上游。比较发现,uAUG引导的序列在同义密码子使用上的偏好性较真正的编码序列差,这可能表明细菌和古菌在同义密码子使用上的偏好性也是决定基因准确地翻译起始的重要因素之一。     

Expression of Human Hemojuvelin (HJV) Is Tightly Regulated by Two Upstream Open Reading Frames in HJV mRNA That Respond to Iron Overload in Hepatic Cells

The gene encoding human hemojuvelin (HJV) is one of the genes that, when mutated, can cause juvenile hemochromatosis, an early-onset inherited disorder associated with iron overload. The 5′ untranslated region of the human HJV mRNA has two upstream open reading frames (uORFs), with 28 and 19 codons formed by two upstream AUGs (uAUGs) sharing the same in-frame stop codon. Here we show that these uORFs decrease the translational efficiency of the downstream main ORF in HeLa and HepG2 cells. Indeed, ribosomal access to the main AUG is conditioned by the strong uAUG context, which results in the first uORF being translated most frequently. The reach of the main ORF is then achieved by ribosomes that resume scanning after uORF translation. Furthermore, the amino acid sequences of the uORF-encoded peptides also reinforce the translational repression of the main ORF. Interestingly, when iron levels increase, translational repression is relieved specifically in hepatic cells. The upregulation of protein levels occurs along with phosphorylation of the eukaryotic initiation factor 2α. Nevertheless, our results support a model in which the increasing recognition of the main AUG is mediated by a tissue-specific factor that promotes uORF bypass. These results support a tight HJV translational regulation involved in iron homeostasis.     

Alternative splicing within the elk-1 5' untranslated region serves to modulate initiation events downstream of the highly conserved upstream open reading frame 2

The 5' untranslated region (UTR) plays a central role in the regulation of mammalian translation initiation. Key components include RNA structure, upstream AUGs (uAUGs), upstream open reading frames (uORFs), and internal ribosome entry site elements that can interact to modulate the readout. We previously reported the characterization of two alternatively spliced 5' UTR isoforms of the human elk-1 gene. Both contain two uAUGs and a stable RNA stem-loop, but the long form (5' UTR(L)) was more repressive than the short form (5' UTR(S)) for initiation at the ELK-1 AUG. We now demonstrate that ELK-1 expression arises by a combination of leaky scanning and reinitiation, with the latter mediated by the small uORF2 conserved in both spliced isoforms. In HEK293T cells, a considerable fraction of ribosomes scans beyond the ELK-1 AUG in a reinitiation mode. These are sequestered by a series of out-of-frame AUG codons that serve to prevent access to a second in-frame AUG start site used to express short ELK-1 (sELK-1), an N-terminally truncated form of ELK-1 that has been observed only in neuronal cells. We present evidence that all these events are fine-tuned by the nature of the 5' UTR and the activity of the α subunit of eukaryotic initiation factor 2 and provide insights into the neuronal specificity of sELK-1 expression.     

Comparative analysis of orthologous eukaryotic mRNAs: potential hidden functional signals

Sequencing of multiple, nearly complete eukaryotic genomes creates opportunities for detecting previously unnoticed, subtle functional signals in non-coding regions. A genome-wide comparative analysis of orthologous sets of mammalian and yeast mRNAs revealed distinct patterns of evolutionary conservation at the boundaries of the untranslated regions (UTRs) and the coding region (CDS). Elevated sequence conservation was detected in ~30 nt regions around the start codon. There seems to be a complementary relationship between sequence conservation in the ~30 nt regions of the 5′-UTR immediately upstream of the start codon and that in the synonymous positions of the 5′-terminal 30 nt of the CDS: in mammalian mRNAs, the 5′-UTR shows a greater conservation than the CDS, whereas the opposite trend holds for yeast mRNAs. Unexpectedly, a ~30 nt region downstream of the stop codon shows a substantially lower level of sequence conservation than the downstream portions of the 3′-UTRs. However, the sequence in this poorly conserved 30 nt portion of the 3′-UTR is non-random in that it has a higher GC content than the rest of the UTR. It is hypothesized that the elevated sequence conservation in the region immediately upstream of the start codon is related to the requirement for initiation factor binding during pre-initiation ribosomal scanning. In contrast, the poorly conserved region downstream of the stop codon could be involved in the post- termination scanning and dissociation of the ribosomes from the mRNA, which requires only the mRNA–ribosome interaction. Additionally, it was found that the choice of the stop codon in mammals, but not in yeasts, and the context in the immediate vicinity of the stop codons in both mammals and yeasts are subject to strong selection. Thus, genome-wide analysis of orthologous gene sets allows detection of previously unrecognized patterns of sequence conservation, which are likely to reflect hidden functional signals, such as ribosomal filters that could regulate translation by modulating the interaction between the mRNA and ribosomes.     

In-Frame cDNA Library Combined with Protein Complementation Assay Identifies ARL11-Binding Partners

The cDNA expression libraries that produce correct proteins are essential in facilitating the identification of protein-protein interactions. The 5′-untranslated regions (UTRs) that are present in the majority of mammalian and non-mammalian genes are predicted to alter the expression of correct proteins from cDNA libraries. We developed a novel cDNA expression library from which 5′-UTRs were removed using a mixture of polymerase chain reaction primers that complement the Kozak sequences we refer to as an “in-frame cDNA library.” We used this library with the protein complementation assay to identify two novel binding partners for ras-related ADP-ribosylation factor-like 11 (ARL11), cellular retinoic acid binding protein 2 (CRABP2), and phosphoglycerate mutase 1 (PGAM1). Thus, the in-frame cDNA library without 5′-UTRs we describe here increases the chance of correctly identifying protein interactions and will have wide applications in both mammalian and non-mammalian detection systems.     

5' and 3' untranslated regions of pestivirus genome: primary and secondary structure analyses.

Within the conserved 5' untranslated region (UTR) of the pestivirus genome three highly variable regions were identified. Preceding the polyprotein start codon, multiple cryptic AUG codons and several small open reading frames are characteristic for all the five pestiviruses. Inspection of the context of AUGs revealed that the polyprotein initiation AUG of pestivirus has a weak context for efficient translation initiation. The most favorable context was found in two of the cryptic AUGs. Two oligopyrimidine-rich tracts upstream to the conserved either cryptic or authentic AUG in the 5'-UTR of pestivirus were identified and 83.3% of their nucleotide sequences are complementary to the consensus sequence at the 3' terminus of eucaryotic 18S rRNA. A secondary structure model for the 5'-UTR of pestivirus was predicted. Nucleotide sequence comparison among five pestiviruses led to the identification of a variable region and a conserved region in the 3'-UTR. A deletion of 41 nucleotides was found within the variable region in Osloss. A secondary structure model for the 3'-UTR was also predicted. The structural similarity of the 5'-UTR between pestiviruses and picornaviruses and hepatitis C viruses was demonstrated and the possible implications of features of the 5' and 3'-UTR of pestiviruses are discussed.     

Regulation of ribonucleotide reductase M2 expression by the upstream AUGs

Ribonucleotide reductase catalyzes a rate-limiting reaction in DNA synthesis by converting ribonucleotides to deoxyribonucleotides. It consists of two subunits and the small one, M2 (or R2), plays an essential role in regulating the enzyme activity and its expression is finely controlled. Changes in the M2 level influence the dNTP pool and, thus, DNA synthesis and cell proliferation. M2 gene has two promoters which produce two major mRNAs with 5′-untranslated regions (5′-UTRs) of different lengths. In this study, we found that the M2 mRNAs with the short (63 nt) 5′-UTR can be translated with high efficiency whereas the mRNAs with the long (222 nt) one cannot. Examination of the long 5′-UTR revealed four upstream AUGs, which are in the same reading frame as the unique physiological translation initiation codon. Further analysis demonstrated that these upstream AUGs act as negative cis elements for initiation at the downstream translation initiation codon and their inhibitory effect on M2 translation is eIF4G dependent. Based on the findings of this study, we conclude that the expression of M2 is likely regulated by fine tuning the translation from the mRNA with a long 5′-UTR during viral infection and during the DNA replication phase of cell proliferation.     

Computer identification of snoRNA genes using a Mammalian Orthologous Intron Database

Based on comparative genomics, we created a bioinformatic package for computer prediction of small nucleolar RNA (snoRNA) genes in mammalian introns. The core of our approach was the use of the Mammalian Orthologous Intron Database (MOID), which contains all known introns within the human, mouse and rat genomes. Introns from orthologous genes from these three species, that have the same position relative to the reading frame, are grouped in a special orthologous intron table. Our program SNO.pl searches for conserved snoRNA motifs within MOID and reports all cases when characteristic snoRNA-like structures are present in all three orthologous introns of human, mouse and rat sequences. Here we report an example of the SNO.pl usage for searching a particular pattern of conserved C/D-box snoRNA motifs (canonical C- and D-boxes and the 6 nt long terminal stem). In this computer analysis, we detected 57 triplets of snoRNA-like structures in three mammals. Among them were 15 triplets that represented known C/D-box snoRNA genes. Six triplets represented snoRNA genes that had only been partially characterized in the mouse genome. One case represented a novel snoRNA gene, and another three cases, putative snoRNAs. Our programs are publicly available and can be easily adapted and/or modified for searching any conserved motifs within mammalian introns.     

mRNA sequences influencing translation and the selection of AUG initiator codons in the yeast Saccharomyces cerevisiae

The secondary structure and sequences influencing the expression and selection of the AUG initiator codon in the yeast Saccharomyces cerevisiae were investigated with two fused genes, which were composed of either the CYC7 or CYC1 leader regions, respectively, linked to the lacZ coding region. In addition, the strains contained the upf1-Δ disruption, which stabilized mRNAs that had premature termination codons, resulting in wild-type levels. The following major conclusions were reached by measuring β-galactosidase activities in yeast strains having integrated single copies of the fused genes with various alterations in the 89 and 38 nucleotide-long untranslated CYC7 and CYC1 leader regions, respectively. The leader region adjacent to the AUG initiator codon was dispensable, but the nucleotide preceding the AUG initiator at position ?3 modified the efficiency of translation by less than twofold, exhibiting an order of preference A>G>C>U. Upstream out-of-frame AUG triplets diminished initiation at the normal site, from essentially complete inhibition to approximately 50% inhibition, depending on the position of the upstream AUG triplet and on the context (?3 position nucleotides) of the two AUG triplets. In this regard, complete inhibition occurred when the upstream and downstream AUG triplets were closer together, and when the upstream and downstream AUG triplets had, respectively, optimal and suboptimal contexts. Thus, leaky scanning occurs in yeast, similar to its occurrence in higher eukaryotes. In contrast, termination codons between two AUG triplets causes reinitiation at the downstream AUG in higher eukaryotes, but not generally in yeast. Our results and the results of others with GCN4 mRNA and its derivatives indicate that reinitiation is not a general phenomenon in yeast, and that special sequences are required.     

Interrelations between the efficiency of translation start sites and other sequence features of yeast mRNAs

The translation start site (TSS) plays an important role in the control of the translational efficiency and cytoplasmic stability of eukaryotic mRNAs. The efficiency of TSS recognition is known to be influenced by sequence context, and mRNAs with "weak" TSSs are relatively abundant. We analyzed a sample of 4113 yeast genes in a search for features that might serve to compensate for the inefficient recognition of "weak" TSSs by initiating ribosomes. The first feature found to correlate with variations in TSS strength is differences in the stability of secondary structure upstream and downstream of the start AUG codon. The second feature concerns the characteristics of AUG triplets found at the beginning of the coding sequence, i.e., downstream of the predicted TSS. In particular, the proximal downstream AUG lies in frame with the CDS significantly more often if the TSS itself is located in a "weak" context. The accuracy of TSS annotation, the possibility of polypeptide heterogeneity due to the use of alternative downstream AUGs, and the influence of related features of mRNA sequences are discussed.