Upstream open reading frames (uORFs) in 5′-untranslated regions (5′-UTRs) of eukaryotic mRNAs play an important role in translation efficiency. Computational analysis of the upstream ATG (uATG) and uORFs of 5′-UTRs of plant mRNAs, adopted from the nucleotide sequence databank, was carried out. Statistical analysis revealed that up to 18% of 5′-UTRs contain uATG, which is much higher than the earlier estimate. Among them, about 50% of the genes have one uATG and nearly 20% of them have two uATGs. About 85% of uORFs are non-overlapping. Thirty per cent of uORF peptides comprise 1–5 aa, and about 80% of uORFs fall in the range of below 20 aa. Sequences flanking the uATG codon differ strikingly from the functional initiation codon and the uATG triplet is more frequently located in a non-optimal context. Consensus sequences of the ATG codon context of mRNA with and without uATG are similar, whereas the ATG codon context of mRNA without uATG is more frequently located in an optimal context than is mRNA with uATG. Most mRNAs with uATGs are possibly related to regulatory functions. In addition, most mRNA uORFs have no similarity between plant species whereas sequences of a few uORFs are highly conserved. For example, mRNA uORFs encoding S-adenosyl-l-methionine decarboxylase (AdoMetDC) share 75–100% homology between plant species, which is much more conserved than AdoMetDC protein.

In mammals, control of S-adenosylmethionine decarboxylase (AdoMetDC) translation is one component of a feedback network that regulates intracellular levels of the polyamines, spermidine, and spermine. AdoMetDC mRNA from mammals contains a highly conserved upstream open reading frame (uORF) within its leader sequence that confers polyamine-regulated suppression of translation on the associated downstream cistron. This regulation is mediated through an interaction that depends on the amino acid sequence of the uORF-encoded hexapeptide. It remains to be shown whether polyamines participate directly in this interaction or indirectly through a specialized signal transduction pathway. We show that Saccharomyces cerevisiae does not have a uORF associated with its AdoMetDC gene (SPE2) and that ribosome loading on the SPE2 mRNA is not positively influenced by polyamine depletion, as it is in mammalian cells. Nevertheless, the mammalian AdoMetDC uORF, when introduced into a polyamine auxotroph of yeast, conferred polyamine regulation of both translational efficiency and ribosome loading on the associated mRNA. This regulatory activity depended on the amino acid sequence encoded by the fourth and fifth codons of the uORF, as in mammalian cells. The fact that the regulatory properties of this mammalian translational control element are quite similar in both mammalian and yeast cells suggests that a specialized signal transduction pathway is not required. Rather, it seems likely that polyamines may be directly participating in an interaction between the uORF-encoded peptide and a constitutive component of the translation machinery, which leads to inhibition of ribosome activity.

A 22-codon upstream open reading frame (uORF2) in the human cytomegalovirus UL4 transcript leader inhibits downstream translation in cis. Previous studies revealed that the peptide product of uORF2 mediates this inhibitory effect by interfering with translation termination at its own stop codon. The block at termination results both in accumulation of the nascent uORF2 peptide linked to tRNAPro, the tRNA that decodes the final codon of uORF2, and in stalling of ribosomes at the end of uORF2. The stalled ribosomes create a barrier that obstructs ribosomal transit to the downstream cistron. In the current studies, we further investigated the mechanism of uORF2-mediated translational inhibition by assessing the kinetics of uORF2 peptidyl tRNAPro hydrolysis and ribosomal release from the uORF2 termination site. Whereas hydrolysis of a mutant, noninhibitory uORF2 peptidyl tRNA is nearly complete in less than 1 min, hydrolysis of the wild-type peptidyl tRNA is negligible even after 30 min. In spite of this remarkably prolonged block to hydrolysis of the uORF2 peptidyl tRNAPro, most ribosomes are released from the uORF2 termination site within 15 min. Thus, peptidyl tRNA hydrolysis is not absolutely required for ribosomal release in this system. These results suggest that a eukaryotic cellular mechanism exists for removing stalled ribosomes from mRNAs in the absence of peptidyl tRNA hydrolysis.