Usage of the three termination codons in a single eukaryotic cell, the Xenopus laevis oocyte.

Oocytes from Xenopus laevis were injected with purified amber (UAG), ochre (UAA), and opal (UGA) suppressor tRNAs from yeasts. The radioactively labeled proteins translated from the endogenous mRNAs were then separated on two-dimensional gels. All three termination codons are used in a single cell, the Xenopus laevis oocyte. But a surprisingly low number of readthrough polypeptides were observed from the 600 mRNAs studied in comparison to uninjected oocytes. The experimental data are compared with the conclusions obtained from the compilation of all available termination sequences on eukaryotic and prokaryotic mRNAs. This comparison indicates that the apparent resistance of natural termination codons against readthrough, as observed by the microinjection experiments, cannot be explained by tandem or very close second stop codons. Instead it suggests that specific context sequences around the termination codons may play a role in the efficiency of translation termination.     

Comparison of characteristics and function of translation termination signals between and within prokaryotic and eukaryotic organisms

Six diverse prokaryotic and five eukaryotic genomes were compared to deduce whether the protein synthesis termination signal has common determinants within and across both kingdoms. Four of the six prokaryotic and all of the eukaryotic genomes investigated demonstrated a similar pattern of nucleotide bias both 5′ and 3′ of the stop codon. A preferred core signal of 4 nt was evident, encompassing the stop codon and the following nucleotide. Codons decoded by hyper-modified tRNAs were over-represented in the region 5′ to the stop codon in genes from both kingdoms. The origin of the 3′ bias was more variable particularly among the prokaryotic organisms. In both kingdoms, genes with the highest expression index exhibited a strong bias but genes with the lowest expression showed none. Absence of bias in parasitic prokaryotes may reflect an absence of pressure to evolve more efficient translation. Experiments were undertaken to determine if a correlation existed between bias in signal abundance and termination efficiency. In Escherichia coli signal abundance correlated with termination efficiency for UAA and UGA stop codons, but not in mammalian cells. Termination signals that were highly inefficient could be made more efficient by increasing the concentration of the cognate decoding release factor.     

Suppression of eukaryotic translation termination by selected RNAs

Using selection-amplification, we have isolated RNAs with affinity for translation termination factors eRF1 and eRF1.eRF3 complex. Individual RNAs not only bind, but inhibit eRF1-mediated release of a model nascent chain from eukaryotic ribosomes. There is also significant but weaker inhibition of eRF1-stimulated eRF3 GTPase and eRF3 stimulation of eRF1 release activity. These latter selected RNAs therefore hinder eRF1.eRF3 interactions. Finally, four RNA inhibitors of release suppress a UAG stop codon in mammalian extracts dependent for termination on eRF1 from several metazoan species. These RNAs are therefore new specific inhibitors for the analysis of eukaryotic termination, and potentially a new class of omnipotent termination suppressors with possible therapeutic significance.     

Toeprint analysis of the positioning of translation apparatus components at initiation and termination codons of fungal mRNAs

The ability to map the position of ribosomes and their associated factors on mRNAs is critical for an understanding of translation mechanisms. Earlier approaches to monitoring these important cellular events characterized nucleotide sequences rendered nuclease-resistant by ribosome binding. While these approaches furthered our understanding of translation initiation and ribosome pausing, the pertinent techniques were technically challenging and not widely applied. Here we describe an alternative assay for determining the mRNA sites at which ribosomes or other factors are bound. This approach uses primer extension inhibition, or "toeprinting," to map the 3' boundaries of mRNA-associated complexes. This methodology, previously used to characterize initiation mechanisms in prokaryotic and eukaryotic systems, is used here to gain an understanding of two interesting translational regulatory phenomena in the fungi Neurospora crassa and Saccharomyces cerevisiae: (a) regulation of translation in response to arginine concentration by an evolutionarily conserved upstream open reading frame, and (b) atypical termination events that occur as a consequence of the presence of premature stop codons.     

Evolution of the eukaryotic translation termination system: origins of release factors

Accurate translation termination is essential for cell viability. In eukaryotes, this process is strictly maintained by two proteins, eukaryotic release factor 1 (eRF1), which recognizes all stop codons and hydrolyzes peptidyl-tRNA, and eukaryotic release factor 3 (eRF3), which is an elongation factor 1alpha (EF-1alpha) homolog stimulating eRF1 activity. To retrace the evolution of this core system, we cloned and sequenced the eRF3 genes from Trichomonas vaginalis (Parabasalia) and Giardia lamblia (Diplomonada), which are generally thought to be "early-diverging eukaryotes," as well as those from two ciliates (Oxytricha trifallax and Euplotes aediculatus). We also determined the sequence of the eRF1 gene for G. lamblia. Surprisingly, the G. lamblia eRF3 appears to have only one domain, corresponding to EF-1alpha, while other eRF3s (including the T. vaginalis protein) have an additional N-terminal domain, of 66-411 amino acids. Considering this novel eRF3 structure and our extensive phylogenetic analyses, we suggest that (1) the current translation termination system in eukaryotes evolved from the archaea-like version, (2) eRF3 was introduced into the system prior to the divergence of extant eukaryotes, including G. lamblia, and (3) G. lamblia might be the first eukaryotic branch among the organisms considered.     

Model of the structure of the eukaryotic ribosomal translation termination complex

Models of the atomic structure of the eukaryotic translation termination complex containing mRNA, P-site tRNA^Phe, human class 1 release factor eRF1, and 80S ribosome, were constructed by computational modeling. The modeling was based on the assumed structural-functional similarity between the tRNA and eFR1 molecules in the ribosomal A site. The known atomic structure of the 70S ribosome complexed with mRNA as well as the P-and A-site tRNAs^Phe was used as a structural template for the modeling. The eRF1 molecule bound in the A site undergoes substantial conformational changes so that the mutual configuration of the N and M domains matches the overall tRNA shape. Two models of eRF1 binding to mRNA at the A site in the presence of P-site tRNA^Phe were generated. A characteristic of these models is complementary interactions between the mRNA stop codon and the grooves at different sides of the surface of the eRF1 fragment, containing helix α2, NIKS loop, and helix α3 of the N domain. In model 1, the nucleotides of the mRNA stop codon at the A site are approximately equidistant (～15 Å) from the N (motifs NIKS and YxCxxxF) and C domains. In model 2, the stop codon is close to the N-domain motifs NIKS and YxCxxxF. Both models fit genetic and biochemical experimental data. The choice of a particular model requires additional studies.     

Tolerance for random recombination of domains in prokaryotic and eukaryotic translation systems: Limited interdomain misfolding in a eukaryotic translation system

It has been proposed that eukaryotic translation systems have a greater capacity for cotranslational folding of domains than prokaryotic translation systems, which reduces interdomain misfolding in multidomain proteins and, therefore, leads to tolerance for random recombination of domains. However, there has been a controversy as to whether prokaryotic and eukaryotic translation systems differ in the capacity for cotranslational domain folding. Here, to examine whether these systems differ in the tolerance for the random domain recombination, we systematically combined six proteins, out of which four are soluble and two are insoluble when produced in an Escherichia coli and a wheat germ cell-free protein synthesis systems, to construct a fusion protein library. Forty out of 60 two-domain proteins and 114 out of 120 three-domain proteins were more soluble when produced in the wheat system than in the E. coli system. Statistical analyses of the solubilities and the activities indicated that, in the wheat system but not in the E. coli system, the two soluble domains comprised mainly of beta-sheets tend to avoid interdomain misfolding and to fold properly even at the neighbor of the misfolded domains. These results demonstrate that a eukaryotic system permits the concomitance of a wider variety of domains within a single polypeptide chain than a prokaryotic system, which is probably due to the difference in the capacity for cotranslational folding. This difference is likely to be related to the postulated difference in the tolerance for random recombination of domains.     

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.     

Metagenomic analysis of viral community in the Yangtze River expands known eukaryotic and prokaryotic virus diversity in freshwater

Viruses in aquatic ecosystems are characterized by extraordinary abundance and diversity. Thus far, there have been limited studies focused on viral communities in river water systems. Here, we investigated the virome of the Yangtze River Delta using viral metagenomic analysis. The compositions of viral communities from six sampling sites were analyzed and compared. By using library construction and next generation sequencing, contigs and singlet reads similar to viral sequences were classified into 17 viral families, including nine dsDNA viral families, four ssDNA viral families and four RNA viral families. Statistical analysis using Friedman test suggested that there was no significant difference among the six sampling sites (P > 0.05). The viromes in this study were all dominated by the order Caudovirales, and a group of Freshwater phage uvFW species were particularly prevalent among all the samples. The virome from Nanjing presented a unique pattern of viral community composition with a relatively high abundance of family Parvoviridae. Phylogenetic analyses based on virus hallmark genes showed that the Caudovirales order and CRESS-DNA viruses presented high genetic diversity, while viruses in the Microviridae and Parvoviridae families and the Riboviria realm were relatively conservative. Our study provides the first insight into viral community composition in large river ecosystem, revealing the diversity and stability of river water virome, contributing to the proper utilization of freshwater resource.     

Molecular modeling of structure of eukaryotic ribosomal translation termination complex

Models of atomic structure of eukaryotic translation termination complex containing mRNA, P-site tRNAPhe, human class-1 polypeptide release factor eRF1 and 80S ribosome were constructed. The method of computational modeling was applied. The modeling was based on the functional and structural similarity between tRNA and eFR1 bound in the ribosomal A site. Structural template for the modeling was a known structure of the 70S ribosome complexed with mRNA, P- and A-site tRNAsPhe. The eRF1 molecule bound to the ribosome undergone substantial conformational changes resulting in the mutual configuration of the N- and M-domains similar to tRNA shape. Two models of binding of eRF1 to mRNA at the A-site in the presence of P-site tRNA were generated and characterized by a shape complementarity between the mRNA stop codon and grooves of the different sides of the molecular surface of the fragment of alpha2-helix, NIKS loop and alpha-helix of the N-domain. In the model 1 the stop-codon nucleotides were at the equal distances from the N- and C-domains. In the model 2 the stop-codon was proximal to the NIKS and YxCxxxF motifs of the N-domain. Both models fit the genetic and biochemical data available so far.     

Aminoglycoside antibiotics mediate context-dependent suppression of termination codons in a mammalian translation system

The translation machinery recognizes codons that enter the ribosomal A site with remarkable accuracy to ensure that polypeptide synthesis proceeds with a minimum of errors. When a termination codon enters the A site of a eukaryotic ribosome, it is recognized by the release factor eRF1. It has been suggested that the recognition of translation termination signals in these organisms is not limited to a simple trinucleotide codon, but is instead recognized by an extended tetranucleotide termination signal comprised of the stop codon and the first nucleotide that follows. Interestingly, pharmacological agents such as aminoglycoside antibiotics can reduce the efficiency of translation termination by a mechanism that alters this ribosomal proofreading process. This leads to the misincorporation of an amino acid through the pairing of a near-cognate aminoacyl tRNA with the stop codon. To determine whether the sequence context surrounding a stop codon can influence aminoglycoside-mediated suppression of translation termination signals, we developed a series of readthrough constructs that contained different tetranucleotide termination signals, as well as differences in the three bases upstream and downstream of the stop codon. Our results demonstrate that the sequences surrounding a stop codon can play an important role in determining its susceptibility to suppression by aminoglycosides. Furthermore, these distal sequences were found to influence the level of suppression in remarkably distinct ways. These results suggest that the mRNA context influences the suppression of stop codons in response to subtle differences in the conformation of the ribosomal decoding site that result from aminoglycoside binding.     

Interplay between termination and translation machinery in eukaryotic selenoprotein synthesis.

Termination of translation in eukaryotes is catalyzed by eRF1, the stop codon recognition factor, and eRF3, an eRF1 and ribosome-dependent GTPase. In selenoprotein mRNAs, UGA codons, which typically specify termination, serve an alternate function as sense codons. Selenocysteine incorporation involves a unique tRNA with an anticodon complementary to UGA, a unique elongation factor specific for this tRNA, and cis-acting secondary structures in selenoprotein mRNAs, termed SECIS elements. To gain insight into the interplay between the selenocysteine insertion and termination machinery, we investigated the effects of overexpressing eRF1 and eRF3, and of altering UGA codon context, on the efficiency of selenoprotein synthesis in a transient transfection system. Overexpression of eRF1 does not increase termination at naturally occurring selenocysteine codons. Surprisingly, selenocysteine incorporation is enhanced. Overexpression of eRF3 did not affect incorporation efficiency. Coexpression of both factors reproduced the effects with eRF1 alone. Finally, we show that the nucleotide context immediately upstream and downstream of the UGA codon significantly affects termination to incorporation ratios and the response to eRF overexpression. Implications for the mechanisms of selenocysteine incorporation and termination are discussed.     

A universal strategy for regulating mRNA translation in prokaryotic and eukaryotic cells

We describe a simple strategy to control mRNA translation in both prokaryotic and eukaryotic cells which relies on a unique protein–RNA interaction. Specifically, we used the Pumilio/FBF (PUF) protein to repress translation by binding in between the ribosome binding site (RBS) and the start codon (in Escherichia coli), or by binding to the 5′ untranslated region of target mRNAs (in mammalian cells). The design principle is straightforward, the extent of translational repression can be tuned and the regulator is genetically encoded, enabling the construction of artificial signal cascades. We demonstrate that this approach can also be used to regulate polycistronic mRNAs; such regulation has rarely been achieved in previous reports. Since the regulator used in this study is a modular RNA-binding protein, which can be engineered to target different 8-nucleotide RNA sequences, our strategy could be used in the future to target endogenous mRNAs for regulating metabolic flows and signaling pathways in both prokaryotic and eukaryotic cells.     

Similar features in the mechanisms of mRNA translation initiation in eukaryotic and prokaryotic systems

Similar features in the mechanisms of mRNA translation initiation on prokaryotic and eukaryotic ribosomes are discussed with examples from mRNAs with nonstandard 5′-untranslated regions (5′-UTRs) and mRNAs lacking 5′-UTR (leaderless mRNAs).