A balanced ratio of proteins from gene G and frameshift-extended gene GT is required for phage lambda tail assembly.

In bacteriophage λ, the overlapping open reading frames G and T are expressed by a programmed translational frameshift similar to that of the gag-pol genes of many retroviruses to produce the proteins gpG and gpGT. An analogous frameshift is widely conserved among other dsDNA tailed phages in their corresponding "G" and "GT" tail genes even in the absence of detectable sequence homology. The longer protein gpGT is known to be essential for tail assembly, but the requirement for the shorter gpG remained unclear because mutations in gene G affect both proteins. A plasmid system that can direct the efficient synthesis of tails was created and used to show that gpG and gpGT are both essential for correct tail assembly. Phage complementation assays under conditions where levels of plasmid-expressed gpG or gpGT could be altered independently revealed that the correct molar ratio of these two related proteins, normally determined by the efficiency of the frameshift, is also crucial for efficient assembly of functional tails. Finally, the physical connection between the G and T domains of gpGT, a consequence of the frameshift mechanism of protein expression, appears to be important for efficient tail assembly.

Evidence of abundant stop codon readthrough in Drosophila and other metazoa.

While translational stop codon readthrough is often used by viral genomes, it has been observed for only a handful of eukaryotic genes. We previously used comparative genomics evidence to recognize protein-coding regions in 12 species of Drosophila and showed that for 149 genes, the open reading frame following the stop codon has a protein-coding conservation signature, hinting that stop codon readthrough might be common in Drosophila. We return to this observation armed with deep RNA sequence data from the modENCODE project, an improved higher-resolution comparative genomics metric for detecting protein-coding regions, comparative sequence information from additional species, and directed experimental evidence. We report an expanded set of 283 readthrough candidates, including 16 double-readthrough candidates; these were manually curated to rule out alternatives such as A-to-I editing, alternative splicing, dicistronic translation, and selenocysteine incorporation. We report experimental evidence of translation using GFP tagging and mass spectrometry for several readthrough regions. We find that the set of readthrough candidates differs from other genes in length, composition, conservation, stop codon context, and in some cases, conserved stem-loops, providing clues about readthrough regulation and potential mechanisms. Lastly, we expand our studies beyond Drosophila and find evidence of abundant readthrough in several other insect species and one crustacean, and several readthrough candidates in nematode and human, suggesting that functionally important translational stop codon readthrough is significantly more prevalent in Metazoa than previously recognized.

Multiple RNA surveillance mechanisms cooperate to reduce the amount of nonfunctional Ig kappa transcripts.

Random V(D)J junctions ensure that the diversity of the Ig primary repertoire is adapted to the vast heterogeneity of Ags. In two-thirds of cases, recombination between variable segments induces a frameshift in the open reading frame and generates a premature termination codon. In B cells harboring biallelic V(D)J rearrangement of Ig genes, transcription is known to occur on both the functional and nonfunctional alleles, generating considerable amounts of primary transcripts with out-of-frame V regions. In this study, we analyzed in cell lines and primary B cells the RNA surveillance of nonfunctional Igkappa transcripts arising from nonproductive rearrangement. We demonstrated that splicing inhibition, nonsense-mediated decay and nonsense-altered splicing each have an individual partial effect that together associate into an efficient surveillance machinery, downregulating nonfunctional Igkappa mRNA. Moreover, we provide evidence that the RNA surveillance efficiency increases throughout B cell development. Whereas splicing inhibition remains constant in most cell lines, differences in nonsense-mediated decay and nonsense-altered splicing are responsible for the higher RNA surveillance observed in plasma cells. Altogether, these data show that nonfunctionally rearranged alleles are subjected to active transcription but that multiple RNA surveillance mechanisms eradicate up to 90% of out-of-frame Igkappa mRNA.

Highly active dimeric and low-activity tetrameric forms of selenium-containing rat thioredoxin reductase 1.

Mammalian thioredoxin reductase 1 (TrxR1) is a selenoprotein that contains a selenocysteine (Sec) residue at the penultimate C-terminal position. When rat TrxR1 is expressed recombinantly in Escherichia coli, partial truncation at the Sec-encoding UGA gives rise to additional protein species that lack Sec. Phenylarsine oxide (PAO) Sepharose can subsequently be used to enrich the Sec-containing protein and yield activity corresponding to that of native enzyme. Herein we extensively purified recombinant rat TrxR1 over PAO Sepharose, which gave an enzyme with about 53 U/mg specific activity. Surprisingly, only about 65% of the subunits of this TrxR1 preparation contained Sec, whereas about 35% were protein products derived from UGA truncation. Further analyses revealed a theoretical maximal specific activity of 70-80 U/mg for the homodimeric enzyme with full Sec content, i.e., significantly higher than that reported for native TrxR1. We also discovered the formation of highly stable noncovalently linked tetrameric forms of TrxR1, having full FAD content but about half the specific activity in relation to the selenium content compared to the dimeric protein. The characterization of these different forms of recombinant TrxR1 revealed that inherent turnover capacity of the enzyme must be revised, that multimeric states of the protein may be formed, and that the yield of bacterial selenoprotein production may be lower than earlier reported. The biological significance of the hitherto unsurpassed high specific activity of the enzyme involves the capacity to support a higher turnover in vivo than previously believed. The tetrameric forms of the protein could represent hitherto unknown regulatory states of the enzyme.

Neurite outgrowth and in vivo sensory innervation mediated by a Ca(V)2.2-laminin beta 2 stop signal.

Axons and dendrites of developing neurons establish distributed innervation patterns enabling precise discrimination in sensory systems. We describe the role of the extracellular matrix molecule, laminin beta2, interacting with the Ca(V)2.2 calcium channel in establishing appropriate sensory innervation. In vivo, Ca(V)2.2 is expressed on the growth cones of Xenopus laevis sensory neurites and laminin beta2 is expressed in the skin. Culturing neurons on a laminin beta2 substrate inhibits neurite outgrowth in a specific and calcium-dependent manner. Blocking signaling between laminin beta2 and Ca(V)2.2 leads to increased numbers of sensory terminals in vivo. These findings suggest that interactions between extracellular matrix molecules and calcium channels regulate connectivity in the developing nervous system.

Halting a cellular production line: responses to ribosomal pausing during translation.

Cellular protein synthesis is a complex polymerization process carried out by multiple ribosomes translating individual mRNAs. The process must be responsive to rapidly changing conditions in the cell that could cause ribosomal pausing and queuing. In some circumstances, pausing of a bacterial ribosome can trigger translational abandonment via the process of trans-translation, mediated by tmRNA (transfer-messenger RNA) and endonucleases. Together, these factors release the ribosome from the mRNA and target the incomplete polypeptide for destruction. In eukaryotes, ribosomal pausing can initiate an analogous process carried out by the Dom34p and Hbs1p proteins, which trigger endonucleolytic attack of the mRNA, a process termed mRNA no-go decay. However, ribosomal pausing can also be employed for regulatory purposes, and controlled translational delays are used to help co-translational folding of the nascent polypeptide on the ribosome, as well as a tactic to delay translation of a protein while its encoding mRNA is being localized within the cell. However, other responses to pausing trigger ribosomal frameshift events. Recent discoveries are thus revealing a wide variety of mechanisms used to respond to translational pausing and thus regulate the flow of ribosomal traffic on the mRNA population.

Selective translational repression of truncated proteins from frameshift mutation-derived mRNAs in tumors.

Frameshift and nonsense mutations are common in tumors with microsatellite instability, and mRNAs from these mutated genes have premature termination codons (PTCs). Abnormal mRNAs containing PTCs are normally degraded by the nonsense-mediated mRNA decay (NMD) system. However, PTCs located within 50-55 nucleotides of the last exon-exon junction are not recognized by NMD (NMD-irrelevant), and some PTC-containing mRNAs can escape from the NMD system (NMD-escape). We investigated protein expression from NMD-irrelevant and NMD-escape PTC-containing mRNAs by Western blotting and transfection assays. We demonstrated that transfection of NMD-irrelevant PTC-containing genomic DNA of MARCKS generates truncated protein. In contrast, NMD-escape PTC-containing versions of hMSH3 and TGFBR2 generate normal levels of mRNA, but do not generate detectable levels of protein. Transfection of NMD-escape mutant TGFBR2 genomic DNA failed to generate expression of truncated proteins, whereas transfection of wild-type TGFBR2 genomic DNA or mutant PTC-containing TGFBR2 cDNA generated expression of wild-type protein and truncated protein, respectively. Our findings suggest a novel mechanism of gene expression regulation for PTC-containing mRNAs in which the deleterious transcripts are regulated either by NMD or translational repression.

A novel beta-Thalassemic allele due to a two nucleotide deletion: beta76 (-GC).

We have identified and characterized a novel beta-thalassemic mutation in a North African adult. The molecular defect consists of a two nucleotide (nt) deletion in the beta-globin gene at codon 76 [beta76 (-GC), c.229-230delGC]. This frameshift mutation generates a TGA stop codon at position 89. The carrier presented with mild microcytic anemia (Hb 12.8 g/dL, MCV 60 fL), no detectable Hb F, an elevated Hb A2 level (5.5%) with no other mutation in the beta-globin gene and none of the more common known deletions in the alpha-globin cluster. No abnormal hemoglobin (Hb) was present in routine electrophoresis or in high performance liquid chromatography (HPLC) analyses. Pathologic inclusions were absent in both mature red cells and in reticulocytes. This observation reinforces the hypothesis that nonsense and frameshift mutations that result in a premature stop codon in exon 1 or exon 2 inherited in the heterozygous state do not generate dominant beta-thalassemia (thal). This is the first example of a premature stop codon at position 89.

Regulated translational bypass of stop codons in yeast.

Stop codons are used to signal the ribosome to terminate the decoding of an mRNA template. Recent studies on translation termination in the yeast Saccharomyces cerevisiae have not only enabled the identification of the key components of the termination machinery, but have also revealed several regulatory mechanisms that might enable the controlled synthesis of C-terminally extended polypeptides via stop-codon readthrough. These include both genetic and epigenetic mechanisms. Rather than being a translation 'error', stop-codon readthrough can have important effects on other cellular processes such as mRNA degradation and, in some cases, can confer a beneficial phenotype to the cell.

[Termination of prokaryotic and eukaryotic translation]. / Terminacja translacji u Prokaryota i Eukaryota.

In prokaryotic and eukaryotic organisms termination of translation differs in many aspects. In the first step of termination the release factors recognize stop codons in A site of the ribosome. These factors are responsible for hydrolysis of peptide-tRNA bond and release of newly synthesized peptide. There is only one factor in eukaryotic cells, called eRF1, whereas in prokaryotic cells there are two factors called RF1 and RF2. In termination of translation in mitochondria, process similar to prokaryotes termination, there is only one factor known, called mitochondrial release factor 1 (mRF1). The research in all these systems has revealed important domains in release factors, which are involved in complicated process of termination of translation. This work summarizes new mechanistic aspects of termination of translation and shows some attempts of visualization of this process in many structural studies.

Exogenous control of mammalian gene expression via modulation of translational termination.

Here, we describe a system for the exogenous control of gene expression in mammalian cells that relies on the control of translational termination. To achieve gene regulation, we modified protein-coding sequences by introduction of a translational termination codon just downstream from the initiator AUG codon. Translation of the resulting mRNA leads to potent reduction in expression of the desired gene product. Expression of the gene product can be controlled by treating cells that express the mRNA with either aminoglycoside antibiotics or several nonantibiotic compounds. We show that the extent of regulation of gene expression can be substantial (60-fold) and that regulation can be achieved in the case of a variety of different genes, in different cultured cell lines and in primary cells in vivo. This gene regulation strategy offers significant advantages over existing methods for controlling gene expression and should have both immediate experimental application and possible clinical application.

Regulated readthrough: a new method for the alternative tagging and targeting of recombinant proteins.

We report here a new method for the alternative peptide tagging of recombinant proteins from mammalian cell lines. This method, which we called regulated readthrough, exploits the property of aminoglycoside antibiotics to promote translational readthrough of nonsense codons. The basic expression cassette includes a translational fusion between a gene of interest and a membrane targeting peptide, which are separated by a nonsense codon. In the presence of an aminoglycoside antibiotic, translational readthrough is promoted and results in the targeting of the fusion protein to the cell membrane, thus allowing the efficient flow cytometry-based isolation of cells expressing very high levels of recombinant protein. For downstream applications requiring the production of soluble recombinant protein, the cells are cultured in the absence of aminoglycoside, leading to an efficient translational termination. By combining different translation termination signals that exhibit various susceptibilities to aminoglycoside-mediated translational readthrough with flow cytometry capabilities, it is possible to use this technology for other applications such as functional library screening or monitoring the stability of recombinant protein production.

Ribosome occupancy of the yeast CPA1 upstream open reading frame termination codon modulates nonsense-mediated mRNA decay.

Saccharomyces cerevisiae CPA1 mRNA contains an upstream open reading frame (uORF) encoding the arginine attenuator peptide (AAP). Negative translational regulation of CPA1 occurs when the nascent AAP responds to arginine (Arg) by stalling ribosomes at the uORF termination codon. CPA1 expression is also controlled by nonsense-mediated mRNA decay (NMD). Using wild-type and decay-defective strains expressing CPA1-LUC, we determined how this uORF contributes to NMD control. Arg addition to media rapidly destabilized the CPA1 transcript in wild-type but not upf1delta cells. The wild-type uORF exerted translational control and induced NMD of CPA1-LUC; the mutated D13N uORF, which eliminates stalling and regulation, did not. Thus, regulation by NMD was not governed simply by ribosomes encountering the uORF terminator but appeared dependent on the AAP's ribosome-stalling ability. Improving the D13N uORF initiation context also promoted NMD. Hence, NMD appears to be triggered by increased ribosomal occupancy of the uORF termination codon.

Involvement of human release factors eRF3a and eRF3b in translation termination and regulation of the termination complex formation.

eRF3 is a GTPase associated with eRF1 in a complex that mediates translation termination in eukaryotes. In mammals, two genes encode two distinct forms of eRF3, eRF3a and eRF3b, which differ in their N-terminal domains. Both bind eRF1 and stimulate its release activity in vitro. However, whether both proteins can function as termination factors in vivo has not been determined. In this study, we used short interfering RNAs to examine the effect of eRF3a and eRF3b depletion on translation termination efficiency in human cells. By measuring the readthrough at a premature nonsense codon in a reporter mRNA, we found that eRF3a silencing induced an important increase in readthrough whereas eRF3b silencing had no significant effect. We also found that eRF3a depletion reduced the intracellular level of eRF1 protein by affecting its stability. In addition, we showed that eRF3b overexpression alleviated the effect of eRF3a silencing on readthrough and on eRF1 cellular levels. These results suggest that eRF3a is the major factor acting in translation termination in mammals and clearly demonstrate that eRF3b can substitute for eRF3a in this function. Finally, our data indicate that the expression level of eRF3a controls the formation of the termination complex by modulating eRF1 protein stability.

U2552 methylation at the ribosomal A-site is a negative modulator of translational accuracy.

We have recently identified RrmJ, the first encoded protein of the rrmJ-ftsH heat shock operon, as being the Um(2552) methyltransferase of 23S rRNA, and reported that rrmJ-deficient strains exhibit growth defects, reduced translation rates and reduced stability of 70S ribosomes. U2552 is an ubiquitously methylated residue. It belongs to the A loop of 23S RNA which is an essential component of the ribosome peptidyltransferase centre and interacts directly with aminoacyl(A)-site tRNA. In the present study, we show that a lack of U2552 methylation, obtained in rrmJ-deficient mutants, results in a decrease in programmed +1 and -1 translational frameshifing and a decrease in readthrough of UAA and UGA stop codons. The increased translational accuracy of rrmJ-deficient strains suggests that the interaction between aminoacyl-tRNA and U2552 is important for selection of the correct tRNA at the ribosomal A site, and supports the idea that translational accuracy in vivo is optimal rather than maximal, thus pointing to the participation of recoding events in the normal cell physiology.

Incomplete processing of peroxidase transcripts in the lignin degrading fungus Phanerochaete chrysosporium.

Phanerochaete chrysosporium has been thoroughly studied as a microbial model for lignin degradation. The enzymes lignin peroxidase (LiP) and manganese peroxidase (MnP), both encoded by several genes, play the main role in the cleavage of different lignin substructures. In this work, the expression of specific LiP and MnP transcripts in liquid medium and in a wood-containing soil system was studied by reverse transcription-PCR and subsequent cloning and sequencing of the products obtained. Splice variants of different LiP and MnP transcripts were observed in wood-containing soil incubations and in liquid cultures. The processed transcripts contained different numbers of complete introns. Since the presence of stop codons in several of these introns would prevent the synthesis of active enzyme, we propose that these transcripts arise as a result of incomplete processing rather than alternative splicing. Interestingly, analysis of splice variants from mnp genes led to the identification of a fourth actively transcribed gene coding for MnP in P. chrysosporium.

Predicting the efficiency of UAG translational stop signal through studies of physicochemical properties of its composite mono- and dinucleotides.

In this study, we explored the problem of predicting the UAG stop-codon read-through efficiency. The reported nucleotide sequences were first converted into physicochemical property vectors before being presented to a machine learning algorithm. Two sets of physicochemical properties were applied: one for mononucleosides (in terms of steric bulk, hydrophobicity and electronics) and another for dinucleotides. To the best of our knowledge, this is the first report of how dinucleotides are converted into principle components derived from NMR chemical shift data. A few efficiency prediction models were then derived and a comparison between mononucleoside and dinucleotide-based models was shown. In the derived models, the coefficients of these property based predictors lend themselves to bio-physical interpretations, an advantage which is demonstrated in this study via a prediction model based on the steric bulk factor. Although it is quite simple, the steric bulk factor model explained well the effect of sequence variations surrounding the amber stop codon and the tRNA bearing UCCU anticodon. We further proposed new alternatives at position -1 and +4 of a UAG stop codon sequence to enhance the readthrough efficiency. This research may contribute to a better understanding of the readthrough mechanisms and may also help to study the normal translation termination process.

Growth at low temperature suppresses readthrough of the UGA stop codon during the expression of Bacillus subtilis flgM gene in Escherichia coli.

The efficient production of recombinant proteins in Escherichia coli requires a proper termination of translation to ensure the synthesis of only the desired product. During the recombinant production of Bacillus subtilis flgM in E. coli, we detected an additional polypeptide of molecular mass higher than the expected, corresponding to a product of a translational readthrough of the UGA stop codon. In this paper we show that the readthrough was abolished when the synthesis of the recombinant protein was carried out at 25 degrees C. The possible causes that contribute to reduce the proportion of readthrough protein species against the correct terminated product are discussed.

Loading neurons with BAPTA-AM activates xbp1 processing indicative of induction of endoplasmic reticulum stress.

Loading cells with the calcium chelator BAPTA-AM is an analytical tool which has been used to suppress a rise in cytoplasmic calcium activity under various experimental conditions and thus, to evaluate the role of elevated cytoplasmic calcium levels in the process under investigation. BAPTA-AM may, however, not only have an isolated effect on cytoplasmic processes but also on functions of other subcellular compartments such as the endoplasmic reticulum (ER). Under conditions associated with ER dysfunction, the unfolded protein response is activated which is characterized by suppression of translation and processing of xbp1 mRNA, resulting in activation of the expression of genes coding for ER stress proteins. To investigate whether BAPTA-AM causes ER stress, primary neuronal cell cultures were loaded with varying amounts of BAPTA-AM. Exposure of cells to BAPTA-AM induced a marked rise in processed xbp1 mRNA levels, correlating with exposure times and BAPTA-AM concentrations in the medium used for loading. The increase in processed xbp1 mRNA was associated with suppression of protein synthesis and induction of cell injury. The results of this study indicate that loading primary neuronal cell cultures with BAPTA-AM activates xbp1 processing, implying that this calcium chelator does not have an isolated effect on cytoplasmic calcium activity but also an affect on ER function.

Terminating eukaryote translation: domain 1 of release factor eRF1 functions in stop codon recognition.

Eukaryote ribosomal translation is terminated when release factor eRF1, in a complex with eRF3, binds to one of the three stop codons. The tertiary structure and dimensions of eRF1 are similar to that of a tRNA, supporting the hypothesis that release factors may act as molecular mimics of tRNAs. To identify the yeast eRF1 stop codon recognition domain (analogous to a tRNA anticodon), a genetic screen was performed to select for mutants with disabled recognition of only one of the three stop codons. Nine out of ten mutations isolated map to conserved residues within the eRF1 N-terminal domain 1. A subset of these mutants, although wild-type for ribosome and eRF3 interaction, differ in their respective abilities to recognize each of the three stop codons, indicating codon-specific discrimination defects. Five of six of these stop codon-specific mutants define yeast domain 1 residues (I32, M48, V68, L123, and H129) that locate at three pockets on the eRF1 domain 1 molecular surface into which a stop codon can be modeled. The genetic screen results and the mutant phenotypes are therefore consistent with a role for domain 1 in stop codon recognition; the topology of this eRF1 domain, together with eRF1-stop codon complex modeling further supports the proposal that this domain may represent the site of stop codon binding itself.