UNIPROT:Q07644 - FACTA Search

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Query: UNIPROT:Q07644 (polypeptide)
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Termination of translation in higher organisms is a GTP-dependent process. However, in the structure of the single polypeptide chain release factor known so far (eRF1) there are no GTP binding motifs. Moreover, in prokaryotes, a GTP binding protein, RF3, stimulates translation termination. From these observations we proposed that a second eRF should exist, conferring GTP dependence for translation termination. Here, we have shown that the newly sequenced GTP binding Sup35-like protein from Xenopus laevis, termed eRF3, exhibits in vitro three important functional properties: (i) although being inactive as an eRF on its own, it greatly stimulates eRF1 activity in the presence of GTP and low concentrations of stop codons, resembling the properties of prokaryotic RF3; (ii) it binds and probably hydrolyses GTP; and (iii) it binds to eRF1. The structure of the C-domain of the X.laevis eRF3 protein is highly conserved with other Sup35-like proteins, as was also shown earlier for the eRF1 protein family. From these and our previous data, we propose that yeast Sup45 and Sup35 proteins belonging to eRF1 and eRF3 protein families respectively are also yeast termination factors. The absence of structural resemblance of eRF1 and eRF3 to prokaryotic RF1/2 and RF3 respectively, may point to the different evolutionary origin of the translation termination machinery in eukaryotes and prokaryotes. It is proposed that a quaternary complex composed of eRF1, eRF3, GTP and a stop codon of the mRNA is involved in termination of polypeptide synthesis in ribosomes.
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PMID:Termination of translation in eukaryotes is governed by two interacting polypeptide chain release factors, eRF1 and eRF3. 766 46

Two protein release factors (RFs) showing codon specificity, RF1 and RF2, are known to be required for polypeptide chain termination in Escherichia coli. A third protein component has also been described that stimulates termination in vitro, but it has remained uncertain whether this protein, RF3, participates in termination in vivo or is essential to cell growth. We report (i) the purification and N-terminal sequencing of RF3; (ii) the isolation of transposon insertion mutants similar to miaD, a suppressor of a leaky UAA mutation affecting the gene miaA, leading to enhanced nonsense suppression; (iii) the localization of the affected gene on the physical map of the chromosome; and (iv) the cloning and sequencing of the wild-type gene, providing proof that it encodes the factor RF3. We designate the gene prfC. Two transposon insertions were shown to interrupt the coding sequence of prfC, at codons 287 and 426. The enhanced nonsense suppression in the insertion mutants shows that the product participates in termination in vivo. The isolation of such mutants strongly suggests that the gene product is not essential to cell viability, though cell growth is affected. RF3 is a protein with a molecular weight of 59,460 containing 528 amino acids and displays much similarity to elongation factor EF-G, a GTP binding protein necessary for ribosomal translocation, and other GTP binding proteins known or thought to interact with the ribosome.
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PMID:Localization and characterization of the gene encoding release factor RF3 in Escherichia coli. 801 77

We have established a new in vitro assay for translational termination. It consists of 70 S ribosomes bound to a synthetic RNA minimessenger via interaction with P-site binding fMet-tRNAfMet. If the A-site codon is a stop signal, release activity can be measured by quantifying hydrolyzed formylmethionine. Characteristics of this assay in terms of reaction time, ion concentration, release factor RF1 and RF2 concentration, and competition with A-site-decoding tRNA are discussed. The new assay shows that polypeptide chain release activity is directly dependent on the presence of a stop codon in the ribosomal A-site.
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PMID:Ribosomal binding site of release factors RF1 and RF2. A new translational termination assay in vitro. 913 73

Two eukaryotic proteins involved in translation termination have recently been characterized in in vitro experiments. Eukaryotic release factor 1 (eRF1) catalyzes the release of the polypeptide chain without any stop codon specificity. The GTP-binding protein eRF3 confers GTP dependence to the termination process and stimulates eRF1 activity. We used tRNA-mediated nonsense suppression at different stop codons in a cat reporter gene to analyze the polypeptide chain release factor activities of the human eRF1 and eRF3 proteins overexpressed in human cells. In a chloramphenicol acetyltransferase assay, we measured the competition between the suppressor tRNA and the human release factors when a stop codon was present in the ribosomal A site. Whatever the stop codon (UAA, UAG, or UGA) present in the cat open reading frame, the overexpression of human eRF1 alone markedly decreased translational readthrough by suppressor tRNA. Thus, like the procaryotic release factors RF1 and RF2 in Escherichia coli, eRF1 seems to have an intrinsic antisuppressor activity in human cells. Levels of antisuppression of overexpression of both eRF3 and eRF1 were almost the same as those of overexpression of eRF1 alone, suggesting that eRF1-eRF3 complex-mediated termination may be controlled by the expression level of eRF1. Surprisingly, when overexpressed alone, eRF3 had an inhibitory effect on cat gene expression. The results of cat mRNA stability studies suggest that eRF3 inhibits gene expression at the transcriptional level. This indicates that in vivo, eRF3 may perform other functions, including the stimulation of eRF1 activity.
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PMID:Overexpression of human release factor 1 alone has an antisuppressor effect in human cells. 915 15

It is known from experiments with bacteria and eukaryotic viruses that readthrough of termination codons located within the open reading frame (ORF) of mRNAs depends on the availability of suppressor tRNA(s) and the efficiency of termination in cells. Consequently, the yield of readthrough products can be used as a measure of the activity of polypeptide chain release factor(s) (RF), key components of the translation termination machinery. Readthrough of the UAG codon located at the end of the ORF encoding the coat protein of beet necrotic yellow vein furovirus is required for virus replication. Constructs harbouring this suppressible UAG codon and derivatives containing a UGA or UAA codon in place of the UAG codon have been used in translation experiments in vitro in the absence or presence of human suppressor tRNAs. Readthrough can be virtually abolished by addition of bacterially-expressed eukaryotic RF1 (eRF1). Thus, eRF1 is functional towards all three termination codons located in a natural mRNA and efficiently competes in vitro with endogenous and exogenous suppressor tRNA(s) at the ribosomal A site. These results are consistent with a crucial role of eRF1 in translation termination and forms the essence of an in vitro assay for RF activity based on the abolishment of readthrough by eRF1.
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PMID:Eukaryotic release factor 1 (eRF1) abolishes readthrough and competes with suppressor tRNAs at all three termination codons in messenger RNA. 917 Oct 74

A prfA gene encoding polypeptide release factor RF1 was cloned from Thermus thermophilus. T thermophilus RF1 shares 68% homology with Escherichia coli RF1, and its overproduction reduced readthrough translation of UAG, not of UGA, in the lacZ gene. Rapid purification of T thermophilus RF1 was achieved by T7-RNA polymerase driven overexpression of T thermophilus RF1 protein with a C-terminal histidine tag.
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PMID:Cloning and overexpression of polypeptide release factor 1 of Thermus thermophilus. 925 37

Polypeptide chain termination in Escherichia coli is known to require two codon specific release factors, RF1 and RF2. A third factor, RF3, has been described to stimulate the termination. Earlier investigations have estimated the cellular content of factors RF1 and RF2. Two different immunological techniques for measuring the amount of RF3 per cell in crude E coli cell extracts are reported here, using a sensitive immunoblotting method and a sandwich assay by ELISA. Monoclonal murine antibodies and polyclonal rabbit antibodies were raised against extensively purified recombinant E coli RF3. The immunoblotting involves a specific monoclonal antibody (mAb), biotinylated second antibody and finally radioactive iodinated streptavidin. In the sandwich assay polyclonal antibodies are immobilised on a polystyrene surface before addition of crude cell extract; a specific mAb serves as primary antibody and an HRP-labelled anti-mouse Ig as secondary antibody. Both methods are accurate and rapid to perform. The number of RF3 molecules per cell in exponentially growing E coli cells was found to vary considerably according to the K12 strain examined and depended on the culture medium (from 20 to 500 molecules per cell), faster growth being positively correlated with the number of RF3 molecules per cell.
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PMID:Immunochemical determination of the cellular content of polypeptide chain release factor RF3 in Escherichia coli. 952 14

Prokaryotic translational release factors, RF1 and RF2, catalyze polypeptide release at UAG/UAA and UGA/UAA stop codons, respectively. In this study, we isolated a bacterial RF2 mutant (RF2*) containing an E167K substitution that restored the growth of a temperature-sensitive RF1 strain of Escherichia coli and the viability of a chromosomal RF1/RF2 double knockout. In both in vivo and in vitro polypeptide termination assays, RF2* catalyzed UAG/UAA termination, as does RF1, as well as UGA termination, showing that RF2* acquired omnipotent release activity. This result suggests that the E167K mutation abolished the putative third-base discriminator function of RF2. These findings are interpreted as indicating that prokaryotic and eukaryotic release factors share the same anticodon moiety and that only one omnipotent release factor is sufficient for bacterial growth, similar to the eukaryotic single omnipotent factor.
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PMID:Single amino acid substitution in prokaryote polypeptide release factor 2 permits it to terminate translation at all three stop codons. 965 58

Prokaryotic release factor RF3 is a stimulatory protein that increases the rate of translational termination by the decoding release factors RF1 and RF2. The favoured model for RF3 function is the recycling of RF1 and RF2 after polypeptide release by displacing the factors from the ribosome. In this study, we have demonstrated that RF3 also plays an indirect role in the decoding of stop signals of highly expressed genes and recoding sites by accentuating the influence of the base following the stop codon (+4 base) on termination signal strength. The efficiency of decoding strong stop signals (e.g. UAAU and UAAG) in vivo is markedly improved with increased RF3 activity, while weak signals (UGAC and UAGC) are only modestly affected. However, RF3 is not responsible for the +4 base influence on termination signal strength, since prfC- strains lacking the protein still exhibit the same qualitative effect. The differential effect of RF3 at stop signals can be mimicked by modest overexpression of decoding RF. These findings can be interpreted according to current views of RF3 as a recycling factor, which functions to maintain the concentration of free decoding RF at stop signals, some of which are highly responsive to changes in RF levels.
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PMID:Indirect regulation of translational termination efficiency at highly expressed genes and recoding sites by the factor recycling function of Escherichia coli release factor RF3. 992 32

The pathway of bacterial ribosome recycling following translation termination has remained obscure. Here, we elucidate two essential steps and describe the roles played by the three translation factors EF-G, RRF, and IF3. Release factor RF3 is known to catalyze the dissociation of RF1 or RF2 from ribosomes after polypeptide release. We show that the next step is dissociation of 50S subunits from the 70S posttermination complex and that it is catalyzed by RRF and EF-G and requires GTP hydrolysis. Removal of deacylated tRNA from the resulting 30S:mRNA:tRNA posttermination complex is then necessary to permit rapid 30S subunit recycling. We show that this step requires initiation factor IF3, whose role was previously thought to be restricted to promoting specific 30S initiation complex formation from free 30S subunits.
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PMID:Novel roles for classical factors at the interface between translation termination and initiation. 1036 Jan 76

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