Release factors and their role as decoding proteins: specificity and fidelity for termination of protein synthesis

Eukaryotic ribosome display for antibody discovery: A review

Monoclonal antibody biologics have significantly transformed the therapeutic landscape within the biopharmaceutical industry, partly due to the utilisation of discovery technologies such as the hybridoma method and phage display. While these established platforms have streamlined the development process to date, their reliance on cell transformation for antibody identification faces limitations related to library diversification and the constraints of host cell physiology. Cell-free systems like ribosome display offer a complementary approach, enabling antibody selection in a completely in vitro setting while harnessing enriched cellular molecular machinery. This review aims to provide an overview of the fundamental principles underlying the ribosome display method and its potential for advancing antibody discovery and development.

Distinct mechanisms of the human mitoribosome recycling and antibiotic resistance

Ribosomes are recycled for a new round of translation initiation by dissociation of ribosomal subunits, messenger RNA and transfer RNA from their translational post-termination complex. Here we present cryo-EM structures of the human 55S mitochondrial ribosome (mitoribosome) and the mitoribosomal large 39S subunit in complex with mitoribosome recycling factor (RRF_mt) and a recycling-specific homolog of elongation factor G (EF-G2_mt). These structures clarify an unusual role of a mitochondria-specific segment of RRF_mt, identify the structural distinctions that confer functional specificity to EF-G2_mt, and show that the deacylated tRNA remains with the dissociated 39S subunit, suggesting a distinct sequence of events in mitoribosome recycling. Furthermore, biochemical and structural analyses reveal that the molecular mechanism of antibiotic fusidic acid resistance for EF-G2_mt is markedly different from that of mitochondrial elongation factor EF-G1_mt, suggesting that the two human EF-G_mts have evolved diversely to negate the effect of a bacterial antibiotic.

High-resolution cryo-EM structures and biochemical analyses of the human mitoribosome, in complex with mitochondria-specific factors mediating mitoribosome recycling, RRFmt and EF-G2mt, offer insight into mechanisms of mitoribosome recycling and resistance to antibiotic fusidic acid.

Translation can affect the antisense activity of RNase H1-dependent oligonucleotides targeting mRNAs

RNase H1-dependent antisense oligonucleotides (ASOs) can degrade complementary RNAs in both the nucleus and the cytoplasm. Since cytoplasmic mRNAs are actively engaged in translation, ASO activity may thus be affected by translating ribosomes that scan the mRNAs. Here we show that mRNAs associated with ribosomes can be cleaved using ASOs and that translation can alter ASO activity. Translation inhibition tends to increase ASO activity when targeting the coding regions of efficiently translated mRNAs, but not nuclear non-coding RNAs or less efficiently translated mRNAs. Increasing the level of RNase H1 protein eliminated the enhancing effects of translation inhibition on ASO activity, suggesting that RNase H1 recruitment to ASO/mRNA heteroduplexes is a rate limiting step and that translating ribosomes can inhibit RNase H1 recruitment. Consistently, ASO activity was not increased by translation inhibition when targeting the 3′ UTRs, independent of the translation efficiency of the mRNAs. Contrarily, the activity of 3′ UTR-targeting ASOs tended to be reduced upon translation inhibition, likely due to decreased accessibility. These results indicate that ASO activity can be affected by the translation process, and the findings also provide important information toward helping better ASO drug design.

Eukaryotic peptide chain release factor 1 participates in translation termination of specific cysteine-poor prolamines in rice endosperm

Prolamines are alcohol-soluble proteins classified as either cysteine-poor (CysP) or cysteine-rich (CysR) based on whether they can be alcohol-extracted without or with reducing agents, respectively. In rice esp1 mutants, various CysP prolamines exhibit both reduced and normal amounts of isoelectric focusing bands, indicating that the mutation affects only certain prolamine classes. To examine the genetic regulation of CysP prolamine synthesis and accumulation, we constructed a high-resolution genetic linkage map of ESP1. The ESP1 gene was mapped to within a 20 kb region on rice chromosome 7. Sequencing analysis of annotated genes in this region revealed a single-nucleotide polymorphism within eukaryotic peptide chain release factor (eRF1), which participates in stop-codon recognition and nascent-polypeptide release from ribosomes during translation. A subsequent complementation test revealed that ESP1 encodes eRF1. We also identified UAA as the stop codon of CysP prolamines with reduced concentration in esp1 mutants. Recognition assays and microarray analysis confirmed that ESP1/eRF1 recognizes UAA/UAG, but not UGA. Our results provide convincing evidence that ESP1/eRF1 participates in the translation termination of CysP prolamines during seed development.

CRISPRi-Manipulation of Genetic Code Expansion via RF1 for Reassignment of Amber Codon in Bacteria

The precise engineering of proteins in bacteria via the amber codon has been hampered by the poor incorporation of unnatural amino acid (UAA). Here we explored the amber assignment as a sense codon for UAA by CRISPRi targeting release factor 1 (RF1). Scanning of RF1 gene with sgRNAs identified target loci that differentiate RF1 repressions. Quantitation of RF1 repressions versus UAA incorporation indicated an increasing interrelation with the amber reassignment maximized upon RF1 knockdown to ~30%, disclosing the beneficial role of RF1 in amber assignment. However, further RF1 repression reversed this trend resulting from the detrimental effects on host cell growth, disclosing the harmful aspect of RF1 in reassignment of the amber codon. Our data indicate RF1 as a switch manipulating genetic code expansion and pave a direction via CRISPRi for precise engineering and efficient production of proteins in bacteria.

Selection of Recombinant Human Antibodies

Since the development of therapeutic antibodies the demand of recombinant human antibodies is steadily increasing. Traditionally, therapeutic antibodies were generated by immunization of rat or mice, the generation of hybridoma clones, cloning of the antibody genes and subsequent humanization and engineering of the lead candidates. In the last few years, techniques were developed that use transgenic animals with a human antibody gene repertoire. Here, modern recombinant DNA technologies can be combined with well established immunization and hybridoma technologies to generate already affinity maturated human antibodies. An alternative are in vitro technologies which enabled the generation of fully human antibodies from antibody gene libraries that even exceed the human antibody repertoire. Specific antibodies can be isolated from these libraries in a very short time and therefore reduce the development time of an antibody drug at a very early stage.In this review, we describe different technologies that are currently used for the in vitro and in vivo generation of human antibodies.

Biotechnology techniques for the development of new tumor specific peptides

Peptides, proteins and antibodies are promising candidates as carriers for radionuclides in endoradiotherapy. This novel class of pharmaceuticals offers a great potential for the targeted therapy of cancer. The fact that some receptors are overexpressed in several tumor types and can be targeted by small peptides, proteins or antibodies conjugated to radionuclides has been used in the past for the development of peptide endoradiotherapeutic agents such as (90)Y-DOTATOC or radioimmunotherapy of lymphomas with Zevalin. These procedures have been shown to be powerful options for the treatment of cancer patients. Design of new peptide libraries and scaffolds combined with biopanning techniques like phage and ribosome display may lead to the discovery of new specific ligands for target structures overexpressed in malignant tumors. Display methods are high throughput systems which select for high affinity binders. These methods allow the screening of a vast amount of potential binding motifs which may be exposed to either cells overexpressing the target structures or in a cell-free system to the protein itself. Labelling these binders with radionuclides creates new potential tracers for application in diagnosis and endoradiotherapy. This review highlights the advantages and problems of phage and ribosome display for the identification and evaluation of new tumor specific peptides.

Three distinct peptides from the N domain of translation termination factor eRF1 surround stop codon in the ribosome

To study positioning of the polypeptide release factor eRF1 toward a stop signal in the ribosomal decoding site, we applied photoactivatable mRNA analogs, derivatives of oligoribonucleotides. The human eRF1 peptides cross-linked to these short mRNAs were identified. Cross-linkers on the guanines at the second, third, and fourth stop signal positions modified fragment 31-33, and to lesser extent amino acids within region 121-131 (the "YxCxxxF loop") in the N domain. Hence, both regions are involved in the recognition of the purines. A cross-linker at the first uridine of the stop codon modifies Val66 near the NIKS loop (positions 61-64), and this region is important for recognition of the first uridine of stop codons. Since the N domain distinct regions of eRF1 are involved in a stop-codon decoding, the eRF1 decoding site is discontinuous and is not of "protein anticodon" type. By molecular modeling, the eRF1 molecule can be fitted to the A site proximal to the P-site-bound tRNA and to a stop codon in mRNA via a large conformational change to one of its three domains. In the simulated eRF1 conformation, the YxCxxxF motif and positions 31-33 are very close to a stop codon, which becomes also proximal to several parts of the C domain. Thus, in the A-site-bound state, the eRF1 conformation significantly differs from those in crystals and solution. The model suggested for eRF1 conformation in the ribosomal A site and cross-linking data are compatible.

Translation at the single-molecule level

Decades of studies have established translation as a multistep, multicomponent process that requires intricate communication to achieve high levels of speed, accuracy, and regulation. A crucial next step in understanding translation is to reveal the functional significance of the large-scale motions implied by static ribosome structures. This requires determining the trajectories, timescales, forces, and biochemical signals that underlie these dynamic conformational changes. Single-molecule methods have emerged as important tools for the characterization of motion in complex systems, including translation. In this review, we chronicle the key discoveries in this nascent field, which have demonstrated the power and promise of single-molecule techniques in the study of translation.

Effects of the [PSI+] prion on rates of adaptation in yeast

The [PSI(+)] prion in yeast has been shown to improve short-term growth in some environments, but its effects on rates of adaptation have not been assessed before now. We adapted three yeast genotypes to three novel environments in the presence and the absence of the prion. There were significant differences in adaptation rates between lines with different combinations of genotype, environment, and prion status. We saw no consistent effect, however, of the prion on the rate of adaptation to new environments. A major factor affecting the rate of adaptation was initial fitness in the new environment: lines with low initial fitness evolved faster than lines with high initial fitness.

mtRF1a is a human mitochondrial translation release factor decoding the major termination codons UAA and UAG

Human mitochondria contain their own genome, encoding 13 polypeptides that are synthesized within the organelle. The molecular processes that govern and facilitate this mitochondrial translation remain unclear. Many key factors have yet to be characterized—for example, those required for translation termination. All other systems have two classes of release factors that either promote codon-specific hydrolysis of peptidyl-tRNA (class I) or lack specificity but stimulate the dissociation of class I factors from the ribosome (class II). One human mitochondrial protein has been previously identified in silico as a putative member of the class I release factors. Although we could not confirm the function of this factor, we report the identification of a different mitochondrial protein, mtRF1a, that is capable in vitro and in vivo of terminating translation at UAA/UAG codons. Further, mtRF1a depletion in HeLa cells led to compromised growth in galactose and increased production of reactive oxygen species.

Accommodating the bacterial decoding release factor as an alien protein among the RNAs at the active site of the ribosome

The decoding release factor (RF) triggers termination of protein synthesis by functionally mimicking a tRNA to span the decoding centre and the peptidyl transferase centre (PTC) of the ribosome. Structurally, it must fit into a site crafted for a tRNA and surrounded by five other RNAs, namely the adjacent peptidyl tRNA carrying the completed polypeptide, the mRNA and the three rRNAs. This is achieved by extending a structural domain from the body of the protein that results in a critical conformational change allowing it to contact the PTC. A structural model of the bacterial termination complex with the accommodated RF shows that it makes close contact with the first, second and third bases of the stop codon in the mRNA with two separate loops of structure: the anticodon loop and the loop at the tip of helix alpha5. The anticodon loop also makes contact with the base following the stop codon that is known to strongly influence termination efficiency. It confirms the close contact of domain 3 of the protein with the key RNA structures of the PTC. The mRNA signal for termination includes sequences upstream as well as downstream of the stop codon, and this may reflect structural restrictions for specific combinations of tRNA and RF to be bound onto the ribosome together. An unbiased SELEX approach has been investigated as a tool to identify potential rRNA-binding contacts of the bacterial RF in its different binding conformations within the active centre of the ribosome.

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.

Comparative analysis of base biases around the stop codons in six eukaryotes

Using full-length cDNA sequences, a comparative analysis of sequence patterns around the stop codons in six eukaryotes was performed. Here, it was showed that the codon immediately before and after the stop codons (defined as -1 codon and +1 codon, respectively) were much more biased than other examined positions, especially at the second position of -1 codons and the first position of +1 codons which were rich in As/Us and purines, respectively, for most species. The author speculated that strongly biased sequence pattern from position -2 to +4 might act as an extended translation termination signal. Translation termination was catalyzed by release factors that recognized the stop codons. The multiple amino acid sequence alignment of eukaryotic release factor 1 (eRF1) of 20 species showed that there were 16 residue sites that were strictly conserved, especially the invariant amino acids Ile70 and Lys71. Accordingly, it could be inferred that those candidate amino acids might involve in the recognition process. Moreover, the possible stop signal recognition hypothesis was also discussed herein.

Effect of energy source on the efficiency of translational termination during cell-free protein synthesis

We studied how the fidelity of translation termination is affected by the method of ATP regeneration during cell-free protein synthesis. During the in vivo expression of hEPO, whose termination is directed by the UGA codon, we found that substantial proportions of the translational products showed a larger molecular weight than expected. Similar results were obtained in a cell-free synthesis reaction using phosphoenol pyruvate (PEP) or 3-phosphoglycerate (3PG) for ATP regeneration. However, when the energy source was switched to creatine phosphate (CP), the readthrough of the UGA codon was completely repressed and only the target protein of the correct size was expressed in a high yield. To the best of our knowledge, this is the first report describing the relationship between the regeneration of nucleotide triphosphates and protein readthrough, and we also believe that the discovery would pave the way to the selective and efficient expression of target proteins in cell-free protein synthesis systems.

Pyrrolysine and Selenocysteine Use Dissimilar Decoding Strategies

Selenocysteine (Sec) and pyrrolysine (Pyl) are known as the 21st and 22nd amino acids in protein. Both are encoded by codons that normally function as stop signals. Sec specification by UGA codons requires the presence of a cis-acting selenocysteine insertion sequence (SECIS) element. Similarly, it is thought that Pyl is inserted by UAG codons with the help of a putative pyrrolysine insertion sequence (PYLIS) element. Herein, we analyzed the occurrence of Pyl-utilizing organisms, Pyl-associated genes, and Pyl-containing proteins. The Pyl trait is restricted to several microbes, and only one organism has both Pyl and Sec. We found that methanogenic archaea that utilize Pyl have few genes that contain in-frame UAG codons, and many of these are followed with nearby UAA or UGA codons. In addition, unambiguous UAG stop signals could not be identified. This bias was not observed in Sec-utilizing organisms and non-Pyl-utilizing archaea, as well as with other stop codons. These observations as well as analyses of the coding potential of UAG codons, overlapping genes, and release factor sequences suggest that UAG is not a typical stop signal in Pyl-utilizing archaea. On the other hand, searches for conserved Pyl-containing proteins revealed only four protein families, including methylamine methyltransferases and transposases. Only methylamine methyltransferases matched the Pyl trait and had conserved Pyl, suggesting that this amino acid is used primarily by these enzymes. These findings are best explained by a model wherein UAG codons may have ambiguous meaning and Pyl insertion can effectively compete with translation termination for UAG codons obviating the need for a specific PYLIS structure. Thus, Sec and Pyl follow dissimilar decoding and evolutionary strategies.

Applications of ribosome display to antibody drug discovery

Ribosome display is a polymerase chain reaction-based in vitro display technology that is well suited to the selection and evolution of high affinity antibodies. Both eukaryotic and prokaryotic translation systems have been applied to ribosome display, and the technology's utility has been demonstrated in the antibody isolation process. In particular, ribosome display lends itself to the evolution of functional characteristics, such as potency, of lead candidate antibodies to provide therapeutic antibodies. Large libraries (10(12)) can be rapidly constructed, antibodies selected, and sequence space extensively explored by targeted mutagenesis techniques or by random mutagenesis throughout the antibody sequence. Using such approaches in ribosome display systems lead antibodies derived from phage display or from immunised animals have been improved > 1000-fold in potency within 6 months. This review will discuss the technology and give an insight into how ribosome display is being applied to the antibody lead discovery and optimisation processes.

Complex signals in the genomic 3' nontranslated region of bovine viral diarrhea virus coordinate translation and replication of the viral RNA

The genomes of positive-strand RNA viruses strongly resemble cellular mRNAs. However, besides operating as a messenger to generate the virus-encoded proteins, the viral RNA serves also as a template during replication. A central issue of the viral life cycle, the coordination of protein and RNA synthesis, is yet poorly understood. Examining bovine viral diarrhea virus (BVDV), we report here on the role of the variable 3'V portion of the viral 3' nontranslated region (3'NTR). Genetic studies and structure probing revealed that 3'V represents a complex RNA motif that is composed of synergistically acting sequence and structure elements. Correct formation of the 3'V motif was shown to be an important determinant of the viral RNA replication process. Most interestingly, we found that a proper conformation of 3'V is required for accurate termination of translation at the stop-codon of the viral open reading frame and that efficient termination of translation is essential for efficient replication of the viral RNA. Within the viral 3'NTR, the complex 3'V motif constitutes also the binding site of recently characterized cellular host factors, the so-called NFAR proteins. Considering that the NFAR proteins associate also with the 5'NTR of the BVDV genome, we propose a model where the viral 3'NTR has a bipartite functional organization: The conserved 3' portion (3'C) is part of the nascent replication complex; the variable 5' portion (3'V) is involved in the coordination of the viral translation and replication. Our data suggest the accuracy of translation termination as a sophisticated device determining viral adaptation to the host.

In-vitro protein evolution by ribosome display and mRNA display

In-vitro display technologies combine two important advantages for identifying and optimizing ligands by evolutionary strategies. First, by obviating the need to transform cells in order to generate and select libraries, they allow a much higher library diversity. Second, by including PCR as an integral step in the procedure, they make PCR-based mutagenesis strategies convenient. The resulting iteration between diversification and selection allows true Darwinian protein evolution to occur in vitro. We describe two such selection methods, ribosome display and mRNA display. In ribosome display, the translated protein remains connected to the ribosome and to its encoding mRNA; the resulting ternary complex is used for selection. In mRNA display, mRNA is first translated and then covalently bonded to the protein it encodes, using puromycin as an adaptor molecule. The covalent mRNA-protein adduct is purified from the ribosome and used for selection. Successful examples of high-affinity, specific target-binding molecules selected by in-vitro display methods include peptides, antibodies, enzymes, and engineered scaffolds, such as fibronectin type III domains and synthetic ankyrins, which can mimic antibody function.

The Molecular Mechanics of Eukaryotic Translation

Great advances have been made in the past three decades in understanding the molecular mechanics underlying protein synthesis in bacteria, but our understanding of the corresponding events in eukaryotic organisms is only beginning to catch up. In this review we describe the current state of our knowledge and ignorance of the molecular mechanics underlying eukaryotic translation. We discuss the mechanisms conserved across the three kingdoms of life as well as the important divergences that have taken place in the pathway.

Divergent tRNA-like element supports initiation, elongation, and termination of protein biosynthesis

The cricket paralysis virus internal ribosome entry site (IRES) can, in the absence of canonical initiation factors and initiator tRNA (Met-tRNAi), occupy the ribosomal P-site and assemble 80S ribosomes. Here we show that the IRES assembles mRNA-80S ribosome complexes by recruitment of 60S subunits to preformed IRES-40S complexes. Addition of eukaryotic elongation factors eEF1A and eEF2 and aminoacylated elongator tRNAs resulted in the synthesis of peptides, implying that the IRES RNA itself mimics the function of Met-tRNAi in the P-site to trigger the first translocation step without peptide bond formation. IRES-80S complexes that contained a stop codon in the A-site recruited eukaryotic release factor eRF1, resulting in ribosome rearrangements in a surprisingly eEF2-dependent manner. Thus, this P-site-occupying IRES directs the assembly of 80S ribosomes, sets the translational reading frame, and mimics the functions of both Met-tRNAi and peptidyl tRNA to support elongation and termination.

Stop codon recognition and interactions with peptide release factor RF3 of truncated and chimeric RF1 and RF2 from Escherichia coli

Release factors RF1 and RF2 recognize stop codons present at the A-site of the ribosome and activate hydrolysis of peptidyl-tRNA to release the peptide chain. Interactions with RF3, a ribosome-dependent GTPase, then initiate a series of reactions that accelerate the dissociation of RF1 or RF2 and their recycling between ribosomes. Two regions of Escherichia coli RF1 and RF2 were identified previously as involved in stop codon recognition and peptidyl-tRNA hydrolysis. We show here that removing the N-terminal domain of RF1 or RF2 or exchanging this domain between the two factors does not affect RF specificity but has different effects on the activity of RF1 and RF2: truncated RF1 remains highly active and able to support rapid cell growth, whereas cells with truncated RF2 grow only poorly. Transplanting a loop of 13 amino acid residues from RF2 to RF1 switches the stop codon specificity. The interaction of the truncated factors with RF3 on the ribosome is defective: they fail to stimulate guanine nucleotide exchange on RF3, recycling is not stimulated by RF3, and nucleotide-free RF3 fails to stabilize the binding of RF1 or RF2 to the ribosome. However, the N-terminal domain seems not to be required for the expulsion of RF1 or RF2 by RF3:GTP.

Survey for g-proteins in the prokaryotic genomes: prediction of functional roles based on classification

The members of the family of G-proteins are characterized by their ability to bind and hydrolyze guanosine triphosphate (GTP) to guanosine diphosphate (GDP). Despite a common biochemical function of GTP hydrolysis shared among the members of the family of G-proteins, they are associated with diverse biological roles. The current work describes the identification and detailed analysis of the putative G-proteins encoded in the completely sequenced prokaryotic genomes. Inferences on the biological roles of these G-proteins have been obtained by their classification into known functional subfamilies. We have identified 497 G-proteins in 42 genomes. Seven small GTP-binding protein homologues have been identified in prokaryotes with at least two of the diagnostic sequence motifs of G-proteins conserved. The translation factors have the largest representation (234 sequences) and are found to be ubiquitous, which is consistent with their critical role in protein synthesis. The GTP_OBG subfamily comprises of 79 sequences in our dataset. A total of 177 sequences belong to the subfamily of GTPase of unknown function and 154 of these could be associated with domains of known functions such as cell cycle regulation and t-RNA modification. The large GTP-binding proteins and the alpha-subunit of heterotrimeric G-proteins are not detected in the genomes of the prokaryotes surveyed.

Stop codons and UGG promote efficient binding of the polypeptide release factor eRF1 to the ribosomal A site

To investigate the codon dependence of human eRF1 binding to the mRNA-ribosome complex, we examined the formation of photocrosslinks between ribosomal components and mRNAs bearing a photoactivable 4-thiouridine probe in the first position of the codon located in the A site. Addition of eRF1 to the phased mRNA-ribosome complexes triggers a codon-dependent quenching of crosslink formation. The concentration of eRF1 triggering half quenching ranges from low for the three stop codons, to intermediate for s4UGG and high for other near-cognate triplets. A theoretical analysis of the photochemical processes occurring in a two-state bimolecular model raises a number of stringent conditions, fulfilled by the system studied here, and shows that in any case sound KD values can be extracted if the ratio mT/KD<<1 (mT is total concentration of mRNA added). Considering the KD values obtained for the stop, s4UGG and sense codons (approximately 0.06 microM, 0.45 microM and 2.3 microM, respectively) and our previous finding that only the stop and s4UGG codons are able to promote formation of an eRF1-mRNA crosslink, implying a role for the NIKS loop at the tip of the N domain, we propose a two-step model for eRF1 binding to the A site: a codon-independent bimolecular step is followed by an isomerisation step observed solely with stop and s4UGG codons. Full recognition of the stop codons by the N domain of eRF1 triggers a rearrangement of bound eRF1 from an open to a closed conformation, allowing the universally conserved GGQ loop at the tip of the M domain to come into close proximity of the peptidyl transferase center of the ribosome. UGG is expected to behave as a cryptic stop codon, which, owing to imperfect eRF1-codon recognition, does not allow full reorientation of the M domain of eRF1. As far as the physical steps of eRF1 binding to the ribosome are considered, they appear to closely mimic the behaviour of the tRNA/EF-Tu/GTP complex, but clearly eRF1 is endowed with a greater conformational flexibility than tRNA.

The ribosomal A site-bound sense and stop codons are similarly positioned towards the A1823-A1824 dinucleotide of the 18S ribosomal RNA

Positioning of the mRNA codon towards the 18S ribosomal RNA in the A site of human 80S ribosomes has been studied applying short mRNA analogs containing either the stop codon UAA or the sense codon UCA with a perfluoroaryl azide group at the uridine residue. Bound to the ribosomal A site, a modified codon crosslinks exclusively to the 40S subunits under mild UV irradiation. This result is inconsistent with the hypothesis [Ivanov et al. (2001) RNA 7, 1683-1692] which requires direct contact between the large rRNA and the stop codon of the mRNA as recognition step at translation termination. Both sense and stop codons crosslink to the same A1823/A1824 invariant dinucleotide in helix 44 of 18S rRNA. The data point to the resemblance between the ternary complexes formed at elongation (sense codon.aminoacyl-tRNA.AA dinucleotide of 18S rRNA) and termination (stop codon.eRF1.AA dinucleotide of 18S rRNA) steps of protein synthesis and support the view that eRF1 may be considered as a functional mimic of aminoacyl-tRNA.

Assessing functional divergence in EF-1alpha and its paralogs in eukaryotes and archaebacteria

A number of methods have recently been published that use phylogenetic information extracted from large multiple sequence alignments to detect sites that have changed properties in related protein families. In this study we use such methods to assess functional divergence between eukaryotic EF-1alpha (eEF-1alpha), archaebacterial EF-1alpha (aEF-1alpha) and two eukaryote-specific EF-1alpha paralogs-eukaryotic release factor 3 (eRF3) and Hsp70 subfamily B suppressor 1 (HBS1). Overall, the evolutionary modes of aEF-1alpha, HBS1 and eRF3 appear to significantly differ from that of eEF-1alpha. However, functionally divergent (FD) sites detected between aEF-1alpha and eEF-1alpha only weakly overlap with sites implicated as putative EF-1beta or aminoacyl-tRNA (aa-tRNA) binding residues in EF-1alpha, as expected based on the shared ancestral primary translational functions of these two orthologs. In contrast, FD sites detected between eEF-1alpha and its paralogs significantly overlap with the putative EF-1beta and/or aa-tRNA binding sites in EF-1alpha. In eRF3 and HBS1, these sites appear to be released from functional constraints, indicating that they bind neither eEF-1beta nor aa-tRNA. These results are consistent with experimental observations that eRF3 does not bind to aa-tRNA, but do not support the 'EF-1alpha-like' function recently proposed for HBS1. We re-assess the available genetic data for HBS1 in light of our analyses, and propose that this protein may function in stop codon-independent peptide release.

Mapping functionally important motifs SPF and GGQ of the decoding release factor RF2 to the Escherichia coli ribosome by hydroxyl radical footprinting. Implications for macromolecular mimicry and structural changes in RF2

The function of the decoding release factor (RF) in translation termination is to couple cognate recognition of the stop codon in the mRNA with hydrolysis of the completed polypeptide from its covalently linked tRNA. For this to occur, the RF must interact with specific A-site components of the active centers within both the small and large ribosomal subunits. In this work, we have used directed hydroxyl radical footprinting to map the ribosomal binding site of the Escherichia coli class I release factor RF2, during translation termination. In the presence of the cognate UGA stop codon, residues flanking the universally conserved (250)GGQ(252) motif of RF2 were each shown to footprint to the large ribosomal subunit, specifically to conserved elements of the peptidyltransferase and GTPase-associated centers. In contrast, residues that flank the putative "peptide anticodon" of RF2, (205)SPF(207), were shown to make a footprint in the small ribosomal subunit at positions within well characterized 16 S rRNA motifs in the vicinity of the decoding center. Within the recently solved crystal structure of E. coli RF2, the GGQ and SPF motifs are separated by 23 A only, a distance that is incompatible with the observed cleavage sites that are up to 100 A apart. Our data suggest that RF2 may undergo gross conformational changes upon ribosome binding, the implications of which are discussed in terms of the mechanism of RF-mediated termination.

Viable nonsense mutants for the essential gene SUP45 of Saccharomyces cerevisiae

BACKGROUND

Termination of protein synthesis in eukaryotes involves at least two polypeptide release factors (eRFs) - eRF1 and eRF3. The highly conserved translation termination factor eRF1 in Saccharomyces cerevisiae is encoded by the essential gene SUP45.

RESULTS

We have isolated five sup45-n (n from nonsense) mutations that cause nonsense substitutions in the following amino acid positions of eRF1: Y53 --> UAA, E266 --> UAA, L283 --> UAA, L317 --> UGA, E385 --> UAA. We found that full-length eRF1 protein is present in all mutants, although in decreased amounts. All mutations are situated in a weak termination context. All these sup45-n mutations are viable in different genetic backgrounds, however their viability increases after growth in the absence of wild-type allele. Any of sup45-n mutations result in temperature sensitivity (37 degrees C). Most of the sup45-n mutations lead to decreased spore viability and spores bearing sup45-n mutations are characterized by limited budding after germination leading to formation of microcolonies of 4-20 cells.

CONCLUSIONS

Nonsense mutations in the essential gene SUP45 can be isolated in the absence of tRNA nonsense suppressors.

Making sense of mimic in translation termination

The mechanism of translation termination has long been a puzzle. Recent crystallographic evidence suggests that the eukaryotic release factor (eRF1), the bacterial release factor (RF2) and the ribosome recycling factor (RRF) all mimic a tRNA structure, whereas biochemical and genetic evidence supports the idea of a tripeptide 'anticodon' in bacterial release factors RF1 and RF2. However, the suggested structural mimicry of RF2 is not in agreement with the tripeptide 'anticodon' hypothesis and, furthermore, recently determined structures using cryo-electron microscopy show that, when bound to the ribosome, RF2 has a conformation that is distinct from the RF2 crystal structure. In addition, hydroxyl-radical probings of RRF on the ribosome are not in agreement with the simple idea that RRF mimics tRNA in the ribosome A-site. All of this evidence seriously questions the simple concept of structural mimicry between proteins and RNA and, thus, leaves only functional mimicry of protein factors of translation to be investigated.

Termination of translation: interplay of mRNA, rRNAs and release factors?

Termination of translation in eukaryotes has focused recently on functional anatomy of polypeptide chain release factor, eRF1, by using a variety of different approaches. The tight correlation between the domain structure and different functions of eRF1 has been revealed. Independently, the role of prokaryotic RF1/2 in GTPase activity of RF3 has been deciphered, as well as RF3 function itself.

Molecular Mimicry in the Decoding of Translational Stop Signals

Molecular mimicry was a concept that was revived as we understood more about the ligands that bound to the active center of the ribosome, and the characteristics of the active center itself. It has been particularly useful for the termination phase of protein synthesis, because for many years this major process seemed not only to be out of step) with the initiation and elongation phases but also there were no common features of the process between eubacteria and eukaryotes. As the facts that supported molecular mimicry emerged, it was seen that the protein factors that facilitated polypeptide chain release when the decoding of an mRNA was complete had common features with the ligands involved in the other phases. Moreover, now common features and mechanisms began to emerge between the eubacterial and eukaryotic RFs and suddenly there seemed to be remarkable synergy between the external ligands and commonality in at least some features of the mechanistic prnciples. Almost 10 years after molecular mimicry took hold as a framework concept, we can now see that this idea is probably too simple. For example, structural mimicry can be apparent if there are extensive conformational changes either in the ribosome active center or in the ligand itself or, most likely, both. Early indications are that the bacterial RF may indeed undergo extensive conformational changes from its solution structure to achieve this accommodation. Thus, as important if not more important than structural and functional mimicry among the ligands, might be their accomodation of a common single active center made up of at least three parts to carry out a complex series of reactions. One part of the ribosomal active center is committed to decoding, a second is committed to the chemistry of putting the protein together and releasing it, and a third part, perhaps residing in the subdomains, is committed to binding ligands so that they can perform their respective single or multiple functions. It might be more accurate to regard the decoding RF as the cuckoo taking over the nest that was crafted and honed through evolution by another, the tRNA. A somewhat ungainly RF, perhaps bigger in dimensions than the tRNA, is able, nevertheless, like the cuckoo, to maneuvre into the nest. Perhaps it pushes the nest a little out of shape, but is still able to use the site for its own functions of stop signal decoding and for facilitating the release of the polypeptide. The term molecular mimicry has been dominant in the literature for a period of important advances in the understanding of protein synthesis. When the first structures of the ribosome appeared, the concept survived and was seen to be valid still. Now, we are at the stage of understanding the more detailed molecular interactions between ligands and the rRNA in particular, and how subtle changes in localized spatial orientations of atoms occur within these interactions. The simplicity of the original concept of mimicry will inevitably be blurred by this more detailed analysis. Nevertheless, it has provided a significant set of principles that allowed development of experimental programs to enhance our understanding of the dynamic events at this remarkable active site at the interface between the two subunits of this fascinating cell organelle, the ribosome.

Orientation of ribosome recycling factor in the ribosome from directed hydroxyl radical probing

Ribosome recycling factor (RRF) disassembles posttermination complexes in conjunction with elongation factor EF-G, liberating ribosomes for further rounds of translation. The striking resemblance of its L-shaped structure to that of tRNA has suggested that the mode of action of RRF may be based on mimicry of tRNA. Directed hydroxyl radical probing of 16S and 23S rRNA from Fe(II) tethered to ten positions on the surface of E. coli RRF constrains it to a well-defined location in the subunit interface cavity. Surprisingly, the orientation of RRF in the ribosome differs markedly from any of those previously observed for tRNA, suggesting that structural mimicry does not necessarily reflect functional mimicry.

The invariant uridine of stop codons contacts the conserved NIKSR loop of human eRF1 in the ribosome

To unravel the region of human eukaryotic release factor 1 (eRF1) that is close to stop codons within the ribosome, we used mRNAs containing a single photoactivatable 4-thiouridine (s(4)U) residue in the first position of stop or control sense codons. Accurate phasing of these mRNAs onto the ribosome was achieved by the addition of tRNA(Asp). Under these conditions, eRF1 was shown to crosslink exclusively to mRNAs containing a stop or s(4)UGG codon. A procedure that yielded (32)P-labeled eRF1 deprived of the mRNA chain was developed; analysis of the labeled peptides generated after specific cleavage of both wild-type and mutant eRF1s maps the crosslink in the tripeptide KSR (positions 63-65 of human eRF1) and points to K63 located in the conserved NIKS loop as the main crosslinking site. These data directly show the interaction of the N-terminal (N) domain of eRF1 with stop codons within the 40S ribosomal subunit and provide strong support for the positioning of the eRF1 middle (M) domain on the 60S subunit. Thus, the N and M domains mimic the tRNA anticodon and acceptor arms, respectively.

Mouse GSPT2, but not GSPT1, can substitute for yeast eRF3 in vivo

BACKGROUND

The termination of protein synthesis in eukaryotes involves at least two polypeptide release factors (eRFs), eRF1 and eRF3. In mammals two genes encoding eRF3 structural homologues were identified and named GSPT1 and GSPT2.

RESULTS

In the present study, we demonstrate that mouse mGSPT2 but not mGSPT1 could functionally substitute the essential yeast gene SUP35. However, we show that the complementation property of mGSPT1 protein is modified when NH2-tagged by GST. Since mGSPT1 and mGSPT2 differ mainly in their N-terminal regions, we developed a series of N-terminal deleted constructs and tested them for complementation in yeast. We found that at least amino acids spanning 84-120 of mGSPT1 prevent the complementation of sup35 mutation. The fact that chimeras between mGSPT1, mGSPT2 and yeast Sup35 complement the disruption of the SUP35 gene indicates that the N-terminal region of mGSPT1 is not sufficient by itself to prevent complementation. Complementation of the mutant with a double disruption of SUP35 and SUP45 genes is obtained when mGSPT2 and human eRF1 are co-expressed but not by co-expression of mGSPT1 and human eRF1.

CONCLUSIONS

Our results strongly suggest that the two proteins (mGSPT1 and mGSPT2) are different. We hypothesize that the full length mGSPT1 does not have the properties expected for eRF3.

Conversion of omnipotent translation termination factor eRF1 into ciliate-like UGA-only unipotent eRF1

In eukaryotic ribosomes, termination of translation is triggered by class 1 polypeptide release factor, eRF1. In organisms with a universal code, eRF1 responds to three stop codons, whereas, in ciliates with variant codes, only one or two codon(s) remain(s) as stop signals. By mutagenesis of the Y-C-F minidomain of the N domain, we converted an omnipotent human eRF1 recognizing all three stop codons into a unipotent 'ciliate-like' UGA-only eRF1. The conserved Cys127 located in the Y-C-F minidomain plays a critical role in stop codon recognition. The UGA-only response has also been achieved by concomitant substitutions of four other amino acids located at the Y-C-F and NIKS minidomains of eRF1. We suggest that for eRF1 the stop codon decoding is of a non-linear (non-protein-anticodon) type and explores a combination of positive and negative determinants. We assume that stop codon recognition is profoundly different by eukaryotic and prokaryotic class 1 RFs.

Mutational eidence for a functional connection between two domains of 23S rRNA in translation termination

Nucleotide 1093 in domain II of Escherichia coli 23S rRNA is part of a highly conserved structure historically referred to as the GTPase center. The mutation G1093A was previously shown to cause readthrough of nonsense codons and high temperature-conditional lethality. Defects in translation termination caused by this mutation have also been demonstrated in vitro. To identify sites in 23S rRNA that may be functionally associated with the G1093 region during termination, we selected for secondary mutations in 23S rRNA that would compensate for the temperature-conditional lethality caused by G1093A. Here we report the isolation and characterization of such a secondary mutation. The mutation is a deletion of two consecutive nucleotides from helix 73 in domain V, close to the peptidyltransferase center. The deletion results in a shortening of the CGCG sequence between positions 2045 and 2048 by two nucleotides to CG. In addition to restoring viability in the presence of G1093A, this deletion dramatically decreased readthrough of UGA nonsense mutations caused by G1093A. An analysis of the amount of mutant rRNA in polysomes revealed that this decrease cannot be explained by an inability of G1093A-containing rRNA to be incorporated into polysomes. Furthermore, the deletion was found to cause UGA readthrough on its own, thereby implicating helix 73 in termination for the first time. These results also indicate the existence of a functional connection between the G1093 region and helix 73 during translation termination.

Positioning of the mRNA stop signal with respect to polypeptide chain release factors and ribosomal proteins in 80S ribosomes

To study positioning of the mRNA stop signal with respect to polypeptide chain release factors (RFs) and ribosomal components within human 80S ribosomes, photoreactive mRNA analogs were applied. Derivatives of the UUCUAAA heptaribonucleotide containing the UUC codon for Phe and the stop signal UAAA, which bore a perfluoroaryl azido group at either the fourth nucleotide or the 3'-terminal phosphate, were synthesized. The UUC codon was directed to the ribosomal P site by the cognate tRNA(Phe), targeting the UAA stop codon to the A site. Mild UV irradiation of the ternary complexes consisting of the 80S ribosome, the mRNA analog and tRNA resulted in tRNA-dependent crosslinking of the mRNA analogs to the 40S ribosomal proteins and the 18S rRNA. mRNA analogs with the photoreactive group at the fourth uridine (the first base of the stop codon) crosslinked mainly to protein S15 (and much less to S2). For the 3'-modified mRNA analog, the major crosslinking target was protein S2, while protein S15 was much less crosslinked. Crosslinking of eukaryotic (e) RF1 was entirely dependent on the presence of a stop signal in the mRNA analog. eRF3 in the presence of eRF1 did not crosslink, but decreased the yield of eRF1 crosslinking. We conclude that (i) proteins S15 and S2 of the 40S ribosomal subunit are located near the A site-bound codon; (ii) eRF1 can induce spatial rearrangement of the 80S ribosome leading to movement of protein L4 of the 60S ribosomal subunit closer to the codon located at the A site; (iii) within the 80S ribosome, eRF3 in the presence of eRF1 does not contact the stop codon at the A site and is probably located mostly (if not entirely) on the 60S subunit.

A tripeptide discriminator for stop codon recognition

Only recently has it been established that a tripeptide in the bacterial release factors (RFs), RF1 and RF2, is responsible for the stop codon recognition. This functional mimic of the anticodon of tRNA is referred to as a tripeptide 'anticodon' or a tripeptide discriminator. Here we review the experimental background and process leading to this discovery, and strengthen functional evidence for the tripeptide determinant for deciphering stop codons in mRNAs in prokaryotes.

Convergence and constraint in eukaryotic release factor 1 (eRF1) domain 1: the evolution of stop codon specificity

Class 1 release factor in eukaryotes (eRF1) recognizes stop codons and promotes peptide release from the ribosome. The 'molecular mimicry' hypothesis suggests that domain 1 of eRF1 is analogous to the tRNA anticodon stem-loop. Recent studies strongly support this hypothesis and several models for specific interactions between stop codons and residues in domain 1 have been proposed. In this study we have sequenced and identified novel eRF1 sequences across a wide diversity of eukaryotes and re-evaluated the codon-binding site by bioinformatic analyses of a large eRF1 dataset. Analyses of the eRF1 structure combined with estimates of evolutionary rates at amino acid sites allow us to define the residues that are under structural (i.e. those involved in intramolecular interactions) versus non-structural selective constraints. Furthermore, we have re-assessed convergent substitutions in the ciliate variant code eRF1s using maximum likelihood-based phylogenetic approaches. Our results favor the model proposed by Bertram et al. that stop codons bind to three 'cavities' on the protein surface, although we suggest that the stop codon may bind in the opposite orientation to the original model. We assess the feasibility of this alternative binding orientation with a triplet stop codon and the eRF1 domain 1 structures using molecular modeling techniques.

The mechanism of tryptophan induction of tryptophanase operon expression: tryptophan inhibits release factor-mediated cleavage of TnaC-peptidyl-tRNA(Pro)

Expression of the tryptophanase (tna) operon of Escherichia coli is regulated by catabolite repression and tryptophan-induced transcription antitermination. In a previous study, we reproduced the regulatory features of this operon observed in vivo by using an in vitro S-30 system. We also found that, under inducing conditions, the leader peptidyl-tRNA (TnaC-peptidyl-tRNA(Pro)) is not cleaved; it accumulates in the S-30 reaction mixture. In this paper, we examine the requirements for TnaC-peptidyl-tRNA(Pro) accumulation and cleavage, in vitro. We show that this peptidyl-tRNA remains bound to the translating ribosome. Removal of free tryptophan and addition of release factor 1 or 2 leads to hydrolysis of TnaC-peptidyl-tRNA(Pro) and release of TnaC from the ribosome-mRNA complex. Release factor-mediated cleavage is prevented by the addition of tryptophan. TnaC of the ribosome-bound TnaC-peptidyl-tRNA(Pro) was transferable to puromycin. This transfer was also blocked by tryptophan. Tests with various tryptophan analogs as substitutes for tryptophan revealed the existence of strict structural requirements for tryptophan action. Our findings demonstrate that the addition of tryptophan to ribosomes bearing nascent TnaC-peptidyl-tRNA(Pro) inhibits both TnaC peptidyl-tRNA(Pro) hydrolysis and TnaC peptidyl transfer. The associated translating ribosome therefore remains attached to the leader transcript where it blocks Rho factor binding and subsequent transcription termination.