Thermal denaturation of class 1 eukaryotic translation termination factor eRF1. Relationship between stability and functional activity of eRF1 mutants

Differential scanning calorimetry (DSC) was used to study thermal denaturation of the human class 1 translation termination factor eRF1 and its mutants. Free energy changes caused by amino acid substitutions in the N domain were computed for eRF1. The melting of eRF1, consisting of three domains, proved to be cooperative. The thermostability of eRF1 was not affected by certain substitutions and was slightly increased by certain others. The corresponding residues were assumed to play no role in maintaining the eRF1 structure, which agreed with the published X-ray data. In these mutants (E55D, Y125F, N61S, E55R, E55A, N61S + S64D, C127A, and S64D), a selective loss of the capability to induce hydrolysis of peptidyl-tRNA in the ribosomal P site in the presence of a stop codon was not associated with destabilization of their spatial structure. Rather, the loss was due to local changes in the stereochemistry of the side groups of the corresponding residues in functionally important sites of the N domain. Two amino acid residues of the N domain, N129 and F131, proved to play an important role in the structural stability of eRF1 and to affect the selective recognition of mRNA stop codons in the ribosome. The recognition of the UAG and UAA stop codons in vitro was more tightly associated with the stability of the spatial structure of eRF1 as compared with that of the UGA stop codon.     

Highly conserved NIKS tetrapeptide is functionally essential in eukaryotic translation termination factor eRF1

Class-1 polypeptide chain release factors (RFs) play a key role in translation termination. Eukaryotic (eRF1) and archaeal class-1 RFs possess a highly conserved Asn-Ile-Lys-Ser (NIKS) tetrapeptide located at the N-terminal domain of human eRF1. In the three-dimensional structure, NIKS forms a loop between helices. The universal occurrence and exposed nature of this motif provoke the appearance of hypotheses postulating an essential role of this tetrapeptide in stop codon recognition and ribosome binding. To approach this problem experimentally, site-directed mutagenesis of the NIKS (positions 61-64) in human eRF1 and adjacent amino acids has been applied followed by determination of release activity and ribosome-binding capacity of mutants. Substitutions of Asn61 and Ile62 residues of the NIKS cause a decrease in the ability of eRF1 mutants to promote termination reaction in vitro, but to a different extent depending on the stop codon specificity, position, and nature of the substituting residues. This observation points to a possibility that Asn-Ile dipeptide modulates the specific recognition of the stop codons by eRF1. Some replacements at positions 60, 63, and 64 cause a negligible (if any) effect in contrast to what has been deduced from some current hypotheses predicting the structure of the termination codon recognition site in eRF1. Reduction in ribosome binding revealed for Ile62, Ser64, Arg65, and Arg68 mutants argues in favor of the essential role played by the right part of the NIKS loop in interaction with the ribosome, most probably with ribosomal RNA.     

Invariant amino acids essential for decoding function of polypeptide release factor eRF1

In eukaryotic ribosome, the N domain of polypeptide release factor eRF1 is involved in decoding stop signals in mRNAs. However, structure of the decoding site remains obscure. Here, we specifically altered the stop codon recognition pattern of human eRF1 by point mutagenesis of the invariant Glu55 and Tyr125 residues in the N domain. The 3D structure of generated eRF1 mutants was not destabilized as demonstrated by calorimetric measurements and calculated free energy perturbations. In mutants, the UAG response was most profoundly and selectively affected. Surprisingly, Glu55Arg mutant completely retained its release activity. Substitution of the aromatic ring in position 125 reduced response toward all stop codons. This result demonstrates the critical importance of Tyr125 for maintenance of the intact structure of the eRF1 decoding site. The results also suggest that Tyr125 is implicated in recognition of the 3d stop codon position and probably forms an H-bond with Glu55. The data point to a pivotal role played by the YxCxxxF motif (positions 125–131) in purine discrimination of the stop codons. We speculate that eRF1 decoding site is formed by a 3D network of amino acids side chains.     

Molecular mechanism of stop codon recognition by eRF1: a wobble hypothesis for peptide anticodons

We propose that the amino acid residues 57/58 and 60/61 of eukaryotic release factors (eRF1s) (counted from the N-terminal Met of human eRF1) are responsible for stop codon recognition in protein synthesis. The proposal is based on amino acid exchanges in these positions in the eRF1s of two ciliates that reassigned one or two stop codons to sense codons in evolution and on the crystal structure of human eRF1. The proposed mechanism of stop codon recognition assumes that the amino acid residues 57/58 interact with the second and the residues 60/61 with the third position of a stop codon. The fact that conventional eRF1s recognize all three stop codons but not the codon for tryptophan is attributed to the flexibility of the helix containing these residues. We suggest that the helix is able to assume a partly relaxed or tight conformation depending on the stop codon recognized. The restricted codon recognition observed in organisms with unconventional eRF1s is attributed mainly to the loss of flexibility of the helix due to exchanged amino acids.     

Decoding the Decoding Region: Analysis of Eukaryotic Release Factor (eRF1) Stop Codon-Binding Residues

Peptide synthesis in eukaryotes terminates when eukaryotic release factor 1 (eRF1) binds to an mRNA stop codon and occupies the ribosomal A site. Domain 1 of the eRF1 protein has been implicated in stop codon recognition in a number of experimental studies. In order to further pinpoint the residues of this protein involved in stop codon recognition, we sequenced and compared eRF1 genes from a variety of ciliated protozoan species. We then performed a series of computational analyses to evaluate the conservation, accessibility, and structural environment of each amino acid located in domain 1. With this new dataset and methodology, we were able to identify eight specific amino acid sites important for stop codon recognition and also to propose a set of cooperative paired substitutions that may underlie stop codon reassignment. Our results are more consistent with current experimental data than previously described models.Han Liang, Jonathan Y. Wong,Contributed equally to this paperReviewingEditor: Dr. Niles Lehman     

Amino acid sequence of seminalplasmin, an antimicrobial protein from bull semen

Analytical ultracentrifugation of highly purified seminalplasmin revealed a molecular mass of 6300. Amino acid analysis of the protein preparation indicated the absence of sulfur-containing amino acids cysteine and methionine. The amino acid sequence of seminalplasmin was determined by manual Edman degradation of peptides obtained by proteolytic enzymes trypsin, chymotrypsin and thermolysin: NH₂-Ser Asp Glu Lys Ala Ser Pro Asp Lys His His Arg Phe Ser Leu Ser Arg Tyr Ala Lys Leu Ala Asn Arg Leu Ser Lys Trp Ile Gly Asn Arg Gly Asn Arg Leu Ala Asn Pro Lys Leu Leu Glu Thr Phe Lys Ser Val-COOH. The number of amino acids according to the sequence were 48, the molecular mass 6385. As predicted from the sequence, seminalplasmin very likely contains two α-helical domains in which residues 8-17 and 40-48 are involved. No evidence for the existence of β-sheet structures was obtained. Treatment of seminalplasmin with the above proteases as well as with amino peptidase M and carboxypeptidase Y completely eliminated biological activity.     

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.     

Genetic analysis of L123 of the tRNA-mimicking eukaryote release factor eRF1, an amino acid residue critical for discrimination of stop codons

In eukaryotes, the tRNA-mimicking polypeptide-chain release factor, eRF1, decodes stop codons on the ribosome in a complex with eRF3; this complex exhibits striking structural similarity to the tRNA–eEF1A–GTP complex. Although amino acid residues or motifs of eRF1 that are critical for stop codon discrimination have been identified, the details of the molecular mechanisms involved in the function of the ribosomal decoding site remain obscure. Here, we report analyses of the position-123 amino acid of eRF1 (L123 in Saccharomyces cerevisiae eRF1), a residue that is phylogenetically conserved among species with canonical and variant genetic codes. In vivo readthrough efficiency analysis and genetic growth complementation analysis of the residue-123 systematic mutants suggested that this amino acid functions in stop codon discrimination in a manner coupled with eRF3 binding, and distinctive from previously reported adjacent residues. Furthermore, aminoglycoside antibiotic sensitivity analysis and ribosomal docking modeling of eRF1 in a quasi-A/T state suggested a functional interaction between the side chain of L123 and ribosomal residues critical for codon recognition in the decoding site, as a molecular explanation for coupling with eRF3. Our results provide insights into the molecular mechanisms underlying stop codon discrimination by a tRNA-mimicking protein on the ribosome.     

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.     

The primary structure of the β-subunit of protocatechuate 3,4-dioxygenase from Pseudomonas aeruginosa

The complete amino acid sequence of the β-subunit of protocatechuate 3,4-dioxygenase was determined. The β-subunit contained four methionine residues. Thus, five peptides were obtained after cleavage of the carboxymethylated β-subunit with cyanogen bromide, and were isolated on Sephadex G-75 column chromatography. The amino acid sequences of the cyanogen bromide peptides were established by characterization of the peptides obtained after digestion with trypsin, chymotrypsin, thermolysin, or Staphylococcus aureus protease. The major sequencing techniques used were automated and manual Edman degradations. The five cyanogen bromide peptides were aligned by means of the amino acid sequences of the peptides containing methionine purified from the tryptic hydrolysate of the carboxymethylated β-subunit. The amino acid sequence of all the 238 residues was as follows: ProAlaGlnAspAsnSerArgPheValIleArgAsp ArgAsnTrpHis ProLysAlaLeuThrPro-Asp — TyrLysThrSerIleAlaArg SerProArgGlnAla LeuValSerIleProGlnSer — IleSerGluThrThrGly ProAsnPheSerHisLeu GlyPheGlyAlaHisAsp-His — AspLeuLeuLeuAsnPheAsn AsnGlyGlyLeu ProIleGlyGluArgIle-Ile — ValAlaGlyArgValValAsp GlnTyrGlyLysPro ValProAsnThrLeuValGluMet — TrpGlnAlaAsnAla GlyGlyArgTyrArg HisLysAsnAspArgTyrLeuAlaPro — LeuAspProAsn PheGlyGlyValGly ArgCysLeuThrAspSerAspGlyTyrTyr — SerPheArg ThrIleLysProGlyPro TyrProTrpArgAsnGlyProAsnAsp — TrpArgProAla HisIleHisPheGlyIle SerGlyProSerIleAlaThr-Lys — LeuIleThrGlnLeuTyr PheGluGlyAspPro LeuIleProMetCysProIleVal — LysSerIleAlaAsn ProGluAlaValGlnGln LeuIleAlaLysLeuAspMetAsnAsn — AlaAsnProMet AsnCysLeuAlaTyr ArgPheAspIleValLeuArgGlyGlnArgLysThrHis PheGluAsnCys. The sequence published earlier in summary form (Iwaki et al., 1979, J. Biochem.86, 1159–1162) contained a few errors which are pointed out in this paper.     

Amino acid sequence of a protease inhibitor isolated from Sarcophaga bullata determined by mass spectrometry.

The amino acid sequence of a protease inhibitor isolated from the hemolymph of Sarcophaga bullata larvae was determined by tandem mass spectrometry. Homology considerations with respect to other protease inhibitors with known primary structures assisted in the choice of the procedure followed in the sequence determination and in the alignment of the various peptides obtained from specific chemical cleavage at cysteines and enzyme digests of the S. bullata protease inhibitor. The resulting sequence of 57 residues is as follows: Val Asp Lys Ser Ala Cys Leu Gln Pro Lys Glu Val Gly Pro Cys Arg Lys Ser Asp Phe Val Phe Phe Tyr Asn Ala Asp Thr Lys Ala Cys Glu Glu Phe Leu Tyr Gly Gly Cys Arg Gly Asn Asp Asn Arg Phe Asn Thr Lys Glu Glu Cys Glu Lys Leu Cys Leu.     

四膜虫eRF1识别终止密码子的功能结构域

原生动物的一些纤毛虫中终止密码子发生重分配现象,将1个或2个终止密码子翻译为氨基酸.目前对这一现象的发生机制仍无合理解释．近年来,对蛋白质合成终止过程中肽链释放因子(eukaryotic polypeptide release factor, eRF)结构和功能的深入研究,为揭示终止密码子的重分配机制提供了重要的线索．本实验以具有终止密码子识别特异性的四膜虫Tt-eRF1为研究对象,将其中与密码子识别有关的GTx、NIKS和Y-C-F关键模体(motif) 引入识别通用终止密码子的酵母Sc=eRF1中,构建成各种嵌合体eRF1．利用双荧光素酶报告系统和细胞活性实验,分析关键模体及其周边的氨基酸对eRF1识别终止密码子性质的影响．结果表明,GTx和NIKS模体一定程度上决定eRF1识别终止密码子第1位碱基U和第2位碱基A;Y-C-F模体决定eRF1识别终止密码子UGA的第2位碱基G．模体内及其相邻氨基酸定点突变分析进一步支持以上结果．本研究推测,eRF1在进化过程中一些关键模体结构的改变决定其识别终止密码子的特异性,只能识别3个终止密码子中的1个或2个．随后,由于tRNA基因的突变产生阻抑性tRNA,促成终止密码子在原生动物纤毛虫中的重新分配．     

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.     

第一类肽链释放因子C端结构域参与调控终止密码子的识别过程

真核生物蛋白质翻译终止过程中,第一类肽链释放因子（eukaryotic polypeptide release factor, eRF1）利用其N端结构域识别终止密码子。eRF1的N结构域中的GTS、NIKS和YxCxxxF模体对于终止密码子的识别发挥重要作用。但至目前为止,eRF1识别终止密码子的机制,尤其是对于终止密码子的选择性识别机制仍不清楚。我们构建了四膜虫（Tetrahymena thermophilia）eRF1的N端结构域与酿酒酵母（Saccharomyces cerevisiae）或裂殖酵母（Schizosaccharomyces pombe）eRF1的M和C结构域组成的杂合eRF1,即Tt/Sc eRF1 和Tt/Sp eRF1。双荧光素酶检测结果证实,两种杂合eRF1在细胞中识别终止密码子的活性具有显著差异。Tt/Sc eRF1仅识别UGA密码子,与四膜虫eRF1一致,具有密码子识别特异性;而Tt/Sp eRF1可以识别3个终止密码子,无密码子识别特异性。为解释这一现象,将Sp eRF1的C结构域中的1个关键的小结构域中的氨基酸进行突变,与Sc eRF1相应位点的氨基酸一致。分析结果显示,突变体Tt/Sp eRF1识别密码子UAA和UAG的性质发生显著变化,说明第一类肽链释放因子的C端结构域参与了终止密码子的识别过程。这提示,四膜虫eRF1识别终止密码子的特异性可能依赖于eRF1分子内的结构域间相互作用。本研究结果为揭示肽链释放因子识别终止密码子的分子机制提供了数据支持。     

Snapping of the carboxyl terminal tail of the catalytic subunit of PKA onto its core: characterization of the sites by mutagenesis

A set of 45 mutants of the carboxyl terminal tail of the PKA catalytic subunit was prepared and used to assess the contribution of this tail to the structure and function of the kinase. Ala substitutions of Asp 323, Phe 327, Glu 333, and Phe 350 resulted in a complete loss of enzymatic activity. Other replacements by Ala (Phe 314, Tyr 330, Glu 332, and Phe 347) brought about either a drop in activity to less than 10% of the wild-type enzyme or a reduction of affinity toward ATP (Lys 317, Lys 319, Tyr 330, and Glu 332) or toward Kemptide (Ile 315, Tyr 330, Val 337, Ile 339, Lys 345, and Glu 346). Mutations of Ser 338, a major autophosphorylation site of PKA, by Ala, Glu, Asp, Gln, and Asn showed that the kinetic parameters of these mutants are similar to those of the wild-type. The contribution of each of these tail mutations to the structure and stability of the kinase was assessed by monitoring its effect on the heat stability (when measurable) or by determining the susceptibility of the mutant kinase to cleavage by the Kinase Splitting Membranal Proteinase/Meprin beta. Here we show that the tail of PKA has a key role in creating the active conformation of the kinase. It does so by means of specific amino acid residues, which act as "snapping points" to embrace the two lobes of the kinase and orient them in the correct juxtaposition for substrate docking, biorecognition, and catalysis.     

Characterization of missense mutations in the SUP45 gene of Saccharomyces cerevisiae encoding translation termination factor eRF1

Collection of missense mutations in the SUP45 gene of Saccharomyces cerevisiae encoding translation termination factor eRF1 has been obtained by different approaches. It has been shown that most of isolated mutations cause amino acid substitutions in the N-terminal part of eRF1 and do not decrease the eRF1 amount. Most of mutations studied do not abolish eRF1-eRF3 interaction. The role of the N-terminal part of eRF1 in stop codon recognition is discussed.     

How translation termination factor eRF1 Euplotes does not recognise UGA stop codon

In universal-code eukaryotes, a single class-1 translation termination factor eRF1 decodes all three stop codons, UAA, UAG, and UGA. In some ciliates with variant genetic codes one or two stop codons are used to encode amino acid(s) and are not recognized by eRF1. In Stylonychia, UAG and UAA codons are reassigned as glutamine codons, and in Euplotes, UGA is reassigned as cysteine codon. In omnipotent eRF1s, stop codon recognition is associated with the N-terminal domain of eRF1. Because variant-code ciliates most likely evolved from universal code ancestor(s), structural features should exist in ciliate eRF1s that restrict their stop codon recognition. To find out amino acid residues which confer UAR-only specificity to Euplotes aediculatus eRF1, eRFI chimeras were constructed by swapping eRF1 E. aediculatus N-terminal domain sequences with the matching ones from the human protein. In these chimeras the MC-domain was from human eRF1. Functional analysis of these chimeric eRFI highlighted the crucial role of the two regions (positions 38-50 and 123-145) in the N-terminal domain of E. aediculatus eRF1 that restrict E. aediculatus eRF1 specificity toward UAR codons. Possibly, restriction of eRF1 specificity to UAR codons might have been an early event occurring in independent instances in ciliate evolutionary history, possibly facilitating the reassignment of UGA to sense codons.     

Sequences of tryptic peptides containing the five cysteinyl residues of ribulosebisphosphate carboxylase/oxygenase from Rhodospirillum rubrum

Tryptic peptides which account for all five cysteinyl residues in ribulosebisphosphate carboxylase/oxygenase from Rhodospirillum rubrum have been purified and sequenced. Collectively, these peptides contain 94 of the approximately 500 amino acid residues per molecule of subunit. Due to one incomplete cleavage at a site for trypsin and two incomplete chymotryptic-like cleavages, eight major radioactive peptides (rather than five as predicted) were recovered from tryptic digests of the enzyme that had been carboxymethylated with [³H]iodoacetate. The established sequences are: GlyTyrThrAlaPheValHisCys¹Lys TyrValAspLeuAlaLeuLysGluGluAspLeuIleAla GlyGlyGluHisValLeuCys¹AlaTyr AlaGlyTyrGlyTyrValAlaThrAlaAlaHisPheAla AlaGluSerSerThrGlyThrAspValGluValCys¹ ThrThrAsxAsxPheThrArg AlaCys¹ThrProIleIleSerGlyGlyMetAsnAla LeuArg ProPheAlaGluAlaCys¹HisAlaPheTrpLeuGly GlyAsnPheIleLys In these peptides, radioactive carboxymethylcysteinyl residues are denoted with asterisks and the sites of incomplete cleavage with vertical wavy lines. None of the peptides appear homologous with either of two cysteinyl-containing, active-site peptides previously isolated from spinach ribulosebisphosphate carboxylase/oxygenase.     

The amino acid sequence of human chorionic gonadotropin. The alpha subunit and beta subunit.

The amino acid sequences of both the alpha and beta subunits of human chorionic gonadotropin have been determined. The amino acid sequence of the alpha subunit is: Ala - Asp - Val - Gln - Asp - Cys - Pro - Glu - Cys-10 - Thr - Leu - Gln - Asp - Pro - Phe - Ser - Gln-20 - Pro - Gly - Ala - Pro - Ile - Leu - Gln - Cys - Met - Gly-30 - Cys - Cys - Phe - Ser - Arg - Ala - Tyr - Pro - Thr - Pro-40 - Leu - Arg - Ser - Lys - Lys - Thr - Met - Leu - Val - Gln-50 - Lys - Asn - Val - Thr - Ser - Glu - Ser - Thr - Cys - Cys-60 - Val - Ala - Lys - Ser - Thr - Asn - Arg - Val - Thr - Val-70 - Met - Gly - Gly - Phe - Lys - Val - Glu - Asn - His - Thr-80 - Ala - Cys - His - Cys - Ser - Thr - Cys - Tyr - Tyr - His-90 - Lys - Ser. Oligosaccharide side chains are attached at residues 52 and 78. In the preparations studied approximately 10 and 30% of the chains lack the initial 2 and 3 NH2-terminal residues, respectively. This sequence is almost identical with that of human luteinizing hormone (Sairam, M. R., Papkoff, H., and Li, C. H. (1972) Biochem. Biophys. Res. Commun. 48, 530-537). The amino acid sequence of the beta subunit is: Ser - Lys - Glu - Pro - Leu - Arg - Pro - Arg - Cys - Arg-10 - Pro - Ile - Asn - Ala - Thr - Leu - Ala - Val - Glu - Lys-20 - Glu - Gly - Cys - Pro - Val - Cys - Ile - Thr - Val - Asn-30 - Thr - Thr - Ile - Cys - Ala - Gly - Tyr - Cys - Pro - Thr-40 - Met - Thr - Arg - Val - Leu - Gln - Gly - Val - Leu - Pro-50 - Ala - Leu - Pro - Gin - Val - Val - Cys - Asn - Tyr - Arg-60 - Asp - Val - Arg - Phe - Glu - Ser - Ile - Arg - Leu - Pro-70 - Gly - Cys - Pro - Arg - Gly - Val - Asn - Pro - Val - Val-80 - Ser - Tyr - Ala - Val - Ala - Leu - Ser - Cys - Gln - Cys-90 - Ala - Leu - Cys - Arg - Arg - Ser - Thr - Thr - Asp - Cys-100 - Gly - Gly - Pro - Lys - Asp - His - Pro - Leu - Thr - Cys-110 - Asp - Asp - Pro - Arg - Phe - Gln - Asp - Ser - Ser - Ser - Ser - Lys - Ala - Pro - Pro - Pro - Ser - Leu - Pro - Ser-130 - Pro - Ser - Arg - Leu - Pro - Gly - Pro - Ser - Asp - Thr-140 - Pro - Ile - Leu - Pro - Gln. Oligosaccharide side chains are found at residues 13, 30, 121, 127, 132, and 138. The proteolytic enzyme, thrombin, which appears to cleave a limited number of arginyl bonds, proved helpful in the determination of the beta sequence.     

Decoding accuracy in eRF1 mutants and its correlation with pleiotropic quantitative traits in yeast

Translation termination in eukaryotes typically requires the decoding of one of three stop codons UAA, UAG or UGA by the eukaryotic release factor eRF1. The molecular mechanisms that allow eRF1 to decode either A or G in the second nucleotide, but to exclude UGG as a stop codon, are currently not well understood. Several models of stop codon recognition have been developed on the basis of evidence from mutagenesis studies, as well as studies on the evolutionary sequence conservation of eRF1. We show here that point mutants of Saccharomyces cerevisiae eRF1 display significant variability in their stop codon read-through phenotypes depending on the background genotype of the strain used, and that evolutionary conservation of amino acids in eRF1 is only a poor indicator of the functional importance of individual residues in translation termination. We further show that many phenotypes associated with eRF1 mutants are quantitatively unlinked with translation termination defects, suggesting that the evolutionary history of eRF1 was shaped by a complex set of molecular functions in addition to translation termination. We reassess current models of stop-codon recognition by eRF1 in the light of these new data.