Exploring Codon-Anticodon Adaptation in Eukaryotes

van Weringh, Anna

12 October 2011

tRNA genes have the fundamental role of translating the genetic code during protein synthesis. Beyond solely a passive decoding role, the tRNA pool exerts selection pressures on the codon usage of organisms and the viruses that infect them because processing codons read by rare tRNAs can be slow or even erroneous. To better understand the interactions of codons and anticodons in eukaryotic species, we first investigated whether tRNAs packaged into HIV-1 particles may relate to the poor codon usage of HIV-1 genes. By comparing the codon usage of HIV-1 genes with that of its human host, we found that tRNAs decoding poorly adapted codons are overrepresented in HIV-1 virions. Because the affinity of Gag-Pol for all tRNAs is non-specific, HIV packaging is most likely passive and reflects the tRNA pool at the time of viral particle formation. Moreover, differences that we found in the codon usage between early and late genes suggest alterations in the tRNA pool are induced late in viral infection. Next, we tested whether a reduced tRNA anticodon pattern, which was called into question by predicted tRNA datasets, is maintained across eukaryotes. tRNA prediction methods are prone to falsely identifying tRNA-derived repetitive sequences as functional tRNA genes. Thus, we proposed and tested a novel approach to identify falsely predicted tRNA genes using phylogenetics. Phylogenetic analysis removed nearly all the genes deviating from the anticodon pattern, therefore the anticodon pattern is reaffirmed across eukaryotes.

tRNA

bioinformatics

phylogenetics

HIV

codon usage

Anticodon

Eukaryotes

Exploring Codon-Anticodon Adaptation in Eukaryotes

van Weringh, Anna

January 2011

tRNA genes have the fundamental role of translating the genetic code during protein synthesis. Beyond solely a passive decoding role, the tRNA pool exerts selection pressures on the codon usage of organisms and the viruses that infect them because processing codons read by rare tRNAs can be slow or even erroneous. To better understand the interactions of codons and anticodons in eukaryotic species, we first investigated whether tRNAs packaged into HIV-1 particles may relate to the poor codon usage of HIV-1 genes. By comparing the codon usage of HIV-1 genes with that of its human host, we found that tRNAs decoding poorly adapted codons are overrepresented in HIV-1 virions. Because the affinity of Gag-Pol for all tRNAs is non-specific, HIV packaging is most likely passive and reflects the tRNA pool at the time of viral particle formation. Moreover, differences that we found in the codon usage between early and late genes suggest alterations in the tRNA pool are induced late in viral infection. Next, we tested whether a reduced tRNA anticodon pattern, which was called into question by predicted tRNA datasets, is maintained across eukaryotes. tRNA prediction methods are prone to falsely identifying tRNA-derived repetitive sequences as functional tRNA genes. Thus, we proposed and tested a novel approach to identify falsely predicted tRNA genes using phylogenetics. Phylogenetic analysis removed nearly all the genes deviating from the anticodon pattern, therefore the anticodon pattern is reaffirmed across eukaryotes.

tRNA

bioinformatics

phylogenetics

HIV

codon usage

Anticodon

Eukaryotes

Structure-based drug discovery against a novel antimalarial drug target, S-adenosylmethionine decarboxylase/ornithine decarboxylase

Reynolds, Jonathan James

07 February 2013

Malaria is one of the most life-threatening diseases affecting mankind, with over 3 billion people being at risk of infection, with most of these people living in Africa, South America and Asia. As the malaria parasite is rapidly becoming resistant to many of the possible treatments on the market, it is of upmost importance to identify new possible drug targets and describe drugs against these that are inexpensive, easy to manufacture and have a long shelf-life in order to combat malaria. One such target is the polyamine pathway. The polyamines putrescine, spermidine, and spermine are crucial for cell differentiation and proliferation. Interference with polyamine biosynthesis by inhibition of the rate-limiting enzymes ornithine decarboxylase (ODC) and S-adenosylmethionine decarboxylase (AdoMetDC) has been discussed as a potential chemotherapy of cancer and parasitic infections. Usually, both enzymes are individually transcribed and highly regulated as monofunctional proteins. However, ODC and AdoMetDC from P. falciparum (PfODC and PfAdoMetDC, respectively) are found as a unique bifunctional protein (PfAdoMetDC/ODC) in the malaria parasite, making it an enticing target for new, selective antimalarial chemotherapies. In order to apply structure-based drug discovery strategies to design inhibitors for PfAdoMetDC/ODC, the atomic resolution structures of these proteins are needed. Each individual domain has had its structure proposed through homology modelling; however atomic resolution structures of these domains are not yet available. The homology model of PfAdoMetDC/ODC has not yet been elucidated due to the interactions between the domains of the bifunctional protein not being fully understood. High levels of recombinant expression of the bifunctional protein have been either unsuccessful or resulted in the formation of insoluble proteins being produced. The purpose of this project is to optimise the recombinant expression of PfAdoMetDC/ODC, and the PfODC domain, to produce high yields of pure, soluble protein for subsequent atomic resolution structure determination. Ultimately, this will enable the utilisation of PfAdoMetDC/ODC in structure-based drug discovery strategies. Overexpression of P. falciparum proteins in E. coli is notoriously difficult, mainly due to the codon bias between the two species. Comparative studies were performed on four constructs of the PfAdoMetDC/ODC gene, containing either the wild-type, fully codon harmonised, or partially codon harmonised gene sequences to analyse the effect codon harmonisation had on protein expression and activity of both domains of PfAdoMetDC/ODC as well as on the monofunctional PfODC domain. Codon harmonisation did not improve the expression levels or the purity of recombinantly expressed PfAdoMetDC/ODC or the monofunctional PfODC domain. Truncated versions of both proteins, and contamination by the E. coli chaperone proteins DnaK and GroEL, were present in the protein samples even after purification by affinity chromatography. However, codon harmonisation improved the activity levels of the PfAdoMetDC domain, while decreasing the activity of the PfODC domain of PfAdoMetDC/ODC. Harmonisation of the monofunctional PfODC domain resulted in a decrease in the activity of the protein. In order to identify possible inhibitors of the PfODC domain of the bifunctional protein, a structure-based drug discovery study was initiated based on a homology model for PfODC. Four hundred compounds with known antimalarial activity were virtually screened against the PfODC homology model and the top two scoring compounds were selected for enzyme inhibition assays based on their predictive binding affinity against the enzyme, and two medium scoring compounds were selected as controls. Enzyme inhibition studies were performed on the bifunctional PfAdoMetDC/ODC to determine the effect the compounds had on both domains of the protein. Of the compounds assayed one of the compounds significantly reduced the activity levels of both domains of PfAdoMetDC/ODC. Additionally, one compound significantly reduced the activity level of the PfAdoMetDC domain of PfAdoMetDC/ODC. This work therefore contributes towards characterisation of the unique PfAdoMetDC/ODC in malaria parasites as a novel drug target. / Dissertation (MSc)--University of Pretoria, 2012. / Biochemistry / unrestricted

Pfadometdc/odc

Codon harmonisation

Virtual screening

Malaria

UCTD

Die Prion-Protein-Isoformen / Prion protein isoforms

Schwarzbach, Katharina

27 September 2016

No description available.

610

Prion, Codon 129 Polymorphismus

prion

Medizin (PPN619874732)

Úloha elF3 a Rps3 v pročítání stop kodonu / The role of elF3 a Rps3 in stop codon readthrough

Poncová, Kristýna

January 2020

Translation represents a highly regulated, interconnected process of protein synthesis in the cell. It could be divided into 4 phases: initiation, elongation, termination, and ribosomal recycling. Our laboratory is involved in in-depth studies of a complex eukaryotic initiation factor 3 protein (eIF3). We are interested not only in revealing its molecular roles in the translational cycle in general but also in specific mechanisms that allow translational regulation according to specific cellular needs. In the budding yeast, the eIF3 is composed of five essential subunits (a/Tif32, b/Prt1, c/Nip1, g/Tif35 and i/Tif34). In mammals, the protein is even more complex, comprising of 12 subunits (a-i, k-m). eIF3 is a key player not only in translation initiation but also in ribosomal recycling and, surprisingly, in translation termination and stop codon readthrough as well. The latter process harbors important clinical potential, as approximately 1/3 of genetically inherited diseases is caused by the presence of a premature termination codon in the protein-coding region. Therefore, understanding the molecular mechanism underlying this phenomenon provides important tools for the targeted and less toxic drug development approaches needed for patient therapy. In this Ph.D. Thesis, I uncovered the role of...

Yeast Upf1 Associates With RibosomesTranslating mRNA Coding Sequences Upstream of Normal Termination Codons: A Dissertation

Min, Ei Ei

15 April 2015

Nonsense-mediated mRNA decay (NMD) specifically targets mRNAs with premature translation termination codons for rapid degradation. NMD is a highly conserved translation-dependent mRNA decay pathway, and its core Upf factors are thought to be recruited to prematurely terminating mRNP complexes, possibly through the release factors that orchestrate translation termination. Upf1 is the central regulator of NMD and recent studies have challenged the notion that this protein is specifically targeted to aberrant, nonsense-containing mRNAs. Rather, it has been proposed that Upf1 binds to most mRNAs in a translation-independent manner. In this thesis, I investigated the nature of Upf1 association with its substrates in the yeast Saccharomyces cerevisiae. Using biochemical and genetic approaches, the basis for Upf1 interaction with ribosomes was evaluated to determine the specificity of Upf1 association with ribosomes, and the extent to which such binding is dependent on prior association of Upf1’s interacting partners. I discovered that Upf1 is specifically associated with Rps26 of the 40S ribosomal subunit, and that this association requires the N-terminal Upf1 CH domain. In addition, using selective ribosome profiling, I investigated when during translation Upf1 associates with ribosomes and showed that Upf1 binding was not limited to polyribosomes that were engaged in translating NMD substrate mRNAs. Rather, Upf1 associated with translating ribosomes on most mRNAs, binding preferentially as ribosomes approached the 3’ ends of open reading frames. Collectively, these studies provide new mechanistic insights into NMD and the dynamics of Upf1 during translation.

Nonsense Codon

Terminator Codon

Nonsense Mediated mRNA Decay

Trans-Activators

Messenger RNA

Ribosomes

Saccharomyces cerevisiae

Dissertations, UMMS

Codon, Nonsense

Codon, Terminator

RNA, Messenger

Genetics and Genomics

Adding new functions to insulin-like growth factor-I (IGF-I) via genetic codon expansion / Hinzufügen neuer Funktionen zu Insulin-like Growth Factor-I (IGF-I) durch genetische Codon-Erweiterung

Wu, Fang

January 2019

Insulin-like growth factor-I (IGF-I) is a 70-amino acid polypeptide with a molecular weight of approximately 7.6 kDa acting as an anabolic effector. It is essential for tissue growth and remodeling. Clinically, it is used for the treatment of growth disorders and has been proposed for various other applications including musculoskeletal diseases. Unlike insulin, IGF-I is complexed to at least six high-affinity binding proteins (IGFBPs) exerting homeostatic effects by modulating IGF-I availability to its receptor (IGF-IR) on most cells in the body as well as changing the distribution of the growth factor within the organism.1-3 Short half-lived IGF-I have been the driving forces for the design of localized IGF-I depot systems or protein modification with enhanced pharmacokinetic properties. In this thesis, we endeavor to present a versatile biologic into which galenical properties were engineered through chemical synthesis, e.g., by site-specific coupling of biomaterials or complex composites to IGF-I. For that, we redesigned the therapeutic via genetic codon expansion resulting in an alkyne introduced IGF-I, thereby becoming a substrate for biorthogonal click chemistries yielding a site-specific decoration. In this approach, an orthogonal pyrrolysine tRNA synthetase (PylRS)/tRNAPyl CUA pair was employed to direct the co-translational incorporation of an unnatural amino acid—¬propargyl-L-lysine (plk)—bearing a clickable alkyne functional handle into IGF-I in response to the amber stop codon (UAG) introduced into the defined position in the gene of interest. We summarized the systematic optimization of upstream and downstream process alike with the ultimate goal to increase the yield of plk modified IGF-I therapeutic, from the construction of gene fusions resulting in (i) Trx-plk-IGF-I fusion variants, (ii) naturally occurring pro-IGF-I protein (IGF-I + Ea peptide) (plk-IGF-I Ea), over the subsequent bacterial cultivation and protein extraction to the final chromatographic purification. The opportunities and hurdles of all of the above strategies were discussed. Evidence was provided that the wild-type IGF-I yields were pure by exploiting the advantages of the pHisTrx expression vector system in concert with a thrombin enzyme with its highly specific proteolytic digestion site and multiple-chromatography steps. The alkyne functionality was successfully introduced into IGF-I by amber codon suppression. The proper folding of plk-IGF-I Ea was assessed by WST-1 proliferation assay and the detection of phosphorylated AKT in MG-63 cell lysate. The purity of plk-IGF-I Ea was monitored with RP-HPLC and SDS-PAGE analysis. This work also showed site-specific coupling an alkyne in plk-IGF-I Ea by copper (I)-catalyzed azide-alkyne cycloaddition (CuAAC) with potent activities in vitro. The site-specific immobilization of plk-IGF-I Ea to the model carrier (i.e., agarose beads) resulted in enhanced cell proliferation and adhesion surrounding the IGF-I-presenting particles. Cell proliferation and differentiation were enhanced in the accessibility of IGF-I decorated beads, reflecting the multivalence on cellular performance. Next, we aimed at effectively showing the disease environment by co-delivery of fibroblast growth factor 2 (FGF2) and IGF-I, deploying localized matrix metalloproteinases (MMPs) upregulation as a surrogate marker driving the response of the drug delivery system. For this purpose, we genetically engineered FGF2 variant containing an (S)-2-amino-6-(((2-azidoethoxy)carbonyl)amino)hexanoic acid incorporated at its N-terminus, followed by an MMPs-cleavable linker (PCL) and FGF2 sequence, thereby allowing site-directed, specific decoration of the resultant azide-PCL-FGF2 with the previously mentioned plk-IGF-I Ea to generate defined protein-protein conjugates with a PCL in between. The click reaction between plk-IGF-I Ea and azide-PCL-FGF2 was systematically optimized to increase the yield of IGF-FGF conjugates, including reaction temperature, incubation duration, the addition of anionic detergent, and different ratios of the participating biopharmaceutics. The challenge here was that CuAAC reaction components or conditions might oxidize free cysteines of azide-PCL-FGF2 and future work needs to present the extent of activity retention after conjugation. Furthermore, our study provides potential options for dual-labeling of IGF-I either by the introduction of unnatural amino acids within two distinct positions of the protein of interest for parallel “double-click” labeling of the resultant plk-IGF-I Ea-plk or by using a combination of enzymatic-catalyzed and CuAAC bioorthogonal coupling strategies for sequentially dual-labeling of plk-IGF-I Ea. In conclusion, genetic code expansion in combination with click-chemistry provides the fundament for novel IGF-I analogs allowing unprecedented site specificity for decoration. Considerable progress towards IGF-I based therapies with enhanced pharmacological properties was made by demonstrating the feasibility of the expression of plk incorporated IGF-I using E. coli and retained activity of unconjugated and conjugated IGF-I variant. Dual-labeling of IGF-I provides further insights into the functional requirements of IGF-I. Still, further investigation warrants to develop precise IGF-I therapy through unmatched temporal and spatial regulation of the pleiotropic IGF-I. / Insulin-like growth factor-I (IGF-I) ist ein 70 Aminosäuren langes Polypeptid mit einem Molekuargewicht von 7,5 kDa, dass als anaboler Effektor wirkt und dadurch eine essentielle Rolle in Gewebewachstum und -umbau spielt. Klinisch wird IGF-I für die Behandlung von Wachstumsstörungen verwendet und ist für weitere Anwendungen wie muskuloskelettale Erkrankungen von Interesse. Im Gegensatz zu Insulin wird IGF-I von mindestens sechs hochaffinen Bindungsproteinen (IGFBPs) komplexiert, die homöostatisch regulierend wirken, indem sie die Verfügbarkeit von IGF-I zu seinem Rezeptor (IGF-IR) auf vielen Zellen modulieren und ebenso die Verteilung des Wachstumsfaktors im Körper steuern. Aufgrund der kurzen Halbwertszeit von IGF-I wurde die Entwicklung von lokalen IGF-I Depot-Systemen und von auf Proteinebene modifizierten IGF-I-Varianten mit verbesserten pharmakokinetischen Eigenschaften vorangetrieben. In der vorliegenden Arbeit sind wir bestrebt ein vielseitiges Biopharmazeutikum zu präsentieren, das hinsichtlich seiner galenischen Eigenschaften optimiert wurde, z. B. durch chemische Modifikation, wie ortsspezifische Kopplung von IGF-I an Biomaterialien oder komplexe Verbundstoffe. Für diesen Zweck wurde das Therapeutikum neu entworfen und über die Erweiterung des genetischen Codes eine Alkin-Funktionalität eingefügt. Durch dieses Alkin wird IGF-I zugänglich für die Modifizierung mit bio-orthogonaler, ortsspezifischer „Click-Chemie“. In diesem Ansatz wird ein orthogonales Pyrrolysin tRNA-Synthase (PylRS)/tRNAPyl-CUA – Paar verwendet, um den co-translationalen Einbau einer unnatürlichen Aminosäure — Propargyl-L-lysine (Plk) —, die eine Alkin-Funktionalität für Click-Reaktionen enthält, an Stelle des Amber-Stop-Codons (UAG) im entsprechenden Gen, im IGF-I-Protein zu gewährleisten. Die systematische Optimierung von Up- und Downstream-Prozessen, mit dem Ziel die Ausbeute von Plk-modifiziertem IGF-I-Biopharmazeutikum zu erhöhen, wurden zusammengefasst: von der Konstruktion von Genfusionen, die in (i) einer Trx-plk-IGF-I Fusionsvariant und (ii) natürlich vorkommendem pro-IGF-I Protein (IGF-I + Ea peptide) (Plk-IGF-I Ea) resultierten, über die folgende Expression in Bakterien und Proteinextraktion, bis hin zur finalen chromatographischen Reinigung des Biopharmazeutikums. Die Möglichkeiten und Schwierigkeiten aller oben genannten Strategien wurden diskutiert. Es wurde gezeigt, dass die Wildtyp-IGF-I-Ausbeuten durch den Einsatz des vorteilhaften pHisTrx-Expressionsvektor-Systems zusammen mit dem Enzym Thrombin und seiner hochspezifischen proteolytischen Spaltstelle und mehrfacher chromatographischer Aufreinigung einen hohen Reinheitsgrad aufwiesen. Die Alkin-Funktionalität wurde erfolgreich durch Unterdrückung des Amber-Codons in IGF-I eingeführt. Die richtige Faltung von Plk-IGF-I Ea wurde durch den WST-1 Proliferationsassay und den Nachweis von phosphorylierten Akt in MG-63-Zelllysat nachgewiesen. Die Reinheit von Plk-IGF-I Ea wurde durch RP-HPLC- und SDS-PAGE-Analyse überwacht. In dieser Arbeit konnte auch gezeigt werden, dass die ortspezifische Kopplung von Alkinen an Plk-IGF-I Ea durch Kupfer(I)-katalysierte Azid-Alkin Zykloaddition (CuAAC) in einem Produkt mit hoher in vitro Aktivität resultiert. Die ortspezifische Immobilisierung von Plk-IGF-I Ea an einem Modell-Trägersystem (hier: Agarosepartikel) führte zu einer verbesserten Zellproliferation und Zelladhäsion in der Umgebung der IGF-I-präsentierenden Partikel. Der vielfältige Einfluss von IGF-I auf Zellen wird durch die verbesserte Zellproliferation und -differenzierung durch die Verfügbarkeit von IGF-I präsentierenden Partikeln widergespiegelt. Als Nächstes setzten wir uns zum Ziel den Krankheitseinfluss durch die gleichzeitige Anwendung von Fibroblast-Wachstumsfaktor 2 (FGF2) und IGF-I zu zeigen, indem wir uns der lokalen Hochregulierung von Matrixmetalloproteinasen (MMPS) als Surrogat-Krankheitsmarker bedienten, der die Antwort des Drug Delivery-Systems auslöst. Zu diesem Zweck wurde eine FGF2-Variante genetisch modifiziert, sodass sie am N-Terminus eine (S)-2-amino-6-(((2-azidoethoxy)carbonyl)amino)Hexansäure trägt - gefolgt von einen durch MMPs spaltbaren Verbindungsstück (PCL) und der FGF2 Sequenz - und dadurch die gezielte, spezifische Konjugation des resultierenden Azid-PCL-FGF2 mit dem vorher erwähnten Plk-IGF-I Ea ermöglicht, um definierte Protein-Protein-Konjugate, die mit einem PCL verbunden sind, zu erzeugen. Die Click-Reaktion zwischen Plk-IGF-I Ea und Azid-PCL-FGF2 wurde zur Erhöhung der IGF-FGF Ausbeute systematisch optimiert, indem die Parameter Temperatur, Inkubationsdauer, Zugabe von anionischem Tensid und verschiedene Eduktverhältnisse untersucht wurden. Es gilt zu bedenken, dass die in der CuAAC Reaktion eingesetzten Komponenten oder Reaktionsbedingungen freie Cysteinreste von Azid-PCL-FGF2 oxidieren können und es in Zukunft gilt, die verbleibende Aktivität nach Proteinkonjugation zu bestimmen. Des Weiteren zeigen unsere Untersuchungen potentielle Möglichkeiten für duale Konjugation von IGF-I entweder durch die Einführung einer unnatürlichen Aminosäure an zwei verschiedenen Positionen innerhalb des Proteins (Plk-IGF-I Ea-Plk) für parallele „Doppel-Click“-Konjugation oder durch die Kombination bioorthogonaler Kopplungsreaktionen - einer enzymkatalysierten Reaktion und CuAAC - für sequentielles duales Verknüpfen von Plk-IGF-I Ea. Schlussendlich stellt die Erweiterung des genetischen Codes in Kombination mit Click-Chemie eine Grundlage für neue IGF-I-Analoga dar, die eine noch nie dagewesene Ortsspezifität für Konjugationen besitzen. Ein entscheidender Fortschritt hin zu IGF-I basierten Therapeutika mit verbesserten pharmakologischen Eigenschaften wurde durch die Expression, Reinigung und Konjugation von bioaktivem IGF-I mit Plk sowie konjugierten IGF-I Varianten erreicht. Duales Modifizieren von IGF-I erlaubt weitere Einblicke in die funktionalen Anforderungen an IGF-I. Dennoch sind weitere Untersuchungen nötig, um eine gezielte IGF-I Therapie trotz der unterschiedlichen zeitlichen und räumlichen Regulierung des pleiotropen IGF-I zu ermöglichen.

Insulin-like Growth Factor I

Codon

ddc:540

Mega-scale Bioinformatics Investigation of Codon Bias in Vertebrates

Nabiyouni, Maryam

23 August 2011

No description available.

Bioinformatics

Biology

Biomedical Research

Codon bias

GC composition

GC3

Vertebrates

Terminal Bias Patterns in Protein Coding Sequences of Phytophthora Sojae

Sarkar, Chandra, SARKAR

26 July 2017

No description available.

Biology

oomycetes

Phytophthora

codon bias

terminal bias

RXLR

Fidélité de la terminaison de la traduction chez les eucaryotes / Translation termination accuracy in eukaryotes

Blanchet, Sandra

18 September 2014

La terminaison de la traduction se produit lorsqu’un codon stop entre au site A du ribosome où il est reconnu par le facteur de terminaison eRF1 accompagné du facteur eRF3. Cette étape de la traduction est encore mal comprise chez les eucaryotes. Au cours de ma thèse je me suis intéressée à l’étude de la fidélité de la terminaison de la traduction afin de mieux comprendre et caractériser les mécanismes moléculaires mis en jeu lors du décodage du codon stop.L’un de mes projets consistait à mieux caractériser une région du domaine N-terminal d’eRF1, la cavité P1, identifiée comme étant impliquée dans l’efficacité de terminaison. Grâce à une quantification de l’efficacité de translecture de mutants de la cavité P1, j’ai pu mettre en évidence le rôle de résidus clés comme les serines 33 et 70, impliquées dans le décodage spécifique du codon UGA probablement via une interaction directe entre les deux résidus, ou encore l’arginine 65 et la lysine 109, essentielles pour une terminaison efficace sur les trois codons stop. L’analyse par RMN de ces mutants a également permis de montrer que ces résidus étaient importants pour la conformation correcte de la cavité et potentiellement impliqués dans une interaction directe avec l’ARNm. La combinaison des données génétiques et structurales nous a permis de proposer un modèle d’interaction entre l’ARNm et le facteur de terminaison eRF1 dans lequel le codon stop serait reconnu en partie par l’intermédiaire de la cavité P1. Dans la cellule, la terminaison est toujours en compétition avec la translecture, qui correspond à l’incorporation d’un ARNt proche-cognat au niveau du codon stop. Afin d’identifier les acides aminés incorporés par translecture au niveau du codon stop, j’ai mis au point un système basé sur l’expression et la purification de protéines issues de la translecture qui sont ensuite analysées par spectrométrie de masse. J’ai pu mettre en évidence que la glutamine, la tyrosine et la lysine s’incorporent au niveau des codons UAA et UAG, alors que le tryptophane, la cystéine et l’arginine sont retrouvés au niveau du codon UGA. J’ai également pu montrer que le contexte en 5’ n’influençait pas l’incorporation des acides aminés au codon stop mais qu’en revanche, la présence de la paromomycine avait un impact sur la sélection des ARNt suppresseurs naturels. Ce projet permet d’apporter de nouvelles informations sur les règles de décodage grâce à l’analyse des appariements entre codons stop et anticodons des ARNt naturels suppresseurs. Il permet également d’envisager des perspectives thérapeutiques dans le cadre des maladies liées à la présence d’un codon stop prématuré et pour lesquelles le traitement repose sur l’utilisation de la translecture afin de ré-exprimer des protéines entières. / Translation termination occurs when a stop codon enters the A site of the ribosome where it is recognized by eRF1 (eukaryotic release factor 1), associated with eRF3. This step of translation is not yet understood in eukaryotes. During my PhD, I was interested in studying translation termination accuracy to better understand and characterize the molecular mechanisms involved in stop codon decoding.One of my project consisted in characterizing a region in eRF1 N-terminal domain, pocket P1, identified to be involved in termination efficiency. Through a quantification of readthrough efficiency of pocket P1 mutants, I have highlighted the role of key residues, like serine 33 and serine 70, implicated in specific recognition of UGA stop codon, probably through a direct interaction between the two amino acids, and also arginine 65 and lysine 109, essential for efficient termination on the three stop codons. The analysis of the mutants by NMR revealed that these residues are also important for proper conformation of the cavity and potentially involved in a direct interaction with mRNA. The combination of our genetic data and structural analysis allowed us to propose a model of interaction between termination factor eRF1 and the mRNA, in which the stop codon would be recognized partially through pocket P1.In cells, termination always competes with readthrough which corresponds to the incorporation of near-cognate tRNAs at the stop codon. To identify the amino acids inserted by readthrough at the stop codon, I have developed a reporter system based on the expression and purification of readthrough proteins that are analyzed by mass spectrometry. I found that glutamine, tyrosine and lysine are inserted at UAA and UAG stop codons, whereas tryptophan, cysteine and arginine are inserted at UGA stop codon. I also showed that the 5’ nucleotide context does not influence the incorporation of amino acids at the stop codons by readthrough, but that, in contrast, the presence of paromomycin impacted the selection of natural suppressors tRNAs incorporated by readthrough. This project gives us new insights into the decoding rules by analyzing the base pairings between stop codon and near-cognates anticodons. It also allows us to consider therapeutic prospects for the treatment of premature stop codon diseases which uses readthrough as a tool to re-express full-length proteins from mRNAs that are interrupted by the presence of a premature stop codon.

Terminaison de la traduction

ERF1

Codon stop

Translecture

ARNt suppresseurs naturels

Translation termination

ERF1

Stop codon

Readthrough

Natural suppressor tRNAs