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1	Úloha translačního iniciačního faktoru 3 v terminaci translace. / The role of translation initiation factor 3 (eIF3) in translation termination. Beznosková, Petra January 2016 (has links) Protein synthesis is a tightly regulated process of gene expression. Each gene has its start and its stop, which is determined by one of the three stop codons. Many recent articles describe ribosomes that purposely bypass stops on specific mRNAs to extend the nascent polypeptide to alter its properties. It is called programmed stop codon readthrough. Since over 15% of human genetic diseases are caused by so called premature termination codons (PTC) that halt translation and produce truncated proteins, this mechanism has a great potential implication in medical research. Numerous labs search for non-toxic drugs specifically increasing readthrough at PTCs; however, the success of this effort requires identification and understanding of all factors that are involved in this process. Here, we present one such factor eukaryotic initiation factor 3 (eIF3) and describe its ability to induce readthrough on stop codons in termination non-favorable context during programmed readthrough and also the consequences of its action on translation regulation. We additionally analyzed which near-cognate (nc) tRNAs are incorporated at UGA stop codons depending on the nucleotide that immediately follows them (so called +4 base). This way we established new rules for stop codon decoding and identified so called... translation; eIF3; 40S ribosome
2	Translational Regulation in Arabidopsis thaliana: Genetic and Functional Characterization of Eukaryotic Initiation Factor 3 Roy, Bijoyita 01 August 2010 (has links) Molecular functions of eukaryotic initiation factor 3 (eIF3) in translation are manifold, encompassing events from initiation complex assembly to translation termination. The contribution of the individual subunits of eIF3 to its multiple activities is quite unclear. It has been hypothesized that several of its 13 subunits contribute to mRNA specific regulation. Prior research had established that the h subunit of eIF3 in Arabidopsis was required for translation of specific mRNAs as well as for organ formation and meristem development. This study aims towards understanding the functions of individual subunits of eIF3 in the context of plant development and to further define the role of eIF3h at the molecular level. This dissertation describes an effort to identify mutations affecting each of the 13 eIF3 subunits. Using a panel of pollen-specific fluorescent marker genes, eIF3 subunits e, h and i1 were demonstrated to be essential for normal male gametophyte development. Furthermore, subunits b and c proved to be essential for embryo development. In contrast, a mutation in eIF3k revealed no phenotypic abnormalities. This work represents a systematic effort to attribute functions to many of the eIF3 subunits in growth and development in a multicellular eukaryote. The h subunit of eIF3 is necessary for the efficient translation of specific mRNAs in Arabidopsis. In particular, eIF3h fosters the translation of those mRNAs that harbor multiple upstream open reading frames (uORFs) in their 5’ leader. The specific molecular activity of eIF3h was investigated by structure-function analysis of the 5' leader of the Arabidopsis AtbZip11 mRNA, which harbors a set of four uORFs that is evolutionarily conserved. By pairing extensive mutagenesis of the AtbZip11 5' leader with gene expression analysis in Arabidopsis seedlings, it was revealed that eIF3h helps the ribosome to retain its reinitiation competence during uORF translation. These data establish a function for the h subunit of eIF3 in a special case of translation initiation, reinitiation. Finally, the molecular events during translation reinitiation were investigated further for a functional cooperation between eIF3h and the large subunit of the ribosome, given that the large ribosomal subunit had been implicated in reinitiation in other biological contexts. Reinitiation profiling using the AtbZip11 leader demonstrated that a protein of the large ribosomal subunit, RPL24B, bolsters reinitiation similar to eIF3h. Taken together, there exists a functional cooperation between the large ribosomal subunit and eIF3 that helps ribosomes to reinitiate after translation of uORFs. Arabidopsis eIF3 Protein synthesis Reinitiation Development Molecular genetics
3	Úloha elF3 a Rps3 v pročítání stop kodonu / The role of elF3 a Rps3 in stop codon readthrough Poncová, Kristýna January 2020 (has links) 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...
4	The Mechanism of Protein Synthesis Inhibition by the P56 Family of Viral Stress Inducible Proteins Hui, Daniel Jason 04 January 2005 (has links) No description available. protein synthesis translation interferon viral stress P56 eIF3
5	Funkční analýza eIF3e podjednotky lidského translačního iniciačního faktoru eIF3 v živých buňkách. / Functional analysis of eIF3e subunit of human translation initiation factor 3 in living cells. Šikrová, Darina January 2015 (has links) 2 Abstract Eukaryotic initiation factor 3 (eIF3) is a critical player involved in many steps of translation initiation, which ultimately result in the formation of the elongation competent 80S ribosome. With its 13 subunits (eIF3a - eIF3m) it is the largest and the most complex translation initiation factor composed of three mutually interconnected modules (i - iii), however, the role of individual subunits involved in its structural integrity and proper function is not fully explored. The eIF3e subunit was shown to be a part of the human eIF3 structural core and to help in the mRNA recruitment to the 43S pre-initiation complex by forming a molecular bridge between the 40S ribosomal subunit and the mRNA cap-binding complex. In this study, we employed siRNA-directed downregulation of eIF3e in HeLa cells and analysed its impact on the overall eIF3 integrity and function in vivo. The eIF3e knock-down (eIF3eK.D. ) led to the severe reduction of protein amounts of other three subunits (eIF3d, k and l), which together with the subunit eIF3c and e form module ii of the eIF3 complex. Remaining module i (composed of a, b, g and i) and iii (containing f, h and m) stayed partially bound perhaps thanks to a bridging effect of eIF3c, and showed reduced binding efficiency towards the 40S subunit compared to control...
6	Effet des microARNs sur la traduction cellulaire et virale / Regulation of cellular and viral translation by microRNAs Limousin, Taran 20 December 2013 (has links) Les microARN jouent un grand rôle dans la régulation de l'expression des gènes bien que leur mécanisme d'action soit encore sujet à débat. Des premières études chez le vers C. elegans aux différents systèmes in vitro qui ont ensuite été développés, plusieurs modèles ont été proposés, comme l'inhibition de la traduction au niveau de l'initiation ou de l'élongation, et la déstabilisation du transcrit par déadénylation. Cependant, à la lumière des découvertes récentes, un consensus semble apparaître et indique que les miARN inhiberaient d'abord la traduction avant d'induire la déadénylation du transcrit, provoquant ainsi sa dégradation prématurée. D'autre part, le blocage traductionnel semble impliquer à la fois la coiffe en 5' et la queue poly(A) en 3' de l'ARNm ainsi que les facteurs qui s'y lient, c'est à dire le facteur d'initiation de la traduction eIF4F et la Poly(A) Binding Protein (PABP). Ces résultats ont conduit au modèle selon lequel, les miARN seraient capables d'empêcher la liaison entre ces deux facteurs et donc la circularisation du transcrit qui est essentielle à la fois au recrutement de la machinerie traductionnelle et à la stabilité de l'ARNm. Afin de mieux comprendre ce mécanisme, notre laboratoire a développé un système in vitro basé sur l'utilisation du lysat de réticulocytes de lapin qui permet d'étudier l'effet traductionnel des miARN en s'affranchissant de dégradation du transcrit. L'étude de l'effet de drogues et d'enzymes virales, capables de bloquer spécifiquement la fonction de chaque facteur d'initiation dans ce système, a permis de déterminer le rôle clé de eIF4G et PABP dans l'inhibition traductionnelle par les miARN. Cependant, leur interaction n'est pas requise et le blocage s'effectue plutôt au cours de l'étape de balayage de la région 5' non codante par la petite sous-unité ribosomique. En parallèle de cette étude in vitro, un travail sur des lignées cellulaires a permis de déterminer l'influence de la queue poly(A) sur l'effet miARN. De façon très surprenante, l'expression des transcrits non polyadénylés n'est plus inhibée et est même stimulée par les miARN. Cet effet est dépendant de l'association du domaine MIF4G du facteur eIF4G avec le facteur eIF3, ce qui suggère qu'en l'absence de queue poly(A), les miARN seraient capables de stimuler le recrutement de la petite sous-unité ribosomique sur l'ARNm. L'ensemble de ces résultats révèle la complexité de l'effet miARN sur la traduction et ouvre de nouvelles voies / The mechanism by which microRNAs (miRNAs) can control gene expression has been a great matter of debate. From the first studies in worm to the in vitro systems that are used today, many models have been proposed that include regulation at the level of translation or at the level of mRNA stability by controlling 3' deadenylation and decay. Recent studies provided a consensus model of all these discrepancies and suggested that translation inhibition occured first and is followed by deadenylation and further degradation of the target transcript. Moreover, translation silencing seems to occur at the initiation level, and requires eIF4F and PABP initiation factors. This led to the hypothesis that miRNAs could interfere with the interaction between these two factors thus affecting the circularisation of the mRNA, which is essential for translation efficiency. In order to gain insight into this mechanism, we have used an in vitro system based on the rabbit reticulocyte lysate that fully recapitulates miRNA effects on translation with virtually no effect on deadenylation and decay. Using this system and a wide spectrum of translational inhibitors, we have narrowed down the step of initiation at which repression is exerted and we found that miRNAs affect mainly ribosomal scanning. This effect requires the presence of both eIF4G and PABP but does not rely on their physical interaction. Further analysis of miRNA repression in cells revealed that the poly(A) tail was an absolute requirement for miRNA action. To most of our surprise, we observed that removal of the poly(A) resulted in a shift from repression to stimulation of mRNA expression. This effect seems to require the middle domain of eIF4G and the presence of the Ago proteins. Altogether, these results reveal the complexity of miRNA effect and open new prospects on translation regulation MicroARN Traduction Initiation de la traduction Régulation des gènes Argonaute EIF4G PABP EIF3 MicroRNAs Translation Translation initiation Control gene Argonaute EIF4G PABP EIF3 572.8
7	Rôle du facteur d’initiation eIF3h dans la réinitiation de la traduction et dans la pathogénèse virale chez les plantes / The role of eukaryotic initiation factor eIF3h in translation reinitiation and viral pathogenesis Makarian, Joelle 02 December 2016 (has links) La réinitiation de la traduction est un mécanisme permettant de traduire des ORF qui sont présents dans la région leader de différents ARNm cellulaires (uORF). La majorité des cas de réinitiation de la traduction chez les eucaryotes concerne des uORF de petite taille. Des stratégies alternatives ont été développées, entre autres par les virus, afin de réinitier la traduction après un long uORF. Le virus de la mosaïque du chou-fleur (CaMV) exprime un ARNm polycistronique codant la totalité des protéines virales. L’une d’entre elle, la protéine TAV (TransActivateur/Viroplasmine) est un facteur essentiel qui rend possible la réinitiation de la traduction après de longs ORF et qui, de plus, active la protéine kinase TOR. La sous-unité h du facteur d’initiation de la traduction eIF3, requise pour promouvoir la reinitiation après un petit ORF chez les plantes, a été identifiée comme étant une nouvelle cible de phosphorylation de la voie de signalisation de TOR. L’objectif principal de ma thèse a été d’élucider la fonction de la protéine eIF3h dans la réinitiation après un petit ORF ainsi que dans la réinitiation de la traduction, assurée par TAV, après un long ORF. Nous avons exploité les lignées transgéniques eif3h-1 d’Arabidopsis exprimant la protéine eif3h tronquée de son extrémité C-terminale, qui sont déficientes pour la réinitiation mais pas pour l’initiation de la traduction. Nous avons montré que la phosphorylation de eIF3h est essentielle pour stabiliser eIF3 au niveau des ribosomes durant l’élongation, ce qui favorise la ré-acquisition par le ribosome de facteurs nécessaires à la réinitiation de la traduction, et que la délétion de sa région Ct abolit son intégration dans le complexe eIF3. De plus, nous avons montré que eIF3h, la cible de la voie de signalisation de TOR, interagit avec S6K1. Des protoplastes préparés à partir des plantes mutantes eif3h-1 sont incapables de promouvoir la réinitiation après de longs ORF en présence de TAV. La surexpression de eIF3h, indifféremment de son état de phosphorylation, est indispensable pour restaurer la reinitiation assurée par TAV dans les protoplastes eif3h-1. Par ailleurs, les plantes eif3h-1 déficientes dans la réinitiation, sont résistantes à l’infection par le CaMV démontrant l’importance de eIF3h pour la réplication du CaMV. En revanche, ces plantes eif3h-1 peuvent être infectées par d’autres virus dont la traduction de l’ARN génomique est coiffe- ou IRES-dépendante. Ainsi, nos résultats suggèrent que eIF3h est un facteur de reinitiation important aussi bien pour la reinitiation après un petit qu’après un long ORF (controlée par TAV), et que TAV exploite cette machinerie cellulaire, et plus particulièrement TOR et eIF3h, pour exprimer ses propres protéines par réinitiation de la traduction. / Translation of mRNAs that harbor upstream open reading frames (uORFs) within their leader regions operates via a reinitiation mechanism. In plants, reinitiation is up regulated by the target of rapamycin (TOR) signaling via phosphorylation of the subunit h of initiation factor 3 (eIF3). The eif3h-1 mutant expressing the C-terminally truncated eIF3h while maintaining high translation initiation efficiency is not active in reinitiation. Cauliflower mosaic virus (CaMV) pregenomic polycistronic RNA is translated via an exceptional mechanism of reinitiation after long ORF translation under control of CaMV protein TAV, which ensures activation of TOR. To find the link between underlying mechanisms, we examined eIF3h function in cellular and viral context. Here we show that eIF3h, if phosphorylated, has a role in recruitment of eIF3 into actively translating ribosomes that is a prerequisite for formation of reinitiation-competent ribosomal complexes. C-terminal truncation of eIF3h abolished its integration into the eIF3 complex and eIF3 loading on polysomes as manifested by the eIF3 core subunit c. We also show that eIF3h as a putative target of TOR/S6K1 binds S6K1 in vitro. eIF3h phosphorylation is not required for eIF3 complex formation. We demonstrated that eIF3h is essential for TAV to activate reinitiation after long ORF translation. Protoplasts derived from eif3h-1 mutant failed to support TAV function in reinitiation, which is restored only upon overexpression of recombinant eIF3h indifferent to its phosphorylation status. eif3h-1 mutant defective in reinitiation was found resistant to CaMV infection suggesting that eIF3h is critical for virus amplification. In contrast, viruses that evolve translation initiation dependent on either cap or the internal ribosome entry site infect reinitiation deficient mutant. Thus, we conclude that TAV exploits the basic cell reinitiation machinery, particularly TOR and eIF3h, to overcome cellular barriers to reinitiation after long ORF translation. Réinitiation de la traduction CaMV TAV Sous-unité h de eIF3 Voie de signalisation TOR Reinitiation CaMV EIF3 subunit h TAV Long ORF translation TOR signaling pathway S6k1 572.8 579.2
8	Structural and functional investigation of the protein synthesis in saccharomyces cerevisiae / Strukturelle und funktionelle Untersuchung der Proteinbiosynthese in saccharomyces cerevisiae Khoshnevis, Sohail 26 October 2010 (has links) No description available. 570 Biowissenschaften Biologie Proteinbiosynthese eIF3 Hefe Rontgen Kristallographie Protein synthesis eIF3 yeast X-ray crystallography 42.13 Molekularbiologie WF 200: Molekularbiologie
9	Rozbor funkčních domén eIF3 podporujících sestavení 48S pre-iniciačního komplexu / Dissection of eIF3 functional domains promoting the 48S pre-initiation complex assembly Beznosková, Petra January 2012 (has links) In eukaryotes, translation initiation is guided by up to twelve protein initiation factors (eIFs) and begins with the formation of the 43S pre-initiation complex (PIC) composed of the small ribosomal subunit (40S), eIF2.GTP/Met-tRNAi Met ternary complex, and eIFs 1, 1A, 3 and 5. The 43S PIC subsequently interacts with the 5'end of an mRNA (an mRNA recruitment step) and thus formed 48S PIC travels in 5' to 3' direction along the mRNA leader sequence to locate the AUG start codon (this presumably linear movement is generally known as scanning). Start site selection results in the dissociation of the initiation factors and joining of the large (60S) ribosomal subunit to form the 80S initiation complex poised for elongation. Eukaryotic initiation factor 3 (eIF3) plays a critical role in most of these events; however, the molecular details of most of its contributions are still unknown to us. Previous in vivo studies generated numerous mutations in all eIF3 subunits with specific defects either in the PICs assembly or in the following steps such as scanning, AUG recognition, etc. To understand the exact role of eIF3 in this intriguing process at the molecular level, we have embarked on a study that aims to dissect the individual functions of each eIF3 subunit in translation initiation using the purified...
10	Charakterizace molekulárních mechanismů reiniciace translace v kvasinkách. / Characterization of the molecular mechanism of translation reinitiation in yeast. Pondělíčková, Vanda January 2014 (has links) Translation initiation is a multi-step process culminating in formation of the elongation- competent 80S ribosome. It requires accurate assembly of small and large ribosomal subunits, mRNA, initiation Met-tRNAi Met and at least 12 eukaryotic initiation factors (eIFs). This phase of protein synthesis is also one of the key points of regulation of gene expression. One of the main aims of our laboratory is a complex characterization of the multiprotein eIF3 complex that has been implicated in most of the steps of translation initiation. For example, we revealed and described its novel role in translation reinitiation (REI), a gene-specific translational control mechanism that among others governs expression of an important yeast transcriptional activator GCN4. Here I present a detailed characterization of the multi-functional N-terminal domain of Tif32 (subunit eIF3a). We demonstrated that the Tif32-NTD functionally interacts with the 5' sequences of short upstream ORF (uORF1) in the GCN4 mRNA leader and thus allows efficient reinitiation downstream of this critical reinitiation-permissive uORF. Four REI- promoting elements (RPEs) were identified in the 5' sequences of uORF1, two of which were shown to work in the Tif32-NTD-dependent manner. The structure of the 5' sequences was determined...

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