Global ETD Search

61	Import des ARNt dans Plasmodium : sélection à l'entrée ? / tRNA import in Plasmodium : selection at the entrance ? Cela Madinaveitia, Marta 20 September 2018 (has links) Mon étude a porté sur la spécificité de l'interaction entre deux protéines du parasite du paludisme (Plasmodium), tRip (tRNA import protein) et la tyrosyl-ARNt synthétase apicoplastique (api-TyrRS), avec l'ARN de transfert (ARNt). Plasmodium est un parasite intracellulaire qui conserve une organelle vestigiale, l’apicoplaste, qui possède son propre système de traduction. J’ai adapté la séquence de l’ARN messager pour produire l’api-TyrRS in vitro, et j’ai étudié la spécificité de la reconnaissance de l’ARNtTyr apicoplastique, qui évite les interactions erronées plutôt que de favoriser les correctes. La protéine tRip est située à la surface du parasite et est responsable de l’import des ARNt de l’hôte. Mes résultats suggèrent que cet import à lieu pendant la phase sanguine duparasite. Elle ne reconnait pas tous les ARNt de la même façon. Les modifications posttranscriptionnelles modulent l’affinité de tRip, et potentiellement, le taux d’import de cet ARNt. Finalement, j’ai identifié par SELEX une séquence nucléotidique qui se lie spécifiquement à tRip, un début pour la conception d'une molécule qui ciblerait spécifiquement le parasite du paludisme. / My study focused on the specificity of the interaction between two proteins of the malaria parasite (Plasmodium), tRip (tRNA import protein) and the apicoplastic tyrosyl-tRNA synthetase (api-TyrRS), with the transfer RNA (tRNA). Plasmodium is an intracellular parasite with a vestigial organelle, the apicoplast, which has its own translation system. The messenger RNA sequence was adapted to produce api-TyrRS in vitro, and I studied the specificity of apicoplastic tRNATyr recognition, which avoids erroneous interactions rather than favoring the correct ones. The tRip protein is located on the surface of the parasite, and is responsible for importing tRNAs from the host. My results suggest that this import takes place during the blood phase of the parasite. In addition, not all tRNAs are recognized uniformly. The post-transcriptional modifications of the tRNAs define the affinity of tRip, and potentialy, the import rate of this tRNA. Finally, I identified a short nucleotide sequence that binds specifically to tRip. It is a good starting point for designing a molecule that specifically targets the malaria parasite. Plasmodium ARNt Import d’ARNt Aminoacylation Plasmodium TRNA TRNA import Aminoacylation 572.8 578.65
62	Computational investigations into the evolution of mitochondrial genomes Sahyoun, Abdullah 02 March 2015 (has links) (PDF) Mitochondria are organelles present in most eukaryotic cells. They generate most of the cells adenosine triphosphate (ATP) supply which make them essential for cell viability. It is assumed that they are derived from a proteobacterial ancestor as they retain their own, drastically small genome. The importance in studying mitochondrial genome evolution came from the discovery of a large number of human diseases that are caused by mitochondrial dysfunction (e.g., Parkinson and Alzheimer). Many of these diseases are a result of a mutation in one of the mitochondrial genes or a defective mitochondrial DNA (mtDNA) maintenance, mostly caused by genetic defects in proteins involved in mtDNA replication. In order to explore the diversity and understand the evolution of mitochondrial genomes (mitogenomes) in animals, multiple methods have been developed in this study to deal with two biological problems related to the mitochondrial genome evolution. A new method for identifying the mitochondrial origins of replication is presented. This method deals with the problem of determining the origins of replication, which despite many previous efforts has remained non-trivial even in the small genomes of animal mitochondria. The replication mechanism is of central interest to understand the evolution of mitochondrial genomes since it allows the duplication of the genetic information. The extensive work that has been done to study the replication of mitochondrial genomes has generated the assumption of the strand displacement model (SDM) also known as the standard model of replication that is known to leave the mitochondrial H-strand in a single stranded state exposing it to mutation and damage. Later on, other models of replication have been suggested such as the strand coupled bidirectional replication model, its refinement which assumes the bidirectional mode but with a unidirectional start, and the \"RNA incorporation throughout the lagging strand\" (RITOLS) model proposed as a refinement of the strand displacement model. Based on the observation that the GC-skew is correlated with the distance from the replication origins in the light of the strand displacement model of replication, a new computational method to infer the position of both the heavy strand and the light strand origins from nucleotide skew data has been developed. The method has been applied in a comprehensive survey of deuterostome mitochondria where conserved positions of the replication origins for the vast majority of vertebrates and cephalochordates have been inferred. Deviations from the consensus picture are presumably associated with genome rearrangements. Additionally, two methods for the identification of tRNA remolding events throughout Metazoa have been developed. Remolding changes the identity of a tRNA by a duplication and a point mutation(s) of the anticodon. This new tRNA takes the identity of another tRNA which is then lost. This can lead to artifacts in the annotation of mitogenomes and thus in studies of mitogenomic evolution. In this work, novel methods are developed to detect tRNA remolding in large-scale data sets. The first method represents an extension of the similarity-based approach to determine remolding candidates with high confidence. This approach uses an extended set of criteria based on both sequence and structural similarities of the tRNAs in conjunction with statistical tests. The second method is a novel phylogeny-based likelihood method which evaluates specific topologies of gene phylogenies of the two tRNA families relevant to a putative remolding event. Both methods have been applied to survey tRNA remolding throughout animal evolution. At least three novel remolding events are identified in addition to the ones previously mentioned in the literature. A detailed analysis of these remoldings showed that many of them are derived ancestral events. mtDNA replication tRNA remolding evolution mtDNA replication tRNA remolding evolution ddc:500
63	Estudos estruturais da Seril-tRNA Sintetase nativa e em interação com tRNAs cognatos de Trypanosoma brucei / Structural studies of the native Seryl-tRNA Synthetase and in interaction with cognates tRNAs from Trypanosoma brucei Daiana Evelin Martil 17 April 2014 (has links) A síntese de selenocisteína e sua incorporação co-traducional em selenoproteínas como resposta a um códon UGA em fase requerem uma complexa maquinaria molecular. Em eucariotos, foram identificados componentes que participam da reação de formação de selenocisteína: Seril-tRNA sintetase (SerRS), O-fosfoseril-tRNA quinase (PSTK), SECIS Binding Protein 2 SBP2, um fator de elongação específico para Sec (EFSec), selenofosfato sintetase 1 (SPS1) e selenofosfato sintetase 2 (SPS2), SEPSECS, proteína ligante de RNA SECp43, proteína ribossomal L30, um tRNA de inserção de selenocisteína (tRNASec, SELC) e uma sequência específica no RNA mensageiro (elemento SECIS). O primeiro passo da incorporação de selenocisteína em proteínas é realizado pela SerRS, que aminoacila o tRNA com serina através da ativação da serina por Mg+2 e ATP, levando a formação de um intermediário ligado a enzima (Ser-AMP). Posteriormente, ocorre a mudança do radical Ser do intermediário Ser-AMP para o tRNASec, e subsequentemente, a conversão enzimática de Ser-tRNASec para Sec-tRNASec. Através de análises in sílico nosso grupo identificou componentes da maquinaria de inserção de selenocisteína em espécies de Kinetoplastida. Foram identificados homólogos de tRNASec e as enzimas TbSerRS, TbSPS2, TbPSTK, TbSepSecS e TbEFSec. Nosso principal alvo é o estudo estrutural da SerRS de Trypanosoma brucei nativa e em complexo com o tRNASec e com as isoformas do tRNASer. Uma nova metodologia no processo de purificação desta enzima foi desenvolvida e, através das técnicas de cromatografia de exclusão molecular, espalhamento de luz dinâmico e ultracentrifugação analítica conseguimos determinar o estado oligomérico da TbSerRS. O resultado de dímeros em solução corroborou com dados reportados na literatura, além de verificarmos por meio de estudos de cinética enzimática que a enzima encontra-se ativa sob as condições utilizadas. A técnica de ultracentrifugação analítica de sedimentação em equilíbrio também nos permitiu verificar a formação do complexo SerRS-tRNA, mas não nos possibilitou definir a estequiometria deste complexo. Estudos estruturais da enzima nativa e em interação com os tRNAs SELC e com as isoformas do tRNASer, L-serina, um análogo não hidrolisável de AMP, MgCl2, e com porções menores dos tRNAs foram realizados por meio da cristalografia por difração de raios X. Através dessa técnica, dezessete conjunto de dados foram coletados, processados e estão em fase de refinamento. Algumas análises estruturais possibilitaram confirmar a presença de duas moléculas de glicerol em cada monômero na região do sítio ativo para a estrutura da TbSerRS nativa e uma molécula de dAMP para o complexo TbSerRS-dAMP. / The synthesis of selenocysteine and its co-translational incorporation in selenoproteins in response to a UGA codon in frame require complex molecular machinery. In eukaryotes, components that participate in the reaction of selenocysteine formation were identified: SeryltRNA synthetase (SerRS), O-phosphoseryl-tRNA kinase (PSTK), SECIS Binding Protein 2 - SBP2, a selenocysteine-specific elongation factor (EFSec), selenophosphate synthetase 1 (SPS1) and selenophosphate synthetase 2 (SPS2), SEPSECS, SECp43 RNA binding protein, ribosomal protein L30, selenocysteine tRNA (tRNASec, SELC), and a specific sequence in the messenger RNA (SECIS element). The first step for selenocysteine incorporating is performed by SerRS that aminoacylates the tRNA with serine through serine activation by Mg2+ and ATP leading to the formation of an intermediate linked to the enzyme (Ser-AMP). Subsequently, the change of the Ser radical to tRNASec takes place followed by the enzymatic conversion of Ser-tRNASec to Sec-tRNASec. Through in silico analysis our group has identified components of the selenocysteine insertion machinery in species of Kinetoplastida. Homologues of tRNASec and the enzymes TbSerRS, TbSPS2, TbPSTK, TbSepSecS and TbEFSec were identified. Our main target is the structural study of the native SerRS from Trypanosoma brucei and SerRS in complex with the tRNASec and the tRNASer isoforms. A new methodology in the purification process of this enzyme has been developed, and through molecular exclusion chromatography, dynamic light scattering and analytical ultracentrifugation techniques we were able to determine the oligomeric state of TbSerRS. The result of dimers in solution corroborated with the data reported in the literature. Moreover, we were able to verify through studies of enzyme kinetics that the enzyme is active. The sedimentation equilibrium analytical ultracentrifugation technique also demonstrated the formation of the SerRS-tRNA complex, however, it did not allow the definition of the complex stoichiometry. Structural studies of the native enzyme and its interaction with SELC, tRNASer isoforms, L-serine, a non-hydrolyzable AMP analog, MgCl2, and smaller portions of tRNAs were performed by X-ray diffraction crystallography. Through this technique, seventeen data sets were collected, processed, and are being submitted to refinement processes. Initial structural analysis allowed the confirmation of the presence of two glycerol molecules in each monomer in the active site region in the native structure of TbSerRS and one dAMP molecule in the TbSerRS-dAMP complex. Selenocisteína Seril-tRNA sintetase tRNASec tRNASer Selenocysteine Seryl-tRNA synthetase tRNASec tRNASer
64	Caracterização do papel da glutamil-tRNA sintetase na localização subcelular de proteínas / Characterization of the role of glutamyl-tRNA synthetase in the protein subcellular localization Luíza Lane de Barros Dantas 17 June 2010 (has links) Nos organismos eucariotos, aproximadamente 50% das proteínas traduzidas no citoplasma são transportadas para as organelas, onde irão desempenhar suas funções. Com isso, surgiu um intricado sistema de transporte intracelular de proteínas. Nas plantas, a presença de uma segunda organela endossimbionte, o plastídio, tornou este sistema mais complexo e gerou demanda adicional por transporte. Ainda, grande maioria das proteínas mitocondriais e plastidiais são codificadas por genes nucleares e importadas do citosol. O dogma uma proteína-uma localização foi associado ao conceito de um gene-uma proteína na biologia celular. Entretanto, proteínas individuais podem ter mais de uma função, e mais recentemente, proteínas codificadas por um único gene foram identificadas em mais de um compartimento subcelular, o que deu origem ao conceito de duplo direcionamento (DD). Um exemplo bem estudado de DD vem das proteínas da família das aminoacil-tRNA sintetases (aaRS), que participam da síntese protéica ao acoplar o aminoácido ao seu tRNA cognato. Dentre as aaRSs, a glutamil-tRNA sintetase citosólica (GluRS), através de sua extensão N-terminal, parece estar envolvida com outras funções além da tradução. Em Arabidopsis thaliana, há dois genes nucleares que codificam a GluRS, um para uma proteína de duplo direcionamento (DD) e outro para uma proteína citosólica. Resultados recentes em nosso laboratório mostraram que a GluRS citosólica pode estar relacionada ao controle da localização subcelular de proteínas organelares em Arabidopsis. Para verificar um eventual papel desta proteína na localização subcelular de outras proteínas, foram realizados ensaios de duplo-híbrido em levedura, os quais mostraram interação entre a GluRS e a glutamina sintetase (GS) de Arabidopsis thaliana, proteína de DD para mitocôndrias e cloroplastos Esta interação foi confirmada in planta, sendo a sequência da GluRS responsável pela interação localizada na região N-terminal, do resíduo 207 ao 316. Análises filogenéticas apontam que esta região encontra-se ausente nas bactérias e que originou-se provavelmente em Archea, entre 2,6 e 1,8 bilhões de anos. Além disso, observa-se que esta sequência é conservada em fungos, musgos e plantas vaculares, tendo originado-se em Arabidopsis há cerca de 2 bilhões de anos. / In eukaryotic organisms, about 50% of cytoplasmic translated proteins are transported to the organelles, where they can play their roles. Thus, a complex system for intracellular transport was established. In plants, the presence of a second endosymbiont organelle, the plastid, turned this system still more intricated and required an additional transport mechanism. Besides, most of organellar proteins are coded by nuclear genes and imported from the cytosol. The one protein-one localization was associated to the idea of one gene-one protein, which has long been established in molecular biology. However, individual proteins can show more than one function, and recently, proteins coded by one single gene were identified in more than one subcellular compartment, which has originated the concept of dual targeting. One of the most studied example of dual targeted proteins is the aminoacyl-tRNA synthetase (aaRS) family, which are related to protein synthesis by attaching the correct amino acid onto the cognate tRNA molecule. Among the aaRSs, cytosolic glutamyl-tRNA synthetase (GluRS), through its N-terminal extension, seems to be involved in other cellular role beyond translation. In Arabidopsis thaliana, there are two genes encoding GluRS, one for a dual-targeted protein and other for a cytosolic protein. Recent results in our laboratory showed that GluRS interacts with proteins destinated to other organelles, which suggest that this protein might have a role in interfering on protein localization in Arabidopsis. In order to gain some information on the role of this protein in subcellular localization, yeast two-hybrid assays were performed. These studies showed the interaction between GluRS and glutamine synthetase (GS), a mitochondrial and chloroplastic dual-targeted protein. This interaction was confirmed in planta. In addition, the GluRS sequence associated to protein interaction was localized at its N-terminal portion, between the residues 207 316. Phylogenetic analysis revealed that this region is absent in bacteria and it probably arose from Archea between 2.6 and 1.8 billion years ago. Also, this sequence is conserved in fungi, moss and all the green plants investigated. Finally, datation analysis showed that this sequence arose in Arabidopsis between 2 and 1.7 billion years ago. Aminoacil tRNA sintetase Glutamina Leveduras Proteínas - Localização. Aminoacyl-tRNA Synthetase Glutamine Protein Localization. Yeast
65	Rôle de l'import des ARN de transfert de l'hôte dans le développement Plasmodium / Role of host's transfer RNA import in Plasmodium development Kapps, Delphine 23 September 2016 (has links) La protéine tRip de Plasmodium, l’agent du paludisme, fait l’objet de mon travail de thèse. Identifiée au laboratoire, elle est localisée à la membrane plasmique de P. berghei, le modèle murin étudié in vivo. Elle permet l’import d’ARNt exogènes à l’intérieur du parasite. La génération et l’étude d’une souche P. berghei tRip-KO m’ont permis d’explorer l’importance de ce mécanisme et l’implication de tRip dans un complexe multiprotéique. J’ai démontré que la multiplication de P. berghei est très réduite lors du stade sanguin chez la souche tRip-KO. Par protéomique, j’ai montré qu’en l’absence de tRip, de nombreuses protéines sont sous-exprimées, en particulier celles riches en asparagines. Enfin, j’ai identifié trois partenaires protéiques de tRip, dont le substrat est l’ARNt. Ces résultats suggèrent que les ARNt importés par Plasmodium via tRip pourraient être substrat de protéines plasmodiales et acteurs de la synthèse protéique du parasite. Le transport d’ARNt étrangers dans une cellule est un mécanisme inconnu en dehors de cette étude. Il révèle une interaction inédite entre un hôte et son parasite intracellulaire, propice au développement de ce dernier. / The organism studied in this work is Plasmodium, the malaria parasite. The laboratory identified a membrane protein, called tRip for tRNA import protein, displaying a tRNA binding domain exposed outside of the parasite. In vivo, in P. berghei which is the murine model used, tRip mediates the import of exogenous tRNAs into the parasite cytosol. My PhD work begun with the construction of a tRip-KO strain of P. berghei to investigate the role of tRNA import and the putative involvement of tRip within a proteic complex. The phenotype of the tRip-KO strain is significantly modified compared to the wild-type parasite during the blood stage: its rate of multiplication is much lower. By proteomic analyses, I showed that many proteins are under-regulated in the tRip-KO strain, especially those very rich in asparagines. Moreover, I dentified three protein partners for tRip, being tRNA aminoacylation or modification enzymes. These results suggest that host imported tRNAs could be taken in charge by parasitic enzymes and take part to Plasmodium protein synthesis. This work reveals a new host pathogen interaction and is the first example showing exogenous tRNA import into a cell. Plasmodium ARNt Import d’ARNt Synthèse protéique Plasmodium TRNA TRNA import Protein synthesis 572.8 616.96
66	The Biochemical Characterization of Human Histidyl-tRNA Synthetase and Disease Associated Variants Abbott, Jamie Alyson 01 January 2017 (has links) Human histidyl-tRNA synthetase (HARS) is an aminoacyl-tRNA synthetase (AARS) that catalyzes the attachment of the amino acid histidine to histidyl-tRNA (tRNAHis) in a two-step reaction that is essential for protein translation. Currently, two human diseases, Usher Syndrome IIIB (USH3B) and an inherited peripheral neuropathy, Charcot Marie Tooth Syndrome (CMT), have been linked genetically to single point mutations in the HARS gene. The recessive HARS USH3B mutation encodes an Y454S substitution localized at the interface between the anticodon-binding domain and the catalytic domain of the opposing subunit. Patients with Usher Syndrome IIIB lose their sight and hearing during their second decade of life, and clinicians have observed that the onset of deafness and blindness may be episodic and correlate with febrile illness. Furthermore, some young USH3B patients present with a fatal form of acute respiratory distress. In addition to the single HARS mutation linked to Usher Syndrome, eight other mutations in the HARS gene are associated with CMT, an inherited peripheral neuropathy. Peripheral neuropathies are associated with progressive and length-dependent damage of the motor and sensory neurons that transmit information to the spinal cord. The age of onset and phenotypic severity of CMT linked to HARS is highly variable. When expressed in a yeast model system, the HARS variants are dominantly lethal, and confer defects in axonal guidance and locomotor deficiencies when expressed in C.elegans. Here, the biochemical characterization of the HARS USH3B and three peripheral neuropathy variants are described. The approaches included enzyme kinetic analysis with purified HARS enzymes to monitor catalytic deficiencies, differential scanning fluorimetry (DSF) to evaluate structural instability, and cellular models to detect physiological effects of axonal outgrowth by CMT variants. The results suggest that Usher Syndrome IIIB is unlikely to be a consequence of a simple loss of aminoacylation function, while HARS-linked peripheral neuropathy variants all share common catalytic defects in aminoacylation. The HARS system represents a notable example in which two different complex human diseases arise from distinct mutations in the same parent gene. By understanding the biochemical basis of these inherited mutations and their link to Usher Syndrome and CMT, it may be possible to develop mechanism-based therapies to improve the quality of life of patients afflicted with them. aminoacylation Charcot Marie Tooth Syndrome histidyl-tRNA synthetase peripheral neuropathy tRNA Usher Syndrome Biochemistry Neuroscience and Neurobiology
67	Differential Expression Of tRNA1 Gly Genes From Within A Multigene Family In Bombyx Mori Parthasarthy, Akhila 05 1900 (has links) (PDF) No description available. Bombyx mori - RNA RNA Gene Expression B. mori tRNA TFIIIB tRNA Gly Genes Biochemical Genetics
68	The identity of the discriminator base has an impact on CCA addition Wende, Sandra, Bonin, Sonja, Götze, Oskar, Betat, Heike, Mörl, Mario January 2015 (has links) CCA-adding enzymes synthesize and maintain the C-C-A sequence at the tRNA 3''-end, generating the attachment site for amino acids. While tRNAs are the most prominent substrates for this polymerase, CCA additions on non-tRNA transcripts are described as well. To identify general features for substrate requirement, a pool of randomized transcripts was incubated with the human CCA-adding enzyme. Most of the RNAs accepted for CCA addition carry an acceptor stem-like terminal structure, consistent with tRNA as the main substrate group for this enzyme. While these RNAs show no sequence conservation, the position upstream of the CCA end was in most cases represented by an adenosine residue. In tRNA, this position is described as discriminator base, an important identity element for correct aminoacylation. Mutational analysis of the impact of the discriminator identity on CCA addition revealed that purine bases (with a preference for adenosine) are strongly favoured over pyrimidines. Furthermore, depending on the tRNA context, a cytosine discriminator can cause a dramatic number of misincorporations during CCA addition. The data correlate with a high frequency of adenosine residues at the discriminator position observed in vivo. Originally identified as a prominent identity element for aminoacylation, this position represents a likewise important element for efficient and accurate CCA addition. info:eu-repo/classification/ddc/572 ddc:572 Enzyme, CAA, tRNA enzymes, CAA, tRNA
69	Analysis of Unusual Eukaryotic tRNA Nucleotidyltransferases and Establishment of a High-Throughput Sequencing Method for Mature tRNAs Erber, Lieselotte 10 August 2020 (has links) Transfer RNA nucleotidyltransferases (CCA-adding enzymes) are important enzymes, which catalyze the attachment of a CCA triplet to the 3‘ end of tRNAs, an essential requirement for subsequent aminoacylation. These special enzymes function in a fascinating manner without a nucleic acid template. Furthermore, a substrate affinity switch from CTP to ATP is fulfilled with high specificity and the reaction is precisely terminated after addition of the terminal ATP. In some bacteria, the CCA-adding activity is divided into two enzymes: a CC- and an A-adding enzyme. This diversity that was long only assigned to Bacteria. However, the growing number of eukaryotic genomes allowed for deep bioinformatic investigation, revealing several eukaryotic organisms with an unusual amount of tRNA nucleotidyltransferase genes. In the present work, the function of several tRNA nucleotidyltransferases found in the genome of certain fungi, amoeba and choanoflagellates was investigated. For the tRNA nucleotidyltrans-ferases detected in Salpingoeca rosetta and Schizosaccharomyces pombe, a divided activity similar to bacterial CC- and A-adding enzymes could be observed. Additionally, in the amoeba Dictyostelium discoideum two bona fide CCA-adding enzymes were found, which are inversely regulated during the developmental cycle. In the amoeba Acanthamoeba castellanii, four different tRNA nucleotidyltransferases with different activities, localization and evolutionary origin were identified. Moreover, a method for the precise analysis of mature tRNAs by high-throughput sequencing was established as well. This method includes the specific ligation of a hairpin adapter molecule, which complementarily and highly efficiently binds to tRNAs with a 3’-CCA end resulting in a very specific preparation of tRNAs for high-throughput sequencing. It also allows for analysis of some modified bases usually found in tRNAs, which was used to analyze the alteration of certain tRNA modifications during the developmental cycle of D. discoideum.:Erklärung der Selbstständigkeit II List of Abbreviations V Bibliografische Darstellung VII Zusammenfassung 1 Summary 6 Chapter I 11 1.1. Transfer RNAs 12 1.1.1. Structure and maturation of transfer ribonucleic acids (tRNAs) 12 1.1.2. tRNAs as regulatory molecules and their role in diseases 13 1.1.3. Sequencing of tRNAs – a special challenge 14 1.1.4. The 3’-CCA end of tRNAs 15 1.2. tRNA nucleotidyltransferases 16 1.2.1. Classification and biological roles 16 1.2.2. Class II tRNA nucleotidyltransferases 18 1.2.3. Enzymes with split activity – bacterial CC- and A-adding enzymes 19 1.2.4. Two types of eukaryotic tRNA nucleotidyltransferases 21 1.2.5. Distribution of eukaryotic organisms with multiple tRNA nucleotidyltransferase genes 22 1.3. Aim of the work 23 1.4. References 25 Chapter II 33 Chapter III 44 Chapter IV 75 Chapter V 100 Chapter VI 119 Publications and Presentations IX Author Contribution Statement XI Danksagung XVI info:eu-repo/classification/ddc/570 ddc:570
70	Catalytic and Biological Implications of The Eukaryotic and Prokaryotic Thg1 Enzyme Family Matlock, Ashanti Ochumare 17 June 2019 (has links) No description available. Biochemistry Molecular Biology tRNA modifications tRNA guanylyltransferase chemical footprinting Protein-RNA interactions Myxococcus xanthus

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