Global ETD Search

11	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 Dantas, Luíza Lane de Barros 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 Aminoacyl-tRNA Synthetase Glutamina Glutamine Leveduras Protein Localization. Proteínas - Localização. Yeast
12	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
13	Mistranslation and Quality Control of Aminoacyl-tRNA Synthetases Han, Nien-Ching 07 October 2021 (has links) No description available. Microbiology Molecular Biology Biochemistry Aminoacyl-tRNA synthetase Translation quality control Mistranslation BMAA AlaRS PheRS
14	Role of Coupled Dynamics and a Strictly Conserved Lysine Residue in the Function of Bacterial Prolyl-tRNA Synthetase and Substrate Binding by a Related <i>trans</i>-Editing Enzyme ProXp-ala Sanford, Brianne 05 September 2014 (has links) No description available. Biochemistry Chemistry Aminoacyl-tRNA synthetase editing translation protein synthesis computational chemistry NMR
15	The Role in Translation of Editing and Multi-Synthetase Complex Formation by Aminoacyl-tRNA Synthetases Raina, Medha Vijay 25 September 2014 (has links) No description available. Biochemistry protein synthesis tRNA aminoacyl-tRNA synthetase multi-synthetase complex quality control editing
16	Beyond Mistranslation: Expanding the Role of Aminoacyl-tRNA Synthetases towards the Maintenance of Cellular Viability Mohler, Kyle 27 October 2017 (has links) No description available. Microbiology Cellular Biology
17	ROLE OF PHENYLALANYL-TRNA SYNTHETASE IN AMINOACYLATION AND TRANSLATION QUALITY CONTROL Yadavalli, Srujana Samhita 27 June 2012 (has links) No description available. Biochemistry Microbiology protein synthesis tRNA aminoacyl-tRNA synthetase quality control editing mitochondrial disease
18	Changes In Threonyl-Trna Synthetase Expression And Secretion In Response To Endoplasmic Reticulum Stress By Monensin In Ovarian Cancer Cells Hammer, Jared Louis 01 January 2017 (has links) Aminoacyl-tRNA synthetases (ARS) are a family of enzymes that catalyze the charging of amino acids to their cognate tRNA in an aminoacylation reaction. Many members of this family have been found to have secondary functions independent of their primary aminoacylation function. Threonyl-tRNA synthetase (TARS), the ARS responsible for charging tRNA with threonine, is secreted from endothelial cells in response to both vascular endothelial growth factor (VEGF) and tumor necrosis factor-α (TNF-α), and stimulates angiogenesis and cell migration. Here we show a novel experimental approach for studying TARS secretion, and for observing the role of intracellular TARS in the endoplasmic reticulum (ER) stress response and in angiogenesis. Using Western blotting, immunofluorescence microscopy and RT-qPCR we were able to investigate changes in TARS protein and transcript levels. We initially hypothesized that TARS was secreted by exosomal release, and so we treated a human ovarian cancer cell line (CaOV-3) with monensin, an ionophore that increases exosome production, and VEGF to observe changes in intracellular and extracellular TARS protein. Monensin treatment consistently increased extracellular and intracellular TARS protein, however CD63, an exosome marker protein, levels were unaffected by monensin treatment. VEGF had no effect on intracellular TARS. We therefore hypothesized that the TARS response was a result of ER stress. The unfolded protein response (UPR) is a series of signaling pathways that are activated upon ER stress. When CaOV-3 cells were treated with increasing concentrations of monensin, intracellular levels of TARS and p-eIF2α, a downstream UPR target, increased accordingly. Monensin increased intracellular TARS protein and transcript levels in CaOV-3 cells. Monensin also increased DNAJB9, an ER chaperone protein, transcript levels, further confirming ER stress. Interestingly, monensin increased VEGF transcript levels about 6-fold. Borrelidin, a natural TARS inhibitor, also increased VEGF transcript levels, and caused an increase in p-eIF2α protein. Although the mechanism of TARS secretion remains unresolved, these data indicate that intracellular TARS expression increases in response to ER stress by monensin. Given TARS and VEGF transcript expression increased accordingly, it is possible that intracellular TARS may have pro-angiogenic function. Future directions may include investigating TARS interactions with translational control machinery. aminoacyl tRNA synthetase angiogenesis ER stress exosome ovarian cancer threonyl tRNA synthetase (TARS) Biochemistry Cell Biology Pharmacology
19	Regulation of aminoacyl-tRNA synthetase genes in <I>Bacillus subtilis</I> Williams-Wagner, Rebecca N. 30 September 2016 (has links) No description available. Microbiology Gene regulation Bacillus subtilis aminoacyl-tRNA synthetase MarR-family transcriptional regulators T box riboswitch tRNA D-tyrosine biofilm
20	Characterizing the role of the bifunctional glutamyl-prolyl-tRNA synthetase in humandiseases Jin, Danni January 2021 (has links) No description available. Biochemistry Biology Molecular Biology Virology Aminoacyl-tRNA synthetase tRNA multi-synthetase complex EPRS genetic disease HIV-1 integrated stress response

Search results