Role of phenylalanyl-tRNA synthetase in translation quality control

Ling, Jiqiang

05 September 2008

No description available.

Biochemistry

tRNA

synthetase

editing

mechanism

mitochondrial disease

MODIFICATION AND EDITING IN MITOCHONDRIAL TRYPTOPHAN tRNA OF TRYPANOSOMES

Wohlgamuth-Benedum, Jessica M.

09 September 2009

No description available.

Biochemistry

Microbiology

tRNA

editing

modification

thiolation

Editing and Modification of Threonyl-tRNAs in Kinetoplastids

Gaston, Kirk W.

11 September 2009

No description available.

Microbiology

tRNA

modification

editing

kinetoplastid

Leishmania

Trypanosoma

<i>Trypanosoma brucei</i> tRNA Editing Deaminase: Conserved Deaminase Core, Unique Deaminase Features

Spears, Jessica Lynn

27 July 2011

No description available.

Biochemistry

Microbiology

tRNA

deaminase

ADAT

enzyme kinetics

Characterization of two novel proteins containing the rhodanese homology domain: YgaP and YbbB of Escherichia coli

Ahmed, Farzana

22 August 2003

Rhodanese homology domains are ubiquitous structural modules found in eubacteria, eukaryotes and archaea. The rhodanese homology domain may comprise the entire structure of a protein. Alternatively it is found as tandemly repeated modules in which the C-terminal domain displays the properly structured active site. Finally it is found as a member of many multidomain proteins. Although some members of this family of proteins show sulfurtransferase activity in vitro, their specific physiological functions remain largely undefined. Fusion of a rhodanese domain to different protein domains of known or unknown functions provides important clues to the diverse roles for these proteins. Nine proteins containing the rhodanese homology domain are predicted in Escherichia coli. In this work, two of these proteins: YgaP and YbbB were characterized using bioinformatics, biochemical and genetic approaches. YgaP is a single domain rhodanese that is predicted to contain an amino-terminal rhodanese domain (118 amino acids) and a hydrophobic carboxy-terminal domain (56 amino acids). The ygaP gene was cloned into a vector that directed overexpression of a membrane-associated rhodanese activity. The cellular location of YgaP was determined by using sucrose density layer ultracentrifugation. YgaP and rhodanese activity co-sedimented with the cytoplasmic membrane marker D-lactate dehydrogenase, and was not present in the outer membrane fractions, indicating YgaP is a cytoplasmic membrane protein. A polyhistidine-tagged variant of YgaP was subsequently solubilized from the membrane by detergent extraction and purified by metal chelate chromatography. Similar to the other characterized rhodaneses, purified YgaP-His6 as well as the membrane-associated native form of the protein displayed a double displacement (ping-pong) mechanism. YgaP is unique in that it is the first membrane-associated rhodanese to be described. To understand the physiological role of YgaP, a strain with ygaP gene disruption was constructed. No obvious phenotype resulted from deletion of ygaP. The ybbB gene of E. coli has an interesting genome organization in several Gram-negative bacteria including Pseudomonas aeruginosa and Azotobacter vinelandii where it is predicted to be in the same operon with selD, encoding selenophosphate synthetase. Thus the role of YbbB in selenium metabolism was investigated. A strain with ybbB gene deletion was constructed and tested for its ability to incorporate 75Se into tRNA and protein. It was shown that the disruption of ybbB prevented specific incorporation of selenium into tRNA but not into proteins in vivo. The modified nucleoside missing in tRNAs of the DybbB strain was identified as 5-methylaminomethyl-2-selenouridine (mnm5se2U), which has previously been shown to be present in the wobble position of the anticodon of E. coli tRNAsLys, Glu and Gln. Data from HPLC analysis showed that the deletion of ybbB did not affect the production of 5-methylaminomethyl-2-thiouridine (mnm5s2U), the precursor to mnm5se2U, suggesting that YbbB is not required for sulfur transfer but is rather involved in selenation of tRNAs. YbbB was subsequently expressed with a C-terminal histidine tag and purified for initial characterization. Purified YbbB-His6 migrated as a 43 kDa monomer under denaturing conditions and displayed spectral properties that suggested its interaction with tRNA. Finally, it was shown that Cys97, which aligns with the active site cysteine of rhodanese and is conserved in all known YbbB homologs, is required for YbbB activity. However, Cys96, which is not conserved, is not required for activity. / Ph. D.

seleno-tRNA

YgaP

YbbB

2-selenouridine

rhodanese

Orthologs, turn-over, and remolding of tRNAs in primates and fruit flies

Velandia-Huerto, Cristian A., Berkemer, Sarah J., Hoffmann, Anne, Retzlaff, Nancy, Romero Marroquín, Liiana C., Hernández-Rosales, Maribel, Stadler, Peter F., Bermúdez-Santana, Clara I.

05 September 2016

Background: Transfer RNAs (tRNAs) are ubiquitous in all living organism. They implement the genetic code so that most genomes contain distinct tRNAs for almost all 61 codons. They behave similar to mobile elements and proliferate in genomes spawning both local and non-local copies. Most tRNA families are therefore typically present as multicopy genes. The members of the individual tRNA families evolve under concerted or rapid birth-death evolution, so that paralogous copies maintain almost identical sequences over long evolutionary time-scales. To a good approximation these are functionally equivalent. Individual tRNA copies thus are evolutionary unstable and easily turn into pseudogenes and disappear. This leads to a rapid turnover of tRNAs and often large differences in the tRNA complements of closely related species. Since tRNA paralogs are not distinguished by sequence, common methods cannot not be used to establish orthology between tRNA genes. Results: In this contribution we introduce a general framework to distinguish orthologs and paralogs in gene families that are subject to concerted evolution. It is based on the use of uniquely aligned adjacent sequence elements as anchors to establish syntenic conservation of sequence intervals. In practice, anchors and intervals can be extracted from genome-wide multiple sequence alignments. Syntenic clusters of concertedly evolving genes of different families can then be subdivided by list alignments, leading to usually small clusters of candidate co-orthologs. On the basis of recent advances in phylogenetic combinatorics, these candidate clusters can be further processed by cograph editing to recover their duplication histories. We developed a workflow that can be conceptualized as stepwise refinement of a graph of homologous genes. We apply this analysis strategy with different types of synteny anchors to investigate the evolution of tRNAs in primates and fruit flies. We identified a large number of tRNA remolding events concentrated at the tips of the phylogeny. With one notable exception all phylogenetically old tRNA remoldings do not change the isoacceptor class. Conclusions: Gene families evolving under concerted evolution are not amenable to classical phylogenetic analyses since paralogs maintain identical, species-specific sequences, precluding the estimation of correct gene trees from sequence differences. This leaves conservation of syntenic arrangements with respect to "anchor elements" that are not subject to concerted evolution as the only viable source of phylogenetic information. We have demonstrated here that a purely synteny-based analysis of tRNA gene histories is indeed feasible. Although the choice of synteny anchors influences the resolution in particular when tight gene clusters are present, and the quality of sequence alignments, genome assemblies, and genome rearrangements limits the scope of the analysis, largely coherent results can be obtained for tRNAs. In particular, we conclude that a large fraction of the tRNAs are recent copies. This proliferation is compensated by rapid pseudogenization as exemplified by many very recent alloacceptor remoldings.

Konzertierte Evolution

tRNA

Struktur

Syntenie

Orthologie

concerted evolution

tRNA remolding

synteny

orthology

ddc:570

ddc:004

Análise da especificidade do tRNASec entre o fator de elongação específico para selenocisteínas (SelB) e Seril-tRNA Sintetase (SerRS) de Escherichia coli / The tRNASec specific interaction of Escherichia coli Selenocysteine Elongation Factor (SelB) and Seryl-tRNA Synthetase (SerRS)

Fernandes, Adriano de Freitas

21 February 2017

A selenocisteína (Sec, U) é o aminoácido que representa a principal forma biológica do elemento selênio e sua incorporação é um processo co-traducional em selenoproteínas como resposta ao códon UGA em fase e requer uma complexa maquinaria molecular. O repertório completo de genes envolvidos nessa via de síntese em procariotos é conhecido, porém algumas das interações moleculares ainda não foram totalmente esclarecidas. Este projeto visa à caracterização molecular nas interações entre o Fator de Elongação específico para incorporação de Sec (SelB) e Seril-tRNA sintetase (SerRS) com distintas construções do tRNASec de Escherichia coli afim de compreender a sua especificidade, seletividade e ordem de eventos. Para isso, medidas de Espectroscopia de Anisotropia de Fluorescência (FAS), Ultracentrifugação Analítica (AUC) e Calorimetria de Varredura Diferencial (DSC) foram utilizadas para determinação das constantes de interação desses complexos proteína-tRNA. Além disto, experimentos de Espalhamento de Raios-X a baixo ângulo (SAXS) e Microscopia eletrônica de transmissão por contraste negativo (NS-EM) foram realizados para elucidação estrutural destes complexos. Os estudos propostos irão auxiliar no entendimento do mecanismo de incorporação e de especificidade do tRNA para este aminoácido em bactérias bem como nos demais domínios da vida além de possibilitar um aumento na compreensão de complexos do tipo proteína-tRNA bem como salientar a importância dos elementos estruturais do tRNA para sua especificidade no processo de síntese de novas proteínas. / Selenocysteine (Sec, U) is an amino acid that represents the main biological form of the selenium element and its incorporation is a co-translational process in selenoproteins in response to the in-phase UGA codon and requires complex molecular machinery. The complete repertoire of genes involved in this pathway of synthesis in prokaryotes is known, although some of the molecular interactions have not yet been fully elucidated. This project aims at the molecular characterization in the interactions between the specific elongation factor for the incorporation of Sec (SelB) and Seril-tRNA synthase (SerRS) with different constructions of tRNASec from Escherichia coli in order to their specificity, selectivity and order of events. For this, measurements using Fluorescence Anisotropy Spectroscopy (FAS), Analytical Ultracentrifugation (AUC) and Differential Scanning Calorimetry (DSC) were employed to determine the interaction constants of the protein-tRNA complexes. In addition, Small Angle X-Ray Scattering (SAXS) experiments and negative stain transmission electron microscopy (NS-EM) were performed for structural elucidation of these complexes. The proposed studies will help to understand the mechanism of tRNA incorporation and specificity for this amino acid in bacteria as well as other domains of life. In addition, it allows an increase in the understanding of protein-tRNA-like complexes as well as emphasizing the importance of structural elements of tRNA for its specificity in the process of synthesis of new proteins.

Fator de elongação específico

Interação proteína-tRNA

Protein-tRNA interaction

Selenocisteína

Selenocysteine

Specific elongation factor

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

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

Análise da especificidade do tRNASec entre o fator de elongação específico para selenocisteínas (SelB) e Seril-tRNA Sintetase (SerRS) de Escherichia coli / The tRNASec specific interaction of Escherichia coli Selenocysteine Elongation Factor (SelB) and Seryl-tRNA Synthetase (SerRS)

Adriano de Freitas Fernandes

21 February 2017

A selenocisteína (Sec, U) é o aminoácido que representa a principal forma biológica do elemento selênio e sua incorporação é um processo co-traducional em selenoproteínas como resposta ao códon UGA em fase e requer uma complexa maquinaria molecular. O repertório completo de genes envolvidos nessa via de síntese em procariotos é conhecido, porém algumas das interações moleculares ainda não foram totalmente esclarecidas. Este projeto visa à caracterização molecular nas interações entre o Fator de Elongação específico para incorporação de Sec (SelB) e Seril-tRNA sintetase (SerRS) com distintas construções do tRNASec de Escherichia coli afim de compreender a sua especificidade, seletividade e ordem de eventos. Para isso, medidas de Espectroscopia de Anisotropia de Fluorescência (FAS), Ultracentrifugação Analítica (AUC) e Calorimetria de Varredura Diferencial (DSC) foram utilizadas para determinação das constantes de interação desses complexos proteína-tRNA. Além disto, experimentos de Espalhamento de Raios-X a baixo ângulo (SAXS) e Microscopia eletrônica de transmissão por contraste negativo (NS-EM) foram realizados para elucidação estrutural destes complexos. Os estudos propostos irão auxiliar no entendimento do mecanismo de incorporação e de especificidade do tRNA para este aminoácido em bactérias bem como nos demais domínios da vida além de possibilitar um aumento na compreensão de complexos do tipo proteína-tRNA bem como salientar a importância dos elementos estruturais do tRNA para sua especificidade no processo de síntese de novas proteínas. / Selenocysteine (Sec, U) is an amino acid that represents the main biological form of the selenium element and its incorporation is a co-translational process in selenoproteins in response to the in-phase UGA codon and requires complex molecular machinery. The complete repertoire of genes involved in this pathway of synthesis in prokaryotes is known, although some of the molecular interactions have not yet been fully elucidated. This project aims at the molecular characterization in the interactions between the specific elongation factor for the incorporation of Sec (SelB) and Seril-tRNA synthase (SerRS) with different constructions of tRNASec from Escherichia coli in order to their specificity, selectivity and order of events. For this, measurements using Fluorescence Anisotropy Spectroscopy (FAS), Analytical Ultracentrifugation (AUC) and Differential Scanning Calorimetry (DSC) were employed to determine the interaction constants of the protein-tRNA complexes. In addition, Small Angle X-Ray Scattering (SAXS) experiments and negative stain transmission electron microscopy (NS-EM) were performed for structural elucidation of these complexes. The proposed studies will help to understand the mechanism of tRNA incorporation and specificity for this amino acid in bacteria as well as other domains of life. In addition, it allows an increase in the understanding of protein-tRNA-like complexes as well as emphasizing the importance of structural elements of tRNA for its specificity in the process of synthesis of new proteins.

Fator de elongação específico

Interação proteína-tRNA

Selenocisteína

Protein-tRNA interaction

Selenocysteine

Specific elongation factor

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

Martil, Daiana Evelin

17 April 2014

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

Selenocysteine

Seril-tRNA sintetase

Seryl-tRNA synthetase

tRNASec

tRNASec

tRNASer

tRNASer