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45 results on '"Armengod, M.-Eugenia"'

4. Structure-function analysis of Escherichia coli MnmG (GidA), a highly conserved tRNA-modifying enzyme

Author

Shi, Rong, Villarroya, Magda, Ruiz-Partida, Rafael, Li, Yunge, Proteau, Ariane, Prado, Silvia, Moukadiri, Ismail, Benitez-Paez, Alfonso, Lomas, Rodrigo, Wagner, John, Matte, Allan, Velazquez-Campoy, Adrian, Armengod M.-Eugenia, and Cygler, Miroslaw

Subjects
Escherichia coli -- Physiological aspects, Transfer RNA -- Physiological aspects, Flavin adenine dinucleotide -- Properties, Biological sciences
Abstract

The MnmE-MnmG complex is involved in tRNA modification. We have determined the crystal structure of Escherichia coli MnmG at 2.4-[Angstrom] resolution, mutated highly conserved residues with putative roles in flavin adenine dinucleotide (FAD) or tRNA binding and MnmE interaction, and analyzed the effects of these mutations in vivo and in vitro. Limited trypsinolysis of MnmG suggests significant conformational changes upon FAD binding. doi: 10.1128/JB.00650-09

Published
2009

10. Transcription termination in the Escherichia coli dnaA gene is not mediated by the internal DnaA box

Author

Perez-Roger, Ignacio, Macian, Fernando, and Armengod, M. Eugenia

Subjects
Escherichia coli -- Research, DNA binding proteins -- Analysis, Biological sciences
Abstract

There is an absence of a regulatory role by internal Dna box in dnaA expression. However, initiation of chromosomal replication and transcription of a number of genes is regulated by a DnaA protein binding to DnaA boxes. The dnaA gene consists of two DnaA boxes located one each in regulatory region and in the structural gene. Since it has been proposed that DnaA box-DnaA protein can block transcribing RNA polymerase, the role of the internal DnaA box in dnaA expression has been researched.

Published
1995

18. Defective Expression of the Mitochondrial-tRNA Modifying Enzyme GTPBP3 Triggers AMPK-Mediated Adaptive Responses Involving Complex I Assembly Factors, Uncoupling Protein 2, and the Mitochondrial Pyruvate Carrier

Author

Martínez-Zamora, Ana, primary, Meseguer, Salvador, additional, Esteve, Juan M., additional, Villarroya, Magda, additional, Aguado, Carmen, additional, Enríquez, J. Antonio, additional, Knecht, Erwin, additional, and Armengod, M.-Eugenia, additional

Published
2015
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19. Bacillus subtilisexhibits MnmC-like tRNA modification activities

Author

Moukadiri, Ismaïl, Villarroya, Magda, Benítez-Páez, Alfonso, and Armengod, M.-Eugenia

Abstract

ABSTRACTThe MnmE-MnmG complex of Escherichia coliuses either ammonium or glycine as a substrate to incorporate the 5-aminomethyl or 5-carboxymethylaminomethyl group into the wobble uridine of certain tRNAs. Both modifications can be converted into a 5-methylaminomethyl group by the independent oxidoreductase and methyltransferase activities of MnmC, which respectively reside in the MnmC(o) and MnmC(m) domains of this bifunctional enzyme. MnmE and MnmG, but not MnmC, are evolutionarily conserved. Bacillus subtilislacks genes encoding MnmC(o) and/or MnmC(m) homologs. The glycine pathway has been considered predominant in this typical gram-positive species because only the 5-carboxymethylaminomethyl group has been detected in tRNALysUUUand bulk tRNA to date. Here, we show that the 5-methylaminomethyl modification is prevalent in B. subtilistRNAGlnUUGand tRNAGluUUC. Our data indicate that B. subtilishas evolved MnmC(o)- and MnmC(m)-like activities that reside in non MnmC homologous protein(s), which suggests that both activities provide some sort of biological advantage.

Published
2018
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24. Enzymology of tRNA modification in the bacterial MnmEG pathway

Author

Armengod, M.-Eugenia, primary, Moukadiri, Ismaïl, additional, Prado, Silvia, additional, Ruiz-Partida, Rafael, additional, Benítez-Páez, Alfonso, additional, Villarroya, Magda, additional, Lomas, Rodrigo, additional, Garzón, María J., additional, Martínez-Zamora, Ana, additional, Meseguer, Salvador, additional, and Navarro-González, Carmen, additional

Published
2012
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28. Characterization of Human GTPBP3, a GTP-Binding Protein Involved in Mitochondrial tRNA Modification

Author

Villarroya, Magda, primary, Prado, Silvia, additional, Esteve, Juan M., additional, Soriano, Miguel A., additional, Aguado, Carmen, additional, Pérez-Martínez, David, additional, Martínez-Ferrandis, José I., additional, Yim, Lucía, additional, Victor, Victor M., additional, Cebolla, Elvira, additional, Montaner, Asunción, additional, Knecht, Erwin, additional, and Armengod, M.-Eugenia, additional

Published
2008
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30. Polymorphisms in TRAIL receptor genes and risk of breast cancer in Spanish women

Author

Martinez-Ferrandis, José I., primary, Rodríguez-López, Raquel, additional, Milne, Roger L., additional, González, Emilio, additional, Cebolla, Elvira, additional, Chirivella, Isabel, additional, Zamora, Pilar, additional, Arias, José I., additional, Palacios, Santiago, additional, Cervantes, Andrés, additional, Díez, Orland, additional, Benitez, Javier, additional, and Armengod, M.-Eugenia, additional

Published
2007
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34. The variant E233G of theRAD51Dgene could be a low-penetrance allele in high-risk breast cancer families withoutBRCA1/2mutations

Author

Rodríguez-López, Raquel, primary, Osorio, Ana, additional, Ribas, Gloria, additional, Pollán, Marina, additional, Sánchez-Pulido, Luis, additional, de la Hoya, Miguel, additional, Ruibal, Álvaro, additional, Zamora, Pilar, additional, Arias, Jose Ignacio, additional, Salazar, Raquel, additional, Vega, Ana, additional, Martínez, Jose Ignacio, additional, Esteban-Cardeñosa, Eva, additional, Alonso, Carmen, additional, Letón, Rocío, additional, Urioste Azcorra, Miguel, additional, Miner, Cristina, additional, Armengod, M. Eugenia, additional, Carracedo, Angel, additional, González-Sarmiento, Rogelio, additional, Caldés, Trinidad, additional, Díez, Orland, additional, and Benítez, Javier, additional

Published
2004
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36. Molecular genetics of familial hypercholesterolemia in Spain: Ten novel LDLR mutations and population analysis

Author

García-García, Ana B., primary, Real, José T., additional, Puig, Oscar, additional, Cebolla, Elvira, additional, Marín-García, Pablo, additional, Martínez Ferrandis, Jose I., additional, García-Sogo, Magdalena, additional, Civera, Miguel, additional, Ascaso, Juan F., additional, Carmena, Rafael, additional, Armengod, M. Eugenia, additional, and Chaves, F. Javier, additional

Published
2001
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37. Structural Basis for Fe-S Cluster Assembly and tRNA Thiolation Mediated by IscS Protein-Protein Interactions.

Author

Rong Shi, Proteau, Ariane, Villarroya, Magda, Moukadiri, Ismaïl, Linhua Zhang, Trempe, Jean-François, Matte, Allan, Armengod, M. Eugenia, and Cygler, Miroslaw

Subjects
CYSTEINE desulfurase, ENZYMES, PHYSIOLOGICAL effects of sulfur, BIOSYNTHESIS, URIDINE, PROTEINS
Abstract

The cysteine desulfurase IscS is a highly conserved master enzyme initiating sulfur transfer via persulfide to a range of acceptor proteins involved in Fe-S cluster assembly, tRNA modifications, and sulfur-containing cofactor biosynthesis. Several IscS-interacting partners including IscU, a scaffold for Fe-S cluster assembly; TusA, the first member of a sulfur relay leading to sulfur incorporation into the wobble uridine of several tRNAs; ThiI, involved in tRNA modification and thiamine biosynthesis; and rhodanese RhdA are sulfur acceptors. Other proteins, such as CyaY/frataxin and IscX, also bind to IscS, but their functional roles are not directly related to sulfur transfer. We have determined the crystal structures of IscS-IscU and IscS-TusA complexes providing the first insight into their different modes of binding and the mechanism of sulfur transfer. Exhaustive mutational analysis of the IscS surface allowed us to map the binding sites of various partner proteins and to determine the functional and biochemical role of selected IscS and TusA residues. IscS interacts with its partners through an extensive surface area centered on the active site Cys328. The structures indicate that the acceptor proteins approach Cys328 from different directions and suggest that the conformational plasticity of a long loop containing this cysteine is essential for the ability of IscS to transfer sulfur to multiple acceptor proteins. The sulfur acceptors can only bind to IscS one at a time, while frataxin and IscX can form a ternary complex with IscU and IscS. Our data support the role of frataxin as an iron donor for IscU to form the Fe-S clusters. [ABSTRACT FROM AUTHOR]

Published
2010
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38. The structure of the TrmE GTP-binding protein and its implications for tRNA modification.

Author

Scrima, Andrea, Vetter, Ingrid R., Armengod, M. Eugenia, and Wittinghofer, Alfred

Subjects
G proteins, TRANSFER RNA, URIDINE, MOLECULAR biology
Abstract

TrmE is a 50 kDa guanine nucleotide-binding protein conserved between bacteria and man. It is involved in the modification of uridine bases (U34) at the first anticodon (wobble) position of tRNAs decoding two-family box triplets. The precise role of TrmE in the modification reaction is hitherto unknown. Here, we report the X-ray structure of TrmE from Thermotoga maritima. The structure reveals a three-domain protein comprising the N-terminala/ßdomain, the central helical domain and the G domain, responsible for GTP binding and hydrolysis. The N-terminal domain induces dimerization and is homologous to the tetrahydrofolate-binding domain of N,N-dimethylglycine oxidase. Biochemical and structural studies show that TrmE indeed binds formyl-tetrahydrofolate. A cysteine residue, necessary for modification of U34, is located close to the C1-group donor 5-formyl-tetrahydrofolate, suggesting a direct role of TrmE in the modification analogous to DNA modification enzymes. We propose a reaction mechanism whereby TrmE actively participates in the formylation reaction of uridine and regulates the ensuing hydrogenation reaction of a Schiff's base intermediate. [ABSTRACT FROM AUTHOR]

Published
2005
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39. The variant E233G of the RAD51D gene could be a low-penetrance allele in high-risk breast cancer families without BRCA1/2 mutations.

Author

Rodríguez-López, Raquel, Osorio, Ana, Ribas, Gloria, Pollán, Marina, Sánchez-Pulido, Luis, de la Hoya, Miguel, Ruibal, Álvaro, Zamora, Pilar, Arias, Jose Ignacio, Salazar, Raquel, Vega, Ana, Martínez, Jose Ignacio, Esteban-Cardeñosa, Eva, Alonso, Carmen, Letón, Rocío, Urioste Azcorra, Miguel, Miner, Cristina, Armengod, M. Eugenia, Carracedo, Angel, and González-Sarmiento, Rogelio

Abstract

Six SNPs have been detected in the DNA repair genes RAD51C and RAD51D, not previously characterized. The novel variant E233G in RAD51D is more highly represented in high-risk, site-specific, familial breast cancer cases that are not associated with the BRCA1/2 genes, with a frequency of 5.74% ( n = 174) compared to a control population ( n = 567) and another subset of breast cancer patients ( n = 765) with a prevalence of around 2% only (comparison to controls, OR = 2.6, 95% CI 1.12-6.03; p < 0.021). We found that the immunohistochemical profile detected in available tumors from these patients differs slightly from those described in non- BRCA1/2 tumors. Finally, the structural prediction of the putative functional consequence of this change indicates that it can diminish protein stability and structure. This suggests a role for E233G as a low-penetrance susceptibility gene in the specific subgroup of high-risk familial breast cancer cases that are not related to BRCA1/2. © 2004 Wiley-Liss, Inc. [ABSTRACT FROM AUTHOR]

Published
2004
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40. The Escherichia coliRlmN methyltransferase is a dual-specificity enzyme that modifies both rRNA and tRNA and controls translational accuracy

Author

Benítez-Páez, Alfonso, Villarroya, Magda, and Armengod, M.-Eugenia

Abstract

While most of the enzymes responsible for tRNA modifications in Escherichia coliwere known, the enzyme that introduces the m2A modification at purine 37 of some tRNAs was not. The authors of this study show that the missing enzyme is the methyltransferase RlmN responsible for introducing the m2A modification at position 2503 of the 23S rRNA, thus demonstrating that RlmN is a dual-specificity enzyme. The authors go on to use a tRNA chimera that should also be useful for the study of other tRNA modifications, to identify the specificity determinants. They also report that strains lacking rlmNhave an error-prone phenotype (expected from loss of m2A2503 modification of rRNA) rather than a hyperaccurate phenotype (expected from loss of m2A37modification of tRNA).

Published
2012
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41. The Escherichia coli trmE (mnmE) gene, involved in tRNA modification, codes for an evolutionarily conserved GTPase with unusual biochemical properties.

Author

Cabedo, Hugo, Macián, Fernando, Villarroya, Magda, Escudero, Juan C., Martínez-Vicente, Marta, Knecht, Erwin, and Armengod, M. Eugenia

Subjects
BACTERIAL genetics, ESCHERICHIA coli, GUANOSINE triphosphatase, TRANSFER RNA, RNA-protein interactions, BIOCHEMICAL genetics, PROTEIN binding
Abstract

The evolutionarily conserved 50K protein of Escherichia coli, encoded by o454, contains a consensus GTP-binding motif. Here we show that 50K is a GTPase that differs extensively from regulatory GTPase such as p21. Thus, 50K exhibits a very high intrinsic GTPase hydrolysis rate, rather low affinity for GTP, and extremely low affinity for GDP. Moreover, it can form self-assemblies. Strikingly, the 17 kDa GTPase domain of 50K conserves the guanine nucleotide-binding and GTPase activities of the intact 50K molecule. Therefore, the structural requirements for GTP binding and GTP hydrolysis by 50K are without precedent and justify a separate classification in the GTPase superfamily. Immunoelectron microscopy reveals that 50K is a cytoplasmic protein partially associated with the inner membrane. We prove that o454 is allelic with trmE, a gene involved in the biosynthesis of the hypermodified nucleoside 5-methylaminomethyl-2-thiouridine, which is found in the wobble position of some tRNAs. Our results demonstrate that 50K is essential for variability depending on the genetic background. We propose that combination of mutations affecting the decoding process, which separately do not reveal an obvious defect in growth, can give rise to lethal phenotypes, most likely due to synergism. [ABSTRACT FROM AUTHOR]

Published
1999
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42. Stationary phase induction of dnaN and recF, two genes of Escherichia coli involved in DNA replication and repair.

Author

Villarroya, Magda, Pérez-Roger, Ignacio, Macián, Fernando, and Armengod, M. Eugenia

Subjects
DNA polymerases, ENZYMES, ESCHERICHIA coli, DNA replication, OPERONS, CELL metabolism
Abstract

The β subunit of DNA polymerase III holoenzyme, the Escherichia coli chromosomal replicase, is a sliding DNA clamp responsible for tethering the polymerase to DNA and endowing it with high processivity. The gene encoding , dnaN, maps between dnaA and recF, which are involved in initiation of DNA replication at oriC and resumption of DNA replication at disrupted replication forks, respectively. In exponentially growing cells, dnaN and recF are expressed predominantly from the dnaA promoters. However, we have found that stationary phase induction of the dnaN promoters drastically changes the expression pattern of the dnaA operon genes. As a striking consequence, synthesis of the β subunit and RecF protein increases when cell metabolism is slowing down. Such an induction is dependent on the stationary phase · factor, RpoS, although the accumulation of this factor alone is not sufficient to activate the dnaN promoters. These promoters are located in DNA regions without static bending, and the ­35 hexamer element is essential for their RpoS-dependent induction. Our results suggest that stationary phase-dependent mechanisms have evolved in order to coordinate expression of dnaN and recF independently of the dnaA regulatory region. These mechanisms might be part of a developmental programme aimed at maintaining DNA integrity under stress conditions. [ABSTRACT FROM AUTHOR]

Published
1998
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44. Structure-Function Analysis of Escherichia coli MnmG (GidA), a Highly Conserved tRNA-Modifying Enzyme.

Author

Rong Shi, Villarroya, Magda, Ruiz-Partida, Rafael, Yunge Li, Proteau, Ariane, Prado, Silvia, Moukadiri, Ismaïl, Benítez-Páez, Alfonso, Lomas, Rodrigo, Wagner, John, Matte, Allan, Velázquez-Campoy, Adrián, Armengod, M.-Eugenia, and Cygler, Miroslaw

Subjects
*ESCHERICHIA coli, *TRANSFER RNA, *ESCHERICHIA, *ENZYMES, *ENTEROBACTERIACEAE, *FLAVINS, *ADENINE nucleotides, *GENETIC mutation, *GENETICS
Abstract

The MnmE-MnmG complex is involved in tRNA modification. We have determined the crystal structure of Escherichia coli MnmG at 2.4-Å resolution, mutated highly conserved residues with putative roles in flavin adenine dinucleotide (FAD) or tRNA binding and MnmE interaction, and analyzed the effects of these mutations in vivo and in vitro. Limited trypsinolysis of MnmG suggests significant conformational changes upon FAD binding. [ABSTRACT FROM AUTHOR]

Published
2009
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45. Backbone 1H, 13C and 15N resonance assignments for the 18.7 kDa GTPase domain of Escherichia coli MnmE protein.

Author

Monleón D, Yim L, Martínez-Vicente M, Armengod ME, and Celda B

Subjects
Animals, Carbon Isotopes, Escherichia coli chemistry, Escherichia coli Proteins genetics, GTP Phosphohydrolases genetics, Guanosine Triphosphate chemistry, Hydrogen chemistry, Nitrogen Isotopes, Protein Structure, Tertiary, Escherichia coli enzymology, Escherichia coli Proteins chemistry, GTP Phosphohydrolases chemistry, Nuclear Magnetic Resonance, Biomolecular
Published
2004
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