Your search keyword '"Henri Grosjean"' showing total 78 results

1. Post-Transcriptional Modifications of Conserved Nucleotides in the T-Loop of tRNA: A Tale of Functional Convergent Evolution

Author

Louis Droogmans, Martine Roovers, and Henri Grosjean

Subjects

0301 basic medicine, Génétique clinique, TRNA, lcsh:QH426-470, Evolution, Nucleotide modifications, Review, Microbiology, Gene Expression Regulation, Enzymologic, Environnement et pollution, Evolution, Molecular, 03 medical and health sciences, Structure-Activity Relationship, 0302 clinical medicine, RNA, Transfer, Convergent evolution, Three-domain system, evolution, Genetics, Native state, Humans, Nucleotide, RNA Processing, Post-Transcriptional, tRNA, T-loop, Genetics (clinical), Organism, Conserved Sequence, chemistry.chemical_classification, Base Sequence, Chemistry, lcsh:Genetics, 030104 developmental biology, Enzyme, Gene Expression Regulation, Evolutionary biology, Transfer RNA, nucleotide modifications, Nucleic Acid Conformation, 030217 neurology & neurosurgery

Abstract

The high conservation of nucleotides of the T-loop, including their chemical identity, are hallmarks of tRNAs from organisms belonging to the three Domains of Life. These structural characteristics allow the T-loop to adopt a peculiar intraloop conformation able to interact specifically with other conserved residues of the D-loop, which ultimately folds the mature tRNA in a unique functional canonical L-shaped architecture. Paradoxically, despite the high conservation of modified nucleotides in the T-loop, enzymes catalyzing their formation depend mostly on the considered organism, attesting for an independent but convergent evolution of the post-transcriptional modification processes. The driving force behind this is the preservation of a native conformation of the tRNA elbow that underlies the various interactions of tRNA molecules with different cellular components., SCOPUS: re.j, info:eu-repo/semantics/published

Published

2020

2. Comparative patterns of modified nucleotides in individual tRNA species from a mesophilic and two thermophilic archaea

Author

Henri Grosjean, Laura Antoine, Claire Villette, Julie Zumsteg, Béatrice Chane-Woon-Ming, Dimitri Heintz, Philippe Wolff, Eric Westhof, Louis Droogmans, Architecture et Réactivité de l'ARN (ARN), Institut de biologie moléculaire et cellulaire (IBMC), Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Architecture et réactivité de l'ARN (ARN), Université Louis Pasteur - Strasbourg I-Centre National de la Recherche Scientifique (CNRS), Institut de biologie moléculaire des plantes (IBMP), Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA), and Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Sulfolobus acidocaldarius, TRNA modification, [SDV]Life Sciences [q-bio], Methanococcus, RNA, Archaeal, Article, 03 medical and health sciences, RNA, Transfer, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, hyperthermophiles, Molecular Biology, tRNA, ComputingMilieux_MISCELLANEOUS, 030304 developmental biology, mass spectrometry, 0303 health sciences, biology, Base Sequence, Nucleotides, 030302 biochemistry & molecular biology, Haloferax volcanii, Methanocaldococcus jannaschii, Biologie moléculaire, modifications, Methanococcus maripaludis, [SDV.BBM.BM]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Molecular biology, biology.organism_classification, Archaea, Hyperthermophile, Pyrococcus furiosus, Biochemistry, Transfer RNA, Nucleic Acid Conformation

Abstract

To improve and complete our knowledge of archaeal tRNA modification patterns, we have identified and compared the modification pattern (type and location) in tRNAs of three very different archaeal species, Methanococcus maripaludis (a mesophilic methanogen), Pyrococcus furiosus (a hyperthermophile thermococcale), and Sulfolobus acidocaldarius (an acidophilic thermophilic sulfolobale). Most abundant isoacceptor tRNAs (79 in total) for each of the 20 amino acids were isolated by two-dimensional gel electrophoresis followed by in-gel RNase digestions. The resulting oligonucleotide fragments were separated by nanoLC and their nucleotide content analyzed by mass spectrometry (MS/MS). Analysis of total modified nucleosides obtained from complete digestion of bulk tRNAs was also performed. Distinct base- and/or ribose-methylations, cytidine acetylations, and thiolated pyrimidines were identified, some at new positions in tRNAs. Novel, some tentatively identified, modifications were also found. The least diversified modification landscape is observed in the mesophilic Methanococcus maripaludis and the most complex one in Sulfolobus acidocaldarius Notable observations are the frequent occurrence of ac4C nucleotides in thermophilic archaeal tRNAs, the presence of m7G at positions 1 and 10 in Pyrococcus furiosus tRNAs, and the use of wyosine derivatives at position 37 of tRNAs, especially those decoding U1- and C1-starting codons. These results complete those already obtained by others with sets of archaeal tRNAs from Methanocaldococcus jannaschii and Haloferax volcanii., SCOPUS: ar.j, info:eu-repo/semantics/published

Published

2020

3. The hyperthermophilic partners Nanoarchaeum and Ignicoccus stabilize their tRNA T-loops via different but structurally equivalent modifications

Author

Stephen Douthwaite, Finn Kirpekar, Jesper F. Havelund, Simon Rose, Harald Huber, Sylvie Auxilien, Henri Grosjean, Institut de Biologie Intégrative de la Cellule (I2BC), and Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS)

Subjects

Ignicoccus, AcademicSubjects/SCI00010, Stereochemistry, transfer-ribonucleic-acid, [SDV]Life Sciences [q-bio], insights, Methylation, Pseudouridine, Nucleobase, 03 medical and health sciences, chemistry.chemical_compound, RNA, Transfer, RNA and RNA-protein complexes, Escherichia coli, Genetics, Nanoarchaeum equitans, Nucleotide, posttranscriptional modification, Phylogeny, 030304 developmental biology, chemistry.chemical_classification, tRNA Methyltransferases, 0303 health sciences, biology, Desulfurococcaceae, psi-c loop, 030302 biochemistry & molecular biology, RNA, crystal-structure, enzymatic-activity, ribosomal-rna, biology.organism_classification, Archaea, Protein tertiary structure, ribothymidine, chemistry, Transfer RNA, Nanoarchaeota, Nucleic Acid Conformation, identification, methyltransferase

Abstract

Place: Oxford Publisher: Oxford Univ Press WOS:000574288800042; The universal L-shaped tertiary structure of tRNAs is maintained with the help of nucleotide modifications within the D- and T-loops, and these modifications are most extensive within hyperthermophilic species. The obligate-commensal Nanoarchaeum equitans and its phylogenetically-distinct host Ignicoccus hospitalis grow physically coupled under identical hyperthermic conditions. We report here two fundamentally different routes by which these archaea modify the key conserved nucleotide U54 within their tRNA T-loops. In N. equitans, this nucleotide is methylated by the S-adenosylmethionine-dependent enzyme NEQ053 to form m(5)U54, and a recombinant version of this enzyme maintains specificity for U54 in Escherichia coli. In N. equitans, m(5)U54 is subsequently thiolated to form m(5)s(2)U54. In contrast, I. hospitalis isomerizes U54 to pseudouridine prior to methylating its N1-position and thiolating the O4-position of the nucleobase to form the previously uncharacterized nucleotide m(1)s(4)Psi. The methyl and thiol groups in m(1)s(4)Psi and m(5)s(2)U are presented within the T-loop in a spatially identical manner that stabilizes the 3'-endo-anti conformation of nucleotide-54, facilitating stacking onto adjacent nucleotides and reverse-Hoogsteen pairing with nucleotide m(1)A58. Thus, two distinct structurally-equivalent solutions have evolved independently and convergently to maintain the tertiary fold of tRNAs under extreme hyperthermic conditions.

Published

2020

4. Reductive Evolution and Diversification of C5-Uracil Methylation in the Nucleic Acids of Mollicutes

Author

Laure Béven, Djemel Hamdane, Catherine Goyenvalle, Simon Rose, Henri Grosjean, Damien Brégeon, Alain Blanchard, Stephen Douthwaite, Pascal Sirand-Pugnet, Valérie de Crécy-Lagard, Biologie du fruit et pathologie (BFP), Université de Bordeaux (UB)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Institut de Biologie Paris Seine (IBPS), Institut National de la Santé et de la Recherche Médicale (INSERM)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), University of Southern Denmark (SDU), Institut de Biologie Intégrative de la Cellule (I2BC), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Laboratoire de Chimie des Processus Biologiques (LCPB), Collège de France (CdF (institution))-Institut de Chimie du CNRS (INC)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), University of Florida [Gainesville] (UF), and SERRE, Marie-Claude

Subjects

Models, Molecular, methyltransferases, lcsh:QR1-502, 01 natural sciences, Biochemistry, Genome, lcsh:Microbiology, RNA, Transfer, Nucleic Acids, rRNA, [SDV.BBM.BC] Life Sciences [q-bio]/Biochemistry, Molecular Biology/Biochemistry [q-bio.BM], Conserved Sequence, Genetics, 0303 health sciences, biology, Methylation, RNA, Ribosomal, 23S, Transfer RNA, Horizontal gene transfer, minimal cell, acholeplasmas, base modification, Dinitrocresols, Mollicutes, Spiroplasma, mycoplasmas, spiroplasmas, 010402 general chemistry, Article, Evolution, Molecular, 03 medical and health sciences, Folic Acid, Bacterial Proteins, 23S ribosomal RNA, evolution, Amino Acid Sequence, [SDV.BBM.BC]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Biochemistry [q-bio.BM], Uracil, Molecular Biology, tRNA, 030304 developmental biology, Binding Sites, Base Sequence, microbiology, moonlighting function, biology.organism_classification, 0104 chemical sciences, Nucleic acid, flavoenzymes, Tenericutes

Abstract

The C5-methylation of uracil to form 5-methyluracil (m5U) is a ubiquitous base modification of nucleic acids. Four enzyme families have converged to catalyze this methylation using different chemical solutions. Here, we investigate the evolution of 5-methyluracil synthase families in Mollicutes, a class of bacteria that has undergone extensive genome erosion. Many mollicutes have lost some of the m5U methyltransferases present in their common ancestor. Cases of duplication and subsequent shift of function are also described. For example, most members of the Spiroplasma subgroup, use the ancestral tetrahydrofolate-dependent TrmFO enzyme, to catalyze the formation of m5U54 in tRNA, while a TrmFO paralog (termed RlmFO) is responsible for m5U1939 formation in 23S RNA. RlmFO has replaced the S-adenosyl-l-methionine (SAM)-enzyme RlmD that adds the same modification in the ancestor and which is still present in mollicutes from the Hominis subgroup. Another paralog of this family, the TrmFO-like protein, has a yet unidentified function that differs from the TrmFO and RlmFO homologs. Despite having evolved towards minimal genomes, the mollicutes possess a repertoire of m5U modifying enzymes that is highly dynamic and has undergone horizontal transfer. This emphasizes the necessity for combining bioinformatics predictions with empirical testing and structural information to get a reliable functional annotation of these enzymes.

Published

2020

5. Tautomeric G•U pairs within the molecular ribosomal grip and fidelity of decoding in bacteria

Author

A. Rozov, Eric Westhof, Gulnara Yusupova, Marat Yusupov, Philippe Wolff, Henri Grosjean, Yusupova, Gulnara, Institut de Génétique et de Biologie Moléculaire et Cellulaire (IGBMC), Université de Strasbourg (UNISTRA)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Architecture et Réactivité de l'ARN (ARN), Institut de biologie moléculaire et cellulaire (IBMC), Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Institut de Biologie Intégrative de la Cellule (I2BC), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Institut de génétique et biologie moléculaire et cellulaire (IGBMC), and Université Louis Pasteur - Strasbourg I-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Models, Molecular, 0301 basic medicine, Base pair, Stereochemistry, [SDV.BBM.BS] Life Sciences [q-bio]/Biochemistry, Molecular Biology/Structural Biology [q-bio.BM], [SDV]Life Sciences [q-bio], Guanosine, Biology, Crystallography, X-Ray, Ribosome, 03 medical and health sciences, chemistry.chemical_compound, RNA, Transfer, Structural Biology, Anticodon, Escherichia coli, Genetics, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, RNA, Messenger, Codon, Base Pairing, ComputingMilieux_MISCELLANEOUS, 030102 biochemistry & molecular biology, [SDV.BBM.BS]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Structural Biology [q-bio.BM], Thermus thermophilus, RNA, Ribosomal RNA, biology.organism_classification, [SDV.MP.BAC]Life Sciences [q-bio]/Microbiology and Parasitology/Bacteriology, 3. Good health, 030104 developmental biology, chemistry, Duplex (building), Protein Biosynthesis, Transfer RNA, Nucleic Acid Conformation, [SDV.MP.BAC] Life Sciences [q-bio]/Microbiology and Parasitology/Bacteriology, Ribosomes

Abstract

International audience; We report new crystallographic structures of Thermus thermophilus ribosomes complexed with long mRNAs and native Escherichia coli tRNAs. They complete the full set of combinations of Watson-Crick G•C and miscoding G•U pairs at the first two positions of the codon-anticodon duplex in ribosome functional complexes. Within the tight decoding center, miscoding G•U pairs occur, in all combinations, with a non-wobble geometry structurally indistinguishable from classical coding Watson-Crick pairs at the same first two positions. The contacts with the ribosomal grip surrounding the decoding center are all quasi-identical, except in the crowded environment of the amino group of a guanosine at the second position; in which case a G in the codons may be preferred. In vivo experimental data show that the translational errors due to miscoding by G•U pairs at the first two positions are the most frequently encountered ones, especially at the second position and with a G on the codon. Such preferred miscodings involve a switch from an A-U to a G•U pair in the tRNA/mRNA complex and very rarely from a G = C to a G•U pair. It is concluded that the frequencies of such occurrences are only weakly affected by the codon/anticodon structures but depend mainly on the stability and lifetime of the complex, the modifications present in the anticodon loop, especially those at positions 34 and 37, in addition to the relative concentration of cognate/near-cognate tRNA species present in the cellular tRNA pool.

Published

2018

6. An integrated, structure- and energy-based view of the genetic code

Author

Henri Grosjean, Eric Westhof, Institut de Biologie Intégrative de la Cellule (I2BC), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Architecture et Réactivité de l'ARN (ARN), Institut de biologie moléculaire et cellulaire (IBMC), Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Institut de Biologie Intégrative de la Cellule ( I2BC ), Université Paris-Saclay-Centre National de la Recherche Scientifique ( CNRS ) -Commissariat à l'énergie atomique et aux énergies alternatives ( CEA ) -Université Paris-Sud - Paris 11 ( UP11 ), Architecture et Réactivité de l'ARN ( ARN ), Institut de biologie moléculaire et cellulaire ( IBMC ), and Université de Strasbourg ( UNISTRA ) -Centre National de la Recherche Scientifique ( CNRS ) -Université de Strasbourg ( UNISTRA ) -Centre National de la Recherche Scientifique ( CNRS ) -Centre National de la Recherche Scientifique ( CNRS )

Subjects

0301 basic medicine, [SDV]Life Sciences [q-bio], Computational biology, Biology, Ribosome, Sense Codon, 03 medical and health sciences, RNA, Transfer, Genetics, Survey and Summary, Codon, chemistry.chemical_classification, [ SDV ] Life Sciences [q-bio], RNA, Genetic code, Amino acid, 030104 developmental biology, chemistry, Genetic Code, Transfer RNA, Nucleic Acid Conformation, Thermodynamics, Ribosomes, GC-content, Decoding methods

Abstract

International audience; The principles of mRNA decoding are conserved among all extant life forms. We present an integrative view of all the interaction networks between mRNA, tRNA and rRNA: the intrinsic stability of codon-anticodon duplex, the conformation of the anticodon hairpin, the presence of modified nucleotides, the occurrence of non-Watson-Crick pairs in the codon-anticodon helix and the interactions with bases of rRNA at the A-site decoding site. We derive a more information-rich, alternative representation of the genetic code, that is circular with an unsymmetrical distribution of codons leading to a clear segregation between GC-rich 4-codon boxes and AU-rich 2:2-codon and 3:1-codon boxes. All tRNA sequence variations can be visualized, within an internal structural and energy framework, for each organism, and each anticodon of the sense codons. The multiplicity and complexity of nucleotide modifications at positions 34 and 37 of the anticodon loop segregate meaningfully, and correlate well with the necessity to stabilize AU-rich codon-anticodon pairs and to avoid miscoding in split codon boxes. The evolution and expansion of the genetic code is viewed as being originally based on GC content with progressive introduction of A/U together with tRNA modifications. The representation we present should help the engineering of the genetic code to include non-natural amino acids.

Published

2016

7. Crystal Structure and Mutational Study of a Unique SpoU Family Archaeal Methylase that Forms 2′-O-Methylcytidine at Position 56 of tRNA

Author

Mitsuo Kuratani, Henri Grosjean, Yoshitaka Bessho, Madoka Nishimoto, Shigeyuki Yokoyama, Institut de génétique et microbiologie [Orsay] (IGM), and Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Models, Molecular, S-Adenosylmethionine, MESH: Sequence Homology, Amino Acid, Protein Conformation, Amino Acid Motifs, MESH: tRNA Methyltransferases, MESH: Protein Structure, Secondary, MESH: Amino Acid Sequence, Cytidine, RNA, Archaeal, Crystallography, X-Ray, Protein Structure, Secondary, MESH: Recombinant Proteins, MESH: Amino Acid Motifs, MESH: Protein Structure, Tertiary, chemistry.chemical_compound, MESH: Protein Conformation, RNA, Transfer, Structural Biology, Transferase, Peptide sequence, tRNA Methyltransferases, 0303 health sciences, MESH: Models, Chemical, 030302 biochemistry & molecular biology, Recombinant Proteins, [SDV.MP]Life Sciences [q-bio]/Microbiology and Parasitology, Transfer RNA, Pyrococcus horikoshii, MESH: Cytidine, Dimerization, Hydrophobic and Hydrophilic Interactions, MESH: Models, Molecular, Protein Binding, MESH: Mutation, Molecular Sequence Data, MESH: Pyrococcus horikoshii, Sequence alignment, Biology, Methylation, MESH: Methylation, 03 medical and health sciences, MESH: Protein Binding, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, MESH: Hydrogen Bonding, Amino Acid Sequence, Molecular Biology, 030304 developmental biology, MESH: Hydrophobicity, MESH: Molecular Sequence Data, Binding Sites, TRNA methylation, Sequence Homology, Amino Acid, MESH: S-Adenosylmethionine, Hydrogen Bonding, MESH: RNA, Transfer, MESH: Crystallography, X-Ray, biology.organism_classification, Protein tertiary structure, Protein Structure, Tertiary, Crystallography, MESH: Binding Sites, MESH: Dimerization, Models, Chemical, chemistry, Mutation, MESH: RNA, Archaeal

Abstract

The conserved cytidine residue at position 56 of tRNA contributes to the maintenance of the L-shaped tertiary structure. aTrm56 catalyzes the 2′- O -methylation of the cytidine residue in archaeal tRNA, using S -adenosyl- L -methionine. Based on the amino acid sequence, aTrm56 is the most distant member of the SpoU family. Here, we determined the crystal structure of Pyrococcus horikoshii aTrm56 complexed with S -adenosyl- L -methionine at 2.48 A resolution. aTrm56 consists of the SPOUT domain, which contains the characteristic deep trefoil knot, and a unique C-terminal β-hairpin. aTrm56 forms a dimer. The S -adenosyl- L -methionine binding and dimerization of aTrm56 were similar to those of the other SpoU members. A structure-based sequence alignment revealed that aTrm56 conserves only motif II, among the four signature motifs. However, an essential Arg16 residue is located at a novel position within motif I. Biochemical assays showed that aTrm56 prefers the L-shaped tRNA to the λ form as its substrate.

Published

2008

8. Distribution and frequencies of post-transcriptional modifications in tRNAs

Author

Henri Grosjean, Janusz M. Bujnicki, Anna Olchowik, and Magdalena A. Machnicka

Subjects

Models, Molecular, Viridiplantae, Biology, Euryarchaeota, RNA, Transfer, Phylogenetics, Protein biosynthesis, Animals, Plastids, RNA, Messenger, Plastid, RNA Processing, Post-Transcriptional, Molecular Biology, Phylogeny, Genetics, Bacteria, Fungi, Translation (biology), Cell Biology, biology.organism_classification, Post-transcriptional modification, Mitochondria, Protein Biosynthesis, Transfer RNA, Nucleic Acid Conformation, T arm, Software, Research Paper

Abstract

Functional tRNA molecules always contain a wide variety of post-transcriptionally modified nucleosides. These modifications stabilize tRNA structure, allow for proper interaction with other macromolecules and fine-tune the decoding of mRNAs during translation. Their presence in functionally important regions of tRNA is conserved in all domains of life. However, the identities of many of these modified residues depend much on the phylogeny of organisms the tRNAs are found in, attesting for domain-specific strategies of tRNA maturation. In this work we present a new tool, tRNAmodviz web server (http://genesilico.pl/trnamodviz) for easy comparative analysis and visualization of modification patterns in individual tRNAs, as well as in groups of selected tRNA sequences. We also present results of comparative analysis of tRNA sequences derived from 7 phylogenetically distinct groups of organisms: Gram-negative bacteria, Gram-positive bacteria, cytosol of eukaryotic single cell organisms, Fungi and Metazoa, cytosol of Viridiplantae, mitochondria, plastids and Euryarchaeota. These data update the study conducted 20 y ago with the tRNA sequences available at that time.

Published

2015

9. Formation of the conserved pseudouridine at position 55 in archaeal tRNA

Author

Michael P. Terns, Louis Droogmans, Rebecca M. Terns, Martine Roovers, Henri Grosjean, Caryn Hale, and Catherine Tricot

Subjects

Molecular Sequence Data, RNA, Transfer -- genetics, medicine.disease_cause, Pseudouridine, RNA, Transfer, Phe, chemistry.chemical_compound, Pseudouridine -- genetics, RNA, Transfer, Phe -- chemistry, RNA, Transfer, Genetics, medicine, Escherichia coli, chemistry.chemical_classification, Base Sequence, biology, Archaea -- genetics, RNA, Sciences bio-médicales et agricoles, Ribosomal RNA, biology.organism_classification, Archaea, Enzyme, chemistry, Biochemistry, Transfer RNA, Pyrococcus furiosus, Nucleic Acid Conformation

Abstract

Pseudouridine (Psi) located at position 55 in tRNA is a nearly universally conserved RNA modification found in all three domains of life. This modification is catalyzed by TruB in bacteria and by Pus4 in eukaryotes, but so far the Psi55 synthase has not been identified in archaea. In this work, we report the ability of two distinct pseudouridine synthases from the hyperthermophilic archaeon Pyrococcus furiosus to specifically modify U55 in tRNA in vitro. These enzymes are (pfu)Cbf5, a protein known to play a role in RNA-guided modification of rRNA, and (pfu)PsuX, a previously uncharacterized enzyme that is not a member of the TruB/Pus4/Cbf5 family of pseudouridine synthases. (pfu)PsuX is hereafter renamed (pfu)Pus10. Both enzymes specifically modify tRNA U55 in vitro but exhibit differences in substrate recognition. In addition, we find that in a heterologous in vivo system, (pfu)Pus10 efficiently complements an Escherichia coli strain deficient in the bacterial Psi55 synthase TruB. These results indicate that it is probable that (pfu)Cbf5 or (pfu)Pus10 (or both) is responsible for the introduction of pseudouridine at U55 in tRNAs in archaea. While we cannot unequivocally assign the function from our results, both possibilities represent unexpected functions of these proteins as discussed herein., Journal Article, Research Support, N.I.H. Extramural, Research Support, Non-U.S. Gov't, SCOPUS: ar.j, info:eu-repo/semantics/published

Published

2006

10. MODOMICS: a database of RNA modification pathways

Author

Stanislaw Dunin-Horkawicz, Marcin Feder, Anna Czerwoniec, Michal J. Gajda, Henri Grosjean, and Janusz M. Bujnicki

Subjects

Sequence analysis, Sequence alignment, Saccharomyces cerevisiae, Biology, computer.software_genre, Article, User-Computer Interface, 03 medical and health sciences, Protein sequencing, RNA, Transfer, Escherichia coli, Genetics, Consensus sequence, RNA Processing, Post-Transcriptional, 030304 developmental biology, Internet, 0303 health sciences, Base Sequence, Database, 030302 biochemistry & molecular biology, RNA, Nucleosides, RNA, Fungal, RNA, Bacterial, Regulatory sequence, RNA editing, Nucleic acid, Databases, Nucleic Acid, Sequence Alignment, computer

Abstract

MODOMICS is the first comprehensive database resource for systems biology of RNA modification. It integrates information about the chemical structure of modified nucleosides, their localization in RNA sequences, pathways of their biosynthesis and enzymes that carry out the respective reactions. MODOMICS also provides literature information, and links to other databases, including the available protein sequence and structure data. The current list of modifications and pathways is comprehensive, while the dataset of enzymes is limited to Escherichia coli and Saccharomyces cerevisiae and sequence alignments are presented only for tRNAs from these organisms. RNAs and enzymes from other organisms will be included in the near future. MODOMICS can be queried by the type of nucleoside (e.g. A, G, C, U, I, m1A, nm5s2U, etc.), type of RNA, position of a particular nucleoside, type of reaction (e.g. methylation, thiolation, deamination, etc.) and name or sequence of an enzyme of interest. Options for data presentation include graphs of pathways involving the query nucleoside, multiple sequence alignments of RNA sequences and tabular forms with enzyme and literature data. The contents of MODOMICS can be accessed through the World Wide Web at http://genesilico.pl/modomics/.

Published

2006

11. Identification of a novel gene encoding a flavin-dependent tRNA:m5U methyltransferase in bacteria--evolutionary implications

Author

Hannu Myllykallio, Jaunius Urbonavičius, Henri Grosjean, and Stéphane Skouloubris

Subjects

Escherichia coli -- metabolism, Methyltransferase, Mutant, Flavin group, Bacterial genome size, RNA, Transfer -- metabolism, Biology, medicine.disease_cause, Article, Flavins -- metabolism, Evolution, Molecular, Bacterial Proteins, RNA, Transfer, Flavins, Escherichia coli, Genetics, medicine, Bacterial Proteins -- chemistry -- classification, Uridine, Gene, Bacillus subtilis -- enzymology, Phylogeny, Bacteria -- enzymology, tRNA Methyltransferases, Bacteria, tRNA Methyltransferases -- classification -- genetics -- metabolism, Genomics, Sciences bio-médicales et agricoles, TRNA Methyltransferases, Uridine -- analogs & derivatives -- metabolism, Biochemistry, Genes, Bacterial, Transfer RNA, Bacillus subtilis

Abstract

Formation of 5-methyluridine (ribothymidine) at position 54 of the T-psi loop of tRNA is catalyzed by site-specific tRNA methyltransferases (tRNA:m(5)U-54 MTase). In all Eukarya and many Gram-negative Bacteria, the methyl donor for this reaction is S-adenosyl-l-methionine (S-AdoMet), while in several Gram-positive Bacteria, the source of carbon is N(5), N(10)-methylenetetrahydrofolate (CH(2)H(4)folate). We have identified the gene for Bacillus subtilis tRNA:m(5)U-54 MTase. The encoded recombinant protein contains tightly bound flavin and is active in Escherichia coli mutant lacking m(5)U-54 in tRNAs and in vitro using T7 tRNA transcript as substrate. This gene is currently annotated gid in Genome Data Banks and it is here renamed trmFO. TrmFO (Gid) orthologs have also been identified in many other bacterial genomes and comparison of their amino acid sequences reveals that they are phylogenetically distinct from either ThyA or ThyX class of thymidylate synthases, which catalyze folate-dependent formation of deoxyribothymine monophosphate, the universal DNA precursor., info:eu-repo/semantics/published

Published

2005

12. Trm11p and Trm112p Are both Required for the Formation of 2-Methylguanosine at Position 10 in Yeast tRNA

Author

Bruno Lapeyre, Henri Grosjean, Suresh K. Purushothaman, and Janusz M. Bujnicki

Subjects

Rossmann fold, Saccharomyces cerevisiae Proteins, Methyltransferase, Protein subunit, Molecular Sequence Data, Saccharomyces cerevisiae, Gene Expression, Guanosine, Biology, Methylation, chemistry.chemical_compound, RNA, Transfer, Amino Acid Sequence, Molecular Biology, Sequence Deletion, tRNA Methyltransferases, Base Sequence, Sequence Homology, Amino Acid, Computational Biology, Methyltransferases, Cell Biology, biology.organism_classification, Molecular biology, TRNA Methyltransferases, chemistry, Biochemistry, Transfer RNA, Nucleic Acid Conformation

Abstract

N(2)-Monomethylguanosine-10 (m(2)G10) and N(2),N(2)-dimethylguanosine-26 (m(2)(2)G26) are the only two guanosine modifications that have been detected in tRNA from nearly all archaea and eukaryotes but not in bacteria. In Saccharomyces cerevisiae, formation of m(2)(2)G26 is catalyzed by Trm1p, and we report here the identification of the enzymatic activity that catalyzes the formation of m(2)G10 in yeast tRNA. It is composed of at least two subunits that are associated in vivo: Trm11p (Yol124c), which is the catalytic subunit, and Trm112p (Ynr046w), a putative zinc-binding protein. While deletion of TRM11 has no detectable phenotype under laboratory conditions, deletion of TRM112 leads to a severe growth defect, suggesting that it has additional functions in the cell. Indeed, Trm112p is associated with at least four proteins: two tRNA methyltransferases (Trm9p and Trm11p), one putative protein methyltransferase (Mtc6p/Ydr140w), and one protein with a Rossmann fold dehydrogenase domain (Lys9p/Ynr050c). In addition, TRM11 interacts genetically with TRM1, thus suggesting that the absence of m(2)G10 and m(2)(2)G26 affects tRNA metabolism or functioning.

Published

2005

13. Transfer RNA paralogs: evidence for genetic code-amino acid biosynthesis coevolution and an archaeal root of life

Author

Ka-Lok Tong, J. Tze-Fei Wong, Henri Grosjean, Christian Marck, and Hong Xue

Subjects

Molecular Sequence Data, Evolution, Molecular, RNA, Transfer, Sequence Homology, Nucleic Acid, Genetics, Animals, Humans, Amino Acids, Gene, Phylogeny, chemistry.chemical_classification, Genome, Bacteria, Base Sequence, Models, Genetic, biology, Phylogenetic tree, Last universal ancestor, General Medicine, biology.organism_classification, Genetic code, Archaea, Amino acid, chemistry, Genetic Code, Transfer RNA, Sequence space (evolution)

Abstract

A search has been performed on 2878 tRNA sequences from 60 different genomes in order to detect the existence of closely related 'alloacceptor' tRNAs accepting dissimilar amino acids that could be paralogs generated by gene duplications. This has led to the identification of extremely conserved tRNA(Phe)-tRNA(Tyr) pairs displaying as high as 94% identity between them, and also other potentially paralogous tRNA pairs in archaeal species. These paralogous pairs are enriched for amino acid pairs belonging to the same amino acid biosynthetic family, thus providing evidence for the coevolution of genetic code and amino acid biosynthesis. Overall, the genetic distances between alloacceptor tRNAs yield estimates of how closely clustered in sequence space are the tRNAs in a genome. Among 34 Bacteria, 18 Archaea and 8 Eukarya, Methanopyrus kandleri and Aeropyrum pernix have yielded the lowest alloacceptor distances and largest number of paralogous pairs. Based on a cluster-dispersion model of tRNA evolution, such tight alloacceptor clustering is a measure of primitiveness of tRNA genotypes, and places last universal common ancestor (LUCA) between the branches leading to these two archaea in the tRNA phylogenetic tree.

Published

2003

14. tRNomics: Analysis of tRNA genes from 50 genomes of Eukarya, Archaea, and Bacteria reveals anticodon-sparing strategies and domain-specific features

Author

Christian Marck and Henri Grosjean

Subjects

Transcription, Genetic, Molecular Sequence Data, Biology, Genome, Conserved sequence, Sense Codon, chemistry.chemical_compound, RNA, Transfer, Consensus sequence, Animals, Humans, Amino Acid Sequence, RNA Processing, Post-Transcriptional, Codon, RNA, Transfer, Ile, Base Pairing, Molecular Biology, Conserved Sequence, Phylogeny, Comparative genomics, Genetics, Base Composition, Bacteria, Base Sequence, biology.organism_classification, Archaea, Eukaryotic Cells, chemistry, Transfer RNA, Nucleic Acid Conformation, Lysidine, Research Article

Abstract

From 50 genomes of the three domains of life (7 eukarya, 13 archaea, and 30 bacteria), we extracted, analyzed, and compared over 4,000 sequences corresponding to cytoplasmic, nonorganellar tRNAs. For each genome, the complete set of tRNAs required to read the 61 sense codons was identified, which permitted revelation of three major anticodon-sparing strategies. Other features and sequence peculiarities analyzed are the following: (1) fit to the standard cloverleaf structure, (2) characteristic consensus sequences for elongator and initiator tDNAs, (3) frequencies of bases at each sequence position, (4) type and frequencies of conserved 2D and 3D base pairs, (5) anticodon/tDNA usages and anticodon-sparing strategies, (6) identification of the tRNA-Ile with anticodon CAU reading AUA, (7) size of variable arm, (8) occurrence and location of introns, (9) occurrence of 3'-CCA and 5'-extra G encoded at the tDNA level, and (10) distribution of the tRNA genes in genomes and their mode of transcription. Among all tRNA isoacceptors, we found that initiator tDNA-iMet is the most conserved across the three domains, yet domain-specific signatures exist. Also, according to which tRNA feature is considered (5'-extra G encoded in tDNAs-His, AUA codon read by tRNA-Ile with anticodon CAU, presence of intron, absence of "two-out-of-three" reading mode and short V-arm in tDNA-Tyr) Archaea sequester either with Bacteria or Eukarya. No common features between Eukarya and Bacteria not shared with Archaea could be unveiled. Thus, from the tRNomic point of view, Archaea appears as an "intermediate domain" between Eukarya and Bacteria.

Published

2002

15. The flavoprotein Mcap0476 (RlmFO) catalyzes m5U1939 modification in Mycoplasma capricolum 23S rRNA

Author

Simon Rose, Alain Blanchard, Stephen Douthwaite, Henri Grosjean, Anne Lebaudy, Basma El Yacoubi, Carole Lartigue, Biologie du fruit et pathologie (BFP), Université Bordeaux Segalen - Bordeaux 2-Institut National de la Recherche Agronomique (INRA)-Université Sciences et Technologies - Bordeaux 1, Department of Microbiology and Cell Science, University of Florida [Gainesville] (UF), Department of Biochemistry and Molecular Biology, University of Southern Denmark (SDU), Centre de génétique moléculaire (CGM), and Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)

Subjects

TRNA modification, [SDV.OT]Life Sciences [q-bio]/Other [q-bio.OT], Biology, Methylation, Mycoplasma capricolum, petit ruminant, 03 medical and health sciences, Bacterial Proteins, RNA, Transfer, 23S ribosomal RNA, Genetics, mycoplasme, mollicute, pathologie animale, caprin, Uridine, 030304 developmental biology, modification post-transcriptionnelle, 0303 health sciences, TRNA methylation, Flavoproteins, 030302 biochemistry & molecular biology, RNA, Methyltransferases, Ribosomal RNA, biology.organism_classification, Molecular biology, RNA, Ribosomal, 23S, Biochemistry, méthyltransférase, Transfer RNA, Biocatalysis, arn ribosomique 23s, biologie synthétique, bactérie pathogène, Autre (Sciences du Vivant)

Abstract

International audience; Efficient protein synthesis in all organisms requires the post-transcriptional methylation of specific ribosomal ribonucleic acid (rRNA) and transfer RNA (tRNA) nucleotides. The methylation reactions are almost invariably catalyzed by enzymes that use S-adenosylmethionine (AdoMet) as the methyl group donor. One noteworthy exception is seen in some bacteria, where the conserved tRNA methylation at m(5)U54 is added by the enzyme TrmFO using flavin adenine dinucleotide together with N(5),N(10)-methylenetetrahydrofolate as the one-carbon donor. The minimalist bacterium Mycoplasma capricolum possesses two homologs of trmFO, but surprisingly lacks the m(5)U54 tRNA modification. We created single and dual deletions of the trmFO homologs using a novel synthetic biology approach. Subsequent analysis of the M. capricolum RNAs by mass spectrometry shows that the TrmFO homolog encoded by Mcap0476 specifically modifies m(5)U1939 in 23S rRNA, a conserved methylation catalyzed by AdoMet-dependent enzymes in all other characterized bacteria. The Mcap0476 methyltransferase (renamed RlmFO) represents the first folate-dependent flavoprotein seen to modify ribosomal RNA.

Published

2014

16. Pus1p-dependent tRNA Pseudouridinylation Becomes Essential When tRNA Biogenesis Is Compromised in Yeast

Author

François Lecointe, George Simos, Ed Hurt, Henri Grosjean, Helge Großhans, Heidelberg University, Laboratoire d'Enzymologie et Biochimie Structurales (LEBS), Centre National de la Recherche Scientifique (CNRS), CNRS, Association pour la Recherche sur le Cancer, Deutsche Forschungsgemeinschaft [SFB352-B11], and Simos, George

Subjects

[SDV]Life Sciences [q-bio], Mutant, Saccharomyces cerevisiae, Biology, Biochemistry, Pseudouridine, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, RNA, Transfer, Nuclear export signal, Molecular Biology, Hydro-Lyases, DNA Primers, 030304 developmental biology, 0303 health sciences, Base Sequence, Genetic Complementation Test, Biological Transport, RNA, Fungal, Cell Biology, Yeast, chemistry, Mutation, Transfer RNA, T arm, 030217 neurology & neurosurgery, Biogenesis, Function (biology)

Abstract

International audience; Yeast Pus1p catalyzes the formation of pseudouridine (ψ) at specific sites of several tRNAs, but its function is not essential for cell viability. We show here that Pus1p becomes essential when another tRNA:pseudouridine synthase, Pus4p, or the essential minor tRNA for glutamine are mutated. Strikingly, this mutant tRNA, which carries a mismatch in the TψC arm, displays a nuclear export defect. Furthermore, nuclear export of at least one wild-type tRNA species becomes defective in the absence of Pus1p. Our data, thus, show that the modifications formed by Pus1p are essential when other aspects of tRNA biogenesis or function are compromised and suggest that impairment of nuclear tRNA export in the absence of Pus1p might contribute to this phenotype.

Published

2001

17. Pseudouridine Mapping in the Saccharomyces cerevisiae Spliceosomal U Small Nuclear RNAs (snRNAs) Reveals that Pseudouridine Synthase Pus1p Exhibits a Dual Substrate Specificity for U2 snRNA and tRNA

Author

Eduard C. Hurt, Yuri Motorin, Denis L. J. Lafontaine, Séverine Massenet, Henri Grosjean, Christiane Branlant, Maturation des ARN et enzymologie moléculaire (MAEM), Cancéropôle du Grand Est-Université Henri Poincaré - Nancy 1 (UHP)-IFR111-Centre National de la Recherche Scientifique (CNRS), Laboratoire d’Enzymologie et Biochimie Structurales, Centre de Recherche de Gif, Centre National de la Recherche Scientifique, 91198 Gif sur Yvette, France, Laboratoire d'Enzymologie et Biochimie Structurales, Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), University of Edinburgh, and Heidelberg University

Subjects

Spliceosome, Saccharomyces cerevisiae Proteins, RNA Splicing, [SDV]Life Sciences [q-bio], Molecular Sequence Data, Saccharomyces cerevisiae, Gene Expression, Catalysis, Pseudouridine, Substrate Specificity, Fungal Proteins, 03 medical and health sciences, chemistry.chemical_compound, RNA, Transfer, RNA, Small Nuclear, RNA Precursors, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Intramolecular Transferases, Molecular Biology, Hydro-Lyases, 030304 developmental biology, 0303 health sciences, Fungal protein, Base Sequence, biology, ATP synthase, 030302 biochemistry & molecular biology, Chromosome Mapping, RNA, Fungal, [SDV.BBM.BM]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Molecular biology, Cell Biology, Ribonucleoprotein, U2 Small Nuclear, biology.organism_classification, chemistry, Biochemistry, Transfer RNA, RNA splicing, Spliceosomes, biology.protein, Nucleic Acid Conformation, Small nuclear RNA

Abstract

International audience; Pseudouridine (Psi) residues were localized in the Saccharomyces cerevisiae spliceosomal U small nuclear RNAs (UsnRNAs) by using the chemical mapping method. In contrast to vertebrate UsnRNAs, S. cerevisiae UsnRNAs contain only a few Psi residues, which are located in segments involved in intermolecular RNA-RNA or RNA-protein interactions. At these positions, UsnRNAs are universally modified. When yeast mutants disrupted for one of the several pseudouridine synthase genes (PUS1, PUS2, PUS3, and PUS4) or depleted in rRNA-pseudouridine synthase Cbf5p were tested for UsnRNA Psi content, only the loss of the Pus1p activity was found to affect Psi formation in spliceosomal UsnRNAs. Indeed, Psi44 formation in U2 snRNA was abolished. By using purified Pus1p enzyme and in vitro-produced U2 snRNA, Pus1p is shown here to catalyze Psi44 formation in the S. cerevisiae U2 snRNA. Thus, Pus1p is the first UsnRNA pseudouridine synthase characterized so far which exhibits a dual substrate specificity, acting on both tRNAs and U2 snRNA. As depletion of rRNA-pseudouridine synthase Cbf5p had no effect on UsnRNA Psi content, formation of Psi residues in S. cerevisiae UsnRNAs is not dependent on the Cbf5p-snoRNA guided mechanism.

Published

1999

18. A pseudoknotted tRNA variant is a substrate for tRNA (cytosine-5)-methyltransferase from Xenopus laevis

Author

Henri Grosjean, Catherine Florentz, Hervé Brulé, and Richard Giegé

Subjects

Saccharomyces cerevisiae Proteins, Xenopus, Xenopus Proteins, Biochemistry, Substrate Specificity, Xenopus laevis, RNA, Transfer, Mosaic Viruses, Animals, Nucleotide, chemistry.chemical_classification, tRNA Methyltransferases, Turnip yellow mosaic virus, Base Sequence, biology, RNA, General Medicine, biology.organism_classification, Protein tertiary structure, Post-transcriptional modification, Enzyme, chemistry, Transfer RNA, Nucleic Acid Conformation, RNA, Viral, Female

Abstract

tRNA post-transcriptional modification enzymes of Xenopus laevis were proposed previously to belong to two major groups according to their sensitivity to structural perturbations in their substrates. To further investigate the structural variations tolerated by these enzymes, the tRNA-like domain of turnip yellow mosaic virus RNA (88 nucleotides in length) has been microinjected into the oocytes of Xenopus laevis. This RNA possesses 12 potential target nucleotides for modification within a structure including a pseudoknotted folding, an extended anticodon stem, and unusual D-loop/T-loop interactions. Results indicate that only cytosine-42, a position equivalent to C-49 in canonical tRNAs, was quantitatively modified into m5C in the microinjected RNA. Modification was detected to high levels, indicating that at least one enzyme tolerates non-canonical structural features.

Published

1998

19. Pseudouridine and ribothymidine formation in the tRNA-like domain of turnip yellow mosaic virus RNA

Author

Richard Giegé, Yuri Motorin, Catherine Florentz, Hubert F. Becker, and Henri Grosjean

Subjects

TRNA modification, Molecular Sequence Data, Guanosine, Pseudouridine, chemistry.chemical_compound, RNA, Transfer, Genetics, Nucleotide, Tymovirus, RNA Processing, Post-Transcriptional, Intramolecular Transferases, Uridine, Hydro-Lyases, chemistry.chemical_classification, Turnip yellow mosaic virus, Base Sequence, biology, Nucleic acid sequence, RNA, biology.organism_classification, Biochemistry, chemistry, Transfer RNA, Nucleic Acid Conformation, RNA, Viral, Research Article

Abstract

The last 82 nucleotides of the 6.3 kb genomic RNA of plant turnip yellow mosaic virus (TYMV), the so-called 'tRNA-like' domain, presents functional, structural and primary sequence homologies with canonical tRNAs. In particular, one of the stem-loops resembles the TPsi(pseudouridine)-branch of tRNA, except for the presence of a guanosine at position 37 (numbering is from the 3'-end) instead of the classical uridine-55 in tRNA (numbering is from the 5'-end). Both the wild-type TYMV-RNA fragment and a variant, TYMV-mut G37U in which G-37 has been replaced by U-37, have been tested as potential substrates for the yeast tRNA modification enzymes. Results indicate that two modified nucleotides were formed upon incubation of the wild-type TYMV-fragment in a yeast extract: one Psi which formed quantitatively at position 65, and one ribothymidine (T) which formed at low level at position U-38. In the TYMV-mutant G37U, besides the quantitative formation of both Psi-65 and T-38, an additional Psi was detected at position 37. Modified nucleotides Psi-65, T-38 and Psi-37 in TYMV RNA are equivalent to Psi-27, T-54 and Psi-55 in tRNA, respectively. Purified yeast recombinant tRNA:Psisynthases (Pus1 and Pus4), which catalyze respectively the formation of Psi-27 and Psi-55 in yeast tRNAs, are shown to catalyze the quantitative formation of Psi-65 and Psi-37, respectively, in the tRNA-like 3'-domain of mutant TYMV RNA in vitro . These results are discussed in relation to structural elements that are needed by the corresponding enzymes in order to catalyze these post-transcriptional modification reactions.

Published

1998

20. RNA-methyltransferase TrmA is a dual-specific enzyme responsible for C ( 5) -methylation of uridine in both tmRNA and tRNA

Author

Céline Fabret, Frédéric Dardel, Henri Grosjean, Sylvie Nonin-Lecomte, Ehsan Ranaei-Siadat, Bili Seijo, Institut de génétique et microbiologie [Orsay] (IGM), Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS), Laboratoire de cristallographie et RMN biologiques (LCRB - UMR 8015), Centre National de la Recherche Scientifique (CNRS)-Université Paris Descartes - Paris 5 (UPD5), and Université Paris Descartes - Paris 5 (UPD5)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)

Subjects

tmRNA, Methyltransferase, Molecular Sequence Data, Biology, Ribosome, RNA, Transfer, Escherichia coli, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, RNA Processing, Post-Transcriptional, Uridine, Molecular Biology, Gene, post-transcriptional modification, ComputingMilieux_MISCELLANEOUS, Genetics, tRNA Methyltransferases, TrmA, Base Sequence, [SDV.BBM.BS]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Structural Biology [q-bio.BM], Escherichia coli Proteins, RNA, Methyltransferases, Cell Biology, Methylation, Ribosomal RNA, Multifunctional Enzymes, NMR, Post-transcriptional modification, RNA, Bacterial, RNA, Ribosomal, 23S, [SDV.BBM.BS]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Biomolecules [q-bio.BM], [SDV.MP]Life Sciences [q-bio]/Microbiology and Parasitology, Biochemistry, Transfer RNA, t-RNA like domain (TLD), Nucleic Acid Conformation, methyltransferase, methylation, Research Paper

Abstract

International audience; In bacteria, trans-translation rescues stalled ribosomes by the combined action of tmRNA (transfer-mRNA) and its associated protein SmpB. The tmRNA 5' and 3' ends fold into a tRNA-like domain (TLD), which shares structural and functional similarities with tRNAs. As in tRNAs, the UUC sequence of the T-arm of the TLD is post-transcriptionally modified to m ( 5) UψC. In tRNAs of gram-negative bacteria, formation of m ( 5) U is catalyzed by the SAM-dependent methyltransferase TrmA, while formation of m ( 5) U at two different positions in rRNA is catalyzed by distinct site-specific methyltransferases RlmC and RlmD. Here, we show that m ( 5) U formation in tmRNAs is exclusively due to TrmA and should be considered as a dual-specific enzyme. The evidence comes from the lack of m ( 5) U in purified tmRNA or TLD variants recovered from an Escherichia coli mutant strain deleted of the trmA gene. Detection of m ( 5) U in RNA was performed by NMR analysis.

Published

2013

21. Enzymatic conversion of adenosine to inosine and to N1-methylinosine in transfer RNAs: A review

Author

C. Simon, Henri Grosjean, D. Foiret, Y. Corda, Marjorie Fournier, Sylvie Auxilien, Hubert F. Becker, Annie Morin, Y.X. Jin, Jean-Louis Fourrey, and F. Constantinesco

Subjects

Adenosine, Transcription, Genetic, Adenosine Deaminase, Molecular Sequence Data, Biology, Biochemistry, RNA, Transfer, Transcription (biology), Anticodon, medicine, Nucleotide, Inosine, Gene, chemistry.chemical_classification, Messenger RNA, Base Sequence, Molecular Structure, RNA, General Medicine, Enzyme, chemistry, Transfer RNA, Nucleic Acid Conformation, medicine.drug

Abstract

Inosine (6-deaminated adenosine) is a characteristic modified nucleoside that is found at the first anticodon position (position 34) of several tRNAs of eukaryotic and eubacterial origins, while N1-methylinosine is found exclusively at position 37 (3' adjacent to the anticodon) of eukaryotic tRNA(Ala) and at position 57 (in the middle of the psi loop) of several tRNAs from halophilic and thermophilic archaebacteria. Inosine has also been recently found in double-stranded RNA, mRNA and viral RNAs. As for all other modified nucleosides in RNAs, formation of inosine and inosine derivative in these RNA is catalysed by specific enzymes acting after transcription of the RNA genes. Using recombinant tRNAs and T7-runoff transcripts of several tRNA genes as substrates, we have studied the mechanism and specificity of tRNA-inosine-forming enzymes. The results show that inosine-34 and inosine-37 in tRNAs are both synthesised by a hydrolytic deamination-type reaction, catalysed by distinct tRNA:adenosine deaminases. Recognition of tRNA substrates by the deaminases does not strictly depend on a particular "identity' nucleotide. However, the efficiency of adenosine to inosine conversion depends on the nucleotides composition of the anticodon loop and the proximal stem as well as on 3D-architecture of the tRNA. In eukaryotic tRNA(Ala), N1-methylinosine-37 is formed from inosine-37 by a specific SAM-dependent methylase, while in the case of N1-methylinosine-57 in archaeal tRNAs, methylation of adenosine-57 into N1-methyladenosine-57 occurs before the deamination process. The T psi-branch of fragmented tRNA is the minimalist substrate for the N1-methylinosine-57 forming enzymes. Inosine-34 and N1-methylinosine-37 in human tRNA(Ala) are targets for specific autoantibodies which are present in the serum of patients with inflammatory muscle disease of the PL-12 polymyositis type. Here we discuss the mechanism, specificity and general properties of the recently discovered RNA:adenosine deaminases/editases acting on double-stranded RNA, intron-containing mRNA and viral RNA in relation to those of the deaminases acting on tRNAs.

Published

1996

22. Characterization and structure of the Aquifex aeolicus protein DUF752: a bacterial tRNA-methyltransferase (MnmC2) functioning without the usually fused oxidase domain (MnmC1)

Author

Aya, Kitamura, Madoka, Nishimoto, Toru, Sengoku, Rie, Shibata, Gunilla, Jäger, Glenn R, Björk, Henri, Grosjean, Shigeyuki, Yokoyama, and Yoshitaka, Bessho

Subjects

S-Adenosylmethionine, tRNA Methyltransferases, Bacteria, Sequence Homology, Amino Acid, Wobble Uridine, RNA Methyltransferase, S-Adenosylmethionine (AdoMet), Crystallography, X-Ray, Methylation, Microbiology, Transfer RNA (tRNA), Protein Structure, Tertiary, RNA, Bacterial, Bacterial Proteins, RNA, Transfer, Genetic Code, Crystal Structure, RNA Modification, Oxidoreductases, tRNA Anticodon

Abstract

Background: Escherichia coli encodes a bifunctional oxidase/methyltransferase catalyzing the final steps of methylaminomethyluridine (mnm5U) formation in tRNA wobble positions. Results: Aquifex aeolicus encodes only a monofunctional aminomethyluridine-dependent methyltransferase, lacking the oxidase domain. Conclusion: An alternative pathway exists for mnm5U biogenesis. Significance: Information about how an organism modifies the wobble base of its tRNA is important for understanding the emergence of the genetic code., Post-transcriptional modifications of the wobble uridine (U34) of tRNAs play a critical role in reading NNA/G codons belonging to split codon boxes. In a subset of Escherichia coli tRNA, this wobble uridine is modified to 5-methylaminomethyluridine (mnm5U34) through sequential enzymatic reactions. Uridine 34 is first converted to 5-carboxymethylaminomethyluridine (cmnm5U34) by the MnmE-MnmG enzyme complex. The cmnm5U34 is further modified to mnm5U by the bifunctional MnmC protein. In the first reaction, the FAD-dependent oxidase domain (MnmC1) converts cmnm5U into 5-aminomethyluridine (nm5U34), and this reaction is immediately followed by the methylation of the free amino group into mnm5U34 by the S-adenosylmethionine-dependent domain (MnmC2). Aquifex aeolicus lacks a bifunctional MnmC protein fusion and instead encodes the Rossmann-fold protein DUF752, which is homologous to the methyltransferase MnmC2 domain of Escherichia coli MnmC (26% identity). Here, we determined the crystal structure of the A. aeolicus DUF752 protein at 2.5 Å resolution, which revealed that it catalyzes the S-adenosylmethionine-dependent methylation of nm5U in vitro, to form mnm5U34 in tRNA. We also showed that naturally occurring tRNA from A. aeolicus contains the 5-mnm group attached to the C5 atom of U34. Taken together, these results support the recent proposal of an alternative MnmC1-independent shortcut pathway for producing mnm5U34 in tRNAs.

Published

2012

23. The archaeal COG1901/DUF358 SPOUT-methyltransferase members, together with pseudouridine synthase Pus10, catalyze the formation of 1-methylpseudouridine at position 54 of tRNA

Author

Valérie de Crécy-Lagard, Ramesh Gupta, Y. Adam Yuan, Henri Grosjean, Mrinmoyee Majumder, Kunal Chatterjee, Patrick C. Thiaville, and Ian K. Blaby

Subjects

Methyltransferase, Protein Conformation, RNA, Archaeal, Methylation, Pseudouridine, Article, Genes, Archaeal, chemistry.chemical_compound, RNA, Transfer, RNA Processing, Post-Transcriptional, Molecular Biology, Gene, Base Pairing, Haloferax volcanii, Intramolecular Transferases, Phylogeny, chemistry.chemical_classification, tRNA Methyltransferases, biology, Base Sequence, Inverted Repeat Sequences, Methanococcales, Methanocaldococcus jannaschii, biology.organism_classification, Molecular biology, Archaea, Enzyme, chemistry, Biochemistry, Transfer RNA, Gene Deletion

Abstract

The methylation of pseudouridine (Ψ) at position 54 of tRNA, producing m1Ψ, is a hallmark of many archaeal species, but the specific methylase involved in the formation of this modification had yet to be characterized. A comparative genomics analysis had previously identified COG1901 (DUF358), part of the SPOUT superfamily, as a candidate for this missing methylase family. To test this prediction, the COG1901 encoding gene, HVO_1989, was deleted from the Haloferax volcanii genome. Analyses of modified base contents indicated that while m1Ψ was present in tRNA extracted from the wild-type strain, it was absent from tRNA extracted from the mutant strain. Expression of the gene encoding COG1901 from Halobacterium sp. NRC-1, VNG1980C, complemented the m1Ψ minus phenotype of the ΔHVO_1989 strain. This in vivo validation was extended with in vitro tests. Using the COG1901 recombinant enzyme from Methanocaldococcus jannaschii (Mj1640), purified enzyme Pus10 from M. jannaschii and full-size tRNA transcripts or TΨ-arm (17-mer) fragments as substrates, the sequential pathway of m1Ψ54 formation in Archaea was reconstituted. The methylation reaction is AdoMet dependent. The efficiency of the methylase reaction depended on the identity of the residue at position 55 of the TΨ-loop. The presence of Ψ55 allowed the efficient conversion of Ψ54 to m1Ψ54, whereas in the presence of C55, the reaction was rather inefficient and no methylation reaction occurred if a purine was present at this position. These results led to renaming the Archaeal COG1901 members as TrmY proteins.

Published

2012

24. Life without the essential bacterial tRNA Ile2-lysidine synthetase TilS: a case of tRNA gene recruitment in Bacillus subtilis

Author

Céline, Fabret, Etienne, Dervyn, Bérengère, Dalmais, Alain, Guillot, Christian, Marck, Henri, Grosjean, and Philippe, Noirot

Subjects

Amino Acyl-tRNA Synthetases, Hot Temperature, Suppression, Genetic, Amino Acid Substitution, RNA, Transfer, Lysine, Protein Biosynthesis, Anticodon, Pyrimidine Nucleosides, Bacillus subtilis

Abstract

In eubacteria, the post-transcriptional modification of the wobble cytidine of the CAU anticodon in a precursor tRNA(Ile2) to a lysidine residue (2-lysyl-cytidine, abbreviated as L) allows the amino acid specificity to change from methionine to isoleucine and the codon decoding specificity to shift from AUG to AUA. The tilS gene encoding the enzyme that catalyses this modification is widely distributed. However, some microbial species lack a tilS gene, indicating that an alternative strategy exists to accurately translate the AUA codon into Ile. To determine whether a TilS-dependent bacterium, such as Bacillus subtilis, can overcome the absence of lysidine in its tRNA(Ile2) (CAU), we analysed the suppressor mutants of a tilS-thermosensitive allele. These tilS-suppressor mutants carry a substitution of the wobble guanosine into thymidine in one of the tRNA(Ile1) genes (the original GAT anticodon is changed to a TAT). In absence of TilS activity, the AUA codons are translated into isoleucine by the suppressor tRNA(Ile1), although a low level of AUA codons is also mistranslated into methionine. Results are in agreement with rare cases of eubacteria (and archaea), which naturally lack the tilS gene (or tiaS in archaea) but contain a tRNA(Ile2) gene containing a TAT instead of a CAT anticodon.

Published

2011

25. Specificity shifts in the rRNA and tRNA nucleotide targets of archaeal and bacterial m5U methyltransferases

Author

Sylvie Auxilien, Céline Brochier-Armanet, Simon Rose, Stephen Douthwaite, Clotilde Husson, Henri Grosjean, Anette Rasmussen, Dominique Fourmy, Institut de génétique et microbiologie [Orsay] (IGM), Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS), Institut de Chimie des Substances Naturelles (ICSN), and Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC)

Subjects

Pyrococcus abyssi, S-Adenosylmethionine, Methyltransferase, MESH: Uridine, Biology, Methylation, Article, Substrate Specificity, MESH: Methylation, MESH: Recombinant Proteins, 03 medical and health sciences, RNA, Transfer, 23S ribosomal RNA, MESH: Methyltransferases, Nanoarchaeota, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Molecular Biology, Uridine, MESH: Pyrococcus abyssi, 030304 developmental biology, Genetics, 0303 health sciences, [CHIM.ORGA]Chemical Sciences/Organic chemistry, 030302 biochemistry & molecular biology, MESH: S-Adenosylmethionine, Methyltransferases, Ribosomal RNA, biology.organism_classification, MESH: RNA, Transfer, Archaea, Recombinant Proteins, Thermococcales, RNA, Bacterial, [SDV.MP]Life Sciences [q-bio]/Microbiology and Parasitology, Biochemistry, MESH: Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, RNA, Ribosomal, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, MESH: Archaea, Transfer RNA, MESH: RNA, Ribosomal, MESH: Substrate Specificity, MESH: RNA, Bacterial

Abstract

Methyltransferase enzymes that use S-adenosylmethionine as a cofactor to catalyze 5-methyl uridine (m5U) formation in tRNAs and rRNAs are widespread in Bacteria and Eukaryota, but are restricted to the Thermococcales and Nanoarchaeota groups amongst the Archaea. The RNA m5U methyltransferases appear to have arisen in Bacteria and were then dispersed by horizontal transfer of an rlmD-type gene to the Archaea and Eukaryota. The bacterium Escherichia coli has three gene paralogs and these encode the methyltransferases TrmA that targets m5U54 in tRNAs, RlmC (formerly RumB) that modifies m5U747 in 23S rRNA, and RlmD (formerly RumA) the archetypical enzyme that is specific for m5U1939 in 23S rRNA. The thermococcale archaeon Pyrococcus abyssi possesses two m5U methyltransferase paralogs, PAB0719 and PAB0760, with sequences most closely related to the bacterial RlmD. Surprisingly, however, neither of the two P. abyssi enzymes displays RlmD-like activity in vitro. PAB0719 acts in a TrmA-like manner to catalyze m5U54 methylation in P. abyssi tRNAs, and here we show that PAB0760 possesses RlmC-like activity and specifically methylates the nucleotide equivalent to U747 in P. abyssi 23S rRNA. The findings indicate that PAB0719 and PAB0760 originated as RlmD-type m5U methyltransferases and underwent changes in target specificity after their acquisition by a Thermococcales ancestor from a bacterial source.

Published

2011

26. Biosynthesis of wyosine derivatives in tRNA: an ancient and highly diverse pathway in Archaea

Author

Valérie de Crécy-Lagard, Henri Grosjean, Akiko Noma, Jean Armengaud, Céline Brochier-Armanet, Sophie Alvarez, Bernard Fernandez, Gabriela Phillips, Benjamin J. Lyons, Jaunius Urbonavičius, Louis Droogmans, Institut de génétique et microbiologie [Orsay] (IGM), and Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Genome, Mass Spectrometry, 03 medical and health sciences, chemistry.chemical_compound, Biosynthesis, RNA, Transfer, Crenarchaeota, Genetics, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Molecular Biology, Gene, Ecology, Evolution, Behavior and Systematics, Research Articles, Phylogeny, 030304 developmental biology, 0303 health sciences, biology, Guanosine, 030302 biochemistry & molecular biology, biology.organism_classification, Archaea, [SDV.MP]Life Sciences [q-bio]/Microbiology and Parasitology, chemistry, Biochemistry, Transfer RNA, Euryarchaeota, Wybutosine, Chromatography, Liquid, Signal Transduction

Abstract

International audience; Wyosine (imG) and its derivatives such as wybutosine (yW) are found at position 37 of phenylalanine-specific transfer RNA (tRNA(Phe)), 3' adjacent to the anticodon in Eucarya and Archaea. In Saccharomyces cerevisiae, formation of yW requires five enzymes acting in a strictly sequential order: Trm5, Tyw1, Tyw2, Tyw3, and Tyw4. Archaea contain wyosine derivatives, but their diversity is greater than in eukaryotes and the corresponding biosynthesis pathways still unknown. To identify these pathways, we analyzed the phylogenetic distribution of homologues of the yeast wybutosine biosynthesis proteins in 62 archaeal genomes and proposed a scenario for the origin and evolution of wyosine derivatives biosynthesis in Archaea that was partly experimentally validated. The key observations were 1) that four of the five wybutosine biosynthetic enzymes are ancient and may have been present in the last common ancestor of Archaea and Eucarya, 2) that the variations in the distribution pattern of biosynthesis enzymes reflect the diversity of the wyosine derivatives found in different Archaea. We also identified 7-aminocarboxypropyl-demethylwyosine (yW-86) and its N4-methyl derivative (yW-72) as final products in tRNAs of several Archaea when these were previously thought to be only intermediates of the eukaryotic pathway. We confirmed that isowyosine (imG2) and 7-methylwyosine (mimG) are two archaeal-specific guanosine-37 derivatives found in tRNA of both Euryarchaeota and Crenarchaeota. Finally, we proposed that the duplication of the trm5 gene in some Archaea led to a change in function from N1 methylation of guanosine to C7 methylation of 4-demethylwyosine (imG-14).

Published

2010

27. Deciphering synonymous codons in the three domains of life: co-evolution with specific tRNA modification enzymes

Author

Christian Marck, Henri Grosjean, Valérie de Crécy-Lagard, Institut de génétique et microbiologie [Orsay] (IGM), Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS), Institut de Biologie et de Technologies de Saclay (IBITECS), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay, and Université Paris-Saclay-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)

Subjects

TRNA modification, Translation, Evolution, Genetic code, Biophysics, MESH: Enzymes, Wobble base pair, Biochemistry, Evolution, Molecular, 03 medical and health sciences, RNA, Transfer, Structural Biology, Three-domain system, Genetics, Modified nucleosides, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Codon, Molecular Biology, tRNA, MESH: Evolution, Molecular, 030304 developmental biology, 0303 health sciences, Wobble base-pairing, biology, Bacteria, MESH: Codon, 030302 biochemistry & molecular biology, RNA, Eukaryota, Translation (biology), Cell Biology, biology.organism_classification, MESH: RNA, Transfer, Archaea, MESH: Genetic Code, Enzymes, Mitochondria, MESH: Bacteria, MESH: Eukaryota, [SDV.MP]Life Sciences [q-bio]/Microbiology and Parasitology, Eukarya, Evolutionary biology, Protein Biosynthesis, MESH: Archaea, MESH: Protein Biosynthesis, Transfer RNA

Abstract

International audience; The strategies organisms use to decode synonymous codons in cytosolic protein synthesis are not uniform. The complete isoacceptor tRNA repertoire and the type of modified nucleoside found at the wobble position 34 of their anticodons were analyzed in all kingdoms of life. This led to the identification of four main decoding strategies that are diversely used in Bacteria, Archaea and Eukarya. Many of the modern tRNA modification enzymes acting at position 34 of tRNAs are present only in specific domains and obviously have arisen late during evolution. In an evolutionary fine-tuning process, these enzymes must have played an essential role in the progressive introduction of new amino acids, and in the refinement and standardization of the canonical nuclear genetic code observed in all extant organisms (functional convergent evolutionary hypothesis).

Published

2010

28. Crystal structure of tRNA N2,N2-guanosine dimethyltransferase Trm1 from Pyrococcus horikoshii

Author

Madoka Nishimoto, Yoshitaka Bessho, Kyoko Higashijima, Henri Grosjean, Shigeyuki Yokoyama, Ihsanawati, Mikako Shirouzu, Institut de génétique et microbiologie [Orsay] (IGM), and Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Models, Molecular, S-Adenosylmethionine, Methyltransferase, MESH: tRNA Methyltransferases, MESH: Amino Acid Sequence, Crystallography, X-Ray, chemistry.chemical_compound, MESH: Protein Structure, Tertiary, Protein structure, RNA, Transfer, Structural Biology, Transferase, Alanine, 0303 health sciences, tRNA Methyltransferases, biology, Molecular Structure, 030302 biochemistry & molecular biology, Methylation, S-Adenosylhomocysteine, MESH: Nucleic Acid Conformation, [SDV.MP]Life Sciences [q-bio]/Microbiology and Parasitology, Biochemistry, Transfer RNA, Pyrococcus horikoshii, MESH: Models, Molecular, MESH: S-Adenosylhomocysteine, Stereochemistry, Molecular Sequence Data, MESH: Molecular Structure, MESH: Sequence Alignment, Guanosine, MESH: Pyrococcus horikoshii, 03 medical and health sciences, Humans, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Amino Acid Sequence, Molecular Biology, 030304 developmental biology, Binding Sites, MESH: Humans, MESH: Molecular Sequence Data, MESH: S-Adenosylmethionine, biology.organism_classification, MESH: RNA, Transfer, MESH: Crystallography, X-Ray, Protein Structure, Tertiary, chemistry, MESH: Binding Sites, Nucleic Acid Conformation, Sequence Alignment

Abstract

International audience; Trm1 catalyzes a two-step reaction, leading to mono- and dimethylation of guanosine at position 26 in most eukaryotic and archaeal tRNAs. We report the crystal structures of Trm1 from Pyrococcus horikoshii liganded with S-adenosyl-l-methionine or S-adenosyl-l-homocysteine. The protein comprises N-terminal and C-terminal domains with class I methyltransferase and novel folds, respectively. The methyl moiety of S-adenosyl-l-methionine points toward the invariant Phe27 and Phe140 within a narrow pocket, where the target G26 might flip in. Mutagenesis of Phe27 or Phe140 to alanine abolished the enzyme activity, indicating their role in methylating G26. Structural analyses revealed that the movements of Phe140 and the loop preceding Phe27 may be involved in dissociation of the monomethylated tRNA*Trm1 complex prior to the second methylation. Moreover, the catalytic residues Asp138, Pro139, and Phe140 are in a different motif from that in DNA 6-methyladenosine methyltransferases, suggesting a different methyl transfer mechanism in the Trm1 family.

Published

2008

29. The crystal structure of Pyrococcus abyssi tRNA (uracil-54, C5)-methyltransferase provides insights into its tRNA specificity

Author

Hélène Walbott, Henri Grosjean, Nicolas Leulliot, Béatrice Golinelli-Pimpaneau, Laboratoire d'Enzymologie et Biochimie Structurales (LEBS), Centre National de la Recherche Scientifique (CNRS), Institut de biochimie et biophysique moléculaire et cellulaire (IBBMC), Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS), and Institut de génétique et microbiologie [Orsay] (IGM)

Subjects

Models, Molecular, Protein Folding, Pyrococcus abyssi, [SDV]Life Sciences [q-bio], Archaeal Proteins, Iron, Crystallography, X-Ray, Substrate Specificity, 03 medical and health sciences, chemistry.chemical_compound, Pyrococcus, Bacterial Proteins, RNA, Transfer, Structural Biology, Catalytic Domain, Genetics, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Binding site, 030304 developmental biology, 0303 health sciences, RNA, Transfer, Asp, tRNA Methyltransferases, Binding Sites, biology, 030302 biochemistry & molecular biology, RNA, Active site, Uracil, [SDV.BBM.BM]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Molecular biology, RNA, Fungal, biology.organism_classification, S-Adenosylhomocysteine, TRNA Methyltransferases, [SDV.BBM.BC]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Biomolecules [q-bio.BM], Protein Structure, Tertiary, [SDV.BBM.BP]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Biophysics, [SDV.BBM.BS]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Biomolecules [q-bio.BM], [SDV.MP]Life Sciences [q-bio]/Microbiology and Parasitology, Biochemistry, chemistry, RNA, Ribosomal, Transfer RNA, biology.protein, Nucleic Acid Conformation, Sulfur

Abstract

International audience; The 5-methyluridine is invariably found at position 54 in the TPsiC loop of tRNAs of most organisms. In Pyrococcus abyssi, its formation is catalyzed by the S-adenosyl-l-methionine-dependent tRNA (uracil-54, C5)-methyltransferase ((Pab)TrmU54), an enzyme that emerged through an ancient horizontal transfer of an RNA (uracil, C5)-methyltransferase-like gene from bacteria to archaea. The crystal structure of (Pab)TrmU54 in complex with S-adenosyl-l-homocysteine at 1.9 A resolution shows the protein organized into three domains like Escherichia coli RumA, which catalyzes the same reaction at position 1939 of 23S rRNA. A positively charged groove at the interface between the three domains probably locates part of the tRNA-binding site of (Pab)TrmU54. We show that a mini-tRNA lacking both the D and anticodon stem-loops is recognized by (Pab)TrmU54. These results were used to model yeast tRNA(Asp) in the (Pab)TrmU54 structure to get further insights into the different RNA specificities of RumA and (Pab)TrmU54. Interestingly, the presence of two flexible loops in the central domain, unique to (Pab)TrmU54, may explain the different substrate selectivities of both enzymes. We also predict that a large TPsiC loop conformational change has to occur for the flipping of the target uridine into the (Pab)TrmU54 active site during catalysis.

Published

2008

30. RNomics and Modomics in the halophilic archaea Haloferax volcanii: identification of RNA modification genes

Author

Christine Gaspin, Christian Marck, Wayne A Decatur, Valérie de Crécy-Lagard, Henri Grosjean, Institut de génétique et microbiologie [Orsay] (IGM), and Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)

Subjects

lcsh:QH426-470, lcsh:Biotechnology, RNA, Archaeal, MESH: Haloferax volcanii, 03 medical and health sciences, RNA, Transfer, RRNA modification, lcsh:TP248.13-248.65, MESH: Genes, rRNA, Genetics, MESH: RNA, Ribosomal, 5S, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Guide RNA, Haloferax volcanii, Gene, 030304 developmental biology, Comparative genomics, 0303 health sciences, biology, MESH: Genomics, 030302 biochemistry & molecular biology, RNA, Ribosomal, 5S, RNA, Genes, rRNA, Genomics, biology.organism_classification, Non-coding RNA, MESH: RNA, Transfer, lcsh:Genetics, [SDV.MP]Life Sciences [q-bio]/Microbiology and Parasitology, Protein Biosynthesis, MESH: Protein Biosynthesis, MESH: RNA, Archaeal, Research Article, Biotechnology, Archaea

Abstract

Background Naturally occurring RNAs contain numerous enzymatically altered nucleosides. Differences in RNA populations (RNomics) and pattern of RNA modifications (Modomics) depends on the organism analyzed and are two of the criteria that distinguish the three kingdoms of life. If the genomic sequences of the RNA molecules can be derived from whole genome sequence information, the modification profile cannot and requires or direct sequencing of the RNAs or predictive methods base on the presence or absence of the modifications genes. Results By employing a comparative genomics approach, we predicted almost all of the genes coding for the t+rRNA modification enzymes in the mesophilic moderate halophile Haloferax volcanii. These encode both guide RNAs and enzymes. Some are orthologous to previously identified genes in Archaea, Bacteria or in Saccharomyces cerevisiae, but several are original predictions. Conclusion The number of modifications in t+rRNAs in the halophilic archaeon is surprisingly low when compared with other Archaea or Bacteria, particularly the hyperthermophilic organisms. This may result from the specific lifestyle of halophiles that require high intracellular salt concentration for survival. This salt content could allow RNA to maintain its functional structural integrity with fewer modifications. We predict that the few modifications present must be particularly important for decoding, accuracy of translation or are modifications that cannot be functionally replaced by the electrostatic interactions provided by the surrounding salt-ions. This analysis also guides future experimental validation work aiming to complete the understanding of the function of RNA modifications in Archaeal translation.

Published

2008

31. Detection of enzymatic activity of transfer RNA modification enzymes using radiolabeled tRNA substrates

Author

Henri, Grosjean, Louis, Droogmans, Martine, Roovers, and Gérard, Keith

Subjects

Radioisotopes, RNA, Transfer, Animals, Humans, RNA Processing, Post-Transcriptional, Enzymes

Abstract

The presence of modified ribonucleotides derived from adenosine, guanosine, cytidine, and uridine is a hallmark of almost all cellular RNA, and especially tRNA. The objective of this chapter is to describe a few simple methods that can be used to identify the presence or absence of a modified nucleotide in tRNA and to reveal the enzymatic activity of particular tRNA-modifying enzymes in vitro and in vivo. The procedures are based on analysis of prelabeled or postlabeled nucleotides (mainly with [(32)P] but also with [(35)S], [(14)C] or [(3)H]) generated after complete digestion with selected nucleases of modified tRNA isolated from cells or incubated in vitro with modifying enzyme(s). Nucleotides of the tRNA digests are separated by two-dimensional (2D) thin-layer chromatography on cellulose plates (TLC), which allows establishment of base composition and identification of the nearest neighbor nucleotide of a given modified nucleotide in the tRNA sequence. This chapter provides useful maps for identification of migration of approximately 70 modified nucleotides on TLC plates by use of two different chromatographic systems. The methods require only a few micrograms of purified tRNA and can be run at low cost in any laboratory.

Published

2007

32. Comparative RNomics and modomics in mollicutes: prediction of gene function and evolutionary implications

Author

Valérie de Crécy-Lagard, Henri Grosjean, Céline Brochier-Armanet, Christian Marck, Bioinformatique, phylogénie et génomique évolutive (BPGE), Département PEGASE [LBBE] (PEGASE), Laboratoire de Biométrie et Biologie Evolutive - UMR 5558 (LBBE), Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de Recherche en Informatique et en Automatique (Inria)-VetAgro Sup - Institut national d'enseignement supérieur et de recherche en alimentation, santé animale, sciences agronomiques et de l'environnement (VAS)-Centre National de la Recherche Scientifique (CNRS)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de Recherche en Informatique et en Automatique (Inria)-VetAgro Sup - Institut national d'enseignement supérieur et de recherche en alimentation, santé animale, sciences agronomiques et de l'environnement (VAS)-Centre National de la Recherche Scientifique (CNRS)-Laboratoire de Biométrie et Biologie Evolutive - UMR 5558 (LBBE), and Université de Lyon-Université de Lyon-Institut National de Recherche en Informatique et en Automatique (Inria)-VetAgro Sup - Institut national d'enseignement supérieur et de recherche en alimentation, santé animale, sciences agronomiques et de l'environnement (VAS)-Centre National de la Recherche Scientifique (CNRS)

Subjects

[SDV.OT]Life Sciences [q-bio]/Other [q-bio.OT], Molecular Sequence Data, Clinical Biochemistry, Wobble base pair, Biochemistry, Ribosome, Evolution, Molecular, 03 medical and health sciences, RNA, Transfer, RRNA modification, Genetics, Codon, Molecular Biology, 030304 developmental biology, Mycoplasma capricolum, tRNA Methyltransferases, 0303 health sciences, Base Sequence, biology, 030302 biochemistry & molecular biology, RNA, Translation (biology), Cell Biology, biology.organism_classification, TRNA Methyltransferases, RNA, Bacterial, Genes, Bacterial, RNA, Ribosomal, Transfer RNA, Mollicutes, Nucleic Acid Conformation, Genome, Bacterial, Tenericutes

Abstract

Stable RNAs are central to protein synthesis. Ribosomal RNAs make the core of the ribosome and provide the scaffold for accurate translation of mRNAs by a set of tRNA molecules each carrying an activated amino acid. To fulfill these important cellular functions, both rRNA and tRNA molecules require more than the four canonical bases and have recruited enzymes that introduce numerous modifications on nucleosides. Mollicutes are parasitic unicellular bacteria that originated from gram-positive bacteria by considerably reducing their genome, reaching a minimal size of 480 kb in Mycoplasma genitalium. By analyzing the complete set of tRNA isoacceptors (tRNomics) and predicting the tRNA/rRNA modification enzymes (Modomics) among all sequenced Mollicutes (15 in all), our goal is to predict the minimal set of RNA modifications needed to sustain accurate translation of the cell's genetic information. Building on the known phylogenetic relationship of the 15 Mollicutes analyzed, we demonstrate that the solutions to reducing the RNA component of the translation apparatus vary from one Mollicute to the other and often rely on co-evolution of specific tRNA isoacceptors and RNA modification enzymes. This analysis also reveals that only a few modification enzymes acting on nucleotides of the anticodon loop in tRNA (the wobble position 34 as well as in position 37, 3'-adjacent to anticodon) and of the peptidyltransferase center of 23S rRNA appear to be absolutely essential and resistant to gene loss during the evolutionary process of genome reduction.

Published

2007

33. The RNA polymerase III-dependent family of genes in hemiascomycetes: comparative RNomics, decoding strategies, transcription and evolutionary implications

Author

Henri Grosjean, Christian Marck, Bernard Dujon, Rym Kachouri-Lafond, Ingrid Lafontaine, Eric Westhof, Architecture et réactivité de l'ARN (ARN), Université Louis Pasteur - Strasbourg I-Centre National de la Recherche Scientifique (CNRS), and Martin, Isabelle

Subjects

RNA, Untranslated, Transcription, Genetic, Genes, Fungal, Molecular Sequence Data, Gene redundancy, Biology, Article, RNA polymerase III, Conserved sequence, Evolution, Molecular, 03 medical and health sciences, 0302 clinical medicine, Ascomycota, RNA, Transfer, Transcription Factors, TFIII, [SDV.BBM] Life Sciences [q-bio]/Biochemistry, Molecular Biology, Genetics, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Codon, DNA, Fungal, Promoter Regions, Genetic, Gene, Conserved Sequence, 030304 developmental biology, 2. Zero hunger, Kluyveromyces lactis, 0303 health sciences, Polymorphism, Genetic, Base Sequence, Intron, RNA Polymerase III, RNA, Genomics, biology.organism_classification, Introns, Multigene Family, Transfer RNA, Genome, Fungal, 030217 neurology & neurosurgery

Abstract

We present the first comprehensive analysis of RNA polymerase III (Pol III) transcribed genes in ten yeast genomes. This set includes all tRNA genes (tDNA) and genes coding for SNR6 (U6), SNR52, SCR1 and RPR1 RNA in the nine hemiascomycetes Saccharomyces cerevisiae, Saccharomyces castellii, Candida glabrata, Kluyveromyces waltii, Kluyveromyces lactis, Eremothecium gossypii, Debaryomyces hansenii, Candida albicans, Yarrowia lipolytica and the archiascomycete Schizosaccharomyces pombe. We systematically analysed sequence specificities of tRNA genes, polymorphism, variability of introns, gene redundancy and gene clustering. Analysis of decoding strategies showed that yeasts close to S.cerevisiae use bacterial decoding rules to read the Leu CUN and Arg CGN codons, in contrast to all other known Eukaryotes. In D.hansenii and C.albicans, we identified a novel tDNA-Leu (AAG), reading the Leu CUU/CUC/CUA codons with an unusual G at position 32. A systematic 'p-distance tree' using the 60 variable positions of the tRNA molecule revealed that most tDNAs cluster into amino acid-specific sub-trees, suggesting that, within hemiascomycetes, orthologous tDNAs are more closely related than paralogs. We finally determined the bipartite A- and B-box sequences recognized by TFIIIC. These minimal sequences are nearly conserved throughout hemiascomycetes and were satisfactorily retrieved at appropriate locations in other Pol III genes.

Published

2006

34. Identity elements required for enzymatic formation of N2,N2-dimethylguanosine from N2-monomethylated derivative and its possible role in avoiding alternative conformations in archaeal tRNA

Author

Jaunius Urbonavičius, Jean Armengaud, and Henri Grosjean

Subjects

TRNA modification, Pyrococcus abyssi, Archaeal Proteins, Molecular Sequence Data, D arm, Saccharomyces cerevisiae, Methylation, Substrate Specificity, chemistry.chemical_compound, Pyrococcus, RNA, Transfer, Structural Biology, Magnesium, Uracil, Molecular Biology, Haloferax volcanii, tRNA Methyltransferases, TRNA methylation, biology, Base Sequence, Guanosine, biology.organism_classification, chemistry, Biochemistry, Transfer RNA, Pyrococcus furiosus, Nucleic Acid Conformation, Dihydrouridine

Abstract

Here, we have investigated the specificity of purified recombinant tRNA:m(2)(2)G10 methyltransferase of Pyrococcus abyssi ((Pab)Trm-m(2)(2)G10 enzyme). This archaeal enzyme catalyses mono- and dimethylation of the N(2)-exocyclic amino group of guanine at position 10 of several tRNA species. Our results indicate that only few identity elements are required for the efficient formation of m(2)(2)G10. They are composed of a G10.U25 wobble base-pair in the dihydrouridine arm (D-arm) and a four nucleotide variable loop (V-loop) within a canonical three-dimensional (3D) structure. The types of base-pairs in the D-arm or amino acid acceptor stem are also important for the enzymatic reaction, but appear to affect only the rate of tRNA methylation. However, in tRNA species harbouring a G10-C25 Watson-Crick base-pair and/or five nucleotide V-loop, only m(2)G10 is produced. To impair the monomethylation reaction, drastic amputation in the T-arm is required. Our observations contrast with those reported earlier for the identity elements required for a remotely related Pyrococcus furiosus Trm-m(2)(2)G26 enzyme (alias (Pfu)Trm1) that also catalyses the two step formation of m(2)(2)G but at position 26 in several tRNA species. In this case, a G10-C25 base-pair together with the five nucleotide V-loop were shown to be required for efficient formation of m(2)(2)G26. Thus, in the Pyrococcus genus, the major identity elements that preclude formation of m(2)(2)G at positions 10 or 26 in tRNA are mutually exclusive. Therefore, the Trm-m(2)(2)G10 and Trm-m(2)(2)G26 enzymes have evolved independently towards different specificities. In addition, identity elements for m(2)/m(2)(2)G10 formation in archaeal tRNA are different from the ones required for m(2)G10 formation in eukaryal tRNA. We propose that archaeal tRNA:m(2)(2)G10 methyltransferases, unlike the orthologous eukaryal tRNA:m(2)G10 methyltransferases, evolved towards m(2)(2)G10 specificity due to the possible requirement of preventing formation of alternative structures in G/C rich archaeal tRNA species.

Published

2005

35. N2-methylation of guanosine at position 10 in tRNA is catalyzed by a THUMP domain-containing, S-adenosylmethionine-dependent methyltransferase, conserved in Archaea and Eukaryota

Author

Jaunius Urbonavičius, Janusz Marek Bujnicki, Jean Armengaud, Henri Grosjean, Bernard Fernandez, and Guylaine Chaussinand

Subjects

Models, Molecular, Rossmann fold, S-Adenosylmethionine, Time Factors, Molecular Sequence Data, Guanosine, Biochemistry, Methylation, Catalysis, chemistry.chemical_compound, RNA, Transfer, Catalytic Domain, Amino Acid Sequence, Protein Structure, Quaternary, Molecular Biology, tRNA Methyltransferases, biology, Calorimetry, Differential Scanning, Sequence Homology, Amino Acid, C-terminus, Temperature, Cell Biology, Methyltransferases, DNA Methylation, biology.organism_classification, Archaea, Recombinant Proteins, Protein Structure, Tertiary, Eukaryotic Cells, chemistry, Databases as Topic, Transfer RNA, Pyrococcus furiosus, Chromatography, Gel, RNA, Electrophoresis, Polyacrylamide Gel, Pyrococcus abyssi, Plasmids

Abstract

In sequenced genomes, genes belonging to the cluster of orthologous group COG1041 are exclusively, and almost ubiquitously, found in Eukaryota and Archaea but never in Bacteria. The corresponding gene products exhibit a characteristic Rossmann fold, S-adenosylmethionine-dependent methyltransferase domain in the C terminus and a predicted RNA-binding THUMP (thiouridine synthases, RNA methyltransferases, and pseudouridine synthases) domain in the N terminus. Recombinant PAB1283 protein from the archaeon Pyrococcus abyssi GE5, a member of COG1041, was purified and shown to behave as a monomeric 39-kDa entity. This protein (EC 2.1.1.32), now renamed (Pab)Trm-G10, which is extremely thermostable, forms a 1:1 complex with tRNA and catalyzes the adenosylmethionine-dependent methylation of the exocyclic amino group (N(2)) of guanosine located at position 10. Depending on the experimental conditions used, as well as the tRNA substrate tested, the enzymatic reaction leads to the formation of either N(2)-monomethyl (m(2)G) or N(2)-dimethylguanosine (m(2)(2)G). Interestingly, (Pab)Trm-G10 exhibits different domain organization and different catalytic site architecture from another, earlier characterized, tRNA-dimethyltransferase from Pyrococcus furiosus ((Pfu)Trm-G26, also known as (Pfu)Trm1, a member of COG1867) that catalyzes an identical two-step dimethylation of guanosine but at position 26 in tRNAs and is also conserved among all sequenced Eukaryota and Archaea. The co-occurrence of these two guanosine dimethyltransferases in both Archaea and Eukaryota but not in Bacteria is a hallmark of distinct tRNAs maturation strategies between these domains of life.

Published

2004

36. Pseudouridylation at Position 32 of Mitochondrial and Cytoplasmic tRNAs Requires Two Distinct Enzymes in Saccharomyces cerevisiae

Author

Isabelle Behm-Ansmant, Yuri Motorin, Christiane Branlant, Henri Grosjean, Séverine Massenet, Maturation des ARN et enzymologie moléculaire (MAEM), Cancéropôle du Grand Est-Université Henri Poincaré - Nancy 1 (UHP)-IFR111-Centre National de la Recherche Scientifique (CNRS), Laboratoire d'enzymologie et biochimie structurales (LEBS), and Centre National de la Recherche Scientifique (CNRS)

Subjects

TRNA modification, Cytoplasm, Saccharomyces cerevisiae Proteins, Saccharomyces cerevisiae, Molecular Sequence Data, Mitochondrion, Biochemistry, Catalysis, 03 medical and health sciences, Open Reading Frames, RNA, Transfer, Aminohydrolases, Amino Acid Sequence, Molecular Biology, Gene, Intramolecular Transferases, Uridine, 030304 developmental biology, 0303 health sciences, Aspartic Acid, biology, Cell-Free System, Dose-Response Relationship, Drug, Sequence Homology, Amino Acid, 030302 biochemistry & molecular biology, Genetic Complementation Test, RNA, [SDV.BBM.BM]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Molecular biology, Cell Biology, biology.organism_classification, Recombinant Proteins, Mitochondria, Protein Structure, Tertiary, Transfer RNA, Mutation, Nucleic Acid Conformation, Biogenesis, Gene Deletion, Plasmids

Abstract

International audience; Cytoplasmic and mitochondrial tRNAs contain several pseudouridylation sites, and the tRNA:-synthase acting at position 32 had not been identified in Saccha-romyces cerevisiae. By combining genetic and biochemical analyses, we demonstrate that two enzymes, Rib2/ Pus8p and Pus9p, are required for 32 formation in cytoplasmic and mitochondrial tRNAs, respectively. Pus9p acts mostly in mitochondria, and Rib2/Pus8p is strictly cytoplasmic. This is the first case reported so far of two distinct tRNA modification enzymes acting at the same position but present in two different compartments. This peculiarity may be the consequence of a gene fusion that occurred during yeast evolution. Indeed , Rib2/Pus8p displays two distinct catalytic activities involved in completely unrelated metabolism: its C-terminal domain has a DRAP-deaminase activity required for riboflavin biogenesis in the cytoplasm, whereas its N-terminal domain carries the tRNA:32-synthase activity. Pus9p has only a tRNA:32-synthase activity and contains a characteristic mitochondrial targeting sequence at its N terminus. These results are discussed in terms of RNA:-synthase evolution.

Published

2004

37. Identification of BHB splicing motifs in intron-containing tRNAs from 18 archaea: evolutionary implications

Author

Henri Grosjean and Christian Marck

Subjects

Genetics, Base Sequence, RNA Splicing, Molecular Sequence Data, Intron, Group II intron, Exons, RNA, Archaeal, Biology, Introns, Article, Evolution, Molecular, Exon, Splicing factor, RNA, Transfer, Minor spliceosome, RNA splicing, Transfer RNA, Nucleic Acid Conformation, Structural motif, Molecular Biology

Abstract

Most introns of archaeal tRNA genes (tDNAs) are located in the anticodon loop, between nucleotides 37 and 38, the unique location of their eukaryotic counterparts. However, in several Archaea, mostly in Crenarchaeota, introns have been found at many other positions of the tDNAs. In the present work, we revisit and extend all previous findings concerning the identification, exact location, size, and possible fit to the proposed bulge-helix-bulge structural motif (BHB, now renamed hBHBh′) of the sequences spanning intron–exon junctions in intron-containing tRNAs of 18 archaea. A total of 103 introns were found located at the usual position 37/38 and 33 introns at 14 other different positions, that is, in the anticodon stem and loop, in the D-and T-loops, in the V-arm, or in the amino acid arm. For introns located at 37/38 and elsewhere in the pre-tRNA, canonical hBHBh′ motifs were not always found. Instead, a relaxed hBH or HBh′ motif including the constant central 4-bp helix H flanked by one helix (h or h′) on either side generating only one bulge could be disclosed. Also, for introns located elsewhere than at position 37/38, the hBHBh′ (or HBh′) structure competes with the three-dimensional structure of the mature tRNA, attesting to important structural rearrangements during the complex multistep maturation-splicing processes. A homotetramer-type of splicing endonuclease (like in all Crenarchaeota) instead of a homodimeric-type of enzyme (as in most Euryarchaeota) appears to best fit the requirement for splicing introns at relaxed hBH or HBh′ motifs, and may represent the most primitive form of this enzyme.

Published

2003

38. Lack of pseudouridine 38/39 in the anticodon arm of yeast cytoplasmic tRNA decreases in vivo recoding efficiency

Author

François Lecointe, George Simos, Olivier Namy, Henri Grosjean, Jean-Pierre Rousset, Isabelle Hatin, Laboratoire d'Enzymologie et Biochimie Structurales (LEBS), Centre National de la Recherche Scientifique (CNRS), Institut de génétique et microbiologie [Orsay] (IGM), Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS), University of Thessaly, CNRS, Association pour la Recherche sur le Cancer [Contract 5297], Ministère de l’Education Nationale de la Recherche et de la Technologie, Association pour la Recherche sur le Cancer [Contract 9873], Association Française Contre les Myopathies [Contract 7757], Ministère de la Recherche et de l’Enseignement Supérieur (predoctoral fellowship), 'Association pour la Recherche sur le Cancer' (predoctoral fellowship), Greek-French Collaboration Program 'PLATON', and Grosjean, Henri

Subjects

Cytoplasm, [SDV]Life Sciences [q-bio], Saccharomyces cerevisiae, Biology, Biochemistry, Ribosome, Pseudouridine, Frameshift mutation, 03 medical and health sciences, chemistry.chemical_compound, RNA, Transfer, Mutant protein, Anticodon, Molecular Biology, 030304 developmental biology, Genetics, 0303 health sciences, 030302 biochemistry & molecular biology, Frameshifting, Ribosomal, Translation (biology), Cell Biology, Stop codon, Nonsense suppressor, chemistry, Protein Biosynthesis, Transfer RNA, Ribosomes

Abstract

International audience; Many different modified nucleotides are found in naturally occurring tRNA, especially in the anticodon region. Their importance for the efficiency of the translational process begins to be well documented. Here we have analyzed the in vivo effect of deleting genes coding for yeast tRNA-modifying enzymes, namely Pus1p, Pus3p, Pus4p, or Trm4p, on termination readthrough and +1 frameshift events. To this end, we have transformed each of the yeast deletion strains with a lacZ-luc dual-reporter vector harboring selected programmed recoding sites. We have found that only deletion of the PUS3 gene, encoding the enzyme that introduces pseudouridines at position 38 or 39 in tRNA, has an effect on the efficiency of the translation process. In this mutant, we have observed a reduced readthrough efficiency of each stop codon by natural nonsense suppressor tRNAs. This effect is solely due to the absence of pseudouridine 38 or 39 in tRNA because the inactive mutant protein Pus3[D151A]p did not restore the level of natural readthrough. Our results also show that absence of pseudouridine 39 in the slippery tRNA(UAG)(Leu) reduces +1 frameshift efficiency. Therefore, the presence of pseudouridine 38 or 39 in the tRNA anticodon arm enhances misreading of certain codons by natural nonsense tRNAs as well as promotes frameshifting on slippery sequences in yeast.

Published

2002

39. Trm7p catalyses the formation of two 2'-O-methylriboses in yeast tRNA anticodon loop

Author

Bruno Lapeyre, François Lecointe, Lionel Pintard, Janusz M. Bujnicki, Henri Grosjean, Claire Bonnerot, Centre de Recherche de Biochimie Macromoléculaire, Centre National de la Recherche Scientifique (CNRS), Laboratoire d'Enzymologie et Biochimie Structurales (LEBS), International Institute of Molecular and Cell Biology, CNRS, Ligue contre le Cancer, Fondation pour la Recherche Médicale, Association pour la Recherche sur le Cancer [ARC5914, ARC5297], MENESR (fellowship), Association pour la Recherche sur le Cancer (fellowship), Polish State Committee for Scientific Research [8T11F01019], and BioInfoBank

Subjects

S-Adenosylmethionine, Methyltransferase, Ribose, [SDV]Life Sciences [q-bio], Cell Cycle Proteins, RNA-binding protein, RNA, Transfer, Maturation, Protein biosynthesis, Genetics, tRNA Methyltransferases, 0303 health sciences, General Neuroscience, 030302 biochemistry & molecular biology, Translation (biology), Three‐Dimensional Structure, Eukaryotic Cells, Biochemistry, Transfer RNA, Saccharomyces cerevisiae Proteins, RNA Methyltransferase, Recombinant Fusion Proteins, Molecular Sequence Data, Saccharomyces cerevisiae, Modification, Biology, Catalysis, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Anticodon, Escherichia coli, Animals, Humans, Amino Acid Sequence, RNA, Messenger, Molecular Biology, 030304 developmental biology, Base Sequence, Sequence Homology, Amino Acid, General Immunology and Microbiology, RNA, RNA, Fungal, Methyltransferases, biology.organism_classification, Protein Structure, Tertiary, TRNA Methyltransferases, RNA Binding Protein, Mutagenesis, Protein Biosynthesis, Nucleic Acid Conformation

Abstract

International audience; The genome of Saccharomyces cerevisiae encodes three close homologues of the Escherichia coli 2′‐O‐rRNA methyltransferase FtsJ/RrmJ, designated Trm7p, Spb1p and Mrm2p. We present evidence that Trm7p methylates the 2′‐O‐ribose of nucleotides at positions 32 and 34 of the tRNA anticodon loop, both in vivo and in vitro. In a trm7Δ strain, which is viable but grows slowly, translation is impaired, thus indicating that these tRNA modifications could be important for translation efficiency. We discuss the emergence of a family of three 2′‐O‐RNA methyltransferases in Eukaryota and one in Prokaryota from a common ancestor. We propose that each eukaryotic enzyme is located in a different cell compartment, in which it would methylate a different RNA that can adopt a very similar secondary structure.

Published

2002

40. Identification and Characterization of the tRNA:Ψ 31 -Synthase (Pus6p) of Saccharomyces cerevisiae

Author

Henri Grosjean, Yuri Motorin, Christiane Branlant, Séverine Massenet, Isabelle Ansmant, Maturation des ARN et enzymologie moléculaire (MAEM), Cancéropôle du Grand Est-Université Henri Poincaré - Nancy 1 (UHP)-IFR111-Centre National de la Recherche Scientifique (CNRS), Laboratoire d’Enzymologie et Biochimie Structurales, Centre de Recherche de Gif, Centre National de la Recherche Scientifique, 91198 Gif sur Yvette, France, Laboratoire d'Enzymologie et Biochimie Structurales, and Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Cytoplasm, [SDV]Life Sciences [q-bio], Saccharomyces cerevisiae, Biochemistry, Pseudouridine, Substrate Specificity, Open Reading Frames, 03 medical and health sciences, chemistry.chemical_compound, RNA, Transfer, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Intramolecular Transferases, Molecular Biology, Gene, Hydro-Lyases, Cellular localization, 030304 developmental biology, 0303 health sciences, biology, 030302 biochemistry & molecular biology, RNA, [SDV.BBM.BM]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Molecular biology, Cell Biology, biology.organism_classification, Mitochondria, Open reading frame, chemistry, Transfer RNA, Small nuclear RNA

Abstract

International audience; To characterize the substrate specificity of the putative RNA:pseudouridine (Psi)-synthase encoded by the Saccharomyces cerevisiae open reading frame (ORF) YGR169c, the corresponding gene was deleted in yeast, and the consequences of the deletion on tRNA and small nuclear RNA modification were tested. The resulting DeltaYGR169c strain showed no detectable growth phenotype, and the only difference in Psi formation in stable cellular RNAs was the absence of Psi at position 31 in cytoplasmic and mitochondrial tRNAs. Complementation of the DeltaYGR169c strain by a plasmid bearing the wild-type YGR169c ORF restored Psi(31) formation in tRNA, whereas a point mutation of the enzyme active site (Asp(168)-->Ala) abolished tRNA:Psi(31)-synthase activity. Moreover, recombinant His(6)-tagged Ygr169 protein produced in Escherichia coli was capable of forming Psi(31) in vitro using tRNAs extracted from the DeltaYGR169c yeast cells as substrates. These results demonstrate that the protein encoded by the S. cerevisiae ORF YGR169c is the Psi-synthase responsible for modification of cytoplasmic and mitochondrial tRNAs at position 31. Because this is the sixth RNA:Psi-synthase characterized thus far in yeast, we propose to rename the corresponding gene PUS6 and the expressed protein Pus6p. Finally, the cellular localization of the green fluorescent protein-tagged Pus6p was studied by functional tests and direct fluorescence microscopy.

Published

2001

41. Identification of the Saccharomyces cerevisiae RNA:pseudouridine synthase responsible for formation of 2819 in 21S mitochondrial ribosomal RNA

Author

Yuri Motorin, Isabelle Ansmant, Henri Grosjean, Séverine Massenet, Christiane Branlant, Maturation des ARN et enzymologie moléculaire (MAEM), and Cancéropôle du Grand Est-Université Henri Poincaré - Nancy 1 (UHP)-IFR111-Centre National de la Recherche Scientifique (CNRS)

Subjects

RNA, Mitochondrial, [SDV]Life Sciences [q-bio], Molecular Sequence Data, Saccharomyces cerevisiae, Biology, Mitochondrion, MT-RNR1, Ribosome, Pseudouridine, Article, Fungal Proteins, 03 medical and health sciences, chemistry.chemical_compound, Open Reading Frames, RNA, Transfer, RNA, Small Nuclear, Genetics, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Amino Acid Sequence, RNA Processing, Post-Transcriptional, Intramolecular Transferases, Uridine, 030304 developmental biology, 0303 health sciences, Base Sequence, Sequence Homology, Amino Acid, 030302 biochemistry & molecular biology, RNA, Biological Transport, [SDV.BBM.BM]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Molecular biology, Ribosomal RNA, Mitochondrial RNA modification, Mitochondria, Biochemistry, chemistry, Mutagenesis, RNA, Ribosomal, Small nuclear RNA, Cell Division

Abstract

International audience; So far, four RNA:pseudouridine (Psi)-synthases have been identified in yeast Saccharomyces cerevisiae. Together, they act on cytoplasmic and mitochondrial tRNAs, U2 snRNA and rRNAs from cytoplasmic ribosomes. However, RNA:Psi-synthases responsible for several U-->Psi conversions in tRNAs and UsnRNAs remained to be identified. Based on conserved amino-acid motifs in already characterised RNA:Psi-synthases, four additional open reading frames (ORFs) encoding putative RNA:Psi-synthases were identified in S.cerevisiae. Upon disruption of one of them, the YLR165c ORF, we found that the unique Psi residue normally present in the fully matured mitochondrial rRNAs (Psi(2819)in 21S rRNA) was missing, while Psi residues at all the tested pseudo-uridylation sites in cytoplasmic and mitochondrial tRNAs and in nuclear UsnRNAs were retained. The selective U-->Psi conversion at position 2819 in mitochondrial 21S rRNA was restored when the deleted yeast strain was transformed by a plasmid expressing the wild-type YLR165c ORF. Complementation was lost after point mutation (D71-->A) in the postulated active site of the YLR165c-encoded protein, indicating the direct role of the YLR165c protein in Psi(2819)synthesis in mitochondrial 21S rRNA. Hence, for nomenclature homogeneity the YLR165c ORF was renamed PUS5 and the corresponding RNA:Psi-synthase Pus5p. As already noticed for other mitochondrial RNA modification enzymes, no canonical mitochondrial targeting signal was identified in Pus5p. Our results also show that Psi(2819)in mitochondrial 21S rRNA is not essential for cell viability.

Published

2000

42. Pseudouridine synthetase Pus1 of Saccharomyces cerevisiae: kinetic characterisation, tRNA structural requirement and real-time analysis of its complex with tRNA

Author

Véronique Arluison, Henri Grosjean, Malcolm Buckle, Institut de génétique et microbiologie [Orsay] (IGM), Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS), Physicochimie des Macromolecules Biologiques, Institut Pasteur [Paris]-Centre National de la Recherche Scientifique (CNRS), and Institut Pasteur [Paris] (IP)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Time Factors, Transcription, Genetic, MESH: Base Pairing, Saccharomyces cerevisiae, MESH: RNA, Transfer, Asp, Biology, Pseudouridine, MESH: Recombinant Proteins, 03 medical and health sciences, chemistry.chemical_compound, RNA, Transfer, Structural Biology, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, RNA, Transfer, Ile, Molecular Biology, Base Pairing, RNA, Transfer, Val, Histidine, Hydro-Lyases, 030304 developmental biology, Sequence Deletion, MESH: RNA, Transfer, Ile, chemistry.chemical_classification, 0303 health sciences, RNA, Transfer, Asp, MESH: Kinetics, MESH: RNA, Transfer, Val, MESH: Transcription, Genetic, MESH: Hydro-Lyases, MESH: Time Factors, 030302 biochemistry & molecular biology, MESH: Sequence Deletion, Surface Plasmon Resonance, MESH: RNA, Transfer, biology.organism_classification, MESH: Saccharomyces cerevisiae, Yeast, Recombinant Proteins, MESH: Surface Plasmon Resonance, Dissociation constant, Kinetics, MESH: Nucleic Acid Conformation, Enzyme, chemistry, Biochemistry, Transfer RNA, Nucleic Acid Conformation, T arm

Abstract

International audience; Pseudouridine synthetase Pus1 from Saccharomyces cerevisiae is a multisite-specific enzyme that catalyses the formation of pseudouridine residues at different positions in several tRNA transcripts. Recombinant Pus1, tagged with six histidine residues at its N terminus was expressed in Escherichia coli and purified. Transcripts of yeast tRNAValand intronless yeast tRNAIlewere used as substrates to measure pseudouridine formation at position 27. The catalytic parameters Kmand kcatfor tRNAValand tRNAIlewere 420(+/-100) nM and 0.4(+/-0.1) min-1, 740(+/-100) nM and 0.5(+/-0.1) min-1, respectively. Pus1 possesses a general affinity for tRNA, irrespective of whether they are substrates. Its equilibrium dissociation constant ranges from 15 nM for the substrate yeast tRNAValand non-substrate yeast intronless tRNAPhe, to 150 nM for the substrate yeast intronless tRNAIle. The difference in the affinity for the different tRNA species is not reflected in the specific activity of the enzyme, indicating that the binding of Pus1 to tRNA is not the kinetically limiting step. The importance of tertiary base-pairs was investigated with several variants of yeast tRNAs. Although dispensable for activity, both the presence of a D-stem-loop and the presence of a G26.A44 base-pair, near the target uridine U27, are important elements for Pus1 tRNA high affinity recognition. The presence of a G26.A44 base-pair in tRNA increases its association constant rate with Pus1 (ka) by a factor of approximately 100, resulting in a decrease of the overall equilibrium dissociation constant (Kd). The dissociation rate (kd) is the same, independent of the presence of a G26.A44 base-pair in the tRNA. A model describing the interaction of Pus1 with tRNA is proposed.

Published

1999

43. The various strategies of codon decoding in organisms of the three domains of Life: evolutionary implications

Author

Christian Marck, Henri Grosjean, and Valérie de Crécy-Lagard

Subjects

Genetics, Evolution of cells, Translation (biology), Genomics, General Medicine, Computational biology, Biology, Genetic code, Evolution, Molecular, Sense Codon, Ascomycota, RNA, Transfer, Genome, Archaeal, RNA editing, Codon usage bias, Transfer RNA, Anticodon, Animals, Genome, Fungal, Codon, Gene, Genome, Bacterial, Tenericutes

Abstract

Over a thousand of cytoplasmic, non organellar tRNA genes were extracted from the whole-genomes of more than 100 organisms spanning the Bacteria, Eukarya and Archaea (tRNomics). Also, whenever possible, the genes coding for modification enzymes acting on tRNA, particularly those involved in modification of nucleotides in the anticodon loop, were identified (Modomics). Combining these two data sets, we were able to reveal three main decoding strategies used by individual contemporary organisms to read the 62 (61+1 initiator) sense codons of mRNA. Based on the known phylogenetic relationships of the different organisms analyzed, this work allows to predict which RNA modification enzymes are essential for an accurate and efficient translation process, as well as to shed light on when these complex and diverse tRNA maturation processes probably emerged during cellular evolution.

Published

2007

44. Tad1p, a yeast tRNA-specific adenosine deaminase, is related to the mammalian pre-mRNA editing enzymes ADAR1 and ADAR2

Author

Walter Keller, Thorsten Melcher, Henri Grosjean, and André P. Gerber

Subjects

TRNA modification, Adenosine Deaminase, Molecular Sequence Data, Saccharomyces cerevisiae, Biology, General Biochemistry, Genetics and Molecular Biology, Substrate Specificity, Adenosine deaminase, RNA, Transfer, medicine, RNA Precursors, Amino Acid Sequence, RNA, Messenger, Molecular Biology, DNA Primers, chemistry.chemical_classification, General Immunology and Microbiology, Base Sequence, Sequence Homology, Amino Acid, General Neuroscience, Intron, RNA, Adenosine, Enzyme, chemistry, Biochemistry, RNA editing, Transfer RNA, biology.protein, RNA Editing, medicine.drug, Research Article

Abstract

We have identified an RNA-specific adenosine deaminase (termed Tad1p/scADAT1) from Saccharomyces cerevisiae that selectively converts adenosine at position 37 of eukaryotic tRNAAla to inosine. The activity of purified recombinant Tad1p depends on the conformation of its tRNA substrate and the enzyme was found to be inactive on all other types of RNA tested. Mutant strains in which the TAD1 gene is disrupted are viable but lack Tad1p enzyme activity and their tRNAAla is not modified at position A37. Transformation of the mutant cells with the TAD1 gene restored enzyme activity. Tad1p has significant sequence similarity with the mammalian editing enzymes which act on specific precursor-mRNAs and on long double-stranded RNA. These findings suggest an evolutionary link between pre-mRNA editing and tRNA modification.

Published

1998

45. Intron-dependent enzymatic formation of modified nucleosides in eukaryotic tRNAs: a review

Author

Yuri Motorin, George Simos, Franco Fasiolo, Henri Grosjean, and Zofia Szweykowska-Kulinska

Subjects

tRNA Methyltransferases, Base Sequence, Nucleolus, Molecular Sequence Data, Intron, Nucleosides, General Medicine, Biology, Biochemistry, Introns, TRNA Methyltransferases, Eukaryotic Cells, RNA, Transfer, Transfer RNA, RNA splicing, Animals, Small nucleolar RNA, RNA Processing, Post-Transcriptional, Gene, Small nuclear RNA

Abstract

In eukaryotic cells, especially in yeast, several genes encoding tRNAs contain introns. These are removed from pre-tRNAs during the maturation process by a tRNA-specific splicing machinery that is located within the nucleus at the nuclear envelope. Before and after the intron removal, several nucleoside modifications are added in a stepwise manner, but most of them are introduced prior to intron removal. Some of these early nucleoside modifications are catalyzed by intron-dependent enzymes while most of the others are catalyzed in an intron-independent manner. In the present paper, we review all known cases where the nucleoside modifications were shown to depend strictly on the presence of an intron. These are pseudouridines at anticodon positions 34, 35 and 36 and 5-methylcytosine at position 34 of several eukaryotic tRNAs. One common property of the corresponding intron-dependent modifying enzymes is that their activities are essentially dependent on the local specific architecture of the pre-tRNA molecule that comprises the anticodon stem and loop prolonged by the intron domain. Thus introns clearly serve as internal (cis-type) RNAs that guide nucleoside modifications by providing transient target sites in tRNA for selected nuclear modifying enzymes. This situation may be similar to the recently discovered (trans-type) snoRNA-guided process of ribose methylations of ribosomal RNAs within the nucleolus of eukaryotic cells.

Published

1997

46. The yeast gene YNL292w encodes a pseudouridine synthase (Pus4) catalyzing the formation of PSI55 in both mitochondrial and cytoplasmic tRNAs

Author

Hubert F. Becker, Rudi J. Planta, Henri Grosjean, Yuri Motorin, Biochemistry and Molecular Biology, and Molecular and Computational Toxicology

Subjects

Cytoplasm, RNA, Mitochondrial, Recombinant Fusion Proteins, Saccharomyces cerevisiae, Genes, Fungal, Molecular Sequence Data, Gene Expression, Pseudouridine, Catalysis, Substrate Specificity, Gene product, chemistry.chemical_compound, Open Reading Frames, RNA, Transfer, Genetics, Amino Acid Sequence, Intramolecular Lyases, Intramolecular Transferases, Expression vector, biology, Structural gene, RNA, Fungal, biology.organism_classification, Chromatography, Ion Exchange, Yeast, Mitochondria, chemistry, Biochemistry, TAF4, Transfer RNA, Nucleic Acid Conformation, RNA, Gene Deletion, Research Article

Abstract

The protein products of two yeast Saccharomyces cerevisiae genes (YNL292w and CBF5) display a remarkable sequence homology with Escherichia coli tRNA:pseudouridine-55 synthase (encoded by gene truB). The gene YNL292w coding for one of these proteins was cloned in an E.coli expression vector downstream of a His6-tag. The resulting recombinant protein (Pus4) was expressed at high level and purified to homogeneity by metal affinity chromatography on Ni2+-NTA-agarose, followed by ion-exchange chromatography on MonoQ. The purified Pus4p catalyzes the formation of pseudouridine-55 in T7 in vitro transcripts of several yeast tRNA genes. In contrast to the known yeast pseudouridine synthase (Pus1) of broad specificity, no other uridines in tRNA molecules are modified by the cloned recombinant tRNA:Psi55 synthase. The disruption of the corresponding gene YNL292w in yeast, which has no significant effect on the growth of yeast cells, leads to the complete disappearance of the Psi55 formation activity in a cell-free extract. These results allow the formal identification of the protein encoded by the yeast ORF YNL292w as the only enzyme responsible for the formation of Psi55 which is almost universally conserved in tRNAs. The substrate specificity of the purified YNL292w-encoded recombinant protein was shown to be similar to that of the native protein present in yeast cell extract. Chemical mapping of pseudouridine residues in both cytoplasmic and mitochondrial tRNAs from the yeast strain carrying the disrupted gene reveals that the same gene product is responsible for Psi55 formation in tRNAs of both cellular compartments.

Published

1997

47. Enzymatic formation of N2,N2-dimethylguanosine in eukaryotic tRNA: importance of the tRNA architecture

Author

Johan Edqvist, Kerstin B. Stråby, and Henri Grosjean

Subjects

chemistry.chemical_classification, S-Adenosylmethionine, tRNA Methyltransferases, Guanosine, Molecular Structure, Base pair, RNA, RNA, Fungal, General Medicine, Methylation, Biology, Biochemistry, Yeast, chemistry.chemical_compound, Enzyme, chemistry, RNA, Transfer, Yeasts, Transfer RNA, Nucleic Acid Conformation, Nucleotide, RNA Processing, Post-Transcriptional

Abstract

In eukaryotic tRNA, guanosine at position 26 in the junction between the D-stem and the anticodon stem is mostly modified to N2,N2-dimethylguanosine (m2(2)G26). Here we review the available information on the enzyme catalyzing the formation of this modified nucleoside, the SAM-dependent tRNA (m2(2)G26)-methyltransferase, and our attemps to identify the parameters in tRNA needed for efficient enzymatic dimethylation of guanosine-26. The required identity elements in yeast tRNA for dimethylation under in vitro conditions by the yeast tRNA(m2(2)G26)-methyltransferase (the TRM1 gene product) are comprised of two G-C base pairs at positions G10-C25 and C11-G24 in the D-stem together with a variable loop of at least five nucleotides. These positive determinants do not seem to act via base specific interactions with the methyltransferase; they instead ensure that G26 is presented to the enzyme in a favorable orientation, within the central 3D-core of the tRNA molecule. The anticodon stem and loop is not involved in such an interaction with the enzyme. In a heterologous in vivo system, consisting of yeast tRNAs microinjected into Xenopus laevis oocytes, the requirements for modification of G26 are less stringent than in the yeast homologous in vitro system. Indeed, G26 in several microinjected tRNAs becomes monomethylated, while in yeast extracts it stays unmethylated, even after extensive incubation. Thus either the X laevis tRNA(m2(2)G26)-methyltransferase has a more relaxed specificity than its yeast homolog, or there exist two distinct G26-methylating activities, one for G26-monomethylation, and one for dimethylation of G26.(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1995

48. The Evolving Trna Molecul

Author

Bernard B. Larue, Henri Grosjean, Dieter Söil, Robert Cedergren, and David Sankoff

Subjects

DNA Replication, Cultural Studies, Genetics, Base Sequence, Models, Genetic, Molecular Conformation, Computational biology, Biology, Genetic code, Biological Evolution, Education, Genes, RNA, Transfer, Genetic Code, Molecular evolution, Mutation, Organelle, Transfer RNA, Anticodon, Protein biosynthesis, Animals, Nucleic Acid Conformation, Codon, Phylogeny

Abstract

The study of tRNA molecular evolution is crucial to understanding the origin and establishment of the genetic code as well as the differentiation and refinement of the machinery of protein synthesis in prokaryotes, eukaryotes, organelles, and phage systems. The small size of the molecule and its critical involvement in a multiplicity of roles distinguish its study from classical protein molecular evolution with respect to goals and methods. Here, theauthors assessavailable and missingdata, existingand needed methodology, and the impact of tRNA studies on current theories both of genetic code evolution and of the evolution of species. They analyze mutational “hot spots”, the role of base modification, synthetase recognition, codon-anticodon interactions and the status of organelle tRNA.

Published

1981

49. Post-transcriptlonal modification of the wobble nucletide in anticodon-substituted yeast tRNAIIArgafter microinjection intoxenopus laevis oocytes

Author

Etienne Haumont, Suzanne De Henau, Jean Gangloff, Henri Grosjean, and Michel Fournier

Subjects

Microinjections, Xenopus, Saccharomyces cerevisiae, Guanosine, Wobble base pair, RNA, Transfer, Amino Acyl, Biology, chemistry.chemical_compound, RNA, Transfer, Anticodon, Genetics, medicine, Animals, Ribonuclease T1, RNA Processing, Post-Transcriptional, Inosine, Ovum, chemistry.chemical_classification, DNA ligase, Base Sequence, Single-Strand Specific DNA and RNA Endonucleases, Endonucleases, biology.organism_classification, Yeast, Uridine, Kinetics, chemistry, Biochemistry, Transfer RNA, Oocytes, Nucleic Acid Conformation, bacteria, Female, medicine.drug

Abstract

An enzymatic procedure for the replacement of the ICG anticodon of yeast tRNAArgII by NCG trinucleotide (N = A, C, G or U) is described. Partial digestion with S1-nuclease and T1-RNAase provides fragments which, when annealed together, form an "anticodon-deprived" yeast tRNAArgII. A novel anticodon, phosphorylated with (32P) label on its 5' terminal residue, is then inserted using T4-RNA ligase. Such "anticodon-substituted" yeast tRNAArgII are microinjected into the cytoplasm of Xenopus laevis oocytes and shown to be able to interact with the anticodon maturation enzymes under in vivo conditions. Our results indicate that when adenosine occurs in the wobble position (A34) in yeast tRNAArgII it is efficiently modified into inosine (I34) while uridine (U34) is transformed into two uridine derivatives, one of which is probably mcm5U. In contrast, when a cytosine (C34) or guanosine (G34) occurs, they are not modified. These results are at variance with those obtained previously under similar conditions with anticodon derivatives of yeast tRNAAsp harbouring A, C, G or U as the first anticodon nucleotide. In this case, guanosine and uridine were modified while adenosine and cytosine were not.

Published

1983

50. Incorrect Aminoacylations Involving tRNAs or Valyl-tRNA Synthetase from BacilIus stearothermophilus

Author

Henri Grosjean, Suzanne De Henau, Jean-Pierre Ebel, Hubert Chantrenne, Daniel Kern, and Richard Giegé

Subjects

Hot Temperature, Acylation, Bacillus, Aminoacylation, Phenylalanine, Saccharomyces cerevisiae, Biology, medicine.disease_cause, Biochemistry, Amino Acyl-tRNA Synthetases, Bacterial Proteins, RNA, Transfer, Escherichia coli, medicine, TRNA aminoacylation, Dimethyl Sulfoxide, Amination, chemistry.chemical_classification, Valine, Yeast, Kinetics, RNA, Bacterial, Enzyme, chemistry, Transfer RNA, bacteria, Isoleucine

Abstract

Numerous misacylations occur on heterologous systems containing unfractionated tRNAs from yeast or from Bacillus stearothermophilus and pure valyl-tRNA synthetase from B. stearothermophilus or from yeast, when special aminoacylation conditions are used. In the homologous system and in heterologous systems where the unfractionated tRNAs and the enzyme originate from prokaryotic organisms (B. stearothermophilus and Escherichia coli), the errors are seldom. This phenomenon is explained by competition effects between the cognate tRNAVal and non-cognate tRNAs for the valyl-tRNA synthetase. But using pure tRNA species, errors can be observed in such systems, even under classical assay conditions; in particular it was shown that the valyl-tRNA synthetase from B. stearothermophilus catalyses the misacylation of E. coli tRNAIle and tRNAtMet and of yeast tRNAtMet and tRNAPhe. These reactions are characterized by Km values slightly increased as compared to the value obtained in the cognate system and by V values decreased by a factor of about 40 to 3000 compared to the cognate tRNA species. In the presence of dimethylsulfoxide, the rate and the extent of those misacylation reactions are enhanced. In the case of E. coli tRNAPhe, the misacylation occurs only in the presence of the organic solvent. In no case however, new aminoacylation errors are induced at high temperature (50–75 °C) in the presence of the thermostable valyl-tRNA synthetase from B. stearothermophilus; only an increase of the rates of the aminoacylation reactions which already occur at 30 °C has been observed at higher temperature. Thus organic solvent and heat must have distinct effects on the essential parameters determining the specificity of the tRNA aminoacylation reactions. Also it has been observed that the most easily misacylated tRNA species by valyl-tRNA synthetase from B. stearothermophilus are the same as those which are misacylated by the valyl-tRNA synthetases from E. coli and from yeast. This observation suggests the existence of a family of tRNAs containing besides of tRNAVal, other tRNAs such as tRNAIle, tRNAtMet and tRNAPhe, and which are likely to be related from a phylogenic point of view. Moreover these tRNA species have also been found to be easily misacylated by other aminoacyl-tRNA synthetases namely the enzymes specific for isoleucine and phenylalanine, thus suggesting more generally the existence of interacting tRNA-aminoacyl-tRNA synthetase families.

Published

1974