Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:6.1.1.10 (methionyl-tRNA synthetase)
 387 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The crystal structure of the tryptic fragment of the methionyl-tRNA synthetase from Escherichia coli, complexed with ATP, has been refined to a crystallographic R-factor of 0.220, at 2.5 A resolution (for 4433 protein atoms). In the last stages of the refinement, the simulated annealing refinement method was fully applied, contributing to a drastic improvement of the model and the identification of the missing atoms. In the final model, the root-mean-square deviation from ideality for bond distances is 0.021 A and for angle distances is 0.054 A. The position of the zinc ion has been confirmed and is located near the active site. The tryptic fragment is composed of two globular domains. The first domain, from the N terminus to Thr360, contains a nucleotide-binding fold into which two long polypeptides of 101 and 70 residues are inserted. The nucleotide-binding fold is strengthened by the presence of the zinc ion in the vicinity of the active site. The second domain, up to Pro526, is mainly alpha-helical. The C-terminal polypeptide, Phe527 to Lys551, folds back towards the first domain, making a link between the two domains. The heptapeptide 528-534 partly shapes a deep cavity that plunges into the central core of the nucleotide-binding fold, where the ATP molecule is located. The adenine ring, deeply buried in the bottom of the cleft, is blocked between the first helix HA, and the strands A and D of the beta-sheet and makes no polar interaction with the enzyme. The 2' and 3' hydroxyl groups of the ribose, whose conformation is C2' endo, interact with the main-chain carbonyl oxygen atoms of Ile231 and Glu241, respectively. The side-chain nitrogen atom of Lys142 is at hydrogen-bonding distance from the ring oxygen O-4' of the ribose. One of the alpha-phosphate oxygen atoms and one of the gamma-phosphate oxygen atoms interact with the imidazole ring of His21, which is well conserved in many of the known synthetases; this indicates a possible crucial role for this residue in binding ATP. The beta-phosphate group is linked to the main-chain carbonyl oxygen atom of Tyr15 through an intermediate water molecule. The gamma-phosphate group interacts with the carbonyl oxygen atom and the side-chain of Asn17.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Crystallographic study at 2.5 A resolution of the interaction of methionyl-tRNA synthetase from Escherichia coli with ATP. 225 37

To obtain direct evidence for the attachment of 5SrRNA-ribosomal L5 protein particles (5SRNP) and methionine-tRNA (tRNA(met)) to methionyl-tRNA synthetase (MetRS) in the macromolecular aminoacyl-tRNA synthetase (ARS) complex of rat liver, a MetRS-5SRNP-tRNA(met) complex was dissociated from the macromolecular ARS complex fraction by n-octyl-beta-D-glucoside (Method I) or by omega-aminooctyl agarose (Method II) chromatography. The dissociated MetRS complex fraction was purified by gel filtration followed by tRNA-Sepharose chromatography using partially purified tRNA(met) in Method I, and by hydrophobic interaction chromatography in Method II. In both methods, final Superdex200 chromatography showed that MetRS activity was present in the region corresponding to the molecular weight of the MetRS-5SRNP-tRNA(met) complex (M(r) 200,000). One main protein band corresponding to the molecular weight of MetRS was observed on SDS-PAGE of the final product, which was concentrated by lyophilizing after dialysis against water. Using serum albumin as an inhibitor of adhesion of L5 to the microconcentrators which was used to concentrate the final product, a distinct L5 band was detected on SDS-PAGE, the intensity of which was comparable to that of the MetRS band. Northern blot analysis of RNA prepared from the tRNA-Sepharose fraction showed the presence of 5SrRNA. Dot blot analysis using an antibody against ribosomal protein L5 showed that L5 was present in the Superdex200 fractions prepared by both methods. The MetRS specific activities in MetRS complex fractions incubated without tRNA increased during the purification procedures, indicating that endogeneous tRNA(met) exists stably in the MetRS complex. 5SRNP and 5SrRNA markedly enhanced the MetRS activity in the MetRS complex, indicating that 5SRNP(A) plays a role as a positive effector of MetRS.
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PMID:Further study on association of 5SrRNA-L5 protein complex and methionyl-tRNA to methionyl-tRNA synthetase in the macromolecular aminoacyl-tRNA synthetase complex. 898 50

Amino acid selection by aminoacyl-tRNA synthetases requires efficient mechanisms to avoid incorrect charging of the cognate tRNAs. A proofreading mechanism prevents Escherichia coli methionyl-tRNA synthetase (EcMet-RS) from activating in vivo L-homocysteine, a natural competitor of L-methionine recognised by the enzyme. The crystal structure of the complex between EcMet-RS and L-methionine solved at 1.8 A resolution exhibits some conspicuous differences with the recently published free enzyme structure. Thus, the methionine delta-sulphur atom replaces a water molecule H-bonded to Leu13N and Tyr260O(eta) in the free enzyme. Rearrangements of aromatic residues enable the protein to form a hydrophobic pocket around the ligand side-chain. The subsequent formation of an extended water molecule network contributes to relative displacements, up to 3 A, of several domains of the protein. The structure of this complex supports a plausible mechanism for the selection of L-methionine versus L-homocysteine and suggests the possibility of information transfer between the different functional domains of the enzyme.
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PMID:How methionyl-tRNA synthetase creates its amino acid recognition pocket upon L-methionine binding. 1124 94

Mimivirus, a DNA virus infecting acanthamoeba, was for a long time the largest known virus both in terms of particle size and gene content. Its genome encodes 979 proteins, including the first four aminoacyl tRNA synthetases (ArgRS, CysRS, MetRS, and TyrRS) ever found outside of cellular organisms. The discovery that Mimivirus encoded trademark cellular functions prompted a wealth of theoretical studies revisiting the concept of virus and associated large DNA viruses with the emergence of early eukaryotes. However, the evolutionary significance of these unique features remained impossible to assess in absence of a Mimivirus relative exhibiting a suitable evolutionary divergence. Here, we present Megavirus chilensis, a giant virus isolated off the coast of Chile, but capable of replicating in fresh water acanthamoeba. Its 1,259,197-bp genome is the largest viral genome fully sequenced so far. It encodes 1,120 putative proteins, of which 258 (23%) have no Mimivirus homologs. The 594 Megavirus/Mimivirus orthologs share an average of 50% of identical residues. Despite this divergence, Megavirus retained all of the genomic features characteristic of Mimivirus, including its cellular-like genes. Moreover, Megavirus exhibits three additional aminoacyl-tRNA synthetase genes (IleRS, TrpRS, and AsnRS) adding strong support to the previous suggestion that the Mimivirus/Megavirus lineage evolved from an ancestral cellular genome by reductive evolution. The main differences in gene content between Mimivirus and Megavirus genomes are due to (i) lineages specific gains or losses of genes, (ii) lineage specific gene family expansion or deletion, and (iii) the insertion/migration of mobile elements (intron, intein).
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PMID:Distant Mimivirus relative with a larger genome highlights the fundamental features of Megaviridae. 2198 20

We recently described Megavirus chilensis, a giant virus isolated off the coast of Chile, also replicating in fresh water acanthamoeba. Its 1,259,197-bp genome encodes 1,120 proteins and is the largest known viral genome. Megavirus and its closest relative Mimivirus only share 594 orthologous genes, themselves sharing only 50% of identical residues in average. Despite this divergence, comparable to the maximal divergence exhibited by bacteria within the same division (e.g., gamma proteobacteria), Megavirus retained all of the genomic features unique to Mimivirus, in particular its genes encoding key-elements of the translation apparatus, a trademark of cellular organisms. Besides homologs to the four aminoacyl-tRNA synthetases (aaRS) encoded by Mimivirus, Megavirus added three additional ones, raising the total of known virus-encoded aaRS to seven: IleRS, TrpRS, AsnRS, ArgRS, CysRS, MetRS, TyrRS. This finding strongly suggests that large DNA viruses derived from an ancestral cellular genome by reductive evolution. The nature of this cellular ancestor remains hotly debated.
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PMID:Genomics of Megavirus and the elusive fourth domain of Life. 2248 24