Enzymes
UniProtKB help_outline | 56,672 proteins |
Enzyme class help_outline |
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- Name help_outline ATP Identifier CHEBI:30616 (Beilstein: 3581767) help_outline Charge -4 Formula C10H12N5O13P3 InChIKeyhelp_outline ZKHQWZAMYRWXGA-KQYNXXCUSA-J SMILEShelp_outline Nc1ncnc2n(cnc12)[C@@H]1O[C@H](COP([O-])(=O)OP([O-])(=O)OP([O-])([O-])=O)[C@@H](O)[C@H]1O 2D coordinates Mol file for the small molecule Search links Involved in 1,280 reaction(s) Find molecules that contain or resemble this structure Find proteins in UniProtKB for this molecule
- Name help_outline L-tyrosine Identifier CHEBI:58315 Charge 0 Formula C9H11NO3 InChIKeyhelp_outline OUYCCCASQSFEME-QMMMGPOBSA-N SMILEShelp_outline [NH3+][C@@H](Cc1ccc(O)cc1)C([O-])=O 2D coordinates Mol file for the small molecule Search links Involved in 53 reaction(s) Find molecules that contain or resemble this structure Find proteins in UniProtKB for this molecule
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Namehelp_outline
tRNATyr
Identifier
RHEA-COMP:9707
Reactive part
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- Name help_outline AMP 3'-end residue Identifier CHEBI:78442 Charge -1 Formula C10H12N5O6P SMILEShelp_outline Nc1ncnc2n(cnc12)[C@@H]1O[C@H](COP([O-])(-*)=O)[C@@H](O)[C@H]1O 2D coordinates Mol file for the small molecule Search links Involved in 76 reaction(s) Find molecules that contain or resemble this structure Find proteins in UniProtKB for this molecule
- Name help_outline AMP Identifier CHEBI:456215 Charge -2 Formula C10H12N5O7P InChIKeyhelp_outline UDMBCSSLTHHNCD-KQYNXXCUSA-L SMILEShelp_outline Nc1ncnc2n(cnc12)[C@@H]1O[C@H](COP([O-])([O-])=O)[C@@H](O)[C@H]1O 2D coordinates Mol file for the small molecule Search links Involved in 508 reaction(s) Find molecules that contain or resemble this structure Find proteins in UniProtKB for this molecule
- Name help_outline diphosphate Identifier CHEBI:33019 (Beilstein: 185088) help_outline Charge -3 Formula HO7P2 InChIKeyhelp_outline XPPKVPWEQAFLFU-UHFFFAOYSA-K SMILEShelp_outline OP([O-])(=O)OP([O-])([O-])=O 2D coordinates Mol file for the small molecule Search links Involved in 1,129 reaction(s) Find molecules that contain or resemble this structure Find proteins in UniProtKB for this molecule
- Name help_outline H+ Identifier CHEBI:15378 Charge 1 Formula H InChIKeyhelp_outline GPRLSGONYQIRFK-UHFFFAOYSA-N SMILEShelp_outline [H+] 2D coordinates Mol file for the small molecule Search links Involved in 9,431 reaction(s) Find molecules that contain or resemble this structure Find proteins in UniProtKB for this molecule
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Namehelp_outline
L-tyrosyl-tRNATyr
Identifier
RHEA-COMP:9706
Reactive part
help_outline
- Name help_outline 3'-(L-tyrosyl)adenylyl group Identifier CHEBI:78536 Charge -1 Formula C19H21N6O8P SMILEShelp_outline N[C@@H](Cc1ccc(O)cc1)C(=O)O[C@@H]1[C@@H](COP([O-])(-*)=O)O[C@H]([C@@H]1O)n1cnc2c(N)ncnc12 2D coordinates Mol file for the small molecule Search links Involved in 3 reaction(s) Find molecules that contain or resemble this structure Find proteins in UniProtKB for this molecule
Cross-references
RHEA:10220 | RHEA:10221 | RHEA:10222 | RHEA:10223 | |
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Reaction direction help_outline | undefined | left-to-right | right-to-left | bidirectional |
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Publications
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Demonstration of two tyrosyl-tRNA synthetases of pea roots.
Cowles J.R., Key J.L.
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Incorporation of amino acids into ribonucleic acid. I. The role of activating enzymes.
ALLEN E.H., GLASSMAN E., SCHWEET R.S.
J Biol Chem 235:1061-1067(1960) [PubMed] [EuropePMC]
This publication is cited by 4 other entries.
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Structure of tyrosyl-tRNA synthetase refined at 2.3-A resolution. Interaction of the enzyme with the tyrosyl adenylate intermediate.
Brick P., Bhat T.N., Blow D.M.
The crystal structure of tyrosyl-tRNA synthetase (EC 6.1.1.1) from Bacillus stearothermophilus has been refined to a crystallographic R-factor of 22.6% at 2.3 A resolution using a restrained least-squares procedure. In the final model the root-mean-square deviation from ideality for bond distances ... >> More
The crystal structure of tyrosyl-tRNA synthetase (EC 6.1.1.1) from Bacillus stearothermophilus has been refined to a crystallographic R-factor of 22.6% at 2.3 A resolution using a restrained least-squares procedure. In the final model the root-mean-square deviation from ideality for bond distances is 0.018 A and for angle distances is 0.044 A. Each monomer consists of three domains: an alpha/beta domain (residues 1 to 220) containing a six-stranded beta-sheet, an alpha-helical domain (248 to 318) containing five helices, and a disordered C-terminal domain (319 to 418) for which the electron density is very weak and where it has not been possible to trace the polypeptide chain. Complexes of the enzyme with the catalytic intermediate tyrosyl adenylate and the inhibitor tyrosinyl adenylate have also been refined to R-factors of 23.9% at 2.8 A resolution and 21.0% at 2.7 A resolution, respectively. Formation of the complexes results in some crystal cracking, but there is no significant difference in the conformation of the polypeptide chain of the three structures described here. The relative orientation of the alpha/beta and alpha-helical domains is similar to that previously observed for the "A" subunit of a deletion mutant lacking the C-terminal domain. Differences between these structures are confined to surface loops that are involved in crystal packing. Tyrosyl adenylate and tyrosinyl adenylate bind in similar conformations within a deep cleft in the alpha/beta domain. The tyrosine moiety is in the equivalent position to that occupied by tyrosine in crystals of the truncated mutant and makes similar strong polar interactions with the enzyme. The alpha-phosphate group interacts with the main-chain nitrogen of Asp38. The two hydroxyl groups of the ribose form strong interactions with the protein. The 2'-hydroxyl group interacts with the carboxylate of Asp194 and the main-chain nitrogen of Gly192 while the 3'-hydroxyl interacts with a tightly bound water molecule (Wat326). The adenine moiety appears to make no significant polar interactions with the protein. The results of site-directed mutagenesis studies are examined in the light of these refined structures. << Less
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Purification and properties of tyrosine-activating enzyme of hog pancreas.
SCHWEET R.S., ALLEN E.H.
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Crystal structure of human mitochondrial tyrosyl-tRNA synthetase reveals common and idiosyncratic features.
Bonnefond L., Frugier M., Touze E., Lorber B., Florentz C., Giege R., Sauter C., Rudinger-Thirion J.
We report the structure of a strictly mitochondrial human synthetase, namely tyrosyl-tRNA synthetase (mt-TyrRS), in complex with an adenylate analog at 2.2 A resolution. The structure is that of an active enzyme deprived of the C-terminal S4-like domain and resembles eubacterial TyrRSs with a cano ... >> More
We report the structure of a strictly mitochondrial human synthetase, namely tyrosyl-tRNA synthetase (mt-TyrRS), in complex with an adenylate analog at 2.2 A resolution. The structure is that of an active enzyme deprived of the C-terminal S4-like domain and resembles eubacterial TyrRSs with a canonical tyrosine-binding pocket and adenylate-binding residues typical of class I synthetases. Two bulges at the enzyme surface, not seen in eubacterial TyrRSs, correspond to conserved sequences in mt-TyrRSs. The synthetase electrostatic surface potential differs from that of other TyrRSs, including the human cytoplasmic homolog and the mitochondrial one from Neurospora crassa. The homodimeric human mt-TyrRS shows an asymmetry propagating from the dimer interface toward the two catalytic sites and extremities of each subunit. Mutagenesis of the catalytic domain reveals functional importance of Ser200 in line with an involvement of A73 rather than N1-N72 in tyrosine identity. << Less
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Partial purification of the threonine- and tyrosine-activating enzymes from rat liver, and the effect of patassium ions on the activity of the tyrosine enzyme.
HOLLEY R.W., BRUNNGRABER E.F., SAAD F., WILLIAMS H.H.
J Biol Chem 236:197-199(1961) [PubMed] [EuropePMC]
This publication is cited by 1 other entry.
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Toward the full set of human mitochondrial aminoacyl-tRNA synthetases: characterization of AspRS and TyrRS.
Bonnefond L., Fender A., Rudinger-Thirion J., Giege R., Florentz C., Sissler M.
The human mitochondrion possesses a translational machinery devoted to the synthesis of 13 proteins. While the required tRNAs and rRNAs are produced by transcription of the mitochondrial genome, all other factors needed for protein synthesis are synthesized in the cytosol and imported. This is the ... >> More
The human mitochondrion possesses a translational machinery devoted to the synthesis of 13 proteins. While the required tRNAs and rRNAs are produced by transcription of the mitochondrial genome, all other factors needed for protein synthesis are synthesized in the cytosol and imported. This is the case for aminoacyl-tRNA synthetases, the enzymes which esterify their cognate tRNA with the specific amino acid. The genes for the full set of cytosolic aaRSs are well defined, but only nine genes for mitochondrial synthetases are known. Here we describe the genes for human mitochondrial aspartyl- and tyrosyl-tRNA synthetases and the initial characterization of the enzymes. Both belong to the expected class of synthetases, have a dimeric organization, and aminoacylate Escherichia coli tRNAs as well as in vitro transcribed human mitochondrial tRNAs. Genes for the remaining missing synthetases were also found with the exception of glutaminyl-tRNA synthetase. Their sequence analysis confirms and further extends the view that, except for lysyl- and glycyl-tRNA synthetases, human mitochondrial and cytosolic enzymes are coded by two different sets of genes. << Less
Biochemistry 44:4805-4816(2005) [PubMed] [EuropePMC]
This publication is cited by 1 other entry.
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Aminoacyl-tRNA synthesis.
Ibba M., Soll D.
Aminoacyl-tRNAs are substrates for translation and are pivotal in determining how the genetic code is interpreted as amino acids. The function of aminoacyl-tRNA synthesis is to precisely match amino acids with tRNAs containing the corresponding anticodon. This is primarily achieved by the direct a ... >> More
Aminoacyl-tRNAs are substrates for translation and are pivotal in determining how the genetic code is interpreted as amino acids. The function of aminoacyl-tRNA synthesis is to precisely match amino acids with tRNAs containing the corresponding anticodon. This is primarily achieved by the direct attachment of an amino acid to the corresponding tRNA by an aminoacyl-tRNA synthetase, although intrinsic proofreading and extrinsic editing are also essential in several cases. Recent studies of aminoacyl-tRNA synthesis, mainly prompted by the advent of whole genome sequencing and the availability of a vast body of structural data, have led to an expanded and more detailed picture of how aminoacyl-tRNAs are synthesized. This article reviews current knowledge of the biochemical, structural, and evolutionary facets of aminoacyl-tRNA synthesis. << Less
Annu Rev Biochem 69:617-650(2000) [PubMed] [EuropePMC]
This publication is cited by 26 other entries.