Literature summary extracted from

Raina, M.; Moghal, A.; Kano, A.; Jerums, M.; Schnier, P.D.; Luo, S.; Deshpande, R.; Bondarenko, P.V.; Lin, H.; Ibba, M.
Reduced amino acid specificity of mammalian tyrosyl-tRNA synthetase is associated with elevated mistranslation of Tyr codons (2014), J. Biol. Chem., 289, 17780-17790 .

Cloned(Commentary)

EC Number	Cloned (Comment)	Organism
6.1.1.1	gene EGW00102, sequence comparisons, recombinant expression of codon-optimized His6-tagged enzyme in Escherichia coli strain BL21(DE3), recombinant expression of the enzyme ligated to a ribozyme for in vitro transcription by T7 polymerase	Cricetulus griseus

Protein Variants

EC Number	Protein Variants	Comment	Organism
6.1.1.1	A74G	site-directed mutagenesis, replacement of Ala74 with Gly increases the Km 7fold and has no effect on kcat for Tyr. The kcat/Km for Phe decreases 5fold	Cricetulus griseus
6.1.1.1	D122N	site-directed mutagenesis, mutant substrate specificity compared to the wild-type enzyme	Cricetulus griseus
6.1.1.1	G120N	site-directed mutagenesis, mutant substrate specificity compared to the wild-type enzyme	Cricetulus griseus
6.1.1.1	H77T	site-directed mutagenesis, mutation of His77 to the smaller nonhydrophobic Thr increases the Km and decreases the kcat by 40fold	Cricetulus griseus
6.1.1.1	L125W	site-directed mutagenesis, mutant substrate specificity compared to the wild-type enzyme	Cricetulus griseus
6.1.1.1	additional information	generation of a truncated mutant enzyme TyrRS	Cricetulus griseus
6.1.1.1	N82D	site-directed mutagenesis, mutant substrate specificity compared to the wild-type enzyme	Cricetulus griseus
6.1.1.1	W40C	site-directed mutagenesis, mutant substrate specificity compared to the wild-type enzyme	Cricetulus griseus
6.1.1.1	Y123W	site-directed mutagenesis, mutant substrate specificity compared to the wild-type enzyme	Cricetulus griseus
6.1.1.1	Y52H	site-directed mutagenesis, mutant substrate specificity compared to the wild-type enzyme	Cricetulus griseus

KM Value [mM]

EC Number	KM Value [mM]	KM Value Maximum [mM]	Substrate	Comment	Organism	Structure
6.1.1.1	additional information	-	additional information	Michaelis-Menten steady-state kinetics. Steady-state kinetic constants for ATP-[32P]PPi exchange for CHO cytosolic full length wild-type and variant TyrRS	Cricetulus griseus
6.1.1.1	0.146	-	L-tyrosine	recombinant wild-type enzyme, pH 7.8, 25°C	Cricetulus griseus
6.1.1.1	0.16	-	L-tyrosine	recombinant truncated mutant enzyme, pH 7.8, 25°C	Cricetulus griseus

Localization

EC Number	Localization	Comment	Organism	GeneOntology No.	Textmining
6.1.1.1	cytosol	-	Cricetulus griseus	5829	-

Metals/Ions

EC Number	Metals/Ions	Comment	Organism	Structure
6.1.1.1	Mg2+	required	Cricetulus griseus

Natural Substrates/ Products (Substrates)

EC Number	Natural Substrates	Organism	Comment (Nat. Sub.)	Natural Products	Comment (Nat. Pro.)	Rev.	Reac.
6.1.1.1	ATP + L-tyrosine + tRNATyr	Cricetulus griseus	-	AMP + diphosphate + L-tyrosyl-tRNATyr	-	?

Organism

EC Number	Organism	UniProt	Comment	Textmining
6.1.1.1	Cricetulus griseus	G3H935	-	-

Source Tissue

EC Number	Source Tissue	Comment	Organism	Textmining
6.1.1.1	CHO cell	-	Cricetulus griseus	-

Substrates and Products (Substrate)

EC Number	Substrates	Comment Substrates	Organism	Products	Comment (Products)	Rev.	Reac.
6.1.1.1	ATP + L-tyrosine + tRNATyr	-	Cricetulus griseus	AMP + diphosphate + L-tyrosyl-tRNATyr	-	?
6.1.1.1	ATP + L-tyrosine + tRNATyrGTA	two sequences, tRNATyr1 and tRNATyr2, substrate CHO tRNATyrGTA is recombinantly expressed. CHOTyrRS is able to attach Phe to both tRNATyr2 and CHO total tRNA containing native tRNATyr, excluding the possibility that mischarging results from the lack of post-transcriptional modifications to the in vitro-transcribed substrate	Cricetulus griseus	AMP + diphosphate + L-tyrosyl-tRNATyrGTA	-	?
6.1.1.1	additional information	the presence of the C-terminal EMAP II-domain has no effect on the recognition of cognate Tyr and discrimination against noncognate Phe	Cricetulus griseus	?	-	?

Synonyms

EC Number	Synonyms	Comment	Organism
6.1.1.1	CHOTyrRS	-	Cricetulus griseus
6.1.1.1	Tyrosyl-tRNA synthetase	-	Cricetulus griseus
6.1.1.1	TyrRS	-	Cricetulus griseus

Temperature Optimum [°C]

EC Number	Temperature Optimum [°C]	Temperature Optimum Maximum [°C]	Comment	Organism
6.1.1.1	25	37	aminoacylation assay at	Cricetulus griseus

Turnover Number [1/s]

EC Number	Turnover Number Minimum [1/s]	Turnover Number Maximum [1/s]	Substrate	Comment	Organism	Structure
6.1.1.1	12.5	-	L-tyrosine	recombinant wild-type enzyme, pH 7.8, 25°C	Cricetulus griseus
6.1.1.1	15	-	L-tyrosine	recombinant truncated mutant enzyme, pH 7.8, 25°C	Cricetulus griseus

pH Optimum

EC Number	pH Optimum Minimum	pH Optimum Maximum	Comment	Organism
6.1.1.1	7.8	-	aminoacylation assay at	Cricetulus griseus

Cofactor

EC Number	Cofactor	Comment	Organism	Structure
6.1.1.1	ATP	-	Cricetulus griseus

General Information

EC Number	General Information	Comment	Organism
6.1.1.1	evolution	mammalian TyrRS has evolved to be significantly less accurate than its bacterial counterpart. Different evolutionary constraints determine the accuracy of translation quality control in eukaryotes and bacteria. Functional comparisons of mammalian and bacterial tyrosyl-tRNA synthetase reveal key differences at residues responsible for amino acid recognition, highlighting differences in evolutionary constraints for translation quality control, overview	Cricetulus griseus
6.1.1.1	malfunction	reduced amino acid specificity of mammalian tyrosyl-tRNA synthetase is associated with elevated mistranslation of Tyr codons. Mischarging of tRNATyr with noncognate Phe by tyrosyl-tRNA synthetase is responsible for mistranslation. Steady-state kinetic analyses of CHO cytoplasmic tyrosyl-tRNA synthetase reveals a 25fold lower specificity for Tyr over Phe as compared with previously characterized bacterial enzymes, consistent with the observed increase in translation error rates during tyrosine limitation	Cricetulus griseus
6.1.1.1	additional information	residues, not conserved between bacteria and eukaryotes, Cys35, His48, Thr51, and Lys233 in bacterial TyrRS interact with ATP during transition state formation. Comparison the Geobacillus stearothermophilus, PDB ID 1tyd, and human, PDB ID 1q11, TyrRS active sites, overview. Hydrogen-bonding interactions between bacterial TyrRS residues Asp176 and Tyr34 and the substrate Tyr hydroxyl group help confer amino acid specificity to the enzyme	Cricetulus griseus
6.1.1.1	physiological function	aa-tRNA synthesis is a two-step reaction: activation of an amino acid with ATP to form aminoacyl adenylate, followed by transfer of the aminoacyl moiety to the 3' end of the tRNA. The error rate of this first step of translation is largely dependent on the specificity of the aaRS, that is selection of the correct amino acid and tRNA from the respective cellular pools of predominantly noncognate substrates. aaRSs select their cognate tRNAs by exploiting sequence-specific differences between various tRNAs during binding and aminoacylation. Translation of Tyr codons is highly prone to Phe isincorporation during amino acid limitation inCHOcells. CHO cell TyrRS is error-prone and readily aminoacylates tRNATyr with Phe, cf. EC 6.1.1.20. Steady-state kinetic analyses of CHO cytoplasmic tyrosyl-tRNA synthetase reveals a 25fold lower specificity for Tyr over Phe as compared with previously characterized bacterial enzymes, consistent with the observed increase in translation error rates during tyrosine limitation	Cricetulus griseus

kcat/KM [mM/s]

EC Number	kcat/KM Value [1/mMs^-1]	kcat/KM Value Maximum [1/mMs^-1]	Substrate	Comment	Organism	Structure
6.1.1.1	93.75	-	L-tyrosine	recombinant truncated mutant enzyme, pH 7.8, 25°C	Cricetulus griseus
6.1.1.1	856.16	-	L-tyrosine	recombinant wild-type enzyme, pH 7.8, 25°C	Cricetulus griseus

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Release 2023.1 (January 2023)