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Query: EC:6.1.1.11 (seryl-tRNA synthetase)
 207 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Monospecific polyclonal antibodies (pAbs) against highly purified bovine seryl-tRNA synthetase (SerRS, EC 6.1.1.1) were prepared and their specificity tested. The interactions of pAbs with SerRS from different organisms were investigated by protein immunoblotting and ELISA methods. pAbs inhibit eukaryotic SerRS aminoacylating activity and exert no effect on SerRS activity from prokaryotes. It is proposed that prokaryotic and eukaryotic SerRS evolve from different ancestor genes.
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PMID:Immuno-chemical non-cross-reactivity between eukaryotic and prokaryotic seryl-tRNA synthetases. 195 33

The aminoacyl-transfer RNA synthetases (aaRS) catalyse the attachment of an amino acid to its cognate transfer RNA molecule in a highly specific two-step reaction. These proteins differ widely in size and oligomeric state, and have limited sequence homology. Out of the 18 known aaRS, only 9 referred to as class I synthetases (GlnRS, TyrRS, MetRS, GluRS, ArgRS, ValRS, IleRS, LeuRS, TrpRS), display two short common consensus sequences ('HIGH' and 'KMSKS') which indicate, as observed in three crystal structures, the presence of a structural domain (the Rossman fold) that binds ATP. We report here the sequence of Escherichia coli ProRS, a dimer of relative molecular mass 127,402, which is homologous to both ThrRS and SerRS. These three latter aaRS share three new sequence motifs with AspRS, AsnRS, LysRS, HisRS and the beta subunit of PheRS. These three motifs (motifs 1, 2 and 3), in a search through the entire data bank, proved to be specific for this set of aaRS (referred to as class II). Class II may also contain AlaRS and GlyRS, because these sequences have a typical motif 3. Surprisingly, this partition of aaRS in two classes is found to be strongly correlated on the functional level with the acylation occurring either on the 2' OH (class I) or 3' OH (class II) of the ribose of the last nucleotide of tRNA.
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PMID:Partition of tRNA synthetases into two classes based on mutually exclusive sets of sequence motifs. 220 71

Seryl-tRNA synthetase is the gene product of the serS locus in Escherichia coli. Its gene has been cloned by complementation of a serS temperature sensitive mutant K28 with an E. coli gene bank DNA. The resulting clones overexpress seryl-tRNA synthetase by a factor greater than 50 and more than 6% of the total cellular protein corresponds to the enzyme. The DNA sequence of the complete coding region and the 5'- and 3' untranslated regions was determined. Protein sequence comparison of SerRS with all available aminoacyl-tRNA synthetase sequences revealed some regions of significant homology particularly with the isoleucyl- and phenylalanyl-tRNA synthetases from E. coli.
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PMID:Cloning and characterization of the gene for Escherichia coli seryl-tRNA synthetase. 302 94

Study by chemical modification of Ser, Arg, His residues and sulfhydryl groups on bovine seryl-tRNA synthetase showed that Ser residues appeared to be unnecessary for the recognition mechanism, but Arg and His residues were essential. It was considered that different sulfhydryl groups related with each recognition of tRNA and ATP. Poly-arginine inhibited the interaction between serine tRNA and SerRS. The CD spectra of a mixture of serine tRNA and poly-arginine indicated that higher-order structure of tRNA changed. Furthermore, the Km and Vmax values of bovine serine isoacceptor, yeast serine tRNA and E. coli serine tRNA for bovine SerRS examined and it was discussed the differences of those base sequences.
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PMID:A study of the interaction between tRNASer and seryl-tRNA synthetase from bovine liver. 385 79

The crystal structure at 2.6 A of the histidyl-tRNA synthetase from Escherichia coli complexed with histidyl-adenylate has been determined. The enzyme is a homodimer with a molecular weight of 94 kDa and belongs to the class II of aminoacyl-tRNA synthetases (aaRS). The asymmetric unit is composed of two homodimers. Each monomer consists of two domains. The N-terminal catalytic core domain contains a six-stranded antiparallel beta-sheet sitting on two alpha-helices, which can be superposed with the catalytic domains of yeast AspRS, and GlyRS and SerRS from Thermus thermophilus with a root-mean-square difference on the C alpha atoms of 1.7-1.9 A. The active sites of all four monomers are occupied by histidyl-adenylate, which apparently forms during crystallization. The 100 residue C-terminal alpha/beta domain resembles half of a beta-barrel, and provides an independent domain oriented to contact the anticodon stem and part of the anticodon loop of tRNA(His). The modular domain organization of histidyl-tRNA synthetase reiterates a repeated theme in aaRS, and its structure should provide insight into the ability of certain aaRS to aminoacylate minihelices and other non-tRNA molecules.
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PMID:Crystal structure of histidyl-tRNA synthetase from Escherichia coli complexed with histidyl-adenylate. 755 55

Phenylalanyl-tRNA synthetase from Thermus thermophilus has an alpha 2 beta 2 type quaternary structure and is one of the most complicated members of the synthetase family. Identification of PheRSTT as a member of class II aaRSs was based only on sequence alignment of the small alpha-subunit with other synthetases. The three-dimensional crystal structure of the catalytic and 'catalytic-like' domains at 2.9 A resolution in PheRSTT is described. The alpha-subunit contains an antiparallel fold which includes signature motifs 1, 2 and 3, characteristic of class II synthetases. One of the three structural domains of the beta-subunit (alpha'-domain) is formed by a seven-stranded antiparallel beta-sheet surrounded by alpha-helices similar to catalytic domains in SerRS, AspRS and the alpha-subunit of PheRSTT. The alpha beta heterodimer (alpha and alpha') exhibits essentially the same topology in the intersubunit region as in the known alpha 2 structures of class II aaRS's. The multimerization area of whole PheRSTT molecule comprises a quasi-tetrahedral four-helix bundle.
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PMID:Phenylalanyl-tRNA synthetase from Thermus thermophilus has four antiparallel folds of which only two are catalytically functional. 819 44

Aminoacyl-RNA synthetases can be divided into two classes according to structural features inferred from sequence alignments. This classification correlates almost perfectly with the attachment of the amino acid to the 2'-OH (class I) or 3'-OH (class II) group of the terminal adenosine. Six subgroups of higher homology can be inferred from sequence analysis. The five aminoacyl-tRNA synthetases whose crystal structures are known (MetRS, TyrRS and GlnRS in class I, SerRS and AspRS in class II) belong to different subgroups. Two of them, GlnRS and AspRS, have been cocrystallized with their cognate tRNA. AspRS, like six other members of class II, is an alpha 2 dimer. Yeast tRNA(Asp) exhibits five identity determinants: the three anticodon bases, the discriminator base G73 and the base pair G10-U25. We report here that the refined crystal structure of AspRS complexed with tRNA(Asp) at 2.9 A resolution reveals three regions of contact, each involving a domain of AspRS and at least one identity determinant of tRNA(Asp). The mode of binding of the acceptor stem of tRNA(Asp) by AspRS can be generalized to class II aminoacyl-tRNA synthetases, whereas the deciphering of the anticodon, which involves a large conformational change of the loop and the formation of a bulge, is more specific to the aspartic system.
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PMID:Yeast tRNA(Asp) recognition by its cognate class II aminoacyl-tRNA synthetase. 845 Aug 89

A mutation in the structural gene coding for seryl-tRNA synthetase in temperature-sensitive Escherichia coli K28 has been reported to alter the level of enzyme expression at high temperature (R. J. Hill and W. Konigsberg, J. Bacteriol. 141:1163-1169, 1980). We identified this mutation as a C-->T transition in the first base of codon 386, resulting in a replacement of histidine by tyrosine. The steady-state levels of serS mRNA in K28 and in the wild-type strains are very similar. Pulse-chase labeling experiments show a difference in protein stability, but not one important enough to account for the temperature sensitivity of K28. The main reason for the temperature sensitivity of K28 appears to be the low level of specific activity of the mutant synthetase at nonpermissive temperature, not a decreased expression level. Spontaneous temperature-resistant revertants were selected which were found to have about a fivefold-higher level of SerRS than the K28 strain. We identified the mutation responsible for the reversion as being upstream from the -10 sequence in the promoter region. The steady-state levels of serS mRNA in the revertants are significantly higher than that in the parental strain.
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PMID:Characterization of a temperature-sensitive Escherichia coli mutant and revertants with altered seryl-tRNA synthetase activity. 907 36

Lysyl-tRNA synthetase, a class II enzyme, edits homocysteine by converting it into homocysteine thiolactone. In a similar reaction, the enzyme converts homoserine into homoserine lactone. Other class II enzymes, aspartyl-tRNA synthetase and seryl-tRNA synthetase, do not edit any of the amino acids tested. However, all three class II aminoacyl-tRNA synthetases catalyze AMP- and pyrophosphate-independent deacylation of cognate aminoacyl-tRNA in the presence of thiols, mimicking editing of homocysteine. Thiol-dependent deacylations exhibit saturation kinetics with respect to concentration of thiols, suggesting the presence of a thiol binding site on each enzyme. 3-Mercaptopropionate-, N-acetyl-L-cysteine-, and dithiothreitol-dependent deacylations of aminoacyl-tRNA yield corresponding aminoacyl thioesters. Cysteine-dependent enzymatic deacylations of aminoacyl-tRNA by these class II enzymes yield dipeptides, N-(aminoacyl)cysteine. The formation of N-(aminoacyl)cysteine involves thioester intermediates S-(aminoacyl)-L-cysteine, which are not observed because of the facile transacylation of the aminoacyl residue from the sulfur to the alpha-amino group of cysteine to form a stable peptide bond. These data indicate that class II aminoacyl-tRNA synthetases possess unique thiol-binding subsites within their active sites. That the thiol-binding subsite exists also in AspRS and SerRS, which do not need editing function, suggests that these class II enzymes possess vestigial editing functions.
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PMID:Aminoacyl thioester chemistry of class II aminoacyl-tRNA synthetases. 928 50

Isoleucyl-tRNA synthetase (IleRS) catalyzes transfer of isoleucine from the enzyme-bound Ile-AMP and Ile-tRNA to the thiol group of coenzyme A, forming a thioester, Ile-S-CoA. Identity of Ile-S-CoA has been confirmed by several enzymatic and chemical tests. The synthesis of Ile-S-CoA, like the synthesis of other isoleucyl thioesters, is strongly shifted toward products. Other aminoacyl-tRNA synthetases, such as MetRS, AspRS, and SerRS also use CoA-SH as an acceptor for their cognate amino acids. Pantetheine also serves as an amino acid acceptor in reactions catalyzed by AspRS, IleRS, and MetRS, forming corresponding aminoacyl-S-pantetheine thioesters. It appears that CoA-SH reacts with activated amino acids by binding to each synthetase at a site, separate from the tRNA and ATP binding sites, that includes the thiol-binding subsite. These and other data support a hypothesis that the present-day aminoacyl-tRNA synthetases have originated from ancestral forms that were involved in noncoded thioester-dependent peptide synthesis, functionally similar to the present-day nonribosomal peptide synthesis by multi-enzyme thiotemplate systems.
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PMID:Aminoacylation of coenzyme A and pantetheine by aminoacyl-tRNA synthetases: possible link between noncoded and coded peptide synthesis. 954 45


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