Literature DB >> 7540217

Structure, function and evolution of seryl-tRNA synthetases: implications for the evolution of aminoacyl-tRNA synthetases and the genetic code.

M Härtlein1, S Cusack.   

Abstract

Two aspects of the evolution of aminoacyl-tRNA synthetases are discussed. Firstly, using recent crystal structure information on seryl-tRNA synthetase and its substrate complexes, the coevolution of the mode of recognition between seryl-tRNA synthetase and tRNA(ser) in different organisms is reviewed. Secondly, using sequence alignments and phylogenetic trees, the early evolution of class 2 aminoacyl-tRNA synthetases is traced. Arguments are presented to suggest that synthetases are not the oldest of protein enzymes, but survived as RNA enzymes during the early period of the evolution of protein catalysts. In this view, the relatedness of the current synthetases, as evidenced by the division into two classes with their associated subclasses, reflects the replacement of RNA synthetases by protein synthetases. This process would have been triggered by the acquisition of tRNA 3' end charging activity by early proteins capable of activating small molecules (e.g., amino acids) with ATP. If these arguments are correct, the genetic code was essentially frozen before the protein synthetases that we know today came into existence.

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Year:  1995        PMID: 7540217     DOI: 10.1007/bf00166620

Source DB:  PubMed          Journal:  J Mol Evol        ISSN: 0022-2844            Impact factor:   2.395


  66 in total

1.  A second class of synthetase structure revealed by X-ray analysis of Escherichia coli seryl-tRNA synthetase at 2.5 A.

Authors:  S Cusack; C Berthet-Colominas; M Härtlein; N Nassar; R Leberman
Journal:  Nature       Date:  1990-09-20       Impact factor: 49.962

2.  Unusual resistance of peptidyl transferase to protein extraction procedures.

Authors:  H F Noller; V Hoffarth; L Zimniak
Journal:  Science       Date:  1992-06-05       Impact factor: 47.728

3.  Genetic code development by stop codon takeover.

Authors:  N Lehman; T H Jukes
Journal:  J Theor Biol       Date:  1988-11-21       Impact factor: 2.691

4.  Phenylalanyl-tRNA synthetase from Thermus thermophilus has four antiparallel folds of which only two are catalytically functional.

Authors:  L Mosyak; M Safro
Journal:  Biochimie       Date:  1993       Impact factor: 4.079

5.  Yeast seryl-tRNA synthetase expressed in Escherichia coli recognizes bacterial serine-specific tRNAs in vivo.

Authors:  I Weygand-Durasević; N Ban; D Jahn; D Söll
Journal:  Eur J Biochem       Date:  1993-06-15

6.  Contributions of discrete tRNA(Ser) domains to aminoacylation by E.coli seryl-tRNA synthetase: a kinetic analysis using model RNA substrates.

Authors:  J R Sampson; M E Saks
Journal:  Nucleic Acids Res       Date:  1993-09-25       Impact factor: 16.971

7.  The long extra arms of human tRNA((Ser)Sec) and tRNA(Ser) function as major identify elements for serylation in an orientation-dependent, but not sequence-specific manner.

Authors:  X Q Wu; H J Gross
Journal:  Nucleic Acids Res       Date:  1993-12-11       Impact factor: 16.971

8.  The crystal structure of the lysyl-tRNA synthetase (LysU) from Escherichia coli.

Authors:  S Onesti; A D Miller; P Brick
Journal:  Structure       Date:  1995-02-15       Impact factor: 5.006

9.  Seryl-tRNA synthetase from Escherichia coli: implication of its N-terminal domain in aminoacylation activity and specificity.

Authors:  F Borel; C Vincent; R Leberman; M Härtlein
Journal:  Nucleic Acids Res       Date:  1994-08-11       Impact factor: 16.971

10.  Specificity of arginine binding by the Tetrahymena intron.

Authors:  M Yarus
Journal:  Biochemistry       Date:  1989-02-07       Impact factor: 3.162
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  14 in total

1.  On the classes of aminoacyl-tRNA synthetases, amino acids and the genetic code.

Authors:  Andre R O Cavalcanti; Elisa Soares Leite; Benício B Neto; Ricardo Ferreira
Journal:  Orig Life Evol Biosph       Date:  2004-08       Impact factor: 1.950

2.  The crystal structure of the ternary complex of T.thermophilus seryl-tRNA synthetase with tRNA(Ser) and a seryl-adenylate analogue reveals a conformational switch in the active site.

Authors:  S Cusack; A Yaremchuk; M Tukalo
Journal:  EMBO J       Date:  1996-06-03       Impact factor: 11.598

3.  Aminoacylating urzymes challenge the RNA world hypothesis.

Authors:  Li Li; Christopher Francklyn; Charles W Carter
Journal:  J Biol Chem       Date:  2013-07-18       Impact factor: 5.157

4.  Signature of a primitive genetic code in ancient protein lineages.

Authors:  Gregory P Fournier; J Peter Gogarten
Journal:  J Mol Evol       Date:  2007-10-06       Impact factor: 2.395

5.  Translocation events in the evolution of aminoacyl-tRNA synthetases.

Authors:  S Brenner; L M Corrochano
Journal:  Proc Natl Acad Sci U S A       Date:  1996-08-06       Impact factor: 11.205

6.  Functional Class I and II Amino Acid-activating Enzymes Can Be Coded by Opposite Strands of the Same Gene.

Authors:  Luis Martinez-Rodriguez; Ozgün Erdogan; Mariel Jimenez-Rodriguez; Katiria Gonzalez-Rivera; Tishan Williams; Li Li; Violetta Weinreb; Martha Collier; Srinivas Niranj Chandrasekaran; Xavier Ambroggio; Brian Kuhlman; Charles W Carter
Journal:  J Biol Chem       Date:  2015-06-18       Impact factor: 5.157

Review 7.  Coding of Class I and II Aminoacyl-tRNA Synthetases.

Authors:  Charles W Carter
Journal:  Adv Exp Med Biol       Date:  2017       Impact factor: 2.622

Review 8.  Partition of aminoacyl-tRNA synthetases in two different structural classes dating back to early metabolism: implications for the origin of the genetic code and the nature of protein sequences.

Authors:  M Delarue
Journal:  J Mol Evol       Date:  1995-12       Impact factor: 2.395

9.  Ancestral Reconstruction of a Pre-LUCA Aminoacyl-tRNA Synthetase Ancestor Supports the Late Addition of Trp to the Genetic Code.

Authors:  G P Fournier; E J Alm
Journal:  J Mol Evol       Date:  2015-03-20       Impact factor: 2.395

10.  Maize mitochondrial seryl-tRNA synthetase recognizes Escherichia coli tRNA(Ser) in vivo and in vitro.

Authors:  J Rokov; D Söll; I Weygand-Durasević
Journal:  Plant Mol Biol       Date:  1998-10       Impact factor: 4.076
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