6emv Citations

Structural and biochemical analysis of the dual-specificity Trm10 enzyme from Thermococcus kodakaraensis prompts reconsideration of its catalytic mechanism.

Singh RK, Feller A, Roovers M, Van Elder D, Wauters L, Droogmans L, Versées W
RNA 24 1080-1092 (2018)
Related entries: 6ems, 6emt, 6emu

Cited: 11 times
EuropePMC logo PMID: 29848639

Abstract

tRNA molecules get heavily modified post-transcriptionally. The N-1 methylation of purines at position 9 of eukaryal and archaeal tRNA is catalyzed by the SPOUT methyltranferase Trm10. Remarkably, while certain Trm10 orthologs are specific for either guanosine or adenosine, others show a dual specificity. Structural and functional studies have been performed on guanosine- and adenosine-specific enzymes. Here we report the structure and biochemical analysis of the dual-specificity enzyme from Thermococcus kodakaraensis (TkTrm10). We report the first crystal structure of a construct of this enzyme, consisting of the N-terminal domain and the catalytic SPOUT domain. Moreover, crystal structures of the SPOUT domain, either in the apo form or bound to S-adenosyl-l-methionine or S-adenosyl-l-homocysteine reveal the conformational plasticity of two active site loops upon substrate binding. Kinetic analysis shows that TkTrm10 has a high affinity for its tRNA substrates, while the enzyme on its own has a very low methyltransferase activity. Mutation of either of two active site aspartate residues (Asp206 and Asp245) to Asn or Ala results in only modest effects on the N-1 methylation reaction, with a small shift toward a preference for m1G formation over m1A formation. Only a double D206A/D245A mutation severely impairs activity. These results are in line with the recent finding that the single active-site aspartate was dispensable for activity in the guanosine-specific Trm10 from yeast, and suggest that also dual-specificity Trm10 orthologs use a noncanonical tRNA methyltransferase mechanism without residues acting as general base catalysts.

Articles - 6emv mentioned but not cited (1)

  1. Insights into Catalytic and tRNA Recognition Mechanism of the Dual-Specific tRNA Methyltransferase from Thermococcus kodakarensis. Krishnamohan A, Dodbele S, Jackman JE. Genes (Basel) 10 (2019)


Reviews citing this publication (5)

  1. Transfer RNA Modification Enzymes from Thermophiles and Their Modified Nucleosides in tRNA. Hori H, Kawamura T, Awai T, Ochi A, Yamagami R, Tomikawa C, Hirata A. Microorganisms 6 (2018)
  2. An overview of 25 years of research on Thermococcus kodakarensis, a genetically versatile model organism for archaeal research. Rashid N, Aslam M. Folia Microbiol (Praha) 65 67-78 (2020)
  3. The life and times of a tRNA. Phizicky EM, Hopper AK. RNA 29 898-957 (2023)
  4. Investigations of Single-Subunit tRNA Methyltransferases from Yeast. Wang Z, Xu X, Li X, Fang J, Huang Z, Zhang M, Liu J, Qiu X. J Fungi (Basel) 9 1030 (2023)
  5. Tied up in knots: Untangling substrate recognition by the SPOUT methyltransferases. Strassler SE, Bowles IE, Dey D, Jackman JE, Conn GL. J Biol Chem 298 102393 (2022)

Articles citing this publication (5)

  1. Structural basis of RNA processing by human mitochondrial RNase P. Bhatta A, Dienemann C, Cramer P, Hillen HS. Nat Struct Mol Biol 28 713-723 (2021)
  2. A Family Divided: Distinct Structural and Mechanistic Features of the SpoU-TrmD (SPOUT) Methyltransferase Superfamily. Krishnamohan A, Jackman JE. Biochemistry 58 336-345 (2019)
  3. Distinct substrate specificities of the human tRNA methyltransferases TRMT10A and TRMT10B. Howell NW, Jora M, Jepson BF, Limbach PA, Jackman JE. RNA 25 1366-1376 (2019)
  4. Structural characterization of B. subtilis m1A22 tRNA methyltransferase TrmK: insights into tRNA recognition. Dégut C, Roovers M, Barraud P, Brachet F, Feller A, Larue V, Al Refaii A, Caillet J, Droogmans L, Tisné C. Nucleic Acids Res. 47 4736-4750 (2019)
  5. The Bacillus subtilis open reading frame ysgA encodes the SPOUT methyltransferase RlmP forming 2'-O-methylguanosine at position 2553 in the A-loop of 23S rRNA. Roovers M, Labar G, Wolff P, Feller A, Van Elder D, Soin R, Gueydan C, Kruys V, Droogmans L. RNA 28 1185-1196 (2022)


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