Modomics - A Database of RNA Modifications

ID Card:

Full name: tRNA (guanine(37)-N1)-methyltransferase Trm5b
GI: 14520947
Orf: PAB0505
COG: COG2520
UniProt: Q9V0Q0
Structures: | 5YAC |
Alpha Fold Predicted Structure: AF-Q9V0Q0-F1
Enzyme type: methyltransferase
Position of modification - modification: t:37 - yW-72


PDB Structures:


5YAC

Structure Description:

Title:
Classification:
Technique:

Abstract of the PDB Structure's related Publication:

The wyosine hypermodification found exclusively at G37 of tRNA Phe in eukaryotes and archaea is a very complicated process involving multiple steps and enzymes, and the derivatives are essential for the maintenance of the reading frame during translation. In the archaea Pyrococcus abyssi, two key enzymes from the Trm5 family, named PaTrm5a and PaTrm5b respectively, start the process by forming N1-methylated guanosine (m 1 G37). In addition, PaTrm5a catalyzes the further methylation of C7 on 4-demethylwyosine (imG-14) to produce isowyosine (imG2) at the same position. The structural basis of the distinct methylation capacities and possible conformational changes during catalysis displayed by the Trm5 enzymes are poorly studied. Here we report the 3.3 Å crystal structure of the mono-functional PaTrm5b, which shares 32% sequence identity with PaTrm5a. Interestingly, structural superposition reveals that the PaTrm5b protein exhibits an extended conformation similar to that of tRNA-bound Trm5b from Methanococcus jannaschii (MjTrm5b), but quite different from the open conformation of apo-PaTrm5a or well folded apo-MjTrm5b reported previously. Truncation of the N-terminal D1 domain leads to reduced tRNA binding as well as the methyltransfer activity of PaTrm5b. The differential positioning of the D1 domains from three reported Trm5 structures were rationalized, which could be attributable to the dissimilar inter-domain interactions and crystal packing patterns. This study expands our understanding on the methylation mechanism of the Trm5 enzymes and wyosine hypermodification.

Download RCSB-PDB Structures:

Pdb Files   5YAC.pdb  
Pdbx/mmCIF Files   5YAC.cif  


Protein sequence:

MTLAVKVPLKEGEIVRRRLIELGALDNTYKIKREGNFLLIPVKFPVKGFEVVEAELEQVSRRPNSYREIVNVPQELRRFLPTSFDIIGNIAIIEIPEELKGYAKEIGRAIVEVHKNVKAVYMKGSKIEGEYRTRELIHIAGENITETIHRENGIRLKLDVAKVYFSPRLATERMRVFKMAQEGEVVFDMFAGVGPFSILLAKKAELVFACDINPWAIKYLEENIKLNKVNNVVPILGDSREIEVKADRIIMNLPKYAHEFLEHAISCINDGGVIHYYGFGPEGDPYGWHLERIRELANKFGVKVEVLGKRVIRNYAPRQYNIAIDFRVSF

Comments:

In P. abyssi two paralogs capable of forming m1G37 are present: Trm5b and Taw22 (Trm5a, a bifunctional enzyme).




Reaction Substrate SubstrateType Position (Anti)Codon Modified (Anti)Codon Amino Acid Change Transcript Name Transcript Region Cellular Localization References
G:m1G tRNA (t) 37 20382657   

Alpha Fold Predicted Structure:






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Protein sequence:

M T L A V K V P L K E G E I V R R R L I E L G A L D N T Y K I K R E G N F L L I P V K F P V K G F E V V E A E L E Q V S R R P N S Y R E I V N V P Q E L R R F L P T S F D I I G N I A I I E I P E E L K G Y A K E I G R A I V E V H K N V K A V Y M K G S K I E G E Y R T R E L I H I A G E N I T E T I H R E N G I R L K L D V A K V Y F S P R L A T E R M R V F K M A Q E G E V V F D M F A G V G P F S I L L A K K A E L V F A C D I N P W A I K Y L E E N I K L N K V N N V V P I L G D S R E I E V K A D R I I M N L P K Y A H E F L E H A I S C I N D G G V I H Y Y G F G P E G D P Y G W H L E R I R E L A N K F G V K V E V L G K R V I R N Y A P R Q Y N I A I D F R V S F

Secondary Structure Alphabet

  • G: 3-turn helix (310helix)
  • H: α-helix
  • I: 𝝅-helix (5 - turn helix)
  • T: Hydrogen Bonded Turn
  • B: β-sheet
  • S: Bend
  • C: Coil (residues not present in any of the above conformations)
  • N: Not assigned

Download PDB Structures & DSSP Secondary Structures:

Alpha Fold Pdb Files   AF-Q9V0Q0-F1.pdb  
Alpha Fold Pdbx/mmCIF Files   AF-Q9V0Q0-F1.cif  
DSSP Secondary Structures   Q9V0Q0.dssp  





Publications:

Title Authors Journal Details PubMed Id DOI
Biosynthesis of wyosine derivatives in tRNA: an ancient and highly diverse pathway in Archaea. de Crecy-Lagard V, Brochier-Armanet C, Urbonavicius J, Fernandez B, Phillips G, Lyons B, Noma A, Alvarez S, Droogmans L, Armengaud J, Grosjean H Mol Biol Evol [details] 20382657 -