The effect of queuosine on tRNA structure and function - PubMed (original) (raw)
The effect of queuosine on tRNA structure and function
R C Morris et al. J Biomol Struct Dyn. 1999 Feb.
Abstract
Computational modeling was performed to determine the potential function of the queuosine modification of tRNA found in wobble position 34 of tRNAasp, tRNAasn, tRNAhis, and tRNAtyr. Using the crystal structure of tRNAasp and a tRNA-tRNA-mRNA complex model, we show that the queuosine modification serves as a structurally restrictive base for tRNA anticodon loop flexibility. An extended intraresidue and intramolecular hydrogen bonding network is established by queuosine. The quaternary amine of the 7-aminomethyl side chain hydrogen bonds with the base's carbonyl oxygen. This positions the dihydroxycyclopentenediol ring of queuosine in proper orientation for hydrogen bonding with the backbone of the neighboring uridine 33 residue. The interresidue association stabilizes the formation of a cross-loop hydrogen bond between the uridine 33 base and the phosphoribosyl backbone of the cytosine at position 36. Additional interactions between RNAs in the translation complex were studied with regard to potential codon context and codon bias effects. Neither steric nor electrostatic interaction occurs between aminoacyl- and peptidyl-site tRNA anticodon loops that are modified with queuosine. However, there is a difference in the strength of anticodon/codon associations (codon bias) based on the presence or lack of queuosine in the wobble position of the tRNA. Unmodified (guanosine-containing) tRNAasp forms a very stable association with cytosine (GAC), but is much less stable in complex with a uridine-containing codon (GAU). Queuosine-modified tRNAasp exhibits no bias for either of cognate codons GAC or GAU and demonstrates a lower binding energy similar to the wobble pairing of guanosine-containing tRNA with a GAU codon. This is proposed to be due to the inflexibility of the queuosine-modified anticodon loop to accommodate proper positioning for optimal Watson-Crick type associations. A preliminary survey of codon usage patterns in oncodevelopmental versus housekeeping gene transcripts suggests a significant difference in bias for the queuosine-associated codons. Therefore, the queuosine modification may have the potential to influence cellular growth and differentiation by codon bias-based regulation of protein synthesis for discrete mRNA transcripts.