AbstractsBiology & Animal Science

Methylation of tRNA plays important roles in the stabilisation of tRNAs and accurate protein synthesis in cells. In eukaryotes various tRNA methyltransferases exist, among them DNMT2 which methylates tRNAAsp at position C38 in the anticodon loop. It is also called tRNA-aspartate methyltransferase 1 (Trdmt1) and the enzyme is highly conserved among eukaryotes. In this work, I investigated the mechanism of DNMT2 interaction with tRNAAsp, characterised the function of the only prokaryotic Dnmt2 homolog found in G. sulfurreducens and studied the physiological importance of the C38 methylation of tRNAAsp in mammalian cells. The molecular details of the interaction of DNMT2 and tRNAAsp are unknown due to lack of the co-crystal structure. Here, I characterised the important residues in DNMT2 required for the tRNA binding and catalysis. By site-directed mutagenesis of 20 conserved lysine and arginine residues in DNMT2, I show that 8 of them have a strong effect on the catalytic activity of the enzyme. They map to one side of the enzyme where the catalytic pocket of DNMT2 is located. The binding of most of the mutant enzymes to tRNA was unaffected suggesting a role of these residues in transition state stabilisation. Manual docking of tRNAAsp into the surface cleft decorated by the 8 residues suggested that DNMT2 interacts mainly with the anticodon stem/loop of tRNAAsp. In my second project, I characterised the function of Dnmt2 homolog found in G. sulfurreducens (GsDnmt2). Here, I show that GsDnmt2 methylates tRNAGlu more efficiently than tRNAAsp. I also report the molecular basis for the swapped substrate specificity of GsDnmt2 and show that the variable loops of G.sulfurreducens tRNAAsp and tRNAGlu of eukaryotes contain a -GG- dinucleotide which is not preferred by Dnmt2. Exchange of the variable loop of mouse tRNAAsp to that tRNAGlu led to dramatic decrease in the activity of human DNMT2. This identifies the variable loop of tRNA as a specificity determinant in the recognition by Dnmt2. In my final project, I investigated the physiological importance of the tRNAAsp C38 methylation in aminoacylation and cellular protein synthesis. Here, I report that C38 methylation enhances the rate of aspartylation on tRNAAsp by 4-5 folds. Concomitant with this, a decrease in the charging levels of tRNAAsp was observed in Dnmt2 knockout MEF cells, which also showed a reduced efficiency in the synthesis of proteins containing poly-Asp sequences. A gene ontology searches for proteins with poly-Asp sequences showed that a significant number of these proteins are associated with transcriptional regulation and gene expression functions. With this I propose that the mild phenotype observed with the Dnmt2 KO cells under stress condition could be correlated to a disregulation of protein synthesis. Die Methylierung von tRNA spielt eine wichtige Rolle in deren Stabilisierung und ist ebenfalls bedeutend für die fehlerfreie Proteinbiosynthese in den Zellen. In Eukaryoten existieren diverse tRNA Methyltransferasen, darunter auch die tRNA…