Abstract
For efficient aminoacylation, tRNAs carry the conserved 3'-terminal sequence C-C-A, which is synthesized by highly specific tRNA nucleotidyltransferases (CCA-adding enzymes). In several prokaryotes, this function is accomplished by separate enzymes for CC- and A-addition. As A-adding enzymes carry an N-terminal catalytic core identical to that of CCA-adding enzymes, it is unclear why their activity is restricted. Here, it is shown that C-terminal deletion variants of A-adding enzymes acquire full and precise CCA-incorporating activity. The deleted region seems to be responsible for tRNA primer selection, restricting the enzyme's specificity to tRNAs ending with CC. The data suggest that A-adding enzymes carry an intrinsic CCA-adding activity that can be reactivated by the introduction of deletions in the C-terminal domain. Furthermore, a unique subtype of CCA-adding enzymes could be identified that evolved out of A-adding enzymes, suggesting that mutations and deletions in nucleotidyltransferases can lead to altered and even more complex activities, as a simple A-incorporation is converted into sequence-specific addition of C and A residues. Such activity-modifying events may have had an important role in the evolution of tRNA nucleotidyltransferases.
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