Abstract
Transfer RNA molecules have been recently recognized as widespread targets of bacterial immune systems. Translation inhibition through tRNA cleavage or modification inhibits phage propagation, thereby protecting the bacterial population. To counteract this, some viruses encode their own tRNA molecules, allowing infection to take place. The AriB effector of the PARIS defence system is a Toprim nuclease previously shown to target the E. coli tRNALys(UUU), but not a tRNALys(UUU) variant encoded by bacteriophage T5. We demonstrate here that the T5-tRNALys(UUU) is required but not sufficient to bypass PARIS immunity. Combining tRNA-sequencing, genetics, phage infection and in vitro biochemical data, we reveal that the E. coli tRNAThr(UGU), is another prime target of AriB and tRNAAsn(GUU) represents a secondary, yet biologically relevant, target of the PARIS effector. Activated AriB protein cleaves these targets in vitro, and the cleavage reaction is not dependent on the presence of specific tRNA modifications. We show that the overexpression of phage T5 tRNALys(UUU), tRNAThr(UGU) and tRNAAsn(GUU) variants is sufficient to inhibit PARIS anti-viral defence. Finally, we propose a model for tRNA recognition by the AriB dimer and provide molecular details of its nuclease activity and specificity.
Competing Interest Statement
The authors have declared no competing interest.