Structural framework for the assembly of the human tRNA ligase complex

In human cells, a subset of tRNA-encoding genes contain introns. These are removed by a non-canonical splicing pathway in which the tRNA splicing endonuclease complex catalyzes intron excision and the resulting exons are subsequently ligated by the tRNA-ligase complex (tRNA-LC). Although recent studies have provided insights into the process of intron removal, the molecular mechanisms underpinning tRNA ligation by tRNA-LC remain elusive. The tRNA-LC is a hetero-pentameric protein assembly consisting of Ashwin, CGI-99, FAM98B, the DEAD-box helicase DDX1 and the catalytic subunit RTCB/HSPC117. Using cryo-EM, we have determined an atomic-resolution reconstruction of human tRNA-LC. We find that CGI-99, DDX1 and FAM98B form an alpha-helical bundle that contacts RTCB via an interface located on the opposite side from the location of the ligase active site and tethers DDX1 to the tRNA-LC via its C-terminal helix. FAM98B and CGI-99 extensively interact in an intricately co-folded heterodimer that clamps Ashwin in a pincer-like structure. Interaction analysis using structure-based mutants of tRNA-LC subunits supports the overall architecture of the complex. Finally, we show that the paralogous proteins FAM98A and FAM98C underpin the assembly of compositionally distinct RTCB-containing complexes that lack Ashwin and may have distinct cellular functions. Together, our results provide new insights into the assembly and mechanism of the tRNA ligase complex, shedding light on its functions in tRNA biogenesis and beyond.