Structural and functional characterisation of human RNA helicase DHX8 provides insights into the mechanism of RNA-stimulated ADP release.

DHX8 is a crucial DEAH-box RNA helicase involved in splicing and required for the release of mature mRNA from the spliceosome. Here, we report the biochemical characterisation of full-length human DHX8 and the catalytically active helicase core DHX8Δ547, alongside crystal structures of DHX8Δ547 bound to ADP and a structure of DHX8Δ547 bound to poly(A)6 single-strand RNA. Our results reveal that DHX8 has an in vitro binding preference for adenine-rich RNA and that RNA binding triggers the release of ADP through significant conformational flexibility in the conserved DEAH-, P-loop and hook-turn motifs. We demonstrate the importance of R620 and both the hook-turn and hook-loop regions for DHX8 helicase activity and propose that the hook-turn acts as a gatekeeper to regulate the directional movement of the 3' end of RNA through the RNA-binding channel. This study provides an in-depth understanding of the activity of DHX8 and contributes insights into the RNA-unwinding mechanisms of the DEAH-box helicase family.

Human cactin interacts with DHX8 and SRRM2 to assure efficient pre-mRNA splicing and sister chromatid cohesion.

Cactins constitute a family of eukaryotic proteins broadly conserved from yeast to human and required for fundamental processes such as cell proliferation, genome stability maintenance, organismal development and immune response. Cactin proteins have been found to associate with the spliceosome in several model organisms, nevertheless their molecular functions await elucidation. Here we show that depletion of human cactin leads to premature sister chromatid separation, genome instability and cell proliferation arrest. Moreover, cactin is essential for efficient splicing of thousands of pre-mRNAs, and incomplete splicing of the pre-mRNA of sororin (also known as CDCA5), a cohesin-associated factor, is largely responsible for the aberrant chromatid separation in cactin-depleted cells. Lastly, cactin physically and functionally interacts with the spliceosome-associated factors DHX8 and SRRM2. We propose that cellular complexes comprising cactin, DHX8 and SRRM2 sustain precise chromosome segregation, genome stability and cell proliferation by allowing faithful splicing of specific pre-mRNAs. Our data point to novel pathways of gene expression regulation dependent on cactin, and provide an explanation for the pleiotropic dysfunctions deriving from cactin inactivation in distant eukaryotes.