The structure of Prp2 bound to RNA and ADP‐BeF 3 − reveals structural features important for RNA unwinding by DEAH‐box ATPases

Noncoding intron sequences present in precursor mRNAs need to be removed prior to translation, and they are excised via the spliceosome, a multimegadalton molecular machine composed of numerous protein and RNA components. The DEAH‐box ATPase Prp2 plays a crucial role during pre‐mRNA splicing as it ensures the catalytic activation of the spliceosome. Despite high structural similarity to other spliceosomal DEAH‐box helicases, Prp2 does not seem to function as an RNA helicase, but rather as an RNA‐dependent ribonucleoprotein particle‐modifying ATPase. Recent crystal structures of the spliceosomal DEAH‐box ATPases Prp43 and Prp22, as well as of the related RNA helicase MLE, in complex with RNA have contributed to a better understanding of how RNA binding and processivity might be achieved in this helicase family. In order to shed light onto the divergent manner of function of Prp2, an N‐terminally truncated construct of Chaetomium thermophilum Prp2 was crystallized in the presence of ADP‐BeF 3 − and a poly‐U 12 RNA. The refined structure revealed a virtually identical conformation of the helicase core compared with the ADP‐BeF 3 − ‐ and RNA‐bound structure of Prp43, and only a minor shift of the C‐terminal domains. However, Prp2 and Prp43 differ in the hook‐loop and a loop of the helix‐bundle domain, which interacts with the hook‐loop and evokes a different RNA conformation immediately after the 3′ stack. On replacing these loop residues in Prp43 by the Prp2 sequence, the unwinding activity of Prp43 was abolished. Furthermore, a putative exit tunnel for the γ‐phosphate after ATP hydrolysis could be identified in one of the Prp2 structures.