RNA Unwinding by the Helicase Mtr4p and the TRAMP Complex Investigated via High-Resolution Optical Trapping

We present single-molecule high-resolution optical trapping measurements of RNA unwinding by the Ski2-like nuclear helicase Mtr4p both alone and within the Trf4/Air2/Mtr4 polyadenylation (TRAMP) complex. RNA helicases such as Mtr4p play key roles in RNA metabolism. Mtr4p is thought to assist RNA degradation by the exosome presumably by unwinding RNA structures. In addition, the TRAMP complex appends short 3′ poly(A) tails to RNA meant for degradation by the exosome. Mtr4p within the TRAMP complex plays a crucial role in regulating the polyadenylation activity, limiting the poly(A) tail length. The unwinding activity of Mtr4p is required and indeed within the TRAMP complex, Mtr4p unwinds duplex RNA 10x faster than when alone. However, the dynamic details of the RNA unwinding activity and interaction of Mtr4p and TRAMP and indeed the Ski2-like family of RNA helicases are unknown. We have performed high-resolution RNA hairpin unwinding experiments for both Mtr4p and TRAMP. We find that Mtr4p unwinds RNA duplexes in a single or multiple bursts with a mean step size of 9 base pairs. The unwinding is irreversible suggesting that Mtr4p remains stably bound after unwinding the duplex, preventing re-annealing. TRAMP unwinding experiments reveal a faster molecular recognition by the Mtr4p helicase when in complex as well as enhanced RNA duplex unwinding dynamics. Combined high-resolution trapping and fluorescence experiments underway may reveal how the competition within TRAMP between the 3′-to-5′ Mtr4p helicase and the 5′-to-3′ Trf4p polymerase is resolved dynamically.