MicroRNAs (miRNAs) affect gene regulation by base pairing with mRNA and contribute to the control of cellular homeostasis. The first step in miRNA maturation is conducted in the nucleus by the “microprocessor” complex made up of an RNase III enzyme, Drosha, that contains one dsRNA binding domain (dsRBD), and DGCR8, that contains two dsRBDs in tandem. The crystal structure of DGCR8-Core (493–720), containing both dsRBDs, and the NMR solution structure of Drosha-dsRBD (1259–1337) have been reported, but the solution dynamics have not been explored for any of these dsRBDs. To better define the mechanism of dsRNA binding and thus the nuclear maturation step of miRNA processing, we report NMR spin relaxation and MD simulations of Drosha-dsRBD (1259–1337) and DGCR8-dsRBD1 (505–583). The study was motivated by electrophoretic mobility shift assays (EMSAs) of the two dsRBDs, which showed that Drosha-dsRBD does not bind a representative miRNA but isolated DGCR8-dsRBD1 does (Kd = 9.4±0.4 µM). Our results show that loop 2 in both dsRBDs is highly dynamic but the pattern of the correlations observed in MD is different for the two proteins. Additionally, the extended loop 1 of Drosha-dsRBD is more flexible than the corresponding loop in DGCR8-dsRBD1 but shows no correlation with loop 2, which potentially explains the lack of dsRNA binding by Drosha-dsRBD in the absence of the RNase III domains. The results presented in this study provide key structural and dynamic features of dsRBDs that contribute to the binding mechanism of these domains to dsRNA.
One of the most exciting recent developments in RNA biology has been the discovery of small non-coding RNAs that affect gene expression through the RNA interference (RNAi) mechanism. Two major classes of RNAs involved in RNAi are small interfering RNA (siRNA) and microRNA (miRNA). Dicer, an RNase III enzyme, plays a central role in the RNAi pathway by cleaving precursors of both of these classes of RNAs to form mature siRNAs and miRNAs, which are then loaded into the RNA-induced silencing complex (RISC). miRNA and siRNA precursors are quite structurally distinct; miRNA precursors are short, imperfect hairpins while siRNA precursors are long, perfect duplexes. Nonetheless, Dicer is able to process both. Dicer, like the majority of RNase III enzymes, contains a dsRNA binding domain (dsRBD), but the data are sparse on the exact role this domain plays in the mechanism of Dicer binding and cleavage. To further explore the role of human Dicer-dsRBD in the RNAi pathway, we determined its binding affinity to various RNAs modeling both miRNA and siRNA precursors. Our study shows that Dicer-dsRBD is an avid binder of dsRNA, but its binding is only minimally influenced by a single-stranded – double-stranded junction caused by large terminal loops observed in miRNA precursors. Thus, the Dicer-dsRBD contributes directly to substrate binding but not to the mechanism of differentiating between pre-miRNA and pre-siRNA. In addition, NMR spin relaxation and MD simulations provide an overview of the role that dynamics contribute to the binding mechanism. We compare this current study with our previous studies of the dsRBDs from Drosha and DGCR8 to give a dynamic profile of dsRBDs in their apo-state and a mechanistic view of dsRNA binding by dsRBDs in general.
Most non-coding RNAs function properly only when folded into complex 3D structures, but the experimental determination of these structures remains challenging. Understanding of primary miRNA maturation is currently limited by a lack of solved structures for non-processed forms of the RNA. SHAPE chemistry efficiently determines RNA secondary structural information with single-nucleotide resolution, providing constraints suitable for input into the MC-Pipeline software for refinement of 3D structure models. Here we combine these approaches to analyze three structurally diverse primary miRNAs, revealing deviations from canonical dsRNA structure in the stem adjacent to the Drosha cut site for all three. The necessity of these deformable sites for efficient processing is demonstrated through Drosha processing assays. The structure models generated herein support the hypothesis that deformable sequences spaced roughly once per turn of A-form helix, created by non-canonical structure elements, combine with the necessary single-stranded RNA:double-stranded RNA junction to define the correct Drosha cleavage site.
We report atomically detailed molecular dynamics simulations characterizing the interaction of the RAP74 winged helix domain with the intrinsically disordered C-terminal of FCP1. The RAP74-FCP1 complex promotes the essential dephosphorylation of RNA polymerase II prior to initiation of transcription. Although disordered in solution, the C-terminal of FCP1 forms an amphipathic helix when bound to RAP74. Our simulations demonstrate that this interaction also reorganizes and stabilizes RAP74. These simulations illuminate the significance of hydrophobic contacts for stabilizing disordered protein complexes, provide new insight into the mechanism of protein binding by winged helix domains, and also reveal "dynamic fuzziness" in the complex as FCP1 retains significant flexibility after binding. In conjunction with our recent NMR experiments identifying residual structure in unbound FCP1, these simulations suggest that FCP1 loses relatively little conformational entropy upon binding and that the associated coupled folding-binding transition may be less sharp than expected.
Over the past decade, microRNAs (miRNAs) have been shown to affect gene regulation by basepairing with messenger RNA, and their misregulation has been directly linked with cancer. DGCR8, a protein that contains two dsRNA-binding domains (dsRBDs) in tandem, is vital for nuclear maturation of primary miRNAs (pri-miRNAs) in connection with the RNase III enzyme Drosha. The crystal structure of the DGCR8 Core (493-720) shows a unique, well-ordered structure of the linker region between the two dsRBDs that differs from the flexible linker connecting the two dsRBDs in the antiviral response protein, PKR. To better understand the interfacial interactions between the two dsRBDs, we ran extensive MD simulations of isolated dsRBDs (505-583 and 614-691) and the Core. The simulations reveal correlated reorientations of the two domains relative to one another, with the well-ordered linker and C-terminus serving as a pivot. The results demonstrate that motions at the domain interface dynamically impact the conformation of the RNA-binding surface and may provide an adaptive separation distance that is necessary to allow interactions with a variety of different pri-miRNAs with heterogeneous structures. These results thus provide an entry point for further in vitro studies of the potentially unique RNA-binding mode of DGCR8.
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