Dicer-TRBP complex formation ensures accurate mammalian microRNA biogenesis.

RNA-mediated gene silencing in human cells requires the accurate generation of ∼22 nt microRNAs (miRNAs) from double-stranded RNA substrates by the endonuclease Dicer. Although the phylogenetically conserved RNA-binding proteins TRBP and PACT are known to contribute to this process, their mode of Dicer binding and their genome-wide effects on miRNA processing have not been determined. We solved the crystal structure of the human Dicer-TRBP interface, revealing the structural basis of the interaction. Interface residues conserved between TRBP and PACT show that the proteins bind to Dicer in a similar manner and by mutual exclusion. Based on the structure, a catalytically active Dicer that cannot bind TRBP or PACT was designed and introduced into Dicer-deficient mammalian cells, revealing selective defects in guide strand selection. These results demonstrate the role of Dicer-associated RNA binding proteins in maintenance of gene silencing fidelity.

Insights into RNA structure and function from genome-wide studies.

A comprehensive understanding of RNA structure will provide fundamental insights into the cellular function of both coding and non-coding RNAs. Although many RNA structures have been analysed by traditional biophysical and biochemical methods, the low-throughput nature of these approaches has prevented investigation of the vast majority of cellular transcripts. Triggered by advances in sequencing technology, genome-wide approaches for probing the transcriptome are beginning to reveal how RNA structure affects each step of protein expression and RNA stability. In this Review, we discuss the emerging relationships between RNA structure and the regulation of gene expression.

RNA Scanning of a Molecular Machine with a Built-in Ruler.

Advanced single-molecule techniques have enabled tracking of nanometer-scale movements of DNA and RNA motor proteins in real time. Previously, we reported an ATP-independent diffusion of transactivation response RNA binding protein (TRBP) on dsRNA, yet the mechanistic details remain elusive. Using single-molecule fluorescence assays, we demonstrate that the diffusion activity of TRBP is coordinated by an independent movement of two subdomains, dsRBD1 and dsRBD2, in which the diffusion distance is determined by the length of a flexible linker domain that connects the two dsRBDs. When the linker is shortened, the diffusion distance is reduced proportionally, suggesting a ruler-like function of the linker domain. Diffusion stalls upon encountering a physical barrier in the form of an RNA:DNA hybrid segment or bulky secondary structures, indicating a dsRNA scanning mode of TRBP. The results display a plausible mechanism of TRBP in scanning for pre-miRNA or pre-siRNA as proper substrates for the RNAi pathway.

ATP-independent diffusion of double-stranded RNA binding proteins.

The proteins harboring double-stranded RNA binding domains (dsRBDs) play diverse functional roles such as RNA localization, splicing, editing, export, and translation, yet mechanistic basis and functional significance of dsRBDs remain unclear. To unravel this enigma, we investigated transactivation response RNA binding protein (TRBP) consisting of three dsRBDs, which functions in HIV replication, protein kinase R(PKR)-mediated immune response, and RNA silencing. Here we report an ATP-independent diffusion activity of TRBP exclusively on dsRNA in a length-dependent manner. The first two dsRBDs of TRBP are essential for diffusion, whereas the third dsRBD is dispensable. Two homologs of TRBP, PKR activator and R3D1-L, displayed the same diffusion, implying a universality of the diffusion activity among this protein family. Furthermore, a Dicer-TRBP complex on dsRNA exhibited dynamic diffusion, which was correlated with Dicer's catalytic activity. These results implicate the dsRNA-specific diffusion activity of TRBP that contributes to enhancing siRNA and miRNA processing by Dicer.

Evolutionarily conserved roles of the dicer helicase domain in regulating RNA interference processing.

The enzyme Dicer generates 21-25 nucleotide RNAs that target specific mRNAs for silencing during RNA interference and related pathways. Although their active sites and RNA binding regions are functionally conserved, the helicase domains have distinct activities in the context of different Dicer enzymes. To examine the evolutionary origins of Dicer helicase functions, we investigated two related Dicer enzymes from the thermophilic fungus Sporotrichum thermophile. RNA cleavage assays showed that S. thermophile Dicer-1 (StDicer-1) can process hairpin precursor microRNAs, whereas StDicer-2 can only cleave linear double-stranded RNAs. Furthermore, only StDicer-2 possesses robust ATP hydrolytic activity in the presence of double-stranded RNA. Deletion of the StDicer-2 helicase domain increases both StDicer-2 cleavage activity and affinity for hairpin RNA. Notably, both StDicer-1 and StDicer-2 could complement the distantly related yeast Schizosaccharomyces pombe lacking its endogenous Dicer gene but only in their full-length forms, underscoring the importance of the helicase domain. These results suggest an in vivo regulatory function for the helicase domain that may be conserved from fungi to humans.

Activating silent argonautes.

Multiple Argonaute proteins are implicated in gene silencing by RNA interference (RNAi), but only one is known to be an endonuclease that can cleave target mRNAs. Chimeric Argonaute proteins now reveal an unexpected mechanism by which mutations distal to the catalytic center can unmask intrinsic catalytic activity, results hinting at structurally mediated regulation.

Coordinated activities of human dicer domains in regulatory RNA processing.

The conserved ribonuclease Dicer generates microRNAs and short-interfering RNAs that guide gene silencing in eukaryotes. The specific contributions of human Dicer's structural domains to RNA product length and substrate preference are incompletely understood, due in part to the difficulties of Dicer purification. Here, we show that active forms of human Dicer can be assembled from recombinant polypeptides expressed in bacteria. Using this system, we find that three distinct modes of RNA recognition give rise to Dicer's fidelity and product length specificity. The first involves anchoring one end of a double-stranded RNA helix within the PAZ domain, which can assemble in trans with Dicer's catalytic domains to reconstitute an accurate but non-substrate-selective dicing activity. The second entails nonspecific RNA binding by the double-stranded RNA binding domain, an interaction that is essential for substrate recruitment in the absence of the PAZ domain. The third mode of recognition involves hairpin RNA loop recognition by the helicase domain, which ensures efficient processing of specific substrates. These results reveal distinct interactions of each Dicer domain with different RNA structural features and provide a facile system for investigating the molecular mechanisms of human microRNA biogenesis.

Long term stability of a recombinant Plasmodium falciparum AMA1 malaria vaccine adjuvanted with Montanide(®) ISA 720 and stabilized with glycine.

Plasmodium falciparum apical membrane antigen 1 (AMA1) is an asexual blood-stage vaccine candidate against the malaria parasite. AMA1-C1/ISA 720 refers to a mixture of recombinant AMA1 proteins representing the FVO and 3D7 alleles in 1:1 mass ratio, formulated with Montanide(®) ISA 720 as a water-in oil emulsion. In order to develop the AMA1-C1/ISA 720 vaccine for human use, it was important to determine the shelf life of this formulation. Previously it was found 267 mM glycine stabilized the proteins in Montanide(®) ISA 720 formulations for a short period of time at 2-8°C [25]. We now test the long term stability of AMA1-C1 at 10 and 40 µg/mL formulated with Montanide(®) ISA 720 with 50mM glycine as a stabilizer. Stability of AMA1-C1/ISA 720 at different time points following formulation (0, 5, 12 or 18 months) was evaluated by determining the mean particle size (diameter of the mean droplet volume), total protein content by a Modified Lowry assay, identity and integrity using western blot and SDS-PAGE. Our results showed that the mean particle size of these emulsions increased over time, whereas protein content, as determined by an ELISA method using a monoclonal antibody against penta-his, decreased over time. For the 10 µg/mL AMA1-C1/ISA 720 vaccine, the protein content was 6.5±2.2 µg/mL, and for the 40 µg/mL AMA1-C1/ISA 720 vaccine, the protein content was only 8.2±2.3 µg/mL after 18 months of storage at 2-8°C. These results suggest that the integrity of the protein was affected by long-term storage. The results of the present study indicate that the AMA1-C1/ISA 720 emulsion was unstable after 12 months of storage, after which AMA1-C1 proteins were partially degraded.