Project description:Here we propose a new general method for directly determining RNA sequence based on the use of the RNA-dependent RNA polymerase from bacteriophage phi6 and the chain terminators (RdRP sequencing). The following properties of the polymerase render it appropriate for this application: (1) the phi6 polymerase can replicate a number of single-stranded RNA templates in vitro. (2) In contrast to the primer-dependent DNA polymerases utilized in the sequencing procedure by Sanger et al. (Proc Natl Acad Sci USA, 1977, 74:5463-5467), it initiates nascent strand synthesis without a primer, starting the polymerization on the very 3'-terminus of the template. (3) The polymerase can incorporate chain-terminating nucleotide analogs into the nascent RNA chain to produce a set of base-specific termination products. Consequently, 3' proximal or even complete sequence of many target RNA molecules can be rapidly deduced without prior sequence information. The new technique proved useful for sequencing several synthetic ssRNA templates. Furthermore, using genomic segments of the bluetongue virus we show that RdRP sequencing can also be applied to naturally occurring dsRNA templates. This suggests possible uses of the method in the RNA virus research and diagnostics.

Project description:The biological role of manganese (Mn(2+)) has been a long-standing puzzle, since at low concentrations it activates several polymerases whilst at higher concentrations it inhibits. Viral RNA polymerases possess a common architecture, reminiscent of a closed right hand. The RNA-dependent RNA polymerase (RdRp) of bacteriophage 6 is one of the best understood examples of this important class of polymerases. We have probed the role of Mn(2+) by biochemical, biophysical and structural analyses of the wild-type enzyme and of a mutant form with an altered Mn(2+)-binding site (E491 to Q). The E491Q mutant has much reduced affinity for Mn(2+), reduced RNA binding and a compromised elongation rate. Loss of Mn(2+) binding structurally stabilizes the enzyme. These data and a re-examination of the structures of other viral RNA polymerases clarify the role of manganese in the activation of polymerization: Mn(2+) coordination of a catalytic aspartate is necessary to allow the active site to properly engage with the triphosphates of the incoming NTPs. The structural flexibility caused by Mn(2+) is also important for the enzyme dynamics, explaining the requirement for manganese throughout RNA polymerization.

Project description:The discovery of RNA interference (RNAi) has revolutionized biological research and has a huge potential for therapy. Since small double-stranded RNAs (dsRNAs) are required for various RNAi applications, there is a need for cost-effective methods for producing large quantities of high-quality dsRNA. We present two novel, flexible virus-based systems for the efficient production of dsRNA: (1) an in vitro system utilizing the combination of T7 RNA polymerase and RNA-dependent RNA polymerase (RdRP) of bacteriophage 6 to generate dsRNA molecules of practically unlimited length, and (2) an in vivo RNA replication system based on carrier state bacterial cells containing the 6 polymerase complex to produce virtually unlimited amounts of dsRNA of up to 4.0 kb. We show that pools of small interfering RNAs (siRNAs) derived from dsRNA produced by these systems significantly decreased the expression of a transgene (eGFP) in HeLa cells and blocked endogenous pro-apoptotic BAX expression and subsequent cell death in cultured sympathetic neurons.

Project description:Molecular dynamics (MD) simulations combined with biochemical studies have suggested the presence of long-range networks of functionally relevant conformational flexibility on the nanosecond time scale in single-subunit RNA polymerases in many RNA viruses. However, experimental verification of these dynamics at a sufficient level of detail has been lacking. Here we describe the fast, picosecond to nanosecond dynamics of an archetypal viral RNA-directed RNA polymerase (RdRp), the 75 kDa P2 protein from cystovirus ?12, using analyses of (1)H-(1)H dipole-dipole cross-correlated relaxation at the methyl positions of Ile (?1), Leu, Val, and Met residues. Our results, which represent the most detailed experimental characterization of fast dynamics in a viral RdRp until date, reveal a highly connected dynamic network as predicted by MD simulations of related systems. Our results suggest that the entry portals for template RNA and substrate NTPs are relatively disordered, while conserved motifs involved in metal binding, nucleotide selection, and catalysis display greater rigidity. Perturbations at the active site through metal binding or functional mutation affect dynamics not only in the immediate vicinity but also at remote regions. Comparison with the limited experimental and extensive functional and in silico results available for homologous systems suggests conservation of the overall pattern of dynamics in viral RdRps.

Project description:The RNA-dependent RNA polymerases (RdRPs) of Cystoviridae bacteriophages, like those of eukaryotic viruses of the Reoviridae, function inside the inner capsid shell in both replication and transcription. In bacteriophage Phi6, this inner shell is first assembled as an icosahedral procapsid with recessed 5-fold vertices that subsequently undergoes major structural changes during maturation. The tripartite genome is packaged as single-stranded RNA molecules via channels on the 5-fold vertices, and transcripts probably exit the mature capsid by the same route. The RdRP (protein P2) is assembled within the procapsid, and it was thought that it should be located on the 5-fold axes near the RNA entry and exit channels. To determine the initial location of the RdRP inside the procapsid of bacteriophage Phi6, we performed cryo-electron microscopy of wild type and mutant procapsids and complemented these data with biochemical determinations of copy numbers. We observe ring-like densities on the 3-fold axes that are strong in a mutant that has approximately 10 copies of P2 per particle; faint in wild type, reflecting the lower copy number of approximately 3; and completely absent in a P2-null mutant. The dimensions and shapes of these densities match those of the known crystal structure of the P2 monomer. We propose that, during maturation, the P2 molecules rotate to occupy positions closer to adjacent 5-fold vertices where they conduct replication and transcription.

Project description: Not available

Project description:We have determined the structure of P2, the self-priming RdRp from cystovirus ?12 in two crystal forms (A, B) at resolutions of 1.7 Å and 2.1 Å. Form A contains Mg(2+) bound at a site that deviates from the canonical noncatalytic position seen in form B. These structures provide insight into the temperature sensitivity of a ts-mutant. However, the tunnel through which template ssRNA accesses the active site is partially occluded by a flexible loop; this feature, along with suboptimal positioning of other structural elements that prevent the formation of a stable initiation complex, indicate an inactive conformation in crystallo.

Project description:Assembly of dsRNA bacteriophage phi6 involves packaging of the three mRNA strands of the segmented genome into the procapsid, an icosahedrally symmetric particle with recessed vertices. The hexameric packaging NTPase (P4) overlies these vertices, and the monomeric RNA-dependent RNA polymerase (RdRP, P2) binds at sites inside the shell. P2 and P4 are present in substoichiometric amounts, raising the questions of whether they are recruited to the nascent procapsid in defined amounts and at specific locations, and whether they may co-localize to form RNA-processing assembly lines at one or more "special" vertices. We have used cryo-electron tomography to map both molecules on individual procapsids. The results show variable complements that accord with binomial distributions with means of 8 (P2) and 5 (P4), suggesting that they are randomly incorporated in copy numbers that simply reflect availability, i.e. their rates of synthesis. Analysis of the occupancy of potential binding sites (20 for P2; 12 for P4) shows no tendency to cluster nor for P2 and P4 to co-localize, suggesting that the binding sites for both proteins are occupied in random fashion. These observations indicate that although P2 and P4 act sequentially on the same substrates there is no direct physical coupling between their activities.

Project description:In the extensive network of interdependent biochemical processes required for cell growth and division, there is mounting evidence that ribosomal DNA transcription by RNA polymerase I (pol I) not only drives cell growth via its direct role in production of the ribosomal RNA (rRNA) component of the protein-synthesis machinery, but that it is also crucial in determining the fate of the cell. Considerable progress has been made in recent years towards understanding both the function of components of the pol I transcription machinery and how cells accomplish the tight control of pol I transcription, balancing the supply of rRNA with demand under different growth conditions.

Project description:A long-lasting challenge in neuroscience has been to find a set of principles that could be used to organize the brain into distinct areas with specific functions. Recent studies have proposed the orderly progression in the time constants of neural dynamics as an organizational principle of cortical computations. However, relationships between these timescales and their dependence on response properties of individual neurons are unknown, making it impossible to determine how mechanisms underlying such a computational principle are related to other aspects of neural processing. Here, we developed a comprehensive method to simultaneously estimate multiple timescales in neuronal dynamics and integration of task-relevant signals along with selectivity to those signals. By applying our method to neural and behavioral data during a dynamic decision-making task, we found that most neurons exhibited multiple timescales in their response, which consistently increased from parietal to prefrontal and cingulate cortex. While predicting rates of behavioral adjustments, these timescales were not correlated across individual neurons in any cortical area, resulting in independent parallel hierarchies of timescales. Additionally, none of these timescales depended on selectivity to task-relevant signals. Our results not only suggest the existence of multiple canonical mechanisms for increasing timescales of neural dynamics across cortex but also point to additional mechanisms that allow decorrelation of these timescales to enable more flexibility.