Project description:Approximately 3% of the world population is infected with hepatitis C virus (HCV), causing a serious public health burden. Like other positive-strand RNA viruses, HCV assembles replicase complexes in association with cellular membranes and produces progeny RNA genomes through negative-strand intermediates. The viral proteins required for RNA replication are nonstructural (NS) proteins NS3 to NS5B. Owing to many obstacles and limitations in structural characterization of proteins and complexes with multiple transmembrane segments, attempts to understand the assembly and action of the HCV replicase complex have been challenging. Nevertheless, great progress has been made in obtaining structural information for several replicase components, providing insights into some aspects of the viral genome replication machinery.

Project description:We report an RNA-negative, temperature-sensitive (ts) mutant of Murine hepatitis virus, Bristol ts31 (MHV-Brts31), that defines a new complementation group within the MHV replicase gene locus. MHV-Brts31 has near-normal levels of RNA synthesis at the permissive temperature of 33 degrees C but is unable to synthesize viral RNA when the infection is initiated and maintained at the nonpermissive temperature of 39.5 degrees C. Sequence analysis of MHV-Brts31 RNA indicated that a single G-to-A transition at codon 1307 in open reading frame 1a, which results in a replacement of methionine-475 with isoleucine in nonstructural protein 3 (nsp3), was responsible for the ts phenotype. This conclusion was confirmed using a vaccinia virus-based reverse genetics system to produce a recombinant virus, Bristol tsc31 (MHV-Brtsc31), which has the same RNA-negative ts phenotype and complementation profile as those of MHV-Brts31. The analysis of protein synthesis in virus-infected cells showed that, at the nonpermissive temperature, MHV-Brtsc31 was not able to proteolytically process either p150, the precursor polypeptide of the replicase nonstructural proteins nsp4 to nsp10, or the replicase polyprotein pp1ab to produce nsp12. The processing of replicase polyprotein pp1a in the region of nsp1 to nsp3 was not affected. Transmission electron microscopy showed that, compared to revertant virus, the number of double-membrane vesicles in MHV-Brts31-infected cells is reduced at the nonpermissive temperature. These results identify a new cistron in the MHV replicase gene locus and show that nsp3 has an essential role in the assembly of a functional MHV replication-transcription complex.

Project description:Aquatic birds represent a vast reservoir from which new pandemic influenza A viruses can emerge1. Influenza viruses contain a negative-sense segmented RNA genome that is transcribed and replicated by the viral heterotrimeric RNA polymerase (FluPol) in the context of viral ribonucleoprotein complexes2,3. RNA polymerases of avian influenza A viruses (FluPolA) replicate viral RNA inefficiently in human cells because of species-specific differences in acidic nuclear phosphoprotein 32 (ANP32), a family of essential host proteins for FluPol activity4. Host-adaptive mutations, particularly a glutamic-acid-to-lysine mutation at amino acid residue 627 (E627K) in the 627 domain of the PB2 subunit, enable avian FluPolA to overcome this restriction and efficiently replicate viral RNA in the presence of human ANP32 proteins. However, the molecular mechanisms of genome replication and the interplay with ANP32 proteins remain largely unknown. Here we report cryo-electron microscopy structures of influenza C virus polymerase (FluPolC) in complex with human and chicken ANP32A. In both structures, two FluPolC molecules form an asymmetric dimer bridged by the N-terminal leucine-rich repeat domain of ANP32A. The C-terminal low-complexity acidic region of ANP32A inserts between the two juxtaposed PB2 627 domains of the asymmetric FluPolA dimer, suggesting a mechanism for how the adaptive PB2(E627K) mutation enables the replication of viral RNA in mammalian hosts. We propose that this complex represents a replication platform for the viral RNA genome, in which one of the FluPol molecules acts as a replicase while the other initiates the assembly of the nascent replication product into a viral ribonucleoprotein complex.

Project description:Oxidative tissue injury often accompanies viral infection, yet there is little understanding of how it influences virus replication. We show that multiple hepatitis C virus (HCV) genotypes are exquisitely sensitive to oxidative membrane damage, a property distinguishing them from other pathogenic RNA viruses. Lipid peroxidation, regulated in part through sphingosine kinase-2, severely restricts HCV replication in Huh-7 cells and primary human hepatoblasts. Endogenous oxidative membrane damage lowers the 50% effective concentration of direct-acting antivirals in vitro, suggesting critical regulation of the conformation of the NS3-4A protease and the NS5B polymerase, membrane-bound HCV replicase components. Resistance to lipid peroxidation maps genetically to transmembrane and membrane-proximal residues within these proteins and is essential for robust replication in cell culture, as exemplified by the atypical JFH1 strain of HCV. Thus, the typical, wild-type HCV replicase is uniquely regulated by lipid peroxidation, providing a mechanism for attenuating replication in stressed tissue and possibly facilitating long-term viral persistence.

Project description:The fusion molecule (i.e. aptazyme) of aptamer and hammerhead ribozyme was developed as in situ sensor. Previously, the hammerhead ribozyme conjugated with aptamer through its stem II module showed a significant blank signal by self-cleavage. To reduce or remove its self-cleavage activity in the absence of target molecule, rational designs were attempted by reducing the binding affinity of the aptazyme to its RNA substrate, while maintaining the ribonuclease activity of the aptazyme. Interestingly, the bis-aptazymes which comprise the two aptamer-binding sites at both stem I and stem III of the hammerhead ribozyme showed very low blank signals, and their ratios of reaction rate constants, i.e. signal to noise ratios, were several tens to hundred times higher than those of the stem II-conjugated bis-aptazymes. The reduction in the blank signals seems to be caused by a higher dissociation constant between the main strand of the bis-aptazyme and its substrate arising from multi-point base-pairing of the bis-aptazymes. The bis-aptazymes for HCV replicase and helicase showed high selectivity against other proteins, and a linear relationship existed between their ribozyme activities and the target concentrations. In addition, a bis-aptazyme of dual functions was designed by inserting both aptamers for HCV replicase and helicase into the stem I and stem III of hammerhead ribozyme, respectively, and it also showed greater sensitivity and specificity for both proteins without blank signal.

Project description:Coronavirus replication requires proteolytic processing of the large polyprotein encoded by ORF1a/ab into putative functional intermediates and eventually approximately 15 mature proteins. The C-terminal ORF1a protein nsp10 colocalizes with viral replication complexes, but its role in transcription/replication is not well defined. To investigate the role of nsp10 in coronavirus transcription/replication, alanine replacements were engineered into a murine hepatitis virus (MHV) infectious clone in place of conserved residues in predicted functional domains or charged amino acid pairs/triplets, and rescued viruses were analyzed for mutant phenotypes. Of the 16 engineered clones, 5 viable viruses were rescued, 3 mutant viruses generated no cytopathic effect but were competent to synthesize viral subgenomic RNAs, and 8 were not viable. All viable mutants showed reductions in growth kinetics and overall viral RNA synthesis, implicating nsp10 as being a cofactor in positive- or negative-strand synthesis. Viable mutant nsp10-E2 was compromised in its ability to process the nascent polyprotein, as processing intermediates were detected in cells infected with this virus that were not detectable in wild-type infections. Mapping the mutations onto the crystal structure of severe acute respiratory syndrome virus nsp10 identified a central core resistant to mutation. Mutations targeting residues in or near either zinc-binding finger generated nonviable phenotypes, demonstrating that both domains are essential to nsp10 function and MHV replication. All mutations resulting in viable phenotypes mapped to loops outside the central core and were characterized by a global decrease in RNA synthesis. These results demonstrate that nsp10 is a critical regulator of coronavirus RNA synthesis and may play an important role in polyprotein processing.

Project description:We have used an ATP analogue 5'-[p-(fluorosulfonyl)benzoyl]adenosine (FSBA) to modify HCV replicase in order to identify the ATP binding site in the enzyme. FSBA inactivates HCV replicase activity in a concentration-dependent manner with a binding stoichiometry of 2 moles of FSBA per mole of enzyme. The enzyme activity is protected from FSBA in the presence of rNTP substrates or double-stranded RNA template primers that do not support ATP as the incoming nucleotide but not in the presence of polyrU.rA(26). HPLC analysis of tryptic peptides of FSBA-modified enzyme revealed the presence of two distinct peptides eluted at 23 and 36 min; these were absent in the control. Further we noted that both peptides were protected from FSBA modification in the presence of Mg·ATP. The LC/MS/MS analysis of the affinity-labeled tryptic peptides purified from HPLC, identified two major modification sites at positions 382 (Tyr), and 491 (Lys) and a minor site at position 38 (Tyr). To validate the functional significance of Tyr38, Tyr382, and Lys491 in catalysis, we individually substituted these residues by alanine and examined their ability to catalyze RdRp activity. We found that both Y382A and K491A mutants were significantly affected in their ability to catalyze RdRp activity while Y38A remained unaffected. We further observed that both Y382A and K491A mutants were not affected in their ability to bind template primer but were significantly affected in their ability to photo-cross-link ATP in the absence or presence of template primer.

Project description:Hepatitis C virus (HCV) is a human pathogen affecting nearly 3% of the world's population. Chronic infections can lead to cirrhosis and liver cancer. The RNA replication machine of HCV is a multi-subunit membrane-associated complex. The non-structural protein NS5A is an active component of HCV replicase, as well as a pivotal regulator of replication and a modulator of cellular processes ranging from innate immunity to dysregulated cell growth. NS5A is a large phosphoprotein (56-58 kDa) with an amphipathic alpha-helix at its amino terminus that promotes membrane association. After this helix region, NS5A is organized into three domains. The N-terminal domain (domain I) coordinates a single zinc atom per protein molecule. Mutations disrupting either the membrane anchor or zinc binding of NS5A are lethal for RNA replication. However, probing the role of NS5A in replication has been hampered by a lack of structural information about this multifunctional protein. Here we report the structure of NS5A domain I at 2.5-A resolution, which contains a novel fold, a new zinc-coordination motif and a disulphide bond. We use molecular surface analysis to suggest the location of protein-, RNA- and membrane-interaction sites.

Project description:Hepatitis C virus (HCV) infection constitutes a significant health burden worldwide, because it is a major etiologic agent of chronic liver disease, cirrhosis and hepatocellular carcinoma. HCV replication cycle is closely tied to lipid metabolism and infection by this virus causes profound changes in host lipid homeostasis. We focused our attention on a phosphatidate phosphate (PAP) enzyme family (the lipin family), which mediate the conversion of phosphatidate to diacylglycerol in the cytoplasm, playing a key role in triglyceride biosynthesis and in phospholipid homeostasis. Lipins may also translocate to the nucleus to act as transcriptional regulators of genes involved in lipid metabolism. The best-characterized member of this family is lipin1, which cooperates with lipin2 to maintain glycerophospholipid homeostasis in the liver. Lipin1-deficient cell lines were generated by RNAi to study the role of this protein in different steps of HCV replication cycle. Using surrogate models that recapitulate different aspects of HCV infection, we concluded that lipin1 is rate limiting for the generation of functional replicase complexes, in a step downstream primary translation that leads to early HCV RNA replication. Infection studies in lipin1-deficient cells overexpressing wild type or phosphatase-defective lipin1 proteins suggest that lipin1 phosphatase activity is required to support HCV infection. Finally, ultrastructural and biochemical analyses in replication-independent models suggest that lipin1 may facilitate the generation of the membranous compartment that contains functional HCV replicase complexes.

Project description:Hepatitis C virus (HCV) RNA is synthesized by the replicase complex (RC), a macromolecular assembly composed of viral non-structural proteins and cellular co-factors. Inhibitors of the HCV NS5A protein block formation of new RCs but do not affect RNA synthesis by pre-formed RCs. Without new RC formation, existing RCs turn over and are eventually lost from the cell. We aimed to use NS5A inhibitors to estimate the half-life of the functional RC of HCV. We compared different cell culture-infectious strains of HCV that may be grouped based on their sensitivity to lipid peroxidation: robustly replicating, lipid peroxidation resistant (LPOR) viruses (e.g. JFH-1 or H77D) and more slowly replicating, lipid peroxidation sensitive (LPOS) viruses (e.g. H77S.3 and N.2). In luciferase assays, LPOS HCV strains declined under NS5A inhibitor therapy with much slower kinetics compared to LPOR HCV strains. This difference in rate of decline was not observed for inhibitors of the NS5B RNA-dependent RNA polymerase suggesting that the difference was not simply a consequence of differences in RNA stability. In further analyses, we compared two isoclonal HCV variants: the LPOS H77S.3 and the LPOR H77D that differ only by 12 amino acids. Differences in rate of decline between H77S.3 and H77D following NS5A inhibitor addition were not due to amino acid sequences in NS5A but rather due to a combination of amino acid differences in the non-structural proteins that make up the HCV RC. Mathematical modeling of intracellular HCV RNA dynamics suggested that differences in RC stability (half-lives of 3.5 and 9.9 hours, for H77D and H77S.3, respectively) are responsible for the different kinetics of antiviral suppression between LPOS and LPOR viruses. In nascent RNA capture assays, the rate of RNA synthesis decline following NS5A inhibitor addition was significantly faster for H77D compared to H77S.3 indicating different half-lives of functional RCs.