Identification of a phosphorylation site within the P protein important for mRNA transcription and growth of parainfluenza virus 5

The viral RNA-dependent RNA polymerase (vRdRp) of paramyxovirus consists of the large (L) protein and the phosphoprotein (P). P is heavily phosphorylated, and it is thought that the phosphorylation of P plays a role in regulating viral RNA synthesis. However, no phosphorylation site within the P protein in paramyxovirus has been identified as playing a positive role in viral RNA synthesis in virus infection. Using mass spectrometry analysis, the threonine residue at position 286 of P of parainfluenza virus 5 (PIV5) was found phosphorylated. Mutation of T286 to alanine (T286A), aspartic acid (T286D), or glutamic acid (T286E) reduced minigenome activity. Recombinant virus containing a mutation at the T286 position (rPIV5-P-T286A) grew slower than wild-type virus; viral mRNA synthesis and protein expression of rPIV5-P-T286A were delayed. Biochemical studies showed that the binding of NP or L protein with the P mutants or tetramer formation by the mutant P proteins was unaltered from that for wild-type P. While we failed to rescue rPIV5-P-T286E virus, several revertant viruses were obtained. All non-wild-type revertants had mutations at T286 and showed defects in both minigenome activity and viral growth. This is the first time that a phosphorylation site within the P protein in paramyxovirus has been found to play a positive role in viral mRNA synthesis and virus growth.     

Solubilization and immunoprecipitation of alphavirus replication complexes.

Alphavirus replication complexes that are located in the mitochondrial fraction of infected cells which pellets at 15,000 x g (P15 fraction) were used for the in vitro synthesis of viral 49S genome RNA, subgenomic 26S mRNA, and replicative intermediates (RIs). Comparison of the polymerase activity in P15 fractions from Sindbis virus (SIN)- and Semliki Forest virus (SFV)-infected cells indicated that both had similar kinetics of viral RNA synthesis in vitro but the SFV fraction was twice as active and produced more labeled RIs than SIN. When assayed in vitro under conditions of high specific activity, which limits incorporation into RIs, at least 70% of the polymerase activity was recovered after detergent treatment. Treatment with Triton X-100 or with Triton X-100 plus deoxycholate (DOC) solubilized some prelabeled SFV RIs but little if any SFV or SIN RNA polymerase activity from large structures that also contained cytoskeletal components. Treatment with concentrations of DOC greater than 0.25% or with 1% Triton X-100-0.5% DOC in the presence of 0.5 M NaCl released the polymerase activity in a soluble form, i.e., it no longer pelleted at 15,000 x g. The DOC-solubilized replication complexes, identified by their polymerase activity in vitro and by the presence of prelabeled RI RNA, had a density of 1.25 g/ml, were 20S to 100S in size, and contained viral nsP1, nsP2, phosphorylated nsP3, nsP4, and possibly nsP34 proteins. Immunoprecipitation of the solubilized structures indicated that the nonstructural proteins were complexed together and that a presumed cellular protein of approximately 120 kDa may be part of the complex. Antibodies specific for nsP3, and to a lesser extent antibodies to nsP1, precipitated native replication complexes that retained prelabeled RIs and were active in vitro in viral RNA synthesis. Thus, antibodies to nsP3 bound but did not disrupt or inhibit the polymerase activity of replication complexes in vitro.     

Role of protein-protein interactions during herpes simplex virus type 1 recombination-dependent replication

Recombination-dependent replication is an integral part of the process by which double-strand DNA breaks are repaired to maintain genome integrity. It also serves as a means to replicate genomic termini. We reported previously on the reconstitution of a recombination-dependent replication system using purified herpes simplex virus type 1 proteins (Nimonkar A. V., and Boehmer, P. E. (2003) Proc. Natl. Acad. Sci. U. S. A. 100, 10201-10206). In this system, homologous pairing by the viral single-strand DNA-binding protein (ICP8) is coupled to DNA synthesis by the viral DNA polymerase and helicase-primase in the presence of a DNA-relaxing enzyme. Here we show that DNA synthesis in this system is dependent on the viral polymerase processivity factor (UL42). Moreover, although DNA synthesis is strictly dependent on topoisomerase I, it is only stimulated by the viral helicase in a manner that requires the helicase-loading protein (UL8). Furthermore, we have examined the dependence of DNA synthesis in the viral system on species-specific protein-protein interactions. Optimal DNA synthesis was observed with the herpes simplex virus type 1 replication proteins, ICP8, DNA polymerase (UL30/UL42), and helicase-primase (UL5/UL52/UL8). Interestingly, substitution of each component with functional homologues from other systems for the most part did not drastically impede DNA synthesis. In contrast, recombination-dependent replication promoted by the bacteriophage T7 replisome was disrupted by substitution with the replication proteins from herpes simplex virus type 1. These results show that although DNA synthesis performed by the T7 replisome is dependent on cognate protein-protein interactions, such interactions are less important in the herpes simplex virus replisome.     

Replication-coupled and host factor-mediated encapsidation of the influenza virus genome by viral nucleoprotein

The influenza virus RNA-dependent RNA polymerase is capable of initiating replication but mainly catalyzes abortive RNA synthesis in the absence of viral and host regulatory factors. Previously, we reported that IREF-1/minichromosome maintenance (MCM) complex stimulates a de novo initiated replication reaction by stabilizing an initiated replication complex through scaffolding between the viral polymerase and nascent cRNA to which MCM binds. In addition, several lines of genetic and biochemical evidence suggest that viral nucleoprotein (NP) is involved in successful replication. Here, using cell-free systems, we have shown the precise stimulatory mechanism of virus genome replication by NP. Stepwise cell-free replication reactions revealed that exogenously added NP free of RNA activates the viral polymerase during promoter escape while it is incapable of encapsidating the nascent cRNA. However, we found that a previously identified cellular protein, RAF-2p48/NPI-5/UAP56, facilitates replication reaction-coupled encapsidation as an NP molecular chaperone. These findings demonstrate that replication of the virus genome is followed by its encapsidation by NP in collaboration with its chaperone.     

Naturally occurring missense mutation in the polymerase gene terminating hepatitis B virus replication.

A hepatitis B virus (HBV) genome was cloned from human liver. Numerous mutations in all viral genes define this HBV DNA as a mutant, divergent from all known HBV DNA sequences. Functional analyses of this mutant demonstrated a defect blocking viral DNA synthesis. The genetic basis of this defect was identified as a single missense mutation in the 5' region of the viral polymerase gene, resulting in the inability to package pregenomic RNA into core particles. The replication defect could be trans-complemented by a full-length wild-type, but not by a full-length mutant or 3'-truncated wild-type, polymerase gene construct. Our findings indicate a critical role of the 5' polymerase gene region in the life cycle of the virus and suggest that introducing missense mutations in this region can be a strategy to terminate viral replication in vivo.     

Coupled translation and replication of poliovirus RNA in vitro: synthesis of functional 3D polymerase and infectious virus.

Poliovirus RNA polymerase and infectious virus particles were synthesized by translation of virion RNA in vitro in HeLa S10 extracts. The in vitro translation reactions were optimized for the synthesis of the viral proteins found in infected cells and in particular the synthesis of the viral polymerase 3Dpol. There was a linear increase in the amount of labeled protein synthesized during the first 6 h of the reaction. The appearance of 3Dpol in the translation products was delayed because of the additional time required for the proteolytic processing of precursor proteins. 3Dpol was first observed at 1 h in polyacrylamide gels, with significant amounts being detected at 6 h and later. Initial attempts to assay for polymerase activity directly in the translation reaction were not successful. Polymerase activity, however, was easily detected by adding a small amount (3 microliters) of translation products to a standard polymerase assay containing poliovirion RNA. Full-length minus-strand RNA was synthesized in the presence of an oligo(U) primer. In the absence of oligo(U), product RNA about twice the size of virion RNA was synthesized in these reactions. RNA stability studies and plaque assays indicated that a significant fraction of the input virion RNA in the translation reactions was very stable and remained intact for 20 h or more. Plaque assays indicated that infectious virus was synthesized in the in vitro translation reactions. Under optimal conditions, the titer of infectious virus produced in the in vitro translation reactions was greater than 100,000 PFU/ml. Virus was first detected at 6 h and increased to maximum levels by 12 h. Overall, the kinetics of poliovirus replication (protein synthesis, polymerase activity, and virus production) observed in the HeLa S10-initiation factor in vitro translation reactions were similar to those observed in infected cells.     

Molecular biology of rotaviruses. I. Characterization of basic growth parameters and pattern of macromolecular synthesis

The United Kingdom tissue-adapted bovine rotavirus growing in African green monkey kidney (BSC-1) cells was selected as a model system with which to study the detailed molecular virology of rotavirus replication. Study of the kinetics of infectious virus production revealed a fairly rapid replication cycle, with maximum yield of virus after 10 to 12 h at 37 degrees C. Progeny genome synthesis was first detected during the virus latent period at 2 to 3 h postinfection. Study of the kinetics of viral polypeptide synthesis showed that virus rapidly inhibited cellular polypeptide synthesis such that by 4 h postinfection, only virus-induced polypeptides, 15 of which were detected, were being synthesized. No qualitative changes in the pattern of viral polypeptide synthesis were observed during infection, although, based on kinetic synthesis, three quantitative classes of polypeptides were defined. Pulse-chase analysis revealed three post-translational changes in viral proteins, two of which were shown to be due to glycosylation. Tunicamycin inhibition studies were used to identify the putative non-glycosylated precursors of the two glycoproteins. Comparison of the infected-cell polypeptides with those present in purified virions revealed that mot of the virus-induced proteins were incorporated into virions, with only VP9 being a truly nonstructural protein. Some localization of the various polypeptides within the purified virion was achieved by producing viral cores.     

The F1 motif of dengue virus polymerase NS5 is involved in promoter-dependent RNA synthesis

The mechanism by which viral RNA-dependent RNA polymerases (RdRp) specifically amplify viral genomes is still unclear. In the case of flaviviruses, a model has been proposed that involves the recognition of an RNA element present at the viral 5' untranslated region, stem-loop A (SLA), that serves as a promoter for NS5 polymerase binding and activity. Here, we investigated requirements for specific promoter-dependent RNA synthesis of the dengue virus NS5 protein. Using mutated purified NS5 recombinant proteins and infectious viral RNAs, we analyzed the requirement of specific amino acids of the RdRp domain on polymerase activity and viral replication. A battery of 19 mutants was designed and analyzed. By measuring polymerase activity using nonspecific poly(rC) templates or specific viral RNA molecules, we identified four mutants with impaired polymerase activity. Viral full-length RNAs carrying these mutations were found to be unable to replicate in cell culture. Interestingly, one recombinant NS5 protein carrying the mutations K456A and K457A located in the F1 motif lacked RNA synthesis dependent on the SLA promoter but displayed high activity using a poly(rC) template. Promoter RNA binding of this NS5 mutant was unaffected while de novo RNA synthesis was abolished. Furthermore, the mutant maintained RNA elongation activity, indicating a role of the F1 region in promoter-dependent initiation. In addition, four NS5 mutants were selected to have polymerase activity in the recombinant protein but delayed or impaired virus replication when introduced into an infectious clone, suggesting a role of these amino acids in other functions of NS5. This work provides new molecular insights on the specific RNA synthesis activity of the dengue virus NS5 polymerase.     

De novo RNA synthesis by a recombinant classical swine fever virus RNA-dependent RNA polymerase.

Classical swine fever virus nonstructural protein 5B (NS5B) encodes an RNA-dependent RNA polymerase, a key enzyme of the viral replication complex. To better understand the initiation of viral RNA synthesis and to establish an in vitro replication system, a recombinant NS5B protein, lacking the C-terminal 24-amino acid hydrophobic domain, was expressed in Escherichia coli. The truncated fusion protein (NS5Bdelta24) was purified on a Ni-chelating HisTrap affinity column and demonstrated to initiate either plus- or minus-strand viral RNA synthesis de novo in a primer-independent manner but not by terminal nucleotidyle transferase activity. De novo RNA synthesis represented the preferred mechanism for initiation of classical swine fever virus RNA synthesis by RNA-dependent RNA polymerase in vitro. Both Mg2+ and Mn2+ supported de novo initiation, however, RNA synthesis was more efficient in the presence of Mn2+ than in the presence of Mg2+. De novo initiation of RNA synthesis was stimulated by preincubation with 0.5 mm GTP, and a 3'-terminal cytidylate on the viral RNA template was preferred for de novo initiation. Furthermore, the purified protein was also shown, by North-Western blot analysis, to specifically interact with the 3'-end of both plus- and minus-strand viral RNA templates.     

The C-terminal transmembrane domain of hepatitis C virus (HCV) RNA polymerase is essential for HCV replication in vivo

Hepatitis C virus (HCV) RNA replication is dependent on the enzymatic activities of the viral RNA-dependent RNA polymerase NS5B, which is a membrane-anchored protein. Recombinant NS5B lacking the C-terminal transmembrane domain (21 amino acids) is enzymatically active. To address the role of this domain in HCV replication in vivo, we introduced a series of mutations into the NS5B of an HCV subgenomic replicon and examined the replication capabilities of the resultant mutants by a colony formation assay. Replicons lacking the transmembrane domain did not yield any colonies. Furthermore, when Huh-7 cells harboring the HCV subgenomic replicon were treated with a synthetic peptide consisting of the NS5B transmembrane domain fused to the antennapedia peptide, the membrane association of NS5B was completely disrupted. Correspondingly, the HCV RNA titer was reduced by approximately 50%. A scrambled peptide used as a control did not have any effects. These findings suggest that the membrane association of NS5B facilitates HCV RNA synthesis. However, a related transmembrane domain derived from bovine viral diarrhea virus could not replace the HCV NS5B transmembrane segment. This finding suggests that the C-terminal 21 amino acids not only have a membrane-anchoring function but also may perform additional functions for RNA synthesis in vivo.     

Identification and biological characterization of heterocyclic inhibitors of the hepatitis C virus RNA-dependent RNA polymerase

The hepatitis C virus (HCV) NS5B protein encodes an RNA-dependent RNA polymerase (RdRp), the primary catalytic enzyme of the HCV replicase complex. We established a biochemical RNA synthesis assay, using purified recombinant NS5B lacking the C-terminal 21 amino acid residues, to identify potential polymerase inhibitors from a high throughput screen of the GlaxoSmithKline proprietary compound collection. The benzo-1,2,4-thiadiazine compound 1 was found to be a potent, highly specific inhibitor of NS5B. This agent interacts directly with the viral polymerase and inhibits RNA synthesis in a manner noncompetitive with respect to GTP. Furthermore, in the absence of an in vitro-reconstituted HCV replicase assay employing viral and host proteins, the ability of compound 1 to inhibit NS5B-directed viral RNA replication was determined using the Huh7 cell-based HCV replicon system. Compound 1 reduced viral RNA in replicon cells with an IC(50) of approximately 0.5 microm, suggesting that the inhibitor was able to access the perinuclear membrane and inhibit the polymerase activity in the context of a replicase complex. Preliminary structure-activity studies on compound 1 led to the identification of a modified inhibitor, compound 4, showing an improvement in both biochemical and cell-based potency. Lastly, data are presented suggesting that these compounds interfere with the formation of negative and positive strand progeny RNA by a similar mode of action. Investigations are ongoing to assess the potential utility of such agents in the treatment of chronic HCV disease.     

Synthesis and Intracellular Localization of Vaccinia Virus Deoxyribonucleic Acid-dependent Ribonucleic Acid Polymerase

The time course of vaccinia deoxyribonucleic acid (DNA)-dependent ribonucleic acid (RNA) polymerase synthesis and its intracellular localization were studied with virus-infected HeLa cells. Viral RNA polymerase activity could be meassured shortly after viral infection in the cytoplasmic fraction of infected cells in vitro. However, unless the cells were broken in the presence of the nonionic detergent Triton-X-100, no significant synthesis of new RNA polymerase was detected during the viral growth cycle. When cells were broken in the presence of this detergent, extensive increases in viral RNA polymerase activity were observed late in the infection cycle. The onset of new RNA polymerase synthesis was dependent on prior viral DNA replication. Fluorodeoxyuridine (5 x 10(-5)m) prevented the onset of viral polymerase synthesis. Streptovitacin A, a specific and complete inhibitor of protein synthesis in HeLa cells, prevented the synthesis of RNA polymerase. Thus, the synthesis of RNA polymerase is a "late" function of the virus. The newly synthesized RNA polymerase activity was primarily bound to particles which sedimented during high-speed centrifugation. These particles have been characterized by sucrose gradient centrifugation. A major class of active RNA polymerase particles were considerably "lighter" than whole virus in sucrose gradients. These particles were entirely resistant to the action of added pancreatic deoxyribonuclease, and they were not stimulated by added calf thymus primer DNA. It is concluded that these particles are not active in RNA synthesis in vivo, and that activation occurs as a result of detergent treatment in vitro.     

Structure of hepatitis C virus polymerase in complex with primer-template RNA

The replication of the hepatitis C viral (HCV) genome is accomplished by the NS5B RNA-dependent RNA polymerase (RdRp), for which mechanistic understanding and structure-guided drug design efforts have been hampered by its propensity to crystallize in a closed, polymerization-incompetent state. The removal of an autoinhibitory β-hairpin loop from genotype 2a HCV NS5B increases de novo RNA synthesis by >100-fold, promotes RNA binding, and facilitated the determination of the first crystallographic structures of HCV polymerase in complex with RNA primer-template pairs. These crystal structures demonstrate the structural realignment required for primer-template recognition and elongation, provide new insights into HCV RNA synthesis at the molecular level, and may prove useful in the structure-based design of novel antiviral compounds. Additionally, our approach for obtaining the RNA primer-template-bound structure of HCV polymerase may be generally applicable to solving RNA-bound complexes for other viral RdRps that contain similar regulatory β-hairpin loops, including bovine viral diarrhea virus, dengue virus, and West Nile virus.