Isolation of a soluble and template-dependent poliovirus RNA polymerase that copies virion RNA in vitro.

A soluble RNA-dependent RNA polymerase was isolated from poliovirus-infected HeLa cells and was shown to copy poliovirus RNA in vitro. The enzyme was purified from a 200,000-X-g supernatant of a cytoplasmic extract of infected cells. The activity of the enzyme was measured throughout the purification by using a polyadenylic acid template and oligouridylic acid primer. The enzyme was partially purified by ammonium sulfate precipitation, glycerol gradient centrifugation, and phosphocellulose chromatography. The polymerase precipitated in a 35% saturated solution of ammonium sulfate, sedimented at about 7S on a glycerol gradient, and eluted from phosphocellulose with 0.15 M KC1. The polymerase was purified about 40-fold and was shown to be totally dependent on exogenous RNA for activity and relatively free of contaminating nuclease. The partially purified polymerase was able to use purified polio virion RNA as well as a template. Under the reaction conditions used, the polymerase required an oligouridylic acid primer and all four ribonucleside triphosphates for activity. The optimum ratio of oligouridylic acid molecules to poliovirus RNA molecules for priming activity was about 16:1. A nearest-neighbor analysis of the in vitro RNA product shows it to be heteropolymeric. Annealing the in vitro product with poliovirus RNA product shows it to be heteropolymeric. Annealing the in vitro product with poliovirus RNA rendered it resistant to RNase digestion, thus suggesting that the product RNA was complementary to the virion RNA template.     

DNA-dependent RNA Polymerase associated with Bacteriophage PM2

A DNA-dependent RNA polymerase is associated with purified preparations of bacteriophage PM2. The template is DNA, as suggested by the reduction in polymerase activity on treatment of disrupted virus particles with DNAase and by the absence of detectable amounts of RNA in the virus.     

Complete replication in vitro of tobacco mosaic virus RNA by a template-dependent, membrane-bound RNA polymerase.

A crude membrane-bound RNA polymerase, obtained by differential centrifugation of extracts of tomato leaves infected with tobacco mosaic tobamovirus (tomato strain L) TMV-L), was purified by sucrose density gradient centrifugation. Removal of the endogenous RNA template with micrococcal nuclease rendered the polymerase template dependent and template specific. The polymerase was primer independent and able to initiate RNA synthesis on templates containing the 3'-terminal sequences of the TMV-L positive or negative strands. TMV-vulgare RNA was a less efficient template, while RNAs of cucumber mosaic cucumovirus and red clover necrotic mosaic dianthovirus, or 5'-terminal sequences of TMV-L positive or negative strands, did not act as templates for the polymerase. A main product of the reaction with TMV-L genomic RNA as a template, carried out in the presence of [alpha-32P]UTP, was genomic-length single-stranded RNA. This was shown to be the positive strand and uniformly labelled along its length, demonstrating complete replication of TMV-L RNA. Genomic-length double-stranded RNA, labelled in both strands, and small amounts of RNAs corresponding to the single- and double-stranded forms of the coat protein subgenomic mRNA were also formed. Antibodies to N-terminal and C-terminal portions of the 126-kDa protein detected the 126-kDa protein and the 183-kDa readthrough protein in purified RNA polymerase preparations, whereas antibodies to the readthrough portion of the 183-kDa protein detected only the 183-kDa protein. All three antibodies inhibited the template-dependent RNA polymerase, but none of them had any effect on the template-bound enzyme.     

RNA-dependent RNA polymerase activity associated with endogenous double-stranded RNA in rice

RNA-dependent RNA polymerase (RdRp) activity was detected in the crude microsomal fraction of rice cultured cells that contain a 14 kbp double-stranded RNA (dsRNA). RdRp activity is maximal in the presence of all four nucleotide triphosphates and Mg2+ ion and is resistant to inhibitors of DNA-dependent RNA polymerases (actinomycin D and alpha-amanitin). RdRp activity increases approximately 2.5-fold in the presence of 0.5% deoxycholate. Treatment of purified microsomal fraction with proteinase K plus deoxycholate suggests that the RdRp enzyme complex with its own 14 kb RNA template is located in vesicles. The RdRp enzyme complex was solubilized with Nonidet P-40 and purified by glycerol gradient centrifugation, then exogenous RNA templates were added. Results indicate that exogenous dsRNA reduces RNA synthesis from the endogenous 14 kb RNA template.     

The predicted stem-loop structure in the 3′-end of the human norovirus antigenomic sequence is required for its genomic RNA synthesis by its RdRp

The norovirus genome consists of a single positive-stranded RNA. The mechanism by which this single-stranded RNA genome is replicated is not well understood. To reveal the mechanism underlying the initiation of the norovirus genomic RNA synthesis by its RNA-dependent RNA polymerase (RdRp), we used an in vitro assay to detect the complementary RNA synthesis activity. Results showed that the purified recombinant RdRp was able to synthesize the complementary positive-sense RNA from a 100-nt template corresponding to the 3′-end of the viral antisense genome sequence, but that the RdRp could not synthesize the antisense genomic RNA from the template corresponding to the 5′-end of the positive-sense genome sequence. We also predicted that the 31 nt region at the 3′-end of the RNA antisense template forms a stem-loop structure. Deletion of this sequence resulted in the loss of complementary RNA synthesis by the RdRp, and connection of the 31 nt to the 3′-end of the inactive positive-sense RNA template resulted in the gain of complementary RNA synthesis by the RdRp. Similarly, an electrophoretic mobility shift assay further revealed that the RdRp bound to the antisense RNA specifically, but was dependent on the 31 nt at the 3′-end. Therefore, based on this observation and further deletion and mutation analyses, we concluded that the predicted stem-loop structure in the 31 nt end and the region close to the antisense viral genomic stem sequences are both important for initiating the positive-sense human norovirus genomic RNA synthesis by its RdRp.     

Genome-length copies of poliovirion RNA are synthesized in vitro by the poliovirus RNA-dependent RNA polymerase

A soluble RNA-dependent RNA polymerase was purified from the cytoplasm of poliovirus-infected HeLa cells. A single virus-specific protein designated as p63 (or NCVP4) copurified with this activity. The purified polymerase was free of ribonuclease activity and was shown to copy poliovirion RNA when oligo(U) was added to the in vitro reaction mixture. Characterization of the product RNA by electrophoresis in methylmercury (II) hydroxide-agarose gels showed that genome-sized copies of poliovirion RNA were synthesized in vitro by the purified polymerase. The product RNA was shown to be heteropolymeric, complementary to virion RNA, and covalently linked to oligo(U). The product RNA contained the expected distribution of UMP and GMP containing dinucleotide pairs which included a very low frequency of CpG pairs. The amount, size distribution, and rate of synthesis of product RNA was very dependent on the in vitro reaction conditions. Full sized product RNA was synthesized in about 6 min when reaction conditions were used that yielded maximum elongation rates (pH 8.0, 7 mM Mg2+, 37 degrees C). Under these conditions, most of the product RNA recovered from a 1-h reaction was full sized. Thus, the polymerase was found to specifically initiate synthesis at the 3'-end of the template using an oligo(U) primer and to carry out an elongation reaction at about 1250 nucleotides/min that resulted in the synthesis of full sized product RNA.     

Protein kinase NII. Interaction with RNA polymerase II and contribution to immunological cross-reactivity of RNA polymerases I and II

The interaction between antibodies directed against RNA polymerase I purified from Morris hepatoma 3924A and homologous RNA polymerase II was investigated. The activity of partially purified polymerase II was inhibited by the antibodies. In contrast, the reaction catalyzed by the purified enzyme was not affected. Partially purified polymerase II preparations contained a protein kinase activity. Sucrose gradient centrifugation in the presence of 0.3 M KCl resulted in complete separation of RNA polymerase II from protein kinase as well as in complete loss of sensitivity to the anti-RNA polymerase I antibodies. The protein kinase possessed reaction characteristics similar to those of the NII protein kinase (Rose, K.M., Bell, L.E., Siefken, D.A. and Jacob, S.T. (1981) J. Biol. Chem. 256, 7468–7477) which is associated with hepatoma RNA polymerase I (Rose, K.M., Stetler, D.A. and Jacob, S.T. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 2833–2837). The activities of both kinases were inhibited to the same extent by anti-RNA polymerase I antibodies and polypeptides of M_r 42000 and 25000, present in both kinase preparations, formed immune complexes with the antisera. Readdition of protein kinase NII to purified polymerase II resulted in phosphorylation of the polymerase and a concomitant enhancement of RNA synthesis. After addition of the kinase, RNA polymerase II activity was again sensitive to anti-RNA polymerase I antibodies. Upon reacting with protein kinase NII, RNA polymerase II polypeptides could be detected in immune complexes with anti-RNA polymerase I antibodies. These data indicate that protein kinase NII is associated with RNA polymerase II during early stages of purification and is at least partially responsible for the immunological cross-reactivity of RNA polymerases I and II.     

Terminal nucleotidyl transferase activity of recombinant Flaviviridae RNA-dependent RNA polymerases: implication for viral RNA synthesis

Recombinant hepatitis C virus (HCV) RNA-dependent RNA polymerase (RdRp) was reported to possess terminal transferase (TNTase) activity, the ability to add nontemplated nucleotides to the 3' end of viral RNAs. However, this TNTase was later purported to be a cellular enzyme copurifying with the HCV RdRp. In this report, we present evidence that TNTase activity is an inherent function of HCV and bovine viral diarrhea virus RdRps highly purified from both prokaryotic and eukaryotic cells. A change of the highly conserved GDD catalytic motif in the HCV RdRp to GAA abolished both RNA synthesis and TNTase activity. Furthermore, the nucleotides added via this TNTase activity are strongly influenced by the sequence near the 3' terminus of the viral template RNA, perhaps accounting for the previous discrepant observations between RdRp preparations. Last, the RdRp TNTase activity was shown to restore the ability to direct initiation of RNA synthesis in vitro on an initiation-defective RNA substrate, thereby implicating this activity in maintaining the integrity of the viral genome termini.     

Purification and characterization of RNA polymerase I from a higher plant.

RNA polymerase I was purified from chromatin isolated from auxin-treated soybean hypocotyl. Purification was achieved by using Agarose A-1.5m gel filtration, DEAE-cellulose, CM-sephadex, and phosphocellulose chromatography, and sucrose density gradient centrifugation. With denatured calf thymus DNA as template, the enzyme has a high specific activity (200-300 nmol/mg/30 min at 28 degrees C) which is comparable to other RNA polymerase I enzymes purified from animals and yeast. While the gel profiles indicate that purification to homogeneity (greater than 90%) may not have been achieved, the enzyme appears to be composed of possibly 7 subunits, several of which are similar to the subunits of yeast RNA polymerase I. The putative subunits and molar ratios are 183 000 (1), 136 000 (1), 50 000 (0.5), 46 000 (0.5), 40 000 (0.5), 33 000 (0.2), and 28 000 (2). The purified enzyme strongly prefers a completely denatured template such as poly(dC).     

Glycerol inhibition of purified and chromatin-associated mouse liver hepatoma RNA polymerase II activity

The stability of mouse liver hepatoma RNA polymerase II is dependent on the type of buffer, pH and, most importantly, the glycerol concentration of the incubation or storage buffer. Glycerol above 2% or 15% shows a linearly increasing inhibition of enzyme activity with increasing glycerol concentration for purified RNA polymerase II and chromatin-associated RNA polymerase II, respectively. At 25% glycerol the activity of purified enzyme on DNA template was inhibited approximately 50% whereas the chromatin-associated activity was inhibited only approximately 30%. RNA polymerase I activity was not inhibited by glycerol at the concentrations examined.     

De novo synthesis of negative-strand RNA by Dengue virus RNA-dependent RNA polymerase in vitro: nucleotide,primer, and template parameters

By using a purified dengue virus RNA-dependent RNA polymerase and a subgenomic 770-nucleotide RNA template, it was shown previously that the ratio of the de novo synthesis product to hairpin product formed was inversely proportional to increments of assay temperatures (20 to 40 degrees C). In this study, the components of the de novo preinitiation complex are defined as ATP, a high concentration of GTP (500 micro M), the polymerase, and the template RNA. Even when the 3'-terminal sequence of template RNA was mutated from -GGUUCU-3' to -GGUUUU-3', a high GTP concentration was required for de novo initiation, suggesting that high GTP concentration plays a conformational role. Furthermore, utilization of synthetic primers by the polymerase indicated that AGAA is the optimal primer whereas AG, AGA, and AGAACC were inefficient primers. Moreover, mutational analysis of the highly conserved 3'-terminal dinucleotide CU of the template RNA indicated that change of the 3'-terminal nucleotide from U to C reduced the efficiency about fivefold. The order of preference for the 3'-terminal nucleotide, from highest to lowest, is U, A - G, and C. However, change of the penultimate nucleotide from C to U did not affect the template activity. A model consistent with these results is that the active site of the polymerase switches from a "closed" form, catalyzing de novo initiation through synthesis of short primers, to an "open" form for elongation of a double-stranded template-primer.     

DNA Polymerase of Murine Sarcoma-Leukemia Virus: Lack of Detectable RNase H and Low Activity With Viral RNA and Natural DNA Templates

Kirsten murine sarcoma-leukemia virus (Ki-MSV[MLV]) was found to contain less RNase H per unit of viral DNA polymerase than avian Rous sarcoma virus (RSV). Upon purification by chromatography on Sephadex G-200 and subsequent glycerol gradient sedimentation the avian DNA polymerase was obtained in association with a constant amount of RNase H. By contrast, equally purified DNA polymerase of Ki-MSV(MLV) and Moloney [Mo-MSV(MLV)] lacked detectable RNase H if assayed with two homopolymer and phage fd DNA-RNA hybrids as substrates. On the basis of picomoles of nucleotides turned over, the ratio of RNase H to purified avian DNA polymerase was 1:20 and that of RNase H to purified murine DNA polymerase ranged between <1:2,800 and 5,000. Based on the same activity with poly (A).oligo(dT) the activity of the murine DNA polymerase was 6 to 60 times lower than that of the avian enzyme with denatured salmon DNA template or with avian or murine viral RNA templates assayed under various conditions (native, heat-dissociated, with or without oligo(dT) and oligo(dC) and at different template enzyme ratios). The template activities of Ki-MSV(MLV) RNA and RSV RNA were enhanced uniformly by oligo(dT) but oligo(dC) was much less efficient in enhancing the activity of MSV(MLV) RNA than that of RSV RNA. It was concluded that the purified DNA polymerase of Ki-MSV(MLV) differs from that of Rous sarcoma virus in its lack of detectable RNase H and in its low capacity to transcribe viral RNA and denatured salmon DNA. Some aspects of these results are discussed.