Kinetics of the interaction of methylene diphosphonic acid and inorganic pyrophosphate with DNA-dependent RNA-polymerase from calf thymus

The kinetics of interaction of PPi and its diphosphonic analog, methylenediphosphonic acid (MDPA), with nucleoside triphosphates, DNA and Mg2+ binding sites of DNA-dependent RNA polymerase II from calf thymus was investigated. The values of apparent Km in the NTP polymerization reaction for ATP and CTP equal to 2.7 X 10(-4) and 1.8 X 10(-4) M, respectively, were determined. It was shown that MDPA and PPi competitively inhibited the RNA polymerase reaction with respect to nucleoside triphosphate. The inhibition constants (Ki) of ATP and CTP incorporation for MDPA were 2.2 X 10(-4) and 3.3 X 10(-4) M, respectively, while those of the nucleoside triphosphate incorporation for PPi were equal to 1.4 X 10(-4) and 2.0 X 10(-4) M, respectively. MDPA and PPi were incompetitive inhibitors of template (DNA) and Mn2+. A possible mechanism of inhibition of the RNA polymerase reaction by MDPA is proposed.     

A continuous nonradioactive assay for RNA-dependent RNA polymerase activity

Current assays for the activity of viral RNA-dependent RNA polymerases (RdRps) are inherently end-point measurements, often requiring the use of radiolabeled or chemically modified nucleotides to detect reaction products. In an effort to improve the characterization of polymerases that are essential to the life cycle of RNA viruses and develop antiviral therapies that target these enzymes, a continuous nonradioactive assay was developed to monitor the activity of RdRps by measuring the release of pyrophosphate (PP(i)) generated during nascent strand synthesis. A coupled-enzyme assay method based on the chemiluminescent detection of PP(i), using ATP sulfurylase and firefly luciferase, was adapted to monitor poliovirus 3D polymerase (3D(pol)) and the hepatitis C virus nonstructural protein 5B (NS5B) RdRp reactions. Light production was dependent on RdRp and sensitive to the concentration of oligonucleotide primer directing RNA synthesis. The assay system was found to be amenable to sensitive kinetic studies of RdRps, requiring only 6nM 3D(pol) to obtain a reliable estimate of the initial velocity in as little as 4 min. The assay can immediately accommodate the use of both homopolymer and heteropolymer RNA templates lacking uridylates and can be adapted to RNA templates containing uridine by substituting alpha-thio ATP for ATP. The low background signal produced by other NTPs can be corrected from no enzyme (RdRp) controls. The effect of RdRp/RNA template preincubation was assessed using NS5B and a homopolymer RNA template and a time-dependent increase of RdRp activity was observed. Progress curves for a chain terminator (3(')-deoxyguanosine 5(')-triphosphate) and an allosteric NS5B inhibitor demonstrated the predicted time- and dose-dependent reductions in signal. This assay should facilitate detailed kinetic studies of RdRps and their potential inhibitors using either standard or single-nucleotide approaches.     

Poly(A)- and primer-independent RNA polymerase of Norovirus

Replication of positive-strand caliciviruses is mediated by a virus-encoded RNA-dependent RNA polymerase (RdRp). To study the replication of Norovirus (NV), a member of the family Caliciviridae, we used a recombinant baculovirus system to express an enzymatically active RdRp protein from the 3D region of the NV genome and defined conditions for optimum enzymatic activity. Using an RNA template from the NV 3' genomic region, we observed similar levels of enzymatic activity in assays with and without a poly(A) tail. RdRp activity was not significantly affected by the addition of an RNA primer to the reaction mixture. Thus, the NV RdRp exhibited primer- and poly(A)-independent RNA polymerase activity. While the RdRp inhibitor phosphonoacetic acid inhibited NV RdRp activity, another gliotoxin did not. The active recombinant NV RdRp will be of benefit to studies of NV replication and will facilitate the development of specific inhibitors of NV proliferation.     

Reconstitution of bluetongue virus polymerase activity from isolated domains based on a three-dimensional structural model

Bluetongue virus (BTV) is a double-stranded RNA virus of the Reoviridae family. The VP1 protein of BTV is the viral RNA-dependent RNA polymerase (RdRp), which is responsible for the replication of the viral genome. Currently there is no structural information available for VP1. By manual alignment of BTV, Reovirus and other viral RdRps we have generated a model for the structure of VP1, the RdRp of BTV. The structure can be divided into three domains: an N-terminal domain, a C-terminal domain, and a central polymerase domain. Mutation of the putative catalytic site in the central polymerase domain by site-directed mutagenesis abrogated in vitro replicase activity. Each of the domains was expressed individually and subsequently partially purified to obtain direct evidence for the location of polymerase activity and the nucleoside triphosphate binding site. The nucleoside triphosphate binding site was located by showing that CTP only bound to the full-length protein or to the polymerase domain and not to either of the other two domains. None of the domains had catalytic activity when tested individually or in tandem but when all three domains were mixed together the RdRp activity was reconstituted. This is the first report of the reconstitution of a functional viral RdRp in vitro from individual domains.     

The mechanism of pyrophosphorolysis of RNA by RNA polymerase. Endowment of RNA polymerase with artificial exonuclease activity.

DNA-directed RNA polymerase from Escherichia coli can break down RNA by catalysing the reverse of the reaction: NTP + (RNA)n = (RNA)n+1 + PPi where n indicates the number of nucleotide residues in the RNA molecule, to yield nucleoside triphosphates. This reaction requires the ternary complex of the polymerase with template DNA and the RNA that it has synthesized. It is now shown that methylenebis(arsonic acid) [CH2(AsO3H2)2], arsonomethylphosphonic acid (H2O3As-CH2-PO3H2) and arsonoacetic acid (H2O3As-CH2-CO2H) can replace pyrophosphate in this reaction. When they do so, the low-Mr products of the reaction prove to be nucleoside 5'-phosphates, so that the arsenical compounds endow the polymerase with an artificial exonuclease activity, an effect previously found by Rozovskaya, Chenchik, Tarusova, Bibilashvili & Khomutov [(1981) Mol. Biol. (Moscow) 15, 636-652] for phosphonoacetic acid (H2O3P-CH2-CO2H). This is explained by instability of the analogues of nucleoside triphosphates believed to be the initial products. Specificity of recognition of pyrophosphate is discussed in terms of the sites, beta and gamma, for the -PO3H2 groups of pyrophosphate that will yield P-beta and P-gamma of the nascent nucleoside triphosphate. Site gamma can accept -AsO3H2 in place of -PO3H2, but less well; site beta can accept both, and also -CO2H. We suggest that partial transfer of an Mg2+ ion from the attacking pyrophosphate to the phosphate of the internucleotide bond of the RNA may increase the nucleophilic reactivity of the pyrophosphate and the electrophilicity of the diester, so that the reaction is assisted.     

Enzymatic method for continuous monitoring of DNA polymerase activity

A simple and rapid method for the assay of DNA polymerase activity has been developed. The PPi formation in the DNA polymerase reaction is continuously monitored by a coupled enzymatic method (P. Nyrén and A. Lundin, 1985, Anal. Biochem. 151, 504-509) utilizing the enzymes ATP-sulfurylase and firefly luciferase. The method has been used for continuous monitoring of DNA synthesis in vitro, and the effect of an inhibitor, adriamycin, on the polymerase activity was studied. The assay is very sensitive and yields linear responses between 1.5 and 30 micrograms/ml of DNA polymerase (Micrococcus luteus) (2-40 pmol of PPi generated per minute).     

Lycorine,a non-nucleoside RNA dependent RNA polymerase inhibitor,as potential treatment for emerging coronavirus infections

Background: Highly effective novel treatments need to be developed to suppress emerging coronavirus (CoV) infections such as COVID-19. The RNA dependent RNA polymerase (RdRp) among the viral proteins is known as an effective antiviral target. Lycorine is a phenanthridine Amaryllidaceae alkaloid isolated from the bulbs of Lycoris radiata (L'Hér.) Herb. and has various pharmacological bioactivities including antiviral function.Purpose: We investigated the direct-inhibiting action of lycorine on CoV's RdRp, as potential treatment for emerging CoV infections.Methods: We examined the inhibitory effect of lycorine on MERS-CoV, SARS-CoV, and SARS-CoV-2 infections, and then quantitatively measured the inhibitory effect of lycorine on MERS-CoV RdRp activity using a cell-based reporter assay. Finally, we performed the docking simulation with lycorine and SARS-CoV-2 RdRp.Results: Lycorine efficiently inhibited these CoVs with IC₅₀ values of 2.123 ± 0.053, 1.021 ± 0.025, and 0.878 ± 0.022 μM, respectively, comparable with anti-CoV effects of remdesivir. Lycorine directly inhibited MERS-CoV RdRp activity with an IC₅₀ of 1.406 ± 0.260 μM, compared with remdesivir's IC₅₀ value of 6.335 ± 0.731 μM. In addition, docking simulation showed that lycorine interacts with SARS-CoV-2 RdRp at the Asp623, Asn691, and Ser759 residues through hydrogen bonding, at which the binding affinities of lycorine (−6.2 kcal/mol) were higher than those of remdesivir (−4.7 kcal/mol).Conclusions: Lycorine is a potent non-nucleoside direct-acting antiviral against emerging coronavirus infections and acts by inhibiting viral RdRp activity; therefore, lycorine may be a candidate against the current COVID-19 pandemic.     

A minimal RNA promoter for minus-strand RNA synthesis by the brome mosaic virus polymerase complex

The approximately 150 nt tRNA-like structure present at the 3' end of each of the brome mosaic virus (BMV) genomic RNAs is sufficient to direct minus-strand RNA synthesis. RNAs containing mutations in the tRNA-like structure that decrease minus-strand synthesis were tested for their ability to interact with RdRp (RNA-dependent RNA polymerase) using a template competition assay. Mutations that are predicted to disrupt the pseudoknot and stem B1 do not affect the ability of the tRNA-like structure to interact with RdRp. Similarly, the +1 and +2 nucleotides are not required for stable template-RdRp interaction. Mutations in the bulge and hairpin loops of stem C decreased the ability of the tRNA-like structure to interact with RdRp. Furthermore, in the absence of the rest of the BMV tRNA, stem C is able to interact with RdRp. The addition of an accessible initiation sequence containing ACCA3' to stem C created an RNA capable of directing RNA synthesis. Synthesis from this minimal minus-strand template is dependent on sequences in the hairpin and bulged loops.     

Homogeneous fluorescent assay for RNA polymerase

A new method for determination of RNA polymerase (RNAP) activity is presented. The method uses nucleoside tri- and tetraphosphate derivatives carrying 4-methylumbelliferone residue at the terminal phosphate. Incorporation of such compounds in RNA by RNA polymerase is accompanied by release of di- and triphosphate derivatives of 4-methylumbelliferone. Subsequent treatment by alkaline phosphatase produces free 4-methylumbelliferone that is highly fluorescent and can be easily detected. The sensitivity of the method is higher than that reported in previous studies. The validity of the assay has been demonstrated by retrieving the RNAP inhibitors from a collection of 16,000 compounds.     

Molecular dynamics simulations of viral RNA polymerases link conserved and correlated motions of functional elements to fidelity

The viral RNA-dependent RNA polymerase (RdRp) is essential for multiplication of all RNA viruses. The sequence diversity of an RNA virus population contributes to its ability to infect the host. This diversity emanates from errors made by the RdRp during RNA synthesis. The physical basis for RdRp fidelity is unclear but is linked to conformational changes occurring during the nucleotide-addition cycle. To understand RdRp dynamics that might influence RdRp function, we have analyzed all-atom molecular dynamics simulations on the nanosecond timescale of four RdRps from the picornavirus family that exhibit 30-74% sequence identity. Principal component analysis showed that the major motions observed during the simulations derived from conserved structural motifs and regions of known function. The dynamics of residues participating in the same biochemical property, for example, RNA binding, nucleotide binding or catalysis, were correlated even when spatially distant on the RdRp structure. The conserved and correlated dynamics of functional structural elements suggest coevolution of dynamics with structure and function of the RdRp. Crystal structures of all picornavirus RdRps exhibit a template-nascent RNA duplex channel too small to fully accommodate duplex RNA. Simulations revealed opening and closing motions of the RNA and nucleoside triphosphate channels, which might be relevant to nucleoside triphosphate entry, inorganic pyrophosphate exit and translocation. A role for nanosecond timescale dynamics in RdRp fidelity is supported by the altered dynamics of the high-fidelity G64S derivative of PV RdRp relative to wild-type enzyme.     

Biochemical characterization of a recombinant Japanese encephalitis virus RNA-dependent RNA polymerase

Background  

Japanese encephalitis virus (JEV) NS5 is a viral nonstructural protein that carries both methyltransferase and RNA-dependent RNA polymerase (RdRp) domains. It is a key component of the viral RNA replicase complex that presumably includes other viral nonstructural and cellular proteins. The biochemical properties of JEV NS5 have not been characterized due to the lack of a robust in vitro RdRp assay system, and the molecular mechanisms for the initiation of RNA synthesis by JEV NS5 remain to be elucidated.     

Mutagenesis analysis of the rGTP-specific binding site of hepatitis C virus RNA-dependent RNA polymerase

Hepatitis C virus (HCV) nonstructural protein 5B (NS5B) is the virus-encoded RNA-dependent RNA polymerase (RdRp) essential for HCV RNA replication. An earlier crystallographic study identified a rGTP-specific binding site lying at the surface between the thumb domain and the fingertip about 30 A away from the active site of the HCV RdRp (S. Bressanelli, L. Tomei, F. A. Rey, and R. De Francesco, J. Virol 76:3482-3492, 2002). To determine its physiological importance, we performed a systematic mutagenesis analysis of the rGTP-specific binding pocket by amino acid substitutions. Effects of mutations of the rGTP-specific binding site on enzymatic activity were determined by an in vitro RdRp assay, while effects of mutations on HCV RNA replication were examined by cell colony formation, as well as by transient replication of subgenomic HCV RNAs. Results derived from these studies demonstrate that amino acid substitutions of the rGTP-specific binding pocket did not significantly affect the in vitro RdRp activity of purified recombinant NS5B proteins, as measured by their abilities to synthesize RNA on an RNA template containing the 3' untranslated region of HCV negative-strand RNA. However, most mutations of the rGTP-specific binding site either impaired or completely ablated the ability of subgenomic HCV RNAs to induce cell colony formation. Likewise, these mutations caused either reduction in or lethality to transient replication of the human immunodeficiency virus Tat-expressing HCV replicon RNAs in the cell. Collectively, these findings demonstrate that the rGTP-specific binding site of the HCV NS5B is not required for in vitro RdRp activity but is important for HCV RNA replication in vivo.