Expression, purification, and properties of recombinant encephalomyocarditis virus RNA-dependent RNA polymerase.

Encephalomyocarditis (EMC) virus RNA-dependent RNA polymerase was expressed in Escherichia coli as a fusion protein with glutathione S-transferase (GST), which allowed easy purification of the fusion protein by affinity chromatography on immobilized glutathione. Inclusion of a thrombin cleavage site between the GST carrier and the viral enzyme facilitated the release of purified mature EMC virus RNA polymerase from the GST carrier by proteolysis with thrombin. The purified recombinant enzyme has a molecular mass of about 52 kDa and is recognized by polyclonal immune serum raised against a peptide sequence corresponding to the C-terminal region of the protein. The recombinant enzyme comigrates with immunoprecipitated EMC virus RNA polymerase from infected mouse L929 cell extracts when run in parallel lanes on a sodium dodecyl sulfate-polyacrylamide gel. The enzyme exhibits rifampin-resistant, poly(A)-dependent poly(U) polymerase activity and RNA polymerase activity, which are both oligo(U) dependent. Template-size products are synthesized in in vitro reactions with EMC virus genomic RNA or globin mRNA. The availability of recombinant EMC virus RNA polymerase in a purified form will allow biochemical analysis of its role in the replication of the virus as well as structure-function studies of this unique class of enzyme.     

DNA polymerase I activity in Escherichia coli is influenced by spot 42 RNA.

We have shown that the level of DNA polymerase I (Pol I) activity in Escherichia coli is influenced by the level of a 109-nucleotide RNA, spot 42 RNA. Deletion of the gene for spot 42 RNA results in a 20 to 25% decrease in Pol I activity, as assayed by nucleotide incorporation in cell extracts and a decrease in the ability of cells to grow in the presence of the DNA-alkylating agent methyl methanesulfonate. Also, a physiological reduction of the level of spot 42 RNA, by growth in media containing poor carbon sources, results in a corresponding decrease in Pol I activity. Conversely, overproduction of spot 42 RNA results in a 10 to 15% increase in Pol I activity in vitro. Thus, changes in the amount of spot 42 RNA result in relatively small but significant changes in Pol I activity.     

Spacing mutations between the Escherichia coli pBAD RNA polymerase binding site and the araC (I) induction site

Mutations in the Escherichia coli promoter PBAD have been constructed which alter the spacing of the adjacent RNA polymerase and araC inducer protein binding sites. While deletion of a single base-pair or small insertions do not detectably affect araC protein binding to DNA and they do not alter the conserved sequence of the RNA polymerase binding site, stimulation of PBAD in vivo is greatly reduced. The experiments suggest that the distance or angle between the two proteins on the DNA is critical for promoter function.     

Localization of Escherichia coli rpoC mutations that affect RNA polymerase assembly and activity at high temperature

We localized five rpoC (beta') mutations affecting Escherichia coli RNA polymerase assembly. The Ts4, XH56, and R120 mutations changed beta' residues conserved throughout eubacteria; the JE10092 mutation occurred in the hypervariable region; rpoC1 (TsX) changed a universally conserved residue and corresponds to yeast rpb1-1. Thus, distinct, predominantly conserved beta' residues participate in interactions holding RNA polymerase together.     

Reactions at the polymerase active site that contribute to the fidelity of Escherichia coli DNA polymerase I (Klenow fragment).

In order to study the structural principles governing DNA polymerase fidelity we have measured the rates of insertion of incorrect nucleotides and the rates of extension from the resulting mismatched base pairs, catalyzed by the Klenow fragment of DNA polymerase I. Using a combination of semi-quantitative and qualitative approaches, we have studied each of the 12 possible mismatches in a variety of sequence contexts. The results indicate that Klenow fragment discriminates between mismatches largely on the basis of the identity of the mismatch, with the surrounding sequence context playing a significant, but secondary, role. For purine-pyrimidine and pyrimidine-pyrimidine mispairs, the relative ease of mismatch synthesis and extension can be rationalized using a simple geometrical model, with the important criterion being the extent to which the mismatched base pair can conform to normal DNA geometry. Essentially similar conclusions have been reached in studies of other polymerases, suggesting that this aspect of mispair geometry is sensed and responded to in a similar way by all polymerases. Purine-purine mismatches form a less cohesive class, showing more variable behavior from mispair to mispair, and a greater apparent susceptibility to sequence context effects. Comparison of our data with studies of other polymerases also suggests that different polymerases respond to purine-purine mismatches in distinct and characteristic ways. An extensive analysis of each of the four purine-purine mispairs in approximately 100 different sequence contexts suggests that the reaction is influenced both by the local DNA structure and by the ability of the mismatched terminus to undergo slippage.     

The conserved active site motif A of Escherichia coli DNA polymerase I is highly mutable

Escherichia coli DNA polymerase I participates in DNA replication, DNA repair, and genetic recombination; it is the most extensively studied of all DNA polymerases. Motif A in the polymerase active site has a required role in catalysis and is highly conserved. To assess the tolerance of motif A for amino acid substitutions, we determined the mutability of the 13 constituent amino acids Val(700)-Arg(712) by using random mutagenesis and genetic selection. We observed that every residue except the catalytically essential Asp(705) can be mutated while allowing bacterial growth and preserving wild-type DNA polymerase activity. Hence, the primary structure of motif A is plastic. We present evidence that mutability of motif A has been conserved during evolution, supporting the premise that the tolerance for mutation is adaptive. In addition, our work allows identification of refinements in catalytic function that may contribute to preservation of the wild-type motif A sequence. As an example, we established that the naturally occurring Ile(709) has a previously undocumented role in supporting sugar discrimination.     

Pheasant virus DNA polymerase is related to avian leukosis virus DNA polymerase at the active site.

The DNA polymerase from Amherst pheasant virus (APV), a member of the pheasant virus species of retroviruses, was compared to the DNA polymerases of avian leukosis viruses (ALV) and a reticuloendotheliosis virus (spleen necrosis virus (SNV)). Immunoglobulin inhibition tests and competition immunoassays showed that APV and ALV DNA polymerases are closely related at their active sites. The determinants common to their active sites are not shared by SNV DNA polymerase. Bu using a species-specific radioimmunoassay, it was shown that both APV and SNV DNA polymerases are grossly different from ALV DNA polymerase. The specificity of the relationship of the active sites of APV and ALV DNA polymerases was confirmed by a heterologous radioimmunoassay. Our data indicate that pheasant viruses are evolutionarily linked to ALV.     

RNA template-mediated inhibition of hepatitis C virus RNA-dependent RNA polymerase activity

The enzymatic activity of hepatitis C virus (HCV) RNA-dependent RNA polymerase NS5B is modulated by the molar ratio of NS5B enzyme and RNA template. Depending on the ratio, either template or enzyme can inhibit activity. Inhibition of NS5B activity by RNA template exhibited characteristics of substrate inhibition, suggesting the template binds to a secondary site on the enzyme forming an inactive complex. Template inhibition was modulated by primer. Increasing concentrations of primer restored NS5B activity and decreased the affinity of template for the secondary site. Conversely, increasing template concentration reduced the affinity of primer binding. The kinetic profiles suggest template inhibition results from the binding of template to a site that interferes with primer binding and the formation of productive replication complexes.     

Cyanobacterial RNA polymerase genes rpoC1 and rpoC2 correspond to rpoC of Escherichia coli.

The DNA-dependent RNA polymerase (ribonucleoside triphosphate:RNA nucleotidyltransferase, EC 2.7.7.6) of cyanobacteria contains a unique core component, gamma, which is absent from the RNA polymerases of other eubacteria (G. J. Schneider, N. E. Tumer, C. Richaud, G. Borbely, and R. Haselkorn, J. Biol. Chem. 262:14633-14639, 1987). We present the complete nucleotide sequence of rpoC1, the gene encoding the gamma subunit, from the heterocystous cyanobacterium Nostoc commune UTEX 584. The derived amino acid sequence of gamma (621 residues) corresponds with the amino-terminal portion of the beta' polypeptide of Escherichia coli RNA polymerase. A second gene in N. commune UTEX 584, rpoC2, encodes a protein which shows correspondence with the carboxy-terminal portion of the E. coli beta' subunit. The rpoBC1C2 genes of N. commune UTEX 584 are present in single copies and are arranged in the order rpoBC1C2, and the coding regions are separated by short AT-rich spacer regions which have the potential to form very stable secondary structures. Our data indicate the occurrence of divergent evolution of structure in the eubacterial DNA-dependent RNA polymerase.     

Influence of polyamines on the activity of DNA polymerase I from Escherichia coli.

The influence of polyamines on the various activities of DNA polymerase I from Escherichia coli (EC 2.7.7.7) has been investigated. For all high molecular weight DNAs spermine and spermidine caused up to 80% inhibition when present in high concentrations, i.e. above 1 mM for spermine and 2 mM for spermidine. In the presence of low concentrations of polyamines a small activation was seen for some DNAs. The diamines cadaverine and putrescine had little influence on the rate of synthesis with natural occurring DNAs. In the case of d(A--T)n the activation/inhibition was found to be markedly dependent on the molecular weight of the samples used. With a low molecular weight DNA, 5.6 S, addition of spermidine resulted in up to 3-fold stimulation of activity. The activation was dependent on the concentration of MgCl2 and ionic strength; increasing concentration of these gave a decrease in the degree of activation. Polyamines also had a dramatic effect on the rate of synthesis using the homopolymers (dA)n . (dT)10 and (rA)n . (dT)10 . (20:1) as primers. Putrescine, in particular, increased the activity up to 10-fold with (rA)n . (dT)10 and somewhat less for (dA)n . (dT)10. The apparent Km for the primer (rA)n . (dT)10 decreased approx. 35-fold in the presence of 6.6 mM putrescine. There was no influence on the apparent Km for dTTP. The influence of polyamines on both the 5' leads to 3' and 3' leads to 5' nuclease activity was also investigated. Inhibition of nuclease activity was observed in the presence of polyamines, particularly with spermine. Thus with d(A--T)n and T7 DNA as substrates addition of 0.7 mM spermine resulted in almost complete inhibition of the activity. The dramatic inhibition observed with high concentrations of spermine (spermidine) both in the case of polymerizing and nuclease activity is thought to be due to polyamine-induced aggregation of DNA molecules.     

Remote site control of an active site fidelity checkpoint in a viral RNA-dependent RNA polymerase

The kinetic, thermodynamic, and structural basis for fidelity of nucleic acid polymerases remains controversial. An understanding of viral RNA-dependent RNA polymerase (RdRp) fidelity has become a topic of considerable interest as a result of recent experiments that show that a 2-fold increase in fidelity attenuates viral pathogenesis and a 2-fold decrease in fidelity reduces viral fitness. Here we show that a conformational change step preceding phosphoryl transfer is a key fidelity checkpoint for the poliovirus RdRp (3Dpol). We provide evidence that this conformational change step is orientation of the triphosphate into a conformation suitable for catalysis, suggesting a kinetic and structural model for RdRp fidelity that can be extrapolated to other classes of nucleic acid polymerases. Finally, we show that a site remote from the catalytic center can control this checkpoint, which occurs at the active site. Importantly, similar connections between a remote site and the active site exist in a wide variety of viral RdRps. The capacity for sites remote from the catalytic center to alter fidelity suggests new possibilities for targeting the viral RdRp for antiviral drug development.     

Localization of binding site for encephalomyocarditis virus RNA polymerase in the 3'-noncoding region of the viral RNA.

We previously showed that encephalomyocarditis (EMC) virus RNA-dependent RNA polymerase (3Dpol) binds specifically to 3'-terminal segments of EMC virus RNA. This binding, which depends on both the 3'-noncoding region (3'-NCR) and 3'-poly (A) tail [together denoted 3'-NCR(A)], may be an important step in the initiation of virus replication. In this paper, the 3'-NCR and 3'-poly(A) were separately transcribed then mixed, but no complex with 3Dpol was obtained, showing that covalent attachment of the 3'-poly(A) to the 3'-NCR is essential for complex formation. Mutational and deletion analyses localized a critical determinant of 3Dpol binding to a U-rich sequence located 38-49 nucleotides upstream of the 3'-poly(A). Similar analyses led to the identification of a sequence of A residues between positions +10 and +15 of the 3'-poly(A) which are also critical for 3Dpol binding. As U-rich and A-rich regions are important for 3Dpol binding, a speculative model is proposed in which 3Dpol induces and stabilizes the base-pairing of the 3'-poly(A) with the adjacent U-rich sequence to form an unusual pseudoknot structure to which 3Dpol binds with high affinity.