Peculiar 2-aminopurine fluorescence monitors the dynamics of open complex formation by bacteriophage T7 RNA polymerase

The kinetics of promoter binding and open complex formation in bacteriophage T7 RNA polymerase was investigated using 2-aminopurine (2-AP) modified promoters. 2-AP serves as an ideal probe to measure the kinetics of open complex formation because its fluorescence is sensitive to both base-unpairing and base-unstacking and to the nature of the neighboring bases. All four 2-AP bases in the TATA box showed an increase in fluorescence with similar kinetics upon binding to the T7 RNA polymerase, indicating that the TATA sequence becomes unpaired in a concerted manner. The 2-AP at -4 showed a peculiarly large increase in fluorescence upon binding to the T7 RNA polymerase. Based on the recent crystal structure of the T7 RNA polymerase-DNA complex, we propose that the large fluorescence increase is due to unstacking of the 2-AP base at -4 from the guanine at -5, during open complex formation. The unstacking may be a critical event in directing and placing the template strand correctly in the T7 RNA polymerase active site upon promoter melting for template directed RNA synthesis. Based on equilibrium fluorescence and stopped-flow kinetic studies, we propose that a fast form of T7 RNA polymerase binds promoter double-stranded DNA by a three-step mechanism. The initial collision complex or a closed complex, ED(c) is formed with a K(d) of 1.8 microm. This complex isomerizes to an open complex, ED(o1), in an energetically unfavorable reaction with an equilibrium constant of 0.12. The ED(o1) further isomerizes to a more stable open complex, ED(o2), with a rate constant around 300 s(-1). Thus, in the absence of the initiating nucleotide, GTP, the overall equilibrium constant for closed to open complex conversion is 0.5 and the net rate of open complex formation is nearly 150 s(-1).     

De novo initiation pocket mutations have multiple effects on hepatitis C virus RNA-dependent RNA polymerase activities

The hepatitis C virus (HCV) RNA-dependent RNA polymerase (RdRp) has several distinct biochemical activities, including initiation of RNA synthesis by a de novo mechanism, extension from a primed template, nontemplated nucleotide addition, and synthesis of a recombinant RNA product from two or more noncovalently linked templates (template switch). All of these activities require specific interaction with nucleoside triphosphates (NTPs). Based on the structure of the HCV RdRp bound to NTP (S. Bressanelli, L. Tomei, F. A. Rey, and R. DeFrancesco, J. Virol. 76:3482-3492, 2002), we mutated the amino acid residues that contact the putative initiation GTP and examined the effects on the various activities. Although all mutations retained the ability for primer extension, alanine substitution at R48, R158, R386, R394, or D225 decreased de novo initiation, and two or more mutations abolished de novo initiation. While the prototype enzyme had a K(m) for GTP of 3.5 microM, all of the mutations except one had K(m)s that were three- to sevenfold higher. These results demonstrate that the affected residues are functionally required to interact with the initiation nucleotide. Unexpectedly, many of the mutations also affected the addition of nontemplated nucleotide, indicating that residues in the initiating NTP (NTPi)-binding pocket are required for nontemplated nucleotide additions. Interestingly, mutations in D225 are dramatically affected in template switch, indicating that this residue of the NTPi pocket also interacts with components in the elongation complex. We also examined the interaction of ribavirin triphosphate with the NTPi-binding site.     

Sensitivity of the Polymerase of Vesicular Stomatitis Virus to 2′ Substitutions in the Template and Nucleotide Triphosphate during Initiation and Elongation

The RNA synthesis machinery of non-segmented negative-sense RNA viruses comprises a ribonucleoprotein complex of the genomic RNA coated by a nucleocapsid protein (N) and associated with polymerase. Work with vesicular stomatitis virus (VSV), a prototype, supports a model of RNA synthesis whereby N is displaced from the template to allow the catalytic subunit of the polymerase, the large protein (L) to gain access to the RNA. Consistent with that model, purified L can copy synthetic RNA that contains requisite promoter sequences. Full processivity of L requires its phosphoprotein cofactor and the template-associated N. Here we demonstrate the importance of the 2′ position of the RNA template and the substrate nucleotide triphosphates during initiation and elongation by L. The VSV polymerase can initiate on both DNA and RNA and can incorporate dNTPs. During elongation, the polymerase is sensitive to 2′ modifications, although dNTPs can be incorporated, and mixed DNA-RNA templates can function. Modifications to the 2′ position of the NTP, including 2′,3′-ddCTP, arabinose-CTP, and 2′-O-methyl-CTP, inhibit polymerase, whereas 2′-amino-CTP is incorporated. The inhibitory effects of the NTPs were more pronounced on authentic N-RNA with the exception of dGTP, which is incorporated. This work underscores the sensitivity of the VSV polymerase to nucleotide modifications during initiation and elongation and highlights the importance of the 2′-hydroxyl of both template and substrate NTP. Moreover, this study demonstrates a critical role of the template-associated N protein in the architecture of the RNA-dependent RNA polymerase domain of L.     

Mechanism of primer synthesis by the herpes simplex virus 1 helicase-primase

We utilized templates of defined sequence to investigate the mechanism of primer synthesis by herpes simplex virus 1 helicase-primase. Under steady-state conditions, the rate of primer synthesis and the size distribution of products remained constant with time, suggesting that the rate-limiting step(s) of primer synthesis occur(s) during primer initiation (at or before the formation of the pppNpN dinucleotide). Consistent with this idea, increasing the concentration of NTPs required for dinucleotide synthesis increased the rate of primer synthesis, whereas increasing the concentration of NTPs not involved in dinucleotide synthesis inhibited primer synthesis. Due to these effects on primer initiation, varying the NTP concentration could affect start site selection on templates containing multiple G-pyr-pyr initiation sites. Increasing the NTP concentration also increased the processivity of primase. However, even at very high concentrations of NTPs, elongation of the dinucleotide into longer products remained relatively inefficient. Primase did not readily elongate preexisting primers under conditions where free template was present in large excess of enzyme. However, if template concentrations were lowered such that primase synthesized primers on all or most of the template present in the reaction, then primase would elongate previously synthesized primers.