Aptamers to Escherichia coli core RNA polymerase that sense its interaction with rifampicin, sigma-subunit and GreB

Highly specific aptamer trap for extremophilic RNA polymerases

During transcription initiation, the holoenzyme of bacterial RNA polymerase (RNAP) specifically recognizes promoters using a dedicated σ factor. During transcription elongation, the core enzyme of RNAP interacts with nucleic acids mainly nonspecifically, by stably locking the DNA template and RNA transcript inside the main cleft. Here, we present a synthetic DNA aptamer that is specifically recognized by both core and holoenzyme RNAPs from extremophilic bacteria of the Deinococcus-Thermus phylum. The aptamer binds RNAP with subnanomolar affinities, forming extremely stable complexes even at high ionic strength conditions, blocks RNAP interactions with the DNA template and inhibits RNAP activity during transcription elongation. We propose that the aptamer binds at a conserved site within the downstream DNA-binding cleft of RNAP and traps it in an inactive conformation. The aptamer can potentially be used for structural studies to reveal RNAP conformational states, affinity binding of RNAP and associated factors, and screening of transcriptional inhibitors.

Site-specific aptamer inhibitors of Thermus RNA polymerase

Bacterial RNA polymerase (RNAP) is an RNA-synthesizing molecular machine and a target for antibiotics. In transcription, RNAP can interact with DNA sequence-specifically, during promoter recognition by the σ-containing holoenzyme, or nonspecifically, during productive RNA elongation by the core RNAP. We describe high-affinity single-stranded DNA aptamers that are specifically recognized by the core RNAP from Thermus aquaticus. The aptamers interact with distinct epitopes inside the RNAP main channel, including the rifamycin pocket, and sense the binding of other RNAP ligands such as rifamycin and the σ^A subunit. The aptamers inhibit RNAP activity and can thus be used for functional studies of transcription and development of novel RNAP inhibitors.

Full shut-off of Escherichia coli RNA-polymerase by T7 phage requires a small phage-encoded DNA-binding protein

Infection of Escherichia coli by the T7 phage leads to rapid and selective inhibition of the bacterial RNA polymerase (RNAP) by the 7 kDa T7 protein Gp2. We describe the identification and functional and structural characterisation of a novel 7 kDa T7 protein, Gp5.7, which adopts a winged helix-turn-helix-like structure and specifically represses transcription initiation from host RNAP-dependent promoters on the phage genome via a mechanism that involves interaction with DNA and the bacterial RNAP. Whereas Gp2 is indispensable for T7 growth in E. coli, we show that Gp5.7 is required for optimal infection outcome. Our findings provide novel insights into how phages fine-tune the activity of the host transcription machinery to ensure both successful and efficient phage progeny development.

Single-stranded DNA aptamers for functional probing of bacterial RNA polymerase

Bacterial RNA polymerase (RNAP) is the main regulatory hub of gene transcription. During transcription, RNAP interacts with the DNA template, RNA product, nucleotide substrates, metal cofactors, and regulatory molecules that bind to distinct RNAP sites to modulate its activity. RNAP is also inhibited by several known antibiotics and is a promising target for development of novel antibacterial compounds. Despite great progress in structural analysis of RNAP in recent years, many details of RNAP interactions with nucleic acids, regulatory molecules and antibiotics remain insufficiently understood. Aptamers that target various epitopes on the RNAP molecule represent a useful tool for functional analysis of transcription. Here, we describe protocols for selection of highly specific aptamers to different components of RNAP and their applications for analysis of RNAP-ligand interactions and RNAP inhibition.

Single-strand promoter traps for bacterial RNA polymerase

Besides canonical double-strand DNA promoters, multisubunit RNAPs (RNA polymerases) recognize a number of specific single-strand DNA and RNA templates, resulting in synthesis of various types of RNA transcripts. The general recognition principles and the mechanisms of transcription initiation on these templates are not fully understood. To investigate further the molecular mechanisms underlying the transcription of single-strand templates by bacterial RNAP, we selected high-affinity single-strand DNA aptamers that are specifically bound by RNAP holoenzyme, and characterized a novel class of aptamer-based transcription templates. The aptamer templates have a hairpin structure that mimics the upstream part of the open promoter bubble with accordingly placed specific promoter elements. The affinity of the RNAP holoenzyme to such DNA structures probably underlies its promoter-melting activity. Depending on the template structure, the aptamer templates can direct synthesis of productive RNA transcripts or effectively trap RNAP in the process of abortive synthesis, involving DNA scrunching, and competitively inhibit promoter recognition. The aptamer templates provide a novel tool for structure-function studies of transcription initiation by bacterial RNAP and its inhibition.

Structural and mechanistic basis for the inhibition of Escherichia coli RNA polymerase by T7 Gp2

The T7 phage-encoded small protein Gp2 is a non-DNA-binding transcription factor that interacts with the jaw domain of the Escherichia coli (Ec) RNA polymerase (RNAp) β′ subunit and inhibits transcriptionally proficient promoter-complex (RPo) formation. Here, we describe the high-resolution solution structure of the Gp2-Ec β′ jaw domain complex and show that Gp2 and DNA compete for binding to the β′ jaw domain. We reveal that efficient inhibition of RPo formation by Gp2 requires the amino-terminal σ⁷⁰ domain region 1.1 (R1.1), and that Gp2 antagonizes the obligatory movement of R1.1 during RPo formation. We demonstrate that Gp2 inhibits RPo formation not just by steric occlusion of the RNAp-DNA interaction but also through long-range antagonistic effects on RNAp-promoter interactions around the RNAp active center that likely occur due to repositioning of R1.1 by Gp2. The inhibition of Ec RNAp by Gp2 thus defines a previously uncharacterized mechanism by which bacterial transcription is regulated by a viral factor.

Distinct functions of regions 1.1 and 1.2 of RNA polymerase σ subunits from Escherichia coli and Thermus aquaticus in transcription initiation

RNA polymerase (RNAP) from thermophilic Thermus aquaticus is characterized by higher temperature of promoter opening, lower promoter complex stability, and higher promoter escape efficiency than RNAP from mesophilic Escherichia coli. We demonstrate that these differences are in part explained by differences in the structures of the N-terminal regions 1.1 and 1.2 of the E. coli σ(70) and T. aquaticus σ(A) subunits. In particular, region 1.1 and, to a lesser extent, region 1.2 of the E. coli σ(70) subunit determine higher promoter complex stability of E. coli RNAP. On the other hand, nonconserved amino acid substitutions in region 1.2, but not region 1.1, contribute to the differences in promoter opening between E. coli and T. aquaticus RNAPs, likely through affecting the σ subunit contacts with DNA nucleotides downstream of the -10 element. At the same time, substitutions in σ regions 1.1 and 1.2 do not affect promoter escape by E. coli and T. aquaticus RNAPs. Thus, evolutionary substitutions in various regions of the σ subunit modulate different steps of the open promoter complex formation pathway, with regions 1.1 and 1.2 affecting promoter complex stability and region 1.2 involved in DNA melting during initiation.

Selection and analytical applications of aptamers binding microbial pathogens

DNA aptamers specifically recognizing microbial cells and viruses have a range of analytical and therapeutic applications. This article describes recent advances in the development of aptamers targeting specific pathogens (e.g., live bacteria, whole viral particles, and virally-infected mammalian cells). Specific aptamers against pathogens have been used as affinity reagents to develop sandwich assays, to label and to image cells, to bind with cells for flow-cytometry analysis, and to act as probes for development of whole-cell biosensors. Future applications of aptamers to pathogens will benefit from recent advances in improved selection and new aptamers containing modified nucleotides, particularly slow off-rate modified aptamers (SOMAmers).

Molecular insights into the control of transcription initiation at the Staphylococcus aureus agr operon

The accessory gene regulatory (agr) operon of the opportunistic human pathogen Staphylococcus aureus is a prime pathogenesis factor in this bacterium. The agr operon consists of two transcription units, RNAII and RNAIII, which are transcribed from divergent promoters, P2 and P3, respectively. RNAII encodes a quorum-sensing system, including AgrA, the master transcription activator of the agr operon. RNAIII is the effector RNA molecule that regulates the expression of many virulence genes. Owing to the atypical spacer lengths of P2 and P3, it is widely considered that transcription from P2 and P3 only occurs in a strictly AgrA-dependent manner. Here, using a fully native S. aureus in vitro transcription system, we provide the first molecular and mechanistic characterisation of the regulation of transcription initiation at the agr operon. Surprisingly, the results demonstrate that RNA polymerase (RNAp) can interact with P2 and P3 equally well in the absence of AgrA. However, formation of a transcription-competent open promoter complex (RPo) occurs more readily at P2 than at P3 when AgrA is absent. Reducing the atypical P3 spacer region length to the optimal length of 17 nucleotides significantly improves promoter activity by facilitating the isomerisation of the initial RNAp-P3 complexes to RPo, and the extended -10-like element of P3 is required for optimal promoter activity. AgrA increases the occupancy of both promoters by RNAp and thereby increases the amount of transcription initiated at P2 and P3. However, the AgrA-mediated effect on transcription initiation is more prominent at P3 that at P2. The effect of AgrA at P2 and P3 appears to be restricted to events leading to the formation of RPo. The relevance of AgrA-independent and AgrA-dependent transcription initiation at P2 and P3 is presented in the context of our current understanding of the role of the agr operon in the pathobiology of S. aureus.

Methods for selection of aptamers to protein targets

Aptamers are synthetic single-stranded RNA or DNA molecules capable of specific binding to other target molecules. In this review, the main aptamer properties are considered and methods for selection of aptamers against various protein targets are described. Special attention is given to the methods for directed selection of aptamers, which allow one to obtain ligands with specified properties.

Inhibition of hepatitis C virus (HCV) RNA polymerase by DNA aptamers: mechanism of inhibition of in vitro RNA synthesis and effect on HCV-infected cells

We describe here the further characterization of two DNA aptamers that specifically bind to hepatitis C virus (HCV) RNA polymerase (NS5B) and inhibit its polymerase activity in vitro. Although they were obtained from the same selection procedure and contain an 11-nucleotide consensus sequence, our results indicate that aptamers 27v and 127v use different mechanisms to inhibit HCV polymerase. While aptamer 27v was able to compete with the RNA template for binding to the enzyme and blocked both the initiation and the elongation of RNA synthesis, aptamer 127v competed poorly and exclusively inhibited initiation and postinitiation events. These results illustrate the power of the selective evolution of ligands by exponential enrichment in vitro selection procedure approach to select specific short DNA aptamers able to inhibit HCV NS5B by different mechanisms. We also determined that, in addition to an in vitro inhibitory effect on RNA synthesis, aptamer 27v was able to interfere with the multiplication of HCV JFH1 in Huh7 cells. The efficient cellular entry of these short DNAs and the inhibitory effect observed on human cells infected with HCV indicate that aptamers are useful tools for the study of HCV RNA synthesis, and their use should become a very attractive and alternative approach to therapy for HCV infection.

A mathematical analysis of SELEX

Systematic evolution of ligands by exponential enrichment (SELEX) is a procedure by which a mixture of nucleic acids that vary in sequence can be separated into pure components with the goal of isolating those with specific biochemical activities. The basic idea is to combine the mixture with a specific target molecule and then separate the target-NA complex from the resulting reaction. The target-NA complex is then separated by mechanical means (for example by filtration), the NA is then eluted from the complex, amplified by polymerase chain reaction (PCR) and the process repeated. After several rounds, one should be left with a pool of [NA] that consists mostly of the species in the original pool that best binds to the target. In Irvine et al. [Irvine, D., Tuerk, C., Gold, L., 1991. SELEXION, systematic evolution of nucleic acids by exponential enrichment with integrated optimization by non-linear analysis. J. Mol. Biol. 222, 739-761] a mathematical analysis of this process was given. In this paper we revisit Irvine et al. [Ibid]. By rewriting the equations for the SELEX process, we considerably reduce the labor of computing the round to round distribution of nucleic acid fractions. We also establish necessary and sufficient conditions for the SELEX process to converge to a pool consisting solely of the best binding nucleic acid to a fixed target in a manner that maximizes the percentage of bound target. The assumption is that there is a single nucleic acid binding site on the target that permits occupation by not more than one nucleic acid. We analyze the case for which there is no background loss (no support losses and no free [NA] left on the support). We then examine the case in which such there are such losses. The significance of the analysis is that it suggests an experimental approach for the SELEX process as defined in Irvine et al. [Ibid] to converge to a pool consisting of a single best binding nucleic acid without recourse to any a priori information about the nature of the binding constants or the distribution of the individual nucleic acid fragments.

A basal promoter element recognized by free RNA polymerase sigma subunit determines promoter recognition by RNA polymerase holoenzyme

During transcription initiation by bacterial RNA polymerase, the sigma subunit recognizes the -35 and -10 promoter elements; free sigma, however, does not bind DNA. We selected ssDNA aptamers that strongly and specifically bound free sigma(A) from Thermus aquaticus. A consensus sequence, GTA(C/T)AATGGGA, was required for aptamer binding to sigma(A), with the TA(C/T)AAT segment making interactions similar to those made by the -10 promoter element (consensus sequence TATAAT) in the context of RNA polymerase holoenzyme. When in dsDNA form, the aptamers function as strong promoters for the T. aquaticus RNA polymerase sigma(A) holoenzyme. Recognition of the aptamer-based promoters depends on the downstream GGGA motif from the aptamers' common sequence, which is contacted by sigma(A) region 1.2 and directs transcription initiation even in the absence of the -35 promoter element. Thus, recognition of bacterial promoters is controlled by independent interactions of sigma with multiple basal promoter elements.

RNA aptamers selected against DNA polymerase beta inhibit the polymerase activities of DNA polymerases beta and kappa

DNA polymerase β (polβ), a member of the X family of DNA polymerases, is the major polymerase in the base excision repair pathway. Using in vitro selection, we obtained RNA aptamers for polβ from a variable pool of 8 × 10¹² individual RNA sequences containing 30 random nucleotides. A total of 60 individual clones selected after seven rounds were screened for the ability to inhibit polβ activity. All of the inhibitory aptamers analyzed have a predicted tri-lobed structure. Gel mobility shift assays demonstrate that the aptamers can displace the DNA substrate from the polβ active site. Inhibition by the aptamers is not polymerase specific; inhibitors of polβ also inhibited DNA polymerase κ, a Y-family DNA polymerase. However, the RNA aptamers did not inhibit the Klenow fragment of DNA polymerase I and only had a minor effect on RB69 DNA polymerase activity. Polβ and κ, despite sharing little sequence similarity and belonging to different DNA polymerase families, have similarly open active sites and relatively few interactions with their DNA substrates. This may allow the aptamers to bind and inhibit polymerase activity. RNA aptamers with inhibitory properties may be useful in modulating DNA polymerase actvity in cells.