Recombinant Thermus aquaticus RNA polymerase, a new tool for structure-based analysis of transcription

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.

Biochemical characterization of Mycobacterial RNA polymerases

Tuberculosis is caused by the bacterium Mycobacterium tuberculosis (Mtb). While eukaryotic species employ several specialized RNA polymerases (Pols) to fulfill the RNA synthesis requirements of the cell, bacterial species use a single RNA polymerase (RNAP). To contribute to the foundational understanding of how Mtb and the related non-pathogenic mycobacterial species, Mycobacterium smegmatis (Msm), perform the essential function of RNA synthesis, we performed a series of in vitro transcription experiments to define the unique enzymatic properties of Mtb and Msm RNAPs. In this study, we characterize the mechanism of nucleotide addition used by these bacterial RNAPs with comparisons to previously characterized eukaryotic Pols I, II, and III. We show that Mtb RNAP and Msm RNAP demonstrate similar enzymatic properties and nucleotide addition kinetics to each other but diverge significantly from eukaryotic Pols. We also show that Mtb RNAP and Msm RNAP uniquely bind a nucleotide analog with significantly higher affinity than canonical nucleotides, in contrast to eukaryotic RNA polymerase II. This affinity for analogs may reveal a vulnerability for selective inhibition of the pathogenic bacterial enzyme.IMPORTANCETuberculosis, caused by the bacterium Mycobacterium tuberculosis (Mtb), remains a severe global health threat. The World Health Organization (WHO) has reported that tuberculosis is second only to COVID-19 as the most lethal infection worldwide, with more annual deaths than HIV and AIDS (WHO.int). The first-line treatment for tuberculosis, Rifampin (or Rifampicin), specifically targets the Mtb RNA polymerase. This drug has been used for decades, leading to increased numbers of multi-drug-resistant infections (Stephanie, et al). To effectively treat tuberculosis, there is an urgent need for new therapeutics that selectively target vulnerabilities of the bacteria and not the host. Characterization of the differences between Mtb enzymes and host enzymes is critical to inform these ongoing drug design efforts.

The effect of pseudoknot base pairing on cotranscriptional structural switching of the fluoride riboswitch

A central question in biology is how RNA sequence changes influence dynamic conformational changes during cotranscriptional folding. Here we investigated this question through the study of transcriptional fluoride riboswitches, non-coding RNAs that sense the fluoride anion through the coordinated folding and rearrangement of a pseudoknotted aptamer domain and a downstream intrinsic terminator expression platform. Using a combination of Escherichia coli RNA polymerase in vitro transcription and cellular gene expression assays, we characterized the function of mesophilic and thermophilic fluoride riboswitch variants. We showed that only variants containing the mesophilic pseudoknot function at 37°C. We next systematically varied the pseudoknot sequence and found that a single wobble base pair is critical for function. Characterizing thermophilic variants at 65°C through Thermus aquaticus RNA polymerase in vitro transcription showed the importance of this wobble pair for function even at elevated temperatures. Finally, we performed all-atom molecular dynamics simulations which supported the experimental findings, visualized the RNA structure switching process, and provided insight into the important role of magnesium ions. Together these studies provide deeper insights into the role of riboswitch sequence in influencing folding and function that will be important for understanding of RNA-based gene regulation and for synthetic biology applications.

The Effect of Pseudoknot Base Pairing on Cotranscriptional Structural Switching of the Fluoride Riboswitch

A central question in biology is how RNA sequence changes influence dynamic conformational changes during cotranscriptional folding. Here we investigated this question through the study of transcriptional fluoride riboswitches, non-coding RNAs that sense the fluoride anion through the coordinated folding and rearrangement of a pseudoknotted aptamer domain and a downstream intrinsic terminator expression platform. Using a combination of E. coli RNA polymerase in vitro transcription and cellular gene expression assays, we characterized the function of mesophilic and thermophilic fluoride riboswitch variants. We showed that only variants containing the mesophilic pseudoknot function at 37 °C. We next systematically varied the pseudoknot sequence and found that a single wobble base pair is critical for function. Characterizing thermophilic variants at 65 °C through Thermus aquaticus RNA polymerase in vitro transcription showed the importance of this wobble pair for function even at elevated temperatures. Finally, we performed all-atom molecular dynamics simulations which supported the experimental findings, visualized the RNA structure switching process, and provided insight into the important role of magnesium ions. Together these studies provide deeper insights into the role of riboswitch sequence in influencing folding and function that will be important for understanding of RNA-based gene regulation and for synthetic biology applications.

Overproduction, purification, and transcriptional activity of recombinant Acinetobacter baylyi ADP1 RNA polymerase holoenzyme

Acinetobacter baylyi is an interesting model organism to investigate bacterial metabolism due to its vast repertoire of metabolic enzymes and ease of genetic manipulation. However, the study of gene expression in vitro is dependent on the availability of its RNA polymerase (RNAp), an essential enzyme in transcription. In this work, we developed a convenient method of producing the recombinant A. baylyi ADP1 RNA polymerase holoenzyme (RNAp^holo) in E. coli that yields 22 mg of a >96% purity protein from a 1-liter shake flask culture. We further characterized the A. baylyi ADP1 RNAp^holo kinetic profile using T7 Phage DNA as template and demonstrated that it is a highly transcriptionally active enzyme with an elongation rate of 24 nt/s and a termination efficiency of 94%. Moreover, the A. baylyi ADP1 RNAp^holo has a substantial sequence identity (∼95%) with the RNAp^holo from the human pathogen Acinetobacter baumannii. This protein can serve as a source of material for structural and biological studies towards advancing our understanding of genome expression and regulation in Acinetobacter species.

Suppressor mutations in Escherichia coli RNA polymerase alter transcription initiation but do not affect translesion RNA synthesis in vitro

Bacterial RNA polymerase (RNAP) coordinates transcription with DNA repair and replication. Many RNAP mutations have pleiotropic phenotypes with profound effects on transcription-coupled processes. One class of RNAP mutations (rpo*) has been shown to suppress mutations in regulatory factors responsible for changes in gene expression during stationary phase or starvation, as well as in factors involved in the restoration of replication forks after DNA damage. These mutations were suggested to affect the ability of RNAP to transcribe damaged DNA and to decrease the stability of transcription complexes, thus facilitating their dislodging during DNA replication and repair, although this was not explicitly demonstrated. Here, we obtained nine mutations of this class located around the DNA/RNA binding cleft of E. coli RNAP and analyzed their transcription properties in vitro. We found that these mutations decreased promoter complex stability to varying degrees and all decreased the activity of rRNA promoters. However, they did not have strong effects on elongation complex stability. Some mutations were shown to stimulate transcriptional pauses or decrease intrinsic RNA cleavage by RNAP, but none altered the ability of RNAP to transcribe DNA templates containing damaged nucleotides. Thus, we conclude that the suppressor phenotypes of the mutations are unlikely to result from direct effects on DNA lesion recognition by RNAP but may be primarily explained by changes in transcription initiation. Further analysis of the effects of these mutations on the genomic distribution of RNAP and its interactions with regulatory factors will be essential for understanding their diverse phenotypes in vivo.

Inhibition of RNA Polymerase by Rifampicin and Rifamycin-Like Molecules

RNA polymerases (RNAPs) accomplish the first step of gene expression in all living organisms. However, the sequence divergence between bacterial and human RNAPs makes the bacterial RNAP a promising target for antibiotic development. The most clinically important and extensively studied class of antibiotics known to inhibit bacterial RNAP are the rifamycins. For example, rifamycins are a vital element of the current combination therapy for treatment of tuberculosis. Here, we provide an overview of the history of the discovery of rifamycins, their mechanisms of action, the mechanisms of bacterial resistance against them, and progress in their further development.

Overproduction and purification of highly active recombinant Pseudomonas aeruginosa str. PAO1 RNA polymerase holoenzyme complex

The bacterial RNA polymerase (RNAP) is a large, complex molecular machine that is the engine of gene expression. Despite global conservation in their structures and function, RNAPs from different bacteria can have unique features in promoter and transcription factor recognition. Therefore, availability of purified RNAP from different bacteria is key to understanding these species-specific aspects and will be valuable for antibiotic drug discovery. Pseudomonas aeruginosa is one of the leading causes of hospital and community acquired infections worldwide - making the organism an important public health pathogen. We developed a method for producing high quantities of highly pure and active recombinant P. aeruginosa str. PAO1 RNAP core and holoenzyme complexes that employed two-vector systems for expressing the core enzyme (α, β, β', and ω subunits) and for expressing the holoenzyme complex (core + σ⁷⁰). Unlike other RNAP expression approaches, we used a low temperature autoinduction system in E. coli with T7 promoters that produced high cell yields and stable protein expression. The purification strategy comprised of four chromatographic separation steps (metal chelate, heparin, and ion-exchange) with yields of up to 11 mg per 500 mL culture. Purified holoenzyme and reconstituted holoenzyme from core and σ⁷⁰ were highly active at transcribing both small and large-sized DNA templates, with a determined elongation rate of ~18 nt/s for the holoenzyme. The successful purification of the P. aeruginosa RNAP provides a gateway for studies focusing on in vitro transcriptional regulation in this pathogen.

Interactions in the active site of Deinococcus radiodurans RNA polymerase during RNA proofreading

Co-transcriptional RNA proofreading by RNA polymerase (RNAP) is essential for accurate mRNA synthesis and reactivation of stalled transcription complexes, which can otherwise compromise genome integrity. RNAP from the stress-resistant bacterium Deinococcus radiodurans exhibits high levels of RNA cleavage in comparison with RNAP from Escherichia coli, which allows it to remove misincorporated nucleotides with high efficiency. Here, we show that the rate of RNA cleavage by D. radiodurans RNAP depends on the structure of the (mis)matched RNA 3'-nucleotide and its contacts with the active site. These interactions likely position the reactive phosphodiester bond in the cleavage-competent conformation, thus facilitating its hydrolysis catalyzed by metal ions in the active center. The universal RNA cleavage factor GreA largely alleviates defects in RNA cleavage caused by modifications in the RNA 3'-nucleotide or in its binding pocket in RNAP, suggesting that GreA functionally substitutes for these contacts. The results demonstrate that various RNAPs rely on a conserved mechanism for RNA proofreading, which can be modulated by changes in accessory parts of the active center.

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.

Lineage-specific variations in the trigger loop modulate RNA proofreading by bacterial RNA polymerases

RNA cleavage by bacterial RNA polymerase (RNAP) has been implicated in transcriptional proofreading and reactivation of arrested transcription elongation complexes but its molecular mechanism is less understood than the mechanism of nucleotide addition, despite both reactions taking place in the same active site. RNAP from the radioresistant bacterium Deinococcus radiodurans is characterized by highly efficient intrinsic RNA cleavage in comparison with Escherichia coli RNAP. We find that the enhanced RNA cleavage activity largely derives from amino acid substitutions in the trigger loop (TL), a mobile element of the active site involved in various RNAP activities. The differences in RNA cleavage between these RNAPs disappear when the TL is deleted, or in the presence of GreA cleavage factors, which replace the TL in the active site. We propose that the TL substitutions modulate the RNA cleavage activity by altering the TL folding and its contacts with substrate RNA and that the resulting differences in transcriptional proofreading may play a role in bacterial stress adaptation.

A dynamic DNA-repair complex observed by correlative single-molecule nanomanipulation and fluorescence

We characterize in real time the composition and catalytic state of the initial Escherichia coli transcription-coupled repair (TCR) machinery by using correlative single-molecule methods. TCR initiates when RNA polymerase (RNAP) stalled by a lesion is displaced by the Mfd DNA translocase, thus giving repair components access to the damage. We previously used DNA nanomanipulation to obtain a nanomechanical readout of protein-DNA interactions during TCR initiation. Here we correlate this signal with simultaneous single-molecule fluorescence imaging of labeled components (RNAP, Mfd or RNA) to monitor the composition and localization of the complex. Displacement of stalled RNAP by Mfd results in loss of nascent RNA but not of RNAP, which remains associated with Mfd as a long-lived complex on the DNA. This complex translocates at ∼4 bp/s along the DNA, in a manner determined by the orientation of the stalled RNAP on the DNA.

Fluorescently labeled recombinant RNAP system to probe archaeal transcription initiation

The transcriptional apparatus is one of the most complex cellular machineries and in order to fully appreciate the behavior of these protein-nucleic acid assemblies one has to understand the molecular details of the system. In addition to classical biochemical and structural studies, fluorescence-based techniques turned out as an important--and sometimes the critical--tool to obtain information about the molecular mechanisms of transcription. Fluorescence is not only a multi-modal parameter that can report on molecular interactions, environment and oligomerization status. Measured on the single-molecule level it also informs about the heterogeneity of the system and gives access to distances and distance changes in the molecular relevant nanometer regime. A pre-requisite for fluorescence-based measurements is the site-specific incorporation of one or multiple fluorescent dyes. In this respect, the archaeal transcription system is ideally suited as it is available in a fully recombinant form and thus allows for site-specific modification via sophisticated labeling schemes. The application of fluorescence based approaches to the archaeal transcription apparatus changed our understanding of the molecular mechanisms and dynamics that drive archaeal transcription and unraveled the architecture of transcriptional complexes not amenable to structural interrogation.

Mycobacterial RNA polymerase requires a U-tract at intrinsic terminators and is aided by NusG at suboptimal terminators

Intrinsic terminators, which encode GC-rich RNA hairpins followed immediately by a 7-to-9-nucleotide (nt) U-rich “U-tract,” play principal roles of punctuating and regulating transcription in most bacteria. However, canonical intrinsic terminators with strong U-tracts are underrepresented in some bacterial lineages, notably mycobacteria, leading to proposals that their RNA polymerases stop at noncanonical intrinsic terminators encoding various RNA structures lacking U-tracts. We generated recombinant forms of mycobacterial RNA polymerase and its major elongation factors NusA and NusG to characterize mycobacterial intrinsic termination. Using in vitro transcription assays devoid of possible mycobacterial contaminants, we established that mycobacterial RNA polymerase terminates more efficiently than Escherichia coli RNA polymerase at canonical terminators with imperfect U-tracts but does not terminate at putative terminators lacking U-tracts even in the presence of mycobacterial NusA and NusG. However, mycobacterial NusG exhibits a novel termination-stimulating activity that may allow intrinsic terminators with suboptimal U-tracts to function efficiently.

Bacteria rely on transcription termination to define and regulate units of gene expression. In most bacteria, precise termination and much regulation by attenuation are accomplished by intrinsic terminators that encode GC-rich hairpins and U-tracts necessary to disrupt stable transcription elongation complexes. Thus, the apparent dearth of canonical intrinsic terminators with recognizable U-tracts in mycobacteria is of significant interest both because noncanonical intrinsic terminators could reveal novel routes to destabilize transcription complexes and because accurate understanding of termination is crucial for strategies to combat mycobacterial diseases and for computational bioinformatics generally. Our finding that mycobacterial RNA polymerase requires U-tracts for intrinsic termination, which can be aided by NusG, will guide future study of mycobacterial transcription and aid improvement of predictive algorithms to annotate bacterial genome sequences.

RNA polymerase-promoter interactions determining different stability of the Escherichia coli and Thermus aquaticus transcription initiation complexes

Transcription initiation complexes formed by bacterial RNA polymerases (RNAPs) exhibit dramatic species-specific differences in stability, leading to different strategies of transcription regulation. The molecular basis for this diversity is unclear. Promoter complexes formed by RNAP from Thermus aquaticus (Taq) are considerably less stable than Escherichia coli RNAP promoter complexes, particularly at temperatures below 37°C. Here, we used a fluorometric RNAP molecular beacon assay to discern partial RNAP-promoter interactions. We quantitatively compared the strength of E. coli and Taq RNAPs partial interactions with the −10, −35 and UP promoter elements; the TG motif of the extended −10 element; the discriminator and the downstream duplex promoter segments. We found that compared with Taq RNAP, E. coli RNAP has much higher affinity only to the UP element and the downstream promoter duplex. This result indicates that the difference in stability between E. coli and Taq promoter complexes is mainly determined by the differential strength of core RNAP–DNA contacts. We suggest that the relative weakness of Taq RNAP interactions with DNA downstream of the transcription start point is the major reason of low stability and temperature sensitivity of promoter complexes formed by this enzyme.

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.

Characteristics of σ-dependent pausing by RNA polymerases from Escherichia coli and Thermus aquaticus

The σ(70) subunit of RNA polymerase (RNAP) is the major transcription initiation factor in Escherichia coli. During transcription initiation, conserved region 2 of the σ(70) subunit interacts with the -10 promoter element and plays a key role in DNA melting around the starting point of transcription. During transcription elongation, the σ(70) subunit can induce pauses in RNA synthesis owing to interactions of region 2 with DNA regions similar to the -10 promoter element. We demonstrated that the major σ subunit from Thermus aquaticus (σ(A)) is also able to induce transcription pausing by T. aquaticus RNAP. However, hybrid RNAP containing the σ(A) subunit and E. coli core RNAP is unable to form pauses during elongation, while being able to recognize promoters and initiate transcription. Inability of the σ(A) subunit to induce pausing by E. coli RNAP is explained by the substitutions of non-conserved amino acids in region 2, in the subregions interacting with the RNAP core enzyme. Thus, changes in the structure of region 2 of the σ(70) subunit have stronger effects on transcription pausing than on promoter recognition, likely by weakening the interactions of the σ subunit with the core RNAP during transcription elongation.

A novel phage-encoded transcription antiterminator acts by suppressing bacterial RNA polymerase pausing

Gp39, a small protein encoded by Thermus thermophilus phage P23–45, specifically binds the host RNA polymerase (RNAP) and inhibits transcription initiation. Here, we demonstrate that gp39 also acts as an antiterminator during transcription through intrinsic terminators. The antitermination activity of gp39 relies on its ability to suppress transcription pausing at poly(U) tracks. Gp39 also accelerates transcription elongation by decreasing RNAP pausing and backtracking but does not significantly affect the rates of catalysis of individual reactions in the RNAP active center. We mapped the RNAP-gp39 interaction site to the β flap, a domain that forms a part of the RNA exit channel and is also a likely target for λ phage antiterminator proteins Q and N, and for bacterial elongation factor NusA. However, in contrast to Q and N, gp39 does not depend on NusA or other auxiliary factors for its activity. To our knowledge, gp39 is the first characterized phage-encoded transcription factor that affects every step of the transcription cycle and suppresses transcription termination through its antipausing activity.

Allosteric control of catalysis by the F loop of RNA polymerase

Bacterial RNA polymerases (RNAPs) undergo coordinated conformational changes during catalysis. In particular, concerted folding of the trigger loop and rearrangements of the bridge helix at the RNAP active center have been implicated in nucleotide addition and RNAP translocation. At moderate temperatures, the rate of catalysis by RNAP from thermophilic Thermus aquaticus is dramatically reduced compared with its closest mesophilic relative, Deinococcus radiodurans. Here, we show that a part of this difference is conferred by a third element, the F loop, which is adjacent to the N terminus of the bridge helix and directly contacts the folded trigger loop. Substitutions of amino acid residues in the F loop and in an adjacent segment of the bridge helix in T. aquaticus RNAP for their D. radiodurans counterparts significantly increased the rate of catalysis (up to 40-fold at 20 degrees C). A deletion in the F loop dramatically impaired the rate of nucleotide addition and pyrophosphorolysis, but it had only a moderate effect on intrinsic RNA cleavage. Streptolydigin, an antibiotic that blocks folding of the trigger loop, did not inhibit nucleotide addition by the mutant enzyme. The resistance to streptolydigin likely results from the loss of its functional target, the folding of the trigger loop, which is already impaired by the F-loop deletion. Our results demonstrate that the F loop is essential for proper folding of the trigger loop during nucleotide addition and governs the temperature adaptivity of RNAPs in different bacteria.

In vitro approaches to analysis of transcription termination

Transcription termination is an important event in the transcription cycle that has been exploited in a variety of genetic regulatory mechanisms. Analysis of transcription termination is greatly facilitated by in vitro approaches. We describe a basic protocol for analysis of transcription termination in vitro, and include descriptions of parameters that can be modified for specific types of experimental questions.

Recombinant bacterial RNA polymerase: preparation and applications

Availability of DNA-dependent RNA polymerase from various bacteria is a key for setting up specific in vitro transcription systems necessary for understanding species-specific transcription regulation. We describe here two main strategies for recombinant RNA polymerase preparation-through in vitro reconstitution and heterologous co-overproduction in Escherichia coli. Both strategies can be used for preparation of large amounts of RNA polymerases from any bacteria for which sequences of rpo (RNA polymerase) genes are known.

Structural modules of RNA polymerase required for transcription from promoters containing downstream basal promoter element GGGA

We recently described a novel basal bacterial promoter element that is located downstream of the -10 consensus promoter element and is recognized by region 1.2 of the sigma subunit of RNA polymerase (RNAP). In the case of Thermus aquaticus RNAP, this element has a consensus sequence GGGA and allows transcription initiation in the absence of the -35 element. In contrast, the Escherichia coli RNAP is unable to initiate transcription from GGGA-containing promoters that lack the -35 element. In the present study, we demonstrate that sigma subunits from both E. coli and T. aquaticus specifically recognize the GGGA element and that the observed species specificity of recognition of GGGA-containing promoters is determined by the RNAP core enzyme. We further demonstrate that transcription initiation by T. aquaticus RNAP on GGGA-containing promoters in the absence of the -35 element requires sigma region 4 and C-terminal domains of the alpha subunits, which interact with upstream promoter DNA. When in the context of promoters containing the -35 element, the GGGA element is recognized by holoenzyme RNAPs from both E. coli and T. aquaticus and increases stability of promoter complexes formed on these promoters. Thus, GGGA is a bona fide basal promoter element that can function in various bacteria and, depending on the properties of the RNAP core enzyme and the presence of additional promoter elements, determine species-specific differences in promoter recognition.

Lineage-specific amino acid substitutions in region 2 of the RNA polymerase sigma subunit affect the temperature of promoter opening

Highly conserved amino acid residues in region 2 of the RNA polymerase sigma subunit are known to participate in promoter recognition and opening. We demonstrated that nonconserved residues in this region collectively determine lineage-specific differences in the temperature of promoter opening.

The Role of the Largest RNA Polymerase Subunit Lid Element in Preventing the Formation of Extended RNA-DNA Hybrid

Analysis of multi-subunit RNA polymerase (RNAP) structures revealed several distinct elements that may perform partial functions of the enzyme. One such element, the "lid", is formed by an evolutionarily conserved segment of the RNAP largest subunit (beta' in bacterial RNAP). The beta' lid contacts the nascent RNA at the upstream edge of the RNA-DNA hybrid, where the RNA gets separated from the DNA template-strand and double-stranded upstream DNA is formed. To test the beta' lid functions, we generated bacterial RNAP lacking the lid and studied the mutant enzyme's properties in vitro. Our results demonstrate that removal of the lid has minimal consequences on transcription elongation from double-stranded DNA. On single-stranded DNA, the mutant RNAP generates full-sized transcripts that remain annealed to the DNA throughout their length. In contrast, the wild-type enzyme produces short, 18-22 nucleotide transcripts that remain part of the transcription complex but cannot be further elongated. The cessation of transcription is apparently triggered by a clash between the lid and the nascent RNA 5' end. The results show that the lid's function is redundant in the presence of the non-template DNA strand, which alone can control the proper geometry of nucleic acids at the upstream edge of the transcription complex. Structural considerations suggest that in the absence of the non-template strand and the lid, a new channel opens within the RNAP molecule that allows continuous DNA-RNA hybrid to exit RNAP.

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.

Differences in contacts of RNA polymerases from Escherichia coli and Thermus aquaticus with lacUV5 promoter are determined by core-enzyme of RNA polymerase

The interaction of RNA polymerases from Escherichia coli and Thermus aquaticus with lacUV5 promoter was studied at various temperatures. Using DNA-protein cross-linking induced by formaldehyde, it was demonstrated that each RNA polymerase formed a unique pattern of contacts with DNA in the open promoter complex. In the case of E. coli RNA polymerase, beta and sigma subunits were involved into formation of cross-links with the promoter, whereas in the case of T. aquaticus RNA polymerase its beta subunit formed the cross-links with the promoter. A cross-linking pattern in promoter complexes of a hybrid holoenzyme comprised of the core-enzyme of E. coli and sigma subunit of T. aquaticus was similar to that of the E. coli holoenzyme. This suggests that DNA-protein contacts in the promoter complex are primarily determined by the core-enzyme of RNA polymerase. However, temperature-dependent behavior of contact formation is determined by the sigma subunit. Results of the present study indicate that the method of formaldehyde cross-linking can be employed for elucidation of differences in the structure of promoter complexes of RNA polymerases from various bacteria.

Recombinant Thermus aquaticus RNA Polymerase for Structural Studies

Advances in the structural biology of bacterial transcription have come from studies of RNA polymerases (RNAPs) from the thermophilic eubacteria Thermus aquaticus (Taq) and Thermus thermophilus (Tth). These structural studies have been limited by the fact that only endogenous Taq or Tth RNAP, laboriously purified from large quantities of Taq or Tth cell paste and offering few options for genetic modification, is suitable for structural studies. Recombinant systems for the preparation of Taq RNAP by co-overexpression and assembly in the heterologous host, Escherichia coli, have been described, but these did not yield enzyme suitable for crystallographic studies. Here we describe recombinant systems for the preparation of Taq RNAP harboring full or partial deletions of the Taq beta' non-conserved domain (NCD), yielding enzyme suitable for crystallographic studies. This opens the way for structural studies of genetically manipulated enzymes, allowing the preparation of more crystallizable enzymes and facilitating detailed structure/function analysis. Characterization of the Taqbeta'NCD deletion mutants generated in this study showed that the beta'NCD is important for the efficient binding of the sigma subunit, confirming previous hypotheses. Finally, preliminary structural analysis (at 4.1Angstroms resolution) of one of the recombinant mutants revealed a previously unobserved conformation of the beta-flap, further defining the range of conformations accessible to this flexible structural element.

RNA polymerase structure and function at lac operon

Transcription of E. coli lac operon by RNA polymerase (RNAP) is a classic example of how the basic functions of this enzyme, specifically the ability to recognize/bind promoters, melt the DNA and initiate RNA synthesis, is positively regulated by transcription activators, such as cyclic AMP-receptor protein, CRP, and negatively regulated by lac-repressor, LacI. In this review, we discuss the recent progress in structural and biochemical studies of RNAP and its binary and ternary complexes with CRP and lac promoter. With structural information now available for RNAP and models of binary and ternary elongation complexes, the interaction between these factors and RNAP can be modeled, and possible molecular mechanisms of their action can be inferred.

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

Bacterial RNA polymerase (RNAP) is the central enzyme of gene expression that is responsible for the synthesis of all types of cellular RNAs. The process of transcription is accompanied by complex structural rearrangements of RNAP. Despite the recent progress in structural studies of RNAP, detailed mechanisms of conformational changes of RNAP that occur at different stages of transcription remain unknown. The goal of this work was to obtain novel ligands to RNAP which would target different epitopes of the enzyme and serve as specific probes to study the mechanism of transcription and conformational flexibility of RNAP. Using in vitro selection methods, we obtained 13 classes of ssDNA aptamers against Escherichia coli core RNAP. The minimal nucleic acid scaffold (an oligonucleotide construct imitating DNA and RNA in elongation complex), rifampicin and the sigma70-subunit inhibited binding of the aptamers to RNAP core but did not affect the dissociation rate of preformed RNAP-aptamer complexes. We argue that these ligands sterically block access of the aptamers to their binding sites within the main RNAP channel. In contrast, transcript cleavage factor GreB increased the rate of dissociation of preformed RNAP-aptamer complexes. This suggested that GreB that binds RNAP outside the main channel actively disrupts RNAP-aptamer complexes by inducing conformational changes in the channel. We propose that the aptamers obtained in this work will be useful for studying the interactions of RNAP with various ligands and regulatory factors and for investigating the conformational flexibility of the enzyme.

Different rifampin sensitivities of Escherichia coli and Mycobacterium tuberculosis RNA polymerases are not explained by the difference in the beta-subunit rifampin regions I and II

Mycobacterium tuberculosis RNA polymerase is 1,000-fold more sensitive to rifampin than Escherichia coli RNA polymerase. Chimeric E. coli RNA polymerase in which the beta-subunit segment encompassing rifampin regions I and II (amino acids [aa] 463 through 590) was replaced with the corresponding region from M. tuberculosis (aa 382 through 509) did not show an increased sensitivity to the antibiotic. Thus, the difference in amino acid sequence between the rifampin regions I and II of the two species does not account for the difference in rifampin sensitivity of the two polymerases.

Mechanistic differences in promoter DNA melting by Thermus aquaticus and Escherichia coli RNA polymerases

Formation of strand-separated, functional complexes at promoters was compared for RNA polymerases from the mesophile Escherichia coli and the thermophile Thermus aquaticus. The RNA polymerases contained sigma factors that were wild type or bearing homologous alanine substitutions for two aromatic amino acids involved in DNA melting. Substitutions in the sigmaA subunit of T. aquaticus RNA polymerase impair promoter DNA melting equally at temperatures from 25 to 75 degrees C. However, homologous substitutions in sigma70 render E. coli RNA polymerase progressively more melting-defective as the temperature is reduced below 37 degrees C. The effects of the mutations on the mechanism of promoter DNA melting were investigated by studying the interaction of wild type and mutant RNA polymerases with "partial promoters" mimicking promoter DNA where the nucleation of DNA melting had taken place. Because T. aquaticus and E. coli RNA polymerases bound these templates similarly, it was concluded that the different effects of the mutations on the two polymerases are exerted at a step preceding nucleation of DNA melting. A model is presented for how this mechanistic difference between the two RNA polymerase could explain our observations.

Structural, functional, and genetic analysis of sorangicin inhibition of bacterial RNA polymerase

A combined structural, functional, and genetic approach was used to investigate inhibition of bacterial RNA polymerase (RNAP) by sorangicin (Sor), a macrolide polyether antibiotic. Sor lacks chemical and structural similarity to the ansamycin rifampicin (Rif), an RNAP inhibitor widely used to treat tuberculosis. Nevertheless, structural analysis revealed Sor binds in the same RNAP beta subunit pocket as Rif, with almost complete overlap of RNAP binding determinants, and functional analysis revealed that both antibiotics inhibit transcription by directly blocking the path of the elongating transcript at a length of 2-3 nucleotides. Genetic analysis indicates that Rif binding is extremely sensitive to mutations expected to change the shape of the antibiotic binding pocket, while Sor is not. We suggest that conformational flexibility of Sor, in contrast to the rigid conformation of Rif, allows Sor to adapt to changes in the binding pocket. This has important implications for drug design against rapidly mutating targets.

Cold sensitivity of thermophilic and mesophilic RNA polymerases

RNA polymerase from mesophilic Deinococcus radiodurans displays the same cold sensitivity of promoter opening as RNA polymerase from the closely related thermophilic Thermus aquaticus. This suggests that, contrary to the accepted view, cold sensitivity of promoter opening by thermophilic RNA polymerases may not be a consequence of their thermostability.

A fluorescence-based assay for multisubunit DNA-dependent RNA polymerases

The properties of DNA-dependent RNA polymerases have been studied since the 1960s, but considerable interest in probing RNA polymerase structure/function relationships, the roles of different classes of RNA polymerases in cellular processes, and the feasibility of using RNA polymerases as drug targets still exists. Historically, RNA polymerase activity has been measured by the incorporation into RNA of radioisotopically labeled nucleotides. We report the development of an assay for RNA polymerase activity that uses the dye RiboGreen to detect transcripts by fluorescence and is thus free of the expense, short shelf life, and high handling costs of radioisotopes. The method is relatively quick and can be performed entirely in microplate format, allowing for the processing of dozens to hundreds of samples in parallel. It should thus be well-suited to use in drug screening and analysis of chromatographic fractions. As RiboGreen fluorescence is enhanced by binding to either RNA or DNA, template DNA must be removed by DNase digestion and ultrafiltration between the transcription and the detection phases of the assay procedure. Although RiboGreen fluorescence is sensitive to changes in solvent environment, solvent exchange in the ultrafiltration step allows comparison of transcription levels even under extremes of salt, pH, etc.

The many conformational states of RNA polymerase elongation complexes and their roles in the regulation of transcription

Transcription is highly regulated both by protein factors and by specific RNA or DNA sequence elements. Central to this regulation is the ability of RNA polymerase (RNAP) to adopt multiple conformational states during elongation. This review focuses on the mechanism of transcription elongation and the role of different conformational states in the regulation of elongation and termination. The discussion centers primarily on data from structural and functional studies on Escherichia coli RNAP. To introduce the players, a brief introduction to the general mechanism of elongation, the regulatory proteins, and the conformational states is provided. The role of each of the conformational states in elongation is then discussed in detail. Finally, an integrated mechanism of elongation is presented, bringing together the panoply of experiments.

Promoting elongation with transcript cleavage stimulatory factors

Transcript elongation by RNA polymerase is a dynamic process, capable of responding to a number of intrinsic and extrinsic signals. A number of elongation factors have been identified that enhance the rate or efficiency of transcription. One such class of factors facilitates RNA polymerase transcription through blocks to elongation by stimulating the polymerase to cleave the nascent RNA transcript within the elongation complex. These cleavage factors are represented by the Gre factors from prokaryotes, and TFIIS and TFIIS-like factors found in archaea and eukaryotes. High-resolution structures of RNA polymerases and the cleavage factors in conjunction with biochemical investigations and genetic analyses have provided insights into the mechanism of action of these elongation factors. However, there are yet many unanswered questions regarding the regulation of these factors and their effects on target genes.

A novel bacteriophage-encoded RNA polymerase binding protein inhibits transcription initiation and abolishes transcription termination by host RNA polymerase

Xp10 is a lytic bacteriophage of Xanthomonas oryzae, a Gram-negative bacterium that causes rice blight. We purified an Xp10 protein, p7, that binds to and inhibits X. oryzae RNA polymerase (RNAP). P7 is a novel 73 amino acid-long protein; it does not bind to and hence does not affect transcription by Escherichia coli RNAP. Analysis of E. coli/X. oryzae RNAP hybrids locates the p7 binding site to the largest X. oryzae RNAP subunit, beta'. Binding of p7 to X. oryzae RNAP holoenzyme prevents large conformational change that places the sigma subunit region 4 into the correct position for interaction with the -35 promoter element. As a result, open promoter complex formation on the -10/-35 class promoters is inhibited. Inhibition of promoter complex formation on the extended -10 class promoters is less efficient. The p7 protein also abolishes factor-independent transcription termination by X. oryzae RNAP by preventing the release of nascent RNA at terminators. Further physiological and mechanistic studies of this novel transcription factor should provide additional insights into its biological role and the processes of promoter recognition and transcription termination.

Structure-based analysis of RNA polymerase function: the largest subunit's rudder contributes critically to elongation complex stability and is not involved in the maintenance of RNA-DNA hybrid length

Analysis of multisubunit RNA polymerase (RNAP) structures revealed several elements that may constitute the enzyme's functional sites. One such element, the 'rudder', is formed by an evolutionarily conserved segment of the largest subunit of RNAP and contacts the nascent RNA at the upstream edge of the RNA-DNA hybrid, where the DNA template strand separates from the RNA transcript and re-anneals with the non-template strand. Thus, the rudder could (i) maintain the correct length of the RNA-DNA hybrid; (ii) stabilize the nascent RNA in the complex; and (iii) promote or maintain localized DNA melting at the upstream edge of the bubble. We generated a recombinant RNAP mutant that lacked the rudder and studied its properties in vitro. Our results demonstrate that the rudder is not required for establishment of the upstream boundary of the transcription bubble during promoter complex formation, nor is it required for separation of the nascent RNA from the DNA template strand or transcription termination. Our results suggest that the rudder makes critical contributions to elongation complex stability through direct interactions with the nascent RNA.

Structure of the bacterial RNA polymerase promoter specificity sigma subunit

The sigma subunit is the key regulator of bacterial transcription. Proteolysis of Thermus aquaticus sigma(A), which occurred in situ during crystallization, reveals three domains, sigma(2), sigma(3), and sigma(4), connected by flexible linkers. Crystal structures of each domain were determined, as well as of sigma(4) complexed with -35 element DNA. Exposed surfaces of each domain are important for RNA polymerase binding. Universally conserved residues important for -10 element recognition and melting lie on one face of sigma(2), while residues important for extended -10 recognition lie on sigma(3). Genetic studies correctly predicted that a helix-turn-helix motif in sigma(4) recognizes the -35 element but not the details of the protein-DNA interactions. Positive control mutants in sigma(4) cluster in two regions, positioned to interact with activators bound just upstream or downstream of the -35 element.

Transcript cleavage by Thermus thermophilus RNA polymerase. Effects of GreA and anti-GreA factors

All known multisubunit RNA polymerases possess the ability to endonucleolytically degrade the nascent RNA transcript. To gain further insight into the conformational changes that govern transcript cleavage, we have examined the effects of certain anions on the intrinsic transcript cleavage activity of Thermus thermophilus RNA polymerase. Our results indicate that the conformational transitions involved in transcript cleavage, and therefore backtracking, are anion-dependent. In addition to characterizing the intrinsic cleavage activity of T. thermophilus RNA polymerase, we have identified, cloned, and expressed a homolog of the prokaryotic transcript cleavage factor GreA from the extreme thermophiles, T. thermophilus and Thermus aquaticus. The thermostable GreA factors contact the 3'-end of RNA, stimulate the intrinsic cleavage activity of T. thermophilus RNA polymerase, and increase the k(app) of the cleavage reaction 25-fold. In addition, we have identified a novel transcription factor in T. thermophilus and T. aquaticus that shares a high degree of sequence similarity with GreA, but has several residues that are not conserved with the N-terminal "basic patch" region of GreA. This protein, Gfh1, functions as an anti-GreA factor in vitro by reducing intrinsic cleavage and competing with GreA for a binding site on the polymerase.

Bacterial RNA polymerase

The recently determined crystal structure of a bacterial core RNA polymerase (RNAP) provides the first glimpse of this family of evolutionarily conserved cellular RNAPs. Using the structure as a framework, a consistent picture of protein-nucleic acid interactions in transcription complexes has been accumulated from cross-linking experiments. The molecule can be viewed as a molecular machine, with distinct structural features hypothesized to perform specific functions. Comparison with the alpha-carbon backbone of a eukaryotic RNAP reveals close structural similarity.

Structural mechanism for rifampicin inhibition of bacterial rna polymerase

Rifampicin (Rif) is one of the most potent and broad spectrum antibiotics against bacterial pathogens and is a key component of anti-tuberculosis therapy, stemming from its inhibition of the bacterial RNA polymerase (RNAP). We determined the crystal structure of Thermus aquaticus core RNAP complexed with Rif. The inhibitor binds in a pocket of the RNAP beta subunit deep within the DNA/RNA channel, but more than 12 A away from the active site. The structure, combined with biochemical results, explains the effects of Rif on RNAP function and indicates that the inhibitor acts by directly blocking the path of the elongating RNA when the transcript becomes 2 to 3 nt in length.