Major groove recognition elements in the middle of the T7 RNA polymerase promoter

Switching promotor recognition of phage RNA polymerase in silico along lab-directed evolution path

In this work, we computationally investigated how a viral RNA polymerase (RNAP) from bacteriophage T7 evolves into RNAP variants under lab-directed evolution to switch recognition from T7 promoter to T3 promoter in transcription initiation. We first constructed a closed initiation complex for the wild-type T7 RNAP and then for six mutant RNAPs discovered from phage-assisted continuous evolution experiments. All-atom molecular dynamics simulations up to 1 μs each were conducted on these RNAPs in a complex with the T7 and T3 promoters. Our simulations show notably that protein-DNA electrostatic interactions or stabilities at the RNAP-DNA promoter interface well dictate the promoter recognition preference of the RNAP and variants. Key residues and structural elements that contribute significantly to switching the promoter recognition were identified. Followed by a first point mutation N748D on the specificity loop to slightly disengage the RNAP from the promoter to hinder the original recognition, we found an auxiliary helix (206-225) that takes over switching the promoter recognition upon further mutations (E222K and E207K) by forming additional charge interactions with the promoter DNA and reorientating differently on the T7 and T3 promoters. Further mutations on the AT-rich loop and the specificity loop can fully switch the RNAP-promoter recognition to the T3 promoter. Overall, our studies reveal energetics and structural dynamics details along an exemplary directed evolutionary path of the phage RNAP variants for a rewired promoter recognition function. The findings demonstrate underlying physical mechanisms and are expected to assist knowledge and data learning or rational redesign of the protein enzyme structure function.

DNA sequence, physics, and promoter function: Analysis of high-throughput data On T7 promoter variants activity

RNA polymerase/promoter recognition represents a basic problem of molecular biology. Decades-long efforts were made in the area, and yet certain challenges persist. The usage of certain most suitable model subjects is pivotal for the research. System of T7 bacteriophage RNA-polymerase/T7 native promoter represents an exceptional example for the purpose. Moreover, it has been studied the most and successfully applied to aims of biotechnology and bioengineering. Both structural simplicity and high specificity of this molecular duo are the reason for this. Despite highly similar sequences of distinct T7 native promoters, the T7 RNA-polymerase enzyme is capable of binding respective promoter in a highly specific and adjustable manner. One explanation here is that the process relies primarily on DNA physical properties rather than nucleotide sequence. Here, we address the issue by analyzing massive data recently published by Komura and colleagues. This initial study employed Next Generation Sequencing (NGS) in order to quantify activity of promoter variants including ones with multiple substitutions. As a result of our work substantial bias in simultaneous occurrence of single-nucleotide sequence alterations was found: the highest rate of co-occurrence was evidenced within specificity loop of binding region while the lowest - in initiation region of promoter. If both location and a kind of nucleotides involved in replacement (both initial and resulting) are taken into consideration, one can easily note that N to A substitutions are most preferred ones across the whole 19 b.p.-long sequence. At the same time, N to C are tolerated only at crucial position in recognition loop of binding region, and N to G are uniformly least tolerable. Later in this work the complete set of variants was split into groups with mutations (1) exclusively in binding region; (2) exclusively in melting region; (3) in both regions. Among these three groups second comprises extremely few variants (at triple-digit rate lesser than in two other groups, 46 versus over one and six thousand). Yet these are all promoter with substantial to high activity. This group two appeared heterogenous by primary sequence; indeed, upon further subdivision into above versus below average activity subgroups first one was found to comprise promoters with negligible conservation at -2 position of melting region; the second was hardly conserved in this region at all. This draws our attention to perfect consensus sequence of class III T7 promoter with -2 nucleotide randomized (all four are present by one to several copies in the previously published source dataset), the picture becomes even more pronounced. We therefore suggest that mutations at the position therefore do not cause significant changes in terms of promoter activity. At the same time, such modifications dramatically change DNA physical properties which were calculated in our study (namely electrostatic potential and propensity to bend). One possible suggestion here is that -2 nucleotide might function as a generic switch; if so, substitution -2A to -2T has important regulatory consequences. The fact that that -2 b.p. is the most evidently different nucleotide between class II versus class III promoters of T7 genome and that it also distinguishes the class III promoter in T7 genome versus promoters of its relative but reproductively isolated bacteriophage T3. In other words, it appears feasible that mutation at -2 nucleotide does not impede promoter activity yet alter its physical properties thus affecting differential RNA polymerase/promoter interaction.

Promoter engineering improves transcription efficiency in biomolecular assays

We identified a novel 12 bp promoter that significantly increased transcription efficiency. Unlike the standard 20 bp promoter, which contains both recognition and initiation regions, the new promoter contains only a recognition region and is more suitable for diagnostic applications due to its smaller size. This promoter effectively produced different light-up RNA aptamers via transcription. Moreover, we used the promoter to analyze RNase H activity and achieved a detection limit of 0.009 U mL^-1, which was significantly better than that achieved via previous methods. We propose that the new promoter may serve as a key component in various diagnostic applications.

Single-pass transcription by T7 RNA polymerase

RNA molecules can be conveniently synthesized in vitro by the T7 RNA polymerase (T7 RNAP). In some experiments, such as cotranscriptional biochemical analyses, continuous synthesis of RNA is not desired. Here, we propose a method for a single-pass transcription that yields a single transcript per template DNA molecule using the T7 RNAP system. We hypothesized that stalling the polymerase downstream from the promoter region and subsequent cleavage of the promoter by a restriction enzyme (to prevent promoter binding by another polymerase) would allow synchronized production of a single transcript per template. The single-pass transcription was verified in two different scenarios: a short self-cleaving ribozyme and a long mRNA. The results show that a controlled single-pass transcription using T7 RNAP allows precise measurement of cotranscriptional ribozyme activity, and this approach will facilitate the study of other kinetic events.

A novel analytical principle using AP site-mediated T7 RNA polymerase transcription regulation for sensing uracil-DNA glycosylase activity

udgactivity could regulateT7 RNApolymerase transcription ability by the heteroduplex substrates with chemical modifications.

Maximizing the Translational Yield of mRNA Therapeutics by Minimizing 5'-UTRs

The 5'-untranslated region (5'-UTR) of mRNA contains structural elements, which are recognized by cell-specific RNA-binding proteins, thereby affecting the translation of the molecule. The activation of an innate immune response upon transfection of mRNA into cells is reduced when the mRNA comprises chemically modified nucleotides, putatively by altering the secondary structure of the molecule. Such alteration in the 5'-UTR in turn may affect the functionality of mRNA. In this study, we report on the impact of seven synthetic minimalistic 5'-UTR sequences on the translation of luciferase-encoding unmodified and different chemically modified mRNAs upon transfection in cell culture and in vivo. One minimalistic 5'-UTR, consisting of 14 nucleotides combining the T7 promoter with a Kozak consensus sequence, yielded similar or even higher expression than a 37 nucleotides human alpha-globin 5'-UTR containing mRNA in HepG2 and A549 cells. Furthermore, also the kind of modified nucleotides used in in vitro transcription, affected mRNA translation when using different translation regulators (Kozak vs. translation initiator of short UTRs). The in vitro data were confirmed by bioluminescence imaging of expression in mouse livers, 6 h postintravenous injection of a lipidoid nanoparticle-formulated RNA in female Balb/c mice. Luciferase measurements from liver and spleen showed that minimal 5'-UTRs (3 and 7) were either equally effective or better than human alpha-globin 5'-UTR. These findings were confirmed with a human erythropoietin (hEPO)-encoding mRNA. Significantly, higher levels of hEPO could be quantified in supernatants from A549 cells transfected with minimal 5'-UTR7 containing RNA when compared to commonly used benchmarks 5'-UTRs. Our results demonstrate the superior potential of synthetic minimalistic 5'-UTRs for use in transcript therapies.

High-throughput evaluation of T7 promoter variants using biased randomization and DNA barcoding

Cis-regulatory elements (CREs) are one of the important factors in controlling gene expression and elucidation of their roles has been attracting great interest. We have developed an improved method for analyzing a large variety of mutant CRE sequences in a simple and high-throughput manner. In our approach, mutant CREs with unique barcode sequences were obtained by biased randomization in a single PCR amplification. The original T7 promoter sequence was randomized by biased randomization, and the target number of base substitutions was set to be within the range of 0 to 5. The DNA library and subsequent transcribed RNA library were sequenced by next generation sequencers (NGS) to quantify transcriptional activity of each mutant. We succeeded in producing a randomized T7 promoter library with high coverage rate at each target number of base substitutions. In a single NGS analysis, we quantified the transcriptional activity of 7847 T7 promoter variants. We confirmed that the bases from -9 to -7 play an important role in the transcriptional activity of the T7 promoter. This information coincides with the previous researches and demonstrated the validity of our methodology. Furthermore, using an in vitro transcription/translation system, we found that transcriptional activities of these T7 variants were well correlated with the resultant protein abundance. We demonstrate that our method enables simple and high-throughput analysis of the effects of various CRE mutations on transcriptional regulation.

Structural and biochemical investigation of bacteriophage N4-encoded RNA polymerases

Bacteriophage N4 regulates the temporal expression of its genome through the activity of three distinct RNA polymerases (RNAP). Expression of the early genes is carried out by a phage-encoded, virion-encapsidated RNAP (vRNAP) that is injected into the host at the onset of infection and transcribes the early genes. These encode the components of new transcriptional machinery (N4 RNAPII and cofactors) responsible for the synthesis of middle RNAs. Both N4 RNAPs belong to the T7-like "single-subunit" family of polymerases. Herein, we describe their mechanisms of promoter recognition, regulation, and roles in the phage life cycle.

A model of sequence-dependent protein diffusion along DNA

We introduce a probabilistic model for protein sliding motion along DNA during the search of a target sequence. The model accounts for possible effects due to sequence-dependent interaction between the nonspecific DNA and the protein. Hydrogen bonds formed at the target site are used as the main sequence-dependent interaction between protein and DNA. The resulting dynamical properties and the possibility of an experimental verification are discussed in details. We show that, while at large times the process reaches a linear diffusion regime, it initially displays a sub-diffusive behavior. The sub-diffusive regime can last sufficiently long to be of biological interest.

Differential scanning calorimetric approach to study the effect of melting region upon transcription initiation by T7 RNA polymerase and role of high affinity GTP binding

Transcription initiation by T7 RNA polymerase is a multistep process consisting of the transition from closed to open complex. The promoters of bacteriophage T7 share a consensus sequence of 23 base pairs, from -17 to +6, relative to transcription start site (+1). In the present study, we have characterized T7 RNA polymerase-promoter complexes by means of fluorescence spectroscopy and differential scanning calorimetry. We have examined the effect of high affinity GTP binding upon the equilibrium of the transition from closed to open complex. We have employed the promoter containing 23 base pair consensus sequence and two variants containing Adenine-Thymine and Guanine-Cytosine stretches in the melting region of the promoter sequence. Variation in the nucleotide sequence of melting region does not have any effect upon the affinity of promoter-T7 RNAP complex. On the other hand, alteration of the base sequence in the melting region of the promoter affects the isomerization process among the closed and open complexes. When the initiating nucleotide GTP is prebound to T7 RNA Polymerase, the isomerization process is affected only in case of the promoter with consensus sequence.

Characterization of a T7-like lytic bacteriophage (phiSG-JL2) of Salmonella enterica serovar gallinarum biovar gallinarum

PhiSG-JL2 is a newly discovered lytic bacteriophage infecting Salmonella enterica serovar Gallinarum biovar Gallinarum but is nonlytic to a rough vaccine strain of serovar Gallinarum biovar Gallinarum (SG-9R), S. enterica serovar Enteritidis, S. enterica serovar Typhimurium, and S. enterica serovar Gallinarum biovar Pullorum. The phiSG-JL2 genome is 38,815 bp in length (GC content, 50.9%; 230-bp-long direct terminal repeats), and 55 putative genes may be transcribed from the same strand. Functions were assigned to 30 genes based on high amino acid similarity to known proteins. Most of the expected proteins except tail fiber (31.9%) and the overall organization of the genomes were similar to those of yersiniophage phiYeO3-12. phiSG-JL2 could be classified as a new T7-like virus and represents the first serovar Gallinarum biovar Gallinarum phage genome to be sequenced. On the basis of intraspecific ratios of nonsynonymous to synonymous nucleotide changes (Pi[a]/Pi[s]), gene 2 encoding the host RNA polymerase inhibitor displayed Darwinian positive selection. Pretreatment of chickens with phiSG-JL2 before intratracheal challenge with wild-type serovar Gallinarum biovar Gallinarum protected most birds from fowl typhoid. Therefore, phiSG-JL2 may be useful for the differentiation of serovar Gallinarum biovar Gallinarum from other Salmonella serotypes, prophylactic application in fowl typhoid control, and understanding of the vertical evolution of T7-like viruses.

Sequential release of promoter contacts during transcription initiation to elongation transition

Bacteriophage T7 RNA polymerase undergoes major conformational changes as transcription proceeds from initiation to elongation. Using limited trypsin digestion and stopped-flow fluorescence kinetic methods, we have monitored promoter release, initial bubble collapse, and refolding of the 152-205 region (subdomain H), the latter being important for RNA channel formation. The kinetic studies show that the conformational changes are temporally coupled, commencing at the synthesis of 9 nt and completing by the synthesis of 12 nt of RNA. The temporal coupling of initial bubble collapse and RNA channel formation is proposed to facilitate proper binding of the RNA dissociated from the late initiation complexes into the RNA channel. Using promoter mutations, we have determined that promoter contacts are broken sequentially during transition from initiation to elongation. The specificity loop interactions are broken after synthesis of 8 nt or 9 nt of RNA, whereas the upstream promoter contacts persists up to synthesis of 12 nt of RNA. Both promoter contacts need to be broken for transition into elongation. The A-15C mutation resulted in efficient transition to elongation by synthesis of 9 nt of RNA, whereas the C-9A mutation resulted in early transition to elongation by synthesis of 7-8 nt of RNA. The effect of early promoter clearance in the mutant promoters was observed as reduced production of long abortive products.

Observation by fluorescence microscopy of transcription on single combed DNA

Molecular combing is a powerful procedure for aligning a large array of DNA molecules onto a surface. This technique usually leads to an overstretching of about 150% of the molecules' contour length. By changing the magnitude of capillary forces during the combing process, we were able to reduce the relative extension of the DNA molecules. Thus we achieved combing of T7 DNA with an extension close to its molecule contour length. We checked the ability of combed DNA to interact with DNA binding proteins. Using the T7 bacteriophage transcription system, we investigated the transcription activity of RNA polymerase on combed DNA by direct visualization of newly synthesized fluorescent RNAs. Our experiments show that no transcription activity occurs on overstretched DNA molecules, whereas we observe a transcription activity for nonoverstretched molecules. This activity is observed both in multiple initiation experiments and for one immobilized T7 RNA polymerase per promoter. These results open possibilities for the study of single enzyme actions on combed DNA by optical methods.

Marking the start site of RNA polymerase III transcription: the role of constraint, compaction and continuity of the transcribed DNA strand

The effects of breaks in the individual strands of an RNA polymerase III promoter on initiation of transcription have been examined. Single breaks have been introduced at 2 bp intervals in a 24 bp segment that spans the transcriptional start site of the U6 snRNA gene promoter. Their effects on transcription are asymmetrically distributed: transcribed (template) strand breaks downstream of bp-14 (relative to the normal start as +1) systematically shift the start site, evidently by disrupting the normal mechanism that measures distance from DNA-bound TBP. Breaks placed close to the normal start site very strongly inhibit transcription. Breaks in the non-transcribed strand generate only minor effects on transcription. A structure-based model interprets these observations and explains how the transcribed strand is used to locate the transcriptional start site.

Substitution of ribonucleotides in the T7 RNA polymerase promoter element

A systematic analysis was carried out to examine the effects of ribonucleotide substitution at various locations within the promoter element for T7 RNA polymerase. Ribonucleotides could be introduced at most positions without significantly decreasing transcription efficiency. A critical window of residues that were intolerant of RNA substitution was defined for both the nontemplate and template strands of the promoter. These residues are involved in important contacts with the AT-rich recognition loop, specificity loop, and beta-intercalating hairpin of the polymerase. These results highlight the malleability of T7 RNA polymerase in recognizing its promoter element and suggest that promoters with altered backbone conformations may be used in molecular biology applications that use T7 RNA polymerase for in vitro transcription.

A combined in vitro/in vivo selection for polymerases with novel promoter specificities

BACKGROUND

The DNA-dependent RNA polymerase from T7 bacteriophage (T7 RNAP) has been extensively characterized, and like other phage RNA polymerases it is highly specific for its promoter. A combined in vitro/in vivo selection method has been developed for the evolution of T7 RNA polymerases with altered promoter specificities. Large (10(3)-10(6)) polymerase libraries were made and cloned downstream of variant promoters. Those polymerase variants that can recognize variant promoters self-amplify both themselves and their attendant mRNAs in vivo. Following RT / PCR amplification in vitro, the most numerous polymerase genes are preferentially cloned and carried into subsequent rounds of selection.

RESULTS AND CONCLUSIONS

A T7 RNA polymerase library that was randomized at three positions was cloned adjacent to a T3-like promoter sequence, and a 'specialist' T7 RNA polymerase was identified. A library that was randomized at a different set of positions was cloned adjacent to a promoter library in which four positions had been randomized, and 'generalist' polymerases that could utilize a variety of T7 promoters were identified, including at least one polymerase with an apparently novel promoter specificity. This method may have applications for evolving other polymerase variants with novel phenotypes, such as the ability to incorporate modified nucleotides.

Interrupting the template strand of the T7 promoter facilitates translocation of the DNA during initiation, reducing transcript slippage and the release of abortive products

We have explored the effects of a variety of structural and sequence changes in the initiation region of the phage T7 promoter on promoter function. At promoters in which the template strand (T strand) is intact, initiation is directed a minimal distance of 5 nt downstream from the binding region. Although the sequence of the DNA surrounding the start site is not critical for correct initiation, it is important for melting of the promoter and stabilization of the initiation complex. At promoters in which the integrity of T strand is interrupted by nicks or gaps between -5 and -2 the enzyme continues to initiate predominately at +1. However, under these conditions there is a decrease in the release of abortive products of 8-10 nt, a decrease in the synthesis of poly(G) products (which arise by slippage of the nascent transcript), and a defect in displacement of the RNA. We propose that unlinking the binding and initiation regions of the T strand changes the manner in which this strand is retained in the abortive complex, reducing or eliminating the need to pack or "scrunch" the strand into the complex during initiation and lowering a thermodynamic barrier to its translocation.

Fluorescence characterization of the transcription bubble in elongation complexes of T7 RNA polymerase

The various kinetic and thermodynamic models for transcription elongation all require an understanding of the nature of the melted bubble which moves with the RNA polymerase active site. Is the general nature of the bubble system-dependent or are there common energetic requirements which constrain a bubble in any RNA polymerases? T7 RNA polymerase is one of the simplest RNA polymerases and is the system for which we have the highest-resolution structural information. However, there is no high-resolution information available for a stable elongation complex. In order to directly map melted regions of the DNA in a functionally paused elongation complex, we have introduced fluorescent probes site-specifically into the DNA. Like 2-aminopurine, which substitutes for adenine bases, the fluorescence intensity of the new probe, pyrrolo-dC, which substitutes for cytosine bases, is sensitive to its environment. Specifically, the fluorescence is quenched in duplex DNA relative to its fluorescence in single-stranded DNA, such that the probe provides direct information on local melting of the DNA. Placement of this new probe at specific positions in the non-template strand shows clearly that the elongation bubble extends about eight bases upstream of the pause site, while 2-aminopurine probes show that the elongation bubble extends only about one nucleotide downstream of the last base incorporated. The positioning of the active site very close to the downstream edge of the bubble is consistent with previous studies and with similar studies of the promoter-bound, pre-initiation complex. The results show clearly that the RNA:DNA hybrid can be no more than eight nucleotides in length, and characterization of different paused species suggests preliminarily that these dimensions are not sequence or position dependent. Finally, the results confirm that the ternary complex is not stable with short lengths of transcript, but persists for a substantial time when paused in the middle or at the (runoff) end of duplex DNA.

Pre-steady-state kinetics of initiation of transcription by T7 RNA polymerase: a new kinetic model

In order to begin to understand the mechanism of the initiation of transcription in the model bacteriophage T7 RNA polymerase system, the simplest possible reaction, the synthesis of a dinucleotide, has been followed by quench-flow kinetics and numerical integration of mechanism-specific rate equations has been used to test specific kinetic models. In order to fit the observed time dependence in the pre-steady-state kinetics, a model for dinucleotide synthesis is proposed in which rebinding of the dinucleotide to the enzyme-DNA complex must be included. Separate reactions using dinucleotide as a substrate confirm this mechanism and the determined rate constants. The dinucleotide rebinding observed as inhibition under these conditions forms a productive intermediate in the synthesis of longer transcripts, and must be included in future kinetic mechanisms. The rate-limiting step leading to product formation shows a substrate dependence consistent with the binding of two substrate GTP molecules, and at saturating levels of GTP, is comparable in magnitude to the product release rate. The rate of product release shows a positive correlation with the concentration of GTP, suggesting that the reaction shows base-specific substrate activation. The binding of another substrate molecule, presumably via interaction with the triphosphate binding site, likely facilitates displacement of the dinucleotide product from the complex.

Effects of saturation mutagenesis of the phage SP6 promoter on transcription activity, presented by activity logos

A full set of SP6 promoter variants with all possible single substitutions at positions -17 to +5 was constructed. Transcription activities of these variants were individually measured in vivo and in vitro to determine the contribution of each base pair to the promoter activity. The in vivo activity was measured indirectly by transcriptional interference of the replication of promoter-bearing plasmids. This activity depends most highly on residues -11, -9, -8, -7, and +1 (initiation site). All substitutions at -11, -9, -8, and -7 abolished formation of closed complexes, except for A-8C. These residues are involved in base-specific interactions with the polymerase, and the substitutions exhibit the same strong inhibition in vitro. In contrast, the in vitro activities of some other variants, measured on linearized templates, were different from those in vivo. Some variants at -13, -4, and -2, among others, showed exceptionally higher activities in vivo than in vitro, supporting the possibility that these residues are involved in postbinding steps, including template melting and bending. The A-3T variant showed much lower activity in vivo than in vitro, but it bound to the polymerase 2-fold more than the consensus sequence and is possibly involved in polymerase binding. A quantitative hierarchy of all the base pairs is graphically displayed by activity logos, revealing the energetic contribution of each base pair to the activity.

Evidence for DNA bending at the T7 RNA polymerase promoter

Phage T7 RNA polymerase is the only DNA-dependent RNA polymerase for which we have a high-resolution structure of the promoter-bound complex. Recent studies with the more complex RNA polymerases have suggested a role for DNA wrapping in the initiation of transcription. Here, circular permutation gel retardation assays provide evidence that the polymerase does indeed bend its promoter DNA. A complementary set of experiments employing differential phasing from an array of phased A-tracts provides further evidence for both intrinsic and polymerase-induced bends in the T7 RNA polymerase promoter DNA. The bend in the complex is predicted to be about 40-60 degrees and to be centered around positions -2 to +1, at the start site for transcription, while the intrinsic bend is much smaller (about 10 degrees ). These results, viewed in the light of a recent crystal structure for the complex, suggest a mechanism by which binding leads directly to bending. Bending at the start site would then facilitate the melting necessary to initiate transcription.

Subgenomic RNA promoters dictate the mode of recognition by bromoviral RNA-dependent RNA polymerases

Both the brome mosaic virus (BMV) and cowpea chlorotic mottle virus (CCMV) RNA-dependent RNA polymerases (RdRps) were found to recognize the BMV core subgenomic promoter in the same manner, requiring specific functional groups at positions -17, -14, -13, and -11 relative to the subgenomic initiation site (+1). For CCMV subgenomic RNA synthesis, both RdRps required the same nucleotides and four additional nucleotides at positions -20, -16, -15, and -10. The -20 nucleotide is partially responsible for the differential mode of recognition of the two promoters. These data provide evidence that the RNA can induce RdRps to alter the mode of promoter recognition.

Recent studies of T7 RNA polymerase mechanism

Bacteriophage T7 RNA polymerase (T7 RNAP) is known to be one of the simplest enzymes catalyzing RNA synthesis. In contrast to most RNA polymerases known, this enzyme consists of one subunit and is able to carry out transcription in the absence of additional protein factors. Owing to its molecular properties, the enzyme is widely used for synthesis of specific transcripts, as well as being a suitable model for studying the mechanisms of transcription. In this minireview the recent data on the structure and mechanism of T7 RNAP, including enzyme-promoter interactions, principal stages of transcription, and the results of functional studies are discussed.

Moieties in an RNA promoter specifically recognized by a viral RNA-dependent RNA polymerase

RNAs 33 nucleotides in length can direct accurate initiation of subgenomic RNA synthesis by the brome mosaic virus RNA-dependent RNA polymerase (RdRp), provided that the native sequences are maintained at five positions: -17, -14, -13, -11, and the +1 initiation site. The functional groups in the bases of these essential nucleotides required to interact with RdRp were examined by using chemically synthesized RNAs containing base analogs at each of the five positions. Analysis using a template competition assay revealed that the mode of recognition for the initiation nucleotide (+1) is distinct from that of the other essential nucleotides in the promoter. Competition experiments also determined that three template nucleotides are sufficient for stable interaction with RdRp. These results identify base moieties in the brome mosaic virus subgenomic promoter required for efficient RNA synthesis and support the hypothesis that the recognition of a RNA promoter by a viral RdRp is analogous to the recognition of DNA promoters by DNA-dependent RNA polymerases.

Promoter specificity determinants of T7 RNA polymerase

The high specificity of T7 RNA polymerase (RNAP) for its promoter sequence is mediated, in part, by a specificity loop (residues 742-773) that projects into the DNA binding cleft (1). Previous work demonstrated a role for the amino acid residue at position 748 (N748) in this loop in discrimination of the base pairs (bp) at positions -10 and -11 (2). A comparison of the sequences of other phage RNAPs and their promoters suggested additional contacts that might be important in promoter recognition. We have found that changing the amino acid residue at position 758 in T7 RNAP results in an enzyme with altered specificity for the bp at position -8. The identification of two amino acid:base pair contacts (i.e., N748 with the bp at -10 and -11, and Q758 with the bp at -8) provides information concerning the disposition of the specificity loop relative to the upstream region of the promoter. The results suggest that substantial rearrangements of the loop (and/or the DNA) are likely to be required to allow these amino acids to interact with their cognate base pairs during promoter recognition.

Interaction of the bacteriophage Mu transcriptional activator protein, C, with its target site in the mom promoter

The bacteriophage Mu C gene encodes a 16.5 kDa site-specific DNA binding protein that is a transcriptional activator of the four "late" promoters, Pmom, Plys, PI and PP. A symmetrical consensus C recognition sequence, TTAT[N5-6]ATAA, containing an inverted tetrad repeat separated by a spacer of five to six G+C-rich nucleotides, has been proposed. To investigate this, we used oligonucleotide mutagenesis to introduce random substitutions within and flanking the proposed C-target region; each variant site was tested for C recognition by an in vivo functional transactivation assay. We observed that all single mutations, in either tetrad, reduced C activation. Although two out of ten substitutions within the spacer reduced activation, the spacer region does not appear to make specific contact with C. We also used in vitro chemical-protection and -interference to study C contacts with Pmom. The results indicate that C contacts Pmom DNA on only one face of the helix through interactions within two adjacent major grooves; this conclusion was supported by gel shift analyses using synthetic oligonucleotide duplexes containing I.C or other base-pair substitutions. Evidence is also presented that C-Pmom contacts are asymmetrical, and that they extend two nucleotides 3' to the promoter-proximal tetrad. We also show that C binding induces a deformation, possibly a bend, in Pmom DNA.

Identification of a minimal binding element within the T7 RNA polymerase promoter

The T7 RNA polymerase promoter has been proposed to contain two domains: the binding region upstream of position -5 is recognized through apparently traditional duplex contacts, while the catalytic domain downstream of position -5 is bound in a melted configuration. This model is tested by following polymerase binding to a series of synthetic oligonucleotides representing truncations of the consensus promoter sequence. The increase in the fluorescence anisotropy of a rhodamine dye linked to the upstream end of the promoter provides a very sensitive measure of enzyme binding in simple thermodynamic titrations, and allows the determination of both increases and decreases in the dissociation constant. The best fit value of Kd=4.0 nM for the native promoter is in good agreement with previous fluorescence and steady state measurements. Deletion of the downstream DNA up to position -1 or to position -5 leads to a fivefold increase in binding, while further sequential single-base deletions upstream result in 20 and 500-fold decreases in binding. These results indicate that the (duplex) region of the promoter upstream of and including position -5 is both necessary and sufficient for tight binding, and represents the core binding element of the promoter. We propose a model in which part of the upstream binding energy is used by T7 RNA polymerase to melt the downstream initiation region of the promoter. We also show that the presence of magnesium is necessary for optimal binding, but not for specific enzyme-promoter complex formation, and we propose that magnesium is not required for melting of the promoter.

Sequence-specific recognition of a subgenomic RNA promoter by a viral RNA polymerase

RNA templates of 33 nucleotides containing the brome mosaic virus (BMV) core subgenomic promoter were used to determine the promoter elements recognized by the BMV RNA-dependent RNA polymerase (RdRp) to initiate RNA synthesis. Nucleotides at positions -17, -14, -13, and -11 relative to the subgenomic initiation site must be maintained for interaction with the RdRp. Changes to every other nucleotide at these four positions allow predictions for the base-specific functional groups required for RdRp recognition. RdRp contact of the nucleotide at position -17 was suggested with a template competition assay. Comparison of the BMV subgenomic promoter to those from other plant and animal alphaviruses shows a remarkable degree of conservation of the nucleotides required for BMV subgenomic RNA synthesis. We show that the RdRp of the plant-infecting BMV is capable of accurately, albeit inefficiently, initiating RNA synthesis from the subgenomic promoter of the animal-infecting Semliki Forest virus. The sequence-specific recognition of RNA by the BMV RdRp is analogous to the recognition of DNA promoters by DNA-dependent RNA polymerases.

Positioning of the start site in the initiation of transcription by bacteriophage T7 RNA polymerase

The determination of various polymerase structures has sparked interest in understanding how the polynucleotide template interacts with the active site. In the primer-independent initiation of transcription, an additional question arises as to how the complex directs the first two bases of the template uniquely into the active site. Recent studies in the model RNA polymerase from bacteriophage T7 demonstrate that upstream duplex contacts provide at least some of the binding specificity and suggest that the enzyme interacts with the template strand in a melted context near the start site for transcription. The current work probes the role of the template strand in positioning of the first two templating bases during initiation. The results suggest that such positioning is not rate-limiting in steady-state turnover, and that the insertion of a very large and flexible linker three or four bases upstream of the start site has no significant effect on the fidelity of start site selection. The insertion of linkers immediately adjacent to the start site, however, does significantly decrease the fidelity of start site selection (as evidenced by a large increase in misinitiation at position +2, with little change in the observed rate of correct initiation), suggesting that some of the non-transcribed template DNA does help to position the first two templating bases into the active site of the RNA polymerase. Finally, incorporation of an abasic site at position -1 yields a similar decrease in initiation fidelity, suggesting a role for stacking of the bases at positions -1 and +1.