Determinants of the stability of transcription elongation complexes: interactions of the nascent RNA with the DNA template and the RNA polymerase

How is polyadenylation restricted to 3'-untranslated regions?

Polyadenylation occurs at numerous sites within 3'-untranslated regions (3'-UTRs) but rarely within coding regions. How does Pol II travel through long coding regions without generating poly(A) sites, yet then permits promiscuous polyadenylation once it reaches the 3'-UTR? The cleavage/polyadenylation (CpA) machinery preferentially associates with 3'-UTRs, but it is unknown how its recruitment is restricted to 3'-UTRs during Pol II elongation. Unlike coding regions, 3'-UTRs have long AT-rich stretches of DNA that may be important for restricting polyadenylation to 3'-UTRs. Recognition of the 3'-UTR could occur at the DNA (AT-rich), RNA (AU-rich), or RNA:DNA hybrid (rU:dA- and/or rA:dT-rich) level. Based on the nucleic acid critical for 3'-UTR recognition, there are three classes of models, not mutually exclusive, for how the CpA machinery is selectively recruited to 3'-UTRs, thereby restricting where polyadenylation occurs: (1) RNA-based models suggest that the CpA complex directly (or indirectly through one or more intermediary proteins) binds long AU-rich stretches that are exposed after Pol II passes through these regions. (2) DNA-based models suggest that the AT-rich sequence affects nucleosome depletion or the elongating Pol II machinery, resulting in dissociation of some elongation factors and subsequent recruitment of the CpA machinery. (3) RNA:DNA hybrid models suggest that preferential destabilization of the Pol II elongation complex at rU:dA- and/or rA:dT-rich duplexes bridging the nucleotide addition and RNA exit sites permits preferential association of the CpA machinery with 3'-UTRs. Experiments to provide evidence for one or more of these models are suggested.

Spatiotemporal Dynamics of Single-stranded DNA Intermediates in Escherichia coli

Single-stranded DNA gaps form within the E. coli chromosome during replication, repair and recombination. However, information about the extent of ssDNA creation in the genome is limited. To complement a recent whole-genome sequencing study revealing ssDNA gap genomic distribution, size, and frequency, we used fluorescence microscopy to monitor the spatiotemporal dynamics of single-stranded DNA within live E. coli cells. The ssDNA was marked by a functional fluorescent protein fusion of the SSB protein that replaces the wild type SSB. During log-phase growth the SSB fusion produces a mixture of punctate foci and diffuse fluorescence spread throughout the cytosol. Many foci are clustered. Fluorescent markers of DNA polymerase III frequently co-localize with SSB foci, often localizing to the outer edge of the large SSB features. Novel SSB-enriched features form and resolve regularly during normal growth. UV irradiation induces a rapid increase in SSB foci intensity and produces large features composed of multiple partially overlapping foci. The results provide a critical baseline for further exploration of ssDNA generation during DNA metabolism. Alterations in the patterns seen in a mutant lacking RecB function tentatively suggest associations of particular SSB features with the repair of double strand breaks and post-replication gaps.

Basic mechanisms and kinetics of pause-interspersed transcript elongation

RNA polymerase pausing during elongation is an important mechanism in the regulation of gene expression. Pausing along DNA templates is thought to be induced by distinct signals encoded in the nucleic acid sequence and halt elongation complexes to allow time for necessary co-transcriptional events. Pausing signals have been classified as those producing short-lived elemental, long-lived backtracked, or hairpin-stabilized pauses. In recent years, structural microbiology and single-molecule studies have significantly advanced our understanding of the paused states, but the dynamics of these states are still uncertain, although several models have been proposed to explain the experimentally observed pausing behaviors. This review summarizes present knowledge about the paused states, discusses key discrepancies among the kinetic models and their basic assumptions, and highlights the importance and challenges in constructing theoretical models that may further our biochemical understanding of transcriptional pausing.

The Integrator Complex Attenuates Promoter-Proximal Transcription at Protein-Coding Genes

The transition of RNA polymerase II (Pol II) from initiation to productive elongation is a central, regulated step in metazoan gene expression. At many genes, Pol II pauses stably in early elongation, remaining engaged with the 25- to 60-nt-long nascent RNA for many minutes while awaiting signals for release into the gene body. However, 15%-20% of genes display highly unstable promoter Pol II, suggesting that paused polymerase might dissociate from template DNA at these promoters and release a short, non-productive mRNA. Here, we report that paused Pol II can be actively destabilized by the Integrator complex. Specifically, we present evidence that Integrator utilizes its RNA endonuclease activity to cleave nascent RNA and drive termination of paused Pol II. These findings uncover a previously unappreciated mechanism of metazoan gene repression, akin to bacterial transcription attenuation, wherein promoter-proximal Pol II is prevented from entering productive elongation through factor-regulated termination.

The Integrator Complex Attenuates Promoter-Proximal Transcription at Protein-Coding Genes

The transition of RNA polymerase II (Pol II) from initiation to productive elongation is a central, regulated step in metazoan gene expression. At many genes, Pol II pauses stably in early elongation, remaining engaged with the 25- to 60-nt-long nascent RNA for many minutes while awaiting signals for release into the gene body. However, 15%-20% of genes display highly unstable promoter Pol II, suggesting that paused polymerase might dissociate from template DNA at these promoters and release a short, non-productive mRNA. Here, we report that paused Pol II can be actively destabilized by the Integrator complex. Specifically, we present evidence that Integrator utilizes its RNA endonuclease activity to cleave nascent RNA and drive termination of paused Pol II. These findings uncover a previously unappreciated mechanism of metazoan gene repression, akin to bacterial transcription attenuation, wherein promoter-proximal Pol II is prevented from entering productive elongation through factor-regulated termination.

Trigger loop dynamics can explain stimulation of intrinsic termination by bacterial RNA polymerase without terminator hairpin contact

In bacteria, intrinsic termination signals cause disassembly of the highly stable elongating transcription complex (EC) over windows of two to three nucleotides after kilobases of RNA synthesis. Intrinsic termination is caused by the formation of a nascent RNA hairpin adjacent to a weak RNA-DNA hybrid within RNA polymerase (RNAP). Although the contributions of RNA and DNA sequences to termination are largely understood, the roles of conformational changes in RNAP are less well described. The polymorphous trigger loop (TL), which folds into the trigger helices to promote nucleotide addition, also is proposed to drive termination by folding into the trigger helices and contacting the terminator hairpin after invasion of the hairpin in the RNAP main cleft [Epshtein V, Cardinale CJ, Ruckenstein AE, Borukhov S, Nudler E (2007) Mol Cell 28:991-1001]. To investigate the contribution of the TL to intrinsic termination, we developed a kinetic assay that distinguishes effects of TL alterations on the rate at which ECs terminate from effects of the TL on the nucleotide addition rate that indirectly affect termination efficiency by altering the time window in which termination can occur. We confirmed that the TL stimulates termination rate, but found that stabilizing either the folded or unfolded TL conformation decreased termination rate. We propose that conformational fluctuations of the TL (TL dynamics), not TL-hairpin contact, aid termination by increasing EC conformational diversity and thus access to favorable termination pathways. We also report that the TL and the TL sequence insertion (SI3) increase overall termination efficiency by stimulating pausing, which increases the flux of ECs into the termination pathway.

Transcription elongation complex stability: the topological lock

Transcription machinery from a variety of organisms shows striking mechanistic similarity. Both multi- and single subunit RNA polymerases have evolved an 8-10-base pair RNA-DNA hybrid as a part of a stably transcribing elongation complex. Through characterization of halted complexes that can readily carry out homopolymeric slippage synthesis, this study reveals that T7 RNA polymerase elongation complexes containing only a 4-base pair hybrid can nevertheless be more stable than those with the normal 8-base pair hybrid. We propose that a key feature of this stability is the topological threading of RNA through the complex and/or around the DNA template strand. The data are consistent with forward translocation as a mechanism to allow unthreading of the topological lock, as can occur during programmed termination of transcription.

Single-molecule studies of RNA polymerase: motoring along

Single-molecule techniques have advanced our understanding of transcription by RNA polymerase (RNAP). A new arsenal of approaches, including single-molecule fluorescence, atomic-force microscopy, magnetic tweezers, and optical traps (OTs) have been employed to probe the many facets of the transcription cycle. These approaches supply fresh insights into the means by which RNAP identifies a promoter, initiates transcription, translocates and pauses along the DNA template, proofreads errors, and ultimately terminates transcription. Results from single-molecule experiments complement the knowledge gained from biochemical and genetic assays by facilitating the observation of states that are otherwise obscured by ensemble averaging, such as those resulting from heterogeneity in molecular structure, elongation rate, or pause propensity. Most studies to date have been performed with bacterial RNAP, but work is also being carried out with eukaryotic polymerase (Pol II) and single-subunit polymerases from bacteriophages. We discuss recent progress achieved by single-molecule studies, highlighting some of the unresolved questions and ongoing debates.

Direct spectroscopic study of reconstituted transcription complexes reveals that intrinsic termination is driven primarily by thermodynamic destabilization of the nucleic acid framework

Changes in near UV circular dichroism (CD) and fluorescence spectra of site-specifically placed pairs of 2-aminopurine residues have been used to probe the roles of the RNA hairpin and the RNA-DNA hybrid in controlling intrinsic termination of transcription. Functional transcription complexes were assembled directly by mixing preformed nucleic acid scaffolds of defined sequence with T7 RNA polymerase (RNAP). Scaffolds containing RNA hairpins immediately upstream of a GC-rich hybrid formed complexes of reduced stability, whereas the same hairpins adjacent to a hybrid of rU-dA base pairs triggered complex dissociation and transcript release. 2-Aminopurine probes at the upstream ends of the hairpin stems show that the hairpins open on RNAP binding and that stem re-formation begins after one or two RNA bases on the downstream side of the stem have emerged from the RNAP exit tunnel. Hairpins directly adjacent to the RNA-DNA hybrid weaken RNAP binding, decrease elongation efficiency, and disrupt the upstream end of the hybrid as well as interfere with the movement of the template base at the RNAP active site. Probing the edges of the DNA transcription bubble demonstrates that termination hairpins prevent translocation of the RNAP, suggesting that they transiently "lock" the polymerase to the nucleic acid scaffold and, thus, hold the RNA-DNA hybrid "in frame." At intrinsic terminators the weak rU-dA hybrid and the adjacent termination hairpin combine to destabilize the elongation complex sufficiently to permit significant transcript release, whereas hairpin-dependent pausing provides time for the process to go to completion.

Direct versus limited-step reconstitution reveals key features of an RNA hairpin-stabilized paused transcription complex

We have identified minimal nucleic acid scaffolds capable of reconstituting hairpin-stabilized paused transcription complexes when incubated with RNAP either directly or in a limited step reconstitution assay. Direct reconstitution was achieved using a 29-nucleotide (nt) RNA whose 3'-proximal 9-10 nt pair to template DNA within an 11-nt noncomplementary bubble of a 39-bp duplex DNA; the 5'-proximal 18 nt of RNA forms the his pause RNA hairpin. Limited-step reconstitution was achieved on the same DNAs using a 27-nt RNA that can be 3'-labeled during reconstitution and then extended 2 nt past the pause site to assay transcriptional pausing. Paused complexes formed by either method recapitulated key features of a promoter-initiated, hairpin-stabilized paused complex, including a slow rate of pause escape, resistance to transcript cleavage and pyrophosphorolysis, and enhancement of pausing by the elongation factor NusA. These findings establish that RNA upstream from the pause hairpin and pyrophosphate are not essential for pausing and for NusA action. Reconstitution of the his paused transcription complex provides a valuable tool for future studies of protein-nucleic interactions involved in transcriptional pausing.

Observed instability of T7 RNA polymerase elongation complexes can be dominated by collision-induced "bumping"

T7 RNA polymerase elongates RNA at a relatively high rate and can displace many tightly bound protein-DNA complexes. Despite these properties, measurements of the stability of stalled elongation complexes have shown lifetimes that are much shorter than those of the multisubunit RNA polymerases. In this work, we demonstrate that the apparent instability of stalled complexes actually arises from the action of trailing RNA polymerases (traveling in the same direction) displacing the stalled complex. Moreover, the instability caused by collision between two polymerases is position dependent. A second polymerase is blocked from promoter binding when a leading complex is stalled 12 bp or less from the promoter. The trailing complex can bind and make abortive transcripts when the leading complex is between 12 and 20 bp from the promoter, but it cannot displace the first complex since it is in a unstable initiation conformation. Only when the leading complex is stalled more than 20 bp away from the promoter can a second polymerase bind, initiate, and displace the leading complex.

Conformational heterogeneity in RNA polymerase observed by single-pair FRET microscopy

Kinetic, structural, and single-molecule transcription measurements suggest that RNA polymerase can adopt many different conformations during elongation. We have measured the geometry of the DNA and RNA in ternary elongation complexes using single-pair fluorescence resonance energy transfer. Six different synthetic transcription elongation complexes were constructed from DNA containing an artificial transcription bubble, an RNA primer, and core RNA polymerase from Escherichia coli. Two different RNA primers were used, an 8-mer and a 5'-extended 11-mer. Fluorescent dye labels were attached at one of three positions on the DNA and at the RNA primer 5'-end. Structurally, the upstream DNA runs perpendicular to the proposed RNA exit channel. Upon nucleoside-triphosphate addition, DNA/RNA hybrid separation occurs readily in the 11-mer complexes but not in the 8-mer complexes. Clear evidence was obtained that RNA polymerase exists in multiple conformations among which it fluctuates.

Thermodynamic and kinetic modeling of transcriptional pausing

We present a statistical mechanics approach for the prediction of backtracked pauses in bacterial transcription elongation derived from structural models of the transcription elongation complex (EC). Our algorithm is based on the thermodynamic stability of the EC along the DNA template calculated from the sequence-dependent free energy of DNA-DNA, DNA-RNA, and RNA-RNA base pairing associated with (i) the translocational and size fluctuations of the transcription bubble; (ii) changes in the associated DNA-RNA hybrid; and (iii) changes in the cotranscriptional RNA secondary structure upstream of the RNA exit channel. The calculations involve no adjustable parameters except for a cutoff used to discriminate paused from nonpaused complexes. When applied to 100 experimental pauses in transcription elongation by Escherichia coli RNA polymerase on 10 DNA templates, the approach produces statistically significant results. We also present a kinetic model for the rate of recovery of backtracked paused complexes. A crucial ingredient of our model is the incorporation of kinetic barriers to backtracking resulting from steric clashes of EC with the cotranscriptionally generated RNA secondary structure, an aspect not included explicitly in previous attempts at modeling the transcription elongation process.

An Extended Winged Helix Domain in General Transcription Factor E/IIEα

Initiation of eukaryotic mRNA transcription requires melting of promoter DNA with the help of the general transcription factors TFIIE and TFIIH. Here we define a conserved and functionally essential N-terminal domain in TFE, the archaeal homolog of the large TFIIE subunit alpha. X-ray crystallography shows that this TFE domain adopts a winged helix-turn-helix (winged helix) fold, extended by specific alpha-helices at the N and C termini. Although the winged helix fold is often found in DNA-binding proteins, we show that TFE is not a typical DNA-binding winged helix protein, because its putative DNA-binding face shows a negatively charged groove and an unusually long wing, and because the domain lacks DNA-binding activity in vitro. The groove and a conserved hydrophobic surface patch on the additional N-terminal alpha-helix may, however, allow for interactions with other general transcription factors and RNA polymerase. Homology modeling shows that the TFE domain is conserved in TFIIE alpha, including the potential functional surfaces.

The functional anatomy of an intrinsic transcription terminator

To induce dissociation of the transcription elongation complex, a typical intrinsic terminator forms a G.C-rich hairpin structure upstream from a U-rich run of approximately eight nucleotides that define the transcript 3' end. Here, we have adapted the nucleotide analog interference mapping (NAIM) approach to identify the critical RNA atoms and functional groups of an intrinsic terminator during transcription with T7 RNA polymerase. The results show that discrete components within the lower half of the hairpin stem form transient termination-specific contacts with the RNA polymerase. Moreover, disruption of interactions with backbone components of the transcript region hybridized to the DNA template favors termination. Importantly, comparative NAIM of termination events occurring at consecutive positions revealed overlapping but distinct sets of functionally important residues. Altogether, the data identify a collection of RNA terminator components, interactions and spacing constraints that govern efficient transcript release. The results also suggest specific architectural rearrangements of the transcription complex that may participate in allosteric control of intrinsic transcription termination.

The initiation-elongation transition: lateral mobility of RNA in RNA polymerase II complexes is greatly reduced at +8/+9 and absent by +23

RNA polymerase II transcription complexes stalled shortly after initiation over a repetitive segment of the template can undergo efficient transcript slippage, during which the 3' end of the RNA slides upstream and then re-pairs with the template, allowing transcription to continue. In the present study, we have used transcript slippage as an assay to identify possible structural transitions that occur as the polymerase passes from the initiation to the elongation phase of transcription. We reasoned that transcript slippage would not occur in fully processive complexes. We constructed a series of templates that allowed us to stall RNA polymerase II after the synthesis of a repetitive sequence (5'-CUCUCU-3') at varying distances downstream of +1. We found that polymerase must synthesize at least a 23-nt RNA to attain resistance to transcript slippage. The ability to undergo slippage was lost in two discrete steps, suggestive of two distinct transitions. The first transition is the formation of the 8- to 9-bp mature RNA-DNA hybrid, when slippage abruptly dropped by 10-fold. However, easily detectable slippage continued until 14 more bonds were made. Thus, although the transcript becomes tightly constrained within the transcription complex once the hybrid reaches its final length, much more RNA synthesis is required before the RNA is no longer able to slip upstream along the template. This last point may reflect an important stabilizing role for the interaction of the polymerase with the transcript well upstream of the RNA-DNA hybrid.

Shortening of RNA:DNA hybrid in the elongation complex of RNA polymerase is a prerequisite for transcription termination

Passage of E. coli RNA polymerase through an intrinsic transcription terminator, which encodes an RNA hairpin followed by a stretch of uridine residues, results in quick dissociation of the elongation complex. We show that folding of the hairpin disrupts the three upstream base pairs of the 8 bp RNA:DNA hybrid, a major stability determinant in the complex. Shortening the weak rU:dA hybrid from 8 nt to 5 nt causes dissociation of the complex. During termination, the hairpin does not directly compete for base pairing with the 8 bp hybrid. Thus, melting of the hybrid seems to result from spatial restrictions in RNA polymerase that couple the hairpin formation with the disruption of the hybrid immediately downstream from the stem. Our results suggest that a similar mechanism disrupts elongation complexes of yeast RNA polymerase II in vitro.

RNA polymerase II transcription complexes may become arrested if the nascent RNA is shortened to less than 50 nucleotides

A significant fraction of RNA polymerase II transcription complexes become arrested when halted within a particular initially transcribed region after the synthesis of 23-32-nucleotide RNAs. If polymerases are halted within the same sequence at a promoter-distal location, they remain elongation-competent. However, when the RNAs within these promoter-distal complexes are truncated to between 21 and 48 nucleotides, many of the polymerases become arrested. The degree of the arrest correlates very well with the length of the RNA in both the promoter-proximal and -distal complexes. This effect is also observed when comparing promoter-proximal and promoter-distal complexes halted over a completely different sequence. The unusual propensity of many promoter-proximal RNA polymerase II complexes to arrest may therefore be recreated in promoter-distal complexes simply by shortening the nascent RNA. Thus, the transition to full elongation competence by RNA polymerase II is dependent on the synthesis of about 50 nt of RNA, and this transition is reversible. We also found that arrest is facilitated in promoter-distal complexes by the hybridization of oligonucleotides to the transcript between 30 and 45 bases upstream of the 3'-end.

Transcription termination: primary intermediates and secondary adducts

In living organisms, stable elongation complexes of RNA polymerase dissociate at specific template positions in a process of transcription termination. It has been suggested that the dissociation is not the immediate cause of termination but is preceded by catalytic inactivation of the elongation complex. In vitro reducing ionic strength can be used to stabilize very unstable and catalytically inactive complex at the point of termination; the previous biochemical characterization of this complex has led to important conclusions regarding termination mechanism. Here we analyze in detail the complexes formed between DNA template, nascent RNA, and Escherichia coli RNA polymerase during transcription through the tR2 terminator of bacteriophage lambda. At low ionic strength, the majority of elongation complexes fall apart upon reaching the terminator. Released RNA and DNA efficiently rebind RNA polymerase (RNAP) and form binary RNAP.RNA and RNAP.DNA complexes, which are indistinguishable from binary complexes obtained by direct mixing of the purified nucleic acids and the enzyme. A small fraction of elongation complexes that reach termination point escapes dissociation because RNA polymerase has backtracked from the terminator to an upstream DNA position. Thus, transcription elongation to a terminator site produces no termination intermediates that withstand dissociation in the time scale appropriate for biochemical studies.

Completion of RNA synthesis by viral RNA replicases

How the 5'-terminus of the template affects RNA synthesis by viral RNA replicases is poorly understood. Using short DNA, RNA and RNA-DNA chimeric templates that can direct synthesis of replicase products, we found that DNA templates tend to direct the synthesis of RNA products that are shorter by 1 nt in comparison to RNA templates. Template-length RNA synthesis was also affected by the concentration of nucleoside triphosphates, the identity of the bases at specific positions close to the 5'-terminus and the C2'-hydroxyl of a ribose at the third nucleotide from the 5'-terminal nucleotide. Similar requirements are observed with two bromoviral replicases, but not with a recombinant RNA-dependent RNA polymerase. These results begin to define the interactions needed for the viral replicase to complete synthesis of viral RNA.

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.

Transcription elongation complex: structure and function

Our understanding of the mechanisms of transcription has been greatly advanced by recent determination of the X-ray structure of bacterial RNA polymerase. Using crosslinking approaches, extensive mapping of DNA and RNA contacts onto this structure allowed tracking of the path of nucleic acids through the transcription elongation complex. The resulting structural model of the transcription elongation complex is linked to the functional one, which is based on numerous data accumulated during previous studies of RNA synthesis. An integrated structure-function model allows the rational explanation of termination and pausing and provides new insights into the mechanisms of transcription.

Identification and characterization of a transcription pause site in rotavirus

In rotavirus, transcription of the 11 double-stranded RNA genome segments occurs within the structurally intact subviral particle, and nascent transcripts are released through channels penetrating the two capsid layers at the icosahedral vertices. To gain insight into the early molecular events in transcription, we used high-resolution polyacrylamide gel electrophoresis to investigate the length distribution of transcription products at various times following initiation. We observed that, in the subviral particle under normal conditions, transcript initiation and capping are followed by a momentary pause in elongation after the addition of 6 to 7 nucleotides. In the absence of the capping reaction cofactor S-adenosylmethionine, conditions under which the rate of nucleotide incorporation is reduced, we observe a significant decrease in the ratio of paused to full-length transcripts. We propose that this pause site may represent the point at which specific molecular events take place to facilitate processive elongation. Furthermore, our results indicate that the presence of specific ligands on the viral surface, such as VP7 in the mature virion, inhibits polymerase function. From the perspective of the viral replication cycle, this inhibition may serve to ensure that transcription occurs with greatest efficiency only after the virus has entered the cytoplasm and assumed the form of a double-layered particle.

Overextended RNA:DNA hybrid as a negative regulator of RNA polymerase II processivity

An eight nucleotide RNA:DNA hybrid at the 3' end of the transcript is required for the stability of the elongation complex (EC) of RNA polymerase II. A non-template DNA strand is not needed for the stability of the EC, which contains this minimal hybrid. Here, we apply a recently developed method for promoter-independent assembly of functional EC of RNA polymerase II from synthetic RNA and DNA oligonucleotides to study the minimal composition of the nucleic acid array required for stability of the complex with RNA longer than eight nucleotides. We found that upon RNA extension beyond 14-16 nt in the course of transcription, non-template DNA becomes essential for maintaining a stable EC. Our data suggest that the overextended RNA:DNA hybrid formed in the absence the non-template DNA acts as a negative regulator of EC stability. The dissociation of the EC correlates with the backsliding of the polymerase along the overextended hybrid. The dual role of the hybrid provides a mechanism for the control of a correct nucleic acid architecture in the EC and of RNA polymerase II processivity.

Analysis of cis-acting sequences involved in plus-strand synthesis of a turnip crinkle virus-associated satellite RNA identifies a new carmovirus replication element

Satellite RNA C (satC) is a 356-base subviral RNA associated with turnip crinkle virus (TCV). A 3'-proximal element (3'-UCCCAAAGUAU) located 11 bases from the 3' terminus of satC minus strands can function as an independent promoter in an in vitro RNA-dependent RNA polymerase (RdRp) transcription system. Furthermore, in the absence of a 5'-proximal element, the 3'-proximal element is required for complementary strand synthesis in vitro. Site-directed mutagenesis was conducted to investigate the functional significance of this element and the 3' minus-strand terminal sequence "3'-OH-CCCUAU," which contains the minus-strand 3'-end sequence "3'-OH-CC(1-2)(A/U)(A/U)(A/U)" found in all carmovirus RNAs. Single mutations in the 3'-terminal sequence, which we have named the carmovirus consensus sequence (CCS), suppressed satC plus-strand synthesis to undetectable levels in protoplasts while still permitting some minus-strand synthesis. However, single and multiple mutations introduced into the 3'-proximal element had little or no effect on satC accumulation in protoplasts. In vivo genetic selection (SELEX) of the minus-strand 3'-terminal 21 bases revealed that all satC species accumulating in plants contained the 3' CCS. In addition, the 3'-proximal element preferentially contained a sequence similar to the CCS and/or polypurines, suggesting that this element may also contribute to accumulation of satC in vivo.

Interactions of Escherichia coli sigma(70) within the transcription elongation complex

A functional transcription elongation complex can be formed without passing through a promoter by adding a complementary RNA primer and core Escherichia coli RNA polymerase in trans to an RNA-primed synthetic bubble-duplex DNA framework. This framework consists of a double-stranded DNA sequence with an internal noncomplementary DNA "bubble" containing a hybridized RNA primer. On addition of core polymerase and the requisite NTPs, the RNA primer is extended in a process that manifests most of the properties of in vitro transcription elongation. This synthetic elongation complex can also be assembled by using holo rather than core RNA polymerase, and in this study we examine the interactions and fate of the sigma(70) specificity subunit of the holopolymerase in the assembly process. We show that the addition of holopolymerase to the bubble-duplex construct triggers the dissociation of the sigma factor from some complexes, whereas in others the RNA oligomer is released into solution instead. These results are consistent with an allosteric competition between sigma(70) and the nascent RNA strand within the elongation complex and suggest that both cannot be bound to the core polymerase simultaneously. However, the dissociation of sigma(70) from the complex can also be stimulated by binding of the holopolymerase to the DNA bubble duplex in the absence of a hybridized RNA primer, suggesting that the binding of the core polymerase to the bubble-duplex construct also triggers a conformational change that additionally weakens the sigma-core interaction.