Balanced branching in transcription termination

High-throughput single-molecule experiments reveal heterogeneity, state switching, and three interconnected pause states in transcription

Pausing by bacterial RNA polymerase (RNAp) is vital in the recruitment of regulatory factors, RNA folding, and coupled translation. While backtracking and intra-structural isomerization have been proposed to trigger pausing, our mechanistic understanding of backtrack-associated pauses and catalytic recovery remains incomplete. Using high-throughput magnetic tweezers, we examine the Escherichia coli RNAp transcription dynamics over a wide range of forces and NTP concentrations. Dwell-time analysis and stochastic modeling identify, in addition to a short-lived elemental pause, two distinct long-lived backtrack pause states differing in recovery rates. We identify two stochastic sources of transcription heterogeneity: alterations in short-pause frequency that underlies elongation-rate switching, and variations in RNA cleavage rates in long-lived backtrack states. Together with effects of force and Gre factors, we demonstrate that recovery from deep backtracks is governed by intrinsic RNA cleavage rather than diffusional Brownian dynamics. We introduce a consensus mechanistic model that unifies our findings with prior models.

Obligate movements of an active site-linked surface domain control RNA polymerase elongation and pausing via a Phe pocket anchor

The catalytic trigger loop (TL) in RNA polymerase (RNAP) alternates between unstructured and helical hairpin conformations to admit and then contact the NTP substrate during transcription. In many bacterial lineages, the TL is interrupted by insertions of two to five surface-exposed, sandwich-barrel hybrid motifs (SBHMs) of poorly understood function. The 188-amino acid, two-SBHM insertion in Escherichia coli RNAP, called SI3, occupies different locations in elongating, NTP-bound, and paused transcription complexes, but its dynamics during active transcription and pausing are undefined. Here, we report the design, optimization, and use of a Cys-triplet reporter to measure the positional bias of SI3 in different transcription complexes and to determine the effect of restricting SI3 movement on nucleotide addition and pausing. We describe the use of H₂O₂ as a superior oxidant for RNAP disulfide reporters. NTP binding biases SI3 toward the closed conformation, whereas transcriptional pausing biases SI3 toward a swiveled position that inhibits TL folding. We find that SI3 must change location in every round of nucleotide addition and that restricting its movements inhibits both transcript elongation and pausing. These dynamics are modulated by a crucial Phe pocket formed by the junction of the two SBHM domains. This SI3 Phe pocket captures a Phe residue in the RNAP jaw when the TL unfolds, explaining the similar phenotypes of alterations in the jaw and SI3. Our findings establish that SI3 functions by modulating TL folding to aid transcriptional regulation and to reset secondary channel trafficking in every round of nucleotide addition.

Single-molecule studies of RNA polymerase: one singular sensation, every little step it takes

Transcription is the first of many biochemical steps that turn the genetic information found in DNA into the proteins responsible for driving cellular processes. In this review, we highlight certain advantages of single-molecule techniques in the study of prokaryotic and eukaryotic transcription, and the specific ways in which these techniques complement conventional, ensemble-based biochemistry. We focus on recent literature, highlighting examples where single-molecule methods have provided fresh insights into mechanism. We also present recent technological advances and outline future directions in the field.

Stochastic bifurcation, slow fluctuations, and bistability as an origin of biochemical complexity

We present a simple, unifying theory for stochastic biochemical systems with multiple time-scale dynamics that exhibit noise-induced bistability in an open-chemical environment, while the corresponding macroscopic reaction is unistable. Nonlinear stochastic biochemical systems like these are fundamentally different from classical systems in equilibrium or near-equilibrium steady state whose fluctuations are unimodal following Einstein-Onsager-Lax-Keizer theory. We show that noise-induced bistability in general arises from slow fluctuations, and a pitchfork bifurcation occurs as the rate of fluctuations decreases. Since an equilibrium distribution, due to detailed balance, has to be independent of changes in time-scale, the bifurcation is necessarily a driven phenomenon. As examples, we analyze three biochemical networks of currently interest: self-regulating gene, stochastic binary decision, and phosphorylation-dephosphorylation cycle with fluctuating kinase. The implications of bistability to biochemical complexity are discussed.

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.

Sequence-resolved detection of pausing by single RNA polymerase molecules

Transcriptional pausing by RNA polymerase (RNAP) plays an important role in the regulation of gene expression. Defined, sequence-specific pause sites have been identified biochemically. Single-molecule studies have also shown that bacterial RNAP pauses frequently during transcriptional elongation, but the relationship of these "ubiquitous" pauses to the underlying DNA sequence has been uncertain. We employed an ultrastable optical-trapping assay to follow the motion of individual molecules of RNAP transcribing templates engineered with repeated sequences carrying imbedded, sequence-specific pause sites of known regulatory function. Both the known and ubiquitous pauses appeared at reproducible locations, identified with base-pair accuracy. Ubiquitous pauses were associated with DNA sequences that show similarities to regulatory pause sequences. Data obtained for the lifetimes and efficiencies of pauses support a model where the transition to pausing branches off of the normal elongation pathway and is mediated by a common elemental state, which corresponds to the ubiquitous pause.

Archaeal RNA polymerase is sensitive to intrinsic termination directed by transcribed and remote sequences

Archaea are prokaryotes with a single DNA-dependent RNA polymerase (RNAP) that is homologous to, and likely resembles the ancestor of all three eukaryotic RNAPs. In vitro studies have confirmed that initiation by archaeal RNAPs resembles the Pol II system, and we report the first detailed in vitro investigation of archaeal transcription termination. Methanothermobacter thermautotrophicus (M.t.) RNAP is susceptible to intrinsic termination at an intergenic sequence that conforms to a bacterial intrinsic terminator, as well as at bona fide bacterial intrinsic terminators. In contrast to bacterial RNAPs, M.t. RNAP also terminated in response to synthetic and natural oligo-T-rich sequences that were not preceded by sequences with any recognizable potential to form a stable RNA hairpin. Both template topology and temperature influenced the position and extent of termination in vitro, and the results argue that transcription of an upstream sequence can alter the termination response of the archaeal RNAP at a remote downstream sequence.

Diversity in the rates of transcript elongation by single RNA polymerase molecules

Single-molecule measurements of the activities of a variety of enzymes show that rates of catalysis may vary markedly between different molecules in putatively homogeneous enzyme preparations. We measured the rate at which purified Escherichia coli RNA polymerase moves along a approximately 2650-bp DNA during transcript elongation in vitro at 0.5 mm nucleoside triphosphates. Individual molecules of a specifically biotinated RNA polymerase derivative were tagged with 199-nm diameter avidin-coated polystyrene beads; enzyme movement along a surface-linked DNA molecule was monitored by observing changes in bead Brownian motion by light microscopy. The DNA was derived from a naturally occurring transcription unit and was selected for the absence of regulatory sequences that induce lengthy pausing or termination of transcription. With rare exceptions, individual enzyme molecules moved at a constant velocity throughout the transcription reaction; the distribution of velocities across a population of 140 molecules was unimodal and was well fit by a Gaussian. However, the width of the Gaussian, sigma = 6.7 bp/s, was considerably larger than the precision of the velocity measurement (1 bp/s). The observations show that different transcription complexes have differences in catalytic rate (and thus differences in structure) that persist for thousands of catalytic turnovers. These differences may provide a parsimonious explanation for the complex transcription kinetics observed in bulk solution.

Reaction pathways in transcript elongation

Transcription of DNA into RNA is a central part of gene expression, and is highly regulated in all organisms. In order to approach transcription control systems on a molecular basis we must understand the mechanisms used by the transcription complex to discharge its various functions, which include transcript initiation, elongation, editing, and termination. In this article we describe recent progress in sorting out the multiple reaction pathways that are, at least in principle, available to the transcription complex at each DNA template position, and show how transcription control systems partition active complexes into these pathways. Understanding these regulatory processes requires an elucidation of the molecular details of how sequence- and factor-dependent changes in the conformations, stabilities, and reaction rates of the complexes determine function. Recent progress in unraveling these issues is summarized in this article and emerging principles that govern the regulation of the elongation phase of transcription are discussed.

Active Escherichia coli transcription elongation complexes are functionally homogeneous

The elongation phase of RNA transcription represents a major target for the regulation of gene expression. Two general classes of models have been proposed to define the dynamic properties of transcription complexes in the elongation phase. Stable heterogeneity models posit that the ensemble of active elongation-competent complexes consists of multiple distinct and stable forms that are specified early in the transcription cycle and isomerize to other forms slowly. In contrast, equilibrium or rapid interconversion models require that active elongation complexes interconvert rapidly on the time-scale of single nucleotide addition. Measurements of transcription termination efficiency (TE) can be used to distinguish between these models, because stable heterogeneity models predict that the termination-resistant fraction of an elongation complex population should be enriched after transcription through an upstream terminator, leading to a decreased TE at downstream terminators. In contrast, rapid interconversion models require that the population of active (elongation-competent) complexes equilibrate after transcription through each terminator and, therefore, that the value of TE observed at identical upstream and downstream terminators should be the same. We have constructed transcription templates containing multiple identical terminators and found no significant changes in TE with terminator position along the template. Various other forms of upstream treatment of elongation complex populations also were used to attempt to fractionate the complexes into functionally different forms. None of these treatments changed the apparent TE at downstream terminators. These results are consistent with a rapid interconversion model of transcript elongation. The consequences of these results for the regulation of gene expression are discussed.