Parameters affecting transcription termination by Escherichia coli RNA polymerase

Prediction of transcriptional terminators in Bacillus subtilis and related species

In prokaryotes, genes belonging to the same operon are transcribed in a single mRNA molecule. Transcription starts as the RNA polymerase binds to the promoter and continues until it reaches a transcriptional terminator. Some terminators rely on the presence of the Rho protein, whereas others function independently of Rho. Such Rho-independent terminators consist of an inverted repeat followed by a stretch of thymine residues, allowing us to predict their presence directly from the DNA sequence. Unlike in Escherichia coli, the Rho protein is dispensable in Bacillus subtilis, suggesting a limited role for Rho-dependent termination in this organism and possibly in other Firmicutes. We analyzed 463 experimentally known terminating sequences in B. subtilis and found a decision rule to distinguish Rho-independent transcriptional terminators from non-terminating sequences. The decision rule allowed us to find the boundaries of operons in B. subtilis with a sensitivity and specificity of about 94%. Using the same decision rule, we found an average sensitivity of 94% for 57 bacteria belonging to the Firmicutes phylum, and a considerably lower sensitivity for other bacteria. Our analysis shows that Rho-independent termination is dominant for Firmicutes in general, and that the properties of the transcriptional terminators are conserved. Terminator prediction can be used to reliably predict the operon structure in these organisms, even in the absence of experimentally known operons. Genome-wide predictions of Rho-independent terminators for the 57 Firmicutes are available in the Supporting Information section.

In prokaryotes, genes belonging to the same operon are transcribed in a single mRNA molecule. Transcription starts as the RNA polymerase binds to the promoter and continues until it reaches a transcriptional terminator. To understand the gene regulatory network of transcription in bacteria, it is important as a first step to determine the operon structure. In this paper, the authors show that (unlike in Escherichia coli) most terminators in Bacillus subtilis function independently of the terminator protein Rho. As these Rho-independent terminators consist of an inverted repeat followed by a stretch of thymine residues, their presence can be predicted directly from the DNA sequence. The authors derived a decision rule by analyzing experimentally known terminating sequences in B. subtilis, and show that the operon boundaries can be found with a high accuracy (about 94%) in B. subtilis and other Firmicutes, even in the absence of experimentally known operons in the given organism. The properties of the transcriptional terminators are shown to be conserved within the Firmicutes phylum. For bacteria other than Firmicutes, the prediction accuracy is considerably lower, suggesting that Rho-dependent or possibly currently unknown termination mechanisms are important in these organisms.

Sequence context effects on oligo(dT) termination signal recognition by Saccharomyces cerevisiae RNA polymerase III

Eukaryotic RNA polymerase (Pol) III terminates transcription at short runs of T residues in the coding DNA strand. By genomic analysis, we found that T(5) and T(4) are the shortest Pol III termination signals in yeasts and mammals, respectively, and that, at variance with yeast, oligo(dT) terminators longer than T(5) are very rare in mammals. In Saccharomyces cerevisiae, the strength of T(5) as a terminator was found to be largely influenced by both the upstream and the downstream sequence context. In particular, the CT sequence, which is naturally present downstream of T(5) in the 3'-flank of some tDNAs, was found to act as a terminator-weakening element that facilitates translocation by reducing Pol III pausing at T(5). In contrast, tDNA transcription termination was highly efficient when T(5) was followed by an A or G residue. Surprisingly, however, when a termination-proficient T(5) signal was taken out from the tDNA context and placed downstream of a fragment of the SCR1 gene, its termination activity was compromised, both in vitro and in vivo. Even the T(6) sequence, acting as a strong terminator in tRNA gene contexts, was unexpectedly weak within the SNR52 transcription unit, where it naturally occurs. The observed sequence context effects reflect intrinsic recognition properties of Pol III, because they were still observed in a simplified in vitro transcription system only consisting of purified RNA polymerase and template DNA. Our findings strengthen the notion that termination signal recognition by Pol III is influenced in a complex way by the region surrounding the T cluster and suggest that read-through transcription beyond T clusters might play a significant role in the biogenesis of class III gene products.

Novel genes of the dsr gene cluster and evidence for close interaction of Dsr proteins during sulfur oxidation in the phototrophic sulfur bacterium Allochromatium vinosum

Seven new genes designated dsrLJOPNSR were identified immediately downstream of dsrABEFHCMK, completing the dsr gene cluster of the phototrophic sulfur bacterium Allochromatium vinosum D (DSM 180(T)). Interposon mutagenesis proved an essential role of the encoded proteins for the oxidation of intracellular sulfur, an obligate intermediate during the oxidation of sulfide and thiosulfate. While dsrR and dsrS encode cytoplasmic proteins of unknown function, the other genes encode a predicted NADPH:acceptor oxidoreductase (DsrL), a triheme c-type cytochrome (DsrJ), a periplasmic iron-sulfur protein (DsrO), and an integral membrane protein (DsrP). DsrN resembles cobyrinic acid a,c-diamide synthases and is probably involved in the biosynthesis of siro(heme)amide, the prosthetic group of the dsrAB-encoded sulfite reductase. The presence of most predicted Dsr proteins in A. vinosum was verified by Western blot analysis. With the exception of the constitutively present DsrC, the formation of Dsr gene products was greatly enhanced by sulfide. DsrEFH were purified from the soluble fraction and constitute a soluble alpha(2)beta(2)gamma(2)-structured 75-kDa holoprotein. DsrKJO were purified from membranes pointing at the presence of a transmembrane electron-transporting complex consisting of DsrKMJOP. In accordance with the suggestion that related complexes from dissimilatory sulfate reducers transfer electrons to sulfite reductase, the A. vinosum Dsr complex is copurified with sulfite reductase, DsrEFH, and DsrC. We therefore now have an ideal and unique possibility to study the interaction of sulfite reductase with other proteins and to clarify the long-standing problem of electron transport from and to sulfite reductase, not only in phototrophic bacteria but also in sulfate-reducing prokaryotes.

Transcriptional interference between convergent promoters caused by elongation over the promoter

Transcriptional interference with convergent transcription from face-to-face promoters is a potentially important form of gene regulation in all organisms. Using LacZ reporter studies, the mechanism of interference was determined for a pair of face-to-face prokaryotic promoters in which a strong promoter interferes 5.6-fold with a weak promoter, 62 bp away. The promoters were variously rearranged to test different models of interference. Terminating transcription from the strong promoter before it reached the weak promoter dramatically reduced interference, indicating a requirement for the passage of the converging RNAP over the weak promoter. Based on in vitro experiments showing a slow rate of escape for open complexes at the weak promoter and their sensitivity to head-on collisions with elongating RNAP, a "sitting duck" model of interference is proposed and supported with in vivo permanganate footprinting. The model is further supported by the analysis of a second set of prokaryotic face-to-face promoters.

Discontinuous movement and conformational change during pausing and termination by T7 RNA polymerase

Time-resolved characterization of T7 RNA polymerase pausing and terminating at a class II termination site has been carried out using site-specifically tethered chemical nucleases. The data indicate that T7RNAP normally moves uniformly down the template as a rigid body. However, at the class II site this movement is interrupted, and the leading edge of the polymerase moves further along the DNA than the trailing edge. This discontinuous movement may persist until it can no longer be accommodated by conformational changes in the elongation complex, at which point the polymerase can either pause or terminate. Termination, but not pausing, is abrogated by introduction of a disulfide bond between the polymerase fingers and thumb subdomains. The introduced cysteines disrupt a thumb-fingers salt-bridge and, under reducing conditions, this mutant enzyme shows reduced processivity coincident with extension of the RNA to 5 nt. These observations suggest that termination requires that the thumb and fingers subdomains move apart, in a reversal of a conformational change important for initially forming a stable transcription complex.

Downstream DNA sequence effects on transcription elongation. Allosteric binding of nucleoside triphosphates facilitates translocation via a ratchet motion

The ability of RNA polymerase (RNAP) to adopt multiple conformations is central to transcriptional regulation. In previous work, we demonstrated that RNAP can exist in an unactivated state that catalyzes synthesis slowly and an activated state that catalyzes synthesis rapidly, with the transition from the unactivated to the activated state being induced by the templated NTP binding to an allosteric site on the RNAP. In this work, we investigate the effects of downstream DNA sequences on the kinetics of single nucleotide incorporation. We demonstrate that changing the identity of the DNA base 1 bp downstream (+2) from the site of incorporation (+1) can regulate the catalytic activity of RNAP. Combining these data with sequence and structural analyses and molecular modeling, we identify the streptolydigin-binding region (Escherichia coli beta residues 543-546), which lies across from the downstream DNA, as the putative allosteric NTP binding site. We present a structural model in which the NTP binds to the streptolydigin loop and upon pairing with the +1 DNA base in the unactivated state or the +2 DNA base in the activated state facilitates translocation via a ratchet motion. This model provides an alternative mechanism for pausing as well as a structural explanation not only for our kinetic data but also for data from elongation studies on yeast RNAP II.

In vitro studies of transcript initiation by Escherichia coli RNA polymerase. 2. Formation and characterization of two distinct classes of initial transcribing complexes

By following the kinetics of abortive and productive synthesis in single-round transcription assays, we confirm the existence of two general classes of initial transcribing complexes (ITCs), which we term "productive ITC" and "unproductive ITC". The productive ITCs are able to escape from the promoter rapidly to produce full-length transcripts, but only after carrying out an obligate series of abortive initiation steps. The unproductive ITCs were found to synthesize mostly abortive transcripts of 2-3 nucleotides and escape from the promoter extremely slowly, if at all. Formation of the unproductive ITC is not due to the inactive RNA polymerase. Instead, RNA polymerase molecules recovered from both the productive and unproductive ITC fractions were shown to carry out abortive and productive synthesis with both the partitioning tendency and transcription kinetics similar to those of the original enzyme. Our results suggest that early transcription complexes are partitioned into the productive and unproductive ITCs most likely during the formation of open promoter complexes. The extent of partitioning varies with individual promoter sequences and is dependent on the nature and concentration of the initiating nucleotide. Thus, multiple classes of ITCs can be formed during promoter binding and transcript initiation.

The downstream DNA jaw of bacterial RNA polymerase facilitates both transcriptional initiation and pausing

Regulation of RNA polymerase during initiation, elongation, and termination of transcription is mediated in part by interactions with intrinsic regulatory signals encoded in the RNA and DNA that contact the enzyme. These interactions include contacts to an 8-9-bp RNA:DNA hybrid within the active-site cleft of the enzyme, contacts to the melted nontemplate DNA strand in the vicinity of the hybrid, contacts to exiting RNA upstream of the hybrid, and contacts to approximately 20 bp of duplex DNA downstream of the active site. Based on characterization of an amino acid substitution (G1161R) and a deletion (Delta1149-1190) in the jaw domain of the bacterial RNA polymerase largest subunit (beta'), we report here that contacts of the jaw domain to downstream DNA at the leading edge of the transcription complex contribute to regulation during all three phases of transcription. The results provide insight into the role of the jaw domain-downstream DNA contact in transcriptional initiation and pausing and suggest possible explanations for the previously reported isolation of the jaw mutants based on reduced ColEI plasmid replication.

NusA-stimulated RNA polymerase pausing and termination participates in the Bacillus subtilis trp operon attenuation mechanism invitro

The trp RNA-binding attenuation protein (TRAP) regulates expression of the Bacillus subtilis trpEDCFBA operon by transcription attenuation and translation control mechanisms. Both mechanisms require the binding of tryptophan-activated TRAP to the 11 (G/U)AG-repeat segment in the trp leader transcript. To promote termination, TRAP must bind to the nascent RNA before the antiterminator structure forms. Because only 20 nucleotides separate the TRAP-binding site from the 3' end of the antiterminator, TRAP has a short time frame to control this regulatory decision. Synchronization of factor binding and/or RNA folding with the RNA polymerase position is a major challenge in all attenuation mechanisms. Because RNA polymerase pausing allows this synchronization in many attenuation mechanisms, we performed experiments in vitro to determine whether pausing participates in the B. subtilis trp attenuation mechanism. We identified two NusA-stimulated pause sites in the trp leader region. Formation of pause hairpins participates in pausing at both positions. The first pause occurred at the nucleotide just preceding the critical overlap between the alternative antiterminator and terminator structures. TRAP binding to transcripts containing preexisting pause complexes releases RNA polymerase, suggesting that pausing provides additional time for TRAP to bind and promote termination. The second pause is downstream from the trp leader termination point, raising the possibility that this pause event participates in the trpE translation control mechanism. NusA also increases the efficiency of termination in the trp leader region and shifts termination one nucleotide upstream. Finally, NusA-stimulated termination is cooperative, suggesting that binding of multiple NusA molecules influences termination.

UTP allosterically regulates transcription by Escherichia coli RNA polymerase from the bacteriophage T7 A1 promoter

In the case of Escherichia coli RNA polymerase, UTP at elevated concentrations suppresses terminated transcript accumulation during multiple-round transcription from a DNA construct containing the T7 A1 promoter and T(e) terminator. The step that is affected by UTP at elevated concentrations is promoter clearance. In an attempt to understand better the mechanism by which UTP regulates this step, we analyzed the effect of UTP on the formation of pppApU in the presence of only UTP and ATP. At elevated concentrations, UTP is a non-competitive inhibitor with respect to ATP in the formation of pppApU. This indicates that the effect of UTP on the formation of pppApU is mediated through an allosteric site. Moreover, the magnitude of the inhibition of pppApU formation is sufficient to account for the decrease in terminated transcript accumulation at elevated UTP concentrations. Thus, it appears that UTP modulates terminated transcript accumulation during multiple-round transcription from this DNA construct by allosteric regulation of promoter clearance at the point of transcription initiation.

Sequence requirements for terminators and antiterminators in the T box transcription antitermination system: disparity between conservation and functional requirements

The T box transcription termination control system is used in Gram-positive bacteria to regulate expression of aminoacyl-tRNA synthetase and other amino acid-related genes. Readthrough of a transcriptional terminator located in the leader region of the target gene is dependent on a specific interaction between the nascent leader transcript and the cognate uncharged tRNA. This interaction is required for formation of an antiterminator structure in the leader, which prevents formation of a competing transcriptional terminator stem-loop. The antiterminators and terminators of genes in this family are highly conserved in both secondary structure and primary sequence; the antiterminator contains the T box sequence, which is the most highly conserved leader element. These conserved features were investigated by phylogenetic and mutational analysis. Changes at highly conserved positions in the bulge and in the helix above the bulge reduced function, while alteration of other positions that were as much as 96% conserved did not have a major effect. The disparity between sequence conservation and function may be due to the requirement for maintaining base pairing in both the antiterminator and terminator structures.

RapA, a bacterial homolog of SWI2/SNF2, stimulates RNA polymerase recycling in transcription

We report that RapA, an Escherichia coli RNA polymerase (RNAP)-associated homolog of SWI2/SNF2, is capable of dramatic activation of RNA synthesis. The RapA-mediated transcriptional activation in vitro depends on supercoiled DNA and high salt concentrations, a condition that is likely to render the DNA superhelix tightly compacted. Moreover, RapA activates transcription by stimulating RNAP recycling. Mutational analyses indicate that the ATPase activity of RapA is essential for its function as a transcriptional activator, and a rapA null mutant exhibits a growth defect on nutrient plates containing high salt concentrations in vivo. Thus, RapA acts as a general transcription factor and an integral component of the transcription machinery. The mode of action of RapA in remodeling posttranscription or posttermination complexes is discussed.

Transcriptional analysis of the tet(P) operon from Clostridium perfringens

The Clostridium perfringens tetracycline resistance determinant from the 47-kb conjugative R-plasmid pCW3 is unique in that it consists of two overlapping genes, tetA(P) and tetB(P), which mediate resistance by different mechanisms. Detailed transcriptional analysis has shown that the inducible tetA(P) and tetB(P) genes comprise an operon that is transcribed from a single promoter, P3, located 529 bp upstream of the tetA(P) start codon. Deletion of P3 or alteration of the spacing between the -35 and -10 regions significantly reduced the level of transcription in a reporter construct. Induction was shown to be mediated at the level of transcription. Unexpectedly, a factor-independent terminator, T1, was detected downstream of P3 but before the start of the tetA(P) gene. Deletion or mutation of this terminator led to increased read-through transcription in the reporter construct. It is postulated that the T1 terminator is an intrinsic control element of the tet(P) operon and that it acts to prevent the overexpression of the TetA(P) transmembrane protein, even in the presence of tetracycline.

Prediction of rho-independent transcriptional terminators in Escherichia coli

A new algorithm called RNAMotif containing RNA structure and sequence constraints and a thermodynamic scoring system was used to search for intrinsic rho-independent terminators in the Escherichia coli K-12 genome. We identified all 135 reported terminators and 940 putative terminator sequences beginning no more than 60 nt away from the 3'-end of the annotated transcription units (TU). Putative and reported terminators with the scores above our chosen threshold were found for 37 of the 53 non-coding RNA TU and for almost 50% of the 2592 annotated protein-encoding TU, which correlates well with the number of TU expected to contain rho-independent terminators. We also identified 439 terminators that could function in a bi-directional fashion, servicing one gene on the positive strand and a different gene on the negative strand. Approximately 700 additional termination signals in non-coding regions (NCR) far away from the nearest annotated gene were predicted. This number correlates well with the excess number of predicted 'orphan' promoters in the NCR, and these promoters and terminators may be associated with as yet unidentified TU. The significant number of high scoring hits that occurred within the reading frame of annotated genes suggests that either an additional component of rho-independent terminators exists or that a suppressive mechanism to prevent unwanted termination remains to be discovered.

Structure in nascent RNA leads to termination of slippage transcription by T7 RNA polymerase

T7 RNA polymerase presents a very simple model system for the study of fundamental aspects of transcription. Some time ago it was observed that in the presence of only GTP as a substrate, on a template encoding the initial sequence GGGA., T7 RNA polymerase will synthesize a 'ladder' of poly-G RNA products. At each step, the ratio of elongation to product release is consistently approximately 0.75 until the RNA reaches a length of approximately 13-14 nt, at which point this ratio drops precipitously. One model to explain this drop in complex stability suggests that the nascent RNA may be structurally hindered by the protein; the RNA may be exiting via a pathway not taken by normally synthesized RNA and therefore becomes sterically destabilized. The fact that the length of RNA at which this occurs is close to the length at which the transition to a stably elongating complex occurs might have led to other mechanistic proposals. Here we show instead that elongation falls off due to the cooperative formation of structure in the nascent RNA, most likely an intramolecular G-quartet structure. Replacement of GTP by 7-deaza-GTP completely abolishes this transition and G-ladder synthesis continues with a constant efficiency of elongation beyond the limit of detection. The polymerase-DNA complex creates no barrier to the growth of the nascent (slippage) RNA, rather termination is similar to that which occurs in rho-independent termination.

Balanced branching in transcription termination

The theory of stochastic transcription termination based on free-energy competition [von Hippel, P. H. & Yager, T. D. (1992) Science 255, 809-812 and von Hippel, P. H. & Yager, T. D. (1991) Proc. Natl. Acad. Sci. USA 88, 2307-2311] requires two or more reaction rates to be delicately balanced over a wide range of physical conditions. A large body of work on glasses and large molecules suggests that this balancing should be impossible in such a large system in the absence of a new organizing principle of matter. We review the experimental literature of termination and find no evidence for such a principle, but do find many troubling inconsistencies, most notably, anomalous memory effects. These effects suggest that termination has a deterministic component and may conceivably not be stochastic at all. We find that a key experiment by Wilson and von Hippel [Wilson, K. S. & von Hippel, P. H. (1994) J. Mol. Biol. 244, 36-51] thought to demonstrate stochastic termination was an incorrectly analyzed regulatory effect of Mg(2+) binding.

In vitro analysis of the terminator T(II) of the inhibitor antisense rna II gene from plasmid pMV158

One element involved in the copy number control of plasmid pMV158 is the antisense RNA II. We have determined the precise size of this RNA synthesized in vitro. Transcript termination occurs at two consecutive template positions within a typical rho-independent terminator, T(II). Using a series of plasmid derivatives in which the T(II) terminator has been partially or totally removed, we have analyzed the relationship between the predicted stability of the RNA hairpin encoded by T(II) and the efficiency of in vitro intrinsic termination. All the plasmids of the pMV158 family, constituted so far of 19 replicons, harbor putative antisense RNA-encoding genes which share in common the relative location with respect to the essential rep gene, the small size, and the presence of rho-independent transcription terminators.

Picomolar affinity antibodies from a fully synthetic naive library selected and evolved by ribosome display

Here we applied ribosome display to in vitro selection and evolution of single-chain antibody fragments (scFvs) from a large synthetic library (Human Combinatorial Antibody Library; HuCAL) against bovine insulin. In three independent ribosome display experiments different clusters of closely related scFvs were selected, all of which bound the antigen with high affinity and specificity. All selected scFvs had affinity-matured up to 40-fold compared to their HuCAL progenitors, by accumulating point mutations during the ribosome display cycles. The dissociation constants of the isolated scFvs were as low as 82 pM, which validates the design of the naïve library and the power of this evolutionary method. We have thus mimicked the process of antibody generation and affinity maturation with a synthetic library in a cell-free system in just a few days, obtaining molecules with higher affinities than most natural antibodies.

RNA polymerases from Bacillus subtilis and Escherichia coli differ in recognition of regulatory signals in vitro

Adaptation of bacterial cells to diverse habitats relies on the ability of RNA polymerase to respond to various regulatory signals. Some of these signals are conserved throughout evolution, whereas others are species specific. In this study we present a comprehensive comparative analysis of RNA polymerases from two distantly related bacterial species, Escherichia coli and Bacillus subtilis, using a panel of in vitro transcription assays. We found substantial species-specific differences in the ability of these enzymes to escape from the promoter and to recognize certain types of elongation signals. Both enzymes responded similarly to other pause and termination signals and to the general E. coli elongation factors NusA and GreA. We also demonstrate that, although promoter recognition depends largely on the sigma subunit, promoter discrimination exhibited in species-specific fashion by both RNA polymerases resides in the core enzyme. We hypothesize that differences in signal recognition are due to the changes in contacts made between the beta and beta' subunits and the downstream DNA duplex.

Sequence of the genome of the temperate, serotype-converting, Pseudomonas aeruginosa bacteriophage D3

Temperate bacteriophage D3, a member of the virus family Siphoviridae, is responsible for serotype conversion in its host, Pseudomonas aeruginosa. The complete sequence of the double-stranded DNA genome has been determined. The 56,426 bp contains 90 putative open reading frames (ORFs) and four genes specifying tRNAs. The latter are specific for methionine (AUG), glycine (GGA), asparagine (AAC), and threonine (ACA). The tRNAs may function in the translation of certain highly expressed proteins from this relatively AT-rich genome. D3 proteins which exhibited a high degree of sequence similarity to previously characterized phage proteins included the portal, major head, tail, and tail tape measure proteins, endolysin, integrase, helicase, and NinG. The layout of genes was reminiscent of lambdoid phages, with the exception of the placement of the endolysin gene, which parenthetically also lacked a cognate holin. The greatest sequence similarity was found in the morphogenesis genes to coliphages HK022 and HK97. Among the ORFs was discovered the gene encoding the fucosamine O-acetylase, which is in part responsible for the serotype conversion events.

Prediction of transcription terminators in bacterial genomes

This study describes an algorithm that finds rho-independent transcription terminators in bacterial genomes and evaluates the accuracy of its predictions. The algorithm identifies terminators by searching for a common mRNA motif: a hairpin structure followed by a short uracil-rich region. For each terminator, an energy-scoring function that reflects hairpin stability, and a tail-scoring function based on the number of U nucleotides and their proximity to the stem, are computed. A confidence value can be assigned to each terminator by analyzing candidate terminators found both within and between genes, and taking into account the energy and tail scores. The confidence is an empirical estimate of the probability that the sequence is a true terminator. The algorithm was used to conduct a comprehensive analysis of 12 bacterial genomes to identify likely candidates for rho-independent transcription terminators. Four of these genomes (Deinococcus radiodurans, Escherichia coli, Haemophilus influenzae and Vibrio cholerae) were found to have large numbers of rho-independent terminators. Among the other genomes, most appear to have no transcription terminators of this type, with the exception of Thermotoga maritima. A set of 131 experimentally determined E. coli terminators was used to evaluate the sensitivity of the method, which ranges from 89 % to 98 %, with corresponding false positive rates of 2 % and 18 %.

Bacteriophage SP6 RNA polymerase mutants with altered termination efficiency and elongation processivity

An Escherichia coli strain containing two plasmids was developed for in vivo isolation of the phage SP6 RNA polymerase mutants. It was developed to isolate mutants with increased proficiency of termination at the SP6 terminator and/or with reduced elongation processivity. Mutations were randomly introduced into an N-terminal third of the polymerase gene that was placed under a lac promoter in one plasmid. In the other plasmid, a promoter-lacking lacZ gene modified for reduced translation efficiency was placed downstream of a tandem pair of the SP6 terminator located downstream of an SP6 promoter-chloramphenicol acetyltransferase gene. Termination-up mutants were selected in vivo as they rendered LacZ activity level lower than the wild-type, without reducing chloramphenicol resistance substantially. Three such mutants (M15L, M15S, and D117G) were purified, and their termination efficiencies were measured in vitro at two different intrinsic termination signals in the E. coli rrnB terminator t1 that are different in requiring RNA hairpin formation. All three mutations enhanced termination efficiencies in vitro at the SP6 terminator and the upstream signal of rrnB t1, but reduced the efficiency at the downstream signal of it. All the mutations reduced elongation processivity, as the mutants produced much less amounts of large transcripts (2.1 kb) than the wild-type but the similar amounts of small transcripts (up to 670 nt). Thus, the mutations, all reducing elongation processivity of the polymerase, exhibited opposite effects on the two types of intrinsic termination signals, suggesting that the two mechanisms involve different interactions with the phage RNA polymerase.

Nonequilibrium mechanism of transcription termination from observations of single RNA polymerase molecules

Cessation of transcription at specific terminator DNA sequences is used by viruses, bacteria, and eukaryotes to regulate the expression of downstream genes, but the mechanisms of transcription termination are poorly characterized. To elucidate the kinetic mechanism of termination at the intrinsic terminators of enteric bacteria, we observed, by using single-molecule light microscopy techniques, the behavior of surface-immobilized Escherichia coli RNA polymerase (RNAP) molecules in vitro. An RNAP molecule remains at a canonical intrinsic terminator for approximately 64 s before releasing DNA, implying the formation of an elongation-incompetent (paused) intermediate by transcription complexes that terminate but not by those that read through the terminator. Analysis of pause lifetimes establishes a complete minimal mechanism of termination in which paused intermediate formation is both necessary and sufficient to induce release of RNAP at the terminator. The data suggest that intrinsic terminators function by a nonequilibrium process in which terminator effectiveness is determined by the relative rates of nucleotide addition and paused state entry by the transcription complex.

Mixed-function supraoperons that exhibit overall conservation, albeit shuffled gene organization, across wide intergenomic distances within eubacteria

Nearly identical mixed-function supraoperons (defined as nested transcriptional units encoding gene products that function in more than one biochemical pathway) have been found recently in Pseudomonas stutzeri and Pseudomonas aeruginosa. The Pseudomonas serC(pdxF)-aroQp.pheA-hisHb-tyrAc-aroF+ ++-cmk-rpsA supraoperon encodes 3-phosphoserine aminotransferase, a bidomain chorismate mutase/prephenate dehydratase, imidazole acetol-phosphate aminotransferase, cyclohexadienyl dehydrogenase, 5-enolpyruvylshikimate 3-phosphate synthase, cytidylate kinase, and 30S ribosomal protein S1. These enzymes participate in the biosynthesis of serine, pyridoxine, histidine, phenylalanine, tyrosine, tryptophan, and aromatic pathway vitamins and cytidylic acid, in addition to the general role of RpsA in the process of protein synthesis. Features that suggest supraoperon-wide translational coupling are the highly compressed intergenic spacing (including overlapping stop and start codons), as well as possible hairpin structures in mRNA, which could sequester many of the ribosome-binding sites. The hisH-tyrA-aroF segment corresponds to the distal genes of the classic Bacillus subtilis supraoperon. Extensive comparative analysis of the member genes of both the Bacillus and Pseudomonas supraoperons from organisms represented in the entire database revealed unmistakable organizational conservation of these genes across wide phylogenetic boundaries, although considerable gene shuffling was apparent. The persistence of aroE-aroB, hisHb-tyrA-aroF, and cmk-rpsA throughout both the gram-negative and gram-positive assemblages of bacteria, but the absence in Archaea, suggests an ancestral gene organization that occurred in bacteria after the separation of the bacterial and archaeal domains. In gram-negative bacteria,the hisHb-tyrAc-aroF grouping may have been expanded (as with the Pseudomonas supraoperon) and then subsequently collapsed (as with the Escherichia serC-aroF supraoperon) via gene shuffling that is herein equated with gene fusion events.

Repression of IS200 transposase synthesis by RNA secondary structures

The IS 200 transposase, a 16 kDa polypeptide encoded by the single open reading frame (ORF) of the insertion element, has been identified using an expression system based on T7 RNA polymerase. In wild-type IS 200, two sets of internal inverted repeats that generate RNA secondary structures provide two independent mechanisms for repression of transposase synthesis. The inverted repeat located near the left end of IS 200 is a transcriptional terminator that terminates read-through transcripts before they reach the IS 200 ORF. The terminator is functional in both directions and may terminate >80% of transcripts. Another control operates at the translational level: transposase synthesis is inhibited by occlusion of the ribosome-binding site (RBS) of the IS 200 ORF. The RBS (5'-AGGGG-3') is occluded by formation of a mRNA stem-loop structure whose 3' end is located only 3 nt upstream of the start codon. This mechanism reduces transposase synthesis approximately 10-fold. Primer extension experiments with AMV reverse transcriptase have provided evidence that this stem-loop RNA structure is actually formed. Tight repression of transposase synthesis, achieved through synergistic mechanisms of negative control, may explain the unusually low transposition frequency of IS 200.

Nus A is involved in transcriptional termination on lambda tI

The transcriptional terminator tI generates the 3'end of the integrase (int) gene transcript that is read from the lambda PI promoter in lambda phage. We have studied the factors that affect transcription termination in vitro and in vivo at the lambda tI terminator. In vitro transcriptional studies showed that tI is about 80% efficient in the presence of purified NusA protein, whereas it is only about 50% efficient in its absence. In vivo studies, where the readthrough transcript of lambda tI was measured by quantitative dot blot analysis, gave about 80% efficiency in wild-type strains, but only 60% in the nusA1 mutant strain at non-permissive temperatures. These results support the idea that termination at lambda tI in vivo involves interaction with the NusA factor.

Activation of Rho-dependent transcription termination by NusG. Dependence on terminator location and acceleration of RNA release

There is a kinetic limitation to Rho function at the first intragenic terminator in the lacZ gene (tiZ1) which can be overcome by NusG: Rho can terminate transcription with slowly moving, but not rapidly moving, RNA polymerase unless NusG is also present. Here we report further studies with two other Rho-dependent terminators that are not kinetically limited (tiZ2 and lambda tR1) which show that the requirement for NusG depends on the properties of the terminator and its location in the transcription unit. NusG is also shown to increase the rate of Rho-mediated dissociation of transcription complexes arrested at a specific termination stop point in the tiZ1 region and the rates of dissociation with three different Rho factors and two different terminators correlated with their sensitivity to RNA polymerase elongation kinetics. These results suggest a model of NusG function which involves an alteration in the susceptibility of the transcription complex to Rho action which allows termination to occur within the short kinetic window when RNA polymerase is traversing the termination region.

Regulation of intrinsic terminator by translation in Escherichia coli: transcription termination at a distance downstream

BACKGROUND

Rho-independent terminators in Escherichia coli are DNA sequences of 30-50 bp consisting of a GC-rich dyad symmetry sequence followed by a run of T residues in the nontemplate strand. The transcription termination at the Rho-independent terminator occurs within the T-tract in vitro. It has been believed that the transcription termination at the Rho-independent terminator occurs within the T-tract in vivo, as established in vitro, and therefore the 3' ends of mRNAs are mostly generated as a direct result of transcription termination. However, how the transcription termination occurs and how the 3' ends of mRNAs are formed in living cells remains to be studied.

RESULTS

We developed a double terminator system in which a second Rho-independent terminator was placed downstream of the crp terminator. This system made it possible to detect transcripts that pass through the crp terminator by Northern blotting. We found that most of the crp transcripts extend beyond the crp terminator. The transcriptional read-through at the crp terminator was reduced when the translation of crp mRNA was interrupted. The level of the read-through transcript decreased with distance between the two terminators, suggesting that transcription termination occurs at multiple positions beyond the crp terminator.

CONCLUSION

We conclude that most RNA polymerase reads through the crp terminator in the natural situation and terminates transcription over a wide region downstream of the crp terminator, resulting in heterogeneous primary transcripts that are subsequently processed back to the terminator hairpin. We propose that ribosome translation to the crp stop codon causes read-through of the terminator. The regulatory effect of translation on Rho-independent termination may be a general phenomenon at other operons.

Allele-specific suppression of ColE1 high-copy-number mutants by a rpoB mutation of Escherichia coli

We have isolated spontaneous rifampicin-resistant mutants from Escherichia coli that showed allele-specific suppression of the copy-number phenotype of ColE1 high-copy-number mutants in vivo. The key step in the regulatory circuitry of the initiation of ColE1 DNA replication is the formation of the persistent hybrid between the primer RNA and the DNA template around the replication origin. Three host-encoded enzymes, RNase H, DNA polymerase I, and RNA polymerase, are essential to the replication initiation in vitro. To decide whether the activity of RNA polymerase is involved directly in the formation of the persistent hybrid, we screened rifampicin-resistant colonies for suppressors of ColE1 copy-number mutants. Suppressor strain YY572 (rpoB572) changes the 572 residue of the beta subunit of RNA polymerase, encoded by the rpoB gene, from isoleucine to leucine. Another suppressor, YY513 (rpoB513), changes the 513 residue from glutamine to lysine. The other known rifampicin-resistant alleles located at residue 513, rpoB8 and rpoB101, did not show a significant suppression of the copy number of those ColE1 copy-number mutants as rpoB513. The suppression by rpoB513 on different ColE1 copy-number mutants showed allelic specificity. The possible roles of RNA polymerase in control of ColE1 copy number are discussed.

Analysis of complete genomes suggests that many prokaryotes do not rely on hairpin formation in transcription termination

Free energy values of mRNA tertiary structures around stop codons were systematically calculated to surmise the hairpin-forming potential for all genes in each of the 16 complete prokaryote genomes. Instead of trying to detect each individual hairpin, we averaged the free energy values around the stop codons over the entire genome to predict how extensively the organism relies on hairpin formation in the process of transcription termination. The free energy values of Escherichia coli K-12 shows a sharp drop, as expected, at 30 bp downstream of the stop codon, presumably due to hairpin-forming sequences. Similar drops are observed for Haemophilus influenzae Rd, Bacillus subtilis and Chlamydia trachomatis, suggesting that these organisms also form hairpins at their transcription termination sites. On the other hand, 12 other prokaryotes- Mycoplasma genitalium, Mycoplasma pneumoniae, Synechocystis PCC6803, Helicobacter pylori, Borrelia burgdorferi, Methanococcus jannaschii, Archaeoglobus fulgidus, Methanobacterium thermoautotrophicum, Aquifex aeolicus, Pyrococcus horikoshii, Mycobacterium tuberculosis and Treponema pallidum -show no apparent decrease in free energy value at the corresponding regions. This result suggests that these prokaryotes, or at least some of them, may never form hairpins at their transcription termination sites.

Interaction of a nascent RNA structure with RNA polymerase is required for hairpin-dependent transcriptional pausing but not for transcript release

Nascent RNA structures may regulate RNA chain elongation either directly through interaction with RNA polymerase or indirectly by disrupting nascent RNA contacts with polymerase or DNA. To distinguish these mechanisms we tested whether the effects of the his leader pause RNA hairpin could be mimicked by pairing of antisense DNA or RNA oligonucleotides to the nascent transcript. The his pause hairpin inhibits nucleotide addition when it forms 11 nucleotides from the transcript 3' end. It also can terminate transcription when base changes extend its stem to Collapse

Key Words

• rna polymerase
• rna hairpins
• pausing
• termination

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MESH Headings

• DNA-Directed RNA Polymerases/metabolism
• Escherichia coli
• Models, Genetic
• Molecular Mimicry
• Nucleic Acid Conformation
• Oligonucleotides, Antisense/metabolism
• RNA/metabolism
• RNA, Bacterial/metabolism
• Structure-Activity Relationship
• Transcription, Genetic

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Grants

• R01 GM038660 NIGMS NIH HHS
• R37 GM038660 NIGMS NIH HHS
• GM38660 NIGMS NIH HHS

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Affiliation(s)

I Artsimovitch Department of Bacteriology, University of Wisconsin, Madison, Wisconsin 53706, USA
R Landick

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Reversible stalling of transcription elongation complexes by high pressure

We have investigated the effect of high hydrostatic pressure on the stability of RNA polymerase molecules during transcription. RNA polymerase molecules participating in stalled or active ternary transcribing complexes do not dissociate from the template DNA and nascent RNA at pressures up to 180 MPa. A lower limit for the free energy of stabilization of an elongating ternary complex relative to the quaternary structure of the free RNAP molecules is estimated to be 20 kcal/mol. The rate of elongation decreases at high pressure; transcription completely halts at sufficiently high pressure. The overall rate of elongation has an apparent activation volume (DeltaVdouble dagger) of 55-65 ml . mol-1 (at 35 degrees C). The pressure-stalled transcripts are stable and resume elongation at the prepressure rate upon decompression. The efficiency of termination decreases at the rho-independent terminator tR2 after the transcription reaction has been exposed to high pressure. This suggests that high pressure modifies the ternary complex such that termination is affected in a manner different from that of elongation. The solvent and temperature dependence of the pressure-induced inhibition show evidence for major conformational changes in the core polymerase enzyme during RNA synthesis. It is proposed that the inhibition of the elongation phase of the transcription reaction at elevated pressures is related to a reduction of the partial specific volume of the RNA polymerase molecule; under high pressure, the RNA polymerase molecule does not have the necessary structural flexibility required for the protein to translocate.

Sirohaem sulfite reductase and other proteins encoded by genes at the dsr locus of Chromatium vinosum are involved in the oxidation of intracellular sulfur

The sequence of the dsr gene region of the phototrophic sulfur bacterium Chromatium vinosum D (DSMZ 180) was determined to clarify the in vivo role of 'reverse' sirohaem sulfite reductase. The dsrAB genes encoding dissimilatory sulfite reductase are part of a gene cluster, dsrABEFHCMK, that encodes four small, soluble proteins (DsrE, DsrF, DsrH and DsrC), a transmembrane protein (DsrM) with similarity to haem-b-binding polypeptides and a soluble protein (DsrK) resembling [4Fe-4S]-cluster-containing heterodisulfide reductase from methanogenic archaea. Northern hybridizations showed that expression of the dsr genes is increased by the presence of reduced sulfur compounds. The dsr genes are not only transcribed from a putative promoter upstream of dsrA but primary transcripts originating from (a) transcription start site(s) downstream of dsrB are also formed. Polar insertion mutations immediately upstream of dsrA, and in dsrB, dsrH and dsrM, led to an inability of the cells to oxidize intracellularly stored sulfur. The capability of the mutants to oxidize sulfide, thiosulfate and sulfite under photolithoautotrophic conditions was unaltered. Photoorganoheterotrophic growth was also unaffected. 'Reverse' sulfite reductase and DsrEFHCMK are, therefore, not essential for oxidation of sulfide or thiosulfate, but are obligatory for sulfur oxidation. These results, together with the finding that the sulfur globules of C. vinosum are located in the extracytoplasmic space whilst the dsr gene products appear to be either cytoplasmic or membrane-bound led to the proposal of new models for the pathway of sulfur oxidation in this phototrophic sulfur bacterium.

A newly identified regulator is required for virulence and toxin production in Pseudomonas syringae

The genes lemA (which we here redesignate gacS) and gacA encode members of a widely conserved two-component regulatory system. In Pseudomonas syringae strain B728a, gacS and gacA are required for lesion formation on bean, as well as for the production of protease and the toxin syringomycin. A gene, designated salA, was discovered that restored syringomycin production to a gacS mutant when present on a multiple-copy plasmid. Disruption of chromosomal salA resulted in loss of syringomycin production and lesion formation in laboratory assays. Sequence analysis of salA suggests that it encodes a protein with a DNA-binding motif but without other significant similarity to proteins in current databases. Chromosomal reporter fusions revealed that gacS and gacA positively regulate salA, that salA upregulates its own expression and that salA positively regulates the expression of a syringomycin biosynthetic gene, syrB. Loss of syringomycin production does not account for the salA mutant's attenuated pathogenicity, as a syrB mutant was found to retain full virulence. The salA gene did not similarly suppress the protease deficient phenotype of gacS mutants, nor were salA mutants affected for protease production. A gacS/gacA-dependent homoserine lactone activity as detected by bioassay was also unaffected by the disruption of salA. Thus, salA appears to encode a novel regulator that activates the expression of at least two separate genetic subsets of the gacS/gacA regulon, one pathway leading to syringomycin production and the other resulting in plant disease.

Characterization of the cvaA and cvi promoters of the colicin V export system: iron-dependent transcription of cvaA is modulated by downstream sequences

Secretion of the Escherichia coli toxin colicin V was previously determined to be iron regulated via the Fur (ferric uptake regulator) protein, based on studies in fur mutants. The iron dependence of transcription and expression of cvaA, which encodes a transporter accessory protein, and cvi, encoding the colicin V immunity protein, was assessed under conditions of iron excess or depletion. Immunoblots showed that production of both Cvi and CvaA is iron dependent. The iron-dependent transcriptional start for cvaA identified by primer extension and S1 nuclease analysis, P1, lies 320 bp upstream of the translational start and is associated with a newly identified Fur binding site. Beta-galactosidase activity in transcriptional lacZ fusions with the P1 promoter alone is higher than with downstream sequences present and is induced 10-fold by iron depletion. Including immediate downstream regions with P1 enhances activity from P1 even more but reduces the induction by iron depletion fivefold. Including subsequent downstream sequences, however, down-modulates overall transcription from P1 almost fourfold. Deletion of a long stem-loop structure in this region alleviates the down-modulation by increasing transcription, indicating that the sequences or structure of this element may contribute to this down-regulation. Characterization of the cvi promoter by primer extension showed that it resides where predicted, about 50 bp upstream of cvi associated with a previously identified Fur binding site. The cvi promoter is also inducible by iron depletion. The modulating sequences from cvaA were placed downstream of the cvi promoter to test their effects in transcriptional fusions of the cvi promoter to lacZ. The fusion results showed that these sequences also modulate transcription of the cvi promoter in a manner similar to that of the cvaA promoter. The potential for up- and down-regulation within the long untranslated region downstream of the cvaA promoter suggests a novel mechanism that fine-tunes expression of the colicin V secretion genes.

Position-specific inhibition of yeast mitochondrial transcription by a poly(T) sequence

The 3' flanking nucleotide(s) of the octanucleotide promoter sequence regulates transcriptional efficiency of some mitochondrial genes in Saccharomyces cerevisiae. To understand this regulation the in vitro transcriptional activity of various synthetic mitochondrial promoters carrying different 3' flanking sequences was examined. The results presented here demonstrate that consecutive thymidine residues, but no other polynucleotides or secondary structure, in the promoter-proximal non-transcribed DNA strand inhibited mitochondrial transcription. The location and the number of T residues in the cluster as well as the concentration of UTP in the transcription reaction are the important factors determining this transcriptional inhibition. For example, a pair of thymidine nucleotides at positions +2 and +3 is sufficient for inactivation of mitochondrial transcription, whereas more than three consecutive thymidine nucleotides beyond these positions are required for inhibition of mitochondrial transcription. However, a cluster of six to 12 thymidine residues beyond position +11, a point where mtRNA polymerase has been shown to form a stable transcription complex, did not interfere with mitochondrial transcription. Interestingly, at low UTP concentration the mtRNA polymerase generates a large quantity of aborted initiation products on a template carrying promoter-proximal poly(T) sequence probably due to the inability of the polymerase to clear this promoter. On the other hand at high UTP concentration the same mtRNA polymerase on the same mitochondrial promoter produces a higher level of productive initiation complex. These observations suggest that the mechanism of poly(T) inhibition of mitochondrial transcription is a UTP-limited transcriptional attenuation at the promoter site, which might occur under specific physiological conditions (i.e. glucose repression-derepression, switching of aerobic-anaerobic conditions).

Escherichia coli RNA polymerase terminates transcription efficiently at rho-independent terminators on single-stranded DNA templates

Several models have been proposed for the mechanism of transcript termination by Escherichia coli RNA polymerase at rho-independent terminators. Yager and von Hippel (Yager, T. D. & von Hippel, P. H. (1991) Biochemistry 30, 1097-118) postulated that the transcription complex is stabilized by enzyme-nucleic acid interactions and the favorable free energy of a 12-bp RNA-DNA hybrid but is destabilized by the free energy required to maintain an extended transcription bubble. Termination, by their model, is viewed simply as displacement of the RNA transcript from the hybrid helix by reformation of the DNA helix. We have proposed an alternative model where the RNA transcript is stably bound to RNA polymerase primarily through interactions with two single-strand specific RNA-binding sites; termination is triggered by formation of an RNA hairpin that reduces binding of the RNA to one RNA-binding site and, ultimately, leads to its ejection from the complex. To distinguish between these models, we have tested whether E. coli RNA polymerase can terminate transcription at rho-independent terminators on single-stranded DNA. RNA polymerase cannot form a transcription bubble on these templates; thus, the Yager-von Hippel model predicts that intrinsic termination will not occur. We find that transcript elongation on single-stranded DNA templates is hindered somewhat by DNA secondary structure. However, E. coli RNA polymerase efficiently terminates and releases transcripts at several rho-independent terminators on such templates at the same positions as termination occurs on duplex DNAs. Therefore, neither the nontranscribed DNA strand nor the transcription bubble is essential for rho-independent termination by E. coli RNA polymerase.

Regulation of the elongation-termination decision at intrinsic terminators by antitermination protein N of phage lambda

The mechanisms that control N-protein-dependent antitermination in the phage lambda life cycle have counterparts in the regulatory systems of other organisms. Here we examine N-dependent antitermination at the intrinsic tR' terminator of lambda to elucidate the regulatory principles involved. The tR' terminator consists of a sequence of six base-pairs along the template at which the transcription complex is sufficiently destabilized to make RNA release possible. Within this "zone of opportunity" for termination the termination efficiency (TE) at each template position is determined by a kinetic competition between alternative reaction pathways that lead either to elongation or to termination. TE values at each position within tR' have been mapped as a function of NTP concentration, and it is shown that N protein (in the presence of NusA and a nut site; the minimal system for N-dependent antitermination) can offset increases in TE that are induced by limiting the concentrations of each of the next required NTPs. By limiting NTP concentrations or working at low temperature we show that a significant effect of N within the minimal system is to increase the rate of transcript elongation three- to fivefold at most positions along the template. Assuming that a comparable increase in elongation rate applies at template positions within the terminator, we show that an increase of this magnitude is not sufficient to account for the antitermination efficiency observed and that an approximately 100-fold stabilization of the transcription complex at intrinsic termination sites as a consequence of binding the N-containing antitermination sub-assembly must be invoked as well. A general method for partitioning TE effects in antitermination between changes in elongation rate and termination complex stability is demonstrated, based on competing free energy of activation barriers for the elongation and termination reactions. The analysis and utility of such mixed modes of transcriptional regulation are considered in general terms.

katGI and katGII encode two different catalases-peroxidases in Mycobacterium fortuitum

It has been suggested that catalase-peroxidase plays an important role in several aspects of mycobacterial metabolism and is a virulence factor in the main pathogenic mycobacteria. In this investigation, we studied genes encoding for this protein in the fast-growing opportunistic pathogen Mycobacterium fortuitum. Nucleotide sequences of two different catalase-peroxidase genes (katGI and katGII) of M. fortuitum are described. They show only 64% homology at the nucleotide level and 55% identity at the amino acid level, and they are more similar to catalases-peroxidases from different bacteria, including mycobacteria, than to each other. Both proteins were found to be expressed in actively growing M. fortuitum, and both could also be expressed when transformed into Escherichia coli and M. aurum. We detected the presence of a copy of IS6100 in the neighboring region of a katG gene in the M. fortuitum strain in which this element was identified (strain FC1). The influence of each katG gene on isoniazid (isonicotinic acid hydrazide; INH) susceptibility of mycobacteria was checked by using the INH-sensitive M. aurum as the host. Resistance to INH was induced when katGI was transformed into INH-sensitive M. aurum, suggesting that this enzyme contributes to the natural resistance of M. fortuitum to the drug. This is the first report showing two different genes encoding same enzyme activity which are actively expressed within the same mycobacterial strain.

Preferential interaction of the his pause RNA hairpin with RNA polymerase beta subunit residues 904-950 correlates with strong transcriptional pausing

RNA secondary structures (hairpins) that form as the nascent RNA emerges from RNA polymerase are important components of many signals that regulate transcription, including some pause sites, all rho-independent terminators, and some antiterminators. At the his leader pause site, a 5-bp-stem, 8-nt-loop pause RNA hairpin forms 11 nt from the RNA 3' end and stabilizes a transcription complex conformation slow to react with NTP substrate. This stabilization appears to depend at least in part on an interaction with RNA polymerase. We tested for RNA hairpin interaction with the paused polymerase by crosslinking 5-iodoUMP positioned specifically in the hairpin loop. In the paused conformation, strong and unusual crosslinking of the pause hairpin to beta904-950 replaced crosslinking to beta' and to other parts of beta that occurred in nonpaused complexes prior to hairpin formation. These changes in nascent RNA interactions may inhibit reactive alignment of the RNA 3' end in the paused complex and be related to events at rho-independent terminators.

In vitro selection and evolution of functional proteins by using ribosome display

We report here a system with which a correctly folded complete protein and its encoding mRNA both remain attached to the ribosome and can be enriched for the ligand-binding properties of the native protein. We have selected a single-chain fragment (scFv) of an antibody 10(8)-fold by five cycles of transcription, translation, antigen-affinity selection, and PCR. The selected scFv fragments all mutated in vitro by acquiring up to four unrelated amino acid exchanges over the five generations, but they remained fully compatible with antigen binding. Libraries of native folded proteins can now be screened and made to evolve in a cell-free system without any transformation or constraints imposed by the host cell.

Cloning and sequencing of the gene encoding the high potential iron-sulfur protein (HiPIP) from the purple sulfur bacterium Chromatium vinosum

The gene encoding the high potential iron-sulfur protein (HiPIP) of Chromatium vinosum strain D (DSM 180T) was cloned from an EcoRI-HindIII digest of genomic DNA. A nucleotide sequence of 648 bp length was determined which contained the coding region and putative promoter and termination sites. The gene codes for a 122 residue 12761 Da protein. The C-terminal 85 residues are those of the previously biochemically determined sequence, whereas the N-terminal 37 residues constitute a leader peptide which shows characteristics of the double arginine signal sequences of complex cofactor containing periplasmic proteins.

Multiple interactions stabilize a single paused transcription intermediate in which hairpin to 3' end spacing distinguishes pause and termination pathways

Transcription is delayed in the leader regions of the Escherichia coli trp and his operons by multipartite pause signals that consist of four components: a nascent RNA structure (the pause hairpin), the 10 or 11 nt 3'-proximal region between the pause hairpin and the RNA 3' end, the bases in the active site, and approximately 14 bp of duplex DNA downstream from the pause site. Results described in the accompanying paper suggest that the his pause hairpin slows nucleotide addition via interaction with an easily disordered surface on RNA polymerase. Here we report that the four pause signal components slow nucleotide addition in a single kinetic intermediate. Formation of the paused transcription complex, in contrast, involves synergistic effects of RNA and DNA sequences that select the wild-type pause site from among several adjacent possibilities. Extending the pause hairpin with one G x C base-pair reduces pausing, apparently by interfering with pause hairpin interaction; adding a second C x G base-pair that reduces the 3'-proximal RNA to 9 nt or less (within the 7 to 9 nt characteristic of rho-independent terminators) induces transcript release. We propose that escape from the pause is governed by a rate-limiting isomerization that may require substrate NTP binding to re-establish the active site geometry, whereas transcript release and termination ensue when the hairpin interaction is weakened and isomerization to an active conformation is blocked.

Effects of neutral salts on RNA chain elongation and pausing by Escherichia coli RNA polymerase

We examined the effects of neutral salts and the non-ionic solute 2-methyl,-2,4-pentanediol (MPD) on transcript elongation by Escherichia coli RNA polymerase and on pausing induced by the multipartite his leader pause signal. All solutes tested slowed the overall rate of elongation, with anions showing the dominant effects in the order: (most inhibitory) HPO4(2-) > OAc- > SO4(2-) > ClO4- > I- approximately NO3- > Br approximately Cl- approximately MPD (least inhibitory). Although the protein structure-stabilizing anions HPO4(2-), OAc-, and SO4(2-) also increased the pause half-life at the his leader pause site, the remaining solutes accelerated escape from pause site in the order: (greatest acceleration) NO3- > ClO4- > I- > Br- > Cl- > MPD (least acceleration). Cl(-)-induced acceleration of escape from the pause site also occurred on mutant templates altered for the 3'-proximal region, RNA 3' end, or downstream DNA. The effect was eliminated, however, by base substitutions that destabilize the pause RNA hairpin or that extend it toward the 3' end. This "perfect hairpin" itself reduced the pause half-life by a factor of 3. We suggest that the pause RNA hairpin stabilizes a paused conformation of the transcription complex through an interaction with an easily disordered region of RNA polymerase. Extending the stem of the pause hairpin may disrupt the interaction by altering the position of the hairpin in the transcription complex. Anions may either compete for the interaction directly or disorder the site of hairpin interaction by chaotropic effects. We suggest that the negative effect of structure-stabilizing anions like OAc- and SO4(2-) may reflect passage of RNA polymerase through significantly different conformations during rapid elongation, some of which may expose hydrophobic surface.

Basic mechanisms of transcript elongation and its regulation

Ternary complexes of DNA-dependent RNA polymerase with its DNA template and nascent transcript are central intermediates in transcription. In recent years, several unusual biochemical reactions have been discovered that affect the progression of RNA polymerase in ternary complexes through various transcription units. These reactions can be signaled intrinsically, by nucleic acid sequences and the RNA polymerase, or extrinsically, by protein or other regulatory factors. These factors can affect any of these processes, including promoter proximal and promoter distal pausing in both prokaryotes and eukaryotes, and therefore play a central role in regulation of gene expression. In eukaryotic systems, at least two of these factors appear to be related to cellular transformation and human cancers. New models for the structure of ternary complexes, and for the mechanism by which they move along DNA, provide plausible explanations for novel biochemical reactions that have been observed. These models predict that RNA polymerase moves along DNA without the constant possibility of dissociation and consequent termination. A further prediction of these models is that the polymerase can move in a discontinuous or inchworm-like manner. Many direct predictions of these models have been confirmed. However, one feature of RNA chain elongation not predicted by the model is that the DNA sequence can determine whether the enzyme moves discontinuously or monotonically. In at least two cases, the encounter between the RNA polymerase and a DNA block to elongation appears to specifically induce a discontinuous mode of synthesis. These findings provide important new insights into the RNA chain elongation process and offer the prospect of understanding many significant biological regulatory systems at the molecular level.