Intrinsic Transcription Terminator Research Articles

Single Molecule Studies Reveal the Mechanism and Energetics of Transcriptional Termination

Intrinsic transcription termination by bacterial RNA polymerase (RNAP) occurs at sequences coding for a G:C‐rich RNA hairpin followed by a 7–9 nt, U‐rich tract. We used single‐molecule optical trapping techniques to investigate the mechanism by which elements from three representative terminators (his, t500, tR2) destabilize the elongation complex (EC). For his and tR2 terminators, loads exerted to bias DNA translocation did not affect termination efficiency (TE). However, the force‐dependent kinetics of release at the t500 terminator and the force‐dependent TE of a mutant imply a forward translocation mechanism for this terminator. Tension applied to isolated U‐tracts induced transcript release in a manner consistent with shearing of the RNA:DNA hybrid. We deduce that different mechanisms of EC dissociation, involving hypertranslocation or RNA:DNA shearing, operate at terminators with different U‐tract sequences. Tension applied to RNA at full terminators suggests that closure of the final 2–3 hairpin bases supplies the energy that destabilizes the hybrid, and that competing nascent RNA structures modulate TE by slowing terminator hairpin formation. We propose a quantitative model based on energetics that successfully predicts the behavior for all three terminators and several mutant variants.

Cloning and structural analysis of the full-length cytolethal distending toxin (cdt) gene operon from Campylobacter lari

Polymerase chain reaction (PCR) amplicons (approximately 2.5 kbp) encoding a cdt gene operon and two partial and putative open reading frames (ORFs) were identified in six urease-negative (UN) Campylobacter lari isolates using a new PCR primer pair constructed in silico. Three closely spaced and putative ORFs for cdtA, cdtB and cdtC, two putative promoters and a hypothetically intrinsic ρ-independent transcription terminator were found in the operon. Each ORF commenced with an ATG start codon and terminated with a TGA stop codon for cdtA and cdtB and a TAA for cdtC. Interestingly, an overlap of four nucleotides was detected between cdtA and cdtB and the non-coding region of six base pairs occurring between cdtB and cdtC. The start codons for the three cdt genes were preceded by Shine-Dalgarno sequences. Although nucleotide sequence differences were identified at seven loci in the cdtA gene, six in cdtB and two in cdtC among the seven isolates (including C. lari RM2100), no polymorphic sites occurred in the putative promoters, hypothetically intrinsic transcription terminator and the three ribosome binding sites among the seven isolates. All nine amino acid residues specific for both Escherichia coli cdtB and mammalian DNase I were completely conserved in the cdtB gene locus in the 26 C. lari isolates, as well as in C. jejuni and C. coli. No PCR amplicons were generated with urease-positive thermophilic campylobacters (UPTC; n=10) using the primer pair.

Genetic organization of pha gene locus affects phaC expression, poly(hydroxyalkanoate) composition and granule morphology in Pseudomonas corrugata

The complete sequence of the pha locus responsible for the biosynthesis of poly(hydroxyalkanoates) (PHAs) in Pseudomonas corrugata 388 was determined. As with the other known pseudomonad pha gene loci, the one in P. corrugata 388 also consists of phaC1 (1,680 bps; PHA synthase 1), phaZ (858 bp; PHA depolymerase) and phaC2 (1,683 bp; PHA synthase 2) genes. A BLAST search showed that the nucleotide sequences of these genes and the amino-acid sequences of their respective gene products are homologous to those of P. corrugata CFBP5454 and P. mediterranea CFBP5447. A putative intrinsic transcription terminator consisting of a dyad symmetry (24 bp; Delta G = -41.8 kcals) that precedes a stretch of dA residues was located in the phaC1-phaZ intergenic region. P. corrugata mutant-clones XI 32-1 and XI 32-4 were constructed in which this intergenic region was replaced with a selectable kanamycin-resistance gene. These mutant clones when grown on oleic acid for 48 h showed 4.7-to 7.0-fold increases of phaC1 and phaC2 relative expression in comparison to the initial inoculants, whereas the parental strain showed only 1.2- to 1.4-fold increases. Furthermore, in comparison to parental P. corrugata with only a few large PHA inclusion bodies, the mutants grown on oleic acid produce numerous smaller PHA granules that line the periphery of the cells. With glucose as a substrate, XI 32-1 and XI 32-4 clones produce mcl-PHA with a high content (26-31 mol%) of the mono-unsaturated 3-hydroxydodecenoate as a repeat-unit monomer. Our results show for the first time the effects of the phaC1-phaZ intergenic region on the substrate-dependent temporal expression of phaC1 and phaC2 genes, the repeat-unit composition of mcl-PHA, and the morphology of the PHA granules.

Systematic mutagenesis of the thymidine tract of the pyrBI attenuator and its effects on intrinsic transcription termination in Escherichia coli

The pyrBI attenuator of Escherichia coli is an intrinsic transcription terminator composed of DNA with a hyphenated dyad symmetry and an adjacent 8 bp T:A tract (T-tract). These elements specify a G+C-rich terminator hairpin followed by a run of eight uridine residues (U-tract) in the RNA transcript. In this study, we examined the effects on in vivo transcription termination of systematic base substitutions in the T/U-tract of the pyrBI attenuator. We found that these substitutions diminished transcription termination efficiency to varying extents, depending on the nature and position of the substitution. In general, substitutions closer to the dyad symmetry/terminator hairpin exhibited the most significant effects. Additionally, we examined the effects on in vivo transcription termination of mutations that insert from 1 to 4 bases between the terminator hairpin and U-tract specified by the pyrBI attenuator. Our results show an inverse relationship between termination efficiency and the number of bases inserted. The effects of the substitution and insertion mutations on termination efficiency at the pyrBI attenuator were also measured in vitro, which corroborated the in vivo results. Our results are discussed in terms of the current models for intrinsic transcription termination and estimating termination efficiencies at intrinsic terminators of other bacteria.

Dissociation of halted T7 RNA polymerase elongation complexes proceeds via a forward-translocation mechanism

A recent model for the mechanism of intrinsic transcription termination involves dissociation of the RNA from forward-translocated (hypertranslocated) states of the complex [Yarnell WS, Roberts JW (1999) Science, 284:611-615]. The current study demonstrates that halted elongation complexes of T7 RNA polymerase in the absence of termination signals can also dissociate via a forward-translocation mechanism. Shortening of the downstream DNA or the introduction of a stretch of mismatched DNA immediately downstream of the halt site reduces a barrier to forward translocation and correspondingly reduces the lifetime of halted complexes. Conversely, introduction of a cross-link downstream of the halt site increases the same barrier and leads to an increase in complex lifetime. Introduction of a mismatch within the bubble reduces a driving force for forward translocation and correspondingly increases the lifetime of the complex, but only for mismatches at the upstream edge of the bubble, as predicted by the model. Mismatching only the two most upstream of the eight bases in the bubble provides a maximal increase in complex stability, suggesting that dissociation occurs primarily from early forward-translocated states. Finally, addition in trans of an oligonucleotide complementary to the nascent RNA just beyond the hybrid complements the loss of driving force derived from placement of a mismatch within the bubble, confirming the expected additivity of effects. Thus, forward translocation is likely a general mechanism for dissociation of elongation complexes, both in the presence and absence of intrinsic termination signals.

Molecular characterization of the full-length 23S and 5S ribosomal RNA (rRNA) genes of Taylorella asinigenitalis

An approximately 4.2 kbp region encoding 23S and 5S rRNA genes was identified when recombinant plasmid DNAs from two genomic DNA libraries and an inverse PCR product of Taylorella asinigenitalis UK-1 isolate were analyzed. Full-length genes of 23S rRNA (3,225 bp) and 5S rRNA (117 bp) of T. asinigenitalis are described. The present sequence analysis identified a non-coding hypothetically intrinsic transcription terminator region downstream of the 5S rRNA gene. The sequence, however, downstream of the 5S rRNA gene did not show any distal tRNA genes. Surprisingly, an intervening sequence (IVS) of 270 bp in length, including two specific tandem repeat units of 80 bp and one partial unit of 48 bp with unknown functions was identified in the first quarter of the 23S rRNA gene sequence. A second IVS of 70 bp in length was also identified in the central region of the 23S rRNA gene. In addition, by using PCR and sequencing procedures, two T. asinigenitalis isolates, UK-1 and UK-2, carried multiple IVSs in the first quarter and central regions. Moreover, the 23S rRNA fragmentation occurred in the UK-1 isolate. A phylogenetic analysis was first carried out based on the 23S rRNA sequence data from T. asinigenitalis UK-1 and 13 other beta-Proteobacteria. This is the first report of IVSs in the 23S rRNA gene from the beta-Proteobacteria.

From Ribosome to Riboswitch: Control of Gene Expression in Bacteria by RNA Structural Rearrangements

ABSTRACTStructural elements in the 5′ region of a bacterial mRNA can have major effects on expression of downstream coding sequences. Folding of the nascent RNA into the helix of an intrinsic transcriptional terminator results in premature termination of transcription and in failure to synthesize the full-length transcript. Structure in the translation initiation region of an mRNA blocks access of the translation initiation complex to the ribosome binding site, thereby preventing protein synthesis. RNA structures can also affect the stability of an RNA by altering sensitivity to ribonucleases. A wide variety of mechanisms have been uncovered in which changes in mRNA structure in response to a regulatory signal are used to modulate gene expression in bacteria. These systems allow the cell to recognize an impressive array of signals, and to monitor those signals in many different ways.

A conserved inverted repeat from rice plastome functions as an intrinsic transcription terminator

Results from a previous rice transcription mapping and the GeSTer algorithm analysis used in this in-vestigation for rice plastid genome suggest that an inverted repeat, IRsl8, in 3′ region of the plastid rps18 gene may serve as a transcription terminator. The in vitro transcription assay showed that the transcript ending at the IRsl8 was not proc-essed by ribonucleases but terminated intrinsically in an rNTP substrate-dependent manner as demonstrated for the first time in plant gene regulation. For the poly-T tract (TTCTTTTTT) 3′-proximal to the IRsl8, the C base conver-sion to T resulting in a perfect 9 Ts can dramatically increase termination efficiency, which is a common feature of bacte-rial intrinsic termination. This study is the first case to indi-cate that a conserved inverted repeat with a poly-T tract from higher plant chloroplast contributes to transcription termination of the translation-associated rps18 gene in a manner with the intrinsic termination, probably resulting from a heritage of endosymbiosis.

A Conserved Zinc Binding Domain in the Largest Subunit of DNA-dependent RNA Polymerase Modulates Intrinsic Transcription Termination and Antitermination but does not Stabilize the Elongation Complex

An evolutionarily conserved zinc-binding motif is found close to the amino terminus of the largest subunits of DNA-dependent RNA polymerases from bacteria, archaea, and eukaryotes. In bacterial RNA polymerase, this motif, the zinc binding domain, has been implicated in protein-DNA interactions that stabilize the transcription elongation complex and that occur downstream of the catalytic center. Here, we show that this view is incorrect, and instead, the zinc binding domain interacts with product RNA located upstream of the catalytic center and the RNA-DNA hybrid, a view consistent with structural studies of the elongation complex. We engineered mutations that alter or remove the zinc binding domain of Escherichia coli RNA polymerase. Several mutants, including one that lacked all four zinc ligands and another that lacked the entire domain, produced enzymes that were active in vitro and formed stable elongation complexes. However, they were defective in two functions that require interaction of polymerase with product RNA. First, they terminated less efficiently than the wild-type at intrinsic transcription terminators. Second, enzymes lacking the tip of the zinc binding domain or the zinc ligands did not antiterminate in response to an intrinsic antiterminator encoded by the put site of phage HK022. Termination, but not antitermination, was restored by the bacterial termination factor NusA. Surprisingly, a mutant that lacks the entire zinc binding domain regained a partial response to put. To account for this we suggest that put RNA interacts with an additional site in the elongation complex to mediate antitermination, and that this site is occluded by the wild-type zinc binding domain.

Attenuation control of pyrG expression in Bacillus subtilis is mediated by CTP-sensitive reiterative transcription.

In Bacillus subtilis and other Gram-positive bacteria, pyrimidine-mediated regulation of the pyrG gene, which encodes CTP synthetase, occurs through an attenuation mechanism involving an intrinsic transcription terminator in the pyrG leader region. Low intracellular levels of CTP prevent termination at the attenuator by a mechanism that requires the nontemplate strand sequence GGGC at the pyrG transcription initiation site (first G =+1) and the leader transcript sequence GCUCCC located at the 5' end of the terminator RNA hairpin. In this study, we demonstrate that reiterative transcription adds G residues (up to at least 10) to the 5' end of pyrG transcripts when B. subtilis cells are starved for pyrimidines but not when cells are grown with excess cytidine. Regulated repetitive addition of G residues, as well as pyrimidine-mediated pyrG regulation, requires the sequence GGGC or GGGT at the start of pyrG transcription. Mutational insertion of four extra G residues at the 5' end of the pyrG transcript (i.e., 5'-GGGGGGGC) results in constitutive pyrG expression. We propose that the incorporation of extra G residues by reiterative transcription at the wild-type promoter occurs when normal transcription elongation is stalled at position +4 by low levels of the incoming substrate, CTP, during pyrimidine limitation. The poly(G) extensions on the 5' ends of pyrG transcripts act to prevent transcription attenuation by base pairing with the sequence CUCCCUUUC located in the 5' strand of the terminator hairpin. This control mechanism is likely to operate in other Gram-positive bacteria containing similar pyrG leader sequences.

Adenine riboswitches and gene activation by disruption of a transcription terminator.

A class of riboswitches that recognizes guanine and discriminates against other purine analogs was recently identified. RNAs that carry the consensus sequence and structural features of guanine riboswitches are located in the 5' untranslated region (UTR) of numerous prokaryotic genes, where they control the expression of proteins involved in purine salvage and biosynthesis. We report that three representatives of this riboswitch class bind adenine with values for apparent dissociation constant (apparent K(d)) that are several orders of magnitude lower than those for binding guanine. Because preference for adenine is attributable to a single nucleotide substitution, the RNA most likely recognizes its ligand by forming a Watson-Crick base pair. In addition, the adenine riboswitch associated with the ydhL gene of Bacillus subtilis functions as a genetic 'on' switch, wherein adenine binding causes a structural rearrangement that precludes formation of an intrinsic transcription terminator stem.

Suppression of factor-dependent transcription termination by antiterminator RNA.

Nascent transcripts of the phage HK022 put sites modify the transcription elongation complex so that it terminates less efficiently at intrinsic transcription terminators and accelerates through pause sites. We show here that the modification also suppresses termination in vivo at two factor-dependent terminators, one that depends on the bacterial Rho protein and a second that depends on the HK022-encoded Nun protein. Suppression was efficient when the termination factors were present at physiological levels, but an increase in the intracellular concentration of Nun increased termination both in the presence and absence of put. put-mediated antitermination thus shows no apparent terminator specificity, suggesting that put inhibits a step that is common to termination at the different types of terminator.

Role of the Non-template Strand of the Elongation Bubble in Intrinsic Transcription Termination

Intrinsic transcription terminators of Escherichia coli and other bacteria, consisting primarily of an RNA hairpin preceding a terminal uridine-rich RNA segment, suffice to dissociate the otherwise stable elongation complex of core RNA polymerase. The essential functions of the hairpin and U-rich segments have been established, although the precise mechanism of termination is unknown. We identify another element of the terminator, namely the non-template DNA strand in the region of the terminal transcription bubble. Failure of the terminal bubble to rewind through complementary base-pairing strongly reduces the efficiency of terminator function, suggesting that the natural pathway of termination consists of coupled rewinding of the DNA template and unwinding of the RNA/DNA hybrid at the site of release.

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.

Analysis of the Intrinsic Transcription Termination Mechanism and Its Control

Publisher Summary This chapter describes approaches that permit dissecting the termination process in several steps and identifying individual roles of the terminator elements, the hairpin and T-stretch, in each step. To study the basic mechanism of intrinsic termination and its control, an in vitro reconstituted system is used that contains Escherichia coli (E.coli) RNAP, a linear DNA template with a strong promoter and the intrinsic terminator, and pure elongation factors, NusA and N. E. coli NusA protein works as a general termination factor, which significantly increases the efficiency of many intrinsic terminators in vitro and in vivo. The trapped complex (TC) represents a unique configuration of the elongation complexes (EC) that occurs exclusively at the intrinsic termination points. Pausing at the tR2 termination point is determined by the downstream portion of its T-stretch. Pausing provides an additional time for the hairpin to form and is required for efficient termination under physiological conditions. To exclude the kinetic component (pausing) from the analysis of termination and to study the “mechanistic” component of the termination process in real time, the slow termination approach has been developed. This approach utilizes a modified A1-tR2 template carrying point substitutions within the T-stretch, rendering the RNA: DNA hybrid strong enough to delay the hairpin folding.

RecX, a new SOS gene that is co-transcribed with the recA gene in Escherichia coli

recX is a small open reading frame located downstream of recA that is conserved in many bacteria. In Escherichia coli, the recX gene (also named oraA) is a 501 bp open reading frame that encodes a predicted basic protein. Transcriptional analysis by Northern blots showed that in E. coli the recX gene is SOS-regulated. Primer extension data and transcriptional fusions indicate that recX transcription is down regulated with respect to recA by an intrinsic transcription terminator that is located between the recA and recX coding sequences. Despite the presence of this terminator, a recA– recX message resulting from transcriptional readthrough is detected at a level of 5–10% of the recA message. In addition, transcriptional/translational fusion experiments show that recX expression is further down regulated at the translational level reaching an estimated protein level about 500-fold lower than RecA. Strains in which the recX gene was disrupted were constructed by insertion of an antibiotic resistance cassette. The survival after UV irradiation, the spontaneous and UV-induced mutation rates were not significantly different in these recX strains compared to the corresponding wild type strain. Overexpression of RecA was shown to be lethal in a recX deletion strain in Pseudomonas aeruginosa [J. Bacteriol. 175 (1993) 2451], Mycobacterium tuberculosis [Mol. Microbiol. 30 (1998) 525] and Streptomyces lividans [J. Bacteriol. 182 (2000) 4005] suggesting that the recX gene may act as a regulator of recA. In contrast in E. coli, in a recX deletion strain, RecA overexpression is neither toxic nor is the expression of the recA + gene affected in a recX deletion strain at the basal level or after UV induction.

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.

Control of Intrinsic Transcription Termination by N and NusA: The Basic Mechanisms

Intrinsic transcription termination plays a crucial role in regulating gene expression in prokaryotes. After a short pause, the termination signal appears in RNA as a hairpin that destabilizes the elongation complex (EC). We demonstrate that negative and positive termination factors control the efficiency of termination primarily through a direct modulation of hairpin folding and, to a much lesser extent, by changing pausing at the point of termination. The mechanism controlling hairpin formation at the termination point relies on weak protein interactions with single-stranded RNA, which corresponds to the upstream portion of the hairpin. Escherichia coli NusA protein destabilizes these interactions and thus promotes hairpin folding and termination. Stabilization of these contacts by phage λ N protein leads to antitermination.

Alternate paradigm for intrinsic transcription termination in eubacteria.

Intrinsic transcription terminators are functionally defined as sites that bring about termination in vitro with purified RNA polymerase alone. Based on studies in Escherichia coli, intrinsic termination requires a palindromic stretch followed by a trail of T (or U) residues in the coding strand. We have developed a highly efficient algorithm to identify hairpin potential sequences in bacterial genomes in order to build a general model for intrinsic transcription termination. The algorithm was applied to analyze the Mycobacterium tuberculosis genome. We find that hairpin potential sequences are concentrated in the immediate downstream of stop codons. However, most of these structures either lack the U trail entirely or have a mixed A/U trail reflecting an evolutionarily relaxed requirement for the U trail in the mycobacterial genome. Predicted atypical structures were shown to work efficiently as terminators both inside the mycobacterial cell and in vitro with purified RNA polymerase. The results are discussed in light of the kinetic competition models for transcription termination. The algorithm identifies >90% of experimentally tested terminators in bacteria and is an invaluable tool in identifying transcription units in whole genomes.

Mechanism of intrinsic transcription termination and antitermination.

Gene expression is modulated by regulatory elements that influence transcription elongation by RNA polymerase: terminators that disrupt the elongation complex and release RNA, and regulators that overcome termination signals. RNA release from Escherichia coli RNA polymerase can be induced by a complementary oligonucleotide that replaces the upstream half of the RNA hairpin stem of intrinsic terminator transcripts, implying that RNA hairpins act by extracting RNA from the transcription complex. A transcription antiterminator inhibits this activity of oligonucleotides and therefore protects the elongation complex from destabilizing attacks on the emerging transcript. These effects illuminate the structure of the complex and the mechanism of transcription termination.