Enzymic synthesis of RNA from T7 DNA

Mechanistic studies on the impact of transcription on sequence-specific termination of DNA replication and vice versa

Since DNA replication and transcription often temporally and spatially overlap each other, the impact of one process on the other is of considerable interest. We have reported previously that transcription is impeded at the replication termini of Escherichia coli and Bacillus subtilis in a polar mode and that, when transcription is allowed to invade a replication terminus from the permissive direction, arrest of replication fork at the terminus is abrogated. In the present report, we have addressed four significant questions pertaining to the mechanism of transcription impedance by the replication terminator proteins. Is transcription arrested at the replication terminus or does RNA polymerase dissociate from the DNA causing authentic transcription termination? How does transcription cause abrogation of replication fork arrest at the terminus? Are the points of arrest of the replication fork and transcription the same or are these different? Are eukaryotic RNA polymerases also arrested at prokaryotic replication termini? Our results show that replication terminator proteins of E. coli and B. subtilis arrest but do not terminate transcription. Passage of an RNA transcript through the replication terminus causes the dissociation of the terminator protein from the terminus DNA, thus causing abrogation of replication fork arrest. DNA and RNA chain elongation are arrested at different locations on the terminator sites. Finally, although bacterial replication terminator proteins blocked yeast RNA polymerases in a polar fashion, a yeast transcription terminator protein (Reb1p) was unable to block T7 RNA polymerase and E. coli DnaB helicase.

Transcription termination

Chromosomes are organized into units of expression that are bounded by sites where transcription of DNA sequences into RNA is initiated and terminated. To allow for efficient stepwise assembly of complete transcripts, the transcribing enzyme (RNA polymerase) makes a stable complex with the DNA template until it reaches the terminator. Three general mechanisms of transcription termination have been recognized: one is by a spontaneous dissociation of the RNA at a sequence segment where RNA polymerase does not maintain its usual stable interaction with the nascent chain; another involves the action of a protein (rho factor in bacteria) on the nascent RNA to mediate its dissociation; and a third involves an action triggered by a protein that binds to the DNA at a sequence that is just downstream of the termination stop point. Transcription termination is important in the regulation of gene expression both by modulating the relative levels of various genes within a single unit of expression and by controlling continuation of transcription in response to a metabolic or regulatory signal.

Parameters affecting transcription termination by Escherichia coli RNA polymerase

Escherichia coli RNA polymerase can terminate transcription efficiently at rho-independent terminators in a purified transcription system in the absence of accessory factors. This process of "intrinsic termination" involves direct recognition of the terminator by the core RNA polymerase, and provides an important model system for the study of the molecular interactions involved in the switch between elongation and termination. We have analyzed the intrinsic termination efficiency (%T) of 13 rho-independent terminators, under a variety of in vitro reaction conditions. Although all of these sites share the general sequence features of typical rho-independent terminators, we find a wide range of %T (2% to 90%) for the different sites under our standard transcription conditions. While %T for a particular site is characteristic of that site, the efficiency can be altered considerably by the nature and concentration of salts in the reaction, by alteration of the concentrations of the nucleoside triphosphate substrates, or by transcription from supercoiled rather than linear templates. Surprisingly, different conditions can alter %T to a different extent for different terminators. For neutral salts such as potassium chloride or potassium glutamate, changes in the range from 0.1 to 1 M affect %T for different terminators in a distinct manner, depending on the terminator and the anion involved. At some sites, %T is greatly increased by Cl- concentrations up to 1 M, while at other sites %T is reduced or unaffected by these conditions. At some sites K+ concentrations up to 1 M give a modest increase in %T, while at other sites %T is slightly reduced under the same conditions. Thus the actual values of %T, as well as the order of terminator sites ranked according to %T, can be altered greatly according to the choice of reaction conditions. Reduction of the Mg2+ concentration below 1 mM has a dramatic and quite different effect, enhancing termination to approximately 100% for all terminators tested. Transcription of supercoiled DNA templates gives somewhat reduced %T as compared with linear DNA templates. However, the effect is no greater than twofold. Our results are not consistent with those expected for models in which %T is determined by the differential stability of DNA, RNA and hybrid duplex structures at the melted region in the transcription complex. Thus, the Cl anion does not affect the stability of nucleic acid duplexes even at 1 M concentrations, but can enhance termination tenfold. Also, the alterations of monovalent cation concentration that affect %T are not expected to have a differential effect on Tm for DNA, RNA and hybrid duplexes.(ABSTRACT TRUNCATED AT 400 WORDS)

RNA chain elongation by Escherichia coli RNA polymerase. Factors affecting the stability of elongating ternary complexes

We have devised a method to follow the stability of individual ternary transcription complexes containing Escherichia coli RNA polymerase halted at many different sites along a DNA template during the transcription process. Studies of complexes formed with phage T7 DNA templates reveal at least three general classes of ternary complexes that differ dramatically in their properties. Complexes of one sort (normal complexes) are highly stable to dissociation and denaturation under a variety of solution conditions. They remain intact and active for up to 24 hours even in salt concentrations up to 1 M-K+. This suggests that they are stabilized to a significant extent by non-ionic interactions between RNA polymerase and the nucleic acids. We consider these to be the normal complexes formed during RNA chain elongation. Complexes of a second sort (release complexes) dissociate rapidly, releasing free RNA transcripts and active RNA polymerase. The rate of dissociation is substantially enhanced by elevated concentrations of K+, hence the interaction between RNA polymerase and nucleic acids in these complexes is stabilized predominantly by ionic interactions. However, release complexes are stabilized by millimolar concentrations of Mg2+, which as been implicated in stabilization of the binding of RNA to free RNA polymerase. These complexes are formed at DNA sequences that we refer to as release sites. Analysis of DNA sequences at release sites reveals that all share a common feature, the potential to form an RNA hairpin in the region just upstream from the actual 3' end of the released RNA. Experiments incorporating IMP in the transcript and blocking potential hairpin formation with DNA oligomers support a direct role for an RNA hairpin in triggering the release reaction. Changes in the 3'-proximal DNA sequences generally have little effect on the presence or rate of the release reaction, although there are significant exceptions. The results suggest that the presence of certain RNA hairpins in the region six to ten nucleotides upstream from the transcript growing point can trigger a substantial structural transition in the ternary transcription complex, forming a "release mode" complex from which transcript dissociation is facilitated. This release, mode complex may be a central intermediate in RNA chain termination. A final class of complexes (dead-end complexes) appear to be elongating complexes that have entered a state or conformation that is stable, but is blocked in resuming the normal elongation reaction. Such complexes bear active RNA polymerase, and can be restarted after limited pyrophosphorolysis. The structural elements that determine the formation of dead-end complexes are not yet known.

Bacteriophage T4 late transcription from plasmid templates is enhanced by negative supercoiling

Concurrent viral replication is normally required to activate bacteriophage T4 late promoters; replication is thought to provide a template structure which is competent for late transcription. Transcription from plasmid-borne T4 late promoters, however, is independent of replication in vivo and in vitro. In this work, we have shown that, when the late gene 23 promoter is located on a plasmid, its utilization in vivo depends upon the ability of host DNA gyrase to maintain some degree of negative superhelicity. This suggests that an alternative pathway exists for activation of late promoters: DNA which is under sufficient negative torsional stress is already competent for late transcription. We also describe a method for isolating ternary complexes of plasmid DNA, RNA polymerase, and nascent RNA which have initiated transcription in vivo. The topoisomer distribution of such ternary complexes prepared from T4-infected cells showed that, late in infection, transcriptional activity resides primarily in the subset of the plasmid population with the most negatively supercoiled topoisomers. However, the overall transcriptional pattern in these ternary complexes indicated that both vector and T4 sequences are actively transcribed. Much of this transcriptional activity could be independent of gp55, the T4-specific RNA polymerase-binding protein that confers late promoter recognition.

Escherichia coli RNA polymerase binding to a DNA terminus prevents formation of a closed promoter complex

A 302 bp DNA fragment and a 113 bp subfragment of the former, both containing the fd gene VIII promoter (P VIII), were found to exhibit temperature-dependent differential behaviour in RNA chain initiation from P VIII. At 37 degrees C no significant differences were observed, while at 17 degrees C chain initiation was strongly suppressed only with the 113 bp fragment. This phenomenon depended on the presence of the (blunt) DNA terminus upstream from P VIII (position -70). Footprinting revealed that at 17 degrees C RNA polymerase was bound to this DNA fragment in a different mode. Contacts were observed only upstream from position -25. On the contrary, at 37 degrees C only the promoter complex footprint was visible. These results indicate that at 17 degrees C formation of the non-initiating complex is more favourable than formation of the promoter complex (which is closed at 17 degrees C; Hofer, B., Müller, D. and Köster, H. (1985) Nucleic Acids Res. 13, 5995-6013) and that formation of both complexes is mutually exclusive. No footprints of RNA polymerase were observed at other DNA termini. This indicates a sequence-specificity for the interaction at the terminus of the 113 bp fragment. The footprint pattern, together with features of the DNA sequence, suggests that the contacts involved in this interaction are similar to those promoter contacts formed upstream from position -20 and that DNA without a -10 region can be specifically recognized by RNA polymerase.

Conformational alterations of transcription termination protein rho induced by ATP and by RNA

Transcription termination protein rho from Escherichia coli possesses an RNA-dependent ATP hydrolysis activity necessary for expression of its termination function. We have used the rate of trypsin-mediated inactivation of ATPase activity as a conformational probe to test for ligand binding-induced conformational changes in the rho polypeptide. When present in molar excess over rho polypeptide, trypsin inactivates rho ATPase by a first order process that correlates well with the loss of intact rho polypeptide. When rho protein binds poly(C) or poly(dC), its susceptible bonds become more accessible to trypsin action. On the other hand, when rho binds either ATP or ADP those bonds become less accessible. These results suggest that rho protein assumes an altered conformation when an RNA cofactor is bound and that is assumes a distinctly different conformation when a nucleotide substrate or product is bound. A special change in the accessibility of trypsin-susceptible bonds is also detected when rho in its complex with poly(C) is catalyzing the hydrolysis of ATP.

On the influence of thymidine analogues on the activity of phage fd promoters in vitro

RF I DNA of phage fd containing 5-bromo-deoxyuridine (br5Ud) or deoxyuridine (Ud) instead of deoxythymidine (Td) inthe codogenic strand was synthesized in vitro. The modified genomes could be cleaved by restriction endonuclease Hpa II. Although the recognition site of Hpa II is CCGG, the cleavage rate was significantly reduced with Ud-containing DNA. Both base substitutions altered the mobilities of several DNA fragments under the conditions of polyacrylamide gel electrophoresis. The fragments containing binding sites for RNA polymerase were assayed for the rates of stable complex formation. The substitution of Td for both, Ud and br5Ud, strongly influenced this parameter. Thus the methyl group of Td has to be regarded as one of the sites in DNA which determine the rate of stable RNA polymerase binding and thereby possibly mediate promoter activity in vitro (24,25,26). In most cases the rate of complex formation was decreased by Ud, but increased by br5Ud.

Novel RNA polymerase sigma factor from Bacillus subtilis

A modified form of Bacillus subtilis RNA polymerase (RNA nucleotidyltransferase) has been isolated that exhibits distinctive transcriptional specificity. This modified enzyme transcribes two cloned genes from the purA-cysA region of the B. subtilis chromosome whose expression in vivo is associated with the process of sporulation. Neither of these genes is transcribed by the usual form of B. subtilis RNA polymerase holoenzyme containing a sigma factor of 55,000 daltons (sigma 55). The modified RNA polymerase lacks sigma 55 but contains a newly identified subunit of 37,000 daltons termed sigma 37. A reconstitution experiment in which sigma 37 was added to core RNA polymerase strongly suggests that sigma 37 is responsible for the transcriptional specificity of the modified RNA polymerase. Sigma 37 apparently acts at the level of promoter recognition; this transcriptional determinant enabled core RNA polymerase to form stable binary and ternary ("initiation") complexes with endonuclease restriction fragments containing promoters for the cloned B. subtilis genes.

Escherichia coli RNA polymerase binding and initiation of transcription on fragments of lambda rifd 18 DNA containing promoters for lambda genes and for rrnB, tufB, rplC,A, rplJ,L, and rpoB,C genes

Promoters of genes for bacteriophage lambda and for Escherichia coli ribosomal RNA (rrnB), elongation factor Tu (tufB), ribosomal proteins L11 (rplK), L1 (rplA), L10 (rplJ), and L7/L12 (rplL), and RNA polymerase subunits beta (rpoB) and beta' (rpoC) were studied by use of two types of filter binding assays which measured E. coli RNA polymerase binding and initiation of transcription on restriction fragments of lambda rifd 18 DNA. The DNA fragments selectively retained on filters were eluted, concentrated, and analyzed by gel electrophoresis. The binding characteristics of these promotor fragments were qualitatively determined by varying the RNA polymerase, salt, and glycerol concentrations in the polymerase binding assay with HaeIII fragments of lambda rifd 18 DNA. The approximate map locations of these small HaeIII fragments were determined by HaeIII digestion of the larger, previously mapped EcoRI, HindIII, and SmaI restriction fragments of the phage DNA. The base compositions proximal to the 5' ends of mRNA's from promoters on these DNA fragments were elucidated by the polymerase initiation assay, in which the addition of various combinations of nucleoside triphosphates to the reaction allowed RNA polymerase to form high-salt-resistant initiation complexes with some of the known SmaI + EcoRI, EcoRI + HindIII, or HaeIII restriction fragments of lambda rifd 18 DNA. The data obtained by this technique are consistent with the map positions and 5' mRNA base sequences of the known lambda promotors p'R, po, pR and pL. In the main focus of this work, we have determined the approximate map locations and 5' mRNA base compositions of several promoters for known E. coli genes including rrnB, tufB, rplK,A, and rplJ,L. No promoter was detected between rplL and the rpoB,C genes. Thus our data are consistent with the conclusion of Yamamoto and Nomura (1978) that the beta and beta' mRNA is probably cotranscribed from the promoter for rplJ,L. Finally, the approximate map positions and the NTP combinations which initiated transcription of several unknown lambda and E. coli in vitro promoters are reported. The methods reported should prove useful for studying the characteristics of promoters on other cloned DNA regions.

The mechanism of inhibition of bacteriophage T7 RNA synthesis by acridines, diacridines and actinomycin D

A homologous series of diacridines, as well as 9-amino acridine, were assayed for their ability to interfere with the synthesis of RNA (bands U-VI) by bacteriophage T7 DNA-dependent RNA polymerase transcribing T7 DNA in vitro; their action was compared to that of actinomycin D. It was found that, in contrast to actinomycin D which inhibits chain elongation, the acridines tested inhibited chain initiation only; no evidence for inhibition of chain elongation was noted. No clear-cut differentiation between single and double intercalators on the mechanism of inhibition of RNA synthesis could be determined, except that the latter are more potent inhibitors. However, it appears that diacridines connected with a diethyldiamine and a butyldiamine chain are less inhibitory to the synthesis of the RNA of Bands III and IV. The results furthermore indicate that the estimation of the number average molecular weight alone, without identification of the product RNA, is a potentially misleading method of determining the mode of action of these drugs.

Studies of DNA bound RNA molecules isolated from nucleoids of Escherichia coli

Methods are developed for studying RNA molecules bound directly to DNA in bacterial nucleoids. It is found that among the 1000-3000 nascent RNA chains that normally are attached to the DNA via their associated RNA polymerase molecules, 74 +/- 14 chains per nucleoid can be bound differently. These chains unlike the other nascent RNAs remained bound to the DNA after the chromosome was deproteinized and sheared. Sensitive assays using radioactive labels detected no RNA polymerase involved in the RNA-DNA linkage. The linkage was stable at low temperatures, but the RNA separated from the DNA at high temperature. The bound RNA molecules were heterodisperse (weight average length 1200 bases). Pulse-chase experiments and studies of the fate of these RNA molecules in rifampicin treated cells demonstrated that they are nascent RNAs, degraded or released from the DNA in vivo with kinetics similar to that of the total nascent RNA. Hybridization analyses showed that the chains are composed at least in part of nascent rRNA and known mRNA molecules. Some, but not more than 5% of the bound chains, contained sequences of about 300 nucleotides in length, bound to the DNA in an RNase resistant form.

Isolation and properties of the transcription complex of Escherichia coli RNA polymerase

A procedure is described which permits complete separation of a transcription complex formed with template DNA, growing RNA chain and functioning RNA polymerase, from RNA polymerase molecules which have bound to DNA but not initiated RNA synthesis. The method is based on the marked stability of the transcription complex to dissociation by high concentrations of CsCl or CS2SO4 which enable banding the complex after equilibrium centrifugation. With use of the newly developed procedure, affinity of Escherichia coli RNA polymerase to T7 phage DNA was found to increase during initiation of RNA synthesis but then decrease concomitant with elongation of RNA chain presumably due to migration of the enzyme to DNA sites of weak affinity. Under the conditions of maximum affinity, the transcription complex contained one core polymerase for each T7 DNA if it was isolated by centrifugation in CsCl; in contrast, 2-6 enzyme molecules remained attached on the complex when the centrifugation was carried out in Cs2SO4. Thus, RNA polymerases bound to different sites of transcription initiation appear to be distinguished based on the affinity of interaction. Attempts are also described to isolate the transcription complex in vivo by Cs2SO4 centrifugation by Brij 58-deoxycholate lysate of lysozyme-treated Escherichia coli cells. The isolated complex contained approx. 50 polymerase molecules per Escherichia coli genome as well as other unidentified proteins.

Adrenocorticotropic hormone stimulation of adrenal RNA polymerase I and III activities. Nucleotide incorporation into internal positions and 3' chain termini

In the presence of 50 mM (NH4)2SO4 and low concentrations of alpha-amanitin (7.7 mug/ml), adrenal nuclei synthesize predominately rRNA as characterized by size and base composition. Approximately 10% of the RNA synthesized under these conditions sediments at 4-5 S; this RNA synthesizing activity is inhibited by high concentrations of alpha-amanitin (231 mug/ml) indicating the presence of RNA polymerase III activity. ACTH administration to guinea pigs results in a twofold increase in adrenal nuclear RNA polymerase I and III activities at 14 hr of hormone treatment. Analysis of the amount of radiolabeled nucleoside triphosphate incorporated in vitro into 3' chain termini and into internal nucleotide positions has been utilized to measure the number of RNA chains and the average chain length synthesized in vitro. Incorporation into 3' chain termini is not changed by ACTH; incorporation into internal nucleotides is doubled in parallel with the increase in RNA polymerase I activity. These results are not due to an altered Km of RNA polymerase I for the four nucleoside triphosphates, nor to differential R Nase or phosphatase activity. These studies suggest that the regulation of RNA polymerase I by ACTH is accomplished in part through an increase in the rate of RNA chain elongation.

In vitro transcription of a transfer RNA gene

The Escherichia coli tRNA(Tyr) gene carried by the varphi80psu(3) + transducing phage was transcribed in vitro by DNA-dependent RNA polymerase. The enzymatically synthesized tRNA(Tyr)-like polynucleotide chains were detected by competition with purified E. coli(32)P-tRNA(Tyr) for specific hybridization sites on varphi80psu(3) + DNA. Analysis by sucrose gradient centrifugation showed the tRNA(Tyr)-like chains to possess a heterogeneous distribution with respect to sedimentation coefficients, with a broad peak around 8 S. The presence of the termination factor rho during the transcription did not significantly reduce the average size of the in vitro synthesized tRNA(Tyr)-like chains.

Initiation and release of RNA by DNA-dependent RNA polymerase

During in vitro transcription of T4 DNA by E. coli RNA polymerase, chain initiation stops coincidentally with synthesis at low ionic strength (0.11) with an average of one RNA chain initiated per 24S polymerase molecule. At high ionic strength (0.37), initiation as well as synthesis continues for several hours, with an average of four chains initiated per enzyme molecule in two hours. The RNA product is released from the T4 DNA template at both low and high ionic strength. At high ionic strength, however, RNA polymerase can repeatedly initiate, synthesize, and release RNA from the synthesis complex in vitro. Under both conditions, the synthesized RNA sediments at 25-44 S, has a number average chain length of 5000 to 7500 nucleotides, and a weight average chain length of 11,500 nucleotides.

Transcriptions of the bacteriophage T4 template in vitro: separation of "delayed early" from "immediate early" transcription

The synthesis of different early T4 transcripts by E. coli RNA polymerase in vitro can be dissociated in two ways: (1) when T4 DNA is mechanically degraded, it selectively loses the ability to serve as a template for the transcription of delayed early T4 RNA; (2) when initiation of RNA synthesis on intact T4 DNA is limited to a very short time interval immediate early T4 RNA is synthesized at once but delayed early polynucleotide sequences appear only after a time lag. We conclude that initiation sites for T4 early RNA synthesis are closer to immediate early than to delayed early segments of the T4 template and that immediate early and delayed early segments of the T4 chromosome are interspersed. We propose that this interspersing is significant for the programming of transcription during T4 development.