Kinetics of RNA polymerase-promoter complex formation: effects of nonspecific DNA-protein interactions.

The rates of formation of RNA polymerase-promoter open complexes at the galactose P2 and lactose UV5 promoters of E. coli were studied using polyacrylamide gels to separate the heparin-resistant complexes from unbound DNA. Both the apparent rate and extent of reaction at these promoters are inhibited at excess RNA polymerase. This inhibition, which can be relieved by the addition of non-promoter DNA, is interpreted to be the result of occlusion of the promoter site by nonspecifically bound polymerase. Additionally, biphasic kinetics are observed at both gal P2 and lac UV5, but not at the PR promoter of phage lambda. This behavior disappears when the concentration of RNA polymerase in the binding reaction is less than that of the promoter fragment. It is proposed that at excess enzyme nonspecifically bound polymerase molecules sliding along the DNA may "bump" closed complexes from the promoter site thereby reducing the rate of open complex formation. Kinetics mechanisms quantifying both the occlusion and bumping phenomena are presented.     

UV cross-linking of the Bacillus subtilis RNA polymerase to DNA in promoter and non-promoter complexes

Complexes between Bacillus subtilus RNA polymerase and 32P-labeled DNA were irradiated with UV light and digested with nuclease; electrophoresis and autoradiography were used to identify the polymerase subunits cross-linked to DNA. These experiments showed: 1) that cross-linkage of promoter complexes yielded predominantly the beta and sigma subunits; 2) that beta, beta', and sigma were detected in non-promoter complexes; 3) that addition of the delta subunit or high concentrations of NaCl decreased cross-linkage of all subunits, especially the cross-linkage of the sigma subunit in non-promoter complexes and the binding of polymerase at DNA ends; 4) that different patterns of cross-linkage were obtained at 0 degrees C (conditions favoring the formation of closed complexes) and 37 degrees C (conditions favoring the formation of open complexes); and 5) predominantly beta and possibly alpha were cross-linked by irradiation of core-DNA complexes whereas similar experiments with core-delta complexed to DNA showed the efficient cross-linkage of beta' and beta.     

Homologous RNA polymerase binding to Escherichia coli DNA: a study of the distribution of stable binding sites.

The number and the distribution of the sites of Escherichia coli DNA that form stable complexes with the homologous RNA polymerase (class A sites according to Hinkle and Chamberlin [3]) have been investigated. Almost all the DNA can bind RNA polymerase, even when fragmented at short (undergenic) size; this general non-promoter-specific binding is highly labile and is not temperature-dependent. The range of RNA polymerase/DNA ratios that give rise to the stable temperature-dependent complexes was examined. The amount and the distribution of class A complexes were studied analysing the dissociation of complexes formed by RNA polymerase on DNA fragments of various length. The E. coli genome appears to form 3.8 X 10(3) stable complexes; the majority of these complexes shows a short-range distribution (800-1200 base pairs). The rest is more widely spaced (1200-6000 base pairs).     

Control of ColE1 plasmid replication. Intermediates in the binding of RNA I and RNA II.

Replication of plasmid ColE1 is regulated by a plasmid-specified small RNA (RNA I). RNA I binds to the precursor (RNA II) of the primer for DNA synthesis and inhibits primer formation. The process of binding of RNA I to RNA II that results in formation of a stably bound complex consists of a series of reactions forming complexes differing in the stability. Formation of a very unstable early intermediate that was previously inferred from the inhibition of stable binding caused by a second RNA I species was firmly established by more extensive studies. This complex is converted to a more stable yet reversible complex that was identified by its RNase sensitivity, which was altered from that of the earlier complex or from that of free RNA I or RNA II. In these complexes, most loops of RNA II interact with their complementary loops of RNA I. The kinetic and structural analyses of the binding process predict formation of a complex interacting at a single pair of complementary loops that precedes formation of these complexes. Thus the process of binding of RNA I to RNA II is seen to consist of a sequence of reactions producing a series of progressively more stable intermediates leading to the final product.     

Comparative study of calf thymus and wheat germ RNA polymerase II: stability of initiation complexes and elongation rates.

Pure wheat germ RNA polymerase II but not calf thymus RNA polymerase II forms relatively stable binary complexes (half life time of 30 minutes at 0°C) with superhelical SV 40 DNA. On the contrary, the addition of a specific dinucleotide and a single ribotriphosphate permits the formation of highly stable complexes between both enzymes and SV 40 DNA. The elongation of RNA chains with preinitiated wheat germ enzyme only is stimulated by sarkosyl. These observations suggest that the wheat germ enzyme, as compared to that isolated from calf thymus, may contain a protein factor, a more native structure or both that permit efficient initiation and elongation of RNA chains on double stranded DNA.     

Transcription of polyoma virus DNA in vitro. III. Localization of calf thymus RNA polymerase II binding sites.

The binding sites of calf thymus RNA polymerase II on polyoma DNA were monitored by electron microscopy. Six discrete binding sites were located at positions 0.06, 0.25, 0.57, 0.66, 0.85 and 0.98 on the physical map of polyoma DNA. Although most of these sites are located in easily denaturable regions of the DNA, the strongest binding sites do not overlap with the major A + T-rich regions. In addition, the same binding sites were observed on superhelical or linear polyoma DNA. These results suggest that the eucaryotic RNA polymerase II can recognize specific sequences on double-stranded DNA and not only easily denaturable regions. At least five of these sites correspond to the binding and initiation sites mapped previously for the Escherichia coli RNA polymerase (Lescure et al., 1976).Stable initiation complexes can be formed with both E. coli and calf thymus RNA polymerases in the presence of a single dinucleotide (GpU) and a specific ribotriphosphate (CTP). Under these conditions, the binding of both enzymes to the sites in positions 0.06 and 0.57 is stimulated whereas the binding in positions 0.65 and 0.84 is partially suppressed. Both eucaryotic and procaryotic RNA polymerases may recognize similar sequences of the viral DNA in vitro.     

The main early and late promoters of Bacillus subtilis phage phi 29 form unstable open complexes with sigma A-RNA polymerase that are stabilized by DNA supercoiling.

Most Escherichia coli promoters studied so far form stable open complexes with sigma 70-RNA polymerase which have relatively long half-lives and, therefore, are resistant to a competitor challenge. A few exceptions are nevertheless known. The analysis of a number of promoters in Bacillus subtilis has suggested that the instability of open complexes formed by the vegetative sigma A-RNA polymerase may be a more general phenomenon than in Escherichia coli. We show that the main early and late promoters from the Bacillus subtilis phage phi 29 form unstable open complexes that are stabilized either by the formation of the first phosphodiester bond between the initiating nucleoside triphosphates or by DNA supercoiling. The functional characteristics of these two strong promoters suggest that they are not optimized for a tight and stable RNA polymerase binding. Their high activity is probably the consequence of the efficiency of further steps leading to the formation of an elongation complex.     

Using 2-aminopurine fluorescence to detect bacteriophage T4 DNA polymerase-DNA complexes that are important for primer extension and proofreading reactions

The fluorescence of the base analogue 2-aminopurine (2AP) was used to probe bacteriophage T4 DNA polymerase-induced conformational changes in the template strand produced during the nucleotide incorporation and proofreading reactions. 2AP fluorescence in DNA is quenched by 2AP interactions with neighboring bases, but T4 DNA polymerase binding to DNA substrates labeled with 2AP in the templating position produces large increases in fluorescence intensity. Fluorescence lifetime studies were performed to characterize the fluorescent complexes. Three fluorescence lifetime components were observed for unbound DNA substrates as reported previously, but T4 DNA polymerase binding modulated the amplitudes of these components and created a new, highly fluorescent 10.5 ns component. Experimental evidence for correlation of fluorescence lifetimes with functionally distinct complexes was obtained by forming complexes under different reaction conditions. T4 DNA polymerase complexes were formed with DNA substrates with matched and mismatched primer ends and with A+T- or G+C-rich primer-terminal regions. dTTP was added to binary complexes to form ternary DNA polymerase-DNA-nucleotide complexes. The effect of temperature on complex formation was studied, and complexes were formed with proofreading-defective T4 DNA polymerases. Complexes characterized by the 10.5 ns lifetime were demonstrated to be formed at the crossroads of the primer-extension and proofreading pathways.     

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.