RNA polymerase and gal repressor bind simultaneously and with DNA bending to the control region of the Escherichia coli galactose operon.

The Escherichia coli galactose operon contains an unusual array of closely spaced binding sites for proteins governing the expression from the two physically overlapping gal promoters. Based on studies of two gal promoter-up mutants we have previously suggested RNA-polymerase-induced DNA bending of gal promoter DNA. Here we present new evidence confirming and extending this interpretation. It was obtained by the circular permutation assay of gel electrophoretic mobility [Wu and Crothers (1984), Nature, 308, 509-513] applied to three analogous series of circularly permuted fragments derived from wild-type and two promoter-up mutant DNAs. The same circularly permuted DNA fragments have further been used to study the binding of gal repressor to its operator sites by electrophoretic mobility shift and by DNase I footprinting techniques. The main results are: (i) complexes carrying repressor either exclusively at the upstream operator O1 or at the downstream operator O2 exhibit different electrophoretic mobilities; (ii) binding to either one of the operators results in protein-induced DNA bending by the criteria of the circular permutation mobility assay; and (iii) occupation of both gal operators by gal repressor does not prevent cAMP-CRP-independent binding of RNA polymerase to the gal promoters, as judged by DNase I protection and gel retardation assays. The latter finding imposes constraints on any attempt to model the regulation of gal expression by assumed DNA-protein and protein-protein interactions.     

Mechanistic differences in promoter DNA melting by Thermus aquaticus and Escherichia coli RNA polymerases

Formation of strand-separated, functional complexes at promoters was compared for RNA polymerases from the mesophile Escherichia coli and the thermophile Thermus aquaticus. The RNA polymerases contained sigma factors that were wild type or bearing homologous alanine substitutions for two aromatic amino acids involved in DNA melting. Substitutions in the sigmaA subunit of T. aquaticus RNA polymerase impair promoter DNA melting equally at temperatures from 25 to 75 degrees C. However, homologous substitutions in sigma70 render E. coli RNA polymerase progressively more melting-defective as the temperature is reduced below 37 degrees C. The effects of the mutations on the mechanism of promoter DNA melting were investigated by studying the interaction of wild type and mutant RNA polymerases with "partial promoters" mimicking promoter DNA where the nucleation of DNA melting had taken place. Because T. aquaticus and E. coli RNA polymerases bound these templates similarly, it was concluded that the different effects of the mutations on the two polymerases are exerted at a step preceding nucleation of DNA melting. A model is presented for how this mechanistic difference between the two RNA polymerase could explain our observations.     

CAP and RNA polymerase interactions with the lac promoter: binding stoichiometry and long range effects.

The binding stoichiometries of the complexes formed when the E. coli cyclic AMP receptor protein (CAP) binds to 203 bp lac promoter-operator restriction fragments have been determined. Under quantitative binding conditions, a single dimer of CAP occupies each of two sites in the promoter. Different electrophoretic mobilities are observed for 1:1 complexes formed with L8-UV5 mutant, L305 mutant, and wild type promoter fragments, indicating sequence-specific structural differences between the complexes. The differences in gel mobility between L8-UV5 and wild type complexes disappear when the promoter fragments are cleaved with Hpa II restriction endonuclease. Models in which CAP alters DNA conformation or in which CAP forms a transient intramolecular bridge between two domains of a DNA molecule could account for these observations. The selective binding of RNA polymerase to CAP-promoter complexes is demonstrated: the binding of a single CAP dimer to the promoter is sufficient to stimulate subsequent polymerase binding. Functional CAP molecules are not released from the promoter on polymerase binding.     

Function-based selection and characterization of base-pair polymorphisms in a promoter of Escherichia coli RNA polymerase-sigma(70)

We performed two sets of in vitro selections to dissect the role of the -10 base sequence in determining the rate and efficiency with which Escherichia coli RNA polymerase-sigma(70) forms stable complexes with a promoter. We identified sequences that (i) rapidly form heparin-resistant complexes with RNA polymerase or (ii) form heparin-resistant complexes at very low RNA polymerase concentrations. The sequences selected under the two conditions differ from each other and from the consensus -10 sequence. The selected promoters have the expected enhanced binding and kinetic properties and are functionally better than the consensus promoter sequence in directing RNA synthesis in vitro. Detailed analysis of the selected promoter functions shows that each step in this multistep pathway may have different sequence requirements, meaning that the sequence of a strong promoter does not contain the optimal sequence for each step but instead is a compromise sequence that allows all steps to proceed with minimal constraint.     

Interaction of Escherichia coli RNA-polymerase with DNA-duplexes containing repetitive sequences

Nitrocellulose filter binding technique has been used to study the binding of E. coli RNA polymerase to synthetic DNA duplexes (100-200 base pairs), containing the repeating fragments of promoters. It has been shown, that the duplex, containing the repeats of "ideal". Pribnow box forms heparin resistant complexes with enzyme, the stability of which is comparable with that of lacUV5 promoter complexes (the half life is approximately 200 min). The synthetic polynucleotide with repeating trp-promoter-operator sequence less stable complexes with RNA polymerase, the half life of which being 30 min.     

Study of the binding of RNA polymerase by a recombinant plasmid using electron microscopy

RNA-polymerase of E. coli was bound in vitro under physiological conditions to a recombinant plasmid pBR322 carrying two identical segments of bacteriophage T4 DNA, each containing a complete gene coding for T4 DNA ligase. After fixation of the complex with formaldehyde it was analysed by electron microscopy. A map of binding sites of the enzyme to DNA was obtained after a statistical assessment of micrographs. The inserted repeat revealed itself in the map as two regions of identical binding patterns, thus proving the adequacy of the preparation procedure. In pBR322 the strong binding sites correlate with the position of promoters. Also, apart from this, there are other strong binding sites within the T4 sequences which correlate strongly with the regions of abnormally high AT content. That means that under physiological conditions the RNA polymerase forms strong binding complexes with any AT rich DNA regions, as well as with real promoters.