Site-directed mutagenesis of the -10 region of the lacUV5 promoter. Introduction of dA4.dT4 tract suppresses open complex formation

Homopolymeric dAn.dTn sequences, where n is 4 or greater, have special properties leading to increased duplex stability and DNA bending. The lacUV5 promoter was used to examine the functional consequences of changing the -10 TATAAT consensus sequence to the sequence TAAAAT. The transversion mutation at the underlined site was accomplished with site-directed mutagenesis using translation termination as the selection procedure. For free DNA, structural differences at the 5' and 3' junction regions of the dA4.dT4 tract can be readily detected by DNase I digestion. However, site binding by Escherichia coli RNA polymerase appeared unaltered by the TAAAAT sequence since identical DNase I footprints were obtained for the lacUV5 and mutant promoters. Binding competition studies under different ionic strengths revealed a significant reduction in mutant promoter open complex formation relative to the lacUV5 promoter. Mutant promoter open complexes also dissociated faster and to a greater extent than the corresponding lacUV5 promoter open complexes when challenged with heparin or a combination of heparin and increased KCl concentration. Consequently, mutant promoter open complexes appear less stable than lacUV5 promoter open complexes.     

Specific contacts between the bacteriophage T3, T7, and SP6 RNA polymerases and their promoters

The specificity and structural simplicity of the bacteriophage T3, T7, and SP6 RNA polymerases make these enzymes particularly well suited for studies of polymerase-promoter interactions. To understand the initial recognition process between the enzyme and its promoters, DNA fragments that carry phage promoters were chemically modified by three different methods: base methylation, phosphate ethylation, and base removal. The positions at which these modifications prevented or enhanced binding by the RNA polymerases were then determined. The results indicate that specific contacts within the major groove of the promoter between positions-5 and -12 are important for phage polymerase binding. Removal of individual bases from either strand of the initiation region (-5 to +3) resulted in enhanced binding of the polymerase, suggesting that disruption of the helix in this region may play a role in stabilization of the polymerase-promoter complexes.     

FIS modulates the kinetics of successive interactions of RNA polymerase with the core and upstream regions of the tyrT promoter

We have applied laser UV photo-footprinting to characterise kinetically complexes involving the activator protein FIS, RNA polymerase and the tyrT promoter of Escherichia coli. FIS photo-footprints strongly to three binding sites upstream of the core promoter. The polymerase photo-footprints in the near-consensus -35 hexamer on the non-template strand of DNA in a fashion similar to that of stable complexes involving the lacUV5 promoter. The kinetics of the interactions of polymerase alone with the tyrT promoter differ from those observed previously at the lacUV5 promoter. In the absence of FIS, we observe an upstream polymerase-induced signal at -122 within FIS site III that occurs subsequent to changes in the core promoter region and is strongly dependent on negative supercoiling. These observations support the proposal that the upstream region of the promoter is wrapped around the polymerase. We propose that the wrapped DNA allows the polymerase to overcome, at least in part, the barrier to DNA untwisting imparted by the G+C-rich discriminator. We further suggest that FIS plays a similar role and may facilitate polymerase escape.     

Different roles for basic and aromatic amino acids in conserved region 2 of Escherichia coli sigma(70) in the nucleation and maintenance of the single-stranded DNA bubble in open RNA polymerase-promoter complexes.

Amino acid residues in region 2 of final sigma(70) have been shown to play an important role in the strand separation step that is necessary for formation of the functional or open RNA polymerase-promoter complex. Here we present a comparison of the roles of basic and aromatic amino acids in the accomplishment of this process, using RNA polymerase bearing alanine substitutions for both types of amino acids in region 2. We determined the effects of the substitutions on the kinetics of open complex formation, as well as on the ability of the RNA polymerase to form complexes with single-stranded DNA, and with forked DNA duplexes carrying a single-stranded overhang consisting of bases in the -10 region. We concluded that two basic amino acids (Lys(414) and Lys(418)) are important for promoter binding and demonstrated distinct roles, at a subsequent step, for two aromatic amino acids (Tyr(430) and Trp(433)). It is likely that these four amino acids, which are close to each other in the structure of final sigma(70), together are involved in the nucleation of the strand separation process.     

Conformational changes in E. coli RNA polymerase during promoter recognition.

We analysed complexes formed during recognition of the lacUV5 promoter by E. coli RNA polymerase using formaldehyde as a DNA-protein and protein-protein cross-linking reagent. Most of the cross-linked complexes specific for the open complex (RPO) contain the beta' subunit of RNA polymerase cross-linked with promoter DNA in the regions: -50 to -49; -5 to -10; + 5 to +8 and +18 to +21. The protein-protein cross-linking pattern of contacting subunits is the same for the RNA polymerase in solution and in RPO: there are strong sigma-beta' and beta-beta' interactions. In contrast, only beta-beta' cross-links were detected in the closed (RPC) and intermediate (RPI) complexes. In presence of lac repressor before or after formation of the RPO cross-linking pattern is similar with that of RPI (RPC) complex.     

Probing of DNA structure with osmium tetroxide,2,2''-bipyridine. Adduct-specific antibodies.

Antibodies against DNA modified with a single-strand selective probe, OsO4 in complex with 2,2'-bipyridine (Os,bipy), were raised in rabbits. These antibodies were fractionated using affinity column chromatography and fractions S89-II and S89-III characterized as highly specific for DNA-Os,bipy adduct with no cross reactivity to at least 1000-fold excess of unmodified DNA, RNA and Os,bipy-modified and unmodified proteins. Cross-reactivity to Os,bipy-modified RNA was very small. S89-II showed no cross-reactivity to DNA modified with OsO4 complexed with tetramethylethylenediamine or with bathophenanthroline disulphonic acid and to DNA oxidized with KMnO4. It cross-reacted, however, with DNA modified with OsO4,1,10-phenanthroline complex. The limit of detection of immunodot-blot analysis of extensively Os,bipy-modified DNA was below 0.5 pg. Small extent of Os,bipy-modification of supercoiled and linearized plasmids can be detected by DNA gel retardation and immunoblotting techniques. E. coli cells contain DNA regions in which bases are accessible to the single-strand selective probe.     

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.     

The 0 degree C closed complexes between Escherichia coli RNA polymerase and two promoters, T7-A3 and lacUV5

The promoter-specific binding of Escherichia coli RNA polymerase to the T7-A3 and the lacUV5 promoters at 0 degrees C was analyzed by DNase I footprinting. At 37 degrees C, the footprint from RNA polymerase bound to the A3 promoter is essentially the same as that reported by Galas, D.J., and Schmitz, A., (1978) Nucleic Acids Res. 5, 3157-3170 for the lacUV5 promoter. At 0 degrees C, the footprint for the A3 promoter is well defined but reduced in size. The principal difference between the 0 and 37 degrees C footprints is a region from -2 to +18 which is protected by polymerase at the higher but not at the lower temperature. In contrast, the 0 degree C footprint for the lacUV5 promoter differs substantially in character from the footprint for A3 at 0 degree C. The footprint is similar to the pattern of DNase I digestion of DNA bound to a surface; alternating regions of sensitive and protected DNA are spaced at intervals of about 10 base pairs. This region of DNase I-sensitive and -resistant DNA has the same boundaries as the 0 degree C footprint on T7-A3. Temperature shift experiments confirmed the sequence specificity of the RNA polymerase interaction with UV5 at 0 degree C. These results indicate that RNA polymerase binds specifically to each promoter sequence in a closed complex. The increased time and amounts of RNA polymerase required to form the 0 degree C footprint on the lacUV5 promoter indicate that it binds RNA polymerase more weakly than does the T7-A3 promoter. Therefore there is a correlation between the binding constant for closed complex formation estimated from kinetic measurements and the formation of the 0 degree C footprint. The -35 region of the promoter may be more important in establishing the 0 degree C footprint because the T7-A3 promoter is a better match to the consensus sequence. Conversely, the -10 region seems less important because lacUV5 is a perfect match to the consensus, whereas the T7-A3 promoter matches at only five out of seven positions. The 0 degree C footprints encompass both regions along with the spacer; the combination of these regions rather than an individual region may determine the character of the footprint and the magnitude of the binding constant.     

Monoclonal antibody against DNA adducts with osmium structural probes.

Osmium tetroxide complexes with nitrogen ligands (Os,L) have been widely used as probes of the DNA structure. A monoclonal antibody OsBP7H8 against DNA adducts with Os,L was produced in mice. OsBP7H8 does not bind to proteins or total yeast RNA modified with Os,2,2'-bipyridine (bipy) nor to the unmodified nucleic acids and proteins. The antibody recognizes DNA modified with Os,bipy (DNA-Os,bipy) or with OsO4,1,10-phenanthroline (DNA-Os,phen) but it does not cross-react with oxidized DNA and with DNA adducts of osmium tetroxide complexes with other ligands (such as pyridine, TEMED and bathophenanthroline disulfonic acid). The affinity of OsBP7H8 to DNA-Os,phen is about five-fold higher as compared to DNA-Os,bipy. The antibody can be thus applied either for recognition of single-stranded and distorted regions in DNA (after DNA modification with Os,bipy) or for detection of both single-stranded and double-stranded DNAs (after DNA modification with Os,phen). A new simplified procedure for the dot-blot analysis is proposed, not requiring the purification of DNA-osmium adduct prior to its application to the membrane.     

A specific and efficient photoreaction between E. coli RNA polymerase and T+1 in the lacUV5 or deoP1 promoter.

Upon irradiation of the RNA polymerase-lacUV5 or deoP1 promoter complex with short wavelength ultraviolet light (lambda less than or equal to 300 nm) the polymerase is covalently crosslinked at an efficiency of greater than 10% to the first transcribed base of the template DNA strand when this is a thymine. The temperature dependence of this RNA polymerase-T+1 photoreaction strongly indicates a relation to the formation of the open complex. It is suggested that open complex formation is preceded or accompanied by a specific contact between the RNA polymerase and the first transcribed base of the DNA template.