Strand opening-deficient Escherichia coli RNA polymerase facilitates investigation of closed complexes with promoter DNA: effects of DNA sequence and temperature

Formation of the strand-separated, open complex between RNA polymerase and a promoter involves several intermediates, the first being the closed complex in which the DNA is fully base-paired. This normally short lived complex has been difficult to study. We have used a mutant Escherichia coli RNA polymerase, deficient in promoter DNA melting, and variants of the P(R) promoter of bacteriophage lambda to model the closed complex intermediate at physiologically relevant temperatures. Our results indicate that in the closed complex, RNA polymerase recognizes base pairs as double-stranded DNA even in the region that becomes single-stranded in the open complex. Additionally, a particular base pair in the -35 region engages in an important interaction with the RNA polymerase, and a DNase I-hypersensitive site, pronounced in the promoter DNA of the open complex, was not present. The effect of temperature on closed complex formation was found to be small over the temperature range from 15 to 37 degrees C. This suggests that low temperature complexes of wild type RNA polymerase and promoter DNA may adequately model the closed complex.     

Regulation of open complex formation at the Escherichia coli galactose operon promoters. Simultaneous interaction of RNA polymerase, gal repressor and CAP/cAMP.

The regulation of open complex formation at the Escherichia coli galactose operon promoters by galactose repressor and catabolite activator protein/cyclic AMP (CAP/cAMP) was investigated in DNA-binding and kinetic experiments performed in vitro. We found that gal repressor and CAP/cAMP bind to the gal regulatory region independently, resulting in simultaneous occupancy of the two gal operators and the CAP/cAMP binding site. Both CAP/cAMP and gal repressor altered the partitioning of RNA polymerase between the two overlapping gal promoters. Open complexes formed in the absence of added regulatory proteins were partitioned between gal P1 and P2 with occupancies of 25% and 75%, respectively. CAP/cAMP caused open complexes to be formed nearly exclusively at P1 (98% occupancy). gal repressor caused a co-ordinated, but incomplete, switch in promoter partitioning from P1 to P2 in both the absence and presence of CAP/cAMP. We measured the kinetic constants governing open complex formation and decay at the gal promoters in the absence and presence of gal repressor and CAP/cAMP. CAP/cAMP had the largest effect on the kinetics of open complex formation, resulting in a 30-fold increase in the apparent binding constant. We conclude that the regulation of open complex formation at the gal promoters does not result from competition between gal repressor, CAP/cAMP and RNA polymerase for binding at the gal operon regulatory region, but instead results from the interactions of the three proteins during the formation of a nucleoprotein complex on the gal DNA fragment. Finally, we present a kinetic model for the regulation of open complex formation at the gal operon.     

The interaction of RNA polymerase and lac repressor with the lac control region.

We have examined the interactions of lac repressor and RNA polymerase with the DNA of the lac control region, using a method for direct visualization of the regions of DNA protected by proteins from DNAase attack. The repressor protects the operator essentially as reported by Gilbert and Maxam (1) with some small modifications. However, the evidence reported here concerning the binding of RNA polymerase to the DNA of the promoter mutant UV5 indicates that : 1) the RNA polymerase molecule binds asymmetrically to the promoter DNA, 2) RNA polymerase protects DNA sequences to within a few bases of the CAP binding site, suggesting direct interaction between polymerase and the CAP protein at this site, 3) RNA polymerase still binds to the promoter when repressor is bound to the operator, but fails to form the same extensive complex.     

A gel electrophoresis method for quantifying the binding of proteins to specific DNA regions: application to components of the Escherichia coli lactose operon regulatory system.

The use of gel electrophoresis for quantitative studies of DNA-protein interactions is described. This rapid and simple technique involves separation of free DNA from DNA-protein complexes based on differences in their electrophoretic mobilities in polyacrylamide gels. Under favorable conditions both unbound DNA and DNA associated with protein can be quantified. This gel method is applied to the study of the E. coli lactose operon regulatory system. At ionic strengths in the physiological range, the catabolite activator protein (CAP) is shown to form a long-lived complex with the wild type lac promotor, but not with a CAP-insensitive mutant. Formation of a stable "open" or "melted-in" complex of RNA polymerase with the wild type promoter requires the participation of CAP and cyclic AMP. Further, it is demonstrated that even when pre-formed in the presence of CAP-cAMP, the polymerase-promoter open complex becomes unstable if CAP is then selectively removed.     

The intercalating beta-hairpin of T7 RNA polymerase plays a role in promoter DNA melting and in stabilizing the melted DNA for efficient RNA synthesis

Phage T7 RNA polymerase contains within its single polypeptide all the elements for specific recognition and melting of its promoter DNA. Crystallographic studies indicate that a beta-hairpin (230-245) with an intercalating valine residue plays a role in promoter opening. We mutated V237 to several amino acids, deleted five amino acid residues at the tip of the hairpin, and mutated E242 and D240 at the base of the hairpin to define the roles of the tip and base of the hairpin in DNA strand separation. The affinity of the hairpin mutants for the promoter DNA was not significantly affected. Stopped-flow kinetic studies showed that the bimolecular rate of DNA binding and the observed rate of pre-initiation open complex formation that corresponds to the sum of DNA opening and closing steps were within 20 to 40 % of the wild-type polymerase. Yet, most mutants showed a smaller amount of the pre-initiation open complex at equilibrium, indicating that the individual rates of promoter opening and closing steps were altered in the mutants. The base mutants, E242A and D240A, showed both a lower rate of promoter opening and a higher rate of promoter closing, suggesting their role in stabilization of the open complex. The V237D and the deletion mutant showed mainly a lower rate of promoter opening, suggesting that the tip of the hairpin may nucleate DNA opening. The defect in pre-initiation open complex formation affected downstream steps such as the rate of the first phosphodiester bond formation step, but did not affect significantly the apparent K(d) of initiating GTPs. We propose that D240 and E242 anchor the hairpin to the DNA and position the tip of the hairpin to allow V237 to intercalate and distort the DNA during open complex formation. The interactions of E242 and D240 with the upstream junction of the melted dsDNA promoter also align the template strand within the active site for efficient RNA synthesis.