Structural organization of bacterial RNA polymerase holoenzyme and the RNA polymerase-promoter open complex

We have used systematic fluorescence resonance energy transfer and distance-constrained docking to define the three-dimensional structures of bacterial RNA polymerase holoenzyme and the bacterial RNA polymerase-promoter open complex in solution. The structures provide a framework for understanding sigma(70)-(RNA polymerase core), sigma(70)-DNA, and sigma(70)-RNA interactions. The positions of sigma(70) regions 1.2, 2, 3, and 4 are similar in holoenzyme and open complex. In contrast, the position of sigma(70) region 1.1 differs dramatically in holoenzyme and open complex. In holoenzyme, region 1.1 is located within the active-center cleft, apparently serving as a "molecular mimic" of DNA, but, in open complex, region 1.1 is located outside the active center cleft. The approach described here should be applicable to the analysis of other nanometer-scale complexes.     

Intermediates in the formation of the open complex by RNA polymerase holoenzyme containing the sigma factor sigma 32 at the groE promoter

The interaction of E sigma 32 with the groE promoter at temperatures between 0 degrees C and 37 degrees C was studied using DNase I footprinting and dimethyl sulfate methylation. Three distinct complexes were observed. At 0 degrees C E sigma 32 fully protected sequences between -60 and -5 from DNase I digestion on the top (non-template) strand of the promoter. At 16 degrees C the majority of the E sigma 32 promoter complexes had a DNase I footprint almost identical with that seen at 37 degrees C, protecting the DNA from about -60 to +20; however, little DNA strand separation had occurred, and the changes in sensitivity of guanine residues to dimethyl sulfate methylation caused by E sigma 32 differed from those seen at 37 degrees C. DNA strand separation, and changes in the pattern of protections from and enhancements of methylation by dimethyl sulfate to those characteristic of the open complex, occurred at temperatures between 16 degrees C and 27 degrees C. It is plausible to assume that these temperature-dependent isomerizations are analogous to the time-dependent sequence of intermediates on the pathway to open complex formation at 37 degrees C. Therefore we propose that the formation of an open complex by E sigma 32 at the groE promoter involves three classes of steps: E sigma 32 initially binds to the promoter in a closed complex (RPC1) in which the enzyme interacts with a smaller region of the DNA than in the open complex. E sigma 32 then isomerizes to form a second closed complex (RPC2) in which the enzyme interacts with the same region of the DNA as in the open complex. Finally, a process of local DNA denaturation (strand opening) leads to formation of the open complex (RPO).     

RNA polymerase and an activator form discrete subcomplexes in a transcription initiation complex

Using high-resolution atomic force microscopy (AFM) we show that in a ternary complex of an activator protein, FIS, and RNA polymerase containing the sigma(70) specificity factor at the Escherichia coli tyrT promoter the polymerase and the activator form discrete, but connected, subcomplexes in close proximity. This is the first time that a ternary complex between an activator, a sigma(70) polymerase holoenzyme and promoter DNA has been visualised. Individually FIS and RNA polymerase wrap approximately 80 and 150 bp of promoter DNA, respectively. We suggest that the architecture of the ternary complex provides a general paradigm for the facilitation of direct, but weak, interactions between polymerase and an activator.     

Mammalian DNA polymerase alpha: a replication competent holoenzyme form from calf thymus.

A complex "replication competent" holoenzyme form of DNA polymerase alpha (RC-alpha) was purified 10,000 fold from calf thymus through the use of an assay employing primed single stranded circular DNA template. The RC-alpha form could partially replicate a double-stranded oligo(dT)-tailed linear DNA and could completely convert primed single-stranded circular DNA to its double stranded form. The RC-alpha was resolved by denaturing gel electrophoresis into at least 10 discrete polypeptide species ranging in apparent molecular mass from 200 to 47 kilodaltons; three of the bands (apparent Mr of 200, 118 and 63 kilodaltons) displayed DNA polymerase activity in denaturing gel activity assay. The isolation of RC-alpha required the use of absolutely fresh calf thymus, the inclusion of ATP and protease inhibitors throughout the purification procedure. Treatment of the RC-alpha with the neutralizing anti-DNA polymerase alpha monoclonal antibody SJK 132-20 (Tanaka et al. (1982), J. Biol. Chem. 257, 8386-8390) in nondenaturing conditions selected the complete set of 10 polypeptides, whereas treatment in denaturing conditions selected the 200 kilodalton catalytic DNA polymerase active polypeptide. The properties and the behaviour of the RC-alpha preparation following removal of specific polypeptides strongly suggested that the capacity of RC-alpha to extend and replicate long template requires the function of nonproteolysed form of the 200 kilodaltons catalytic DNA polymerase core and at least 6 other auxiliary polypeptides of, respectively, 98, 87, 63, 54, 49 and 47 kilodaltons.