Factor-independent activation of Escherichia coli rRNA transcription. II. characterization of complexes of rrnB P1 promoters containing or lacking the upstream activator region with Escherichia coli RNA polymerase.

A region upstream from the Escherichia coli rrnB P1 promoter, the upstream activator region (UAR), increases the activity of the promoter in vivo and the rate of association with RNA polymerase (E sigma 70) in vitro in the presence of the two initiating nucleotides. We have used four types of chemical and enzymatic footprinting probes to determine whether rrnB P1-E sigma 70 complexes formed in the presence of the initiating nucleotides (RPinit) differ from typical open complexes (RPo) formed in the absence of the initiating nucleotides and to examine the structural differences between rrnB P1 complexes containing the UAR and those lacking the UAR. We find that the rrnB P1-RPinit complex closely resembles open complexes formed at other E sigma 70 promoters, indicating that the formation of the first phosphodiester bond does not result in a major rearrangement of the promoter-RNA polymerase complex. An unusual potassium permanganate modification at position -18 in both RPo and RPinit indicates the possible presence of a subtle difference in the -10, -35 spacer structure compared to some other E. coli promoters. We show that the E sigma 70-rrnB P1 complex formed with the promoter containing the UAR has DNase I and hydroxyl radical cleavage patterns in the -50 region different from those observed with the same promoter lacking the UAR. These results are interpreted to indicate that E sigma 70 may interact with a region further upstream from that contacted by RNA polymerase bound at most other promoters and/or that unusual structural properties of this region are induced by bound E sigma 70.     

Interaction between RNA polymerase and a ribosomal RNA promoter of E. coli.

The interaction between RNA polymerase and the E. coli ribosomal (r) RNA promoter(s) of the rrnE operon has been studied by the filter-binding method. The extent of complex formation between RNA polymerase and rrnE promoter(s) is salt-dependent; ppGpp specifically inhibits interaction of RNA polymerase with the rrnE promoter(s). A tentative model is proposed for the molecular events in the early steps of rRNA initiation: a transition of the primarily formed, labile RNA polymerase-rRNA promoter complex to a more stable form is the determining step. This step is salt-sensitive; ppGpp acts on this "isomerization".     

How Escherichia coli RNA polymerase can negatively regulate transcription from a constitutive promoter

We previously described the structures and functions of specific complexes between the bla promoter from Tn3 (present in pBR322) and RNA polymerase (RNAP), showing that, at excess RNAP, complexes can form in which one or two RNAPs bind to the same promoter (1:1 and 2:1 complexes) (Duval-Valentin and Ehrlich, 1988). We report here that the 2:1 complex cannot be detected below 25 degrees C; above that temperature, a 1:1 complex forms at a rate one order of magnitude faster than that of the 2:1 complex, and above 30 degrees C, the amounts of both species become equal for RNAP/promoter ratio r30 less than or equal to r less than or equal to 70. The 2:1 complex decays back to a 1:1 complex losing the last RNAP at a rate about three times that of the 1:1 complex decay. Functional assays of the complexes formed at excess RNAP show that both 1:1 and 2:1 complexes are immediately and permanently inhibited, even when the promoters are pre-incubated with ribonucleotide selections potentially enabling entrance into abortive cycling or formation of a stressed complex. We conclude that the inhibition step probably takes place in the complex formation pathway between RPi and RPo, at a novel stable intermediate isomer, RPj, formed above 25 degrees C. A possible mechanism of formation of the 2:1 complex is outlined. In vivo studies, in which r was modified by varying the bacterial growth rate, show a reduction of bla expression as r values are upshifted, specific to the bla promoter from Tn3.