Interaction of Escherichia coli RNA Polymerase with the Eukaryotic TATA-Binding Protein

Interaction with eukaryotic TATA-binding protein (TBP) was analyzed for natural Escherichia coli RNA polymerase or the recombinant holoenzyme, minimal enzyme, or its subunit. Upon preincubation of full-sized RNA polymerase with TBP and further incubation with a constant amount of a ³²P-labeled phosph-amide derivative of a TATA-containing oligodeoxyribonucleotide, the yield of the holoenzyme–oligonucleotide covalent complex decreased with increasing TBP concentration. This was considered as indirect evidence for complexing of RNA polymerase with TBP. In gel retardation assays, the holoenzyme, but neither the minimal enzyme nor the subunit, interacted with TPB, since the labeled probe formed complexes with both proteins in the reaction mixture combining TBP with the minimal enzyme or the subunit. It was assumed that E. coli RNA polymerase is functionally similar to eukaryotic RNA polymerase II, and that the complete ensemble of all subunits is essential for the specific function of the holoenzyme.     

GroEL is involved in activation of Escherichia coli RNA polymerase devoid of the omega subunit in vivo.

Highly purified Escherichia coli RNA polymerase contains a small subunit termed omega that has a molecular mass of 10 105 Da and is comprised of 91 amino acids. E. coli strains lacking omega (omega-less) are viable, but exhibit a slow-growth phenotype. Renaturation of RNA polymerase isolated from an omega-less mutant, in the presence of omega, resulted in maximum recovery of activity. The omega-less RNA polymerase from omega-less strains recruits the chaperonin, GroEL (unlike the wild-type enzyme), suggesting a structural deformity of the mutant enzyme. The GroEL-containing core RNA polymerase interacts efficiently with sigma70 to generate the fully functional holoenzyme. However, when GroEL was removed, the enzyme was irreversibly nonfunctional and was unable to bind to sigma70. The damaged enzyme regained activity after going through a cycle of denaturation and reconstitution in the presence of omega or GroEL. GroES was found to have an inhibitory effect on the core-sigma70 association unlike the omega subunit. The omega subunit may therefore be needed for stabilization of the structure of RNA polymerase.     

Subunit topography of RNA polymerase from Escherichia coli. A cross-linking study with bifunctional reagents.

The quaternary structures of Escherichia coli DNA-dependent RNA polymerase holenzyme (alpha 2 beta beta' sigma) and core enzyme (alpha 2 beta beta') have been investigated by chemical cross-linking with a cleavable bifunctional reagent, methyl 4-mercaptobutyrimidate, and noncleavable reagents, dimethyl suberimidate and N,N'-(1,4-phenylene)bismaleimide. A model of the subunit organization deduced from cross-linked subunit neighbors identified by dodecyl sulfate-polyacrylamide gel electrophoresis indicates that the large beta and beta' subunits constitute the backbone of both core and holoenzyme, while sigma and two alpha subunits interact with this structure along the contact domain of beta and beta' subunits. In holoenzyme, sigma subunit is in the vicinity of at least one alpha subunit. The two alpha subunits are close to each other in holoenzyme, core enzyme, and the isolated alpha 2 beta complex. Cross-linking of the "premature" core and holoenzyme intermediates in the in vitro reconstitution of active enzyme from isolated subunits suggests that these species are composed of subunit complexes of molecular weight lower than that of native core and holoenzyme, respectively. The structural information obtained for RNA polymerase and its subcomplexes has important implications for the enzyme-promoter recognition as well as the mechanism of subunit assembly of the enzyme.     

Purification and characterization of the DNA-dependent RNA polymerase and its subunit sigma from Micrococcus luteus

DNA-dependent RNA polymerase from Micrococcus luteus can be isolated from cell extracts after removal of an excess of nucleic acids by fractionation with ammonium sulfate, followed by two consecutive gel filtrations through agarose and chromatography on cellulose phospate. Either homogeneous holoenzyme or a mixture of core and holoenzyme is obtained in this way, as is indicated by electrophoresis in polyacrylamide gels in the absence of detergent, where core enzyme migrates ahead of holoenzyme. Homogeneous core enzyme can be isolated from holoenzyme by chromatography on DEAE-cellulose. Core enzyme contains the subunits alpha, beta and beta' previously described [U.I. Lill et al., (1975) Eur. J. Biochem. 52, 411-420] in a molar ratio of 2:1:1. Holoenzyme contains an additional subunit sigma of 80 000 molecular weight (molar subunit composition alpha2 betabeta' sigma) and two relatively small polypeptides (molecular weight 14 000 and 25 000, respectively). Subunit sigma may be isolated from holoenzyme by chromatography on DEAE-cellulose at pH 6.9 in the presence of low concentrations of glycerol. The behaviour of holoenzyme during sedimentation in a glycerol gradient at low ionic strength indicates its occurrence as a dimer of the alpha2betabeta'sigma-protomer, whereas the monomeric form is preferred by core enzyme. Holoenzyme is much more active than core enzyme in RNA synthesis on bacteriophage T4DNA as template. The activity of the latter is stimulated by isolated sigma. M. luteus sigma as well as holoenzyme enhances also the activity of core enzyme fro- Escherichia coli. The formation of a hybrid between micrococcal sigma and E. coli core polymerase is also suggested by the influence of sigma on the oligomerisation of the enzyme from E. coli.     

Differences in Contacts of RNA Polymerases from <Emphasis Type="Italic">Escherichia coli</Emphasis> and <Emphasis Type="Italic">Thermus aquaticus</Emphasis> with <Emphasis Type="Italic">lac</Emphasis>UV5 Promoter Are Determined by Core-Enzyme of RNA Polymerase

The interaction of RNA polymerases from Escherichia coli and Thermus aquaticus with lacUV5 promoter was studied at various temperatures. Using DNA-protein cross-linking induced by formaldehyde, it was demonstrated that each RNA polymerase formed a unique pattern of contacts with DNA in the open promoter complex. In the case of E. coli RNA polymerase, beta and sigma subunits were involved into formation of cross-links with the promoter, whereas in the case of T. aquaticus RNA polymerase its beta subunit formed the cross-links with the promoter. A cross-linking pattern in promoter complexes of a hybrid holoenzyme comprised of the core-enzyme of E. coli and sigma subunit of T. aquaticus was similar to that of the E. coli holoenzyme. This suggests that DNA-protein contacts in the promoter complex are primarily determined by the core-enzyme of RNA polymerase. However, temperature-dependent behavior of contact formation is determined by the sigma subunit. Results of the present study indicate that the method of formaldehyde cross-linking can be employed for elucidation of differences in the structure of promoter complexes of RNA polymerases from various bacteria.     

A new protein subunit k for RNA polymerase from Xanthomonas campestris pv. oryzae

During the purification of RNA polymerase from Xanthomonas campestris pv. oryzae, a new subunit named k was found to be associated with this enzyme. The removal of subunit k from holoenzyme by DEAE-cellulose column chromatography results in a decrease in specific activity of the enzyme. The readdition of subunit k to subunit k-depleted holoenzyme results in restoration of enzymatic activity. Subunit k increase the activity of RNA polymerase; the activation was in proportion to the concentration of subunit k added. Antiserum against holoenzyme devoid of subunit k was prepared. This antiserum did not react with purified subunit k; therefore, subunit k may not be the proteolytic fragment of the beta, beta', sigma, or alpha subunit. When this antiserum was used to precipitate RNA polymerase obtained from a crude extract of bacterial cells, subunit k was coprecipitated as determined by sodium dodecyl sulfate gel electrophoretic analysis. The molecular mass of subunit k is approximately 29 kDa, and the molar ratio of beta:beta':sigma:alpha:k was estimated to be 1:1:1:2:4. When native Xp10 DNA was used as template, subunit k stimulated subunit k-depleted holoenzyme, but not core enzyme. When the synthetic polynucleotide poly[d(A-T)] was used, subunit k activated both subunit k-depleted holoenzyme and core enzyme. Subunit k also activated the binding of RNA polymerase to template DNA.     

Specific recognition of the -10 promoter element by the free RNA polymerase sigma subunit

Bacterial RNA polymerase holoenzyme relies on its sigma subunit for promoter recognition and opening. In the holoenzyme, regions 2 and 4 of the sigma subunit are positioned at an optimal distance to allow specific recognition of the -10 and -35 promoter elements, respectively. In free sigma, the promoter binding regions are positioned closer to each other and are masked for interactions with the promoter, with sigma region 1 playing a role in the masking. To analyze the DNA-binding properties of the free sigma, we selected single-stranded DNA aptamers that are specific to primary sigma subunits from several bacterial species, including Escherichia coli and Thermus aquaticus. The aptamers share a consensus motif, TGTAGAAT, that is similar to the extended -10 promoter. We demonstrate that recognition of this motif by sigma region 2 occurs without major structural rearrangements of sigma observed upon the holoenzyme formation and is not inhibited by sigma regions 1 and 4. Thus, the complex process of the -10 element recognition by RNA polymerase holoenzyme can be reduced to a simple system consisting of an isolated sigma subunit and a short aptamer oligonucleotide.     

Separation of Escherichia coli RNA polymerase sigma-70 holoenzyme from core enzyme on heparin-Sepharose columns

A method is described for the rapid purification of DNA-dependent RNA polymerase sigma-70 holoenzyme from Escherichia coli. The essential step in this protocol involves the differential elution of sigma-70 holoenzyme from core polymerase on a heparin-Sepharose column. Using a linear gradient of KCl, holoenzyme was found to elute at 0.25 M whereas core polymerase eluted at 0.35 M. From 20 g of cells, up to 1 mg of RNA polymerase holoenzyme could be isolated in two days. The preparations were greater than 95% pure with respect to protein, and saturated with the sigma subunit.     

Use of Mono Q high-resolution ion-exchange chromatography to obtain highly pure and active Escherichia coli RNA polymerase

A method for the purification of highly pure and active Escherichia coli RNA polymerase holoenzyme is described. This method is simple, reproducible, and can be performed at room temperature. The procedure involves the high-performance liquid chromatography of a partially purified RNA polymerase sample on a Mono Q ion-exchange column. Under the conditions used, RNA polymerase holoenzyme is well separated from the core RNA polymerase and other impurities. The purified RNA polymerase contains virtually no impurities as judged by SDS-polyacrylamide gel electrophoresis. The purified RNA polymerase holoenzyme contains the sigma 70 subunit in stoichiometric amounts and is at least 90% active.     

Escherichia coli RNA polymerase core and holoenzyme structures

Multisubunit RNA polymerase is an essential enzyme for regulated gene expression. Here we report two Escherichia coli RNA polymerase structures: an 11.0 A structure of the core RNA polymerase and a 9.5 A structure of the sigma(70) holoenzyme. Both structures were obtained by cryo-electron microscopy and angular reconstitution. Core RNA polymerase exists in an open conformation. Extensive conformational changes occur between the core and the holoenzyme forms of the RNA polymerase, which are largely associated with movements in ss'. All common RNA polymerase subunits (alpha(2), ss, ss') could be localized in both structures, thus suggesting the position of sigma(70) in the holoenzyme.     

A noncycling activity assay for the omega subunit of Escherichia coli RNA polymerase.

We describe a new method for quantitatively assaying the omega subunit of Escherichia coli RNA polymerase. The assay is based on the ability of RNA polymerase holoenzyme to catalyze the continuous synthesis of the dinucleotide pApU on a poly[d(A-T)] . poly[d(A-T)] template when supplied with AMP and UTP as substrates. Core enzyme, lacking omega subunit, catalyzed this reaction at a rate less than 1% that of holoenzyme. The omega subunit was not released from the enzyme/DNA complex during dinucleotide synthesis. Using this assay, a titration of a fixed concentration of core enzyme was observed with increasing concentrations of added omega subunit. Below a 1:1 omega:core ratio the measured activity increased linearly with omega concentration, whereas above a 1:1 ratio the activity remained constant. An immediate application of the assay is in determining the concentration of active omega, or equivalently of active holoenzyme, in any RNA polymerase preparation.