On the binding of tRNA to Escherichia coli RNA polymerase.

The fixation of tRNA to Escherichia coli RNA polymerase has been investigated. Bound and free tRNA have been separated and quantified after filtration through cellulose nitrate filters, centrifugation or sucrose gradients or electrophoresis in polyacrylamide gels. We detect no differences between the fixation of E. coli fMet-tRNAfMet, Met-tRNAmMet or uncharged unfractionated tRNA to RNA polymerase. Tight complexes, with a long residence time, are formed between core enzyme and tRNA with a dissociation constant of less than 1 nM. Complexes exist between tRNA and both monomer and dimer forms of the core enzyme. In the monomer complex, one tRNA is bound per alpha 2 beta beta' unit, whereas in the dimer complex only 0.5 tRNA molecule is fixed per alpha 2 beta beta' unit. In contrast to the core enzyme, very little tRNA fixes tightly to the holoenzyme at salt concentrations greater than 80 mM. At lower salt concentrations tRNA fixation results in a loss of sigma subunit from the holo enzyme to the resulting core enzyme where it binds tightly. DNA fixation reduces the binding of tRNA to RNA polymerase and tRNA fixation reduces the binding of DNA. However, binding of DNA to polymerase is not competitive with binding of tRNA, and ternary complexes between RNA polymerase, DNA and tRNA are shown to exist. Our results are discussed in relation to other studies concerning the effects of tRNA upon RNA polymerase.     

DNA strand specificity in promoter recognition by RNA polymerase.

DNA strand and enzyme subunit specificities involved in the interaction between E. coli RNA polymerase and T7 DNA were studied by photo-crosslinking techniques. In non-specific enzyme-DNA complexes, subunits, sigma, beta, and beta' were crosslinked to both strands of the DNA. Under conditions leading to specific enzyme-promoter complexes, however, only sigma and beta subunits were crosslinked. The sigma subunit was crosslinked preferentially to the non-sense strand at promoter sites. No such strand specificity was observed for the beta subunit. These results provide insight into the molecular mechanism of promoter recognition and indicate that the interaction between RNA polymerase and DNA template is different at promoters and at non-specific sites.     

UV cross-linking of the Bacillus subtilis RNA polymerase to DNA in promoter and non-promoter complexes

Complexes between Bacillus subtilus RNA polymerase and 32P-labeled DNA were irradiated with UV light and digested with nuclease; electrophoresis and autoradiography were used to identify the polymerase subunits cross-linked to DNA. These experiments showed: 1) that cross-linkage of promoter complexes yielded predominantly the beta and sigma subunits; 2) that beta, beta', and sigma were detected in non-promoter complexes; 3) that addition of the delta subunit or high concentrations of NaCl decreased cross-linkage of all subunits, especially the cross-linkage of the sigma subunit in non-promoter complexes and the binding of polymerase at DNA ends; 4) that different patterns of cross-linkage were obtained at 0 degrees C (conditions favoring the formation of closed complexes) and 37 degrees C (conditions favoring the formation of open complexes); and 5) predominantly beta and possibly alpha were cross-linked by irradiation of core-DNA complexes whereas similar experiments with core-delta complexed to DNA showed the efficient cross-linkage of beta' and beta.     

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.     

Antibodies against the subunits of E. coli RNA polymerase as probes for subunit-specific binding of DNA and other ligands.

Antibodies against the isolated subunits alpha, beta, and beta' of DNA-dependent RNA polymerase from E. coli have been prepared. They have been used to compare the extent of antibody-binding, as measured by complement fixation, to the isolated subunits and to the intact enzyme, in the absence and presence of ligands, such as inhibitors, nucleotides, nucleosides, oligo- and poly-nucleotides, and DNA of different composition. In many cases the results show a subunit-specific dependence of complement fixation upon the presence of a ligand and suggest a functional topography of the interaction between the subunits alpha, beta, and beta' of RNA polymerase and defined nucleotide sequences and small ligands.     

Escherichia coli RNA polymerase subunit omega and its N-terminal domain bind full-length beta' to facilitate incorporation into the alpha2beta subassembly.

The omega subunit of Escherichia coli RNA polymerase, consisting of 90 amino acids, is present in stoichiometric amounts per molecule of core RNA polymerase (alpha2betabeta'). The presence of omega is necessary to restore denatured RNA polymerase in vitro to its fully functional form, and, in an omega-less strain of E. coli, GroEL appears to substitute for omega in the maturation of RNA polymerase. The X-ray structure of Thermus aquaticus core RNA polymerase suggests that two regions of omega latch on to beta' at its N-terminus and C-terminus. We show here that omega binds only the intact beta' subunit and not the beta' N-terminal domain or beta' C-terminal domain, implying that omega binding requires both these regions of beta'. We further show that omega can prevent the aggregation of beta' during its renaturation in vitro and that a V8-protease-resistant 52-amino-acid-long N-terminal domain of omega is sufficient for binding and renaturation of beta'. CD and functional assays show that this N-terminal fragment retains the structure of native omega and is able to enhance the reconstitution of core RNA polymerase. Reconstitution of core RNA polymerase from its individual subunits proceeds according to the steps alpha + alpha --> alpha2 + beta --> alpha2beta + beta' --> alpha2betabeta'. It is shown here that omega participates during the last stage of enzyme assembly when beta' associates with the alpha2beta subassembly.     

Preparation and characterization of various Escherichia coli RNA polymerases containing one or two intrinsic metal ions

The Escherichia coli DNA-dependent RNA polymerase (RPase) holoenzyme (alpha 2 beta beta' sigma) possesses 2 mol equiv of Zn: beta and beta' subunits each contain one Zn ion. An in vitro metal-substitution method developed earlier (method I) was used to remove the two intrinsic Zn ions and then to reconstitute other metal ions into the beta subunit of RPase. One Cd or Hg ion was successfully reconstituted into half-active enzymes (rec-Cd1- or rec-Hg1-RPase), while Mn or Ni ion was not incorporated. A new, simplified in vitro metal-substitution method (method II), which omitted the low-pH treatment and subsequent urea dialysis in method I, was devised in this study. Consequently, Zn or Cd could be incorporated into both the beta and beta' subunits, resulting in rec-Zn2- or rec-Cd2-RPase, respectively. However, only one Hg was incorporated, probably due to steric hindrance by the large size of the Hg ion, while Mn, Ni, or Cr was not bound by the reconstituted enzyme, which instead incorporated only one Zn. Analysis of the metal content of various reconstituted RPases indicated that without low-pH treatment Zn bound to both the beta and beta' subunits when Zn concentrations were higher than 2 X 10(-6)M, but it bound only to the beta' subunit at lower concentrations. Moreover, low-pH treatment destroys the metal binding site in the beta' subunit. The metal sites on the beta and beta' subunits did not have significant affinity for the transition metals such as Mn, Ni, and Cr.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

A peptide from Tetrahymena disrupts subunit organization of E. coli RNA polymerase.

Incubation of the E. coli RNA polymerase with a polypeptide factor from the protozoan Tetrahymena reduces the affinity of the holoenzyme for DNA. SDS-polyacrylamide gel electrophoresis of the peptide-treated RNA polymerase showed that the band pattern of the polymerase subunits was strongly altered. The three large subunits, beta', beta and sigma, disappear and a high number of rapidly migrating bands appeared. However, a brief heat treatment of the samples almost restored the original RNA polymerase subunit composition, and in addition a high molecular weight protein band approximately 240 kDa appeared. It is suggested that the Tetrahymena peptide specifically binds to the RNA polymerase and changes the structures of the large subunits.     

Subunit assembly and metabolic stability of E. coli RNA polymerase

Immunological cross-reaction was employed for identification of proteolytic fragments of E. coli RNA polymerase generated both in vitro and in vivo. Several species of partially denatured but assembled RNA polymerase were isolated, which were composed of fragments of the two large subunits, beta and beta', and the two small and intact subunits, alpha and sigma. Comparison of the rate and pathway of proteolytic cleavage in vitro of unassembled subunits, subassemblies, and intact enzymes indicated that the susceptibility of RNA polymerase subunits to proteolytic degradation was dependent on the assembly state. Using this method, degradation in vivo was found for some, but not all, of the amber fragments of beta subunit in merodiploid cells carrying both wild-type and mutant rpoB genes. Although the RNA polymerase is a metabolically stable component in exponentially growing cells of E. coli, degradation of the full-sized subunits was found in two cases, i.e., several temperature-sensitive E. coli mutants with a defect in the assembly of RNA polymerase and the stationary-phase cells of a wild-type E. coli. The in vivo degradation of RNA polymerase was indicated to be initiated by alteration of the enzyme structure.     

Purification and partial characterization of the DNA-dependent RNA polymerase from Rickettsia prowazekii

The DNA-dependent RNA polymerase was purified from Rickettsia prowazekii, an obligate intracellular bacterial parasite. Because of limitation of available rickettsiae, the classical methods for isolation of the enzyme from other procaryotes were modified to purify RNA polymerase from small quantities of cells (25 mg of protein). The subunit composition of the rickettsial RNA polymerase was typical of a eubacterial RNA polymerase. R. prowazekii had beta' (148,000 daltons), beta (142,000 daltons), sigma (85,000 daltons), and alpha (34,500 daltons) subunits as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The appropriate subunits of the rickettsial RNA polymerase bound to polyclonal antisera against Escherichia coli core polymerase and E. coli sigma 70 subunit in Western blots (immunoblots). The enzyme activity was dependent on all four ribonucleoside triphosphates, Mg2+, and a DNA template. Optimal activity occurred in the presence of 10 mM MgCl2 and 50 mM NaCl. Interestingly, in striking contrast to E. coli, approximately 74% of the rickettsial RNA polymerase activity was associated with the rickettsial cell membrane at a low salt concentration (50 mM NaCl) and dissociated from the membrane at a high salt concentration (600 mM NaCl).     

Laser crosslinking of E. coli RNA polymerase and T7 DNA.

The first photochemical crosslinking of a protein to a nucleic acid using laser excitation is reported. A single, 120 mJ, 20 ns pulse at 248 nm crosslinks about 10% of bound E. coli RNA polymerase to T7 DNA under the conditions studied. The crosslinking yield depends on mercaptoethanol concentration, and is a linear function of laser intensity. The protein subunits crosslinked to DNA are beta, beta' and sigma.     

Zinc is associated with the beta subunit of DNA-dependent RNA polymerase of Bacillus subtilis.

The Bacillus subtilis DNA-dependent RNA polymerase holoenzyme and core enzyme each contain approximately two atoms of zinc per molecule. When the dissociated subunits of the enzyme are passed through a blue dextran-Sepharose affinity column, only the beta subunit binds to the column. The total zinc content of the enzyme is tightly bound to the beta subunit. Dialysis studies suggest that the two zinc ions differ in the strength of their association with the beta subunit. The presence of zinc in beta is consistent with several other lines of evidence which indicate that this subunit is dirrectly involved in phosphodiester bond formation. The blue dextran-Sepharose column procedure should be useful in future studies of the dissociation and reassociation of the enzyme since the method is rapid and provides excellent recovery of the beta subunit as well as the alpha and beta' subunits of the RNA polymerase.     

Cloning and characterization of RNA polymerase core subunits of Chlamydia trachomatis by using the polymerase chain reaction.

Taking advantage of sequence conservation of portions of the alpha, beta, and beta' subunits of RNA polymerase of bacteria and plant chloroplasts, we have designed degenerate oligonucleotides corresponding to these domains and used these synthetic DNA sequences as primers in a polymerase chain reaction to amplify DNA sequences from the chlamydial genome. The polymerase chain reaction products were used as a probe to recover the genomic fragments encoding the beta subunit and the 5' portion of the beta' subunit from a library of cloned murine Chlamydia trachomatis DNA. Similar attempts to recover the alpha subunit were unsuccessful. Sequence analysis demonstrated that the beta subunit of RNA polymerase was located between genes encoding the L7/L12 ribosomal protein and the beta' subunit of RNA polymerase; this organization is reminiscent of the rpoBC operon of Escherichia coli. The C. trachomatis beta subunit overproduced in E. coli was used as an antigen in rabbits to make a polyclonal antibody to this subunit. Although this polyclonal antibody specifically immunoprecipitated the beta subunit from Chlamydia-infected cells, it did not immunoprecipitate core or holoenzyme. Immunoblots with this antibody demonstrated that the beta subunit appeared early in infection.