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.     

Mapping protein-protein interactions with a library of tethered cutting reagents: the binding site of sigma 70 on Escherichia coli RNA polymerase

Surface-exposed lysine amino groups and other reactive nucleophiles of the sigma 70 protein were conjugated with the cutting reagent iron (S)-1-[p-(bromoacetamido)benzyl]ethylenediaminetetraacetate (FeBABE) via 2-iminothiolane (2IT) with low efficiency. The result is a library of sigma 70 conjugates, with an average of 1-2 cutting reagents tethered to any of a variety of sites (lysine, cysteine, etc.) on the surface of the protein. Model calculations indicate that the conjugates in this library should be capable of cutting nearby sites on the backbone of almost any protein or nucleic acid to which sigma 70 binds. Since cutting occurs only when the protein is bound, the cleaved sites indicate proximity; since only proximal sites are cleaved, interpretation of the results is straightforward. We used this library to map the periphery of the binding site on the core enzyme (alpha 2 beta beta') of Escherichia coli RNA polymerase. The beta subunit was cut primarily within its conserved regions C, D, Rif I, and G; additional sites were also cut between A and B and near conserved regions E and H. The cut sites within the beta' subunit were intensely clustered between residues 250-450, which include its conserved regions C and D, along with two additional cut sites in conserved regions A and G. No cut sites on the alpha subunit were observed. These results recapitulate and extend those obtained using FeBABE conjugates of seven strategically placed single-Cys sigma 70 mutants [Owens, J. T., Miyake, R., Murakami, K., Chmura, A. J., Fujita, N., Ishihama, A., and Meares, C. F. (1998) Proc. Natl. Acad. Sci. U.S.A. 95, 6021-6026]. This technique provides a straightforward, general approach to mapping protein interactions without mutagenesis.     

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.     

Affinity purification of the tobacco plastid RNA polymerase and in vitro reconstitution of the holoenzyme

We affinity-purified the tobacco plastid-encoded plastid RNA polymerase (PEP) complex by the alpha subunit containing a C-terminal 12 x histidine tag using heparin and Ni(2+) chromatography. The composition of the complex was determined by mass spectrometry after separating the proteins of the >900 kDa complex in blue native and SDS polyacrylamide gels. The purified PEP contained the core alpha, beta, beta', beta" subunits and five major associated proteins of unknown function, but lacked sigma factors required for promoter recognition. The holoenzyme efficiently recognized a plastid psbA promoter when it was reconstituted from the purified PEP and recombinant plastid sigma factors. Reconstitution of a plastid holoenzyme with individual sigma factors will facilitate identification of sigma factor-specific promoter elements.     

Inhibitory effect of phosphate on in vitro development of 2-cell rat embryos is overcome by a factor(s) in oviductal extracts

The promoter recognition site on the sigma70 initiation factor is shielded from interaction with DNA unless sigma70 is bound to the core component of RNA polymerase (RNAP). It is shown that interaction of sigma70 with the isolated beta' subunit of Escherichia coli RNAP is sufficient to induce unshielding of the DNA binding site. Using UV-induced DNA-protein cross-linking we demonstrate that free beta' stimulates specific cross-links between region 2 of the sigma70 polypeptide and a fragment of the non-template promoter strand containing the TATAAT sequence. Thus the sigmabeta' subassembly of RNAP can assume a functionally competent conformation independently of the bulk of the RNAP core.     

Core residue replacements cause coiled-coil orientation switching in vitro and in vivo: structure-function correlations for osmosensory transporter ProP

Protein ProP acts as an osmosensory transporter in diverse bacteria. C-Terminal residues 468-497 of Escherichia coli ProP (ProPEc) form a four-heptad homodimeric alpha-helical coiled coil. Arg 488, at a core heptad a position, causes it to assume an antiparallel orientation. Arg in the hydrophobic core of coiled coils is destabilizing, but Arg 488 forms stabilizing interstrand salt bridges with Asp 475 and Asp 478. Mutation R488I destabilizes the coiled coil and elevates the osmotic pressure at which ProPEc activates. It may switch the coiled-coil orientation to parallel by eliminating the salt bridges and increasing the hydrophobicity of the core. In this study, mutations D475A and D478A, which disrupt the salt bridges without increasing the hydrophobicity of the coiled-coil core, had the expected modest impacts on the osmotic activation of ProPEc. The five-heptad coiled coil of Agrobacterium tumefaciens ProP (ProPAt) has K498 and R505 at a positions. Mutation K498I had little effect on the osmotic activation of ProPAt, and ProPAt-R505I was activated only at high osmotic pressure; on the other hand, the double mutant was refractory to osmotic activation. Both a synthetic peptide corresponding to ProPAt residues 478-516 and its K498I variant maintained the antiparallel orientation. The single R505I substitution created an unstable coiled coil with little orientation preference. Double mutation K498I/R505I switched the alignment, creating a stable parallel coiled coil. In vivo cross-linking showed that the C-termini of ProPAt and ProPAt-K498I/R505I were antiparallel and parallel, respectively. Thus, the antiparallel orientation of the ProP coiled coil is contingent on Arg in the hydrophobic core and interchain salt bridges. Two key amino acid replacements can convert it to a stable parallel structure, in vitro and in vivo. An intermolecular antiparallel coiled coil, present on only some orthologues, lowers the osmotic pressure required to activate ProP. Formation of a parallel coiled coil renders ProP inactive.