Low concentrations of free hydrophobic amino acids disrupt the Escherichia coli RNA polymerase core-sigma(70) protein-protein interaction.

Studies of the Escherichia coli RNA polymerase subunit sigma-70 employing limited proteolytic digestion and binding by monoclonal antibodies indicate that conserved region 3 is solvent accessible in the free protein and in the RNA polymerase holoenzyme. Conversely, when sigma-70 binds to core RNA polymerase, proteolytic cleavage of region 3 is dramatically reduced. The former set of results seems to indicate the physical presence of region 3 on or near the surface of the holoenzyme while the latter of these results suggest that region 3 is sequestered in a direct protein-protein contact within the RNA holoenzyme which alters its protease sensitivity. To further investigate these possibilities we inserted an internal histidine-tag within region 3 of sigma(70) (sigma(70)-R3-His6) between amino acids 508 and 509. Confirmation that the internal His-tag insertion does not disrupt normal sigma(70) function was verified by genetic complementation. His-tagged protein was immobilized on nickel-agarose and core RNAP was tethered via the sigma-core interaction. Our results are consistent with the localization of region 3 on or near the surface both of free sigma(70) and of RNA polymerase holoenzyme. Furthermore, we find that the sigma(70)-core interaction is resistant to high ionic conditions but is completely disrupted by the presence of the low-molecular-weight hydrophobic amino acids phenylalanine and leucine free in solution. These results demonstrate the general usefulness of this approach to the disruption of protein-protein interactions and its potential application for protein purification.     

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.     

Sigma factors from E. coli, B. subtilis, phage SP01, and phage T4 are homologous proteins.

We show, using dot matrix comparisons and statistical analysis of sequence alignments, that seven sequenced sigma factors, E. coli sigma-70 and sigma-32, B. subtilis sigma-43 and sigma-29, phage SP01 gene products 28 and 34, and phage T4 gene product 55, comprise a homologous family of proteins. Sigma-70, sigma-32, and sigma-43 each have two copies of a sequence similar to the helix-turn-helix DNA binding motif seen in CRP, and lambda repressor and cro proteins. B. subtilis sigma-29, SP01 gp28, and SP01 gp34 have at least one copy similar to this sequence. We propose that a second sequence, conserved in all seven proteins is the core RNA polymerase binding site. A third region, present only in sigma-70 and sigma-43, may also be involved in interaction with core. Available mutational evidence supports our model for sigma factor structure.     

The effect of metyrapone on the 17,20-lyase from rat testis microsomes

A new and simple method was presented to isolate purified holoenzyme of $\text{E. coli}$ RNA polymerase. When a purified enzyme preparation was chromatographed on a DNA-cellulose column equilibrated with a buffer containing 10mM MgCl₂, holoenzyme was separated from core enzyme. Thus holoenzyme was eluted at 0.15M KCl and core enzyme at 0.25M KCl.     

A mammalian DNA polymerase alpha holoenzyme functioning on defined in vivo-like templates.

In analogy to the Escherichia coli replicative DNA polymerase III we define two forms of DNA polymerase alpha: the core enzyme and the holoenzyme. The core enzyme is not able to elongate efficiently primed single-stranded DNA templates, in contrast to the holoenzyme which functions well on in vivo-like template. Using these criteria, we have identified and partially purified DNA polymerase alpha holoenzyme from calf thymus and have compared it to the corresponding homogeneous DNA polymerase alpha (defined as the core enzyme) from the same tissue. The holoenzyme is able to use single-stranded parvoviral DNA and M13 DNA with a single RNA primer as template. The core enzyme, on the other hand, although active on DNAs treated with deoxyribonuclease to create random gaps, is unable to act on these two long, single-stranded DNAs. E. coli DNA polymerase III holoenzyme also copies the two in vivo-like templates, while the core enzyme is virtually inactive. The homologous single-stranded DNA-binding proteins from calf thymus and from E. coli stimulate the respective holoenzymes and inhibit the core enzymes. These results suggest a cooperation between a DNA polymerase holoenzyme and its homologous single-stranded DNA-binding protein. The prokaryotic and the mammalian holoenzyme behave similarly in several chromatographic systems.     

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.     

Competition for the DNA template between RNA polymerase molecules from normal and phage-infected E. coli

Summary Preincubation of E. coli core RNA polymerase lacking sigma-factor with limiting amounts of T2-DNA markedly decreases subsequent synthesis of RNA by RNA polymerase holoenzyme. Hence, although the core binds to DNA more weakly than does the holoenzyme, it can actively compete with RNA polymerase for the DNA template.Both core RNA polymerase and holoenzyme from uninfected bacteria are effective in competition with RNA polymerase isolated from T2-infected cells. On the other hand the enzyme obtained from T2-infected cells compete weakly with RNA polymerase from E. coli. The incubation of bacterial core-enzyme with a supernatant protein fraction obtained from phage-infected bacteria lowers its ability to compete with normal RNA polymerase for DNA template.These results are discussed from the viewpoint that in certain cases the RNA polymerase itself can act as a kind of repressor, effecting negative regulation of RNA synthesis. The modification of core and formation of anti-sigma induced by bacteriophage could participate in such kind of regulation.     

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.     

Inhibition of RNA polymerase from Bacillus thuringiensis and Escherichia coli by beta-exotoxin.

The characteristics of exotoxin inhibition of deoxyribonucleic acid (DNA) dependent ribonucleic acid (RNA) polymerase isolated from Escherichia coli and Bacillus thuringiensis were investigated. RNA polymerase isolated from a variety of growth stages was partially purified and assayed using several different native and synthetic DNA templates, and exotoxin inhibition patterns were recorded for each. Although 8 to 20-h RNA polymerase extracts of E. coli retained normal sensitivity to exotoxin (50% inhibition at a concentration of 7.5 X 10(-6) M exotoxin), RNA polymerase isolated from late exponential and ensuing stationary-phase cultures of B. thuringiensis were nearly 50% less sensitive than exponential RNA polymerase activity. Inhibition patterns relating culture age at the time of RNA polymerase extraction to exotoxin inhibition suggested a direct correlation between diminishing exotoxin sensitivity and sporulation. Escherichia coli RNA polymerase could be made to mimic the B. thuringiensis exotoxin inhibition pattern by removal of sigma from the holoenzyme. After passage through phosphocellulose, exotoxin inhibition of the core polymerase was 30% less than the corresponding inhibition of E. coli holoenzyme. Heterologous enzyme reconstruction and assay were not possible due to loss of activity from the B. thuringiensis preparation during phosphocellulose chromatography, apparently from the removal of magnesium. In enzyme velocity studies, inhibition with exotoxin was noncompetitive with respect to the DNA template in the RNA polymerase reaction.