Competition between sigma factors for core RNA polymerase.

The switch of RNA polymerase specificity from early to late promoters of bacteriophage T4 is achieved by substitution of host sigma factor, sigma 70, with the T4 induced factor, sigma gp55. However, overproduction of sigma gp55 from an expression vector is not detrimental to Escherichia coli growth. Direct competition binding assays demonstrate that sigma 70 readily displaces sigma gp55 from RNA polymerase and thereby reverses the promoter specificity of the enzyme. The displacement also occurs with the core enzyme modified by bacteriophage T4 infection. We postulate that an antagonist of sigma 70 should be formed in T4-infected cells to aid sigma gp55 in the early/late switch.     

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.     

Mapping protease susceptibility sites on the Escherichia coli transcription factor sigma70.

N-terminally and C-terminally histidine-tagged versions of Escherichia coli RNA polymerase initiation factor sigma70 were subjected to limited proteolysis and electrophoretic separation. The protein fragments were transferred to nitrocellulose, and biotinylated nitrilotriacetic acid was used to detect the His-tagged ladder that resulted. Using size markers of known lengths derived from chemical cleavage of the same His-tagged sigma70, we were able to map the sites of proteolysis for sigma70 free in solution, bound to core RNA polymerase, and in the Mg2+-dependent open complex with lambdaPR promoter DNA. Numerous sites of changed susceptibility were mapped. Most of these sites mapped near residues 100 and 500. In addition, the highly acidic region around residue 190 became susceptible to cleavage in the open promoter complex. These results suggest that sigma70 undergoes significant conformational changes upon binding to core RNA polymerase and upon open promoter complex formation.     

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.     

Mutational analysis of an extracytoplasmic-function sigma factor to investigate its interactions with RNA polymerase and DNA

The extracytoplasmic-function (ECF) family of sigma factors comprises a large group of proteins required for synthesis of a wide variety of extracytoplasmic products by bacteria. Residues important for core RNA polymerase (RNAP) binding, DNA melting, and promoter recognition have been identified in conserved regions 2 and 4.2 of primary sigma factors. Seventeen residues in region 2 and eight residues in region 4.2 of an ECF sigma factor, PvdS from Pseudomonas aeruginosa, were selected for alanine-scanning mutagenesis on the basis of sequence alignments with other sigma factors. Fourteen of the mutations in region 2 had a significant effect on protein function in an in vivo assay. Four proteins with alterations in regions 2.1 and 2.2 were purified as His-tagged fusions, and all showed a reduced affinity for core RNAP in vitro, consistent with a role in core binding. Region 2.3 and 2.4 mutant proteins retained the ability to bind core RNAP, but four mutants had reduced or no ability to cause core RNA polymerase to bind promoter DNA in a band-shift assay, identifying residues important for DNA binding. All mutations in region 4.2 reduced the activity of PvdS in vivo. Two of the region 4.2 mutant proteins were purified, and each showed a reduced ability to cause core RNA polymerase to bind to promoter DNA. The results show that some residues in PvdS have functions equivalent to those of corresponding residues in primary sigma factors; however, they also show that several residues not shared with primary sigma factors contribute to protein function.