RNA polymerase mutant with altered sigma factor in Escherichia coli.

Summary E. gracilis chloroplast DNA Bam fragments E and D, coding for rRNA were cloned separately using the plasmid pBR 322 as vector and E. coli as host. The newly constructed recombinant plasmids EgcKS 8 and EgcKS 11 (containing the Bam HI fragments E and D respectively) were analysed and characterized by gel electrophoresis, electronmicroscopy and analytical ultracentrifugation.Abbreviations Ap Ampicillin - Tc Tetracycline-hydrochloride - Bam HI endonuclease isolated from Bacillus amyloliquefaciens - Eco RI endonuclease isolated from E. coli RY13 - Bgl II endonuclease isolated from Bacillus globiggi - EDTA Ethylene-diamine-tetra-acetic-acid - ctDNA chloroplast DNA An abstract of this work was presented at the 10th annual meeting of the Union Schweizerischer Gesellschaften für Experimentelle Biologie, Davos 19th and 20th Mai, 1978. The recommendations of the Schweizerische Akademie für medizinische Wissenschaften for work with recombinant DNA-molecules were respected throughout this work.     

Mutations in the sigma subunit of E. coli RNA polymerase which affect positive control of transcription

Summary An electrophoretic mobility variant of phenoloxidase in a lz stock of Drosophila melanogaster was identified as the A₃ component of the phenoloxidase complex by using two different activators to study enzyme activity — natural activator isolated from pupae and 50% 2-propanol. The structural gene for the A₃ proenzyme, Dox-3, was not associated with lz on the X chromosome; it mapped to the right of rdo (53.1) and left of M(2)m in the second linkage group.The lz locus affects the differentiation of the crystal cell, the type of hemocyte that carries prophenoloxidase(s) in paracrystalline form. Alleles of lz lacking paracrystalline inclusions in their hemocytes do not have phenoloxidase activity whereas alleles with paracrystalline inclusions have enzyme activity. The presence of proenzyme in the paracrystalline inclusions was demonstrated by in situ activation with natural activator or propanol followed by incubation in buffered dopa.     

Sequence-specific interaction of sigma subunit of E. coli RNA polymerase with DNA.

The interaction of sigma subunit of E. coli RNA polymerase with DNA, either double or single-stranded, and with two inhibitors of RNA synthesis was investigated by using antibodies directed against the subunit. Free sigma subunit was shown to interact with poly(dA), poly(dT), poly(dAC).poly(dGT), T7 DNA and, to a lesser degree, with lambda DNA. When the sigma subunit forms part of the holo enzyme, sigma also interacts with poly(dG).poly(dC). Rifampicin and streptolydigin interact with sigma in the holo enzyme and with free and core bound sigma subunit, respectively. The results suggest that sigma recognizes mainly AC-GT-sequences in double-stranded DNA. The findings are correlated with the base composition in RNA polymerase binding regions of promoters and suggest at least a general interaction between sigma subunit and single-stranded DNA in open complexes.     

Chemical modifications of the sigma subunit of the E. coli RNA polymerase.

The function of arginine, cysteine and carboxylic amino acid (glutamic and aspartic) residues of sigma was studied using chemical modification by group specific reagents. Following modification of 3 arginine residues with phenylglyoxal or 3 cysteine residues with N-ethylmaleimide (NEM) sigma activity was lost. Analysis of the kinetic data for inactivation indicated that one arginine or cysteine residue is essential for sigma activity. At low NEM concentration alkylation was limited to a non-critical cysteine which was identified as cysteine-132. Modification of arginine or cysteine residues had no observable effect on the binding of the inactivated sigma to the core polymerase. Modification of aspartic and/or glutamic acid residues with the water-soluble carbodiimides 1-ethyl-3-(3-dimethylamino-propyl) carbodiimide hydrochloride (EDC) or 1-cyclohexyl-3-(2-morpholinoethyl) carbodiimide metho-p-toluene sulfonate (CMC) resulted in loss of sigma activity. The inactivation data indicated that one carboxylic amino acid residue is essential for sigma activity. Sigma modified with EDC, CMC or EDC in the presence of glycine was inactive in supporting promoter binding and initiation by core polymerase. Reaction with EDC plus (3H)glycine resulted in the incorporation of glycine into sigma. The (3H)glycine-sigma was unable to form a stable holoenzyme complex.     

Interaction between RNA polymerase and a ribosomal RNA promoter of E. coli.

The interaction between RNA polymerase and the E. coli ribosomal (r) RNA promoter(s) of the rrnE operon has been studied by the filter-binding method. The extent of complex formation between RNA polymerase and rrnE promoter(s) is salt-dependent; ppGpp specifically inhibits interaction of RNA polymerase with the rrnE promoter(s). A tentative model is proposed for the molecular events in the early steps of rRNA initiation: a transition of the primarily formed, labile RNA polymerase-rRNA promoter complex to a more stable form is the determining step. This step is salt-sensitive; ppGpp acts on this "isomerization".     

Interaction of Escherichia coli RNA polymerase with 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 sigma subunit. Upon preincubation of full-sized RNA polymerase with TBP and further incubation with a constant amount of 32P-labeled phosphamide 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 minimal enzyme nor the sigma 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 sigma 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.