A fully active DNA polymerase I from Escherichia coli lacking stoichiometric zinc

DNA polymerase I produced by an Escherichia coli strain lysogenized with a λpolA phage has been purified using a modification of the method of Kelley and Stump (Kelley, W.S. and Stump, K.H. (1979) J. Biol. Chem. 254, 3206–3210). This modification involves an additional phosphocellulose column and a hydroxylapatite column and results in a preparation of DNA polymerase I which is at least 97% pure. The metal content of the purified enzyme was analyzed and only 0.13 moles of zinc were detected per mole of DNA polymerase I. Since the enzyme still retained its full activity, this result did not support previous investigations which stated that zinc bound to the enzyme in stoichiometric amounts was necessary for polymerase activity. These findings suggest that the mechanism of DNA polymerase I with respect to the role of zinc should be reevaluated.     

The structure of the zinc sites of Escherichia coli DNA-dependent RNA polymerase.

X-ray absorption spectroscopy is ideally suited for the investigation of the electronic structure and the local environment (approximately 5 A) of specific atoms in biomolecules. While the edge region provides information about the valence state of the absorbing atom, the chemical identity of neighboring atoms, and the coordination geometry, the extended x-ray absorption fine structure region contains information about the number and average distance of neighboring atoms and their relative disorder. The development of sensitive detection methods has allowed studies using near physiological concentrations (as low as approximately 100 microM). RNA polymerase from Escherichia coli contains two zinc atoms: one tightly bound in the beta' subunit, the subunit that participates in template binding, and the other loosely bound in the beta subunit, the subunit that participates in substrate binding. X-ray absorption studies of these zinc sites in the native protein and of the zinc site in the beta' subunit after removal of the zinc in the beta subunit site by p-(hydroxymercuri)benzenesulfonate (Giedroc, D. P., and Coleman, J. E. (1986) Biochemistry 25, 4969-4978) indicate that both zinc sites have octahedral coordination. The zinc in the beta' subunit site has four sulfur ligands at an average distance of 2.36 +/- 0.02 A and two oxygen (or nitrogen) ligands at an average distance of 2.23 +/- 0.02 A. The beta subunit zinc site has five sulfur ligands at an average distance of 2.38 +/- 0.01 A and one histidine nitrogen ligand at 2.14 +/- 0.02 A. These results are in general agreement with earlier biochemical and spectroscopic studies.     

Relaxed mutants of Escherichia coli RNA polymerase

When Escherichia coli cells are treated with either polymixin or gramicidin at concentrations that block protein and RNA synthesis, they accumulate a significant amount of guanosine tetraphosphate ppGpp. Such accumulation occurs in stringent (relA+) as well as in relaxed (relA) strains and no guanosine pentaphosphate pppGpp is then detected within the cells. These observations suggest that polypeptide antibiotics elicit ppGpp formation through a mechanism different from the stringent control system triggered by amino acid starvation of bacteria. Experiments based on tetracycline action indicate, moreover, that the accumulation of ppGpp under polymixin or gramicidin treatment is connected with a strong restriction of the degradation rate of this nucleotide.     

The 4.5 S RNA gene of Escherichia coli is essential for cell growth

The Escherichia coli gene coding for the metabolically stable 4.5 S RNA (ffs) has been shown to be required for cell viability. Essentiality was demonstrated by examining the recombination behavior of substitution mutations of ffs generated in vitro. Substitution mutants of ffs are able to replace the chromosomal allele only in the presence of a second, intact copy of ffs. Independent evidence of essentiality and the finding that 4.5 S RNA is important for protein synthetic activity came from characterization of cells dependent on the lac operon inducer isopropyl-beta-D-thiogalactoside for ffs gene expression. Here, a strain dependent on isopropyl-beta-D-thiogalactoside for 4.5 S RNA synthesis was developed by inactivation of the chromosomal ffs allele and lysogenization by a lambda phage containing 4.5 S DNA fused to a hybrid trp-lac promoter. Withdrawal of the thiogalactoside leads to a deficiency in 4.5 S RNA, a dramatic loss in protein synthesis activity, and eventual cell death. Tagging of the chromosomal ffs region with a kanamycin-resistance gene allowed mapping of the 4.5 S RNA gene. Results from this analysis place ffs near lon at approximately ten minutes on the E. coli linkage map.     

Initiation of RNA molecules by purified Escherichia coli RNA polymerase

Summary The kinesties of appearance of, and the distribution among, the four bases of the chain-initial nucleotides (5-termini) of RNA chains synthesized in vitro under various conditions have been investigated. The results of this study have shown that when native T4 bacteriophage DNA is the template for the RNA polymerase, most chains start with a purine nucleotide. The ratio of ATP termini to GTP termini is independent of the reaction time and of the template/enzyme ratio in the reaction mixture. A similar preferential purine initiation was observed when denatured T4 is the template, but the ratio of ATP to GTP termini is reduced. All 5-termini of poly-AU chains synthesized on poly-dAT templates are ATP.The determination of the kinetics of initiation of RNA chains has allowed direct confirmation of some conclusions which had been inferred previously from sedimentation analyses of the RNA product. (1) Most RNA chains are initiated during a short period at the outset of the reaction. (2) Low concentrations of native DNA templates limit the number of RNA chains synthesized, not the rate of RNA chain growth. (3) The maximum number of RNA molecules which can be synthesized on denatured DNA templates is severalfold larger than the maximum number which can be synthesized on the same weight of native DNA.