Methylation-dependent DNA synthesis in Escherichia coli mediated by DNA polymerase I.

An in vitro system was used to study DNA synthesis in lysates of Escherichia coli cells which had been grown in the presence of ethionine. Such lysates showed a reduced capacity to incorporate [3H]TTP into high-molecular-weight material. Activity could be restored by incubation with S-adenosyl methionine and ATP. S-adenosyl methionine-reactivated TTP incorporation required the presence of DNA polymerase I, ATP, and all four deoxyribonucleotide triphosphates. DNA polymerase III was not required.     

Binding and transcription of simian virus 40 DNA by DNA-dependent RNA polymerase from Escherichia coli.

Supercoiled simian virus 40 was transcribed more efficiently than nonsupercoiled DNA. The effect was increased from two- to fivefold by the addition of rifampin with triphosphates. The number and locations of polymerase binding sites with respect to Hin II-III restriction fragments were determined. The total number of binding sites was nine, as determined by UV difference spectroscopy. The locations of these binding sites were on the A, B, D, E, F, and G fragments, as determined by gel electrophoresis. The number of sites was the same for both supercoiled and relaxed or Hin II-III-digested DNA, and the point of saturation of supercoiled DNA by polymerase remained the same with increasing concentrations of rifampin from 0 to 8 microgram/ml.     

Ellipticine increases the superhelical density of intracellular SV40 DNA by intercalation.

We investigated the in vivo effect of ellipticine, a mammalian topoisomeraseII(topoII) inhibitor, on SV40 DNA topology. In contrast to epipodophyllotoxins, ellipticine did not cause significant double stranded cleavage of intracellular SV40 DNA. Furthermore, ellipticine reduced cleavage induced by epipodophyllotoxins, VP16 and VM26. Unexpectedly, ellipticine dramatically increased the superhelical density of a fraction of intracellular SV40 DNA. Several lines of evidence suggest that the formation of this highly supercoiled DNA species (Ih form DNA) is not due to the inhibition of topoII per se, but is the result of intercalation by ellipticine in a subfraction of the intracellular SV40 chromatin followed by the fixation of DNA linking number by a topoisomerase activity. Based on the linking number change and the known unwinding angle of ellipticine, the intercalation density was calculated as one ellipticine molecule per 10-20 bp in the Ih DNA. This result suggests the existence of different populations of intracellular SV40 chromatin with respect to the accessibility to ellipticine intercalation.     

Random cleavage of superhelical SV 40 DNA S1 nuclease.

SV40 DNA FO I is randomly cleaved by S1 nuclease both at moderate (50 mM) and higher salt concentrations (250 mM NaC1). Full length linear S1 cleavage products of SV40 DNA when digested with various restriction endonucleases revealed fragments that were electrophoretically indistinguishable from the products found after digestion of superhelical SV40 DNA FO I with the corresponding enzyme. Concordingly, when the linear S1 generated duplexes were melted and renatured, circular duplexes were formed in addition to complex larger structures. This indicated that cleavage must have occurred at different sites. The double-strand-cleaving activity present in S1 nuclease preparations requires circular DNA as a substrate, as linear SV40 DNA is not cleaved. With regard to these properties S1 nuclease resembles some of the complex type I restriction nucleases from Escherichia coli which also cleave SV40 DNA only once, and, completely at random.     

SV40 DNA injected into Xenopus oocyte nuclei is transcribed by RNA polymerase B.

SV40 DNA I. injected into Xenopus oocyte nuclei is transcribed. The SV40-specific RNA molecules migrate on sucrose gradients as do viral RNAs formed in infected green monkey cells but a variable proportion of RNA sequences complementary to SV40 DNA is also found in the light region of the gradients. All SV40-specific RNA species seem to be synthesized by RNA polymerase B as their synthesis is completely sensitive to low concentrations (0.1 microgram/ml) of alpha-amanitin. Concomittantly, the formation of SV40-specific proteins (tumor antigens) is inhibited by injecting alpha-amanitin together with the SV40 DNA.     

Physiochemical studies on interactions between DNA and RNA polymerase. Unwinding of the DNA helix by Escherichia coli RNA polymerase.

In a medium containing 10mM Tris, pH 8, 10 mM MG++, 50 mM K+ and 10 mM NH4, the binding of an E. coli RNA polymerase holoenzyme unwinds the DNA helix by about 240 degrees at 37 degrees C. In this medium the total unwinding of the DNA increases linearly with the molar ratio of polymerase to DNA. The number of binding sites at which unwinding can occur is very large. If the K+ concentration is increased at 200 mM, the enzyme binds to only a limited number of sites, and the bound and free enzyme molecules do not exchange at an appreciable rate. The unwinding angle of the DNA per bound enzyme in this high salt medium is measured to be 140 degrees at 37 degrees C. The total unwinding angle for a fixed number of bound polymerase molecules per DNA is strongly temperature dependent, and decreases with decreasing temperature.     

Evidence for specific control of RNA polymerase synthesis in Escherichia coli

Studies on the synthesis of RNA polymerase in E. coli rif mutants containing both sensitive and resistant RNA polymerase molecules show that the synthesis of E. coli RNA polymerase is under a specific and active control system.     

Transcription of polyoma virus DNA in vitro. II. Transcription of superhelical and linear polyoma DNA by RNA polymerase II.

The protein product of the bacteriophage T4 gene 32 is a single-stranded DNA binding protein which functions during phage DNA repair, replication and recombination. Recently the gene 32 protein was shown to participate in the regulation of its own expression. Although the purified protein is known to interact with DNA, the autoregulation was shown to occur at the translational level. The previous analysis in vivo, although coherent, was indirect. We report here direct cell-free experiments in which purified gene 32 protein specifically represses translation of gene 32 messenger RNA.