Differences in replication of a DNA template containing an ethyl phosphotriester by T4 DNA polymerase and Escherichia coli DNA polymerase I

A DNA template containing a single ethyl phosphotriester was replicated in vitro by the bacteriophage T4 DNA polymerase and by Escherichia coli DNA polymerase I (DNA pol I). Escherichia coli DNA pol I bypassed the lesion efficiently, but partial inhibition was observed for T4 DNA polymerase. The replication block produced by the ethyl phosphotriester was increased at low dNTP concentrations and for a mutant T4 DNA polymerase with an antimutator phenotype, increased proofreading activity, and reduced ability to bind DNA in the polymerase active center. These observations support a model in which an ethyl phosphotriester impedes primer elongation by T4 DNA polymerase by decreasing formation of the ternary DNA polymerase–DNA–dNTP complex. When primer elongation is not possible, proofreading becomes the favored reaction. Apparent futile cycles of nucleotide incorporation and proofreading, the idling reaction, were observed at the site of the lesion. The replication block was overcome by higher dNTP concentrations. Thus, ethyl phosphotriesters may be tolerated in vivo by the up-regulation of dNTP biosynthesis that occurs during the cellular checkpoint response to blocked DNA replication forks.     

RNA polymerase synthesis in vitro directed by T7 phage DNA

Summary T7 RNA polymerase is synthesized in vitro, dependent on T7 DNA. The in vitro synthesized T7 polymerase has the characteristic properties: resistance to rifampicin and streptolydigin and the typical template specificity.     

Site-specific forced misincorporation mutagenesis using modified T7 DNA polymerase

A new method for forced misincorporation site-specific mutagenesis is described. The method uses an exonuclease-deficient modified version of T7 DNA polymerase in the presence of one dNTP to force a misincorporation. Analysis by PAGE is used to monitor the efficiency of such misincorporation reactions. Brief extension of the terminally mismatched primer/template using the same enzyme in the presence of all four dNTPs is followed by chase/ligation using unmodified T7 DNA polymerase and T4 DNA ligase to give heteroduplex DNA. We have applied the method to mutagenesis of the Lac Z region of M13 and found that, using strand selection, efficiencies of mutagenesis at one site are greater than 50%. When the mutating dNTP is complementary to a neighbouring homopolymeric tract on the template, multiple mutation is observed and efficiences are lower. The method is more general than internal mismatch mutagenesis and, because of its rapidity, is more expedient than existing methods of forced misincorporation mutagenesis.     

The presence of nucleosomes on a DNA template prevents initiation by RNA polymerase II in vitro

RNA was synthesized in vitro using HeLa cell nuclear extracts and circular DNA templates onto which varying numbers of nucleosomes had been reconstituted with Xenopus oocyte extracts. We found that fully reconstituted templates supported no specific initiation by RNA polymerase II; however, DNA exposed to the reconstitution extracts under conditions which did not allow nucleosome deposition was transcribed normally. A set of successively less reconstituted templates was also transcribed. No initiation occurred on reconstitutes with more than two-thirds of the physiological nucleosome density; reconstitutes with less than one-third of the physiological nucleosome density were transcribed as efficiently as naked DNA.     

Stimulation of T7 DNA polymerase by a new phage-coded protein

Summary A bacteriophage-induced DNA-binding protein was purified from T7 infected E. coli. The protein has a molecular weight of about 25000, as judged by SDS-polyacrylamide gel electrophoresis. The purified protein binds to single-stranded but not to native T7 DNA. Like the T4 gene-32 protein and the 22000-dalton unwinding protein of E. coli, the T7 25000 protein lowers the melting temperature of poly d(A-T). Using partially single-stranded T7 DNA as template-primer, the protein stimulates in vitro DNA synthesis by T7 DNA polymerase about five-fold. It was also found that the DNA-unwinding protein of E. coli stimulates T7 DNA polymerase to approximately the same extent. However, neither of the unwinding proteins stimulate DNA polymerase I of E. coli.