Preparative purification of plasmid DNA templates for in vitro transcription assays by consecutive differential precipitations

A procedure for large-scale isolation of plasmid DNA without the use of RNase has been developed to obtain a DNA template for preparative in vitro RNA synthesis catalyzed by phage RNA polymerases. The separation of plasmid DNA from admixtures has been achieved only through selective precipitations of either plasmid DNA or contaminants. No expensive reagents or equipment were required. Plasmid quality was evaluated by gel electrophoresis and restriction analysis. The obtained plasmid DNA templates have been shown to be devoid of any detectable ribonucleolytic activity that may interfere with the following RNA synthesis.     

Identification of RNase-resistant RNAs in Saccharomyces cerevisiae extracts: Separation from chromosomal DNA by selective precipitation

High-quality chromosomal DNA is a requirement for many biochemical and molecular biological techniques. To isolate cellular DNA, standard protocols typically lyse cells and separate nucleic acids from other biological molecules using a combination of chemical and physical methods. After a standard chemical-based protocol to isolate chromosomal DNA from Saccharomyces cerevisiae and then treatment with RNase A to degrade RNA, two RNase-resistant bands persisted when analyzed using gel electrophoresis. Interestingly, such resistant bands did not appear in preparations of Escherichia coli bacterial DNA after RNase treatment. Several enzymatic, chemical, and physical methods were employed in an effort to remove the resistant RNAs, including use of multiple RNases and alcohol precipitation, base hydrolysis, and chromatographic methods. These experiments resulted in the development of a new method for isolation of S. cerevisiae chromosomal DNA. This method utilizes selective precipitation of DNA in the presence of a potassium acetate/isopropanol mixture and produces high yields of chromosomal DNA without detectable contaminating RNAs.     

Rapid and simple removal of contaminating RNA from plasmid DNA without the use of RNase

A procedure for the removal of RNA and RNA fragments from large quantities of pBR322 plasmid DNA without the use of RNase is described. Sephacryl S-300 is employed for the separation of low-molecular-weight RNA from plasmid DNA molecules on the basis of gel filtration. The technique thus circumvents many of the dangers associated with treating plasmid DNA preparations with RNase. The procedure should be generally applicable to the purification of virtually any type of plasmid DNA isolated from a bacterial host.     

Plasmid purification by phenol extraction from guanidinium thiocyanate solution: development of an automated protocol.

We have developed a novel plasmid isolation procedure and have adapted it for use on an automated nucleic acid extraction instrument. The protocol is based on the finding that phenol extraction of a 1 M guanidinium thiocyanate solution at pH 4.5 efficiently removes genomic DNA from the aqueous phase, while supercoiled plasmid DNA is retained in the aqueous phase. S1 nuclease digestion of the removed genomic DNA shows that it has been denatured, which presumably confers solubility in the organic phase. The complete automated protocol for plasmid isolation involves pretreatment of bacterial cells successively with lysozyme, RNase A, and proteinase K. Following these digestions, the solution is extracted twice with a phenol/chloroform/water mixture and once with chloroform. Purified plasmid is then collected by isopropanol precipitation. The purified plasmid is essentially free of genomic DNA, RNA, and protein and is a suitable substrate for DNA sequencing and other applications requiring highly pure supercoiled plasmid.     

Molecular cloning of extensive sequences of the in vitro synthesized chicken ovalbumin structural gene.

Double-stranded DNA molecules complementary to ovalbumin chicken messenger RNA were synthesized in vitro and integrated into the E. coli plasmid pCR1 using an oligodG-dc tailing procedure. The resultant hybrid plasmids, amplified by transfection of E. coli, were shown by hybridization and gel electrophoresis to contain extensive DNA sequences of the ovalbumin structural gene.     

A rapid method for preparation of bacterial plasmids

A method for isolating plasmids from Escherichia coli which requires less than 8 h from cell pellet to purified plasmid essentially free of protein, RNA, and chromosomal DNA is presented. By this procedure, amplified plasmid pBR322 was isolated from E. coli strain RR1. The final product had no detectable protein or RNA, and plasmid comprised approximately 99% of the total DNA. The procedure includes lysozyme treatment in hypertonic solution followed by lysis with a mild detergent in the presence of high salt and an RNase inhibitor--conditions which prevent unfolding of the bacterial nucleoid. After centrifuging out the nucleoid and cell debris, the nucleic acids are selectively precipitated with a neutral solution of sodium trichloroacetate and ethanol. RNA is degraded with RNase and the degradation products and RNase are eliminated through a second trichloroacetate/ethanol precipitation. Finally, the plasmid is resuspended and passed through a nitrocellulose filter to remove aggregates and any residual protein and single-stranded DNA--giving a plasmid preparation suitable for electrophoretic fractionation or cleavage with restriction nucleases.     

Purification of RNA-free plasmid DNA using alkaline extraction followed by Ultrogel A2 column chromatography

A procedure for extracting RNA-free plasmid DNA from bacterial cells is described. The method is simple and rapid enough to obtain pure plasmid DNA in 8 to 10 h after plasmid amplification. The protocol uses the alkaline extraction procedure described by Birnboim and Doly (1979, Nucl. Acid Res. 7, 1513-1523). Plasmid DNA is then separated from high-molecular-weight RNA by ammonium acetate precipitation and from low-molecular-weight RNA contaminants by Ultrogel A2 column chromatography. The plasmid DNA obtained by this inexpensive technique is sufficiently pure to be used for restriction endonuclease analysis, 5'-end labeling, S1 mapping, DNA sequencing, and colony hydridization.