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.     

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.     

A simple procedure for large-scale preparation of pure plasmid DNA free from chromosomal DNA from bacteria

A very simple, inexpensive procedure for preparing pure plasmid DNA from bacteria is described. In this method, lysozyme-induced spheroplasts are made in presence of 833 micrograms/ml of ethidium bromide which are then lysed by a mixture of Brij 58 and sodium deoxycholate, and the lysate is centrifuged at 48,000 g for 25 min whereby about 99.9% of total chromosomal DNA is pelleted. From the supernatant containing plasmid DNA, the proteins are removed by phenol extraction and the major part of RNA by CaCl2 precipitation, and finally the small amount of residual RNA is removed by RNase treatment. The average yield of pBR322 DNA from 1 liter of amplified culture by this procedure is 2 to 2.5 mg and the preparation is highly pure, containing only about 0.005% of total yield as chromosomal DNA contaminant. Moreover, the substrate activity and the transforming ability of the plasmid DNA prepared by this method remain unaffected.     

Purification of pharmaceutical-grade plasmid DNA by anion-exchange chromatography in an RNase-free process

Anion-exchange is the most popular chromatography technique in plasmid DNA purification. However, poor resolution of plasmid DNA from RNA often results in the addition of bovine-derived ribonuclease (RNase) A to degrade RNA impurities which raises regulatory concerns for the production of pharmaceutical-grade plasmid DNA. Low capacity for plasmid of most commercial media is another issue affecting the suitability of anion-exchange chromatography for large-scale processing. This study reports the use of anion-exchange chromatography to remove RNA in an RNase-free plasmid purification process. Resolution was achieved through careful selection of adsorbent and operating conditions as well as RNA reduction steps before chromatography. Dynamic capacity for plasmid was significantly increased (to 3.0mg/ml) so that it is now possible to envisage the large-scale manufacturing of therapeutic-grade plasmid DNA in the absence of added RNase using anion-exchange chromatography as a polishing step.     

A rapid and inexpensive method for preparing E. coli plasmid-DNA

A simple, rapid and inexpensive scaled up miniprep procedure for preparing pure E. coli plasmid DNA is described. Bacterial cells were subjected to the boiling procedure and high molecular weight RNA was removed by LiCl-precipitation. Residual RNA and proteins were removed by subsequent treatment with RNase A and proteinase K/SDS respectively, followed by Sephadex G-50 and Sepharose 6B-Cl chromatography. The average yield from a 100 ml over-night bacterial suspension was 100 to 150 micrograms for pBR-322 DNA, and 250-500 micrograms for SP-6 derived recombinant plasmids. In addition, the described "scaled up" preparation does not require CsCl-ethidium bromide centrifugation; pure plasmid DNA can be prepared within 1 to 2 days.     

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.     

Purification of plasmid DNA by tangential flow filtration

A simple, scalable method for purification of plasmid DNA is described. The method includes modification of the classical alkaline-lysis-based plasmid extraction method by extending the solubilization step from less than 30 min to 24 h. The extraction is followed by the novel use of tangential flow filtration (TFF) for purification of the remaining contaminants. The method does not include the use of any organic solvents, RNase, high-speed centrifugation, or column chromatography steps. The method typically yields 15 to 20 mg of plasmid DNA per liter of bacterial culture and results in removal of >99% of RNA and >95% of the protein that remains after the modified alkaline lysis procedure. The procedure has been demonstrated to be effective in the isolation of seven different plasmids. Plasmids isolated using this method had comparable transfection capability relative to plasmid isolated using a classical, cesium chloride gradient-based method.     

Synthesis and repair of RNA-containing supercoiled plasmid ColE1 DNA in Escherichia coli

Supercoiled plasmid molecules sensitive to nicking by RNase or alkali have been shown to accumulate during replication of colicinogenic factor E1 (ColE1) in Escherichia coli in the presence of chloramphenicol. The possibility that this sensitivity is due to the covalent integration of RNA molecules during the synthesis of plasmid DNA is supported by the demonstration that (a) strands of supercoiled ColE1 newly replicated in the presence of chloramphenicol exhibit sensitivity to RNase and alkali treatment, while (b) RNase- and alkali-resistant circular strands of plasmid DNA synthesized either before or after the addition of chloramphenicol remain resistant during subsequent replication of the plasmid in the presence of chloramphenicol. Furthermore, newly made plasmid DNA strands cannot act as templates for further rounds of replication if they possess an RNA segment. The existence of a repair mechanism for the removal of the RNA segment from supercoiled ColE1 DNA molecules was demonstrated by pulse-chase experiments. It was observed that the proportion of RNase-sensitive molecules is considerably higher in pulse-labeled as compared to continuously labeled ColE1 DNA synthesized in the presence of chloramphenicol, and the proportion of pulse-labeled ColE1 DNA that is RNase sensitive is greatly reduced during a chase period. Removal of the RNA segment is also carried out effectively at the restrictive temperature in temperature-sensitive DNA polymerase I mutants. In a survey of other bacterial mutants defective in the repair of damaged DNA, a substantial increase in the rate of accumulation of RNase-and alkali-sensitive supercoiled ColE1 DNA in the presence of chloramphenicol was observed in recBC and uvrA mutants in comparison with the wild-type strains.     

A gene affecting accumulation of the RNA moiety of the processing enzyme RNase P.

The level of 10Sb (M1) RNA, the RNA of RNase P, is very low in growing cultures of rnpB mutants. Northern transfer experiments suggested that these strains accumulate no more than 10% of the wild-type level of 10Sb RNA. However, there is no indication that there is a limiting amount of RNase P activity in these mutants in vivo. A plasmid that directs the synthesis of 10Sb RNA does not complement the rnpB mutants, even though there is only a single gene for 10Sb RNA in the Escherichia coli genome. The 10Sb RNA synthesized from this plasmid is equivalent to wild-type 10Sb RNA since it can replace it in the reconstitution of RNase P. The 10Sb RNA, which is a rather stable molecule, is unstable in the presence of the rnpB mutation. This could explain why rnpB mutants do not accumulate 10Sb RNA. An F' plasmid that contains DNA from the rnpB region of the chromosome complements an rnpB mutant in vivo and in vitro, and it also contains the 10Sb RNA gene. A number of possible explanations for these phenomena are discussed.     

RnhP is a plasmid‐borne RNase HI that contributes to genome maintenance in the ancestral strain Bacillus subtilis NCIB 3610

RNA‐DNA hybrids form throughout the chromosome during normal growth and under stress conditions. When left unresolved, RNA‐DNA hybrids can slow replication fork progression, cause DNA breaks, and increase mutagenesis. To remove hybrids, all organisms use ribonuclease H (RNase H) to specifically degrade the RNA portion. Here we show that, in addition to chromosomally encoded RNase HII and RNase HIII, Bacillus subtilis NCIB 3610 encodes a previously uncharacterized RNase HI protein, RnhP, on the endogenous plasmid pBS32. Like other RNase HI enzymes, RnhP incises Okazaki fragments, ribopatches, and a complementary RNA‐DNA hybrid. We show that while chromosomally encoded RNase HIII is required for pBS32 hyper‐replication, RnhP compensates for the loss of RNase HIII activity on the chromosome. Consequently, loss of RnhP and RNase HIII impairs bacterial growth. We show that the decreased growth rate can be explained by laggard replication fork progression near the terminus region of the right replichore, resulting in SOS induction and inhibition of cell division. We conclude that all three functional RNase H enzymes are present in B. subtilis NCIB 3610 and that the plasmid‐encoded RNase HI contributes to chromosome stability, while the chromosomally encoded RNase HIII is important for chromosome stability and plasmid hyper‐replication.     

碱裂解提取质粒DNA的改进

碱裂解提取质粒DNA是分子生物学实验中常用的方法,但通常方法所提取的质粒往往含有大量的RNA和其他杂质.本文适时加入较高浓度的RNA酶和适当延长冰浴时间,结果得到了几乎没有RNA和其他杂质的高纯质粒DNA,不仅达到了分子生物学实验要求,而且可用作抗原检测抗dsDNA抗体.该法操作简单、经济、实用.     

RNases in ColE1 DNA metabolism

ColEl DNA replication is initiated by RNA II and inhibited by RNA I. Control of the replication occurs through the interaction between RNA I and RNA II. Therefore, RNases involved in the metabolism of RNA I and RNA II are expected to play a key role in the control of the ColEl plasmid replication. RNase H, RNase E, RNase III, RNase P, and polynucleotide phosphorylase carry out the many specific reactions of the RNA metabolism.     

Construction and characterization of a plasmid containing a nearly full-size DNA copy of bacteriophage MS2 RNA.

An apparently full-length complementary DNA copy of in vitro polyadenylated MS2 RNA was synthesized with avian myeloblastosis virus RNA-dependent DNA polymerase. After the MS2 RNA template was removed from the complementary DNA strand with T₁ and pancreatic RNase digestion, the complementary DNA became a good template for the synthesis of double-stranded MS2 DNA with Escherichia coli DNA polymerase I. We then constructed molecular chimeras by inserting the double-stranded MS2 DNA into the PstI restriction endonuclease cleavage site of the E. coli plasmid pBR322 by means of the poly(dA)· poly(dT) tailing procedure. An E. coli transformant carrying a plasmid with a nearly full-length MS2 DNA insertion, called pMS2-7, was chosen for further study. Correlation between the restriction cleavage site map of pMS2-7 DNA and the cleavage map predicted from the primary structure of MS2 RNA, and nucleotide sequence analysis of the 5′ and 3′ end regions of the MS2 DNA insertion, showed that the entire MS2 RNA had been faithfully copied, and that, except for 14 nucleotides corresponding to the 5′-terminal sequence of MS2 RNA, the fulllength DNA copy of the viral genetic information had been inserted into the plasmid. Restriction endonuclease analysis of the chimera plasmid DNA also revealed the presence of an extra DNA insertion which was identified as the translocatable element IS1³ (see following paper).