Determination of plasmid copy number by the "boiling" method

A fast and reliable approach for determination of plasmid copy number in Escherichia coli is proposed, based on the "boiling" method (5) for separation of plasmid and chromosomal DNA. The method includes in vivo uniform labeling of total bacterial DNA, separation of DNA into plasmid and chromosomal DNA fractions, and quantitation of DNA in the two fractions by radioactivity measurement. No isolation and purification of native DNA are necessary.     

Purification of bacteriophage DNA by gel filtration chromatography

Two fast and effective methods for high-scale purification of linear phage lambda DNA and circular double-stranded M13 replicative form are presented. A substantial reduction of time is attained by avoiding the long-term CsCl gradient centrifugations and dialysis common to standard procedures. Biologically active DNA preparations, free of chromosomal DNA and RNA, are obtained by including a simple gel filtration chromatography as the last step of purification. Yields are comparable to those from previously described methods.     

A simple procedure for large-scale purification of plasmid DNA

We report a simple, rapid and reliable procedure for large-scale purification of plasmid DNA from non-amplified bacterial cultures. It is a modification of the boiling method of Holmes and Quigley [Anal. Biochem. 114 (1981) 193-197] and involves gel-filtration chromatography using Sephacryl S-1000 for final purification of plasmid DNA. This method does not require CsCl gradients and the recovered plasmids are free of RNA and chromosomal DNA, are supercoiled, retain their biological activity, and are suitable for restriction analysis.     

Removal of contaminant nucleic acids by nitrocellulose filtration during pharmaceutical-grade plasmid DNA processing

Pharmaceutical-grade plasmid DNA for use in vaccines and gene therapy requires the development of reproducible and scaleable downstream processes. Shearing of chromosomal DNA at the commencement of the purification results in fragments that are difficult to separate from supercoiled plasmid DNA. Regulatory standards will probably require that the level of chromosomal DNA contamination is kept below 0.01 mg mg(-1) plasmid DNA. This work reports the use of nitrocellulose membranes to decrease chromosomal DNA contamination in plasmid DNA preparations derived from a 450-l bioreactor. Clarified lysates, resuspended PEG precipitates and anion exchange chromatography elutes were filtered through nitrocellulose. In all the cases, chromosomal DNA was selectively retained by the membrane while most supercoiled plasmid DNA was recovered in the filtrate. Contamination levels dropped from over 27% to below 1% as measured by Southern analysis. Under ionic strength conditions equal to or above 1.5 M NaCl, a fraction of the contaminant RNA was also retained by the nitrocellulose membrane.     

A ten-minute DNA preparation from yeast efficiently releases autonomous plasmids for transformation of Escherichia coli

A procedure for the rapid isolation of DNA from the yeast Saccharomyces cerevisiae is described. To release plasmid DNA for the transformation of Escherichia coli, cells are subjected to vortex mixing in the presence of acid-washed glass beads, Triton X-100, sodium dodecyl sulfate, phenol and chloroform. Centrifugation of this mixture separates the DNA from cellular debris. E. coli can be efficiently transformed with plasmid present in the aqueous layer without further purification of the plasmid DNA. This procedure also releases chromosomal DNA. Following two ethanol precipitations, the chromosomal DNA can be digested by restriction endonucleases and analysed by Southern blot analysis.     

Specificity of the histone lysine methyltransferases from rat brain chromatin

The histone lysine methyltransferases catalyze the transfer of methyl groups from S-adenosylmethionine to specific epsilon-N-lysine residues in the N-terminal regions of histones H3 and H4. These enzymes are located exclusively within the nucleus and are firmly bound to chromatin. The chromosomal bound enzymes do not methylate free or nonspecifically associated histones, while histones H3 and H4 within newly synthesized chromatin are methylated. These enzymes can be solubilized by limited digestion (10-16%) of chromosomal DNA from rapidly proliferating rat brain chromatin with micrococcal nuclease. Histone H3 lysine methyltransferase remained associated with a short DNA fragment throughout purification. Dissociation of the enzyme from the DNA fragment with DNAase digestion resulted in complete loss of enzyme activity; however, when this enzyme remained associated with DNA it was quite stable. Activity of the dissociated enzyme could not be restored upon the addition of sheared calf thymus or Escherichia coli DNA. Histone H3 lysine methyltransferase was found to methylate lysine residues in chromosomal bound or soluble histone H3, while H3 associated with mature nucleosomes was not methylated. The histone H4 lysine methyltransferase which was detectable in the crude nuclease digest was extremely labile, losing all activity upon further purification. We isolated a methyltransferase by DEAE-cellulose chromatography, which would transfer methyl groups to arginine residues in soluble histone H4. However, this enzyme would not methylate nucleosomal or chromosomal bound histone H4, nor were methylated arginine nucleosomal or chromosomal bound histone H4, nor were methylated arginine residues detectable upon incubating intact nuclei or chromatin with S-adenosylmethionine.     

Generation of chromosomal DNA during alkaline lysis and removal by reverse micellar extraction

The separation of structurally related impurities from pharmaceutical plasmid DNA by highly scalable purification techniques is a challenge for biochemical engineering. Next to RNA, proteins, and lipopolysaccharides, the chromosomal DNA of the plasmid replicating host has to be removed. Here, we describe the application of reverse micellar extraction for the separation of chromosomal from plasmid DNA. By applying different procedures for alkaline lysis, bacterial lysates with different amounts of chromosomal DNA were generated. A reverse micellar extraction step enabled us to deplete the concentration of this impurity below the required level of 50 mg g⁻¹ of plasmid DNA with almost complete plasmid recovery.     

A procedure for the isolation and purification of plasmid DNA from Rhizobium meliloti

A procedure is described for the isolation and purification of the DNA of plasmids that are indigenous to the agriculturally important nitrogen-fixing bacterium Rhizobium meliloti. The procedure involves the lysis of bacteria with an ionic detergent or a mixture of ionic and nonionic detergents, the extraction of total DNA from precipitated membrane-DNA complexes, the enrichment of supercoiled plasmid DNA by the selective alkaline denaturation of chromosomal DNA, and a further purification of plasmid DNA using cesium chloridepropidium diiodide gradients. This procedure yields pure plasmid DNA in amounts of 30 to 50 μg per liter of a culture of cell density of approximately one A550 unit. The DNA thus obtained has been found to be of sufficient purity to serve as substrate for the most commonly used restriction endonucleases.     

Compaction agent protection of nucleic acids during mechanical lysis

Mechanical lysis is an efficient and widely used method of liberating the contents of microbial cells, but the sensitivity of large nucleic acids to shear damage has prevented the application of mechanical lysis to DNA purification. It is demonstrated that polycationic compaction agents can protect DNA from shear damage and allow chromosomal and plasmid DNA purification by mechanical lysis. In addition to being substantially protected during mechanical lysis, the compacted DNA can be separated with the insoluble cell debris, washed, and selectively resolubilized, yielding a substantially purified DNA product. An additional benefit of this method is that lysate viscosity is greatly reduced, allowing the use of much smaller processing volumes when compared with traditional lysis methods used in nucleic acid purification.     

Rapid identification of hybridization probes for chromosomal walking

The presence of repeated elements in restriction fragments used as hybridization probes for chromosomal walking poses a major obstacle to the success of this gene-cloning strategy. This report describes a simple and rapid means of identifying restriction fragments devoid of repeated sequences and therefore useful as hybridization probes for chromosomal walking. Restriction fragments derived from a genomic DNA clone are Southern blotted and hybridized to nick-translated total genomic [32P]DNA. Fragments of the genomic clone that contain high abundance sequences (i.e., repeated elements) hybridize strongly to their nick-translated counterparts, which, due to their high copy number, comprise a significant proportion of the total genomic DNA probe. Conversely, fragments containing single-copy or low-abundance sequences do not hybridize, as their nick-translated counterparts are poorly represented in the total genomic DNA probe. These latter fragments, by virtue of their low-abundance sequences, are well suited as probes for chromosomal walking. Ensuring the absence of repeated elements in restriction fragments prior to their purification and utilization as chromosomal walking probes results in marked savings of time, effort and materials.     

GINS is a DNA polymerase epsilon accessory factor during chromosomal DNA replication in budding yeast

GINS is a protein complex found in eukaryotic cells that is composed of Sld5p, Psf1p, Psf2p, and Psf3p. GINS polypeptides are highly conserved in eukaryotes, and the GINS complex is required for chromosomal DNA replication in yeasts and Xenopus egg. This study reports purification and biochemical characterization of GINS from Saccharomyces cerevisiae. The results presented here demonstrate that GINS forms a 1:1 complex with DNA polymerase epsilon (Pol epsilon) holoenzyme and greatly stimulates its catalytic activity in vitro. In the presence of GINS, Pol epsilon is more processive and dissociates more readily from replicated DNA, while under identical conditions, proliferating cell nuclear antigen slightly stimulates Pol epsilon in vitro. These results strongly suggest that GINS is a Pol epsilon accessory protein during chromosomal DNA replication in budding yeast. Based on these results, we propose a model for molecular dynamics at eukaryotic chromosomal replication fork.     

Simple and rapid preparation of plasmid template by a filtration method using microtiter filter plates.

We developed a new simple high-throughput plasmid DNA extraction procedure, based on a modified alkaline lysis method, using only one 96-well microtiter glassfilter plate. In this method, cell harvesting, lysis by alkaline and plasmid purification are performed on only one microtiter glassfilter plate. After washing out RNAs or other contaminants, plasmid DNA is eluted by low-ion strength solution, although precipitated chromosomal DNA is not eluted. The plasmid prepared by this method can be applied to sequencing reactions or restriction enzyme cleavage.     

Adsorptive purification of pDNA on superporous rigid cross-linked cellulose matrix

Use of plasmid DNA (pDNA) in the emerging gene therapy requires pure DNA in large quantities requiring production of safe DNA on large scale. While a number of kit-based DNA purification techniques have become popular, large scale cost effective purification of DNA remains a technological challenge. Most traditional, as well as newly developed methods for DNA purification are expensive, tedious, use toxic reagents, and/or generally not amenable for scaled up production. Our attempts to develop a scalable adsorptive separation technology resulted in successful use of indigenously developed rigid cross-linked cellulose beads for single step purification of pDNA from alkaline cell lysates. This mode of purification employs a combination of intra-particle interactions that could give a product plasmid DNA free from chromosomal DNA, RNA and host proteins in a single scalable chromatographic step. The technology can be employed as a batch adsorption step on small scale, or on a large scale column chromatography. A high copy number 9.8 kb plasmid (from an Escherichia coli strain) was purified in yields of 77 and 52%, respectively in batch and column modes. The product obtained was homogeneous supercoiled plasmid with no RNA and protein contamination confirmed by quantitative analysis, agarose gel electrophoresis and SDS-PAGE.     

A procedure for the large-scale isolation of highly purified plasmid DNA using alkaline extraction and binding to glass powder

A preparative procedure for obtaining highly purified plasmid DNA from bacterial cells is described. The method is adapted from our earlier procedure, which gave partially purified plasmid in a form suitable for rapid screening of a large number of samples. In the present method, all detectable RNA, chromosomal DNA, and protein are removed without the use of enzymes, phenol extraction, dialysis, or equilibrium centrifugation. Binding of plasmid DNA to glass powder in the presence of 6 m sodium perchlorate is used for the final purification step.     

Purification of the E. coli dnaA gene product.

The product of the dnaA gene of Escherichia coli was isolated in a highly enriched form. The purification product binds specifically to DNA containing the E. coli chromosomal origin of replication, oriC.     

Affinity purification of plasmid DNA by temperature-triggered precipitation

This report describes a new plasmid DNA purification method, which takes advantage of the DNA-binding affinity and specificity of the bacterial metalloregulatory protein MerR, and of the temperature responsiveness of elastin-like proteins (ELPs). Upon increasing the temperature, ELP undergoes a reversible phase transition from water-soluble forms into aggregates, and this property was exploited for the precipitation of plasmid DNA containing the MerR recognition sequence by a simple temperature trigger. In one purification step, plasmid DNA was purified from E. coli cell lysates to a better purity than that prepared by a standard alkaline purification method, with no contaminating chromosomal DNA and cellular proteins. This protein-based approach, in combination with the reversible phase transition feature of ELP, makes the outlined method a promising candidate for large-scale purification of plasmid DNA for sensitive applications such as nonviral gene therapy or DNA vaccines.     

Prep-A-Gene: a superior matrix for the purification of DNA and DNA fragments

A new chromatographic matrix, Prep-A-Gene, is described for the isolation and purification of high quality DNA suitable for restriction analysis, ligation, transformation and sequencing protocols. This matrix selectively binds DNA greater than approximately 200 base pairs in length, while RNA, proteins, cellular components, agarose and other contaminants are washed free in minutes. This eliminates the need for time-consuming and laborious RNase treatments, gel extractions and phenol extractions. The DNA that is desorbed from the matrix is available immediately as a substrate for subsequent protocols. DNA purified in this manner exhibits no detectable shearing, even with more fragile chromosomal DNA.     

Yeast chromosomal DNA molecules have strands which are cross-linked at their termini

The microbial eukaryote Saccharomyces cerevisiae has 18 chromosomes, each consisting of a DNA molecule of 1 to 15×10⁸ daltons (150 to 2,300 kilobase pairs). Interstand cross-links have now been found in molecules of all sizes by examining the ability of high molecular weight DNA to snap back, i.e., to rapidly renature after denaturation. Experiments in which snap back was assessed for molecules broken by shearing indicate that there are probably two cross-links in each chromosome. Evidence that the cross-links occur at specific sites in the genome was obtained by treating total chromosomal DNA with the endonuclease EcoRI which cleaves the yeast genome into approximately 2,000 discrete fragments. Cross-link containing fragments were separated from fragments without cross-links. This purification resulted in enrichment for about 18 specific fragments. To determine whether the cross-links are terminal or at internal sites in chromosomal DNA, large shear-produced fragments were examined by electron microscopy. With complete denaturation few fragments exhibited the X-shaped single strand configuration expected for internal cross-links. When partially denatured fragments were examined some ends had single strand loops as expected for (AT-rich) cross-linked termini. The percentage of looped ends was sufficient to account for all the cross-links in the population of chromosomal molecules. The data suggest that yeast chromosomal DNA molecules have cross-linked termini. We propose that a duplex chromosomal DNA molecule in this eukaryote consists of a continuous, single, self-complementary strand of DNA. This structure has implications for the mechanism of chromosome replication and may be the basis of telomere behavior.     

Precipitation of RNA impurities with high salt in a plasmid DNA purification process: use of experimental design to determine reaction conditions

The use of high salt solution to precipitate RNA in a pharmaceutical-grade plasmid DNA purification process was investigated. Five antichaotropic salts were tested for their potential to precipitate RNA. Calcium chloride was by far the best precipitant with high RNA removal in a very short incubation time. Calcium chloride precipitation conditions were investigated at two stages of a plasmid purification process using experimental design techniques. The effect of up to five factors on RNA precipitation and plasmid recovery was assessed by statistical modeling. Optimized conditions for calcium chloride precipitation were then introduced to the plasmid purification process resulting in the efficient removal of most impurities (RNA, chromosomal DNA, proteins, and endotoxins).     

Improved methods for the isolation of individual and clustered mitotic chromosomes

We have optimized procedures for the isolation of mitotic chromosomes from tissue culture cells. The first procedure is a rapid method for obtaining individual, structurally intact chromosomes suitable for analysis by electron microscopy. Further purification of these on Percoll gradients results in chromosomes free of cytoplasmic contamination, allowing biochemical characterization of the structural proteins and enzymatic activities intrinsic to mitotic chromosomes. A third procedure permits efficient, large-scale purification of chromosomes clustered together, referred to as a chromosomal cluster. The use of EDTA-containing polyamine buffers minimizes modifications of proteins and DNA during isolation and maintains the integrity of the chromosomal structure. The conditions which lead to the isolation of chromosomal clusters, as opposed to individual chromosomes, have been analyzed. Comparison of the gei patterns of proteins derived from individual chromosomes, as compared to clusters, identifies additional proteins in the latter pattern. These proteins could be involved in maintaining interchromosomal organization or positioning in the metaphase cell.