Hofmeister series salts enhance purification of plasmid DNA by non-ionic detergents

Ion-exchange chromatography is the standard technique used for plasmid DNA purification, an essential molecular biology procedure. Non-ionic detergents (NIDs) have been used for plasmid DNA purification, but it is unclear whether Hofmeister series salts (HSS) change the solubility and phase separation properties of specific NIDs, enhancing plasmid DNA purification. After scaling-up NID-mediated plasmid DNA isolation, we established that NIDs in HSS solutions minimize plasmid DNA contamination with protein. In addition, large-scale NID/HSS solutions eliminated lipopolysaccharides (LPS) contamination of plasmid DNA more effectively than Qiagen ion-exchange columns. Large-scale NID isolation/NID purification generated increased yields of high-quality DNA compared to alkali isolation/column purification. This work characterizes how HSS enhance NID-mediated plasmid DNA purification, and demonstrates that NID phase transition is not necessary for LPS removal from plasmid DNA. Specific NIDs such as IGEPAL CA-520 can be utilized for rapid, inexpensive, and efficient laboratory-based large-scale plasmid DNA purification, outperforming Qiagen-based column procedures.     

Binding and purification of plasmid DNA using multi-layered carbon nanotubes

We propose a new method for the separation of nucleic acids using multi-layered carbon nanotubes (CNTs) as an adsorbent. According to agarose gel electrophoresis, oxidized water-stable CNTs adsorb certain forms of nucleic acids, such as high molecular weight RNA, chromosomal DNA, linear and denatured forms of plasmid DNA. However, CNTs do not adsorb supercoiled form of plasmid DNA. Nucleic acids bound to CNTs can be readily removed by centrifugation whereas supercoiled plasmid DNA remains in solution. Upon the addition of divalent metal ions supercoiled plasmid DNA forms relatively stable complexes with CNTs due to chelation. Thus, new details about association of nucleic acids with CNTs were revealed and stoichiometry of the complexes was estimated. Our results can be used for fine purification of supercoiled plasmid DNA for gene therapy applications as well as manipulation of nucleic acids for biosensor design.     

A method for plasmid purification directly from yeast

A rapid technique for purifying plasmids from yeast Saccharomyces cerevisiae is described that yields high-quality DNA suitable for bacterial transformation, yeast transformation, and direct DNA sequencing. The method requires only small culture volumes and proprietary bacterial plasmid miniprep kits that allow one to simultaneously prepare a large number of samples in a very short period of time while avoiding the use of toxic organic chemicals. Both yeast single-copy CEN/ARS and high-copy 2micro shuttle plasmids can be isolated using this method. This technique is useful for plasmid purification from yeast two-hybrid experiments as well as yeast genetics and molecular biology experiments.     

A one-step miniprep for the isolation of plasmid DNA and lambda phage particles

Plasmid DNA minipreps are fundamental techniques in molecular biology. Current plasmid DNA minipreps use alkali and the anionic detergent SDS in a three-solution format. In addition, alkali minipreps usually require additional column-based purification steps and cannot isolate other extra-chromosomal elements, such as bacteriophages. Non-ionic detergents (NIDs) have been used occasionally as components of multiple-solution plasmid DNA minipreps, but a one-step approach has not been developed. Here, we have established a one-tube, one-solution NID plasmid DNA miniprep, and we show that this approach also isolates bacteriophage lambda particles. NID minipreps are more time-efficient than alkali minipreps, and NID plasmid DNA performs better than alkali DNA in many downstream applications. In fact, NID crude lysate DNA is sufficiently pure to be used in digestion and sequencing reactions. Microscopic analysis showed that the NID procedure fragments E. coli cells into small protoplast-like components, which may, at least in part, explain the effectiveness of this approach. This work demonstrates that one-step NID minipreps are a robust method to generate high quality plasmid DNA, and NID approaches can also isolate bacteriophage lambda particles, outperforming current standard alkali-based minipreps.     

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.     

The use of cetyltrimethylammonium bromide for the rapid isolation from Staphylococcus aureus of relaxable and non-relaxable plasmid DNA suitable for in vitro manipulation

Plasmid DNA was isolated from Staphylococcus aureus by a rapid method that depends on the precipitation of DNA from cleared lysates by cetyltrimethylammonium bromide at low salt concentrations. The method was validated by its ability to provide DNA for restriction analysis of a highly relaxable plasmid species that is not isolated by more traditional techniques. The DNA can be digested with restriction endonucleases and used for transformation without further purification. The method also provides the basis for analysing staphylococcal plasmids that display a high frequency of deletion after transfer. Simple modifications of the technique allow plasmid DNA to be isolated from other bacteria and the rapid purification of DNA samples before in vitro manipulation.     

Rapid quantitation and monitoring of plasmid DNA using an ultrasensitive DNA-binding dye

A sensitive fluorescence-based method for monitoring plasmid DNA during production was investigated. This simple method of assaying for plasmid DNA allows rapid monitoring of plasmid yields from a recombinant Escherichia coli fed-batch fermentation. The assay has several advantages over traditional methods of plasmid DNA measurement. The fluorescent dye is highly specific and can measure total plasmid DNA concentration in about 5 min. The assay is sensitive over a wide range of plasmid concentrations of between 15 and 280 ng/mL, even in the presence of impurities that occur within alkaline lysate preparations. The technique can also be applied to monitoring fermentation and downstream purification steps.     

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.     

Rapid isolation of plasmid DNA by LiCl-ethidium bromide treatment and gel filtration.

We established a simple and rapid plasmid DNA purification method. Crude plasmid DNA preparations are treated with 4 M LiCl in the presence of 0.6 mg/ml ethidium bromide to precipitate RNA and proteins contained in the DNA preparations. After removal of RNA and protein precipitates, the supernatant is filtered through a Sepharose CL6B column to remove low-molecular-weight contaminants. This procedure takes only 30 min and provides pure plasmid DNA preparations that consist mainly of covalently closed circular plasmid DNA but have no detectable RNA and protein. The purified DNA preparations are susceptible to various six- and four-base-recognition restriction endonucleases, T4 DNA ligase, the Klenow fragment of DNA polymerase I, and T7 and Taq DNA polymerase. Since no special equipment is needed for this purification method, 20 or more samples of microgram to milligram levels can be treated in parallel.     

Purification of nuclear factor I by DNA recognition site affinity chromatography

Nuclear factor I (NF-I) is a cellular protein that enhances the initiation of adenovirus DNA replication in vitro. The enhancement of initiation correlates with the ability of NF-I to bind a specific nucleotide sequence within the viral origin of replication. We have developed a method for the purification of NF-I which is based upon the high affinity interaction between the protein and its recognition site. This approach may be generally applicable to the purification of other site-specific DNA binding proteins. The essential feature of the method is a two-step column chromatographic procedure in which proteins are first fractionated on an affinity matrix consisting of nonspecific (Escherichia coli) DNA and then on a matrix that is highly enriched in the specific DNA sequence that is recognized by NF-I. During the first step NF-I coelutes with proteins that have similar general affinity for DNA. During the second step NF-I elutes at a much higher ionic strength than the contaminating nonspecific DNA binding proteins. The DNA recognition site affinity matrix used in the second step is prepared from a plasmid (pKB67-88) that contains 88 copies of the NF-I binding site. This plasmid was constructed by means of a novel cloning strategy that generates concatenated NF-I binding sites arranged exclusively in a direct head to tail configuration. Using this purification scheme, we have obtained a 2400-fold purification of NF-I from crude HeLa nuclear extract with a 57% recovery of specific DNA binding activity. Throughout the purification procedure NF-I retained the ability to enhance the efficiency of initiation of adenovirus DNA replication in vitro. Electrophoresis of the purified fraction on sodium dodecyl sulfate-polyacrylamide gels revealed a population of related polypeptides that ranged in apparent molecular weight from 66,000 to 52,000. The native molecular weight of NF-I deduced from gel filtration and glycerol sedimentation studies is 55,000 and the frictional ratio is 1.3. These results suggest that NF-I exists as a globular monomer in solution.     

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.     

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.     

Separation of genomic DNA from plasmid DNA by selective renaturation with immobilized metal affinity capture

In contrast to proteins, many nucleic acids can undergo reversible modification of their conformations, and this flexibility can be used to facilitate purification. Selective renaturation with capture is a novel method of removing contaminating genomic DNA from plasmid samples. Plasmid DNA quickly renatures after thermal denaturation and cooling (or alkaline denaturation followed by neutralization), whereas genomic DNA remains locally denatured after rapid cooling in mismatch-stabilizing high ionic strength buffer. Partially denatured genomic DNA can be selectively bound to a metal chelate affinity adsorbent through exposed purine bases, while double-stranded renatured plasmid DNA is not bound. Using this method we have readily achieved 1,000,000-fold clearance of 71 wt % contaminating E. coli genomic DNA from plasmid samples.     

Large-scale purification of plasmid DNA by fast protein liquid chromatography using a Hi-Load Q Sepharose column.

The large-scale purification of plasmid DNA was achieved using fast protein liquid chromatography on a Hi-Load Q Sepharose column. This method allows for the purification of plasmids starting from crude plasmid DNA, prepared by a simple alkaline lysis procedure, to pure DNA in less than 5 h. In contrast to the previously described plasmid purification methods of CsCl gradient centrifugation or high-pressure liquid chromatography, this method does not require the use of any hazardous or expensive chemicals. More than 100 plasmids varying in size from 3 to 15 kb have been purified using this procedure. A Mono Q Sepharose column was initially used to purify plasmids smaller than 8.0 kb; however, a Hi-Load Q Sepharose column proved more effective with plasmids larger than 8 kb. The loading of plasmids larger than 8 kb on the Mono Q column resulted in a high back pressure and the plasmid DNA could not be eluted from the column. Thus, for routine purification we utilize the Hi-Load Q Sepharose column. Plasmids purified by this method had purity, yield, and transfection efficiency in mammalian cells similar to those of plasmids purified by CsCl density gradient centrifugation.     

Contaminant eluted from solid-phase plasmid affinity-purification protocol columns is not found using liquid-phase methods and can be prevented.

The preparation of high quality plasmid DNA is a necessary requirement for most molecular biology applications. We compared four different large plasmid preparation protocols, which were based on either a liquid-phase approach (Triton lysis) or purification of alkaline lysis bacterial extracts followed by supercoiled plasmid purification on affinity columns. Two host Escherichia coli strains, JM 109 and INValphaF', were used to grow the test plasmids for comparison of product plasmid DNA produced from the four different plasmid isolation methods. While the DNA grown in E. coli strain JM109, prepared by liquid-phase Triton lysis was appropriately restricted by 12 restriction enzymes, this was not the case for any of the JM109-grown DNA purified by any of the affinity column solid-phase approaches. In contrast to this, when the plasmid DNA was grown in E. coli strain INValphaF', most restriction enzymes cut DNA appropriately, irregardless of the plasmid preparation protocol used. It seems that an impurity commonly eluted with the DNA from all three of the solid-phase DNA columns had an equal effect on the above enzymes using the common host strain JM109, but not strain INValphaF'.     

Parallel tagged sequencing on the 454 platform

Parallel tagged sequencing (PTS) is a molecular barcoding method designed to adapt the recently developed high-throughput 454 parallel sequencing technology for use with multiple samples. Unlike other barcoding methods, PTS can be applied to any type of double-stranded DNA (dsDNA) sample, including shotgun DNA libraries and pools of PCR products, and requires no amplification or gel purification steps. The method relies on attaching sample-specific barcoding adapters, which include sequence tags and a restriction site, to blunt-end repaired DNA samples by ligation and strand-displacement. After pooling multiple barcoded samples, molecules without sequence tags are effectively excluded from sequencing by dephosphorylation and restriction digestion, and using the tag sequences, the source of each DNA sequence can be traced. This protocol allows for sequencing 300 or more complete mitochondrial genomes on a single 454 GS FLX run, or twenty-five 6-kb plasmid sequences on only one 16th plate region. Most of the reactions can be performed in a multichannel setup on 96-well reaction plates, allowing for processing up to several hundreds of samples in a few days.     

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.     

Fractionation of DNA with Sephacryl S-1000

In this study the application of gel filtration for purification of heterogeneous DNA is described. The fractionation of partial restriction enzyme digests of bacterial chromosomal DNA on a Sephacryl S-1000 -column is easy and rapid. Simultaneously intact chromosomal DNA and low molecular weight substances are eliminated in the run. The method is also applicable to the purification of plasmid DNA, as has been previously reported (3). Thus we are able to get pure DNA with yields over 80%.     

Preparative scale, high resolution purification of low molecular weight DNA fragments

A commercially available continuous electroelution system has been used to separate and purify low molecular weight DNA fragments from polyacrylamide gels. This method has several advantages over previously reported methods for the recovery of DNA fragments from polyacrylamide gels. This technique, which gives very high recovery rates (80-95%), can be carried out on a relatively large scale and in a way that is not labour intensive. Data are presented for the purification of DNA fragments with molecular weights in the range 1-4 x 10(5) (200-700 base-pairs), although the method is also applicable to larger molecular weight DNA fragments, RNAs and proteins.     

A simple and rapid strategy for the molecular cloning and monitoring of mouse HtrA2 serine protease

A simple and rapid strategy for molecular cloning using a gel-free and antibiotic selection method is described which allows for the complete elimination of DNA extraction by gel electrophoresis, and thus has several advantages over gel-based cloning methods, including: (i) a cloning efficiency that is approximately 10-times higher due to the prevention of ethidium bromide ultraviolet-induced DNA damage and contamination with ligase inhibitors; (ii) the amount of plasmid DNA required is approximately five times less; and (iii) the cloning time is several hours less. Once the target gene, such as mouse HtrA2 serine protease, was cloned into the pEGFP-N3 plasmid, the integrity of the kanamycin-resistant molecular clone encoding the GFP fusion protein was verified by immunoblot and immunofluorescence assays. In addition, the integrity of the ampicillin-resistant molecular clone was directly evaluated by analyzing the expression and affinity purification of the GST fusion protein and by measuring its enzymatic activity. Therefore, this method is suitable for the routine construction of a plasmid expressing the gene of interest, and the usefulness of this strategy can be demonstrated by monitoring the expression of the target gene in E. coli and mammalian cells. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. G-Y Kim, M-K Nam, and S-S Kim contributed equally to this work.