High-throughput method for isolating plasmid DNA with reduced lipopolysaccharide content

Isolating plasmid DNA from bacteria is a fundamental step in molecular biology. It is often accomplished by an alkaline lysis of bacteria and the subsequent adsorption of nucleic acids to silica oxide in the presence of chaotropic substances. Here we show that the addition of such chaotropic reagents is not required for the efficient DNA isolation with silica oxide. This surprising finding allowed us to purify plasmid DNA with significantly less lipopolysaccharides (LPS), which is otherwise a common bacterial contaminant of silica oxide-isolated DNA and inhibits subsequent applications. In addition, we have implemented a precipitation step that altogether leads to a reduction of the LPS content by a factor of 900 relative to published methods. Our novel protocol facilitates an inexpensive high-throughput analysis of pure plasmids in a 96-well format without the addition of hazardous reagents.     

Thiophilic interaction chromatography for supercoiled plasmid DNA purification

Supercoiled plasmid DNA was selectively purified from its open circular form by thiophilic interaction chromatography, performed in the presence of high concentrations of water-structuring salts. To identify optimal conditions for purification, various aromatic thioether ligands were coupled to a chromatographic support and screened for their ability to separate plasmid isoforms from each other and from other host cell contaminants, including RNA, genomic DNA, protein, and endotoxins. Selectivity of the chromatographic medium depended on the structure of the ligands, with characteristics of the substituents on the aromatic ring determining the resolution between the different plasmid DNA isoforms. Optimal resolution was obtained with ligands consisting of an thioaromate, substituted with highly electronegative groups. When 2-mercaptopyridine was used as a ligand, the difference in conductivity for eluting open circular and supercoiled plasmid DNA is only 6 mS/cm. However, with 4-nitrothiophol the resolution for plasmid DNA separation on the media increased, resulting in a 20 mS/cm difference. When used in combination with a prior group separation step, these aromatic thioether ligands facilitated the isolation of highly purified supercoiled plasmid DNA, suitable for use in gene therapy and DNA vaccine applications.     

Large scale purification of plasmid DNA

A simple and rapid procedure for large scale purification of plasmid DNA is described. The procedure consists of two main steps: 1. Alkaline extraction of plasmid DNA (by a slight modification of the method of Birnboim and Doly (1)) and 2. Purification of the crude extract by hydroxyapatite chromatography. The plasmids obtained are biologically active and can be used in gene manipulation experiments.     

Enzymatic purification of plasmid DNA.

A novel method for plasmid DNA purification using enzymes that degrade all major types of contaminating nucleic acids present in crude plasmid DNA mixtures (but not plasmid DNA) has been devised. This method is quick (can be accomplished in two hours), requires no expensive laboratory equipment (an ultracentrifuge is not necessary) and is inexpensive. Plasmid DNA purified by this methodology can be used in a variety of molecular biological techniques including restriction enzyme digestions, subcloning, sequencing, nick translation and end labeling. This plasmid purification technique will be very useful for the molecular biologist performing cloning experiments.     

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.     

High-throughput isolation of ultra-pure plasmid DNA by a robotic system

Background  

Short hairpin RNA (shRNA) encoded within an expression vector has proven an effective means of harnessing the RNA interference (RNAi) pathway in mammalian cells. A survey of the literature revealed that shRNA vector construction can be hindered by high mutation rates and the ensuing sequencing is often problematic. Current options for constructing shRNA vectors include the use of annealed complementary oligonucleotides (74 % of surveyed studies), a PCR approach using hairpin containing primers (22 %) and primer extension of hairpin templates (4 %).     

High-throughput isolation of ultra-pure plasmid DNA by a robotic system

Background  

With the availability of complete genomes, a systematic inventory of cellular processes becomes achievable. This requires assessing the function of all individual genes. Transfection of plasmid DNA into cell culture cells is an essential technique for this aim as it allows functional overexpression or downregulation of genes. While many robotic systems isolate plasmids for sequencing purposes, for more demanding applications such as transfections there is a shortage of robots for the high-throughput isolation of plasmid DNA.     

Affinity purification of plasmid DNA by temperature-triggered precipitation

This protocol presents a new method to purify plasmid DNA using temperature-triggered precipitation. The principle is based on the specific DNA-binding affinity of a bacterial metalloregulatory (MerR) protein to its cognate DNA sequence and the temperature responsiveness of elastin-like protein (ELP). A bifunctional ELP-MerR fusion protein is created to enable the precipitation of plasmid DNA, designed to contain the MerR recognition sequence, by a simple temperature trigger. The protocol covers all stages of the process from the design of ELP-MerR fusion proteins and MerR-binding plasmids, to the isolation of plasmid DNA from Escherichia coli cultures after boiling lysis, the subsequent temperature-triggered precipitation of plasmid DNA-fusion protein complexes and final elution of plasmid DNA by mild heating. This protocol is well suited to laboratory research-scale applications, producing plasmid DNA of better purity and similar yield as one of the most commonly used laboratory methods, standard alkaline lysis (known as the midiprep procedure). The protocol takes approximately 30 min to obtain pure plasmid DNA from cell cultures using the temperature-triggered precipitation method.     

A cost-effective plasmid purification protocol suitable for fluorescent automated DNA sequencing

A cost-effective, reliable, and reproducible method has been developed to produce good-quality, double-stranded plasmid DNA for automated sequence analysis. The method incorporates modifications to a previously described plasmid-purification protocol used in manual sequencing. The quality of the DNA produced from the present protocol is suitable for automated fluorescent sequencing. Using a dye-terminator sequencing protocol, most runs using plasmid DNA prepared using this protocol produced over 700 bases with greater than 99% base-calling accuracy.     

Application of short monolithic columns for fast purification of plasmid DNA

A simple method for the separation of the four major neutral glycosphingolipids, present in all human tissue, was developed. This gradient normal phase-HPLC method utilises a polyvinyl alcohol bonded stationary phase and an evaporative light-scattering detection (ELSD). Screening pure solvents in a binary gradient elution mode allowed, in a first step, to assess the behaviour of the studied solutes and to select the solvents for further mobile phase optimisation. The proportion of the remaining solvents was defined to reach a maximal resolution. The reduction of the analysis time and the enhancement of the signal were obtained by optimising the gradient slope and the flow-rate. Optimal levels of triethylamine and formic acid (TEA-FA) for the enhancement of the evaporative light scattering detector response were established at 0.1% (v/v). Thus, the optimal conditions for the separation of the four glycosphingolipids was obtained with a gradient elution from a 100% chloroform to a 100% acetone:methanol (90:10 (v/v)) mobile phase at 0.2 ml min-1, using a 10% min-1 gradient slope. Finally, this method was applied to detect the excess of one of the neutral sphingolipids, namely globotriaosylceramide (Gb3) in the urine of patients affected with Fabry disease. A liquid-liquid extraction of the sediments obtained from an aliquot of only ten ml of urine proved sufficient to detect the excess of Gb3 present in both hemizygote and heterozygote patients. In all, the ability of our method to detect abnormal amounts of Gb3 in urinary sediments could allow the diagnosis of weakly symptomatic Fabry patients in large screening programs     

Impact of lysine-affinity chromatography on supercoiled plasmid DNA purification

Gene therapy and DNA vaccination cover a variety of applications using viral and non-viral vectors as vehicles of choice for treatment of genetic or acquired diseases. Recently, most therapeutic applications have been performed with non-viral biological agents preparations highly enriched in supercoiled plasmid molecules and it has been concluded that this isoform is more efficient at gene transfection than open circular isoform. This work describes for the first time a new strategy that uses lysine-chromatography to efficiently eliminate Escherichia coli impurities as well as other ineffective plasmid isoforms present in a complex clarified lysate to purify and obtain pharmaceutical-grade supercoiled plasmid DNA. The quality control tests indicated that the levels of impurities in the final plasmid product were below the generally accepted specifications. Furthermore, the delivery of the purified product to eukaryotic cells, the cell uptake and transfection efficiency were also analyzed. The results showed that the transfection efficiency reached with the application of the supercoiled plasmid conformation, purified with lysine-agarose, was higher than the values achieved for other plasmid topologies. Therefore, this study presents a new enabling technology to obtain the completely purified non-viral vector, able to act with good efficiency as gene therapy delivery vehicle in several diseases like cancer.     

Reverse micellar extraction systems for the purification of pharmaceutical grade plasmid DNA

Plasmid DNA as an active pharmaceutical ingredient (API) is gaining more and more importance. For the production of multigram quantities of this substance robust and scalable processes comprising several purification steps have to be designed. One main challenge is the initial separation of plasmid DNA and RNA in such a purification scheme. In this study we investigated the distribution of plasmid DNA and RNA in reverse micellar two-phase systems which is considered to be the basis for the development of an extractive purification step that can easily be integrated into common processes. For this purpose the distribution of the 4.6kb plasmid pUT649 and Escherichia coli RNA in systems comprising isooctane, ethylhexanol, and the surfactant methyltrioctylammoniumchloride (TOMAC) under the influence of different salts was studied. Anion concentrations at which the partitioning behaviour for nucleic acids inverted (inversion point) were identified. Systems capable of separating RNA from plasmid DNA were further analysed and applied to extract RNA from plasmid DNA out of a preconditioned cleared lysate. The capability of reverse micellar systems for plasmid form separation was also shown by capillary and agarose gel electrophoresis.     

Poly(hydroxyethyl methacrylate) based affinity cryogel for plasmid DNA purification

The aim of this study is to prepare supermacroporous pseudospecific cryogel which can be used for the purification of plasmid DNA (pDNA) from bacterial lysate. N-methacryloyl-(l)-histidine methyl ester (MAH) was chosen as the pseudospecific ligand and/or comonomer. Poly(hydroxyethyl methacrylate-N-methacryloyl-(l)-histidine methyl ester) [PHEMAH] cryogel was produced by free radical polymerization initiated by N,N,N',N'-tetramethylene diamine (TEMED) and ammonium persulfate (APS) pair in an ice bath. Compared with the PHEMA cryogel (50 μg/g polymer), the pDNA adsorption capacity of the PHEMAH cryogel (13,350 μg/g polymer) was improved significantly due to the MAH incorporation into the polymeric matrix. The amount of pDNA bound onto the PHEMAH cryogel disks first increased and then reached a saturation value (i.e., 13,350μg/g) at around 300 μg/ml pDNA concentration. pDNA adsorption amount decreased from 1137 μg/g to 160 μg/g with the increasing NaCl concentration. The maximum pDNA adsorption was achieved at 25 °C. The overall recovery of pDNA was calculated as 90%. The PHEMAH cryogel could be used 3 times without decreasing the pDNA adsorption capacity significantly. The results indicate that the PHEMAH cryogel disks promise high selectivity for pDNA.     

High-throughput protein purification and quality assessment for crystallization

The ultimate goal of structural biology is to understand the structural basis of proteins in cellular processes. In structural biology, the most critical issue is the availability of high-quality samples. "Structural biology-grade" proteins must be generated in the quantity and quality suitable for structure determination using X-ray crystallography or nuclear magnetic resonance (NMR) spectroscopy. The purification procedures must reproducibly yield homogeneous proteins or their derivatives containing marker atom(s) in milligram quantities. The choice of protein purification and handling procedures plays a critical role in obtaining high-quality protein samples. With structural genomics emphasizing a genome-based approach in understanding protein structure and function, a number of unique structures covering most of the protein folding space have been determined and new technologies with high efficiency have been developed. At the Midwest Center for Structural Genomics (MCSG), we have developed semi-automated protocols for high-throughput parallel protein expression and purification. A protein, expressed as a fusion with a cleavable affinity tag, is purified in two consecutive immobilized metal affinity chromatography (IMAC) steps: (i) the first step is an IMAC coupled with buffer-exchange, or size exclusion chromatography (IMAC-I), followed by the cleavage of the affinity tag using the highly specific Tobacco Etch Virus (TEV) protease; the second step is IMAC and buffer exchange (IMAC-II) to remove the cleaved tag and tagged TEV protease. These protocols have been implemented on multidimensional chromatography workstations and, as we have shown, many proteins can be successfully produced in large-scale. All methods and protocols used for purification, some developed by MCSG, others adopted and integrated into the MCSG purification pipeline and more recently the Center for Structural Genomics of Infectious Diseases (CSGID) purification pipeline, are discussed in this chapter.     

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.     

Anion exchange purification of plasmid DNA using expanded bed adsorption

Recent developments in gene therapy with non-viral vectors and DNA vaccination have increased the demand for large amounts of pharmaceutical-grade plasmid DNA. The high viscosity of process streams is of major concern in the purification of plasmids, since it can cause high back pressures in column operations, thus limiting the throughput. In order to avoid these high back pressures, expanded bed anion exchange chromatography was evaluated as an alternative to fixed bed chromatography. A Streamline 25 column filled with 100 ml of Streamline QXL media, was equilibrated with 0.5 M NaCl in TE (10 mM Tris, 1 mM EDTA, pH=8.0) buffer at an upward flow of 300 cmh^-1, E. coli lysates (obtained from up to 3 liters of fermentation broth) were injected in the column. After washing out the unbound material, the media was allowed to sediment and the plasmid was eluted with 1 M NaCl in TE buffer at a downward flow of 120 cmh^-1. Purification factors of 36±1 fold, 26±0.4 plasmid purity, and close to 100% yields were obtained when less than one settled column volume of plasmid feed was injected. However, both recovery yield and purity abruptly decreased when larger amounts were processed–values of 35±2 and 5±0.7 were obtained for the recovery yield and purity, respectively, when 250 ml of feedstock were processed. In these cases, gel clogging and expansion collapse were observed. The processing of larger volumes, thus larger plasmid quantities, was only possible by performing an isopropanol precipitation step prior to the chromatographic step. This step led to an enhancement of the purification step.     

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.     

Synthesis, purification and sample experiment for fluorescent pteridine-containing DNA: tools for studying DNA interactive systems

Fluorescent nucleoside analogs provide a means to study DNA interactive systems through direct measurement of fluorescence properties. As integrated parts of DNA, these probes provide opportunities for monitoring subtle changes in DNA structure as it meets and reacts with other molecules. This protocol describes modifications to standard DNA synthesis to efficiently use smaller volumes of the probe phosphoramidite, purification of pteridine-containing sequences and a deprotection procedure specific for 6MI-containing sequences. Yields for probe incorporation in DNA synthesis are comparable to those for standard phosphoramidites. Examples of the fluorescence signals one can expect are described. Automated synthesis, which is dependent on the length of the sequence, takes about 4-5 h for a 20-mer. The deprotection of 6MI-containing sequences takes approximately 6-7 h before the standard ammonium hydroxide overnight incubation. Purification through polyacrylamide gels, electroelution and ethanol precipitation can be accomplished in 6-8 h.