Selective precipitation of DNA by spermine during the chemical extraction of insoluble cytoplasmic protein.

The direct chemical extraction of recombinant L1 protein (the major capsid protein of human papillomavirus type 16) from the cytoplasm of E. coli HMS174(DE3) has recently been demonstrated at high cell density (to OD(600) = 160) without the use of reducing agent (1). Coextraction of DNA at high concentration prevents direct coupling to postextraction recovery operations including expanded bed adsorption. In this study, spermine is used to selectively precipitate DNA during chemical extraction. Highly efficient and selective DNA precipitation was achieved. An approximate 10-fold increase in the specific spermine concentration (mg of spermine/mg of DNA) was required to precipitate DNA when 8 M urea was added to the extraction buffer. EDTA (3 mM), required for effective chemical extraction, does not significantly inhibit DNA precipitation. Precipitation selectivity was demonstrated in a bovine serum albumin spiking test, with almost complete recovery of the spiked protein. During studies on the direct extraction of L1 protein from cells at OD(600) = 80, high DNA removal efficiency (>85%) and negligible L1 protein coprecipitation were achieved. This selective precipitation technique simply requires the addition of spermine to the chemical extraction buffer and therefore does not increase technique complexity. This modification enhances the method's general applicability and enables direct coupling to downstream recovery units following chemical extraction at high cell and product concentrations.     

CTAB-PEG DNA Extraction from Fungi with High Contents of Polysaccharides

Polysaccharides influence concentration and purity of extracted DNA. Here we present rapid and efficient protocol for DNA extraction from samples rich in polysaccharides. The technique has been developed using cultures of Schizophyllum commune and involves a modification of known Cetyltrimethyl Ammonium Bromide (CTAB) protocol. To remove polysaccharides, Polyethylene Glycol (PEG) 8000 was added during DNA precipitation. Genomic DNA obtained with the CTAB-PEG method had high integrity, with average fragment size >30 kb, the concentration higher than 100 ng/μL, and the yield more than 30 μg/g. Presented technique is suitable for DNA extraction from fungi, bacteria, archaea or even mollusks with high polysaccharide content.     

Rapid purification of covalently closed circular DNAs of bacterial plasmids and animal tumor viruses

A rapid and simple purification of covalently closed circular (supercoiled) DNA from both bacterial clones (plasmids) and African green monkey cells (SV40) is presented. The method involves immediate treatment of lysed cells with sodium hydroxide, followed by neutralization and phenol extraction in high salt. After the extraction mixture is centrifuged, supercoiled DNA is found in the aqueous phase, the noncovalently closed DNA molecules form a white precipitate at the interphase, and proteins pellet. Contaminating RNA is eliminated from the aqueous phase by RNAse treatment and precipitation of the supercoiled DNA with polyethylene glycol. Residual polyethylene glycol is removed from the resuspended DNA by chloroform extraction. The purified supercoiled DNA is compatible with restriction enzymes, and is efficient at transforming both _χ1776 and HB101 bacterial hosts. Centrifugation in ethidium bromide-cesium chloride or sucrose gradients is not necessary. The method is virtually independent of the molecular size and gives good yields of supercoiled DNA. The technique is applicable to large-scale preparations and as a rapid “screening” procedure in which 20 to 30 samples can be easily purified within 5 to 6 h.     

Comparison of different methods for the isolation and purification of total community DNA from soil

The efficiency and reproducibility of DNA extraction from soil was tested for variations in lytic and purification treatments and their effect on yield and purity of DNA. The extraction yield was improved by increasing the concentration of EDTA or monovalent ions in isolation buffers, by the introduction of mechanical lysis treatments, and by the use of ethanol precipitation in place of PEG precipitation. Purity was improved using buffers with decreasing concentration of EDTA or by reducing the ionic strength of the buffer, and by all mechanical treatments. No lytic treatment was efficient on its own, the highest purity was achieved using Crombach buffer and a combination of bead-beating with lysozyme and SDS lysis followed by potassium acetate and PEG precipitation, phenol/chloroform purification, isopropanol precipitation, and spermine-HCl precipitation. Sonication sheared the DNA more than bead-beating. Lysozyme and SDS lysis without any mechanical treatments allowed isolation of larger fragments (40-90 kb). Denaturing gradient gel electrophoresis analysis of DNA isolated using a range of lytic treatments revealed alterations in band patterns which might reflect differences in the efficiency of lytic treatments.     

Methods for microbial DNA extraction from soil for PCR amplification

Amplification of DNA from soil is often inhibited by co-purified contaminants. A rapid, inexpensive, large-scale DNA extraction method involving minimal purification has been developed that is applicable to various soil types (1). DNA is also suitable for PCR amplification using various DNA targets. DNA was extracted from 100g of soil using direct lysis with glass beads and SDS followed by potassium acetate precipitation, polyethylene glycol precipitation, phenol extraction and isopropanol precipitation. This method was compared to other DNA extraction methods with regard to DNA purity and size.     

Incorporation of tritiated thymidine into DNA of rat liver: a critique of various evaluation methods]

We have measured the incorporation of 3H-(methyl)-thymidine by cell cultures of rat foetal liver and in vivo by the livers of young rats stimulated by casein, in order to compare three methods for the extraction of DNA. The DNA was extracted by three different techniques: perchloric acid precipitation, trichloroacetic acid precipitation and phenol extraction, and its specific activity was determined. The radioactive labelling was also determined for the lipid, ribonucleic acid and protein fractions for the two first methods, in both of which 70 p. cent of the incorporated tritium is found in the DNA fraction and about 10 p. cent in each of the other fractions. The determination of the specific radioactivity of DNA gives similar results for the three extraction methods. However, since larger yields were obtained by both acid precipitation techniques than by phenol extraction, we believe them to be more suitable for studies on cell cultures.     

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.     

A rapid preparation of plasmid DNA fromSaccharomyces cerevisiae

A procedure for extraction of plasmid DNA from Saccharomyces cerevisiae is described. The plasmid DNA of interest is extracted together with 2-micron circular DNA naturally occurring in many yeast strains. Spheroplasts are lyzed at alkaline pH which denatures linear but not covalently closed circular (CCC) DNA. The CCC DNA is recovered by ethanol precipitation and can be detected by gel electrophoresis or used for routine bacterial transformation.     

A rapid method for tissue collection and high-throughput isolation of genomic DNA from mature trees

Collection of tissue and subsequent isolation of genomic DNA from mature tree species often proves difficult. DNA extraction from needles, leaves, or buds is recommended in many protocols. Collecting these tissues from mature trees generally requires the use of firearms or climbing if sampling is to be nondestructive. As a result, sample collection is a major expense of many tree-based projects. Tree (and plant) tissues generally contain large amounts of polysaccharides and phenolic compounds that are difficult to separate from DNA. Many methods aim to overcom these problems, with most involving extraction in buffers containing the nonionic detergent cetyltrimethyl-ammonium bromide (CTAB), followed by numerous steps to clean contaminants from the DNA, using organic solvents and differential salt precipitation. These steps are time-consuming, such that isolation of DNA becomes the bottleneck in many molecular studies. This paper presents a new, efficient, cambium collection method for tree species and a DNA extraction protocol based on that of Doyle and Doyle (1987), with follow-up purification using the Wizard nuclei lysis and protein precipitation solutions (Promega). Results show a significant improvement in yield and DNA purity compared with other published methods, with consistently high yields of pure genomic DNA and high sample throughput. The relatively low cost per extraction, no requirement for use of liquid nitrogen, no requirement for freezer storage, and long-term sample stability after collection are important additional benefits.     

A rapid and inexpensive method for isolation of total DNA from Trichoderma spp (Hypocreaceae)

Extraction of high-quality genomic DNA for PCR amplification from filamentous fungi is difficult because of the complex cell wall and the high concentrations of polysaccharides and other secondary metabolites that bind to or co-precipitate with nucleic acids. We developed a modified sodium dodecyl sulfate/phenol protocol, without maceration in liquid nitrogen and without a final ethanol precipitation step. The A(260/280) absorbance ratios of isolated DNA were approximately 1.7-1.9, demonstrating that the DNA fraction is pure and can be used for analysis. Additionally, the A(260/230) values were higher than 1.6, demonstrating negligible contamination by polysaccharides. The DNA isolated by this protocol is of sufficient quality for molecular applications; this technique could be applied to other organisms that have similar substances that hinder DNA extraction. The main advantages of the method are that the mycelium is directly recovered from culture medium and it does not require the use of expensive and specialized equipment.     

Extraction of geminiviral DNA from a highly mucilaginous plant (Abelmoschus esculentus)

A protocol is described for the extraction of geminiviral DNA from bhendi yellow vein mosaic virus-infectedAbelmoschus esculentus (known as bhendi or okra) containing high amounts of mucilage and other phenolic compounds. This method involves extraction with a buffer containing sodium citrate at pH 6 and PEG precipitation of the virus followed by alkali lysis. The extraction buffer eliminates the mucilage and other polyphenols, PEG precipitates the viral particles and DNA and the alkali lysis enriches the replicative forms of the viral DNA. The extracted DNA could be digested with restriction enzymes and cloned without any interference from chromosomal DNA. The quality of the DNA extracted by this method was compared to three other common plant DNA extraction protocols and was found superior. This method was used for PCR amplification and cloning of the 2.7 kbp DNA-A of BYVMV.     

Comparison of strategies for the isolation of PCR-compatible, genomic DNA from a municipal biogas plants

The goal of the project was the extraction of PCR-compatible genomic DNA representative of the entire microbial community from municipal biogas plant samples (mash, bioreactor content, process water, liquid fertilizer). For the initial isolation of representative DNA from the respective lysates, methods were used that employed adsorption, extraction, or precipitation to specifically enrich the DNA. Since no dedicated method for biogas plant samples was available, preference was given to kits/methods suited to samples that resembled either the bioreactor feed, e.g. foodstuffs, or those intended for environmental samples including wastewater. None of the methods succeeded in preparing DNA that was directly PCR-compatible. Instead the DNA was found to still contain considerable amounts of difficult-to-remove enzyme inhibitors (presumably humic acids) that hindered the PCR reaction. Based on the isolation method that gave the highest yield/purity for all sample types, subsequent purification was attempted by agarose gel electrophoresis followed by electroelution, spermine precipitation, or dialysis through nitrocellulose membrane. A combination of phenol/chloroform extraction followed by purification via dialysis constituted the most efficient sample treatment. When such DNA preparations were diluted 1:100 they did no longer inhibit PCR reactions, while they still contained sufficient genomic DNA to allow specific amplification of specific target sequences.     

Polyethyleneimine-mediated chemical extraction of cytoplasmic His-tagged inclusion body proteins from Escherichia coli

The selectivity of polyethyleneimine (PEI) in DNA precipitation during chemical extraction was investigated. Chemical extraction was used to recover two His-tagged model proteins: gloshedobin, a thrombin-like enzyme from snake venom, and IbpA, a molecular chaperone, which were expressed mainly in the form of inclusion bodies. High DNA removal efficiency (more than 90%) was achieved at various cell densities (with OD600 ranging from 30 to 150) without affecting the solubility of host cell proteins. Compared to spermine-induced precipitation method reported elsewhere, PEI provided a higher DNA precipitation efficiency at a significantly lower cost. Moreover, PEI obviated the use of EDTA, which has been reported to be essential for the chemical extraction methods, hence exhibiting dual roles in replacing cost-prohibitive spermine and EDTA. The residual PEI in the post-extraction mixture was efficiently counteracted by addition of Mg2+, allowing the streamlined application of the extraction broth to immobilized metal affinity chromatography. Taken together, the PEI-mediated chemical extraction method provides a simpler and more economically viable processing route for the production of recombinant proteins whose expression is hampered by IB formation.     

A simple method for extraction of fungal genomic DNA

We have developed a new, simple and effective method for extraction of fungal genomic DNA. The initial steps involved suspension of freeze-dried mycelium in buffer containing sodium dodecyl sulphate, detachment of DNA from polysaccharides by mild shearing, NaCl precipitation of polysaccharides and protein, chloroform extraction and ethanol precipitation. The ethanol precipitate was then subjected to a second round of mild shearing, NaCl precipitation, chloroform extraction and ethanol precipitation. The procedure required approximately 1 h to perform. The method yielded 8-32 microg of high molecular weight DNA per 30 mg of freeze-dried mycelium when tested on six fungal species: Aspergillus niger, A. flavus, Fusarium graminarum, Neotyphodium lolii, Penicillium citrinum and Rhizopus nigricanes. The DNA was digestible with EcoRI, HindIII, SalI and BamHI. For the slow-growing N. lolii, a modification of the method was developed that removed the agar residue from colonies grown on agar plates by centrifugation at 13 000 rev min(-1) in the presence of CsCl. The modified method yielded 1.5-2 microg of high molecular weight DNA per colony.     

Purification of Genomic DNA with Minimal Contamination of Proteins

The purification is based on a set of solutions and a simple centrifugation procedure. Protocols are designed for an easy extraction and purification of genomic DNA from a wide range of samples, including whole blood, buffy coat, bone marrow, body fluids, buccal cells, tissues, mouse tails, etc. RBCs are lysed by dilution into a hypotonic solution. Tissues are broken down and digested by proteinase K in the presence of an anion detergent to release genomic DNA. After precipitation of the detergent and proteins, unique beads that bind proteins, lipids, and RNAs are added to achieve the supreme purity. Genomic DNA is then separated by alcohol precipitation. A proprietary nucleic acid precipitation reagent is used to enhance DNA recovery from low concentration samples. No DNA-binding beads or columns are used in the method, eliminating the problem of low yield and the risk of shearing of genomic DNA. The purified samples are free of proteins, lipids, salts, and RNA contamination. Purified samples are also stable for storage and suitable for all downstream applications.     

A rapid, efficient method for isolating DNA from yeast

A method is described for the purification of chromosomal and plasmid DNA from the yeast Saccharomyces cerevisiae. This method is rapid, gives 75% of theoretical yield, and produces DNA that can be cut with restriction endonucleases. Yeast cells are treated with zymolyase, and the resulting spheroplasts are lysed in the presence of the chaotropic agent guanidine hydrochloride. After a brief ethanol precipitation, protein is removed by treatment with proteinase K followed by phenol-chloroform extraction. After ethanol precipitation, the DNA is sufficiently pure for restriction analysis or for the transformation of Escherichia coli.     

A high-throughput protocol for extracting high-purity genomic DNA from plants and animals

DNA extraction techniques that employ the reversible binding of DNA to silica via chaotropic salts can deliver high-quality genomic DNA from plant and animal tissues, while avoiding the use of toxic organic solvents. Existing techniques that use this method are either prohibitively expensive, or are applicable to only a restricted set of taxa. Here we describe a cost-effective DNA extraction technique suitable for a wide range of plant and animal taxa that yields microgram quantities of high-molecular-weight genomic DNA at a throughput of 192 samples per day. Our technique is particularly robust for tissue samples that are insoluble or are rapidly discoloured or oxidized in standard DNA extraction buffers. We demonstrate the quality of DNA extracted using this method by applying the amplified fragment length polymorphism technique to plant species.     

模式小鼠总DNA三种提取方法比较

目的：建立简便、快捷、经济的模式小鼠总DNA提取方法,以快速鉴定大批量模式小鼠基因型。方法采用苯酚抽提法、异丙醇沉淀法、鼠耳煮沸法提取同种模式小鼠总DNA,对比DNA纯度、得率、耗费时间,并比较基因型鉴定结果。结果苯酚抽提法得率最高,异丙醇沉淀法最低;而纯度则按照苯酚抽提法、异丙醇沉淀法、鼠耳煮沸法顺序递减;在耗时上鼠耳煮沸法最短。三种方法提取的DNA均可做模版用于基因型鉴定。结论鼠耳煮沸法操作简单、成本最低,快速、基因型鉴定结果可靠,可用于规模化的基因型鉴定实验中。     

PCR amplification of crude microbial DNA extracted from soil

A rapid, inexpensive, large-scale DNA extraction method involving minimal purification hasbeen developed that is applicable to various soil types. DNA was extracted from 100 g of soilusing direct lysis with glass beads and sodium dodecyl sulphate (SDS) followed by polyethyleneglycol precipitation, potassium acetate precipitation, phenol extraction and isopropanolprecipitation. The crude extract could be used in PCR directed at high-copy number (bacterialsmall subunit rRNA) and single-copy (fungal β-tubulin) genes.