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.     

The single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction: twenty-something years on

Since its introduction, the 'single-step' method has become widely used for isolating total RNA from biological samples of different sources. The principle at the basis of the method is that RNA is separated from DNA after extraction with an acidic solution containing guanidinium thiocyanate, sodium acetate, phenol and chloroform, followed by centrifugation. Under acidic conditions, total RNA remains in the upper aqueous phase, while most of DNA and proteins remain either in the interphase or in the lower organic phase. Total RNA is then recovered by precipitation with isopropanol and can be used for several applications. The original protocol, enabling the isolation of RNA from cells and tissues in less than 4 hours, greatly advanced the analysis of gene expression in plant and animal models as well as in pathological samples, as demonstrated by the overwhelming number of citations the paper gained over 20 years.     

Rapid purification of Ti plasmids from Agrobacterium by ethidium bromide treatment and phenol extraction

An efficient method is described for the purification of Ti plasmid DNA from Agro-bacterium. The procedure is based on the relative binding capacity of ethidium bromide to supercoiled plasmid DNA and linear DNA and on the high solubility of ethidium bromide in phenol. Following treatment with ethidium bromide, more than 87% of linear chromosomal DNA and most of the RNA was present in the phenol phase, while 91% of Ti plasmid DNA was recovered from the aqueous phase. The Ti plasmid DNA was sufficiently pure for restriction endonuclease analysis and cloning. The procedure is simple, fast and provides eight times higher yield than the standard isopycnic ultracentrifugation method.     

More than skin and bones: Comparing extraction methods and alternative sources of DNA from avian museum specimens

Next‐generation sequencing has greatly expanded the utility and value of museum collections by revealing specimens as genomic resources. As the field of museum genomics grows, so does the need for extraction methods that maximize DNA yields. For avian museum specimens, the established method of extracting DNA from toe pads works well for most specimens. However, for some specimens, especially those of birds that are very small or very large, toe pads can be a poor source of DNA. In this study, we apply two DNA extraction methods (phenol–chloroform and silica column) to three different sources of DNA (toe pad, skin punch and bone) from 10 historical avian museum specimens. We show that a modified phenol–chloroform protocol yielded significantly more DNA than a silica column protocol (e.g., Qiagen DNeasy Blood & Tissue Kit) across all tissue types. However, extractions using the silica column protocol contained longer fragments on average than those using the phenol–chloroform protocol, probably as a result of loss of small fragments through the silica column. While toe pads yielded more DNA than skin punches and bone fragments, skin punches proved to be a reliable alternative source of DNA and might be especially appealing when toe pad extractions are impractical. Overall, we found that historical bird museum specimens contain substantial amounts of DNA for genomic studies under most extraction scenarios, but that a phenol–chloroform protocol consistently provides the high quantities of DNA required for most current genomic protocols.     

一种提取质粒DNA的改良方法

本文详细介绍了一种改良碱裂解法提取质粒ＤＮＡ的方法,该法采用ＮＨ４Ａｃ代替苯酚和氯份的抽提过程,得率高,质量好,完全达到了分子生物学常规实验的要求,如酶切、连接、转化大肠杆菌、ＰＣＲ等,甚至用于序列测定和植物遗传转化,该法重复性好,操作简单、实用．     

Simple and efficient genomic DNA extraction protocol for molecular characterisation of Phytophthora colocasiae causing taro leaf blight

Genomic DNA extraction protocol with relatively high quantity and purity is prerequisite for the successful molecular identification and characterisation of plant pathogens. Conventional DNA extraction methods are often time-consuming and yield only very poor quantity of genomic DNA for samples with higher mycelial age. In our laboratory, we have aimed at establishing an efficient DNA isolation procedure, exclusively for the oomycete pathogen Phytophthora colocasiae causing serious leaf blight disease in taro. For this a phenol free protocol was adopted, which involves SDS/Proteinase K-based inactivation of protein contaminants, extraction of nucleic acids using chloroform: isoamyl alcohol and later precipitation of genomic DNA using isopropanol and sodium acetate. The purity of the isolated DNA was analysed by A_260/280 and A_260/230 spectrophotometric readings and confirmed by restriction digestion with restriction enzyme Eco RI. In this study, a comparative assessment was done with CTAB method and the commercial genomic DNA purification kit (Thermo Fisher Scientific, Fermentas, EU). The extracted DNA was found to be suitable for further downstream applications like ITS amplification of the rDNA ITS region and PCR amplification with species-specific primers.     

Simultaneous and rapid isolation of bacterial and eukaryotic DNA and RNA: a new approach for isolating DNA.

A very simple procedure for the simultaneous preparation of genomic DNA and total RNA is described. The procedure is essentially the same for eukaryotes and prokaryotes except for the lysis buffer and can be used for small or large numbers of cells. Mammalian cells are lysed in sodium dodecyl sulfate and bacterial cells are lysed in Triton X-100, both in the presence of EDTA. RNA is obtained in the aqueous phase after phenol (acidic pH):chloroform:isoamyl alcohol extraction. DNA is eluted out of the organic phase (and the interface) into the aqueous phase by increasing the pH with highly basic 1 M Tris solution. The method is extremely rapid for small or large numbers of cells, and several large samples can be processed in one day. The qualities of both nucleic acids are excellent and the yield is high.     

A simple procedure for maximum yield of high-quality plasmid DNA

We have established a simple procedure for the rapid isolation of high-quality plasmid DNA suitable for various molecular techniques and provided a step-by-step protocol. The DNA samples isolated by this procedure have been used successfully for double-stranded DNA sequencing, restriction enzyme mapping, subcloning, in vitro mutagenesis, generation of deletion clones and so on. The procedure is highly reproducible, and superior quality DNA can be obtained without the use of phenol, chloroform or other organic solvents.     

High efficiency method to obtain supercoiled DNA with a commercial plasmid purification kit

Supercoiled state corresponds to the active form for plasmid applications. The relaxed circular form of plasmids is often inactive or poorly active. To obtain significant amounts of almost fully supercoiled DNA, we modified the standard protocol of a commercially available Qiagen plasmid purification kit. Our changes led to isolation of almost 100% of the plasmids in the supercoiled state. The modified protocol was used to purify different plasmids with consistent results. The purified plasmids maintain supercoiled state for about two months. The modified protocol is very advantageous because it allows easy DNA production with high degree of supercoiled form at low cost.     

A rapid and simple method for screening large numbers of recombinant DNA clones

A simple and rapid method has been described for the isolation of plasmid, phagemid and phage DNAs. Hundreds of recombinant clones can be screened in one day employing this method. It takes half an hour to prepare plasmid DNA from ten clones, and the DNA prepared from a single colony using this method is of sufficient quality and in sufficient amount to perform at least five restriction digestions. This method eliminates the need for RNase treatment and phenol chloroform extraction if the plasmids are needed only for the restriction digestion. If needed, RNAs can be removed after restriction digestion by adding RNase and incubating for two minutes at room temperature. After RNase treatment and phenol/chloroform extraction, the plasmid DNA serves as a good template for sequencing. The DNA can be stored at -20 degrees C for over eight weeks.     

Effect of saliva processing on bacterial DNA extraction

More than 700 bacterial species inhabit oral cavity of humans. Various oral diseases are related to changes in the structure of this complex community. Their pathogenesis can, thus, be better understood by study of oral microbial flora. As many bacteria are refractory to cultivation, molecular approaches based on PCR followed by downstream analysis are more suitable for community analysis than culture dependent methods. Effective DNA extraction from the sample matrix is a fundamental part of the pre-analytical phase but it can be influenced by processing of the starting material. The aim of this study was to analyze the effects of saliva processing on DNA extraction using several non-commercial isolation procedures. Bacterial chromosomal DNA was extracted from three different sample matrices: fresh saliva, diluted saliva and pelleted saliva using four different extraction methods: phenol chloroform protocol, benzyl-chloride protocol, extraction with Chelex-100 and extraction with Triton X. Extraction from different saliva samples and the use of different extraction methods significantly affected the effectiveness of DNA extraction. The most suitable material for bacterial DNA extraction for molecular analysis is a fresh saliva sample. The most effective methods for isolating salivary DNA are the benzyl-chloride protocol and Chelex-100 extraction. Our results have implications for studies concentrating on salivary microbiome and its role in the pathogenesis of oral diseases.     

A method for the preparation of high molecular weight yeast DNA

A method is described for the isolation of high molecular weight DNA in solution using the principles that have allowed electrophoresis of chromosome-sized DNA in pulse field gradient electrophoresis. Stationary phase yeast cells are converted to spheroplasts by the action of zymolyase in 1 M sorbitol. In the presence of EDTA and sodium lauroyl sarcosinate, proteins are digested with proteinase K. DNA is extracted with phenol and chloroform, and high molecular weight DNA is collected by ethanol precipitation. RNA is removed by RNase digestion of the redissolved pellet, and RNase is removed by chloroform extraction followed by a second ethanol precipitation. The method is rapid and gives a high yield of DNA that is readily digestible by restriction endonucleases.     

Isolation of DNA from bacterial samples of the human gastrointestinal tract

The human gastrointestinal (GI) tract contains a complex microbial community that develops in time and space. The most widely used approaches to study microbial diversity and activity are all based on the analysis of nucleic acids, DNA, rRNA and mRNA. Here, we present a DNA isolation protocol that is suitable for a wide variety of GI tract samples, including biopsies with minute amounts of material. The protocol is set up in such a way that sampling can be performed outside the laboratory, which offers possibilities for implementation in large intervention studies. The DNA isolation is based on mechanical disruption, followed by isolation of nucleic acids using phenol:chloroform:isoamylalcohol extraction. In addition, it includes an alternative DNA isolation protocol that is based on a commercial kit. These protocols have all been successfully used in our laboratory, resulting in isolation of DNA of sufficient quality for microbial diversity studies. Depending on the number of samples and sample type, the whole procedure will take approximately 2.5-4 hours.     

Purification of human genomic DNA from whole blood using sodium perchlorate in place of phenol

We have developed a new, rapid method for the extraction of human genomic DNA from whole blood samples. Traditionally, genomic DNA has been extracted from blood by overnight proteinase K digestion of lysed peripheral lymphocytes followed by phenol/chloroform extraction. In addition to being time consuming, the use of phenol involves inherent risks due to the toxic nature of the reagent. Our method for the extraction of DNA from whole blood uses sodium perchlorate and chloroform instead of phenol with a significant time savings realized as well as fewer hazards to the technician. Furthermore, DNA prepared by this new method is an excellent substrate for restriction endonuclease digestion and Southern hybridization analysis.     

The effects of pH and salts on nucleic acid partitioning during phenol extraction

The partitioning of nucleic acids is sensitive to pH during phenol extraction. However, the exact effects of pH on phenol extraction had not been systematically investigated, and the mechanism of which were not fully elucidated. In this paper, we showed that the partitioning of nucleic acids was determined neither solely by the pH of the aqueous buffer being used, nor by the “pH of the phenol”; the latter is a completely wrong conception. We demonstrated that a key determinant for nucleic acid partitioning during phenol extraction was the equilibrated pH of the aqueous phase, which should be defined as the pH of phenol extraction. For example, when 50?mM NaAc-HAc buffer at pH of 3.47 was mixed with an equal volume of water-saturated phenol, the equilibrated pH of aqueous phase would be raised to ～3.84. At this pH, almost all of genomic DNA partitioned into the phenol phase, and genomic DNA-free total RNA was retained in the aqueous phase. Several salts were found affecting the partitioning of nucleic acids during phenol extraction in different manners. Based on these results, a low-cost and efficient method for genomic DNA-free total RNA extraction was developed.     

Evaluating genomic DNA extraction methods from human whole blood using endpoint and real-time PCR assays

The extraction of genomic DNA is the crucial first step in large-scale epidemiological studies. Though there are many popular DNA isolation methods from human whole blood, only a few reports have compared their efficiencies using both end-point and real-time PCR assays. Genomic DNA was extracted from coronary artery disease patients using solution-based conventional protocols such as the phenol–chloroform/proteinase-K method and a non-phenolic non-enzymatic Rapid-Method, which were evaluated and compared vis-a-vis a commercially available silica column-based Blood DNA isolation kit. The appropriate method for efficiently extracting relatively pure DNA was assessed based on the total DNA yield, concentration, purity ratios (A₂₆₀/A₂₈₀ and A₂₆₀/A₂₃₀), spectral profile and agarose gel electrophoresis analysis. The quality of the isolated DNA was further analysed for PCR inhibition using a murine specific ATP1A3 qPCR assay and mtDNA/Y-chromosome ratio determination assay. The suitability of the extracted DNA for downstream applications such as end-point SNP genotyping, was tested using PCR-RFLP analysis of the AGTR1-1166A>C variant, a mirSNP having pharmacogenetic relevance in cardiovascular diseases. Compared to the traditional phenol–chloroform/proteinase-K method, our results indicated the Rapid-Method to be a more suitable protocol for genomic DNA extraction from human whole blood in terms of DNA quantity, quality, safety, processing time and cost. The Rapid-Method, which is based on a simple salting-out procedure, is not only safe and cost-effective, but also has the added advantage of being scaled up to process variable sample volumes, thus enabling it to be applied in large-scale epidemiological studies.     

Optimization of the method of isolation of microamounts of plasmid DNA from lactobacilli

Modification of the alkaline lysis at elevated temperature technique is proposed isolation of plasmid DNA from lactobacilli. Modification consists of colorimetric control of culture phase during the biomass growth, pH control at the probes treatment with lysozyme and alkaline solution of natrium dodecylsulfate by adding the indicator bromcrezolpurple into the medium for biomass growth. The high concentration of lysozyme is used (10 mkg.ml-1). Lactobacilli are lysed at 2 min incubations of the probes with the lytic solution in the boiling water bath. The treatment of the probes by proteinase K, by the mixture of chloroform:phenol:isoamyl spirit (25:24:1 vol/vol/vol) and by diethylpirocarbonate increased considerably the quality of the obtained DNA preparations. The modified technique is suitable for isolation of the plasmid DNA from lactobacilli of different species, enterococci, streptococci and other lactic bacteria. The connection of antibiotic resistance marker and the plasmid profile of lactobacilli under different conditions with the presence of the plasmid DNA- protein complex is discussed.     

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.     

鳞翅目成虫乙醇保存标本基因组DNA的提取及在微卫星研究中的应用

高质量的基因组DNA样品是分子生态学研究的先决条件。本研究目的在于探索从东方粘虫Pseudaletia separata (Walker)成虫自然种群的乙醇保存标本中分离高质量基因组DNA的有效方案。在2 mL微型离心管中进行4种提取方案的实验比较,结果发现采用传统的苯酚抽提方法的2种方案提取腹部中段组织的基因组DNA,样品合格率只有7.69%~40%。但是,如果在苯酚抽提以前加入高浓度盐和十六烷基三甲基溴化铵（CTAB）,就会使DNA样品合格率达到68.42%~95.28%,而且DNA平均产量达到5.59~10.04 mg/g,明显高于前者的2.83~5.78 mg/g （统计检验表明,在不同种群中差异显著或不显著）。研究结果还证明腹部组织比胸部组织更适宜提取DNA。对来自一个自然种群的99头东方粘虫DNA合格样品的统计分析表明,DNA提取总量（μg）与组织样品用量（mg）之间存在弱的正相关关系,平均DNA提取量（mg/g）与组织样品用量（mg）之间存在中度负相关关系。总之,在2 mL微型离心管中,用10~20 mg腹部组织,利用CTAB+苯酚抽提方法可以获得高纯度和高含量的基因组DNA样品。用该方案提取的基因组DNA能够顺利地进行微卫星位点的分离和基因分型。     

Rapid and high quality DNA isolation from Origanum onites for RAPD and ISSR analysis

Origanum onites is an economically important medicinal plant with high essential oil content. Lack of an appropriate DNA isolation procedure is a limiting factor for any molecular study of this plant. We have used a protocol for genomic DNA isolation based on a hexadecyltrimethylammonium bromide (CTAB) method described for other plant species. The method involves mortar grinding of leaf tissue, modified CTAB extraction using high salt concentrations and polyvinyl pyrrolidone, and successive isoamyl alcohol/chloroform extractions. The yield was approx. 20 microg DNA per 200 mg of initial fresh plant material. The genomic DNA obtained by this method was suitable to be used in restriction digests, inter simple sequence repeat (ISSR) and randomly amplified polymorphic DNA (RAPD) reactions. This extraction method should facilitate the molecular analysis of Origanum chemotypes.