Comparison between modified DNA extraction protocols and commercial isolation kits in grapevine (Vitis vinifera L.)

Various protocols have been developed and used for DNA extraction in grapevine. However, owing to the long duration of the isolation steps in previously developed protocols, researchers have preferred to use isolation kits for studies in recent years. In our study, the DNA yield and purity obtained using six methods - namely three DNA isolation protocols and three commercial DNA isolation kits - were compared. Modifications were made and the isolation steps were shortened in the previously developed DNA isolation protocols to achieve more rapid and practical protocols. The samples were taken from plants grown under vineyard and greenhouse conditions in two periods during spring and autumn. The best results among the six DNA isolation methods were discussed. The results were also supported with polymerase chain reaction analyses conducted with isolated DNAs.     

DNA isolation methods for medicinal and aromatic plants

Several protocols described for plant DNA isolation fail to produce good quality DNA from medicinal herbs and aromatic plants. These plants contain exceptionally high amounts of secondary metabolites that interfere with DNA isolation. To address this problem, we developed 2 DNA isolation methods for sundew and tarragon that produce DNA suitable for molecular biological applications. One of the methods also is applicable for milfoil and Siberian ginseng.     

Comparison of Some Plant DNA Extraction Methods

DNA isolation is a routine procedure when performed in laboratory environment, yet in the field it may still remain problematic. This is especially true of some crop species bred for useful metabolites that may also hinder DNA extraction. Here we compare the efficiency of DNA extraction protocols and commercial DNA isolation kits when used on samples from Helianthus and Allium. Since extraction of DNA is known to be compromised by co-extraction of PCR-inhibiting metabolites, the isolation of DNA was followed by PCR as a testing procedure for the isolation step. The MagnoPrime Fact and MagnoPrime Uni DNA isolation kits were better suited for field work due to faster processing times and smaller required amount of starting material (20 mg fresh/0.5 mg dry). In all cases the subsequent PCR managed to amplify the DNA fragments of interest well enough to be useful in further research.     

A Method for Isolation of Chloroplast DNA and Mitochondrial DNA from Sunflower

We present a method for isolation of chloroplast and mitochondrial DNA from sunflower seedlings. The protocol includes: organelle isolation, deoxyribonuclease treatment, lysis, deproteinisation and a final DNA purification with sodium dodecyl sulphate and potassium acetate. The organelle DNA yield is 5–10 micrograms per gram of tissue and the DNA is fully restrictable. The technique is inexpensive and appropriate for the isolation of multiple samples of organelle DNA from a small amount of tissue.     

Rapid Isolation of DNA from Dry and Fresh Samples of Plants Producing Large Amounts of Secondary Metabolites and Essential Oils

The presence of certain metabolites has been observed to interfere with DNA isolation procedures and downstream reactions such as DNA restriction, amplification and cloning. The chemotypic heterogeneity among species may not permit optimal DNA yields with a single protocol, and thus, even closely related species may require different isolation protocols. Here we describe the essential steps of a rapid DNA isolation protocol that can be used for diverse medicinal and aromatic plants, which produce essential oils and secondary metabolites such as alkaloids, flavanoids, phenols, gummy polysaccharides, terpenes and quinones. The procedure is applicable to dry as well as fresh plant tissues. This protocol, in our experiments, permitted isolation of DNA from tissues of diverse plant species and produced fairly good yields. The isolated DNA proved amenable to PCR amplification and restriction digestion.     

Protocol for Optimal Quality and Quantity Pollen DNA Isolation from Honey Samples

The present study illustrates an optimized sample preparation method for an efficient DNA isolation from low quantities of honey samples. A conventional PCR-based method was validated, which potentially enables characterization of plant species from as low as 3 ml bee-honey samples. In the present study, an anionic detergent was used to lyse the hard outer pollen shell, and DTT was used for isolation of thiolated DNA, as it might facilitate protein digestion and assists in releasing the DNA into solution, as well as reduce cross-links between DNA and other biomolecules. Optimization of both the quantity of honey sample and time duration for DNA isolation was done during development of this method. With the use of this method, chloroplast DNA was successfully PCR amplified and sequenced from honey DNA samples.     

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.     

High Throughput BAC DNA Isolation for Physical Map Construction of Sorghum (Sorghum bicolor)

With the aim of constructing a physical map of sorghum, we developed a rapid, high throughput approach for isolating BAC DNA suitable for restriction endonuclease digestion fingerprinting, PCR- based STS-content mapping, and BAC-end sequencing. The system utilizes a programmable 96 channel liquid handling system and associated accessories that permit bacterial cultivation and DNA isolation in 96-well plate format. This protocol details culture conditions that optimize bacterial growth in deep-well plates and criteria for BAC DNA isolation to obtain high yields of quality BAC DNA. The system is robust, accurate, and relatively cost-effective. The BAC DNA isolation system has been tested during efforts to construct a physical map of sorghum.     

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.     

Adaptation of a Silica Membrane-based Kit for Purification of Sequencing-ready BAC DNA

We describe a modification of a protocol for the isolation of BAC DNA using a silica membrane-based kit designed for the isolation of plasmid DNA. The major advantages of this protocol are the expediency of the procedure, the high yield and purity, and the high quality of the BAC DNA that is suitable for direct sequencing.     

Evaluation of four methods of DNA recovery from Mycobacterium avium subspecies paratuberculosis present in intestine tissue of goats and comparative sensitivity of IS900 PCR with respect to culture for diagnosis of Johne's disease

Low sensitivity of PCR reaction for detection of Mycoobacterium avium subspecies paratuberculosis (MAP) in tissues and fecal samples is mainly attributed to false negative results. Present study was undertaken to compare four methods of DNA isolation from tissues of infected animals and to determine most sensitive protocol for the recovery of DNA, suitable for IS900 PCR based detection of Johne's disease infection. Method I, the traditional van Soolingen2 method of DNA isolation was adopted for the isolation of DNA from tissues. Method II was modification (hexadecyl pyridinium chloride-HPC treatment) of van Soolingen2 method. Method III was traditional tissue DNA isolation method based on tissue lysis buffer. Method IV was modification of method III (HPC treatment). Using four methods of DNA isolation from 25 intestinal tissues of clinically infected goats, DNA was isolated from 15 (60.0%), 18 (72.0%), 13 (52.0%) and 13 (52.0%) tissues using method I, II, III and IV, respectively. All isolated DNA preparations were positive for MAP in IS900 PCR. HPC treatment enhanced the recovery of DNA from tissues of infected animals using method II. Therefore, method II can improve the diagnosis MAP infection using IS900 PCR.     

Comparison of Methods for Isolation of Bacterial and Fungal DNA from Human Blood

The study aimed at optimization of DNA isolation from blood of representatives of four microbial groups causing sepsis, i.e., Gram negative: Escherichia coli, Gram positive: Staphylococcus aureus, yeast: Candida albicans, and filamentous fungus: Aspergillus fumigatus. Additionally, the five commercial kits for microbial DNA isolation from the blood were tested. The developed procedure of DNA isolation consisted of three consecutive steps, i.e., mechanical disruption, chemical lysis, and thermal lysis. Afterward, DNA was isolated from the previously prepared samples (erythrocyte lysis) with the use of five commercial kits for DNA isolation. They were compared paying heed to detection limit, concentration, DNA purity, and heme concentration in samples. The isolation of DNA without preliminary erythrocyte lysis resulted in far higher heme concentration than when lysis was applied. In the variant with erythrocyte lysis, two of the commercial kits were most effective in purifying the DNA extract from heme. Designed procedure allowed obtaining microbial DNA from all four groups of pathogens under study in the amount sufficient to conduct the rtPCR reaction, which aimed at detecting them in the blood.     

Isolation of DNA using magnetic nanoparticles coated with dimercaptosuccinic acid

Lately, the isolation of DNA using magnetic nanoparticles has received increased attention owing to their facile manipulation and low costs. Although methods involving their magnetic separation have been extensively studied, there is currently a need for an efficient technique to isolate DNA for highly sensitive diagnostic applications. We describe herein a method to isolate and purify DNA using biofunctionalized superparamagnetic nanoparticles synthesized by a modified polyol method to obtain the desired monodispersity, followed by surface modification with meso-2,3-dimercaptosuccinic acid (DMSA) containing carboxyl groups for DNA absorption. The DMSA-coated magnetic nanoparticles (DMSA-MNPs) were used for the isolation of DNA, with a maximum yield of 86.16%. In particular, we found that the isolation of DNA using small quantities of DMSA-MNPs was much more efficient than that using commercial microbeads (NucliSENS-easyMAG, BioMérieux). Moreover, the DMSA-MNPs were successfully employed in the isolation of genomic DNA from human blood. In addition, the resulting DNA–nanoparticle complex was directly subjected to PCR amplification without prior elution, which could eventually lead to simple, rapid, sensitive and integrated diagnostic systems.     

Isolation of high-molecular-weight DNA from insects.

A simple and rapid method for the isolation of high-molecular-weight DNA from insects is described. The method does not require CsCl ultracentrifugation or extensive dialysis. High-molecular-weight DNA was obtained within 24 h. Since the entire insect was used for DNA isolation, an initial nuclei-enriched fraction was required. Genomic DNA was extracted from lysed nuclei by organic phase separation (liquid/liquid extraction). This method has been successfully applied to the isolation and purification of DNA from eight different adult insects (Heliothis zea, Musca autumnalis, M. domestica, Blatta orientalis, Tenebrio molitor, Lymantria dispar, Ostrinia nubilalis, and Manduca sexta). The recovered DNA can be cleaved with restriction endonucleases, ligated efficiently using standard cloning vectors, and hybridized to synthetic oligonucleotides.     

Rapid preparation of PCR-amplifiable fungal DNA by benzyl bromide extraction

For isolation of fungal DNA for PCR amplification, we compared three DNA isolation methods: enzymatic cleavage and the use of benzyl chloride or benzyl bromide. Since benzyl bromide is more reactive, its use enabled us to readily isolate the total nucleic acids as a DNA template source from various fungi, including dematiaceous hyphomycetes, for RAPD analysis.     

Rapid and efficient protocol for DNA extraction and molecular identification of the basidiomycete Crinipellis perniciosa

DNA isolation from some fungal organisms is difficult because they have cell walls or capsules that are relatively unsusceptible to lysis. Beginning with a yeast Saccharomyces cerevisiae genomic DNA isolation method, we developed a 30-min DNA isolation protocol for filamentous fungi by combining cell wall digestion with cell disruption by glass beads. High-quality DNA was isolated with good yield from the hyphae of Crinipellis perniciosa, which causes witches' broom disease in cacao, from three other filamentous fungi, Lentinus edodes, Agaricus blazei, Trichoderma stromaticum, and from the yeast S. cerevisiae. Genomic DNA was suitable for PCR of specific actin primers of C. perniciosa, allowing it to be differentiated from fungal contaminants, including its natural competitor, T. stromaticum.     

商城肥鲵二碱基重复和四碱基重复微卫星DNA的结构特征及对筛选效率的影响

两栖类有尾目物种的微卫星分离中的筛选成功率常常较低。为探索微卫星结构对筛选效率的影响,本研究通过AFLP快速分离法(fast isolation by AFLP of sequences containing repeats,FIASCO)对商城肥鲵(Pachyhynobius shangchengensis)二碱基重复类型和四碱基重复类型微卫星进行分离,并对微卫星序列进行了分析。研究中发现二碱基微卫星位点多以微卫星DNA家族形式存在,并因此导致了微卫星位点分离较低的筛选率;在四碱基重复的微卫星位点中未发现微卫星DNA家族的存在。对研究中得到的3个微卫星DNA家族的分析发现,同一家族的上、下游侧翼序列变异程度存在差异;毗邻微卫星重复单元区的侧翼序列碱基变异程度较高,而较远处的区段则相对保守。这些结构特征可能反映出微卫星DNA家族在演化中的复杂性。本文的研究结果提示在两栖动物的一些类群中,微卫星的筛选必须考虑微卫星DNA家族的影响,选取适宜的碱基重复类型将是决定筛选效率的关键。     

A method for isolation and purification of peanut genomic DNA suitable for analytical applications

Numerous methods are available for isolation of plant genomic DNA, but in practice these procedures are empirical due to variability in plant tissue composition. Consistent isolation of quality DNA from peanut (Arachis hypogaea L.) is particularly problematic due to the presence of phenolic compounds and polysaccharides. Inconsistencies in extraction results can be attributed to the age and growth stage of the plant material analyzed. Mature leaves have higher quantities of polyphenols, tannins, and polysaccharides that can contaminate DNA during isolation. We show that four published protocols could not be used to isolate peanut DNA of sufficient quality for PCR amplification or Southern hybridization. We have devised a new protocol that uses DEAE-cellulose purification to isolate peanut DNA useful for downstream applications.     

Rapid isolation of high molecular weight plant DNA.

A method is presented for the rapid isolation of high molecular weight plant DNA (50,000 base pairs or more in length) which is free of contaminants which interfere with complete digestion by restriction endonucleases. The procedure yields total cellular DNA (i.e. nuclear, chloroplast, and mitochondrial DNA). The technique is ideal for the rapid isolation of small amounts of DNA from many different species and is also useful for large scale isolations.     

A METHOD FOR ISOLATION OF CHROMOSOMAL AND PLASMID DNA FROM YERSINIA ENTEROCOLITICA FOR SIMULTANEOUS AMPLIFICATION BY POLYMERASE CHAIN REACTION: A POSSIBLE MODEL FOR OTHER BACTERIA

A commercial DNA isolation kit was evaluated for simultaneous isolation of chromosomal and plasmid DNA from Yersina enterocolitica for polymerase chain reaction amplification. The genomic and plasmid DNA samples obtained by use of the kit were suitable for use in polymerase chain reactions both individually and in multiplex reactions. The results obtained by the use of the kit suggest that this kit may be applied to isolate both genomic and plasmid DNA from other microorganisms for polymerase chain reaction amplification.