A simple and reliable method for DNA extraction from bivalve mantle

A simple and reliable method was developed for extracting genomic DNA from preserved mantle tissues of Pacific oyster Crassostrea gigas for reproducible PCR amplification. The method was based on destruction of the tissue using Proteinase K, Chelex 100 resin, detergents, and urea, followed by preferential capturing of genomic DNA with silica particles. Approximately 5 mg of mantle tissue provided a sufficient quality and quantity of DNA for several hundreds of PCR reactions amplifying the hypervariable mitochondrial DNA intergenic spacer, which is a useful genetic marker for population structure analysis of Pacific oyster. The method can be applied for DNA preparation from not only fresh and frozen but also ethanol-preserved mantle tissues, so this rapid and economical method can serve for investigating a large number of bivalve specimens collected in the field and next transported in ethanol at ambient temperature.     

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 simple method of DNA extraction for Eimeria species

A new, simple method is described for extracting DNA from coccidia (Eimeriidae) oocysts. In our hands this method works well for all Eimeria oocysts and, presumably, will work equally well for oocysts of other coccidia genera. This method combines the two steps of breaking oocyst and sporocyst walls, and dissolving the sporozoite membrane in one step. This greatly simplifies the currently used DNA extraction procedures for Eimeria species and overcomes the disadvantages of existing DNA extraction methods based on glass-bead grinding and sporozoite excystation procedures. Because all the procedures are done in a 1.5-ml microfuge tube, which minimizes the loss of DNA in the extraction procedures, this method is especially suitable for samples with small number of oocysts. In addition, this method directly lyses the oocyst and sporocyst walls as well as the sporozoite membrane in a continuous incubation; therefore, it does not require the sporozoites to be alive. The results of PCR experiments indicate that this method generates better quality of DNA than what the existing glass-bead grinding method does for molecular analysis, and is suitable for both large or small number (<10(2) oocysts) of living or dead oocyst samples.     

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.     

A cost-effective,simple and high-throughput method for DNA extraction from insects

Abstract We present a high-throughput cost-effective method to extract DNA suitable for polymerase chain reaction (PCR) from insect tissue. The method uses standard 200 μL-deep 96-well plates in which samples are ground, digested and subsequently purified. The test extraction using four different insect species and controlling for potential contamination showed that the method yields good-quantity and quality DNA. PCR with mitochondrial and nuclear primers was reliable. The proposed extraction protocol combines the speed of commercial 96-well plate methods with the economies associated with readily available and cheap laboratory chemicals, consumables and equipment. Therefore, this method is particularly suitable for low-budget research projects and for laboratories with only basic equipment present.     

A simple method for DNA extraction from marine bacteria that produce extracellular materials

We present a simple method for extracting DNA from the marine bacteria Hahella chejuensis, a Streptomyces sp., and a Cytophaga sp. Previously, DNA purification from these strains was hindered by the presence of extracellular materials. In our extraction method, the marine bacteria are lysed by freezing and grinding in liquid nitrogen, and treated with SDS. The extracted DNA is purified using a phenol/chloroform mixture, and precipitated in isopropanol. The extracted DNA is of high quality and suitable for molecular analyses, such as PCR, restriction enzyme digestion, genomic DNA blot hybridization, and genomic DNA library construction. We used this method to extract genomic DNA from several other marine bacteria. Our method is a reproducible, simple, and rapid technique for routine DNA extractions from marine bacteria. Furthermore, the low cost of this method makes it attractive for large-scale studies.     

A simple and efficient method for DNA extraction from grapevine cultivars andVitis species

A quick, simple, and reliable method for the extraction of DNA from grapevine species, hybrids, andAmpelopsis brevipedunculata (Vitaceae) has been developed. This method, based on that of Doyle and Doyle (1990), is a CTBA-based extraction procedure modified by the use of NaCl to remove polysaccharides and PVP to eliminate polyphenols during DNA purification. The method has also been used successfully for extraction of total DNA from other fruit species such as apple (Malus domestica), apricot (Prunus armeniaca), cherry (Prunus avium), peach (Prunus persica), plum (Prunus domestica), and raspberry (Rubus idaeus). DNA yield from this procedure is high (up to 1 mg/g of leaf tissue). DNA is completely digestible with restriction endonucleases and amplifiable in the polymerase chain reaction (PCR), indicating freedom from common contaminating compounds.     

A simple and efficient method for PCR amplifiable DNA extraction from ancient bones

A simple and effective modified ethanol precipitation-based protocol is described for the preparation of DNA from ancient human bones. This method is fast and requires neither hazardous chemicals nor special devices. After the powdering and incubating of the bone samples Dextran Blue was added as a carrier for removing the PCR inhibitors with selective ethanol precipitation. This method could eliminate the time-consuming separate decalcification step, dialysis, application of centrifugation-driven microconcentrators and the second consecutive PCR amplification. The efficiency of this procedure was demonstrated on ten 500–1200-year-old human bones from four different Hungarian burial sites. A mitochondrial specific primer pair was used to obtain sequence information from the purified ancient DNA. The PCR amplification, after our DNA extraction protocol, was successful from each of the 10 bone samples investigated. The results demonstrate that extraction of DNA from ancient bone samples with this new approach increases the success rate of PCR amplification.     

A simple and efficient method for the oligodeoxyribonucleotide-directed mutagenesis of double-stranded plasmid DNA.

A method for the oligodeoxyribonucleotide-directed mutagenesis of double-stranded DNA without the necessity for phenotypic selection is described. Plasmids denatured with alkali and purified by adsorption to and elution from nitrocellulose have single-stranded regions where primers can hybridize and serve as templates for a T7 DNA polymerase-catalyzed synthesis of complementary mutant DNA strands. When this procedure was carried out such that the original nonmutant strand contained uracil [method of Kunkel, Proc. Natl. Acad. Sci. USA 82(1985)488-492], mutation frequencies of between 30% and 40% were obtained. The technique has been used to generate mutant genes in plasmids of a wide variety of sizes. The largest plasmid manipulated and successfully mutagenized was 22 kb. The method is rapid and efficient and is not dependent upon either f1 phage vectors or the presence of restriction sites in the vicinity of the sequence targeted for mutation.     

A simple method for the preparation of the covalently closed circular form of plasmid DNA

We describe a simple, rapid, inexpensive method for isolation of covalently closed circular plasmid DNA. The method involves the electrophoresis of crude DNA preparations in an agarose gel, electrotransfer onto a dialysis membrane and elution of the highly purified circular covalently closed plasmid DNA. Native and recombinant plasmid DNA have been purified by this method and shown to be suitable for restriction enzyme digestion and transformation of bacteria. The yield of this rapid purification procedure makes it a good alternative method to standard centrifugation in cesium chloride ethidium bromide gradients.     

A rapid simple procedure for direct measurement of excreted thiamine from yeast

A new rapid method for the detection of extracellular thiamine production in yeast is described. This method is based on a modified thiochrome assay where fluorescent zones surrounding thiamine excretor colonies can be directly visualized under UV light on agar plates. This new procedure is simple to perform on a large number of colonies simultaneously and results can be obtained within minutes.     

A continuous method for the large-scale extraction of plasmid DNA by modified boiling lysis

This protocol describes a streamlined method of plasmid DNA extraction by continual thermal lysis, a modification of the basic boiling lysis technique, to simplify the processing of large volumes of Escherichia coli cultures. Fermented bacteria are harvested using a hollow fiber-membrane module and pre-treated with lysozyme prior to passing through a thermal exchange coil set at 70 degrees C to lyse the cells, and into a juxtaposed cooling coil on ice. The lysed and cooled bacteria are subsequently separated from the lysate by centrifugation and plasmid DNA is precipitated from the supernatant for further purification. The use of peristaltic pumps and two heating coils at constant temperature without the use of centrifugation enable the lysis process to become constant and controllable, providing a flow-through protocol for cell lysis and plasmid DNA extraction. Large volumes of bacterial cultures (20 l) can be processed in 2 h, yielding approximately 100 mg plasmid DNA l(-1) culture, making this an attractive protocol for consistent and large-scale preparation of plasmid DNA.     

A rapid method for protein extraction from fission yeast

Researchers working with fission yeast conduct protein extraction widely and frequently, but this includes the handling of glass beads, and hence is laborious and cumbersome, especially when dealing with a large number of samples. Here we describe a rapid and reliable method for preparing protein extract from fission yeast, one which is applicable to routine western blotting.     

Rapid method for direct extraction of DNA from soil and sediments.

A rapid method for the direct extraction of DNA from soil and sediments was developed. The indigenous microorganisms in the soil and sediments were lysed by using lysozyme and a freeze-thaw procedure. The lysate was extracted with sodium dodecyl sulfate and phenol-chloroform. In addition to a high recovery efficiency (greater than 90%), the yields of DNA were high (38 and 12 micrograms/g [wet weight] from sediments and soil, respectively). This method generated minimal shearing of the extracted DNA. The crude DNA could be further purified with an Elutip-d column if necessary. An additional advantage of this method is that only 1 g of sample is required, which allows for the analysis of small samples and the processing of many samples in a relatively short (7 h) period.     

Rapid method for direct extraction of DNA from soil and sediments.

A rapid method for the direct extraction of DNA from soil and sediments was developed. The indigenous microorganisms in the soil and sediments were lysed by using lysozyme and a freeze-thaw procedure. The lysate was extracted with sodium dodecyl sulfate and phenol-chloroform. In addition to a high recovery efficiency (greater than 90%), the yields of DNA were high (38 and 12 micrograms/g [wet weight] from sediments and soil, respectively). This method generated minimal shearing of the extracted DNA. The crude DNA could be further purified with an Elutip-d column if necessary. An additional advantage of this method is that only 1 g of sample is required, which allows for the analysis of small samples and the processing of many samples in a relatively short (7 h) period.     

A simple method for extraction of DNA from fungi and yeasts with anhydrous hydrogen fluoride

A novel method is described for the extraction of DNAs from fungi and yeasts. Anhydrous hydrogen fluoride (HF) selectively cleaves their cell walls under mild conditions (for 5 min at 0°C), enabling the effective extraction of DNAs from organisms with a cell wall. A possible mechanism for this method concerning the selective cleavage of O-glycosidic linkages in cell walls has been described previously [(1977) Anal. Biochem. 82, 289–309]. The extracted DNA is intact: in fact, the yeast DNA is directly applicable for restriction analysis and transformation of Escherichia coli.