Rapid isolation of phage lambda DNA

A modified procedure in two versions (micro, for 10 ml of phage lysate, and macro, for 200-500 ml) is described for preparing lambda phage DNA. The main advantage of the modified method is that it gives a possibility to isolate high-quality DNA from lambda phage lysates in 2-3 hrs. Only standard solutions (TE, NaCl, SDS, MgCl2, EDTA, RNAse A) were used throughout the whole protocol. Incubation with DNAse I and proteinase K was omitted and in microvariant concentration of the phage by PEG 6000 was excluded. Digestion by RNAse A was performed in solution with EDTA and SDS and leads to RNA degradation. The yields of DNA (0.5-2 micrograms per ml of L-broth) are similar to those obtained by other methods. DNA quality is better than in the samples of DNA prepared by other express-methods and practically the same as after CsCl centrifugation. DNA can be used for splitting by restriction enzymes, cloning and gene library construction.     

Rapid isolation of DNA from Staphylococcus aureus

We describe a Staphylococcus aureus bulk DNA isolation procedure which uses detergent and guanidine hydrochloride to free the nucleic acid from contaminants. The procedure is rapid and yields high-molecular-weight DNA suitable for molecular biological procedures.     

Rapid isolation of DNA from Staphylococcus aureus.

We describe a Staphylococcus aureus bulk DNA isolation procedure which uses detergent and guanidine hydrochloride to free the nucleic acid from contaminants. The procedure is rapid and yields high-molecular-weight DNA suitable for molecular biological procedures.     

Rapid isolation of high-molecular-weight DNA from agarose gels

We have developed a simple, reliable, and rapid method for recovering DNA from agarose gels. While many methods for DNA extraction have already been described, few provide quantitative recovery of large DNA molecules. These procedures generally require costly apparatus, extended elution times, or considerable handling of the sample after elution. Our method employs a novel electroelution chamber constructed from acrylic plastic. Gel slices containing DNA are placed in the chamber between platinum electrodes. Voltage is applied and a continuous flow of buffer sweeps the eluted DNA from the chamber into an external receptacle. Elution is complete in 7 min. Concentrated DNA is obtained by butanol extraction and alcohol precipitation in 1 h. Recoveries, quantitated by counting radiolabeled DNA or by densitometry of analytical gels, were 94 to 100% for fragments of 4 to 50 kb. The eluted DNA was undegraded and could be digested with restriction enzymes, ligated, end-labeled, or used to transform cells as efficiently as noneluted DNA. Complete elution of a 100-kb plasmid, a 194-kb concatemer of bacteriophage lambda, and of 440- and 550- chromosomes of Saccharomyces cerevisiae was also achieved using the same process. This method is suitable for routine use in a wide range of cloning applications, including the electrophoretic isolation of large DNA molecules.     

Rapid isolation of genomic DNA from animal tissues

A simple technique for the isolation of very high molecular weight genomic DNA from animal tissues and cells is described. The method involves rapid isolation of nuclei and their embedding in agarose beads followed by extraction of lipids and proteins with SDS. The protocol does not require proteolytic digestion and the whole procedure can be completed in 1 day. The isolated DNA is digestible by restriction enzymes and free of ligase inhibitors.     

Rapid isolation of animal mitochondrial DNA by alkaline extraction

A simple technique for rapid isolation of mitochondrial DNA (mtDNA) from animal cells is described. The method is based on the selective alkaline denaturation procedure of Birnboim and Doly [(1979) Nucleic Acids Res. 7, 1513-1523] and avoids the use of CsCl gradient centrifugation. The yield of mtDNA is comparable to that obtained by standard techniques. This DNA is sufficiently pure for restriction analysis and cloning of mtDNA fragments.     

Rapid isolation of substrate-quality plasmid DNA without CsCl-dye density gradients

The isolation of plasmid DNA produced in transformed bacterial cells is essential for many molecular biology techniques. Two drawbacks to the widely used CsCl-ethidium bromide method of preparation are the need for ultracentrifuge time and the generation of ethidium bromide waste. In this article we describe a method for the quick isolation of plasmid DNA without the use of an ultracentrifuge or ethidium bromide.     

Rapid isolation of metaphase chromosomes containing high molecular weight DNA

Normal rat kidney cells were cultured in medium supplemented with normal fetal bovine serum (FBS) or FBS depleted of fibronectin. The cell surface fibronectin of these cultures was visualized by indirect immunofluorescence using species-specific antisera for either rat fibronectin or bovine fibronectin. Anti-rat-fibronectin revealed fibrillar structures on the cells grown in either normal medium or fibronectin-depleted medium. Anti-bovine fibronectin revealed similar fibrillar networks, but only on the cells grown in medium containing bovine fibronectin. Staining in each case was abolished by absorption with the homologous antigen. It appears that exogenous fibronectin was incorporated into the same structures as endogenous fibronectin. This finding suggests that circulating fibronectin may serve as a building block for the assembly of extracellular matrix, possibly by cells which are incapable of synthesizing it.     

Rapid isolation of yeast genomic DNA: Bust n' Grab

Background

Mutagenesis of yeast artificial chromosomes (YACs) often requires analysis of large numbers of yeast clones to obtain correctly targeted mutants. Conventional ways to isolate yeast genomic DNA utilize either glass beads or enzymatic digestion to disrupt yeast cell wall. Using small glass beads is messy, whereas enzymatic digestion of the cells is expensive when many samples need to be analyzed. We sought to develop an easier and faster protocol than the existing methods for obtaining yeast genomic DNA from liquid cultures or colonies on plates.

Results

Repeated freeze-thawing of cells in a lysis buffer was used to disrupt the cells and release genomic DNA. Cell lysis was followed by extraction with chloroform and ethanol precipitation of DNA. Two hundred ng – 3 μg of genomic DNA could be isolated from a 1.5 ml overnight liquid culture or from a large colony. Samples were either resuspended directly in a restriction enzyme/RNase coctail mixture for Southern blot hybridization or used for several PCR reactions. We demonstrated the utility of this method by showing an analysis of yeast clones containing a mutagenized human β-globin locus YAC.

Conclusion

An efficient, inexpensive method for obtaining yeast genomic DNA from liquid cultures or directly from colonies was developed. This protocol circumvents the use of enzymes or glass beads, and therefore is cheaper and easier to perform when processing large numbers of samples.

     

Rapid plasmid DNA isolation from Lactococcus lactis using overnight cultures

A simple and quick method has been developed to isolate plasmid DNA from Lactococcus lactis using overnight or stationary-phase cultures which therefore eliminates the need for subculturing for generating log-phase cultures that are necessary with existing methods. The new method was effective in isolating plasmids, from 1.4 to 64 kb, from the three subspecies of Lactococcus lactis. The resultant DNA was of high yield and purity and therefore no additional purification steps were required for down-stream molecular procedures.     

Rapid isolation of fungal genomic DNA suitable for long distance PCR

A quick and reliable method for screening fungal transformants for specific genetic modifications is essential for many molecular applications. We have compared the applicability of a few rapid DNA extraction methods for Myrothecium and Aspergillus and tested the resulting DNA as to its suitability for PCR. For Myrothecium gramineum, the highest DNA concentration was obtained with the procedure described by N. Vanittanakom et al. (J Clin Microbiol 2002, 40: 1739–1742). For A. nidulans, concentrations higher than 100 ng/μl were reached with the glass bead, the LiCl, the boiling, the liquid N₂ and the protoplast-based method. Samples of M. gramineum resulting from the boiling and the liquid N₂ procedure were suitable for the amplification of fragments up to 2.3 kb. The direct use of mycelium from M. gramineum in the PCR tube can be employed for the reproducible amplification of fragments up to 1 kb. Amplification of fragments up to 4.3 kb requires the use of the Elongase Mix on samples extracted with the liquid N₂ procedure.     

Comparison of commercial DNA extraction kits for isolation and purification of bacterial and eukaryotic DNA from PAH-contaminated soils

Molecular characterization of the microbial populations of soils and sediments contaminated with polycyclic aromatic hydrocarbons (PAHs) is often a first step in assessing intrinsic biodegradation potential. However, soils are problematic for molecular analysis owing to the presence of organic matter, such as humic acids. Furthermore, the presence of contaminants, such as PAHs, can cause further challenges to DNA extraction, quantification, and amplification. The goal of our study was to compare the effectiveness of four commercial soil DNA extraction kits (UltraClean Soil DNA Isolation kit, PowerSoil DNA Isolation kit, PowerMax Soil DNA Isolation kit, and FastDNA SPIN kit) to extract pure, high-quality bacterial and eukaryotic DNA from PAH-contaminated soils. Six different contaminated soils were used to determine if there were any biases among the kits due to soil properties or level of contamination. Extracted DNA was used as a template for bacterial 16S rDNA and eukaryotic 18S rDNA amplifications, and PCR products were subsequently analyzed using denaturing gel gradient electrophoresis (DGGE). We found that the FastDNA SPIN kit provided significantly higher DNA yields for all soils; however, it also resulted in the highest levels of humic acid contamination. Soil texture and organic carbon content of the soil did not affect the DNA yield of any kit. Moreover, a liquid-liquid extraction of the DNA extracts found no residual PAHs, indicating that all kits were effective at removing contaminants in the extraction process. Although the PowerSoil DNA Isolation kit gave relatively low DNA yields, it provided the highest quality DNA based on successful amplification of both bacterial and eukaryotic DNA for all six soils. DGGE fingerprints among the kits were dramatically different for both bacterial and eukaryotic DNA. The PowerSoil DNA Isolation kit revealed multiple bands for each soil and provided the most consistent DGGE profiles among replicates for both bacterial and eukaryotic DNA.