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.     

Extensive deproteinization of Dictyostelium discoideum RNase P reveals a new catalytic activity.

Nuclear Dictyostelium discoideum RNase P was subjected to vigorous deproteinization procedures. After treatment with proteinase K followed by phenol extraction of samples containing D. discoideum RNase P activity, a new enzymatic activity was recovered. The proteinase K/phenol/SDS treated enzyme cleaves Schizossacharomyces pombe tRNAser (supS1), D. discoideum tRNASer and tRNALeu precursors several nucleotides upstream of the cleavage site of RNase P, liberating products with 5'-hydroxyl ends. This activity seems to be associated with one or two RNA molecules copurifying with D. discoideum RNase P activity as judged by its inhibition in the presence of micrococcal nuclease, which is in contrast to its resistance to proteinase K/phenol/SDS treatment.     

The Isolation of Amoeba RNA of Low Protein Content in High Yields

Comparison of six different RNA isolation procedures from amoebae showed that RNA recovery was increased by approximately 65% if pronase treatment was carried out prior to phenol extraction and was decreased by about 55%. and 17%. respectively if chloroform-isoamyl alcohol extraction or dialysis were carried out following phenol extraction. Dialysis was found to decrease contamination from protein or protein degradation products by 6–12 fold. Although pronase digestion appeared to increase protein contamination of the RNA preparation, the fact that chloroform-isoamyl alcohol extraction did not reduce it indicates that the contaminants were not protein. It is concluded that the most efficient scheme for isolating and purifying RNA from the free-living amoebae utilizes pronase digestion prior to phenol extraction and dialysis prior to RNA precipitation.     

Detection of high levels of polyadenylate-containing RNA in bacteria by the use of a single-step RNA isolation procedure

A new one-step procedure for the isolation of bacterial RNA, involving lysis by proteinase K in the presence of sodium dodecyl sulfate, is described. Pulse-labeled RNA isolated by this procedure for Bacillus brevis, Bacillus subtilis, and Escherichia coli B has been found to contain a substantial fraction (15-40%) of polyadenylated RNA as determined by adsorption to oligo(dT)-cellulose. This contrasts with RNA isolated by procedures involving phenol extraction, a process which appears to lead to the selective loss of polyadenylated RNA. The presence of polyadenylated RNA in E. coli was confirmed by an independent method which involved hybridization with [3H]polyuridylic acid. Using the proteinase K method for RNA isolation, it was possible to demonstrate the in vitro synthesis of polyadenylated RNA by toluene-treated cells of B. brevis, B. subtilis, and E. coli.     

Plasmid purification by phenol extraction from guanidinium thiocyanate solution: development of an automated protocol.

We have developed a novel plasmid isolation procedure and have adapted it for use on an automated nucleic acid extraction instrument. The protocol is based on the finding that phenol extraction of a 1 M guanidinium thiocyanate solution at pH 4.5 efficiently removes genomic DNA from the aqueous phase, while supercoiled plasmid DNA is retained in the aqueous phase. S1 nuclease digestion of the removed genomic DNA shows that it has been denatured, which presumably confers solubility in the organic phase. The complete automated protocol for plasmid isolation involves pretreatment of bacterial cells successively with lysozyme, RNase A, and proteinase K. Following these digestions, the solution is extracted twice with a phenol/chloroform/water mixture and once with chloroform. Purified plasmid is then collected by isopropanol precipitation. The purified plasmid is essentially free of genomic DNA, RNA, and protein and is a suitable substrate for DNA sequencing and other applications requiring highly pure supercoiled plasmid.     

RNase Protection Assay

The RNase protection assay is a highly sensitive technique developed to detect and measure the abundance of specific mRNAs in samples of total cellular RNA. The assay utilizesin vitrotranscribed³²P-labeled antisense RNA probes that are hybridized in solution to their complementary cellular mRNAs. This is followed by digestion of nonhybridizing (single-stranded) RNA species with RNases, removal of the RNases by treatment with proteinase K, phenol extraction of the cRNA:mRNA complexes, and electrophoretic isolation of the hybridizing cRNA fragments. Since one can synthesize “sense” mRNAs having the same sequence as the target cellular mRNA, appropriate standard curves can be generated and used to quantitate the changes in tissue mRNA levels. Because the assay requires perfect sequence complementarity for full protection, it not only serves as a quantitative tool but also provides conclusive evidence for the existence of a specific mRNA in a given tissue. The procedure described here is a modification of that originally described by M. Gilman [1993,inCurrent Protocols in Molecular Biology (Ausubel, F. M., Brent, R., Kingston, R. E., Moore, D. D., Seidman, J. G., Smith, J. A., and Struhl, K., Eds.), Vol. 1, pp. 4.7.1–4.7.6, Greene and Wiley–Interscience, New York].     

Rapid isolation of RNA using proteinase K and sodium perchlorate.

A simple, efficient procedure for the isolation of cellular nucleic acids is described. It combines the use of sodium dodecyl sulfate, proteinase K, sodium perchlorate, and isopropanol precipitation. The yields and purity of RNA extracted from a variety of sources are comparable or superior to those obtained by phenol extraction. High molecular weight RNA (ribosomal as well as nonribosomal) is recovered intact and in high yield. Fibroin messenger RNA (M_r 5.8 × 10⁶) isolated by this procedure is biologically active.     

In situ hybridization with non-radioactive digoxigenin-11-UTP-labeled cRNA probes: localization of developmentally regulated mouse tenascin mRNAs.

An improved method for in situ hybridization was developed in order to identify the tissue-specific expression of messenger RNA (mRNA) for the novel extracellular matrix glycoprotein, tenascin, during mouse development. Non-radioactive RNA probes were generated by incorporating digoxigenin-11-UTP instead of conventional isotopic labels. Hybridization of anti-sense probes to complementary mRNAs was detected by a chromogenic staining reaction catalyzed by an anti-digoxigenin antibody-alkaline phosphatase conjugate. Markedly improved enhancement of staining was achieved by expanding the complexity of probes and strictly controlling the degree of proteolytic digestion of paraformaldehyde-fixed tissue sections. Six different complementary RNA (cRNA) probes representing most of the tenascin mRNA sequence were prepared. Very weak signals were obtained after single applications of each probe, but strong specific signals were present when all six probes were mixed together. In either case, no signal was found without prior proteolytic digestion of tissue sections with proteinase K. Treatment with increasing concentrations of proteinase K initially resulted in increased sensitivity of signal detection, but extensive digestion resulted in histological sections of poor quality for light microscopy. Optimal conditions varied according to the tissue type examined. In lung, in situ hybridization detected tenascin mRNA in the relatively large cells lining alveolar walls adjacent to type I pneumocytes. In cerebellum, glial cells of the Purkinje cell layer contained tenascin mRNA, but Purkinje cells did not. In both cases, hybridization signals were confined to the cytoplasm of cells, and no extracellular staining was observed. This method provides a promising new tool for analysis of spatio-temporal regulation of tenascin gene expression during embryogenesis and oncogenesis.     

Purification of human leucocyte DNA: proteinase K is not necessary.

A rapid nontoxic method for the purification of DNA from human leucocytes is described. Preliminary experiments which tested different methods of DNA purification indicated that digestion of proteins with proteinase K was unnecessary. This led to the development of a simple procedure involving lysis of the cells in SDS followed by extraction with 6 M NaCl. The method described overcomes the requirement for lengthy incubations in the presence of expensive proteinase K and subsequent extraction with toxic chemicals.     

A simple, efficient method for the separate isolation of RNA and DNA from the same cells.

A method for the isolation of total cytoplasmic RNA and high molecular weight DNA from the same cells is described. Cells are gently lysed with NP40 in the presence of vanadyl ribonucleoside complex and the nuclei pelleted by centrifugation. RNA is purified by phenol/CHCl3 extraction of the lysate supernatant followed by ethanol precipitation. Protein is removed from high molecular weight DNA by salt-precipitation after nuclei are digested with proteinase K in the presence of sodium dodecyl sulfate. High yields of clean, intact RNA and DNA are obtained. A major advantage of the method is that it can be scaled down to quantitatively extract RNA and DNA from as little as 1000 cells.     

Translation in a cell-free system of mRNA from term placenta extracted by guanidine hydrochloride

Human term placenta RNA and polyadenylated mRNA were prepared using guanidine HCl and oligo (dT)-cellulose affinity chromatography. Both fractions translated in a wheat germ cell-free system showed, under optimal condition of K+ and Mg++ ions and spermidine, about 9 times activity for RNA and 15-25 times for poly(A+) mRNA greater than the control. Homogenization of the tissue at high speed compared to that at low speed improved 4-fold activity. Analysis of tritiated products by SDS-Polyacrylamide gel electrophoresis and detected by fluorography showed more than ten different intensity bands ranging between 12 and 66 kD. According to the results obtained, guanidine HCl is an advantageous procedure for the extraction of RNA from this nuclease-rich tissue compared with that obtained with phenol extraction, in both activity and in larger translation products.     

A mammalian tRNAHis-containing antigen is recognized by the polymyositis-specific antibody anti-Jo-1

The mammalian cell antigen reactive with the autoantibody anti-Jo-1 has been shown to contain tRNAHis. The RNA sequence of this human and mouse cell tRNA was determined in a search for unusual features that might be related to antigenicity. The 5' terminal nucleotide is unique among other sequenced tRNAs in that it is a methylated guanine. The presence of the hypermodified base queuine, which occurs in the wobble position of the anticodon of tRNAHis from several species, was not detected in the tRNAHis immunoprecipitated by anti-Jo-1 from either human HeLa or mouse Friend erytholeukemia cell extracts. The binding of protein(s) appears to confer antigenicity on tRNAHis since either proteinase K treatment or phenol extraction resulted in the loss of immunoprecipitability. However, we have not succeeded in identifying an antigenic protein, and we find that the antigenic complex is not resolved from purified tRNAHis by Sephacryl S-200 column chromatography. Immunofluorescence studies indicate that the antigenic form of tRNAHis is located preferentially in the mammalian cell cytoplasm. The results presented here are discussed in light of an earlier report (1) on the nature of the Jo-1 antigen.     

High-efficiency preparation of DNA from limiting quantities of eukaryotic cells for hybridization analysis

This report describes a DNA preparation method which allows the detection of single-copy genes in samples of as few as 6000 eukaryotic cells. The technique uses proteinase K digestion in detergent and low-gelation-temperature agarose followed by solidification of the agarose and removal of the detergent by diffusion. RNase and restriction enzyme digestion are carried out in solution after remelting the agarose. The procedure can be performed successfully with mammalian cells in suspension, with parasitic protozoa and with pieces of mammalian tissue weighing less than 1 mg. Numerous samples can be processed simultaneously using frozen as well as fresh material.     

A non-organic and non-enzymatic extraction method gives higher yields of genomic DNA from whole-blood samples than do nine other methods tested.

We compared ten methods for extraction of DNA from whole blood. Nine methods require incubation with either enzymes or treatment of organic solvents or both. The 'Rapid Method' (RM) (Method 10) avoids the use of organic solvents (phenol/chloroform) and eliminates completely the use of proteinase K. Thus, the time and cost of DNA extraction are reduced significantly. This is accomplished by salting out and precipitation of the cellular proteins in saturated sodium chloride. This method takes less than an hour to completion, without compromising the yield or the quality of DNA. Using RM, we can make DNA from 0.1 ml of whole blood and as little as 0.5 ml of blood yields DNA sufficient to run a few Southern blots. The RM can also be applied to packed cells. The DNA is free of RNA, protein and degrading enzymes. The uncut DNA runs as a typical slow-migrating, high-molecular-weight and undegraded species in an agarose gel. The DNA is suitable for digestion by various restriction endonucleases. This procedure works equally well with fresh blood samples and with those that are stored at 4 degrees C and -70 degrees C. To our knowledge the RM reported here is the safest, fastest and most quantitative and economical method for preparation of DNA from whole blood and cells.     

Redox ribonucleosides. Isolation and characterization of 5-hydroxyuridine, 8-hydroxyguanosine, and 8-hydroxyadenosine from Torula yeast RNA.

Three hydroxyribonucleosides catalyzing the oxido-reduction of NADH and K3F3(CN)6 were purified from Torula yeast RNA by a series of steps including sodium dodecyl sulfate/phenol extraction, nuclease P1 digestion, alkaline phosphatase digestion, anion-exchange chromatography, and high performance liquid chromatography on an ODS column. Analysis by fast atom bombardment-mass spectrometry and 1H and 13C NMR spectroscopy led to identification of the redox ribonucleosides as 5-hydroxyuridine, 8-hydroxyguanosine, and 8-hydroxyadenosine. Their mass spectra, chromatographic behavior, UV spectra, NMR spectra, and IR spectra were identical to those from natural and synthetic sources. Oxidoreduction activities were specific for K3Fe(CN)6 as the oxidant and NADH as the reductant; and their magnitudes decreased in the order 5-hydroxycytidine, 5-hydroxyuridine, 8-hydroxyguanosine, and 8-hydroxyadenosine. The fact that these nucleosides have redox activities suggests new functional roles for RNAs as catalysts.     

DNA detection in hair of transgenic mice--a simple technique minimizing the distress on the animals

The breeding of transgenic animals requires that each individual offspring be analysed for integration of transgenic deoxyribonucleic acid (DNA), unless exclusively homozygous animals are mated. The standard protocol for identification of transgenic animals (Hogan et al. 1994) is based on tissue samples and preparation of chromosomal DNA including proteinase K digestion and phenol/chloroform extraction. The procedure described here represents a much simpler and faster method to screen offspring for the transgene DNA. It is based on the use of hair bulbs as sample material, which can be directly used for polymerase chain reaction (PCR) after alkaline lysis. This protocol allows large numbers of animals to be easily screened in a minimum amount of time. A unique advantage though, is the reduction of the distress caused to the animals. With respect to the 3Rs (Replacement, Reduction, Refinement), and because of technical advantages this method may replace ear or tail clipping.     

Rapid DNA extraction methods and new primers for randomly amplified polymorphic DNA analysis of Giardia duodenalis.

A randomly amplified polymorphic DNA (RAPD) procedure using simple genomic DNA preparation methods and newly designed primers was optimized for analyzing Giardia duodenalis strains. Genomic DNA was extracted from in vitro cultivated trophozoites by five freezing-thawing cycles or by sonic treatment. Compared to a conventional method involving proteinase K digestion and phenol extraction, both freezing-thawing and sonication were equally efficient, yet with the advantage of being much less time- and labor-intensive. Five of the 10 tested RAPD primers produced reproducible polymorphisms among five human origin G. duodenalis strains, and grouping of these strains based on RAPD profiles was in agreement among these primers. The consistent classification of two standard laboratory reference strains, Portland-1 and WB, in the same group confirmed previous results using other fingerprinting methods, indicating that the reported simple DNA extraction methods and the selected primers are useful in RAPD for molecular characterization of G. duodenalis strains.     

Noninvasive Method of DNA Isolation From Fecal Epithelial Tissue of Dairy Animals

A novel noninvasive genomic DNA isolation protocol from fecal tissue, by the proteinase K digestion and guanidine hydrochloride extraction method, was assessed for the genotyping of cattle and buffalo. The epithelial tissues present on the surface of the feces were used as source for isolation of genomic DNA. The DNA isolated from fecal tissue was found to be similar as those obtained from other body tissues such as skin, brain, liver, kidney, and muscle. The quality of DNA was checked by agarose gel electrophoresis and polymerase chain reaction (PCR). We successfully amplified a 320 bp MHC class II DRB gene and a 125 bp mt-DNA D-loop region from isolated genomic DNA of cattle. Thus, the DNA isolated using this method was suitable for common molecular biology methods, such as restriction enzyme digestion and genotyping of dairy animals through PCR.