FRACTIONATION OF NUCLEAR,CHLOROPLAST, AND MITOCHONDRIAL DNA FROM POLYSIPHONIA BOLDII (RHODOPHYTA) USING A RAPID AND SIMPLE METHOD FOR THE SIMULTANEOUS ISOLATION OF RNA AND DNA1

Extraction of nucleic acids from red algae is complicated by the presence of phycocolloids. For this reason, methods used for nucleic acid isolation from other organisms are not always amenable to use with red algal preparations; modifications in some cases lead to protocols that are time consuming and complicated, often requiring large amounts of algal tissue for starting material. Here we describe the isolation of both RNA and DNA followed by fractionation and identification of nuclear, chloroplast, and mitochondrial DNAs from a single preparation of Polysiphonia boldii Wynne and Edwards using a simple method that yielded approximately 100 μg of total RNA and 20 μg of total DNA from 1 g of frozen powdered algae. The potent protein denaturant guanidinium thiocyanate and the detergent sarkosyl were used to gently lyse the cells and organelles and immediately inhibit nuclease activity in the extract. The nucleic acids were isolated by ultracentrifugation into a dense solution of CsCl; the RNA was recovered as a pellet and the DNA as a band within the CsCl solution. Agarose gel electrophoresis of the total RNA showed discrete ribosomal RNA bands, indicating little nonspecific degradation. The nuclear, chloroplast, and mitochondrial DNAs were fractionated by density gradient ultracentrifugation in the presence of the DNA binding dye, bisbenzimide H (Hoechst 33258), which binds preferentially to DNA with a high A + T:G + C ratio, thus altering its density to a greater degree than it does that of DNA with a lower nucleotide ratio. The three fractions were identified by Southern blot analysis using heterologous gene probes specific for the different genomes. The protocol should be applicable to different types of algae. The simple nucleic acid isolation step can be performed on multiple samples simultaneously without subsequent fractionation of DNA, allowing comparison of DNA from different individuals, populations, or species.     

A simple and efficient procedure for the isolation of high-quality phage lambda DNA using a DEAE-cellulose column

A simple and rapid procedure for purifying large quantities of bacteriophage lambda particles and DNA is described. The procedure involves DEAE-cellulose column chromatography of the phage particles and elution of the phage particles from the column with a low-ionic-strength buffer. The resulting phage were well separated from RNA, DNA, and proteins derived from Escherichia coli host cells. The lambda DNA was prepared from the purified phage particles by the conventional method of phenol extraction and ethanol precipitation. This procedure did not use nucleases, proteases, detergents, or CsCl density gradient centrifugation. The lambda DNA obtained by this method was equivalent in purity to the material prepared by CsCl density gradient centrifugation and amenable to restriction enzyme digestion, ligation, radiolabeling, and double-stranded DNA sequencing. A detailed protocol is described for obtaining 0.5 to 1.0 mg DNA from a 1-liter liquid lysate in less than 5 h. This procedure is simple, inexpensive, and timesaving, and is particularly suitable for large-scale isolation of lambda DNA.     

Rapid step-gradient purification of mitochondrial DNA

A convenient modification of the step gradient (CsCl/ethidium bomide) procedure is described. This rapid method allows isolation of covalently closed circular DNA separated from contaminating proteins, RNA and chromosomal DNA in ca. 5 h. Large scale preparations can be performed for circular DNA from eukaryotic organelles (mitochondria). The protocol uses organelle pelleting/NaCl-sarcosyl incubation steps for mitochondria followed by a CsCl step gradient and exhibits yields equal to the conventional procedures. It results in DNA sufficiently pure to be used for restriction endonuclease analysis, subcloning, 5-end labeling, gel retention assays, and various types of hybridization.     

Rapid isolation of total RNA from mammalian tissues

A rapid procedure for the isolation of total RNA from small amounts of mammalian tissue (35 to 150 mg) is described. Tissues were homogenized in the presence of RNase inhibitors but in the absence of strong detergents. Contaminants were removed by phenol/chloroform extraction and Sephadex column chromatography. Total RNAs were precipitated with ethanol and sodium acetate. The RNAs isolated were intact and suitable for mRNA quantitation via Northern blot or slot-blot analyses. This procedure isolates total RNAs in high yield and purity, without CsCl ultracentrifugation, and is especially useful when mRNAs must be quantitated from many samples.     

Isolation of a hybrid between rat ribosomal RNA and DNA.

A procedure for the isolation and purification of a specific hybrid between rat 28S and 18S ribosomal RNA's and nucleolar DNA is described. The method employed includes the following steps: 1) isolation of the nucleolar DNA, 2) hybridization of [14C]rRNA with the nucleolar DNA, and 3) isolation and purification of the rRNA-DNA hybrid complex by chromatography on hydroxylapatite and centrifugation in a CsCl density gradient. In the isolated hybrid complex the RNA:DNA ratio is close to 1:1, and the degree of enrichment of the DNA by the rRNA cistrons is about 1500 times. The hybrid obtained has a sedimentation constant on the order of 20S, is resistant to the action of pancreatic RNase and RNase T1 and sheep brain DNase, and is characterized by high thermostability. Acording to the physicochemical tests used, the rRNA-DNA hybrid complex is a double-stranded poly-nucleotide with an ordered secondary structure.     

RNA isolation from cartilage using density gradient centrifugation in cesium trifluoroacetate: an RNA preparation technique effective in the presence of high proteoglycan content.

An efficient method for the isolation of RNA from cartilage is described. The difficulties in obtaining RNA from cartilage, a tissue of low cell density and high proteoglycan content, were overcome by making several modifications to the guanidine thiocyanate/cesium chloride method of RNA extraction. Cartilage tissue is frozen, crushed, and homogenized in a 4 M guanidine thiocyanate lysis buffer. The RNA is then pelleted by ultracentrifugation through a cesium trifluoroacetate density gradient. The use of cesium trifluoroacetate, rather than cesium chloride, for density gradient centrifugation improves both the yield and purity of total RNA isolated from cartilage. The ultracentrifugation has been adapted to the Beckman TL100 tabletop centrifuge and is complete in 3 h. This fast, simple method produces high quality RNA, suitable for use in RNase protection assays, polymerase chain reaction analysis, and Northern analysis. This purification procedure may be applicable to other sources, from which RNA isolation is complicated by the presence of abundant cell wall or matrix components.     

An improved method for mRNA isolation and characterization of in vitro translation products by Western blotting

A method is described for isolation of messenger RNA (mRNA) from a rather intractable tissue source, calf stomach. The use of additional RNase inhibitors, vanadyl ribonucleoside complexes and proteinase K, which are used in conjunction with the guanidine thiocyanate/CsCl ultracentrifugation procedure traditionally employed for isolation of mRNA, is described. These modifications make the procedure universally applicable to a wide variety of tissues and cell types. The validity of the procedure is demonstrated by isolation of biologically active full-length preprochymosin mRNA. The integrity of the mRNA is measured by in vitro translation, Northern blot analysis, Southern blot analysis of preprochymosin cDNA using synthetic oligodeoxynucleotide probes and immunospecific identification of in vitro translation products using a modification of the Western blot which is described in this report.     

Characterization of cytoplasmic DNA of mouse-myeloma cells.

Cytoplasmic DNA from mouse myeloma cells comprised between 1% and 2% of the total cellular DNA. Detergent-prepared cytoplasmic lysate consisted mainly of 8-S and 22-S species. While these DNA species were present in the 13000 times g pellet of the detergent-prepared cytoplasmic lysate, only the light DNA species was present in the 13000 times g supernatant fraction. In neutral CsCl gradients the DNA of both cytoplasmic fractions had a buoyant density of 1700 g/cm3, which is identical to that of nuclear DNA. The similarity between the cytoplasmic and nuclear DNA was also demonstrated by analysis on alkaline CsCl gradients. A small proportion of closed-circular DNA, presumably of mitochondrial origin, was demonstrated only in cytoplasmic fraction obtained from mechanically disrupted cells and not in detergent-prepared cytoplasmic lysate. It was found that poly (A)-containing mRNA and 28-S ribosomal RNA hybridized to about the same extent to the cytoplasmic DNA as compared to nuclear DNA. The results indicate that most of the cytoplasmic DNA in myeloma cells is similar to nuclear DNA and does not consist of mitochondrial DNA.     

An Improved Protocol for the Isolation of RNA from Roots of Tea (Camellia sinensis (L.) O. Kuntze)

Tea, a beverage crop, is a rich source of polyphenols and polysaccharides which greatly attribute to its importance. However, oxidation and precipitation of these compounds during nucleic acids extraction is a limitation to molecular biology and genomic studies. On isolation of total RNA from root tissue using established protocols, difficulties were encountered in terms of purity and quantity of isolated RNA or some of the methods were time-consuming and also yields were low. The present communication combines a phenol-based RNA isolation protocol with a cetyltrimethylammonium bromide-based procedure with appropriate modifications. This protocol successfully isolated RNA from tap root tissue in 2-3 h as compared with 16 h reported by the previous method. Also, RNA yield was higher by more than fourfold. The RNA isolated by this protocol was successfully used for downstream applications such as RT-PCR and the construction of suppression subtractive hybridization library. The developed protocol worked well with other plant tissue with high polyphenols and polysaccharides contents.     

A rapid and efficient method for purification of recombinant adenovirus with arginine-glycine-aspartic acid-modified fibers

Recombinant adenoviral vectors (adenovectors) have been subject to various genetic modifications to improve their transduction efficiency and targeting capacity. Production and purification of adenovectors with modified capsid proteins can be problematic using conventional two-cycle CsCl gradient ultracentrifugation. We have developed a new method for purifying recombinant adenovectors in two steps: iodixanol discontinuous density gradient ultracentrifugation and size exclusion column chromatography. The purity and infectious activity of adenovectors isolated by the two methods were comparable. The new method yielded three to four times more adenovectors with arginine-glycine-aspartic acid (RGD)-modified fiber proteins than did the conventional CsCl method. For other fiber-modified and wild-type adenovectors, the yields of the two methods were comparable. Thus, the iodixanol-based method can be used not only to improve the production of RGD-modified adenovectors but also to purify adenovectors with or without fiber modifications. Moreover, the whole procedure can be completed in 3h. Therefore, this method is rapid and efficient for production of recombination adenovectors, especially those with RGD-modified fibers.     

Large-scale isolation of covalently closed circular DNA using gel filtration chromatography

The isolation of covalently closed circular (ccc) DNA free of contamination by RNA and other forms of DNA is fundamental to molecular biology. A variety of methods have been explored but CsCl density-gradient centrifugation remains the method most widely used for preparative scale resolution. The process is expensive, time-consuming, requires the use of large amounts of the carcinogen ethidium bromide, and is subject to considerable variation in yield and purity. To avoid these problems, we have devised a procedure for the preparation of cell lysates which results in consistently good yields of biologically active ccc DNA minimally contaminated with chromosomal DNA fragments and RNA. Lysates are deproteinized, precipitated with CaCl2 to remove rRNA, concentrated by ethanol precipitation, and applied to a Sephacryl S-1000 column which resolves chromosomal fragments, open circular plasmid DNA, and residual RNA from the ccc DNA. We have found that substituting the gel filtration column for CsCl density-gradient centrifugation results in substantially better purification as well as reducing processing time, cost, and degree of difficulty. The time required from harvest of cells to final recovery of DNA is about 16 h. We have used the method to isolate plasmids from 4.4 to 12 kb and, with slight modifications, recombinant M13 replicative form DNAs.     

The preparation of poly(A)+mRNA from the hagfish slime gland

The isolation of translatable poly(A)+mRNA from the slime glands of the Pacific hagfish, Eptatretus stouti, is not possible by the commonly used procedures because of the viscous slime that is formed when the contents of the glands are hydrated. This paper reports on a procedure developed to overcome this problem. Briefly, the tissue was powdered in liquid nitrogen, mixed with sodium lauroylsarcosine and proteinase K and lyophilized. The lyophilized powder was then mixed with 0.3 mm diameter glass beads, thoroughly ground and wetted with buffer and digested at 37 degrees C. The RNA from the digest was recovered by ultracentrifugation through a CsCl cushion. Further purification of the RNA was accomplished by the usual methods with slight modifications.     

Isolation of DNA-free RNA, DNA, and proteins by cesium trifluoroacetate centrifugation

The ability to simultaneously isolate intact DNA-free RNA, genomic DNA, and proteins from a biological specimen can be useful in cloning genes and analyzing gene expression. Equilibrium density gradient centrifugation with CsCl is a useful tool for fractionating, quantitatively separating, and characterizing RNA, DNA, and the total quota of proteins, respectively, based on differences in their buoyant densities. In the present study we have reexamined the rarely used cesium salt, cesium trifluoroacetate, for the same purpose. A significant advantage of CsTFA lies in the fact that, unlike in CsCl, RNA can be recovered from a single, soluble fraction of the CsTFA gradient. Furthermore, unlike CsCl, CsTFA is freely soluble in ethanol so that co-precipitation of the salt in the recovered RNA upon alcohol precipitation does not take place. Hence, the RNA is recovered with minimum manipulations. The one-step separation of cellular macromolecule classes free of each other in small amount of starting materials provides a major advantage over other methods currently in use.