Spectrophotometric analysis of RNA and DNA using cetyltrimethylammonium bromide

A versatile procedure is described for the analysis of RNA and DNA in brain using cetyltrimethylammonium bromide as the initial precipitant. Optimal conditions are described for the precipitation, hydrolysis, and effective separation of the RNA and DNA fractions from contaminating protein. The RNA and DNA fraction can now be accurately estimated by uv absorbance without a two wavelength correction. This method has also been used for the analysis of other mammalian organs and for mammalian cells obtained from tissue culture. The method may also be used for the simultaneous determination of radioactivity in nucleic acids. The orcinol reaction is shown to give high values for brain RNA.     

Rayleigh light scattering study on the reaction of nucleic acids and methyl violet

A new quantitative determination method for nucleic acids in aqueous solutions, based on the enhancement of Rayleigh light scattering of methyl violet by nucleic acids, has been developed. The sensitivity of the assay allows amounts of nucleic acids as little as 100 ng/ml to be quantitated reliably. In addition to its high sensitivity, this method has other advantages: rapidity of reaction (<5 min), simplicity of operation (one-step assay), commonality of spectrofluorimeter and reagents, stability of mixtures formed, and reproducibility. Under the experimental conditions, there is little or no interference from proteins, nucleosides, and most metal ions. Interference by a few metal ions, detergents, and some salts can be minimized by dilution. The method can also be used to determine the total amount of nucleic acids without the arduous choice of standard and difficult separation of DNA and RNA.     

Effects of the trivalent and hexavalent chromium on the physicochemical properties of mammalian cell nucleic acids and synthetic polynucleotides

The effects of trivalent (chromium chloride) and hexavalent (potassium dichromate) chromium have been studied on the nucleic acids of cultured mammalian cells (BHK hamster fibroblast line), commercial DNA and RNA, and synthetic polynucleotides of known base composition. Modifications of UV absorption spectra and alterations of thermal denaturation and renaturation patterns have been observed by directly treating purified nucleic acids, as well as by examining nucleic acids extracted from cells treated with chromium compounds.Cr(III) interacts with nucleic acid bases, mostly guanine and cytosine, but also with phosphate groups, leading to deprotonation of bases as well as intramolecular cross-links, sandwich complexes between bases and chelation between bases and phosphates. Such interactions destabilize the DNA structure. On the contrary, stabilization of RNA, due to intramolecular metal bonds between nitrogen bases in GC-rich regions, is mainly produced. The kind of interaction of Cr(III) with nucleic acids is not significantly different when intact BHK cells are treated.Cr(VI) interacts similarly with DNA and RNA giving instead different effects when purified nucleic acids or intact cells are treated. Treatment of purified DNA produces breakages in the polynucleotide chain due to the oxidizing power of Cr(VI). In intact cell treatments, changes in the properties of DNA are observed. These could result from the combined action of Cr(III), produced by the intracellular reduction of Cr(VI) and the oxidizing activity of residual Cr(VI).The relevance of Cr(VI) and Cr(III) interactions to the mechanisms of chromium (carcino)genic action is summarized. It is stressed that Cr(VI), if not completely reduced to Cr(III) by extracellular and endoplasmic constituents, can reach the cell nucleus and directly interact with DNA.     

End-joining long nucleic acid polymers

Many experiments involving nucleic acids require the hybridization and ligation of multiple DNA or RNA molecules to form a compound molecule. When one of the constituents is single stranded, however, the efficiency of ligation can be very low and requires significant individually tailored optimization. Also, when the molecules involved are very long (>10 kb), the reaction efficiency typically reduces dramatically. Here, we present a simple procedure to efficiently and specifically end-join two different nucleic acids using the well-known biotin–streptavidin linkage. We introduce a two-step approach, in which we initially bind only one molecule to streptavidin (STV). The second molecule is added only after complete removal of the unbound STV. This primarily forms heterodimers and nearly completely suppresses formation of unwanted homodimers. We demonstrate that the joining efficiency is 50 ± 25% and is insensitive to molecule length (up to at least 20 kb). Furthermore, our method eliminates the requirement for specific complementary overhangs and can therefore be applied to both DNA and RNA. Demonstrated examples of the method include the efficient end-joining of DNA to single-stranded and double-stranded RNA, and the joining of two double-stranded RNA molecules. End-joining of long nucleic acids using this procedure may find applications in bionanotechnology and in single-molecule experiments.     

Development of a sensitive and rapid nucleic acid assay with tetraphenyl porphyrinatoiron chloride by a resonance light scattering technique.

Based on the interaction between nucleic acids and tetraphenyl porphyrinatoiron chloride (FeTPPCl), a novel method for the determination of nucleic acids at the nanogram level has been developed. Under the optimum conditions, the weak resonance light scattering (RLS) intensity of FeTPPCl was greatly enhanced by nucleic acids and the enhanced RLS intensity was proportional to the concentration of nucleic acids in the range 0.02-2.8 microg/mL for calf thymus DNA, 0.05-3.3 microg/mL for fish sperm DNA and 0.07-4.5 microg/mL for yeast RNA. The detection limits (3sigma) were 2.9 ng/mL for calf thymus DNA, 3.9 ng/mL for fish sperm DNA and 5.2 ng/mL for yeast RNA. Almost no interference could be observed from proteins, nucleosides and most of the metal ions. The proposed method showed good reliability, sensitivity, rapidity and reproducibility when applied to the determination of nucleic acids in synthetic and biochemical samples. The time savings make this method suitable for large routine analyses.     

Optimization of acetonitrile co-solvent and copper stoichiometry for pseudo-ligandless click chemistry with nucleic acids

The copper(I) catalyzed azide-alkyne cycloaddition 'click' reaction yields a specific product under mild conditions and in some of the most chemically complex environments. This reaction has been used extensively to tag DNA, proteins, glycans and only recently RNA. Click reactions in aqueous buffer typically include a ligand for Cu(I), however we find that acetonitrile as a minor co-solvent can serve this role. Here we investigate the click labeling of RNA and DNA in aqueous buffer to determine the relationship between the stoichoimetry of Cu(I) and the acetonitrile co-solvent that affects nucleic acid stability. We find that very low concentrations of acetonitrile perform equally well and obviate the need for any additional Cu(I) stabilizing ligand. These pseudo-ligandless reaction conditions are optimal for nucleic acids click conjugations.     

A fluorimetric method for the determination of nucleic acids using Ce(IV) and sodium triphosphate.

A novel and stable fluorimetric method was established for the determination of nucleic acids. The proposed method is based on the reduction by nucleic acids of Ce(IV) to fluorescent Ce(III). The fluorescence intensity can be greatly increased by sodium triphosphate. The enhanced fluorescence intensity is proportional to the concentration of nucleic acids in the range 4.2 x 10(-8)-4.2 x 10(-6) g/mL for fish sperm DNA and 5.0 x 10(-8)-6.5 x 10(-6) g/mL for yeast RNA, and the detection limits (S/N = 3) are 13.5 ng/mL and 45 ng/mL, respectively. The reaction mechanism of the hydrolytic scission of nucleic acids by Ce(IV) is discussed.     

Use of diphenylamine as a colorimetric reagent for ribonucleic acid

RNA has been demonstrated to react with diphenylamine when acid hydrolysis is performed for 1 hour or more at 100°C. This reaction can be used for quantitative analysis of RNA, since there is a linear relationship between RNA concentration and absorbance. The reaction of RNA with diphenylamine can be quanlitatively distinguished from the reaction of DNA: the absorption spectrum of the RNA-diphenylamine reaction product has a maximum at 650 mμ, and a second, smaller peak at 490 mμ, while the DNA-diphenylamine reaction product has a single maximum at 605 mμ. It was found that, when mixtures of DNA and RNA are reacted with diphenylamine, the spectra reflect both the DNA:RNA ratios and the total amounts of nucleic acids. When the two-wavelength method of spectrum analysis was applied to such spectra, good agreement was found between actual and calculated values of nucleic acid concentrations. In this way, diphenylamine can be used for the simultaneous determination of the concentrations of DNA and RNA in mixtures. As is the case for the reaction of DNA with diphenylamine, it was found that the reaction of RNA is not altered by the presence of protein and that it involves primarily the purine nucleotides. The reaction of RNA with diphenylamine is discussed in relation to its possible analytical applications.     

Binding of reticulocyte elongation factor 1 to ribosomes and nucleic acids.

The present study has examined the requirements for the binding of rabbit reticulocyte elongation factor 1 (EF-1) to ribosomes under different assay conditions. When a centrifugation procedure was used to separate the ribosome EF-1 complex, the binding of EF-1 to ribosomes required GTP and Phe-tRNA, but not poly(U). The results suggested that undr these conditions a ternary complex, EF-1 . GTP . aminoacyl-tRNA, is necessary for the formation of a ribosome . EF-1 complex. However, when gel filtration was used to isolate the ribosome . EF-1 complex, only template and tRNA were required. These studie emphasize the fact that the procedure used to isolate the ribosome . EF-1 complex determines the requirements for stable complex formation. EF-1 can also interact with nucleic acids such as 28 S and 18 S rRNA, messenger RNA and DNA. In contrast to the binding to ribosomes, EF-1 binding to nucleic acids requires only Mg2+.     

Influence of C-5 halogenation of uridines on hairpin versus duplex RNA folding

Halogenation of bases is a widespread method used for solving crystal structures of nucleic acids. However, this modification may have important consequences on RNA folding and thus on the success of crystallization. We have used a combination of UV thermal melting, steady-state fluorescence, X-ray crystallography, and gel electrophoresis techniques to study the influence of uridine halogenation (bromination or iodination) on the RNA folding. The HIV-1 Dimerization Initiation Site is an RNA hairpin that can adopt an alternative duplex conformation and was used as a model. We have shown that, unexpectedly, the RNA hairpin/duplex ratio is strongly dependent not only on the presence but also on the position of halogenation.     

A new approach to the isolation of RNA-DNA hybrids and its application to the quantitative determination of labeled tumor virus RNA

A procedure has been developed by which the hybrid formed between a labeled RNA and complementary DNA can be selectively separated from all other single and double-stranded nucleic acids. We describe the application of this procedure to the quantitative determination of labeled avian tumor virus RNA. Purified DNA complementary to avian myeloblastosis virus RNA is extended at its 3′ terminus with 40 to 60 dCMP residues, using terminal deoxynucleotidyl-transferase. The elongated DNA is annealed with the labeled nucleic acid preparation and the mixture is passed through a column of Sephadex to which poly(I) has been covalently bound. The poly(I) retains the specific RNA-DNA hybrids by virtue of their poly(C) extension. The column is washed with RNAase to degrade nonhybridized RNA, the RNA retained on the column is eluted with formamide and its radioactivity is determined. The background hybridization was reduced to 0.003 to 0.008% by addition of oligo(C)_5.20 to the hybridization mixture and by carrying out the adsorption to the poly(I)-Sephadex column in the presence of poly(U). The hybridization efficiency was about 50%. The content of radioactive Rous sarcoma virus-specific RNA was determined in infected and uninfected cells after labeling with [³H]uridine for two hours. The content of labeled virus-specific RNA in infected cells was 0.6 to 0.9% and 0.05% in uninfected cells. The value found for monkey cell RNA was 0.009%. This method can be used for the detection of hybrids between labeled RNA and complementary DNAs too short to allow quantitation by conventional methods. If the RNAase step is omitted the procedure can be used for the isolation of any RNA for which a complementary DNA is available, as well as for its precursor.     

Altered nucleic acid partitioning during phenol extraction or silica adsorption by guanidinium and potassium salts

Nucleic acids were found to partition into the phenol phase during phenol extraction in the presence of guanidinium at certain concentrations under acidic conditions. The guanidinium-concentration-dependent nucleic acid partitioning patterns were analogous to those of the nucleic acid adsorption/partitioning onto silica mediated by guanidinium, which implied that phenol and silica interact with nucleic acids through similar mechanisms. A competition effect was observed in which the nucleic acids that had partitioned into the phenol phase or onto the silica solid phase could be recovered to the aqueous phases by potassium in a molecular weight–salt concentration-dependent manner (the higher molecular weight nucleic acids needed higher concentrations of potassium to be recovered, and vice versa). Methods were developed based on these findings to isolate total RNA from Escherichia coli. By controlling the concentrations of guanidinium and potassium salts used before phenol extraction or silica adsorption, we can selectively recover total RNA but not the high molecular weight genomic DNA in the aqueous phases. Genomic DNA-free total RNA obtained by our methods is suitable for RT-PCR or other purposes. The methods can also be adapted to isolate small RNAs or RNA in certain molecular weight ranges by changing the salt concentrations used.     

The sensitive determination of nucleic acids using a fluorescence-quenching method.

Experiments indicated that nucleic acids can quench the fluorescence of the Eu3+ -2-thenoyltrifluoroacetone (TTA)-1,10-phenanthroline (Phen) system. Based on this, a sensitive method for the determination of nucleic acids was proposed. The experiments indicated that under the optimum conditions, the quenched fluorescence intensity was in proportion to the concentration of nucleic acids in the range 1.0 x 10(-11)-1.0 x 10(-6) g/mL for yeast RNA (yRNA), 5.0 x 10(-11)-5.0 x 10(-7) g/mL for fish sperm (fsDNA) and 1.0 x 10(-10)-1.5 x 10(-6) g/mL for calf thymus DNA (ctDNA). Their detection limits were 3.0 x 10(-12), 4.0 x 10(-12) and 5.0 x 10(-11) g/mL, respectively. Therefore, the proposed method is one of the most sensitive methods available. The interaction between nucleic acids and Eu3+ -TTA-Phen is also discussed.     

Selective precipitation of ribonucleic acid from a mixture of total cellular nucleic acids extracted from cultured mammalian cells

A simple and reproducible method is described for precipitating RNA selectively from total mammalian-cell nucleic acids extracted by the phenol-sodium dodecyl sulphate procedure at pH8.0. Under specified conditions bulk RNA is precipitated almost quantitatively whereas bulk DNA remains in solution. Minor components of RNA (detected by pulse-labelling and chromatography on methylated albumin-kieselguhr) and rapidly labelled components of DNA containing single-stranded regions are also precipitated. The usefulness of the method is discussed in the context of isolating separately both RNA and DNA from cultured cells that are difficult to obtain in quantity.     

Iodination of proteins,glycoproteins, and peptides using a solid-phase oxidizing agent, 1,3,4,6-tetrachloro-3α,6α-diphenyl glycoluril (Iodogen)

A new, commercially available oxidizing agent, 1,3,4,6-tetrachloro-3α,6α-diphenyl glycoluril (Iodogen) was compared with chloramine-T and solid-phase lactoperoxidase in the radioiodination of proteins, glycoproteins, and peptides. A method for performing low-level iodinations is described and was used to determine maximum ¹²⁵I incorporation. Iodinated proteins were purified on analytical gel filtration columns and peptides by reverse-phase high-performance liquid chromatography. Both methods were designed to analyze the tracers for the presence of aggregate and breakdown products caused by the iodination. All tracers prepared were tested in antibody dilution and dose-response curves in their respective radioimmunoassays. Results indicate that Iodogen can be used for a wide range of proteins and peptides, can permit theoretical iodine incorporation with minimal oxidation damage, and can produce tracer stable for up to 3 months.